Gene, 121 (1992) 237-246 0 1992 Elsevier Science Publishers
GENE
B.V. All rights reserved.
237
0378-l 119/92/$05.00
06764
Sequence of rat lipoprotein (Mouse;
human;
bovine;
lipase-encoding
guinea pig; chicken;
PCR; untranslated
cDNA exon; A+T-rich
sequences;
CpG islands)
Didier Brault a, Lydie No& a, Jacqueline Etienne a, Jocelyne Hamelin b, Alain Raisonnier ‘, Aziz Souli a, Jean-Claude Chuat b, Isabelle Dugail d, Annie Quignard-Boulangi: d, Marcelle Lavau d and Francis Galibert a uLaboratoire de Biochimie et Biologic Molkulaire, Fact& de M&decine St-Antoine, 75012 Paris, France: b C.N.R.S. UPR 41, Centre Hayem, H6pital St-Louis, 75010 Paris. France. Tel. (33-l/42 02 1605; ’ Biochimie. CHU Piti&Salp&i&e, 75013 Paris, France. Tel. (33-l/40 779805; ’ INSERUM France. Tel. (33-l/4633 Received
U I 17. 75006 Paris,
7105
by G. Bernardi:
5 May 1992; Revised/Accepted:
9 July/l2
July 1992; Received
at publishers:
30 July 1992
SUMMARY
A rat lipoprotein lipase (LPL)-encoding cDNA (LPL) has been entirely sequenced and compared to the sequences of all the LPL cDNAs reported in other species. As expected, high homology was found between the coding exons. The putative catalytic triad, Ser’32, Aspire, His24’, according to human numbering, is conserved in rat. As is the case in mouse, an Asn444 present in human LPL is also missing. The major divergences between human, mouse and rat LPLs were observed in the untranslated exon 10, where (i) the rat cDNA exhibits a 157-bp insertion and an 81-bp deletion relative to human; (ii) neither the B 1 repeat nor the homopurine stretch reported in mouse can be recognized, and (iii) the rat cDNA displays several A+T-rich stretches.
INTRODUCTION
Lipoprotein lipase (LPL) is a key enzyme of lipoprotein metabolism that hydrolyzes the triglyceride moiety of chylomicrons and VLDL. It is involved in various pathologies, such as hyperlipemia, atherosclerosis and obesity. For studies on lipoproteins and LPL, rat is one of the most useful laboratory animals. Since it is resistant to this affection, rat is also a model for atherosclerosis research. Moreover, the genetical nature of its obesity makes the
Correspondence to: Dr. J. Etienne, Biochimie, Mtdecine
St-Antoine,
Tel. (33-1)40306249; Abbreviations:
27 rue Chaligny,
aa, amino acid(s); bp, base pair(s); DlT,
dithiothreitol;
or 1000 bp; h (prefix), human;
lipase; LPL, gene encoding
godeoxyribonucleotide;
507, Faculte de
Fax (33-1)40307840.
(prefix), guinea pig; kb, kilobase lipoprotein
Laboratory
75012 Paris, France.
PCR, polymerase
LPL; nt, nucleotide(s); chain reaction;
cytoplasmic RNA required for both structural of signal recognition protein.
oligo, oli-
7 SLRNA,
and functional
gp LPL, small
properties
Zucker rat a valuable model for research in this field. Lastly, cell lines derived from rat tissues lend themselves to studies of LPL gene expression. However, whereas in recent years the sequencing of LPL has been carried out, via cDNA, in five species, human (Wion et al., 1987), bovine (Senda et al., 1987) mouse (Kirchgessner et al., 1987; Semenkovich et al., 1989; Zechner et al., 1991), guinea pig (Enerback et al., 1987) and chicken (Cooper et al., 1989), it has not yet been determined in rat. The aim of this work was to clone and to sequence rat LPL cDNA as a preliminary to metabolic studies on LPL mRNA. Furthermore, it is meant as a contribution to the comparative study of LPL cDNA in different species, with a view to pointing out which aa have been conserved during evolution and are thus likely to belong to domains playing a major role in LPL activity. Four rat cDNA LPL clones were isolated. The longest, a 3.18-kb clone, lacked about 0.20 kb at the 5’ extremity with regard to the mRNA. The missing 5’ fragment was obtained by PCR. The cDNA sequence was compared to
238 of all the LPL cDNAs
the sequences
reported
in other
species. The divergences appearing between rat, mouse and human in the untranslated exon-10 are pointed out.
RESULTS
(b) Comparison of coding exons of rat LPL cDNA with LPL cDNAs from other species
AND DISCUSSION
(a) Nucleotide sequence of the rat cDNA The strategy used for sequencing the clone isolated from a rat cDNA library, as well as the 0.5-kb 5’ fragment obtained by PCR is shown in Fig. 1 and Table I. The clone comprises a total of 3.18 kb. It lacks the first 183 5’ nt coding
region has thus been achieved by sequencing the OS-kb 5’ fragment obtained by PCR. Nucleotide and aa sequences of rat, mouse, human, bovine, guinea pig and chicken have been aligned (Fig. 2).
for mature
LPL. The sequence
1) Clone RP . _. . . . . .) 5
’ 267
of this
(1) High homology
High homology is found between the coding exons of rat and human cDNA LPL, as well as with the other published An exception concerns guinea pig exon 1, which cannot be aligned with exons 1 of other species.
LPL cDNAs.
w19 El3 \“,, __________+ El . _.--. -. ) W5 -------w ..W!.3... w ______* ______+ w21 w9 Wll ______* ______+ WlS ___Y! ________) ____-_____) .--. w3_.._ t 3444 )
Wl ._..._. _)
OAC
3’
3’ 4-&---
2 ) 0.5 kb 5’ fragment
W4
WlO
4_.__.._.__ w2
I
s
RP
W16
w20
, W26
a)
RP ._.._.. __* b)
)
4 Fig. 1. Strategy
(Clontech
for sequencing
Laboratories,
.___._.._ UP
rat LPL cDNA.
The cDNA
Palo Alto, CA). It was screened
library used was prepared
from 4-week-old
with a 150-mer probe synthesized
the last 14 nt of exon-7 and to the 135 first nt of exon-8 of human the Ml3 vector). Four clones were isolated and subcloned
cDNA
LPL (plus
Sprague-Dawley
by the phosphoramidite
rat testicular
method.
1nt added to create a 5’ BumHI restriction
in the EcoRI site of pUC 18. The OS-kb 5’ fragment
was prepared
I
fat cells in lgtl
This probe corresponds
to
site for cloning into
by PCR. Briefly, total RNA
was isolated from rat frozen adipose tissue using the guanidium isothiocyanate/LiCI method as described by Cathala et al. (1983). Total RNA (6 pg) was heated at 65°C for 10 min before priming for cDNA synthesis with 125 ng random hexamer oligos (Pharmacia, Piscataway, NJ) in a 50 ~1 reaction containing
1 x reverse transcriptase
1 mM each dATP,
dGTP,
stopped by incubating This cDNA
dCTP
buffer (50 mM Tris.HCI and dTTP,
pH 8.3/75 mM KCljlO mM DTT/3 mM MgCl,),
and 200 units M-MLV
at 70°C for 10 min. The resulting cDNA
was used as a template
reverse transcriptase
was purified and concentrated
for PCR with (i) an upstream
primer (Table I: PCRl)
20 units RNasin
(BRL). The reaction on a Centricon consisting
(Promega,
was performed
Madison,
WI),
at 37°C for 60 min and
30 column (Amicon
of the first 20 nt transcribed
Corp., Danvers,
MA).
in mouse according
to Zechner et al. (1991). This was attempted in view of the high putative sequence similitude in rat and mouse; (ii) a rat LPL specific downstream primer (Table I: PCR2) complementary to rat nt 382 to 361 (Fig. 2) (plus EcoRI and Hind111 recognition sites). For PCR, samples were denaturated at 94°C (5 min), annealed at 52°C (2 min) and extended at 72°C (2 min)followed by 30cycles of 94”C(l min), 52°C (1 min) and 72°C (2 min) with a final extension of 10 min. The PCR product phosphorylation ing was carried
of approx.
580 bp was excised
and eluted from a 2% Nusieve
LMP
agarose
gel. This fragment
was subcloned
after
into M13mp89 cut by EcoRV and sequenced. The 0.5-kb fragment was inserted in the two possible orientations (a) and (b). Sequencout by the dideoxy method of Sanger et al. (1977), using [C(-35S]dATP, T7 DNA polymerase and the specific probes.
239 TABLE
I
Synthetic
oligos for PCR and for sequencing
the cat LPf. cDNA
(A) Oligos used for PCR PCR 1 = 5 ’ -TGTCAGACTCTCGATTTCTC
PCRZ = 5’-TATAGCCGGCAGACACTGGATA
382-361
(B) Oligos used for sequencing” (1) The 3.18kb
clone UP = TGTAAAACGGCCAGT
RP = AACAGCTT’AGACCATG
= ATGTCCAC~C~AGGGTAC
435-474
W2 = AATCACTGATGGAGGTGGAC
1887-1868
W3 = CGTGTAATTGCAGAGAAGGG
748-767
W4 = AGCCTAATGAAACCAGTCAC
1652-1633
WI
W5 = CGCTCTCAGATGCCCTACAA
997-1016
W6 = TTTCTGTTCCCAGCAACAG
1439-1421
W7 = GGTCAGACTGGTGGAGCAGT
1250-1269
W8 = GCTCCTCACTTTGCACGCAA
1247-1228
El3 = GGACGCTGCAGTGTTTGTGA
1371-1390
WlO = GCCAAGGCAGGATGGTTGAGA
940-920
W9 = GCAGAGAGGAGAAGCATGCC
240-259
W 12 = TGACTTGTACTTCGT-TGTGG
636-617
EI
385-366
= GGGCCT~TA~TCA~AG
349-368
W 14 = ~AAAACCTCAGAGATCTA
W Ii = AAGCAATGGACGACGTGGCT
572-591
W16 = ACT~CAAGATATAGCTGGG
W 13 = TCAGGCTTACCTTGAACTCT
903-922
W 18 = TCCCTGGCACAGAAGATGAC
1343-1324 1100-1081
148-129
W152 = GTACAAGTI-TTAGAGCAGGA
1141-1160
W20 = TACAGAGAAATCTCGAAGGC
W 17 = GCTCGTTGCCGCTCTTTTGT
1279-1298
W22 = TGTATGCCTTGCTGGGGTI’T
868-849
W 19 = CAGAAAGGAAAGAGTCAAGA
1515-1534
W24 = ACATCTACGAAATCCGCATC
624-604
W21=
1773-1792
W26 = TCAll-l-CCCACCAGCTTGGT
401-382
AGCTGTAAATAATGTGTGGG
(2) The 0.3-kb 5’ fragment RP = AACAGCTTAGACCATG
UP = TGTAAAACGGCCAGT
S( = PCRI) = TGTCAGACTCTCGATTTCTC
0 = CTGCTGTGGTTGAAGTGGCA
it The sequence Numbe~ng
of all the probes is given in the 5’ to 3’ direction.
is as in Fig. 2 (coding
sequence)
The left column corresponds
Divergences between the rat sequence and the five other sequences, from the first ATG to the stop codon (1428 nt), are shown in Table II. The ratio of transitions to transver-
TABLE
II
Divergence
between
six LPL cDNA
sequences
(1428 nt from the first
ATG 5’ nt, except for bovine, to the stop codon) Rat vs.:
Mouse
Human
Bovine
Guinea
Chicken
pig Identities Transitions
(I)
Transversions I/V Insertions
(V)
(i)
1358
1242
1151
1163
59
123
136
148
193
114
209 0.923
18 3.277
60 2.050
75 1.813
1023
1.298
0
1
1
1
1
1425
1426
1363
1426
1426
Informative positions” % Divergence’
5.40
12.90
15.55
28.26
18.44
’ For determining the number of positions, each gap was counted as one position, regardless of insertion length, as these gaps are no targets for substitution. Consequently, the insertion of an Asn codon at the end of the protein is counted for one position only rather than three, since obviously the two other positions stitution. b The percentage (1987) equation:
of divergence
to the sense sequence,
and Fig. 3 (exon 10). RP, reverse primer; UP, universal
are not informative was calculated
as regards
to nt sub-
by the Miyamoto
P % = (I + V + i) x lOO/Nb of informative
positions.
et al.
218-199 the right column
to the antisense.
primer.
sions decreases as divergence increases. This could be explained by a double substitution occurring at one position. Paradoxically, the percentage of divergence between rat and guinea pig is greater than between rat and human or human and bovine. However, results tending to place the guinea pig differently on the mammalian phylogenetic tree have been reported (Graur et al., 1991). The longest segments that present homology among the six species studied up to the present time are the end of exon 2 and the beginning of exon 3, This homology has not been previously pointed out. These regions comprisent 42-87, with only three nonconserved aa out of 46; even position 45, which has Thr in chicken, rather than Ser in the five mammals, is functional, since it belongs to the potential ~-glycosylation site, which accepts Ser or Thr (see section bl). Also conserved is the well-known nt 170-217 region (exon 5), with five nonconserved aa out of 48, or else region 234-264 (exon 6) with three nonconserved aa out of 31. But region 287-320, which Semenkovich et al. (1989) indicated as being well conserved at a time when the chicken sequence was not published appears to be less so (seven nonconserved aa out of 34). The ATG in position 1 for the five mammals, or positions 1 and 19 for chicken, which has two alternative start codons (Fig. 2) codes for the N-terminal Met of the hydrophobic signal sequence. The
240 Open Reading Frame
/
rLPt. mLPL hLPL
-174 T&TCT + GTAOCTGTTATGCCCT CcrJ TTT~~~~~TT~T~~ TACTCCTCCTCCGWEAATTCTGCGC CCTGTAACTGTTCT0XCTCXXCTlTAAAGGTTGACTT@XCTACG3ZSC TCCTCCTCCTCAAGGG~AAGCTGCCCACTTCTAGCTGZCCTGCJZATCCCCTTTAAAG~X~%CTT~XTC
rLPL mLPL hLPL
GACXXCTCCGGCTCAACCCTTTBXA TOCOCCTCCTGCTCAACC CXAGCCTCCGOCTG4GCC
rLPL mLPL hLPL bl.PL LPL cge PL
rLPL mLPL hLPL bLPL 2z.L rLPL r?tLPL hLPL bLPL c PL TPL
I
I
TrXCGDkXTGACT
CTATAGTCCTCT TCC4ccMi CTCCAGTETCT ACCGCCAAACCOCGGCTCCAGCCGTCT
’ GCCCGf&-GTTC&CA&CA GAA& CGCCGXTAGTTKZAGCAGAKAGAA~~~G CCGCCCCTTGTAGCTCCTC CAGAGGGA~CGAG
EEEEEW
GAG
ACW,TTTC!CAG4CATC&AGTAAATT 4 W.XTAAG&CCCTGAA d CACAGCTGA ki4 CACTTGT&ATCTG4TTC&TU3ATTA&KTCTGTG A~OATTTCTCAU\CATCGAAAGCAAATTTOCCCTAAOGA AG4GATTTTATCGACATCAAGTAAATTTOCCCTAAC AAAW\TTTTAOAG4CATTG4AAGTAAATTTGCTCTCAGGAG G4AC9CAOIT64GG4CACCTGTUICCTCATT~T~~~~~TCT~G AAAC?ATTATACGG4TATCAGTAAATTT‘XCO34AGG4fXCCCG4 ATGAATTTTGACYYjAATCGI\GAGCAAGTTTTCCTTAAGTTG l l e l 0 l l l l l ArgAspPheSerAsp Ile Glu Sar LysP~ AlaL~Arg Thr ProGl~ AspThr Ata~uA~pThrCysHis Lau lle Peony Lau AlaA~S~r ArgAspPheSerAsp Ile Glu Ser Lys Pha Ala LsuArg Thr Pro Glu AspThr Ala Glu AspThrCys His Lau Ile Pro Gly Leu Ala AspSer ArgAspPhs Ile Asp Ile Glu Ser Lys Pha Ala Lw Arg Thr Pro Glu AspThr Ala Glu AspThrCys His Lsu Ile Pro Gly Val Ala Glu SW LysAspPhsArgAsp lie Glu Ser Lys Phs Ala Lau Arg Thr Pro Glu AspThr Ala Glu AspThrCys His Lau Ile Pro Gly Val Thr Glu Ser L s Asp Tyr Thr Asp Ile Glu Ser Lys Phs Ala Arg Arg Thr Pro Glu Asn Thr Val Glu Asp Thr Cys His Lau lle Pro Gly Val Thr Glu Ser Myet Lys Pi-m Glu Gly Ile Glu Ser Lys Phs SW Lw Arg Thr Pro Ala Glu Pro Asp Glu Asp Val Cys Tyr Lau Val Pro Gly Gln Mat Asp Ser
Ser AsnCts Ser AsnCys
hLPL bLPL
Ala Thr Cys His AlaAsnCys His Ala AsnCys His Ala Gln CysAsn
192 l;: 126 162 102 Val Val Vat ‘2.4 Vat Leu
Phe Asn Phe Asn PheAsn PheAsn
l * l e*e His Ser SW Lys Thr Pha Val Val His Ser SW Lys Thr Pha Val Val His His His His
SW Ser Ser Thr
SW SW SW Ser
Lys Lys Lys Lys
Thr Thr Thr Thr
Phe Pha Pha Pha
Met Val Met Val
Val Val Val Val
c:: 291 225 261 291
*ee*****ee***eeeee Ile Ile
His Gly Trp Thr Val Thr Gly Mel Tyr Glu Ser Trp Val Pro Lys Lau Val Ala His Gly Trp Thr Val Thr Gly Met Tyr Glu Ser Trp Val Pro Lys Leu Val Ala
Ile 11s Ile Ile
His His His His
Gly Gly Qly Gly
Trp Trp Trp Trp
Thr Thr Thr Thr
Val Vat Vat Val
Thr Thr Thr Thr
Gly Gly Gly Gly
Met Met Met Mat
Ttr Tyr Tyr Tyr
Glu Glu Glu 610
Ser Ser Ser Ser
Trp Trp Trp Trp
Val Val Val Val
Pro Pro Pro Pro
Lys Lys Lys Lys
Leu Leu Leu Leu
rLPL InLPL hLPL bLF3. LPL 9e c PL
Ala Ala Ala Ala
rLPL mLPL hLPL bLPL
rLPL IllLPL
GTGOGAAAT b TGT-LTCATCAA k TGfXTGWIGkAAGAATTT J CTACWCCT 1 GACAATGT &ACCTCTTAG~GTA~GTCT~G~GCCC.AT GTGGG9AATGATCiT-GATTCATCAACT~T~~~~TT~~A~TA~~~~~TCTTA~A~~TT~~~T TTATCAACTG04TGGAc33WWGTTTAACTACCCTCT~~AT~CC4TCTCTTGGGATACA~TT~~T GTGf33CAGGATOTGGCCWGT GGCGGPTGAATTTAACTATCCCCTGGGCAATGTGCATCTCTT~TACAGCCTT~T GTGWACAGGATGT GGCCAAGTTTATOAACTGGAT GTTG6909AGATGTAGCCA~TTATCAACTOOATGG4aC GIGOG4AAEOATFTTGCCATGITCATTGATIGG9TGG(\GT l eeeeeeeeeee V& $y AsnA?pV% A?a Arg P% lie Asn Tfp Leu Glu Glu Glu Pt Asn TTr Pro Leu AspAsn Val His Lau Leu Gly Tyr Val Gly A:n Asp Val Ala Arg Phe lie Asn Trp Met Glu Glu Glu Pha Lys Tyr Pro Leu AspAsn Val His Lau Lau Gly
hLPL bLPL LPL c9: PL
Val Gly Vs.1 Gly Val Gly Val Gly
(continued
on
Lau Lsu Lau Leu
p.
Tyr Tyr Tyr Tyr
&In Gln Glu Lys
Lys Arg Glu Pro Lys Arg Glu Prc Lys Arg Glu Pro Lys Arg Glu Pro
Asp Asp Asp Asp
Val Val Val Val
Ala Arg Ala Lys Ala Arg AlaMet
Asp Asp Asp Asp
Pha Phs Phs Pb
Ser Ser Ser Ser
Ile Met Ile Ile
Asn Asn Asn Asn
Vat Vat Val Val
Asn Trp Asn Trp Asn Trp AspTrp
lie Val Ile Val Ile Val Ile Val
Met Met Met Met
Glu Ala Glu Glu
Val Val Val Val
Glu Asp Asp Glu
Asp Asp Asp Asp
Glu Glu Glu Lys
Trp Tip Trp Trp
V’,l Val Val Val
l l l l l l l l e l l l Leu TyrArgAla Gln Gin His Tyr Pro Val Ser Ala Gly Tyr Thr Lys Leu Lau Tyr Arg Ala Gln Gln His Tyr Pro Val Ser Ala Gly Tyr Thr Lys Leu
SW
Lw Arg Ala Lau SW Arg Ala La! Ar Arg Ala Lau Va I Arg Ala
PhaAsn PhaAsn Phe Lys PheAsn
Tyr Tyr Tyr Tyr
Pro Pro Ser Pro
Gin Gin Gln Gln
Glu Gln His Gln
Lsu AspAsn Lau Gly Asn ValAspAsn LsuAsnAsn
His His His His
Val Val Val Val
Tyr Tyr Tyr Tyr
His His His His
Pro Pro Pro Pro
Lsu Lsu Lw Lau
Val Val Glu Val
Leu Leu Lsu Lsu
Ser Set Ser Ssr
Gly Gly Gly Gly
Ala Ala Ala Ala
Gly Gly Asp Ala
Tyr Tyr Tyr Tyr
Thr Thr Thr Thr
Lzs Lys Lys Lys
:II
Ala Ala Ala Asp
+ GTAT ~-CAT!ATC~~~T~TA!ACCG GCAACATTATC09GTGTCAOCTGGCTACACCAACCTG TACACCAAACTG GZAGCATTATCCAGTGTCTGCAGWTACACZAAGCTG GQ3XCAWXCATTACCCAGGTCTGCGGACTACACCAA~TG
COXTATA~AAAGWi4ACkTGACTCCAA 4 GTCATTGTA&TAGACTGGT GCCCTGiftCAAWIGAWUlCCT~ATGTUITTGTAG OCCCTGTACAA~AW\WU\CCAGI\CTCCAATOTCI\TTGT GCCTTGTACAAG9GGG4ACCGGACTCCAACOTCATCOTOO GCTCTGTACAAOAGGOAACCAGACTCCAATGTUITTGTOO GCTCTGTACAAOAGOGAACCTGATTCAAAT~~TTGTTTG l ee*eeeeeee*eeeee Ala Lsu Tyr LysArg Glu ProAspSerAsnVal Ile Val ValAspTrp Ala Lsu Tyr Lys Arg Glu ProAsp Ser Asn Val Ile Val ValAspT;p
OPL TPL
Fig. 2
l l His PhaAsn His PheAsn
rLPL mLPL
2% LPI. cBe PL
1; -1
Met Asn tie AspArg Lys Ire Lau Asn Lys Ala Leu Ala Lys Glu Lys Val Met Glu Arg Gly Arg Gly Met Gly Lys Tyr Ala Lw Lsu Ala Val Lsu Cys LauCys Lsu Arg Gly Ala Ala Gly
3EL
rLPL InLPL
-72
_Sienal eplide Met Glu g er Lys Ala Lsu Leu Lau Val Ala Leu Gly Val Trp Leu Gln Ser Leu Thr Ala Phs Arg Gly Gly Val Ala Ala Met Glu Ser Lys Ala Lsu Lau Lsu Val Val Leo Qly Val Trp Lau Gln SW Lau Thr Ala PI-e Arg Gly Gly Val Ala Ala Met Glu SW Lys Ala Leu Leu Val Lsu Thr Lw Ala Val Trp Lau Gln Ser Leu Thr Ala Ser Arg Gly Gly Val Ala Ala
rLPL nlLPL hLPL bLPL
%F
:p:
Leu Leu Leu Lw
390 390 390 324 360 300 103 103 103 105 103 105
469 469 489 423 459 460 136 136 136 136 136 136
241)
first aa of the mature protein is conserved in four of the six species. It is Ala in rat, human, mouse and guinea pig. In rat, human and mouse, this Ala is the third of a stretch of three Ala, while there is no such stretch in guinea pig. There are two more N-terminal aa in bovine, -Asp-Arg, followed by Ile instead of Ala and in chicken, Ser-Asp followed by Pro instead of Ala. In rat, we found that aa 444 of the
human sequence (Asn) is missing, as was the case in mouse (Zeckner et al., 1991). In chicken, the C-terminal sequence is 15 aa longer (see below for an explanation). All these particular differences result in hLPL and gpLPL being 448 aa long, while rat and mouse are 447 (448 -1) bovine 450 (448 + 2), and chicken 465 (448 + 2 + 15).
241
rLPL mLPL hLPL bLPL LPL Be c PL
GCT~T~TTGCA~OCT~~TM~~~~~TTACT~T~T~~T~~T~CTTT~~AT~~~GT GCT~T~ATTGCAGOI\AGTCT~~TM~~~~~TM~TTA~T~~T~~TMCTT~~AT~~~T~GT GCTOCTGGCGTTGCTGGGAGTCOGACCAATACGAAGGTCAGT GAAAAAGGTOI\ACAGPIATTACTOOTCT~T~T~T~~~T~T~.~~T~T~T~TATC ~T~T~TT”.‘~~TTAAeW l eeeee*e*e l l Pro Ala Gly Pro As” Phs Ala Ala Gly Val Ala Gly Se, Leu Asn Lys Lys Val As” Arg Ile Thr Gly Leu rLPL P;o Ala Gly Pro As” Pi-m Ala Ala Gly Val Ala GJy Se, Leu Thr As” Lys Lys Val As” Arg Ile Thr Gly Lsu mLPL * P;o Ala Gly Pro As” Phe hLPL Ala Ala Gly Its Ala &y Se, Lsu Thr As” Lys Lys Val As” Arg Ile Thr kly Lsu Pro Ala Gly Pro As” Phs bLPL Ala Ala Gly Ile Ala Gly Se, Lsu Thr As” L s Lys Val As” Arg Ile Thr Gly Lsu Pro Ala Gly Pro Am Phs LPL Ala Ala Gly Val Ala Gly Se, Arg Thr As” T 6 r Lys Val Se, Arg Ile Thr Gly Lsu Pro AlaGly ProThrPhsGlu cge PL Ala AlaGly Ile AlaGly Se, LsuThrLys LysLysValAsnArg Ile Thr Gly LB”
Th,
. Gl” Tyr Ala Glu Ala Glu Tyr Ala Gl” Ala
Pro Se, Pro SW
169 169
Gl” Tyr Ala Glu Ala Pro Se, Glu Tyr Ala Glu Ala Pro Se, Glu Tyr Ala Glu Ala Thr Se, Tyr AlaAspAla Pro Ile
169 171 169 171
66.7 667 607 621 657 667
rLPL
KY-
bLPL LPL ge c PL rLPL mLPL
hLPL bLPL LPL cge PL
_-__.-...__.. Pro
l eeeeee l eeeeee Arg Leu SW AspAsp Ala AspPhs Val AspVal Arg Lsu Ser ProAspAspAlaAspPhs ValAspVal * Arg Lsu Ser Pro AspAsp Ala AspPhs ValAsp Val Arg Lsu Ser Pro AspAsp Ala AspPhs Val AspVal Arg Lsu SW ProAspAsp Ala Gln PheVal AspVal Arg Lsu SW Pro AspAsp AlaAsp Phs Val AspVal
l l l l l l eeeeeeeeee Lsu His Thr Phe ThrArg Gly SW Pro Gly Arg Ser Ile Gly II8 Lsu His Thr PhsThr Arg G:y Ser Pro Gly Arg Ser Ile Gly Ile * Lsu His Thr Phs Thr Arg Gly SW Pro Gly Arg SW Ile Gly Ile Lsu His Thr Phs Thr Arg Gly SW Pro Gly Arg Ser Ile Gly Ile Lsu His Thr PheThr Arg Gly Ser Pro Gly Arg SW Ile Gly Ile Lsu His Thr Tyr Thr Arg Gly Ser ProAspArg Ser Ile Gly Ile
Gln Lys Pro Val Gly His Gin Lys Pro Val Gly HIS
202 202
Gln Gl” Gln Gln
202 204 202 204
Lys Lys Lys Lys
Pro Pro Pro Pro
Val Val Val Val
Gly Gly Gly Gly
His His His His
766 766 766 720 756 706
,LPL mLPL hLPL bLPL LPL cBe PL rLPL mLPL
235 237 235 237
hLPL bLPL LPL cgP PL
rLPL mLPL hLPL bLPL LPL cge PL ,LPL mLPL
CTAGTGAAGTGCTCCCACGAGCGCTCCATTCATCTCTTCAA CTGGTG9AGTGCTCCCAC~T~T~TCTCTCTTCA CTAGT~GTGCTCCCATGAGCOCTCCATTCATCTCTTCG CTGGTOPIAOT~TCTCATOAACGPITCCATCTCTT~TT~CT~CT~TCTAT~~e~~~T~TA~T~A~~A~G l eeeeee*eeeooeeeee Glu Arg Ser Ile His Lsu Phs Ile Asp Ser Lsu Leu Asn Glu Glu Asn PTo St, Lys A7.s TT,A?gCTsAsn Se, L:s &J Glu Arg Ser Ile His Leu Phs Ile Asp SW Lsu Leu Asn Glu Glu Asn Pro Ser Lys Ala Tyr Arg Cys Asn SW Lys Glu Glu Glu Glu Glu
hLPL bLPL ZK’
rLPL mLPL hLPL bLPL LPL cge PL rLPL mLPL hLPL bLPL LPL cge PL
rLPL mLPL hLPL bLPL LPL cge PL rLPL mLPL hLPL bLPL LPL cge PL
Fig. 2. (continued
A?g Arg Arg Arg
S*r Ser SW Ser
Ile Ile Ile Ile
His His His His
Leu Lsu Lsu Lsu
Phs Phe Phs Phs
II8 Ile Ile Ile
A:p Asp Asp Asp
Ser Ser Ser Ser
Leu Lsu Lsu Lsu
Leu Leu Leu Lsu
Asn Asn Asn Tyr
Glu Glu Glu Glu
Glu Glu Glu Glu
Asn Asn Asn Lys
Pro Pro Pro Pro
~TTTGAGAAAOGGCTCTGCTTGAGTTGTAGAAAGPJ\TG ~TTT~-OGTCTCTG~~T~~~~T~~~T-TA~~T~~~~~~~~~-~TG ~TTTGAAAAAOGGCTCT~T~~T~~M~~T~~~~~TA~~T~A~~~~~~~~-~TG G9ACCGTTGCAACAACTTGTATAAAGTCAACAGAGTGTG GXTTTG4WGajCCTCTGCCTAA~Tl l eeeeeeeeeeeee*e* l l Ala Phe Glu Lys Gly Lsu Cys Lsu Se, Cys Arg Lys As” Arg Cys As” As” Val Gly Tyr Glu Ile Asn Ala Phs Glu Lys Gly Lsu Cys Leu Se, Cys Arg Lys Asn Arg Cys AsnAs” Leu Gly Tyr Gl” Ile Asn Ala Phs Glu Lys Gly Lsu Cys Leu Se, Cys Arg Lys Asn Arg CysAsnAs” Lsu Gly Tyr Glu II8 As” Ala Phs Glu Lys Gly Lsu Cys Lsu SerCys Arg LysAs”ArgCysAsnAsnMeI Gly Tyr Glu Ile As” Ala Phs Glu Lys Gly Lsu Cys Leu Se, Cys Arg LysAs”ArgCysAs”As” Val Gly Tyr Gl” Ile As” Ala Phs Glu Lys Gly Leu Cys Leu Se, Cys Arg LysAs”ArgCysAsnAs” Lsu Gly Tyr Lys Val As”
Gt CAAGATTCA A TTTTCTGGP, TACCTGAA d CTCGCTCT d GATGXCTA &AA AGTATTCkATTACCAA TACCTGPJIGACTCGCTCTC~T~TACAAAGTGTTCC TACCTGPIP~CTCGTTCTCAGATGCCCTACAAAGTCTT~TTA-~~~TT~TTTTTCT-CT~~~~~TA-T~~C TACCTGAA~CTCGTTCTCAG4TGCCTTACAAAGTCTTCCC TACCT09AGACTCCCTCACA~T~TACAAAGTGTTWC TACTTG4AGACCCGT~TC~T~TACAAAGTCTTC l eeeoeeeeeeem T:r L’, L;s T!, A?g SW Gln Met Pro Tyr Lys Val Phs His Tyr Gln Val Lys Ile His P’;, Ser G?y Tyr Leu Lys Thr Arg Ser Gln Mel Pro Tyr Lys Val Phs His Tyr Gln Val Lys Ile His Phs SW Gly Tyr Lsu Lys Thr Arg Ser Gln Met Pro Tyr Lys Val Phe His Tyr Gln Val Lys Ile His Phs SW Gly Tyr Lsu Lys Thr Arg Ser Gln Met Pro Tyr Lys Val Phs His Tyr Gln Val Lys 11s His Phs Ser Gly Tyr Lsu Lys Thr Arg Ser Gln Met Pro Tyr Lys Val Phs His Tyr Gln Val Lys Ile Tyr Phs Ser Gly Tyr Lsu Lys Thr Arg Ala Gln Met Pro Tyr Lys Val Phs His Tyr Gln Val Lys Ile HIS Phs Phs Gly
Ser SW Ser Ser
Lys Lys Lys Mel
Ala Ala Ala Ala
Tt, Tyr Tyr Tyr
Arg Arg Arg Arg
Cys Cys Cys Cys
Ser Asn Asn Asn
Ser Ser Ser Thr
Lys Lys Lys Lys
Glu Glu Glu Glu
665 665 085 619 655 605 266 266 266 270 266 270
964 964 964 916 954 964 Lys Lys Lys Lys Lys Arg
l Val Val Val Val Val Val
l Arg Arg Arg Arg Arg Arg
Ala Ala Ala Ala Ala Thr
ACTGAGAAT d
Thr Thr Thr Thr Thr Lys
Glu Glu Glu Glu Glu Thr
Asn Asn Ser Ser Thr Asn
. Lys Lys Lys Lys Lys Lys
l Arg Arg Arg Arg Arg Arg
Se, Se, Se, Se, Se, As”
CAAGCAAAA
Asp Gly Glu Asn Thr Val
Lys L s T yhr Thr Thr Thr
Gln Gln His Tyr Tyr Lys
Se, Se, Se, SW Se, Thr
l Lys Lys Lys Lys Lys Lys
l Met Met Met Mel Met Met
kwc.acc
AsnAsn His Asn Thr Am Thr Asn Thr Asn Val Asp
C% Gln Gln Gln Gln Gln
301 301 301 z 303
1063 1063 1063 1017 1053 1063 Ala Ala Ala Ala Ala Pro
334 E 336 334 336
on p. 242)
The putative catalytic triads Ser13*, AsP’~~, His241 coded by exons 4, 5 and 6 in human is conserved in rat, with the same aa in the same positions, the codon for Ser13*, however, being AGC in human and AGT in rat. Ser13* occurs in the consensus sequence Gly-Xaa-Ser-Xaa-Gly present in serine proteinases and in human pancreatic lipase. It has
been shown that hydrolysis of tri- and monoacylglycerol by LPL stems from a common active site. The catalytic site and the heparin-binding domain reside on two separate folded domains. Although the heparin-binding domain of LPL has not yet been definitely assigned, this site was shown by peptide cleavage experiments (Olivecrona et al.,
242
1182 1162
1LPL mLPL hLPL bLPL LPL c PL ge rLPL mLPL hLPL bLPL LPL cge PL
rLPL mLPL hLPL bLPL LPL cge PL rLPL mLPL hLPL bLPL ZK’
rLPL I$?blPL LPL cBe PL rLPL mLPL hLPL bLPL splPL CLPL
1::: 1t52 1182 & Phe Phe Phe Phe Phe
Glu Glu Glu Glu Glu Leu
It, Ile Ile I le Ile lie
Sir Ser Ser Ser Ser Ser
t Leu Leu Leu Leu Leu
T-r Tyr Tyr Tyr Tyr Tyr
T:r Thr Thr Thr Thr Thr
Val Val Val Val Val Leu
l Glu Glu Glu Glu Glu Glu
Ala Ala Ala Ala Ala Asp
e**ea**ee**e Ser Giu As” Ser Glu As” Ser Glu As” Ser Glu As” Ser Glu As” Ser Glu Asn
ile Pro Phe Thr Leu Pro Glu Ile Pro Phe Thr Leu Pro Glu Ile Pro Phe Thr Lw Pro GIu Ile Pro Phe Thr Leu Pro Glu Ile Pro Phe Thr Leu Pro Glu Ile Pro Plm Thr Leu Pro Glu
Val Val Val Val Val Val
Ser Ser Ser Ser Ser Ser
Thr Thr Thr Thr Ala Ser
A:” Lys As” Lys As” Lys As” Lys AsnAsn As” Lys
l Thr Thr Thr Thr Thr Thr
Tyr Tyr Tyr Tyr Tyr Phe
l Ser Ser Ser Ser Ser Ser
l Phe Ptw Phe Phe Phe Phe
l Lw Leu Leu Leu Leu Leu
lie Ile I le Leu Ile lie
T:r Tyr Tyr Tyr Tyr Tyr
367 367 367 369 367 369
1281 1261 1281
l eeeee l ee Thr Glu Val Asp I le Gly Glu Leu Leu Met Met L;s t Lys T:p Thr Glu Val Asp 118 Gly Glu Leu Lw Met Met Lys Leu Lys Trp * Thr Glu Val Asp Ile Gly Glu Leu Lea Me( Leu Lys Leu Lys Trp Thr Glu Val Asp Ile Cly Glu Leu Leu Mel Leu Lys Leu Lys Trp Thr Glu Val Asp Ile Gly Glu Leu Leu Met Leu Lys Leu Lys Trp Thr Glu Val Asp lie Gly AspLeu Leu Met Leu Lys Leu Gl” Trp
I
I
I
ATUMCNAW\TCCG4GTG4AACD.%XA~GACTCAGAA ATCGAG9GGATCCGAOTOAAAGCCOGI\OAGACTCAGAAA ATTCAGAAGATCA~OTAAAAGCAGGAGPIGACTCAGAA ATTEYrJ\AGAT~WIG~~~~CT~~~~~TCTTCT~T~ ATCGAAAAG9TCAG9GTAAAAOCAOU\GAGR04CAG4AA ATTCAGAG4GT~GAGTG9AGTCRGOCUIAACTCAG4AA l eeeee . eee Ile Glu Lys Ile Arg Val Lys Ala Gly Glu Thr Gln I le Glu Arg Ile Arg Val Lys Ala Gly Glu Thr Gln Ile Gln Lvs Ile Am Val Lvs Ala Glv Glu Thr Gin Ile Gly c(‘s lie Ari Val L,, Ala Glj, Glu Thr Gln lfe Glu Lys II8 Arg Val Lys Ala Gly Glu Thr Gin I le Gln Arg Val Arg Val Lys Ser Gly Glu Thr Gln
I rLPL “lLPL hLPL bLPL
‘.i?y Gly Gly Gly Gly Gly
I
1::: 1281 Lys Ser Asp Ser T yr Pk S:r T:p Ser Asp Ttp T:p Ser SW Pro Ser P: Val Mei Ser Asp Ser Tyr Phe Ser Trp ProAsp Trp Trp Ser SW Pro Ser Phe Val Lys Ile Ile Glu
SerAsp Ser Ser Asp Ser Thr Glu Ser Lys AspThr
Tyr Tyr Tyr Phe
Phe Phe Phe phe
SW SW Ser Ser
Trp Trp Trp Trp
SerAsp Ser As” Ser Ser Ser Asn
Trp Trp Trp Trp
Trp Trp Trp Trp
Ser Ser Gly Thr
SW Ser Arg Pro
Pro Pro Pro Phe
Gly Gly Thr Ala
Plw Ala PheAsp Phe Thr Phe Thr
1380 1380 1380 1314 1350 1360
Ad, GGTCATCT!CTGTGCCAC~~~T~CT~~CT~~A~~~~T~A ~TGTCTTATCTOCAOA~A~~~~~~
l
Lys Lys Lvs L+ Lys Lys
Lys Lys Lvs L,, Lys Lys
Val Val Val Val lie Vat
Ile Ile Ile lie Vat Val
*
PheCys Ala PheCys PheCvs PheC;s PheCys Phe Cys
Ala Ser Ser Ser Ser
l Arg Arg Ara Ar; Arg Arg
Glu Glu Glu Glu Glu Asp
Lys Lys Lvs Ljrs Lys Gly
I
I
Val Val Val Met Vat Ser
l Ser Ser Ser Ser Ser Ser
His His His Tyr Lys Arg
e Lw Leu Leu L&w Leo Leu
I
Gln Gln Gln Gl” Gin Gly
400 402 400 402
l Lys Lys Lvs L$s Lys Lys
l Gly Gly Glv Glj, Gly Gly
LysAspArg Lys Asp Ser Lvs Ala Pro Lis Sar Pro Lys Glu Ala Glu Glu Ala
I
Ala Ala Ala Vat Pro Ala
433 433 433 435 433 435
I
GTGTTTGTWAATGCCATGKAAGTCTCTG GTGTTTGTGAAATWCAT69CAAGTCTCTG
ZKL rLPL mLPL
l l l l Val Phe Val Lys Cys His Asp Lys Ser Leu Val Phe Val Lys Cys His Asp Lys Ser Lw
hLPL bLPL gpLPL CLPL
Val Ile Val Ile
Fig. 2. Nucleotidc
Val Val Val Val
sequences
guinea pig and chicken aa (although
Pha Pha Phe Ptw
Lys Cys LysCys Lys Cys Lys Cys
Lys Lys Lys Gln
mouse (mLPL), bovine (bLPL), guinea
pig
of chicken
are translated
again in Fig. 3 in order to align all the exon-10 in the six species are indicated
and deduced
The beginning
aa of chicken
*
Ser Lw Asn Lys Lys Ser LeuAsn Arg Lys Ser Lou Asn Lys Lys Pro Val Ser Arg Lys
of rat ML cDNA
sequences.
the C-terminal
His Asp His Asp His Asp LWJ Glu
. l Lys Lys SW GtySlop Lys Lys Set GlyStop
sequences.
(gpLPL)
SW Ser SW Arg
447 447
Slop
Gly GlyStop GlySlop Gly Gly Ala
aa sequence.
448 450 448 Lys Lys Ala Ser Lys Glu Asn SW Ala
The nt sequence of rat LPL cDNA.
exon-10 sequence
from the beginning
1987) to be located in the middle part of the C-terminal region. A candidate region is Ly~~~~-Lys”“” (numbered as in human LPL), that harbours a cluster of positively charged aa. Thus, 5 aa out of 9 (italicised) are positively charged (KVRARRSSK). This sequence, located in exon 6 (human gene), is entirely conserved in terms of aa with, however, four codons differing at the third base in art, mouse, human, bovine and guinea pig (Enerbgck et al., 1987). In chicken, there is only functional homology and no identity, RVRTKRNTK. Cooper et al. (1989) proposed three other candidate regions by analogy with the heparinbinding regions of apolipoproteins E and B. Such a region is found in 279-282 (human numbering), where RKNR is conserved in all six species (in terms of aa not codons). The ten conserved Cys of the previously described species are also conserved in rat (Cys 27, 40, 216, 239, 264,
465
with human, mouse, bovine,
as predicted
mutations
all the C-terminal
and not from the end of exon-9 as for the other 5 cDNAs)
and chicken (cLPL). The aaof the catalytic
by black spots; those involved in missense
Comparison
is written twice, once in this figure, in order to gather
of exon-10
Aligned aa sequences
His Glu SW AlaStop
from LPL cDNA
clones for rat (rLPL),
human
and
(hLPL),
triad (Ser’j2, AsP’~~, His2” ) are boxed. Those aa conserved
in human
are indicated
by asterisks.
275, 278, 283,418,438). The sequences around these Cys are highly conserved. It has been shown for bovine LPL that all Cys were disulfide-bonded (Yang et al., 1989). Two N-glycosylation sites, Asn43 and Asn359, that correspond to the consensus sequence Asn-Xaa-Ser/Thr where Pro is excluded as Xaa and that have been previously shown to be conserved in all five species, are also conserved in rat. At the present time, the LPI, site of interaction with apolipoprotein CII has not yet been identified. Similarly, the site involved in the formation of the LPL homodimer, the active predominant form of LPL bound to endothelial heparan sulfate, remains to be established. Interestingly, the aa involved in the missense mutations already known to be responsible for human LPL deficiency are all conserved in all six species, with two apparent ex-
243 ceptions.
These
following.
In exon 3: Tyr61 (+ Stop), Va169 (+Leu),
aa, that are indicated
in Fig. 2, are the Trp*’
(+Arg),
Lys102 (+insertion + frameshift), Glnlo6 (- Stop); in exon 4: His136 (-+ Arg), Gly14* (4 Glu), G~Y’~~ (4 Ser); in exon 5: Asp156 (+Gly or +Asn), Pro15’ (+Arg), Ala’76 (+Thr), Gly”’ (-+Glu), Ile’94 (+Thr), Asp204 (+Glu), Ile205 (+ Ser), Pro*” (+Leu), Cys216 (+ Ser), Ala221 (+frameshift); in exon 6: Arg243 (-+His), Ser244 (+Thr), Tyr262 (+ Stop); in exon 8: Trp 382 Asp250 (+Asn), (+ Stop); in exon 9: Ser447 (+ Stop). One exception occurs in Ser447, but this exception is more apparent than real, because this mutation has been likened to a polymorphism rather than to a source of metabolic pathology. In fact, the two last aa of LPL are not necessary for LPL activity. Another exception is Glnlo6, but in this case we are dealing with premature termination of the peptide chain rather than with a missense mutation. For references concerning these mutations, see a review by Etienne et al. (1992). (2) CG content CG sequences are known to be rather unevenly distributed in the genome. CGs have been lost in the course of evolution, leaving vertebrates with a remarkable deficiency of this dinucleotide in the different genes (where CG/GC: is approx. 0.1) except in the regions surrounding the promoters of housekeeping genes, the CpG island, where CC/CC is approx. 1. LPL exons 2 to 9 are relatively rich in CG. The ratios CG/GC are 0.41,0.42,0.43,0.47,0.53,0.26 for rat, mouse, human, bovine, guinea pig and chicken, respectively. The role of CG enrichment in these exons cannot be presently explained. (c) Comparison of the sequences of the untranslated exon 10 The 3.18-kb clone alone covers the whole of rat exon 10, while several overlapping clones in mouse and in human were necessary to achieve this. The untranslated exon 10 of rat LPL cDNA is 2019 nt long, i.e., it is longer than the total of the nine other coding exons (1160 nt). This exon is 1948 nt long in human (Wion et al., 1987) and 2353 nt in mouse (Zechner et al., 1991). Gene LPL organization is known for human (Deeb and Peng, 1989; Kirchgessner et al., 1989), mouse (Zechner et al., 1991), and chicken (Cooper et al., 1992). Exon 10 starts with A, the last nt of the stop codon TGA that was interrupted by intron 9. This is the only known example so far of stop codon interruption by an intron (3.1-kb long in human and mouse) or with the last noncoding exon containing only the third nt of the stop codon and overriding in length the total of the coding exons located upstream. Remarkably, in chicken (Cooper et al., 1992) the last codon in exon 9 interrupted by intron 9 is GG/T (Gly)
rather than TG/A (stop codon), as is the case in human and the four other species.
Chicken
exon 10 thus presents
a
short ORF translated into Gly + 14 aa up to the next stop codon. This explains why the chicken aa sequence is longer, not because exon 9 is longer, but because there is no stop codon between exon 9 and exon 10 (Figs. 2 and 3). Zechner et al. (1991) have reported in mouse an insert (relative to man) consisting of (i) a Bl repetitive element (Kalb et al., 1983) (belonging to the Ah family) of 152 nt followed by (ii) a homopurine stretch of 169 nt consisting solely of A and G residues. This insert is flanked just upstream (GAAAATGAGCTTATAA) and downstream (GAAAATGAGCTTGTAA) by a 16-nt direct repeat. (differing only where italicised; see Fig. 3.) Six different mouse strains were tested by Zechner et al. (1991) and the B 1 element was found in exon 10 of all these. The mouse insert was not described by Kirchgessner et al. (1987) because their clone stopped about 250 nt ahead of it. In rat, both the Bl repetitive element and the homopurine stretch are missing. Consequently, only one of the two repeats is present. One copy of this direct repeat is found in human exon 10 and bovine exon 10, which likewise lack the mouse-specific Bl element (Fig. 3). Zechner et al. (1991) have reported in mouse a 195-nt region, located just after the 3’ direct repeat following the insert, that has no homology to human 3’ cDNA. We have also found this region in rat, where it includes a stretch of 157 nt that is highly homologous to the 3’ part of this mouse sequence. However, it is deleted in man. This clearly appears when the sequences of mouse, human and rat are aligned. The 157-nt stretch was compared to known rodent repetitive elements, such as mouse Bl (or Ah type I), also present in rat (Kalb et al., 1983); rat B2 (Bains et al., 1989) (or Ah type 2) (Kalb et al., 1989) and rat newtype (Kalb et al., 1989) both also present in mouse. There is no homology with any of these. Of course, there is no homology with 7 SLRNA either, since this element, which is assumed to be the progenitor of the Bl family, is itself homologous to the Bl element (Quentin, 1989). However, a sequence of this mouse/rat insert can be recognized in other genes: 930CCTGCCTTGGCTTCCTGAGTGCTGGGA956 (Fig. 3). Its percentage of homology (interrogation of the data bank GenBank) is 74% with the murine eosinophil differentiation factor (interleukin 5)-encoding gene, 88 % with the hamster replication-initiation locus, 88 % with mouse pim-1 proto-oncogene, 85% with mouse p-2 microglobulin-encoding gene, 8 1 y0 with human cosmid clone HDAB, 85% with human PRT, 77% with rat heme oxygenase-encoding gene, 74% with R. norvegicus toninencoding gene, 66% with human apolipoprotein E-encoding gene, 88 y0 with HSAG-1 middle repetitive element, 81 y0 with the mouse surfeit locus, 74% with the mouse
244 Exons 10
rLPL mLPL hLPL bLPL LPL cge PL
’
c&4 cw4AkGCATCTGA G-+TCTTTGudCCGAAGAAA A TGAAGTAAA!TTTATTT AAkAA AATAkC TTGTTT CAAGA GAAGAAA GCATCCOAGTTCTTTGUGCAGUGUAACAMGTAAATTTAATTT AAAAMATAATACCC TTGTTT CAGAACAMG9ACGGCATOT~TTCT~~~T~~~~~MCTTTTAC AAAA CATACCCAGTGTTT CGGAAGAAAGUCAGCATATWTTCTATWAGAATG AAGTAACTTTTAC MM GATGCCCAGTGCTTT CAGAAAW~TTAGTACTWGCTCTGTGAAOAACA AAATWTTTTAC AAAA GATGTTCAGTGCTTT AAAGAAAATTCTGCACACGAGTCTGCT~~AAG ACACT-GG4GGATGGTCTGTTCA
rLPL mLPL hLPL bLPL LPL cge PL
GGG TGTTTkAA GTGGA + TTTCCTGA G+ ATTAATCCCkCTATA TC + TGTTAGTTdAT GGG TGTTTCiUA GTGGGTTTTCCTOAGTATTMTcCCAf3ZTCTA TCTTGTTAGTTAAAC CGGGTGTTTCAAAAGTGGATTTTCCTGAATATTAATCCCATTCA ACi4 TGOT Ci4AATGTGWTTTTCCGGAGTATTAACCCCA~TCTAGCCTTATTAGTTATTT Go0 TGCTTAAAA GTWTTTTCCTWGTATTAATCCCAQZTATCTCCT~TTAGTTC.UC TCCCTGT G9ACTOGATGTTCA09ACCAAATATATATA~TATC
AGAAG4 L GTGTCAAA + ATTAAAA CK&TMCAC~ AOlUIOACAGTCTWAATATTAAACOOTOGCTAACCCCA
rLPL rnLPL hLPL bLPL LPL cge PL
CCTAAT G&G ATAGCA+GTCCTCCA~TCAG4AG9’CAGCAGAGA~GAAGCATCTCTTAT~T~TT~~-TCAT+ ACGTGPI G& GGGTGAGGM TCTAATOOCCC ATAWAaTTCTTCCAGCATCAGU~ CATCAGGCAGGWAAACATOGTCTTGTATCCCTTAAGAAG~XATCATT ATTTATGOGG TATAGTGGCCAAATAGCACATCCTccAAcGrT~~ CAGTGGATCAT WAAAGTOCTGTTTTG TCCTTTGAGAAAWAATAAT ATTTGAGGTG TATAGTGXCAAA TAOCACATCTTCCMCATTAAAAAAA TAACAGAT AT WAAAGCACTGCATTCTGTCTTTT WAAAAATATGAGT AT TAAGGCC TCTAGTGGGTA ACTCCA ATCCTC AGCATTA AA09 TGGTA ATCG CS,AGC CCGTGTT TGTCT TTOAGOGACAAA A TTGTAAGGAAGTCTCAGACAAAAGTTACTAACCATAATTA CATTATCTGATAGTTAAGAACAAAW,AACCcCT(3ZAACAACTTccGAAAG
rLPL mLPL hLPL bLPL LPL cge PL
TGTTCCCAA JXATA CAAGACTCC!TCATGTGA &A TTTGGTdTGGTCT d TTAGTAAGGkCTCTTATT~TCATTAGAT A TCTGAGG TGTTCCCAACAATA TAAGACTCC4TCATGTGACTTTGGTcAT~CTAAAATTAGTAAGAAC TCTC%GG TGTTT04GCOCAOAGTAAMTAAGGCTCCTTCATGTGGCGTCTT TATTTAAAATGATAAAATAATCAGATCTCTTCATGTAGTAT TTTTAATTGGGATTCTQXT TGTKCCA TAGTAATATCC GCTTGAGTGTTAGGAAOTAATAAGTAATTTT~TTAATC~~~TT~~~~TTCTT~T~~T~TCTTTA~~TTT~A~ATTTATT
rLPL rnLPL hLPL bLPL CLPL
GACCTTCTkAAGTTCTC + TGAAGTCT TT AAATTd MTATAkAACAACA T + TTTTTGTGC!GTWTCAdTCCATTTCT + TAGCAGT TT ATATTGA G4CCTTTTCAMGTTTTCTCGTCT AATATAGACAATA TTTTTTGTGGCATGAGTCAGGTCCATTTCTTTAOCGGT CTTTTCCGCGGCA CCAATCAGACTCATCTACACQZAGTATG TC GOACTGPI GGCCTTCTCAAACTTTACTCTAAGTCTCCAAGAATACAGAAATG TCTAG4CTG4TAACCTTCTCAGAGTTTTCTCCG4GTCT AAATATAOOAAGTAAGTTTTTTT@XXGTCi4GTAGGKccGTTTAccTATcAATCAA GAAAAGATGCAAAGCTCTOTACCTMjTCCTCTTTTTAGTGTTTTT
rLPL mLPL hLPL bLPL CLPL
190 192 193 177 161 195
AGGAGACAGTCTCAMTACTAAAA CTAATTCA G~GS~GVITCTCAAATACTAAAAAGTGACTMTTCA TTC
’
’
T
T+ TT TT
267 269 260 274 264 294
360 363 366 372 263 394
T& TG
470 452 464 466 494
C!TTTACCAT d GG4TATA&CCCTACCA~TAAAATA AAACAGCTGkCCA TTGTAkTAGTT J TAAATAAAG&CAGUjA~T~GACTT AAACACCTGGCCT TTWAACTAGTTTTTTTTTACCATT~TATATTCCCCCCA CCAAAAAAAAAAAAAAAAAAAAGTAACCAGGAACGTGTGACTTG TGATGTTTTAGAATGA TTCCCTCTTGCTATTGCAATGTCXTCCA~cGTC4 ACCAGGAACATGTAACTTG 2 TCCCTACTTTCTTGGAATTACTCTCCTCTTGGAA ACCAGGAACTAGTGACTTG TGTTGTTCTCCTGGCCTTGACTGAATTTTCAGGCAC;TTTCTCAT
+
567 551 556 545 594
rLPL mLPL hLPL bLPL CLPL
GfJ TTCCTGA &TT @XAAGCA~TGWGA~GGCTCGT Ac&WCAdC CWTACkTCAGTA d GGTACAAAA k TAG4 GCAAAAGCAGTTGAAG4CATGOCTCATGAAGTCCTGACCCTT GGTCCCACCACAAC AAAGTACAAGTC’MCAGAGTACAAMCCTAGA GAGAGGGACGAAGAAAG CTGATAAA CACAGAGGTTTTAAACAGTCCC TACCATTGGCCTGCATCATGC+IAAGTTACAAATTcAAGSAGATA GAG4TAGAAATG4AGAATAGAGTTGATAAAGCACTGAAccTTTAAAC CCCCTCTACGGTTGGT TGCATCATAACTAAGTTACCAATTAAAGGAGATA GGAAAAAAATACCCTTGTGTGTA04GCTATAACAGAGATGTTTAC
’
rLPL mLPL hLPL bLPL CLPL
CT &I G T A ATTCTTAGTTIGACTTCAA GTTTTATOOC + TAATTCCTC!GTCTTTT AAAAACGT $A: ?:::;:;;;:A CTGAG TAATTCTTAATAGACTTGAA TTTTTATGXTTMTCCTTCTATCTTTTAAATATTT TA AMTCT AGATCAATTAATTCTTAATA~TTTATCGTTT ATTGCTTMTCCCTCTCTCCCCCTTCTTTTTT GTCTCAAMTTATATTATAATA TATAMGTTGWATCAATTAMTCT TTAACAGTTT ATGGTTTAGTATTTCCCCTTCCTTTTCCT~TTTGTCTCAAGATTATATTTTAATA TmGTAGAT-ATOCTTCTTA TATAATCTGTTMGATATGTAATCCTATGCACCTTAT ~AGCAATAGC~~G~~~SU~
rLPL mLPL hLPL bLPL
TTATTCTC + AGACAGAT G-+TGAAA T&TTGTGA TTGTTCTCTOGATAGATGT ATGTTCTCTWGTAGGTGT GTTTTTCCCTAGATAGGCTTTTWACTGTTA
I
I
I
I
I
I
656 640 651 642 694
733 717 746 741 707
I
TGGZAATGGTGGCOCTCACCTTTMTcccA@ZACTTGGZAG3XGAG%AGWGGATTTC
766 616 762 778
rLPL mLPL hLPL bLPL
916
rLPL mLPL hLPL bLPL
1016
rLPL mLPL hLPL bLPL
rLPL rnLPL hLPL bLPL
I
I
I
I
AAGAAA~MGAMGAAAGAAAGAAAGAAA~M~A~AA~~-~AA~A
I
T +
Insertion G&c TGGCTGA!TTTATTTCTATGTTTGCT GAGCTCiKi&AATAAT + TCTTGAGAAAAGGAATACT TTGCTG4AAGACAAAMTOTAGGTTGATTTTTACTTCTCTTTTTT~TTTCTT~A~~~TT~~T~T~~~A~CT~TA~ GTGCAGUAAAAAAAA ACAGAGGWAAAAMT
d
’
T GGTGACATA TGAAT! TGAGGTGACACA TAAATT CCTCAGCTGACACATAATTTGAATG TCATCAGCTGATACAGAATTTTAACT
+ GTCCCACT &ATcTGA&TwzcAAJ
rLPL mLPL hLPL bLPL
ACTAAACTA + GTACTTCAGbCTTACCTTdACTCTCAA ACTAAACTATGTATTTCAGGCTGGCCTTGAACTCTCAACCTTT
rLPL mLPL hLPL bLPL
TAGAACA&TTCAAT TTCTTAGT d TTTTCACCAd GCC~ATCGTTAG&TTT~TT~GKTCATC!TG~CCO l&T TTCTTACTTGTTTTCATCAATTTGAAAT GCCCAATATCCAATACTTTGTATTTCATTTG~GACTCATCT~CGCCATGC~TCTGTCACACTT~~~~~~A T CCAMTGATTTTCATCAATTTAAAATCATTCAATATCTU\G T CACAATTACATTCA TTGAAGTCCTTTAATGT GATAGTTACTGTTCA TTTTAWCTTATTTCAQXATGCTTcAGTcAG4CTTTOAGATG
Fig. 3 (continued
c&A TCCTGCCT!GGCTTCCTdGT~TG&CTT~TMc&ATAATTTTA OATA G4TA
on
p.
707 1109 606 604
+ TATCAGATT
867 1209 824 620
+
967 1309 650 646
1
1066 1406 949 937
CCGTAATTTTATTATTAGATTC CTGTAATTTTATTATCAGACTT
245)
kidney androgen-regulated protein-encoding gene and 88 % with human cytochrome P450 IIEl-encoding gene. Another interesting feature of the rat sequence that was not pointed out by Zechner et al. (1991) in mouse, but again
clearly appears upon alignment of the three sequences, is a deletion of 8 1 nt (rat)/7 1 nt (mouse) relative to man. This rat deletion corresponds to a fragment spanning 15911671 in human (Fig. 3).
245
’
rLPL mLPL hLPL bLPL
ad TTTTTTTTTC ICAAGTTTTA!WCAGG~ T>TCWT~cTGCAcT G&MAGT TCACATTAA + TTCTAGTTT 1 GMGTOA AWGTTTTA~XAGGACCATTTTTTTTT TCAAGTTCUATTCTGCACTGT-GT TCACATTAATTTCTAGTTTAaTGTGA TCTCTTTTOTTCCTCrCTTTGAU\TOAAAAGATAGGTTTGTTTT TCTCTTTC TCCCTAACTTTGATA GAAA CACGTATTCAC09GTA CTTTGCATCAT-GTCCTACAAATTTTAGWAAA~TTGTTTTT
1173 1493 1044 1027
rLPL mLPL hLPL bLPL
ACCACGTAG TCG+d TTACTAG&AATGTGTA+AT C&A TGCTTGTk.4CTGTT&-GTGkiWCCTTC+ATTGTGATA~ GM TGCTTGTAAACTOCT GT-GMAAGWXCTCAACTGTAAT~~ ATCACATWG TTGAAA TTACTAGAAAATGTOCATAT GCAGTGCTTGTAAACCATCGCGTGCAATO ACTAAGTUAA~OOAGAGOTTCCTOGGG T(XjPTTCCTAA ACTAAGTAAAGWACA~AAAGTTACAGTCA GTCATATAGTCACTOCCAGTGCTTA AAACCGTTGTG64CXATGGGATcAATT~TATATCCA
1262 1560 1117 1124
rLPL mLPL hLPi_ bLPL
CCATAOACA &r ACCAGGCT CTATAGUAGTACCAGGATTGTTGCcGCTGTTTTGTTTTAcCTT~AA.4AcAAGWAAAAATCMTAATGAACiUT ~~TGGI\GTACCATGA~T~TATTT~T~~~~~ AACAAC ATTGTCATWGTTG
rLPL k? bLPL
CJA TATAAAAT&TAAAAAAdAAAATAAAA CAAGPITCT d TATGTT CA&TTGCTTTTkTATTCAT CGAGPlTCTCACATTTT CAGATTGCTTTTATTATTCATTAATGTAAAAAAATAAAO CTAOATCTCCTATTTTTGWAATGCTCTT CTACGTATAAATATWTGTUG CTAWTCTCATATTTT CAGUTGCTTTT CTATATATTATTATCAAATGTAGAG
rLPL mLPL hLPL bLPL
+ GAACAC ~TACACA ~-~cAAGAGc+TT~~TTC~ATGTCAAA AACAGAAAC 1,GTGUA TGk-TGWTATC CAACCCA CAT~CCCCACAAGTGTAGTCGTCATTCAATGTAA AGCAGAAACTFTGAAA TTTGTGGGTATCTGUCAC AACCCGA CTGTGAAAGTATGTG ATATCTWC4CATACTAGCZTCTGCATGTGTGTTG CA CGTATGAAECCMCATACACG9TTATTGCTCAGCATGGAAA AATCCAAACTGT04ATGTGTGTGGGTGTCTGpJ\CACATATT
rLPL mLPL hLPL bLPL
CSGTCAAGA L TATAC’XT kI TATGTCAG’ GKEAAGCGPTATACTGTATGTTAG TCAAWGATGTATTGGAACATGT~GTA~ TGATTAAGAOGTACATTAGAACACACTGA
rLPL mLPL hLPL bLPL
ATAGGA c+d AGTGKT ATAGG4GUAGOT~CCWTTTCATCA GTAKWXAATGTTGTGATTAA~T~T~~TTGGAAT GTAGAATGAATGCTGTGATTGKATGVXCA~TTGMATC+IATTCTCTCT
rLPL mLPL hLPL
ATTCA T G&I GTATATA C& ATTCA TTACAGTATATACACATCCACATGCA ATTAAATTTCTOGATTTOOGTTGTGACCCAGGGTGCATTAT
rLPL mLPL hLPL
TACATATC + CAATGATGC + TTGACTTTA & TTTTATTT TTAGCTGT TACATATGTWT~TGCTTTAOCTTTTCAATTT ATTTATTAGCTGTAAATA TTATATATATCAAGG9TGTTCTGGCTTTTA~TTTTTACATT
rLPL mLPL hLPL
G+ GTCCACCT ~ATCAGTGAT+GTCT GTGGCTATCkGGG TGTA&TTTGTGGTbCTAACTCT GTGGTTATCTGCAG TATAGATTTGTGGTCCTAACTTTGTGTCCGTCTCCATCCAGTA GTGETATCTGCATTTATAAAAATGTFTajTOCTAACTGTATGr GTCTTTATCAGTGATGGTCT
rLPL mLPL hLPL
~GGAAG4AAATAAAC+C~T~~~-T~TCT~TTT CAATOGAAT GCTTTT MAA~AGUAACTCACCTGTGTGAAGUATWTATCTGCTTT CAATCSAATAGGCTTTT ATCSAATGGGCTTTAACAAAACAAG#,AWAAcGTACTTAACTGTGTC&WAAATCXUTcA~TTT
rLPL mLPL
CGCG TAAC
bT~&TTmTTTAcTATd
window
TATTTATOA TATTTATGAA TAATCAA~GTG4GTMACAACTATTTATAAA TAGTCAAG4GTG4GTGUCATTTATTTATAAA
1194 1166
1431 1752 1279 1272
TATCTCAGA Gd TGTTGCTGd &AA GTTC AAGATC TATCTCAGA%CTATAGCTGGG ATGTCAAATATCTCAG4GATAGCTGGG AAGTCAAATATTTCAG4GATTACTGAA
’
’
’
’
’
Deletion
’
1525 1646 1374 1367
1621 1942 1470 1463
GATGTA c&A TATGTCA TATGTATMTTTGTTAC G4TGTAT~TTTGTTGTTGTCUXTTTATTAATTC GTTGTGTGKTTGTaaaaaaaaa
1712 2034 1570 1539
’
’
KGAAAAACTTTG
1731 2063 1670
,&TA ATaOC-mdmA mTTdt,t,AwCT&mTGd 1620 ATGTGTGOGTATGTMWT GCTTGTAAACACT-GTCTGTT 2159 1770
&TGAGCCAA&TC
ACTCTdTCi4A
CACAGAGCCAACTC
ACTCTT
CAGC
A 2256 1921 1652
TC&.WACGTTT~ATCAT CTGKSACATTTTATCATGATAC TTGKAACATTTTATTACCaa
L
2015 2349 1946 2019 2353
of exon-10 in six species. The polyadenylation
signals are boxed. GenBank/EMBL
and that of the five other species was made using NUCALN manually
A 1334 1669
I
TGAACiUT’
'
size = 20; gap penalty = 7. Aligned
was optimized
L
TkTTCC4GAT~TOCTGTkCTACXXcTTkCTAGG4G&TTGGTTGTk!CTATGTAA+ TAGTTCCAGPITATCCTKiMTGTTAGCCCTTCCTAGOI\ATGTAAT TTGTTCCTG4TGTGCXXGCTTCG4cCCTTTCTCTG4Ci4GKNTGkTCGECCTATAAATA ACTCCTTCATCTGAGAGATACGGTTGRXCTGTACAAA GTACiUAATGGTTCCAGT@ZTjTGCCGGI\AC
A
A
T
ACi4AG AWAG
’
Fig. 3. The nt sequence the rat sequence
’
for a minimum
sequences
were transferred
rate of divergence,
respecting
(Wilbur and Lipman,
into a WingZ
spreadsheet
the choice order: transitions>
We have also sequenced another independent 2.5kb clone, that was shorter than the 3.18-kb clone at the 5’ end but identical to it at its 3’ end. It provided confirmation of the 157-bp insertion and of the 8 1-bp deletion and was also devoid of the mouse Bl element and of the homopurine stretch insert. The consequences of the presence of these inserts and deletions in the untranslated region of mRNA remain to be elucidated. (d) Particular features of rat cDNA LPL exon 10 (I) Polyadenylation signals Mouse and human LPL cDNA have two polyadenylation signals. It is likely that only one of these is functional in rat, since a single LPL mRNA species (3.6 kb) was isolated from different rat tissues (Kirchgessner et al., 1987; Semenkovich et al., 1989). However, eight AATAAA se-
accession
No. L03294.
Alignment
1983) with the following parameters: (Informix,
USA) and alignment
between
K-tuple size = 3;
of the six sequences
transversions>gaps.
quences (four of which overlap) can be found (Fig. 3). These A+T-rich sequences might be involved in mRNA stability. (2) Richness in A+T exclusive sequences Our attention focused on elements rich in A+T, such as: 22-nt: TAAATTTTATTTAAAAAAAATA (64-85); 1 lnt: AAATATTAAAA (167- 177); 20-nt: AAATAAAATAAATAAATAAA (526-545); 9-nt: ATTTTATTT (816824); 13-nt: ATAATTTTATTAT (968-980); 12-nt: ATTTTTTTTTTA (1163-l 174); 14-nt: TATAAAAAAATAAT (1304-1317); lo-nt: AATTATTTAT (1322-1331); 30-nt: AATATAAAAT(G)TTAAAAAAAAAAAATAAAA (1373-1402); 18-nt: TTTAAATTTTATTTATTA (1756-1773). The role of these A+T-rich motifs is presently unknown. It was suggested that A+T-rich motifs such as ATTTA could play some part in the instability of mRNAs (Caput et al., 1986; Shaw et al., 1986; Wilson and Treisman, 1988;
246 Brawerman 1989) or else could be repressive elements decreasing translation efficiency (Kruys et al., 1987; 1989; Han et al., 1990). They presumably play a role in the secondary or tertiary structure of RNA and might be involved, whether directly or indirectly, in the recognition of mRNA by specific degradation endonucleases. It must be pointed out that the consensus sequence AATAAATAAATAAA,
which has been described
(Reeves
and Magnuson, 1990) in the 3’-untranslated region of a variety of genes involved in cellular stimulation (lymphokines, cytokines and proto-oncogenes), is also found in rat (nt 1692-1705). The half-life of LPL mRNA in different species is poorly documented. In view of the present results, it would be interesting to study the stability of all these mRNA and to investigate
the role of their A+T-rich
Han, J., Brown, T. and Beutler, B.: Endotoxin-responsive trol cachectin/tumor necrosis factor biosynthesis level.: J. Exp. Med. 171 (1990) 465-475. Kalb, V.F., Glasser, tive elements
S., King, D. and Lingrel, J.B.: A cluster of repeti-
within a 700 base pair region in the mouse gcnome.
Nucleic Acids Res. 11 (1983) 2177-2184. Kirchgessner,
T.G.,
sequence
Svenson,
of cDNA
K.L., Lusis, A.J. and Schotz,
encoding
lipoprotein
M.C.: The
lipase. J. Biol. Chem.
262
C., Etienne, J., Guilhot,
S.,
(1987) 8463-8466. Kirchgessncr,
T.G., Chuat, J.C., Heinzmann,
Svenson,
K., Ameis, D., Pilon, C., D’Auriol,
M.C., Galibert,
L., Andalibi,
F. and Lusis, A.: Organization
A., Schotz,
of the human
lipo-
protein lipase gene and evolution of the lipase gene family. Proc. Natl. Acad.
Sci. USA 86 (1989) 9647-9651.
Kruys, V., Wathelet,
M., Poupart,
P., Contreras,
J. and Huez, G.: The 3’ untranslated beta mRNA has an inhibitory
R., Fiers, W., Content,
region of the human interferon-
effect on translation.
Proc. Natl. Acad.
Sci. USA 84 (1987) 6030. Kruys, V., Marinx,
sequences.
sequence con-
at the translational
lational
O., Shaw, G., Deschamps,
blockade
imposed
J. and Huez, G.: Trans-
by cytokines-derived
UA-rich
sequcnccs.
Science 245 (1989) 852-855. Miyamoto,
ACKNOWLEDGEMENTS
M.M.,
Slightom,
tions of humans
We thank Dr. Michel Bouillot (Genset) for his stimulating participation in the construction of the synthetic probe. This work was supported by grants from Institut National de la Sante et de la Recherche Mtdicale (grant 900 203 to J.E.) and from the Centre National de la Recherche Scientifique through UPR41. We thank Beatrice Pelletier for typing the manuscript.
globin region. Olivecrona,
J.L. and Goodman,
and African
rela-
in the $n-
Science 238 (1987) 369-373.
T. and Bcngtsson-Olivecrona,
milk-the model enzyme in lipoprotein J. (Ed.),
M.: Phylogenetic
apes from DNA sequences
Lipoprotein
Lipase.
G.: Lipoprotein lipasc research.
Evener
lipase from
In: Borensztajn,
Publishers,
Chicago,
1987,
pp. 15-28. Quentin,
Y.: Succcssivc
history. Reeves,
waves of fixation of B 1 variants
R. and Magnuson,
pression
in rodent lineage
J. Mol. Erol. 28 (1989) 299-305. N.S.:
of mammalian
Mechanisms
cytokine
regulating
transient
genes and cellular oncogenes.
exProg.
Nucleic Acid. Res. Mol. Biol. 38 (1990) 241-282. Sanger, F., Nicklen,
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Caput, D., Beutler, B., Hartog, R., Thayer, Cerami, A.: Identification of a common 3’-untranslated mediators.
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Deeb, S.S. and Peng, R.: Structure of the human lipoprotein Biochemistry 28 (1989) 4131-4135.
lipase gene.
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lipase and hepatic lipase mRNA tissue specific
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J. Lipid Res. 30
(1989) 423-43 I. Senda, M., Oka, K., Brown, lipase. Proc. Natl. Acad. Shaw, G. and Kamen,
W.V., Qasba,
P.K. and Furuichi,
Y.: Mo-
radation.
lipase of guinea
AU sequence
mRNA mediates
from the 3’ un-
selective mRNA deg-
Cell 46 (1986) 659-667.
Wilbur, W.J. and Lipman,
D.J.: Rapid similarity
and protein data banks. 730. Wilson, T. and Treisman, radation
Sci. USA 84 (1987) 4369-4373.
R.: A conserved
region of GM-CSF
of
Proc. Natl. Acad. R.: Removal
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of poly(A) and consequent
c-fosmRNA facilitated by 3’ AU-rich sequcnccs.
dcgNature
336 (1988) 396-399. Wion, K.L.,
Kirchgessner,
R.M.: Human
Enerback, S., Semb, H., Bengtsson-Olivecrona, G., Carlsson, P., Hermansson, M.L., Olivecrona, T. and Bjursell, G.: Molecular cloning and sequence analysis of cDNA encoding pig. Gene 58 (1987) l-12.
with chain-
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5467. Semenkovich,
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Cooper, D.A., Stein, J.C., Strielemen, P.J. and Bensadoun, adipose lipoprotein lipase cDNA sequence and reciprocal
A.R.: DNA sequencing
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Cathala, G., Savouret, J.F., Mendez, B., West, B.L., Karin, M., Martial, J.A. and Baxter, J.D.: A method for isolation of intact translationally active ribonucleic
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ence 235 (1987) 1638-1641. Yang,
C.Y., Gu, Z.W.,
Pownall,
H.J.:
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Etienne, J. and Brault, D.: Les deficits en lipoproteine Clin. 50 (1992) 299-309.
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Zechner, R., Newman, T.C., Steiner, E. and Breslow, J.L.: The structure of the mouse lipoprotein lipase gene: a B 1 repetitive element is inserted into the 3’ untranslated 62-76.
region of the mRNA.
Genomics
11 (1991)
GENE
B.V. All rights reserved.
237
0378-l 119/92/$05.00
06764
Sequence of rat lipoprotein (Mouse;
human;
bovine;
lipase-encoding
guinea pig; chicken;
PCR; untranslated
cDNA exon; A+T-rich
sequences;
CpG islands)
Didier Brault a, Lydie No& a, Jacqueline Etienne a, Jocelyne Hamelin b, Alain Raisonnier ‘, Aziz Souli a, Jean-Claude Chuat b, Isabelle Dugail d, Annie Quignard-Boulangi: d, Marcelle Lavau d and Francis Galibert a uLaboratoire de Biochimie et Biologic Molkulaire, Fact& de M&decine St-Antoine, 75012 Paris, France: b C.N.R.S. UPR 41, Centre Hayem, H6pital St-Louis, 75010 Paris. France. Tel. (33-l/42 02 1605; ’ Biochimie. CHU Piti&Salp&i&e, 75013 Paris, France. Tel. (33-l/40 779805; ’ INSERUM France. Tel. (33-l/4633 Received
U I 17. 75006 Paris,
7105
by G. Bernardi:
5 May 1992; Revised/Accepted:
9 July/l2
July 1992; Received
at publishers:
30 July 1992
SUMMARY
A rat lipoprotein lipase (LPL)-encoding cDNA (LPL) has been entirely sequenced and compared to the sequences of all the LPL cDNAs reported in other species. As expected, high homology was found between the coding exons. The putative catalytic triad, Ser’32, Aspire, His24’, according to human numbering, is conserved in rat. As is the case in mouse, an Asn444 present in human LPL is also missing. The major divergences between human, mouse and rat LPLs were observed in the untranslated exon 10, where (i) the rat cDNA exhibits a 157-bp insertion and an 81-bp deletion relative to human; (ii) neither the B 1 repeat nor the homopurine stretch reported in mouse can be recognized, and (iii) the rat cDNA displays several A+T-rich stretches.
INTRODUCTION
Lipoprotein lipase (LPL) is a key enzyme of lipoprotein metabolism that hydrolyzes the triglyceride moiety of chylomicrons and VLDL. It is involved in various pathologies, such as hyperlipemia, atherosclerosis and obesity. For studies on lipoproteins and LPL, rat is one of the most useful laboratory animals. Since it is resistant to this affection, rat is also a model for atherosclerosis research. Moreover, the genetical nature of its obesity makes the
Correspondence to: Dr. J. Etienne, Biochimie, Mtdecine
St-Antoine,
Tel. (33-1)40306249; Abbreviations:
27 rue Chaligny,
aa, amino acid(s); bp, base pair(s); DlT,
dithiothreitol;
or 1000 bp; h (prefix), human;
lipase; LPL, gene encoding
godeoxyribonucleotide;
507, Faculte de
Fax (33-1)40307840.
(prefix), guinea pig; kb, kilobase lipoprotein
Laboratory
75012 Paris, France.
PCR, polymerase
LPL; nt, nucleotide(s); chain reaction;
cytoplasmic RNA required for both structural of signal recognition protein.
oligo, oli-
7 SLRNA,
and functional
gp LPL, small
properties
Zucker rat a valuable model for research in this field. Lastly, cell lines derived from rat tissues lend themselves to studies of LPL gene expression. However, whereas in recent years the sequencing of LPL has been carried out, via cDNA, in five species, human (Wion et al., 1987), bovine (Senda et al., 1987) mouse (Kirchgessner et al., 1987; Semenkovich et al., 1989; Zechner et al., 1991), guinea pig (Enerback et al., 1987) and chicken (Cooper et al., 1989), it has not yet been determined in rat. The aim of this work was to clone and to sequence rat LPL cDNA as a preliminary to metabolic studies on LPL mRNA. Furthermore, it is meant as a contribution to the comparative study of LPL cDNA in different species, with a view to pointing out which aa have been conserved during evolution and are thus likely to belong to domains playing a major role in LPL activity. Four rat cDNA LPL clones were isolated. The longest, a 3.18-kb clone, lacked about 0.20 kb at the 5’ extremity with regard to the mRNA. The missing 5’ fragment was obtained by PCR. The cDNA sequence was compared to
238 of all the LPL cDNAs
the sequences
reported
in other
species. The divergences appearing between rat, mouse and human in the untranslated exon-10 are pointed out.
RESULTS
(b) Comparison of coding exons of rat LPL cDNA with LPL cDNAs from other species
AND DISCUSSION
(a) Nucleotide sequence of the rat cDNA The strategy used for sequencing the clone isolated from a rat cDNA library, as well as the 0.5-kb 5’ fragment obtained by PCR is shown in Fig. 1 and Table I. The clone comprises a total of 3.18 kb. It lacks the first 183 5’ nt coding
region has thus been achieved by sequencing the OS-kb 5’ fragment obtained by PCR. Nucleotide and aa sequences of rat, mouse, human, bovine, guinea pig and chicken have been aligned (Fig. 2).
for mature
LPL. The sequence
1) Clone RP . _. . . . . .) 5
’ 267
of this
(1) High homology
High homology is found between the coding exons of rat and human cDNA LPL, as well as with the other published An exception concerns guinea pig exon 1, which cannot be aligned with exons 1 of other species.
LPL cDNAs.
w19 El3 \“,, __________+ El . _.--. -. ) W5 -------w ..W!.3... w ______* ______+ w21 w9 Wll ______* ______+ WlS ___Y! ________) ____-_____) .--. w3_.._ t 3444 )
Wl ._..._. _)
OAC
3’
3’ 4-&---
2 ) 0.5 kb 5’ fragment
W4
WlO
4_.__.._.__ w2
I
s
RP
W16
w20
, W26
a)
RP ._.._.. __* b)
)
4 Fig. 1. Strategy
(Clontech
for sequencing
Laboratories,
.___._.._ UP
rat LPL cDNA.
The cDNA
Palo Alto, CA). It was screened
library used was prepared
from 4-week-old
with a 150-mer probe synthesized
the last 14 nt of exon-7 and to the 135 first nt of exon-8 of human the Ml3 vector). Four clones were isolated and subcloned
cDNA
LPL (plus
Sprague-Dawley
by the phosphoramidite
rat testicular
method.
1nt added to create a 5’ BumHI restriction
in the EcoRI site of pUC 18. The OS-kb 5’ fragment
was prepared
I
fat cells in lgtl
This probe corresponds
to
site for cloning into
by PCR. Briefly, total RNA
was isolated from rat frozen adipose tissue using the guanidium isothiocyanate/LiCI method as described by Cathala et al. (1983). Total RNA (6 pg) was heated at 65°C for 10 min before priming for cDNA synthesis with 125 ng random hexamer oligos (Pharmacia, Piscataway, NJ) in a 50 ~1 reaction containing
1 x reverse transcriptase
1 mM each dATP,
dGTP,
stopped by incubating This cDNA
dCTP
buffer (50 mM Tris.HCI and dTTP,
pH 8.3/75 mM KCljlO mM DTT/3 mM MgCl,),
and 200 units M-MLV
at 70°C for 10 min. The resulting cDNA
was used as a template
reverse transcriptase
was purified and concentrated
for PCR with (i) an upstream
primer (Table I: PCRl)
20 units RNasin
(BRL). The reaction on a Centricon consisting
(Promega,
was performed
Madison,
WI),
at 37°C for 60 min and
30 column (Amicon
of the first 20 nt transcribed
Corp., Danvers,
MA).
in mouse according
to Zechner et al. (1991). This was attempted in view of the high putative sequence similitude in rat and mouse; (ii) a rat LPL specific downstream primer (Table I: PCR2) complementary to rat nt 382 to 361 (Fig. 2) (plus EcoRI and Hind111 recognition sites). For PCR, samples were denaturated at 94°C (5 min), annealed at 52°C (2 min) and extended at 72°C (2 min)followed by 30cycles of 94”C(l min), 52°C (1 min) and 72°C (2 min) with a final extension of 10 min. The PCR product phosphorylation ing was carried
of approx.
580 bp was excised
and eluted from a 2% Nusieve
LMP
agarose
gel. This fragment
was subcloned
after
into M13mp89 cut by EcoRV and sequenced. The 0.5-kb fragment was inserted in the two possible orientations (a) and (b). Sequencout by the dideoxy method of Sanger et al. (1977), using [C(-35S]dATP, T7 DNA polymerase and the specific probes.
239 TABLE
I
Synthetic
oligos for PCR and for sequencing
the cat LPf. cDNA
(A) Oligos used for PCR PCR 1 = 5 ’ -TGTCAGACTCTCGATTTCTC
PCRZ = 5’-TATAGCCGGCAGACACTGGATA
382-361
(B) Oligos used for sequencing” (1) The 3.18kb
clone UP = TGTAAAACGGCCAGT
RP = AACAGCTT’AGACCATG
= ATGTCCAC~C~AGGGTAC
435-474
W2 = AATCACTGATGGAGGTGGAC
1887-1868
W3 = CGTGTAATTGCAGAGAAGGG
748-767
W4 = AGCCTAATGAAACCAGTCAC
1652-1633
WI
W5 = CGCTCTCAGATGCCCTACAA
997-1016
W6 = TTTCTGTTCCCAGCAACAG
1439-1421
W7 = GGTCAGACTGGTGGAGCAGT
1250-1269
W8 = GCTCCTCACTTTGCACGCAA
1247-1228
El3 = GGACGCTGCAGTGTTTGTGA
1371-1390
WlO = GCCAAGGCAGGATGGTTGAGA
940-920
W9 = GCAGAGAGGAGAAGCATGCC
240-259
W 12 = TGACTTGTACTTCGT-TGTGG
636-617
EI
385-366
= GGGCCT~TA~TCA~AG
349-368
W 14 = ~AAAACCTCAGAGATCTA
W Ii = AAGCAATGGACGACGTGGCT
572-591
W16 = ACT~CAAGATATAGCTGGG
W 13 = TCAGGCTTACCTTGAACTCT
903-922
W 18 = TCCCTGGCACAGAAGATGAC
1343-1324 1100-1081
148-129
W152 = GTACAAGTI-TTAGAGCAGGA
1141-1160
W20 = TACAGAGAAATCTCGAAGGC
W 17 = GCTCGTTGCCGCTCTTTTGT
1279-1298
W22 = TGTATGCCTTGCTGGGGTI’T
868-849
W 19 = CAGAAAGGAAAGAGTCAAGA
1515-1534
W24 = ACATCTACGAAATCCGCATC
624-604
W21=
1773-1792
W26 = TCAll-l-CCCACCAGCTTGGT
401-382
AGCTGTAAATAATGTGTGGG
(2) The 0.3-kb 5’ fragment RP = AACAGCTTAGACCATG
UP = TGTAAAACGGCCAGT
S( = PCRI) = TGTCAGACTCTCGATTTCTC
0 = CTGCTGTGGTTGAAGTGGCA
it The sequence Numbe~ng
of all the probes is given in the 5’ to 3’ direction.
is as in Fig. 2 (coding
sequence)
The left column corresponds
Divergences between the rat sequence and the five other sequences, from the first ATG to the stop codon (1428 nt), are shown in Table II. The ratio of transitions to transver-
TABLE
II
Divergence
between
six LPL cDNA
sequences
(1428 nt from the first
ATG 5’ nt, except for bovine, to the stop codon) Rat vs.:
Mouse
Human
Bovine
Guinea
Chicken
pig Identities Transitions
(I)
Transversions I/V Insertions
(V)
(i)
1358
1242
1151
1163
59
123
136
148
193
114
209 0.923
18 3.277
60 2.050
75 1.813
1023
1.298
0
1
1
1
1
1425
1426
1363
1426
1426
Informative positions” % Divergence’
5.40
12.90
15.55
28.26
18.44
’ For determining the number of positions, each gap was counted as one position, regardless of insertion length, as these gaps are no targets for substitution. Consequently, the insertion of an Asn codon at the end of the protein is counted for one position only rather than three, since obviously the two other positions stitution. b The percentage (1987) equation:
of divergence
to the sense sequence,
and Fig. 3 (exon 10). RP, reverse primer; UP, universal
are not informative was calculated
as regards
to nt sub-
by the Miyamoto
P % = (I + V + i) x lOO/Nb of informative
positions.
et al.
218-199 the right column
to the antisense.
primer.
sions decreases as divergence increases. This could be explained by a double substitution occurring at one position. Paradoxically, the percentage of divergence between rat and guinea pig is greater than between rat and human or human and bovine. However, results tending to place the guinea pig differently on the mammalian phylogenetic tree have been reported (Graur et al., 1991). The longest segments that present homology among the six species studied up to the present time are the end of exon 2 and the beginning of exon 3, This homology has not been previously pointed out. These regions comprisent 42-87, with only three nonconserved aa out of 46; even position 45, which has Thr in chicken, rather than Ser in the five mammals, is functional, since it belongs to the potential ~-glycosylation site, which accepts Ser or Thr (see section bl). Also conserved is the well-known nt 170-217 region (exon 5), with five nonconserved aa out of 48, or else region 234-264 (exon 6) with three nonconserved aa out of 31. But region 287-320, which Semenkovich et al. (1989) indicated as being well conserved at a time when the chicken sequence was not published appears to be less so (seven nonconserved aa out of 34). The ATG in position 1 for the five mammals, or positions 1 and 19 for chicken, which has two alternative start codons (Fig. 2) codes for the N-terminal Met of the hydrophobic signal sequence. The
240 Open Reading Frame
/
rLPt. mLPL hLPL
-174 T&TCT + GTAOCTGTTATGCCCT CcrJ TTT~~~~~TT~T~~ TACTCCTCCTCCGWEAATTCTGCGC CCTGTAACTGTTCT0XCTCXXCTlTAAAGGTTGACTT@XCTACG3ZSC TCCTCCTCCTCAAGGG~AAGCTGCCCACTTCTAGCTGZCCTGCJZATCCCCTTTAAAG~X~%CTT~XTC
rLPL mLPL hLPL
GACXXCTCCGGCTCAACCCTTTBXA TOCOCCTCCTGCTCAACC CXAGCCTCCGOCTG4GCC
rLPL mLPL hLPL bl.PL LPL cge PL
rLPL mLPL hLPL bLPL 2z.L rLPL r?tLPL hLPL bLPL c PL TPL
I
I
TrXCGDkXTGACT
CTATAGTCCTCT TCC4ccMi CTCCAGTETCT ACCGCCAAACCOCGGCTCCAGCCGTCT
’ GCCCGf&-GTTC&CA&CA GAA& CGCCGXTAGTTKZAGCAGAKAGAA~~~G CCGCCCCTTGTAGCTCCTC CAGAGGGA~CGAG
EEEEEW
GAG
ACW,TTTC!CAG4CATC&AGTAAATT 4 W.XTAAG&CCCTGAA d CACAGCTGA ki4 CACTTGT&ATCTG4TTC&TU3ATTA&KTCTGTG A~OATTTCTCAU\CATCGAAAGCAAATTTOCCCTAAOGA AG4GATTTTATCGACATCAAGTAAATTTOCCCTAAC AAAW\TTTTAOAG4CATTG4AAGTAAATTTGCTCTCAGGAG G4AC9CAOIT64GG4CACCTGTUICCTCATT~T~~~~~TCT~G AAAC?ATTATACGG4TATCAGTAAATTT‘XCO34AGG4fXCCCG4 ATGAATTTTGACYYjAATCGI\GAGCAAGTTTTCCTTAAGTTG l l e l 0 l l l l l ArgAspPheSerAsp Ile Glu Sar LysP~ AlaL~Arg Thr ProGl~ AspThr Ata~uA~pThrCysHis Lau lle Peony Lau AlaA~S~r ArgAspPheSerAsp Ile Glu Ser Lys Pha Ala LsuArg Thr Pro Glu AspThr Ala Glu AspThrCys His Lau Ile Pro Gly Leu Ala AspSer ArgAspPhs Ile Asp Ile Glu Ser Lys Pha Ala Lw Arg Thr Pro Glu AspThr Ala Glu AspThrCys His Lsu Ile Pro Gly Val Ala Glu SW LysAspPhsArgAsp lie Glu Ser Lys Phs Ala Lau Arg Thr Pro Glu AspThr Ala Glu AspThrCys His Lau Ile Pro Gly Val Thr Glu Ser L s Asp Tyr Thr Asp Ile Glu Ser Lys Phs Ala Arg Arg Thr Pro Glu Asn Thr Val Glu Asp Thr Cys His Lau lle Pro Gly Val Thr Glu Ser Myet Lys Pi-m Glu Gly Ile Glu Ser Lys Phs SW Lw Arg Thr Pro Ala Glu Pro Asp Glu Asp Val Cys Tyr Lau Val Pro Gly Gln Mat Asp Ser
Ser AsnCts Ser AsnCys
hLPL bLPL
Ala Thr Cys His AlaAsnCys His Ala AsnCys His Ala Gln CysAsn
192 l;: 126 162 102 Val Val Vat ‘2.4 Vat Leu
Phe Asn Phe Asn PheAsn PheAsn
l * l e*e His Ser SW Lys Thr Pha Val Val His Ser SW Lys Thr Pha Val Val His His His His
SW Ser Ser Thr
SW SW SW Ser
Lys Lys Lys Lys
Thr Thr Thr Thr
Phe Pha Pha Pha
Met Val Met Val
Val Val Val Val
c:: 291 225 261 291
*ee*****ee***eeeee Ile Ile
His Gly Trp Thr Val Thr Gly Mel Tyr Glu Ser Trp Val Pro Lys Lau Val Ala His Gly Trp Thr Val Thr Gly Met Tyr Glu Ser Trp Val Pro Lys Leu Val Ala
Ile 11s Ile Ile
His His His His
Gly Gly Qly Gly
Trp Trp Trp Trp
Thr Thr Thr Thr
Val Vat Vat Val
Thr Thr Thr Thr
Gly Gly Gly Gly
Met Met Met Mat
Ttr Tyr Tyr Tyr
Glu Glu Glu 610
Ser Ser Ser Ser
Trp Trp Trp Trp
Val Val Val Val
Pro Pro Pro Pro
Lys Lys Lys Lys
Leu Leu Leu Leu
rLPL InLPL hLPL bLF3. LPL 9e c PL
Ala Ala Ala Ala
rLPL mLPL hLPL bLPL
rLPL IllLPL
GTGOGAAAT b TGT-LTCATCAA k TGfXTGWIGkAAGAATTT J CTACWCCT 1 GACAATGT &ACCTCTTAG~GTA~GTCT~G~GCCC.AT GTGGG9AATGATCiT-GATTCATCAACT~T~~~~TT~~A~TA~~~~~TCTTA~A~~TT~~~T TTATCAACTG04TGGAc33WWGTTTAACTACCCTCT~~AT~CC4TCTCTTGGGATACA~TT~~T GTGf33CAGGATOTGGCCWGT GGCGGPTGAATTTAACTATCCCCTGGGCAATGTGCATCTCTT~TACAGCCTT~T GTGWACAGGATGT GGCCAAGTTTATOAACTGGAT GTTG6909AGATGTAGCCA~TTATCAACTOOATGG4aC GIGOG4AAEOATFTTGCCATGITCATTGATIGG9TGG(\GT l eeeeeeeeeee V& $y AsnA?pV% A?a Arg P% lie Asn Tfp Leu Glu Glu Glu Pt Asn TTr Pro Leu AspAsn Val His Lau Leu Gly Tyr Val Gly A:n Asp Val Ala Arg Phe lie Asn Trp Met Glu Glu Glu Pha Lys Tyr Pro Leu AspAsn Val His Lau Lau Gly
hLPL bLPL LPL c9: PL
Val Gly Vs.1 Gly Val Gly Val Gly
(continued
on
Lau Lsu Lau Leu
p.
Tyr Tyr Tyr Tyr
&In Gln Glu Lys
Lys Arg Glu Pro Lys Arg Glu Prc Lys Arg Glu Pro Lys Arg Glu Pro
Asp Asp Asp Asp
Val Val Val Val
Ala Arg Ala Lys Ala Arg AlaMet
Asp Asp Asp Asp
Pha Phs Phs Pb
Ser Ser Ser Ser
Ile Met Ile Ile
Asn Asn Asn Asn
Vat Vat Val Val
Asn Trp Asn Trp Asn Trp AspTrp
lie Val Ile Val Ile Val Ile Val
Met Met Met Met
Glu Ala Glu Glu
Val Val Val Val
Glu Asp Asp Glu
Asp Asp Asp Asp
Glu Glu Glu Lys
Trp Tip Trp Trp
V’,l Val Val Val
l l l l l l l l e l l l Leu TyrArgAla Gln Gin His Tyr Pro Val Ser Ala Gly Tyr Thr Lys Leu Lau Tyr Arg Ala Gln Gln His Tyr Pro Val Ser Ala Gly Tyr Thr Lys Leu
SW
Lw Arg Ala Lau SW Arg Ala La! Ar Arg Ala Lau Va I Arg Ala
PhaAsn PhaAsn Phe Lys PheAsn
Tyr Tyr Tyr Tyr
Pro Pro Ser Pro
Gin Gin Gln Gln
Glu Gln His Gln
Lsu AspAsn Lau Gly Asn ValAspAsn LsuAsnAsn
His His His His
Val Val Val Val
Tyr Tyr Tyr Tyr
His His His His
Pro Pro Pro Pro
Lsu Lsu Lw Lau
Val Val Glu Val
Leu Leu Lsu Lsu
Ser Set Ser Ssr
Gly Gly Gly Gly
Ala Ala Ala Ala
Gly Gly Asp Ala
Tyr Tyr Tyr Tyr
Thr Thr Thr Thr
Lzs Lys Lys Lys
:II
Ala Ala Ala Asp
+ GTAT ~-CAT!ATC~~~T~TA!ACCG GCAACATTATC09GTGTCAOCTGGCTACACCAACCTG TACACCAAACTG GZAGCATTATCCAGTGTCTGCAGWTACACZAAGCTG GQ3XCAWXCATTACCCAGGTCTGCGGACTACACCAA~TG
COXTATA~AAAGWi4ACkTGACTCCAA 4 GTCATTGTA&TAGACTGGT GCCCTGiftCAAWIGAWUlCCT~ATGTUITTGTAG OCCCTGTACAA~AW\WU\CCAGI\CTCCAATOTCI\TTGT GCCTTGTACAAG9GGG4ACCGGACTCCAACOTCATCOTOO GCTCTGTACAAOAGGOAACCAGACTCCAATGTUITTGTOO GCTCTGTACAAOAGOGAACCTGATTCAAAT~~TTGTTTG l ee*eeeeeee*eeeee Ala Lsu Tyr LysArg Glu ProAspSerAsnVal Ile Val ValAspTrp Ala Lsu Tyr Lys Arg Glu ProAsp Ser Asn Val Ile Val ValAspT;p
OPL TPL
Fig. 2
l l His PhaAsn His PheAsn
rLPL mLPL
2% LPI. cBe PL
1; -1
Met Asn tie AspArg Lys Ire Lau Asn Lys Ala Leu Ala Lys Glu Lys Val Met Glu Arg Gly Arg Gly Met Gly Lys Tyr Ala Lw Lsu Ala Val Lsu Cys LauCys Lsu Arg Gly Ala Ala Gly
3EL
rLPL InLPL
-72
_Sienal eplide Met Glu g er Lys Ala Lsu Leu Lau Val Ala Leu Gly Val Trp Leu Gln Ser Leu Thr Ala Phs Arg Gly Gly Val Ala Ala Met Glu Ser Lys Ala Lsu Lau Lsu Val Val Leo Qly Val Trp Lau Gln SW Lau Thr Ala PI-e Arg Gly Gly Val Ala Ala Met Glu SW Lys Ala Leu Leu Val Lsu Thr Lw Ala Val Trp Lau Gln Ser Leu Thr Ala Ser Arg Gly Gly Val Ala Ala
rLPL nlLPL hLPL bLPL
%F
:p:
Leu Leu Leu Lw
390 390 390 324 360 300 103 103 103 105 103 105
469 469 489 423 459 460 136 136 136 136 136 136
241)
first aa of the mature protein is conserved in four of the six species. It is Ala in rat, human, mouse and guinea pig. In rat, human and mouse, this Ala is the third of a stretch of three Ala, while there is no such stretch in guinea pig. There are two more N-terminal aa in bovine, -Asp-Arg, followed by Ile instead of Ala and in chicken, Ser-Asp followed by Pro instead of Ala. In rat, we found that aa 444 of the
human sequence (Asn) is missing, as was the case in mouse (Zeckner et al., 1991). In chicken, the C-terminal sequence is 15 aa longer (see below for an explanation). All these particular differences result in hLPL and gpLPL being 448 aa long, while rat and mouse are 447 (448 -1) bovine 450 (448 + 2), and chicken 465 (448 + 2 + 15).
241
rLPL mLPL hLPL bLPL LPL Be c PL
GCT~T~TTGCA~OCT~~TM~~~~~TTACT~T~T~~T~~T~CTTT~~AT~~~GT GCT~T~ATTGCAGOI\AGTCT~~TM~~~~~TM~TTA~T~~T~~TMCTT~~AT~~~T~GT GCTOCTGGCGTTGCTGGGAGTCOGACCAATACGAAGGTCAGT GAAAAAGGTOI\ACAGPIATTACTOOTCT~T~T~T~~~T~T~.~~T~T~T~TATC ~T~T~TT”.‘~~TTAAeW l eeeee*e*e l l Pro Ala Gly Pro As” Phs Ala Ala Gly Val Ala Gly Se, Leu Asn Lys Lys Val As” Arg Ile Thr Gly Leu rLPL P;o Ala Gly Pro As” Pi-m Ala Ala Gly Val Ala GJy Se, Leu Thr As” Lys Lys Val As” Arg Ile Thr Gly Lsu mLPL * P;o Ala Gly Pro As” Phe hLPL Ala Ala Gly Its Ala &y Se, Lsu Thr As” Lys Lys Val As” Arg Ile Thr kly Lsu Pro Ala Gly Pro As” Phs bLPL Ala Ala Gly Ile Ala Gly Se, Lsu Thr As” L s Lys Val As” Arg Ile Thr Gly Lsu Pro Ala Gly Pro Am Phs LPL Ala Ala Gly Val Ala Gly Se, Arg Thr As” T 6 r Lys Val Se, Arg Ile Thr Gly Lsu Pro AlaGly ProThrPhsGlu cge PL Ala AlaGly Ile AlaGly Se, LsuThrLys LysLysValAsnArg Ile Thr Gly LB”
Th,
. Gl” Tyr Ala Glu Ala Glu Tyr Ala Gl” Ala
Pro Se, Pro SW
169 169
Gl” Tyr Ala Glu Ala Pro Se, Glu Tyr Ala Glu Ala Pro Se, Glu Tyr Ala Glu Ala Thr Se, Tyr AlaAspAla Pro Ile
169 171 169 171
66.7 667 607 621 657 667
rLPL
KY-
bLPL LPL ge c PL rLPL mLPL
hLPL bLPL LPL cge PL
_-__.-...__.. Pro
l eeeeee l eeeeee Arg Leu SW AspAsp Ala AspPhs Val AspVal Arg Lsu Ser ProAspAspAlaAspPhs ValAspVal * Arg Lsu Ser Pro AspAsp Ala AspPhs ValAsp Val Arg Lsu Ser Pro AspAsp Ala AspPhs Val AspVal Arg Lsu SW ProAspAsp Ala Gln PheVal AspVal Arg Lsu SW Pro AspAsp AlaAsp Phs Val AspVal
l l l l l l eeeeeeeeee Lsu His Thr Phe ThrArg Gly SW Pro Gly Arg Ser Ile Gly II8 Lsu His Thr PhsThr Arg G:y Ser Pro Gly Arg Ser Ile Gly Ile * Lsu His Thr Phs Thr Arg Gly SW Pro Gly Arg SW Ile Gly Ile Lsu His Thr Phs Thr Arg Gly SW Pro Gly Arg Ser Ile Gly Ile Lsu His Thr PheThr Arg Gly Ser Pro Gly Arg SW Ile Gly Ile Lsu His Thr Tyr Thr Arg Gly Ser ProAspArg Ser Ile Gly Ile
Gln Lys Pro Val Gly His Gin Lys Pro Val Gly HIS
202 202
Gln Gl” Gln Gln
202 204 202 204
Lys Lys Lys Lys
Pro Pro Pro Pro
Val Val Val Val
Gly Gly Gly Gly
His His His His
766 766 766 720 756 706
,LPL mLPL hLPL bLPL LPL cBe PL rLPL mLPL
235 237 235 237
hLPL bLPL LPL cgP PL
rLPL mLPL hLPL bLPL LPL cge PL ,LPL mLPL
CTAGTGAAGTGCTCCCACGAGCGCTCCATTCATCTCTTCAA CTGGTG9AGTGCTCCCAC~T~T~TCTCTCTTCA CTAGT~GTGCTCCCATGAGCOCTCCATTCATCTCTTCG CTGGTOPIAOT~TCTCATOAACGPITCCATCTCTT~TT~CT~CT~TCTAT~~e~~~T~TA~T~A~~A~G l eeeeee*eeeooeeeee Glu Arg Ser Ile His Lsu Phs Ile Asp Ser Lsu Leu Asn Glu Glu Asn PTo St, Lys A7.s TT,A?gCTsAsn Se, L:s &J Glu Arg Ser Ile His Leu Phs Ile Asp SW Lsu Leu Asn Glu Glu Asn Pro Ser Lys Ala Tyr Arg Cys Asn SW Lys Glu Glu Glu Glu Glu
hLPL bLPL ZK’
rLPL mLPL hLPL bLPL LPL cge PL rLPL mLPL hLPL bLPL LPL cge PL
rLPL mLPL hLPL bLPL LPL cge PL rLPL mLPL hLPL bLPL LPL cge PL
Fig. 2. (continued
A?g Arg Arg Arg
S*r Ser SW Ser
Ile Ile Ile Ile
His His His His
Leu Lsu Lsu Lsu
Phs Phe Phs Phs
II8 Ile Ile Ile
A:p Asp Asp Asp
Ser Ser Ser Ser
Leu Lsu Lsu Lsu
Leu Leu Leu Lsu
Asn Asn Asn Tyr
Glu Glu Glu Glu
Glu Glu Glu Glu
Asn Asn Asn Lys
Pro Pro Pro Pro
~TTTGAGAAAOGGCTCTGCTTGAGTTGTAGAAAGPJ\TG ~TTT~-OGTCTCTG~~T~~~~T~~~T-TA~~T~~~~~~~~~-~TG ~TTTGAAAAAOGGCTCT~T~~T~~M~~T~~~~~TA~~T~A~~~~~~~~-~TG G9ACCGTTGCAACAACTTGTATAAAGTCAACAGAGTGTG GXTTTG4WGajCCTCTGCCTAA~Tl l eeeeeeeeeeeee*e* l l Ala Phe Glu Lys Gly Lsu Cys Lsu Se, Cys Arg Lys As” Arg Cys As” As” Val Gly Tyr Glu Ile Asn Ala Phs Glu Lys Gly Lsu Cys Leu Se, Cys Arg Lys Asn Arg Cys AsnAs” Leu Gly Tyr Gl” Ile Asn Ala Phs Glu Lys Gly Lsu Cys Leu Se, Cys Arg Lys Asn Arg CysAsnAs” Lsu Gly Tyr Glu II8 As” Ala Phs Glu Lys Gly Lsu Cys Lsu SerCys Arg LysAs”ArgCysAsnAsnMeI Gly Tyr Glu Ile As” Ala Phs Glu Lys Gly Lsu Cys Leu Se, Cys Arg LysAs”ArgCysAs”As” Val Gly Tyr Gl” Ile As” Ala Phs Glu Lys Gly Leu Cys Leu Se, Cys Arg LysAs”ArgCysAsnAs” Lsu Gly Tyr Lys Val As”
Gt CAAGATTCA A TTTTCTGGP, TACCTGAA d CTCGCTCT d GATGXCTA &AA AGTATTCkATTACCAA TACCTGPJIGACTCGCTCTC~T~TACAAAGTGTTCC TACCTGPIP~CTCGTTCTCAGATGCCCTACAAAGTCTT~TTA-~~~TT~TTTTTCT-CT~~~~~TA-T~~C TACCTGAA~CTCGTTCTCAG4TGCCTTACAAAGTCTTCCC TACCT09AGACTCCCTCACA~T~TACAAAGTGTTWC TACTTG4AGACCCGT~TC~T~TACAAAGTCTTC l eeeoeeeeeeem T:r L’, L;s T!, A?g SW Gln Met Pro Tyr Lys Val Phs His Tyr Gln Val Lys Ile His P’;, Ser G?y Tyr Leu Lys Thr Arg Ser Gln Mel Pro Tyr Lys Val Phs His Tyr Gln Val Lys Ile His Phs SW Gly Tyr Lsu Lys Thr Arg Ser Gln Met Pro Tyr Lys Val Phe His Tyr Gln Val Lys Ile His Phs SW Gly Tyr Lsu Lys Thr Arg Ser Gln Met Pro Tyr Lys Val Phs His Tyr Gln Val Lys 11s His Phs Ser Gly Tyr Lsu Lys Thr Arg Ser Gln Met Pro Tyr Lys Val Phs His Tyr Gln Val Lys Ile Tyr Phs Ser Gly Tyr Lsu Lys Thr Arg Ala Gln Met Pro Tyr Lys Val Phs His Tyr Gln Val Lys Ile HIS Phs Phs Gly
Ser SW Ser Ser
Lys Lys Lys Mel
Ala Ala Ala Ala
Tt, Tyr Tyr Tyr
Arg Arg Arg Arg
Cys Cys Cys Cys
Ser Asn Asn Asn
Ser Ser Ser Thr
Lys Lys Lys Lys
Glu Glu Glu Glu
665 665 085 619 655 605 266 266 266 270 266 270
964 964 964 916 954 964 Lys Lys Lys Lys Lys Arg
l Val Val Val Val Val Val
l Arg Arg Arg Arg Arg Arg
Ala Ala Ala Ala Ala Thr
ACTGAGAAT d
Thr Thr Thr Thr Thr Lys
Glu Glu Glu Glu Glu Thr
Asn Asn Ser Ser Thr Asn
. Lys Lys Lys Lys Lys Lys
l Arg Arg Arg Arg Arg Arg
Se, Se, Se, Se, Se, As”
CAAGCAAAA
Asp Gly Glu Asn Thr Val
Lys L s T yhr Thr Thr Thr
Gln Gln His Tyr Tyr Lys
Se, Se, Se, SW Se, Thr
l Lys Lys Lys Lys Lys Lys
l Met Met Met Mel Met Met
kwc.acc
AsnAsn His Asn Thr Am Thr Asn Thr Asn Val Asp
C% Gln Gln Gln Gln Gln
301 301 301 z 303
1063 1063 1063 1017 1053 1063 Ala Ala Ala Ala Ala Pro
334 E 336 334 336
on p. 242)
The putative catalytic triads Ser13*, AsP’~~, His241 coded by exons 4, 5 and 6 in human is conserved in rat, with the same aa in the same positions, the codon for Ser13*, however, being AGC in human and AGT in rat. Ser13* occurs in the consensus sequence Gly-Xaa-Ser-Xaa-Gly present in serine proteinases and in human pancreatic lipase. It has
been shown that hydrolysis of tri- and monoacylglycerol by LPL stems from a common active site. The catalytic site and the heparin-binding domain reside on two separate folded domains. Although the heparin-binding domain of LPL has not yet been definitely assigned, this site was shown by peptide cleavage experiments (Olivecrona et al.,
242
1182 1162
1LPL mLPL hLPL bLPL LPL c PL ge rLPL mLPL hLPL bLPL LPL cge PL
rLPL mLPL hLPL bLPL LPL cge PL rLPL mLPL hLPL bLPL ZK’
rLPL I$?blPL LPL cBe PL rLPL mLPL hLPL bLPL splPL CLPL
1::: 1t52 1182 & Phe Phe Phe Phe Phe
Glu Glu Glu Glu Glu Leu
It, Ile Ile I le Ile lie
Sir Ser Ser Ser Ser Ser
t Leu Leu Leu Leu Leu
T-r Tyr Tyr Tyr Tyr Tyr
T:r Thr Thr Thr Thr Thr
Val Val Val Val Val Leu
l Glu Glu Glu Glu Glu Glu
Ala Ala Ala Ala Ala Asp
e**ea**ee**e Ser Giu As” Ser Glu As” Ser Glu As” Ser Glu As” Ser Glu As” Ser Glu Asn
ile Pro Phe Thr Leu Pro Glu Ile Pro Phe Thr Leu Pro Glu Ile Pro Phe Thr Lw Pro GIu Ile Pro Phe Thr Leu Pro Glu Ile Pro Phe Thr Leu Pro Glu Ile Pro Plm Thr Leu Pro Glu
Val Val Val Val Val Val
Ser Ser Ser Ser Ser Ser
Thr Thr Thr Thr Ala Ser
A:” Lys As” Lys As” Lys As” Lys AsnAsn As” Lys
l Thr Thr Thr Thr Thr Thr
Tyr Tyr Tyr Tyr Tyr Phe
l Ser Ser Ser Ser Ser Ser
l Phe Ptw Phe Phe Phe Phe
l Lw Leu Leu Leu Leu Leu
lie Ile I le Leu Ile lie
T:r Tyr Tyr Tyr Tyr Tyr
367 367 367 369 367 369
1281 1261 1281
l eeeee l ee Thr Glu Val Asp I le Gly Glu Leu Leu Met Met L;s t Lys T:p Thr Glu Val Asp 118 Gly Glu Leu Lw Met Met Lys Leu Lys Trp * Thr Glu Val Asp Ile Gly Glu Leu Lea Me( Leu Lys Leu Lys Trp Thr Glu Val Asp Ile Cly Glu Leu Leu Mel Leu Lys Leu Lys Trp Thr Glu Val Asp Ile Gly Glu Leu Leu Met Leu Lys Leu Lys Trp Thr Glu Val Asp lie Gly AspLeu Leu Met Leu Lys Leu Gl” Trp
I
I
I
ATUMCNAW\TCCG4GTG4AACD.%XA~GACTCAGAA ATCGAG9GGATCCGAOTOAAAGCCOGI\OAGACTCAGAAA ATTCAGAAGATCA~OTAAAAGCAGGAGPIGACTCAGAA ATTEYrJ\AGAT~WIG~~~~CT~~~~~TCTTCT~T~ ATCGAAAAG9TCAG9GTAAAAOCAOU\GAGR04CAG4AA ATTCAGAG4GT~GAGTG9AGTCRGOCUIAACTCAG4AA l eeeee . eee Ile Glu Lys Ile Arg Val Lys Ala Gly Glu Thr Gln I le Glu Arg Ile Arg Val Lys Ala Gly Glu Thr Gln Ile Gln Lvs Ile Am Val Lvs Ala Glv Glu Thr Gin Ile Gly c(‘s lie Ari Val L,, Ala Glj, Glu Thr Gln lfe Glu Lys II8 Arg Val Lys Ala Gly Glu Thr Gin I le Gln Arg Val Arg Val Lys Ser Gly Glu Thr Gln
I rLPL “lLPL hLPL bLPL
‘.i?y Gly Gly Gly Gly Gly
I
1::: 1281 Lys Ser Asp Ser T yr Pk S:r T:p Ser Asp Ttp T:p Ser SW Pro Ser P: Val Mei Ser Asp Ser Tyr Phe Ser Trp ProAsp Trp Trp Ser SW Pro Ser Phe Val Lys Ile Ile Glu
SerAsp Ser Ser Asp Ser Thr Glu Ser Lys AspThr
Tyr Tyr Tyr Phe
Phe Phe Phe phe
SW SW Ser Ser
Trp Trp Trp Trp
SerAsp Ser As” Ser Ser Ser Asn
Trp Trp Trp Trp
Trp Trp Trp Trp
Ser Ser Gly Thr
SW Ser Arg Pro
Pro Pro Pro Phe
Gly Gly Thr Ala
Plw Ala PheAsp Phe Thr Phe Thr
1380 1380 1380 1314 1350 1360
Ad, GGTCATCT!CTGTGCCAC~~~T~CT~~CT~~A~~~~T~A ~TGTCTTATCTOCAOA~A~~~~~~
l
Lys Lys Lvs L+ Lys Lys
Lys Lys Lvs L,, Lys Lys
Val Val Val Val lie Vat
Ile Ile Ile lie Vat Val
*
PheCys Ala PheCys PheCvs PheC;s PheCys Phe Cys
Ala Ser Ser Ser Ser
l Arg Arg Ara Ar; Arg Arg
Glu Glu Glu Glu Glu Asp
Lys Lys Lvs Ljrs Lys Gly
I
I
Val Val Val Met Vat Ser
l Ser Ser Ser Ser Ser Ser
His His His Tyr Lys Arg
e Lw Leu Leu L&w Leo Leu
I
Gln Gln Gln Gl” Gin Gly
400 402 400 402
l Lys Lys Lvs L$s Lys Lys
l Gly Gly Glv Glj, Gly Gly
LysAspArg Lys Asp Ser Lvs Ala Pro Lis Sar Pro Lys Glu Ala Glu Glu Ala
I
Ala Ala Ala Vat Pro Ala
433 433 433 435 433 435
I
GTGTTTGTWAATGCCATGKAAGTCTCTG GTGTTTGTGAAATWCAT69CAAGTCTCTG
ZKL rLPL mLPL
l l l l Val Phe Val Lys Cys His Asp Lys Ser Leu Val Phe Val Lys Cys His Asp Lys Ser Lw
hLPL bLPL gpLPL CLPL
Val Ile Val Ile
Fig. 2. Nucleotidc
Val Val Val Val
sequences
guinea pig and chicken aa (although
Pha Pha Phe Ptw
Lys Cys LysCys Lys Cys Lys Cys
Lys Lys Lys Gln
mouse (mLPL), bovine (bLPL), guinea
pig
of chicken
are translated
again in Fig. 3 in order to align all the exon-10 in the six species are indicated
and deduced
The beginning
aa of chicken
*
Ser Lw Asn Lys Lys Ser LeuAsn Arg Lys Ser Lou Asn Lys Lys Pro Val Ser Arg Lys
of rat ML cDNA
sequences.
the C-terminal
His Asp His Asp His Asp LWJ Glu
. l Lys Lys SW GtySlop Lys Lys Set GlyStop
sequences.
(gpLPL)
SW Ser SW Arg
447 447
Slop
Gly GlyStop GlySlop Gly Gly Ala
aa sequence.
448 450 448 Lys Lys Ala Ser Lys Glu Asn SW Ala
The nt sequence of rat LPL cDNA.
exon-10 sequence
from the beginning
1987) to be located in the middle part of the C-terminal region. A candidate region is Ly~~~~-Lys”“” (numbered as in human LPL), that harbours a cluster of positively charged aa. Thus, 5 aa out of 9 (italicised) are positively charged (KVRARRSSK). This sequence, located in exon 6 (human gene), is entirely conserved in terms of aa with, however, four codons differing at the third base in art, mouse, human, bovine and guinea pig (Enerbgck et al., 1987). In chicken, there is only functional homology and no identity, RVRTKRNTK. Cooper et al. (1989) proposed three other candidate regions by analogy with the heparinbinding regions of apolipoproteins E and B. Such a region is found in 279-282 (human numbering), where RKNR is conserved in all six species (in terms of aa not codons). The ten conserved Cys of the previously described species are also conserved in rat (Cys 27, 40, 216, 239, 264,
465
with human, mouse, bovine,
as predicted
mutations
all the C-terminal
and not from the end of exon-9 as for the other 5 cDNAs)
and chicken (cLPL). The aaof the catalytic
by black spots; those involved in missense
Comparison
is written twice, once in this figure, in order to gather
of exon-10
Aligned aa sequences
His Glu SW AlaStop
from LPL cDNA
clones for rat (rLPL),
human
and
(hLPL),
triad (Ser’j2, AsP’~~, His2” ) are boxed. Those aa conserved
in human
are indicated
by asterisks.
275, 278, 283,418,438). The sequences around these Cys are highly conserved. It has been shown for bovine LPL that all Cys were disulfide-bonded (Yang et al., 1989). Two N-glycosylation sites, Asn43 and Asn359, that correspond to the consensus sequence Asn-Xaa-Ser/Thr where Pro is excluded as Xaa and that have been previously shown to be conserved in all five species, are also conserved in rat. At the present time, the LPI, site of interaction with apolipoprotein CII has not yet been identified. Similarly, the site involved in the formation of the LPL homodimer, the active predominant form of LPL bound to endothelial heparan sulfate, remains to be established. Interestingly, the aa involved in the missense mutations already known to be responsible for human LPL deficiency are all conserved in all six species, with two apparent ex-
243 ceptions.
These
following.
In exon 3: Tyr61 (+ Stop), Va169 (+Leu),
aa, that are indicated
in Fig. 2, are the Trp*’
(+Arg),
Lys102 (+insertion + frameshift), Glnlo6 (- Stop); in exon 4: His136 (-+ Arg), Gly14* (4 Glu), G~Y’~~ (4 Ser); in exon 5: Asp156 (+Gly or +Asn), Pro15’ (+Arg), Ala’76 (+Thr), Gly”’ (-+Glu), Ile’94 (+Thr), Asp204 (+Glu), Ile205 (+ Ser), Pro*” (+Leu), Cys216 (+ Ser), Ala221 (+frameshift); in exon 6: Arg243 (-+His), Ser244 (+Thr), Tyr262 (+ Stop); in exon 8: Trp 382 Asp250 (+Asn), (+ Stop); in exon 9: Ser447 (+ Stop). One exception occurs in Ser447, but this exception is more apparent than real, because this mutation has been likened to a polymorphism rather than to a source of metabolic pathology. In fact, the two last aa of LPL are not necessary for LPL activity. Another exception is Glnlo6, but in this case we are dealing with premature termination of the peptide chain rather than with a missense mutation. For references concerning these mutations, see a review by Etienne et al. (1992). (2) CG content CG sequences are known to be rather unevenly distributed in the genome. CGs have been lost in the course of evolution, leaving vertebrates with a remarkable deficiency of this dinucleotide in the different genes (where CG/GC: is approx. 0.1) except in the regions surrounding the promoters of housekeeping genes, the CpG island, where CC/CC is approx. 1. LPL exons 2 to 9 are relatively rich in CG. The ratios CG/GC are 0.41,0.42,0.43,0.47,0.53,0.26 for rat, mouse, human, bovine, guinea pig and chicken, respectively. The role of CG enrichment in these exons cannot be presently explained. (c) Comparison of the sequences of the untranslated exon 10 The 3.18-kb clone alone covers the whole of rat exon 10, while several overlapping clones in mouse and in human were necessary to achieve this. The untranslated exon 10 of rat LPL cDNA is 2019 nt long, i.e., it is longer than the total of the nine other coding exons (1160 nt). This exon is 1948 nt long in human (Wion et al., 1987) and 2353 nt in mouse (Zechner et al., 1991). Gene LPL organization is known for human (Deeb and Peng, 1989; Kirchgessner et al., 1989), mouse (Zechner et al., 1991), and chicken (Cooper et al., 1992). Exon 10 starts with A, the last nt of the stop codon TGA that was interrupted by intron 9. This is the only known example so far of stop codon interruption by an intron (3.1-kb long in human and mouse) or with the last noncoding exon containing only the third nt of the stop codon and overriding in length the total of the coding exons located upstream. Remarkably, in chicken (Cooper et al., 1992) the last codon in exon 9 interrupted by intron 9 is GG/T (Gly)
rather than TG/A (stop codon), as is the case in human and the four other species.
Chicken
exon 10 thus presents
a
short ORF translated into Gly + 14 aa up to the next stop codon. This explains why the chicken aa sequence is longer, not because exon 9 is longer, but because there is no stop codon between exon 9 and exon 10 (Figs. 2 and 3). Zechner et al. (1991) have reported in mouse an insert (relative to man) consisting of (i) a Bl repetitive element (Kalb et al., 1983) (belonging to the Ah family) of 152 nt followed by (ii) a homopurine stretch of 169 nt consisting solely of A and G residues. This insert is flanked just upstream (GAAAATGAGCTTATAA) and downstream (GAAAATGAGCTTGTAA) by a 16-nt direct repeat. (differing only where italicised; see Fig. 3.) Six different mouse strains were tested by Zechner et al. (1991) and the B 1 element was found in exon 10 of all these. The mouse insert was not described by Kirchgessner et al. (1987) because their clone stopped about 250 nt ahead of it. In rat, both the Bl repetitive element and the homopurine stretch are missing. Consequently, only one of the two repeats is present. One copy of this direct repeat is found in human exon 10 and bovine exon 10, which likewise lack the mouse-specific Bl element (Fig. 3). Zechner et al. (1991) have reported in mouse a 195-nt region, located just after the 3’ direct repeat following the insert, that has no homology to human 3’ cDNA. We have also found this region in rat, where it includes a stretch of 157 nt that is highly homologous to the 3’ part of this mouse sequence. However, it is deleted in man. This clearly appears when the sequences of mouse, human and rat are aligned. The 157-nt stretch was compared to known rodent repetitive elements, such as mouse Bl (or Ah type I), also present in rat (Kalb et al., 1983); rat B2 (Bains et al., 1989) (or Ah type 2) (Kalb et al., 1989) and rat newtype (Kalb et al., 1989) both also present in mouse. There is no homology with any of these. Of course, there is no homology with 7 SLRNA either, since this element, which is assumed to be the progenitor of the Bl family, is itself homologous to the Bl element (Quentin, 1989). However, a sequence of this mouse/rat insert can be recognized in other genes: 930CCTGCCTTGGCTTCCTGAGTGCTGGGA956 (Fig. 3). Its percentage of homology (interrogation of the data bank GenBank) is 74% with the murine eosinophil differentiation factor (interleukin 5)-encoding gene, 88 % with the hamster replication-initiation locus, 88 % with mouse pim-1 proto-oncogene, 85% with mouse p-2 microglobulin-encoding gene, 8 1 y0 with human cosmid clone HDAB, 85% with human PRT, 77% with rat heme oxygenase-encoding gene, 74% with R. norvegicus toninencoding gene, 66% with human apolipoprotein E-encoding gene, 88 y0 with HSAG-1 middle repetitive element, 81 y0 with the mouse surfeit locus, 74% with the mouse
244 Exons 10
rLPL mLPL hLPL bLPL LPL cge PL
’
c&4 cw4AkGCATCTGA G-+TCTTTGudCCGAAGAAA A TGAAGTAAA!TTTATTT AAkAA AATAkC TTGTTT CAAGA GAAGAAA GCATCCOAGTTCTTTGUGCAGUGUAACAMGTAAATTTAATTT AAAAMATAATACCC TTGTTT CAGAACAMG9ACGGCATOT~TTCT~~~T~~~~~MCTTTTAC AAAA CATACCCAGTGTTT CGGAAGAAAGUCAGCATATWTTCTATWAGAATG AAGTAACTTTTAC MM GATGCCCAGTGCTTT CAGAAAW~TTAGTACTWGCTCTGTGAAOAACA AAATWTTTTAC AAAA GATGTTCAGTGCTTT AAAGAAAATTCTGCACACGAGTCTGCT~~AAG ACACT-GG4GGATGGTCTGTTCA
rLPL mLPL hLPL bLPL LPL cge PL
GGG TGTTTkAA GTGGA + TTTCCTGA G+ ATTAATCCCkCTATA TC + TGTTAGTTdAT GGG TGTTTCiUA GTGGGTTTTCCTOAGTATTMTcCCAf3ZTCTA TCTTGTTAGTTAAAC CGGGTGTTTCAAAAGTGGATTTTCCTGAATATTAATCCCATTCA ACi4 TGOT Ci4AATGTGWTTTTCCGGAGTATTAACCCCA~TCTAGCCTTATTAGTTATTT Go0 TGCTTAAAA GTWTTTTCCTWGTATTAATCCCAQZTATCTCCT~TTAGTTC.UC TCCCTGT G9ACTOGATGTTCA09ACCAAATATATATA~TATC
AGAAG4 L GTGTCAAA + ATTAAAA CK&TMCAC~ AOlUIOACAGTCTWAATATTAAACOOTOGCTAACCCCA
rLPL rnLPL hLPL bLPL LPL cge PL
CCTAAT G&G ATAGCA+GTCCTCCA~TCAG4AG9’CAGCAGAGA~GAAGCATCTCTTAT~T~TT~~-TCAT+ ACGTGPI G& GGGTGAGGM TCTAATOOCCC ATAWAaTTCTTCCAGCATCAGU~ CATCAGGCAGGWAAACATOGTCTTGTATCCCTTAAGAAG~XATCATT ATTTATGOGG TATAGTGGCCAAATAGCACATCCTccAAcGrT~~ CAGTGGATCAT WAAAGTOCTGTTTTG TCCTTTGAGAAAWAATAAT ATTTGAGGTG TATAGTGXCAAA TAOCACATCTTCCMCATTAAAAAAA TAACAGAT AT WAAAGCACTGCATTCTGTCTTTT WAAAAATATGAGT AT TAAGGCC TCTAGTGGGTA ACTCCA ATCCTC AGCATTA AA09 TGGTA ATCG CS,AGC CCGTGTT TGTCT TTOAGOGACAAA A TTGTAAGGAAGTCTCAGACAAAAGTTACTAACCATAATTA CATTATCTGATAGTTAAGAACAAAW,AACCcCT(3ZAACAACTTccGAAAG
rLPL mLPL hLPL bLPL LPL cge PL
TGTTCCCAA JXATA CAAGACTCC!TCATGTGA &A TTTGGTdTGGTCT d TTAGTAAGGkCTCTTATT~TCATTAGAT A TCTGAGG TGTTCCCAACAATA TAAGACTCC4TCATGTGACTTTGGTcAT~CTAAAATTAGTAAGAAC TCTC%GG TGTTT04GCOCAOAGTAAMTAAGGCTCCTTCATGTGGCGTCTT TATTTAAAATGATAAAATAATCAGATCTCTTCATGTAGTAT TTTTAATTGGGATTCTQXT TGTKCCA TAGTAATATCC GCTTGAGTGTTAGGAAOTAATAAGTAATTTT~TTAATC~~~TT~~~~TTCTT~T~~T~TCTTTA~~TTT~A~ATTTATT
rLPL rnLPL hLPL bLPL CLPL
GACCTTCTkAAGTTCTC + TGAAGTCT TT AAATTd MTATAkAACAACA T + TTTTTGTGC!GTWTCAdTCCATTTCT + TAGCAGT TT ATATTGA G4CCTTTTCAMGTTTTCTCGTCT AATATAGACAATA TTTTTTGTGGCATGAGTCAGGTCCATTTCTTTAOCGGT CTTTTCCGCGGCA CCAATCAGACTCATCTACACQZAGTATG TC GOACTGPI GGCCTTCTCAAACTTTACTCTAAGTCTCCAAGAATACAGAAATG TCTAG4CTG4TAACCTTCTCAGAGTTTTCTCCG4GTCT AAATATAOOAAGTAAGTTTTTTT@XXGTCi4GTAGGKccGTTTAccTATcAATCAA GAAAAGATGCAAAGCTCTOTACCTMjTCCTCTTTTTAGTGTTTTT
rLPL mLPL hLPL bLPL CLPL
190 192 193 177 161 195
AGGAGACAGTCTCAMTACTAAAA CTAATTCA G~GS~GVITCTCAAATACTAAAAAGTGACTMTTCA TTC
’
’
T
T+ TT TT
267 269 260 274 264 294
360 363 366 372 263 394
T& TG
470 452 464 466 494
C!TTTACCAT d GG4TATA&CCCTACCA~TAAAATA AAACAGCTGkCCA TTGTAkTAGTT J TAAATAAAG&CAGUjA~T~GACTT AAACACCTGGCCT TTWAACTAGTTTTTTTTTACCATT~TATATTCCCCCCA CCAAAAAAAAAAAAAAAAAAAAGTAACCAGGAACGTGTGACTTG TGATGTTTTAGAATGA TTCCCTCTTGCTATTGCAATGTCXTCCA~cGTC4 ACCAGGAACATGTAACTTG 2 TCCCTACTTTCTTGGAATTACTCTCCTCTTGGAA ACCAGGAACTAGTGACTTG TGTTGTTCTCCTGGCCTTGACTGAATTTTCAGGCAC;TTTCTCAT
+
567 551 556 545 594
rLPL mLPL hLPL bLPL CLPL
GfJ TTCCTGA &TT @XAAGCA~TGWGA~GGCTCGT Ac&WCAdC CWTACkTCAGTA d GGTACAAAA k TAG4 GCAAAAGCAGTTGAAG4CATGOCTCATGAAGTCCTGACCCTT GGTCCCACCACAAC AAAGTACAAGTC’MCAGAGTACAAMCCTAGA GAGAGGGACGAAGAAAG CTGATAAA CACAGAGGTTTTAAACAGTCCC TACCATTGGCCTGCATCATGC+IAAGTTACAAATTcAAGSAGATA GAG4TAGAAATG4AGAATAGAGTTGATAAAGCACTGAAccTTTAAAC CCCCTCTACGGTTGGT TGCATCATAACTAAGTTACCAATTAAAGGAGATA GGAAAAAAATACCCTTGTGTGTA04GCTATAACAGAGATGTTTAC
’
rLPL mLPL hLPL bLPL CLPL
CT &I G T A ATTCTTAGTTIGACTTCAA GTTTTATOOC + TAATTCCTC!GTCTTTT AAAAACGT $A: ?:::;:;;;:A CTGAG TAATTCTTAATAGACTTGAA TTTTTATGXTTMTCCTTCTATCTTTTAAATATTT TA AMTCT AGATCAATTAATTCTTAATA~TTTATCGTTT ATTGCTTMTCCCTCTCTCCCCCTTCTTTTTT GTCTCAAMTTATATTATAATA TATAMGTTGWATCAATTAMTCT TTAACAGTTT ATGGTTTAGTATTTCCCCTTCCTTTTCCT~TTTGTCTCAAGATTATATTTTAATA TmGTAGAT-ATOCTTCTTA TATAATCTGTTMGATATGTAATCCTATGCACCTTAT ~AGCAATAGC~~G~~~SU~
rLPL mLPL hLPL bLPL
TTATTCTC + AGACAGAT G-+TGAAA T&TTGTGA TTGTTCTCTOGATAGATGT ATGTTCTCTWGTAGGTGT GTTTTTCCCTAGATAGGCTTTTWACTGTTA
I
I
I
I
I
I
656 640 651 642 694
733 717 746 741 707
I
TGGZAATGGTGGCOCTCACCTTTMTcccA@ZACTTGGZAG3XGAG%AGWGGATTTC
766 616 762 778
rLPL mLPL hLPL bLPL
916
rLPL mLPL hLPL bLPL
1016
rLPL mLPL hLPL bLPL
rLPL rnLPL hLPL bLPL
I
I
I
I
AAGAAA~MGAMGAAAGAAAGAAAGAAA~M~A~AA~~-~AA~A
I
T +
Insertion G&c TGGCTGA!TTTATTTCTATGTTTGCT GAGCTCiKi&AATAAT + TCTTGAGAAAAGGAATACT TTGCTG4AAGACAAAMTOTAGGTTGATTTTTACTTCTCTTTTTT~TTTCTT~A~~~TT~~T~T~~~A~CT~TA~ GTGCAGUAAAAAAAA ACAGAGGWAAAAMT
d
’
T GGTGACATA TGAAT! TGAGGTGACACA TAAATT CCTCAGCTGACACATAATTTGAATG TCATCAGCTGATACAGAATTTTAACT
+ GTCCCACT &ATcTGA&TwzcAAJ
rLPL mLPL hLPL bLPL
ACTAAACTA + GTACTTCAGbCTTACCTTdACTCTCAA ACTAAACTATGTATTTCAGGCTGGCCTTGAACTCTCAACCTTT
rLPL mLPL hLPL bLPL
TAGAACA&TTCAAT TTCTTAGT d TTTTCACCAd GCC~ATCGTTAG&TTT~TT~GKTCATC!TG~CCO l&T TTCTTACTTGTTTTCATCAATTTGAAAT GCCCAATATCCAATACTTTGTATTTCATTTG~GACTCATCT~CGCCATGC~TCTGTCACACTT~~~~~~A T CCAMTGATTTTCATCAATTTAAAATCATTCAATATCTU\G T CACAATTACATTCA TTGAAGTCCTTTAATGT GATAGTTACTGTTCA TTTTAWCTTATTTCAQXATGCTTcAGTcAG4CTTTOAGATG
Fig. 3 (continued
c&A TCCTGCCT!GGCTTCCTdGT~TG&CTT~TMc&ATAATTTTA OATA G4TA
on
p.
707 1109 606 604
+ TATCAGATT
867 1209 824 620
+
967 1309 650 646
1
1066 1406 949 937
CCGTAATTTTATTATTAGATTC CTGTAATTTTATTATCAGACTT
245)
kidney androgen-regulated protein-encoding gene and 88 % with human cytochrome P450 IIEl-encoding gene. Another interesting feature of the rat sequence that was not pointed out by Zechner et al. (1991) in mouse, but again
clearly appears upon alignment of the three sequences, is a deletion of 8 1 nt (rat)/7 1 nt (mouse) relative to man. This rat deletion corresponds to a fragment spanning 15911671 in human (Fig. 3).
245
’
rLPL mLPL hLPL bLPL
ad TTTTTTTTTC ICAAGTTTTA!WCAGG~ T>TCWT~cTGCAcT G&MAGT TCACATTAA + TTCTAGTTT 1 GMGTOA AWGTTTTA~XAGGACCATTTTTTTTT TCAAGTTCUATTCTGCACTGT-GT TCACATTAATTTCTAGTTTAaTGTGA TCTCTTTTOTTCCTCrCTTTGAU\TOAAAAGATAGGTTTGTTTT TCTCTTTC TCCCTAACTTTGATA GAAA CACGTATTCAC09GTA CTTTGCATCAT-GTCCTACAAATTTTAGWAAA~TTGTTTTT
1173 1493 1044 1027
rLPL mLPL hLPL bLPL
ACCACGTAG TCG+d TTACTAG&AATGTGTA+AT C&A TGCTTGTk.4CTGTT&-GTGkiWCCTTC+ATTGTGATA~ GM TGCTTGTAAACTOCT GT-GMAAGWXCTCAACTGTAAT~~ ATCACATWG TTGAAA TTACTAGAAAATGTOCATAT GCAGTGCTTGTAAACCATCGCGTGCAATO ACTAAGTUAA~OOAGAGOTTCCTOGGG T(XjPTTCCTAA ACTAAGTAAAGWACA~AAAGTTACAGTCA GTCATATAGTCACTOCCAGTGCTTA AAACCGTTGTG64CXATGGGATcAATT~TATATCCA
1262 1560 1117 1124
rLPL mLPL hLPi_ bLPL
CCATAOACA &r ACCAGGCT CTATAGUAGTACCAGGATTGTTGCcGCTGTTTTGTTTTAcCTT~AA.4AcAAGWAAAAATCMTAATGAACiUT ~~TGGI\GTACCATGA~T~TATTT~T~~~~~ AACAAC ATTGTCATWGTTG
rLPL k? bLPL
CJA TATAAAAT&TAAAAAAdAAAATAAAA CAAGPITCT d TATGTT CA&TTGCTTTTkTATTCAT CGAGPlTCTCACATTTT CAGATTGCTTTTATTATTCATTAATGTAAAAAAATAAAO CTAOATCTCCTATTTTTGWAATGCTCTT CTACGTATAAATATWTGTUG CTAWTCTCATATTTT CAGUTGCTTTT CTATATATTATTATCAAATGTAGAG
rLPL mLPL hLPL bLPL
+ GAACAC ~TACACA ~-~cAAGAGc+TT~~TTC~ATGTCAAA AACAGAAAC 1,GTGUA TGk-TGWTATC CAACCCA CAT~CCCCACAAGTGTAGTCGTCATTCAATGTAA AGCAGAAACTFTGAAA TTTGTGGGTATCTGUCAC AACCCGA CTGTGAAAGTATGTG ATATCTWC4CATACTAGCZTCTGCATGTGTGTTG CA CGTATGAAECCMCATACACG9TTATTGCTCAGCATGGAAA AATCCAAACTGT04ATGTGTGTGGGTGTCTGpJ\CACATATT
rLPL mLPL hLPL bLPL
CSGTCAAGA L TATAC’XT kI TATGTCAG’ GKEAAGCGPTATACTGTATGTTAG TCAAWGATGTATTGGAACATGT~GTA~ TGATTAAGAOGTACATTAGAACACACTGA
rLPL mLPL hLPL bLPL
ATAGGA c+d AGTGKT ATAGG4GUAGOT~CCWTTTCATCA GTAKWXAATGTTGTGATTAA~T~T~~TTGGAAT GTAGAATGAATGCTGTGATTGKATGVXCA~TTGMATC+IATTCTCTCT
rLPL mLPL hLPL
ATTCA T G&I GTATATA C& ATTCA TTACAGTATATACACATCCACATGCA ATTAAATTTCTOGATTTOOGTTGTGACCCAGGGTGCATTAT
rLPL mLPL hLPL
TACATATC + CAATGATGC + TTGACTTTA & TTTTATTT TTAGCTGT TACATATGTWT~TGCTTTAOCTTTTCAATTT ATTTATTAGCTGTAAATA TTATATATATCAAGG9TGTTCTGGCTTTTA~TTTTTACATT
rLPL mLPL hLPL
G+ GTCCACCT ~ATCAGTGAT+GTCT GTGGCTATCkGGG TGTA&TTTGTGGTbCTAACTCT GTGGTTATCTGCAG TATAGATTTGTGGTCCTAACTTTGTGTCCGTCTCCATCCAGTA GTGETATCTGCATTTATAAAAATGTFTajTOCTAACTGTATGr GTCTTTATCAGTGATGGTCT
rLPL mLPL hLPL
~GGAAG4AAATAAAC+C~T~~~-T~TCT~TTT CAATOGAAT GCTTTT MAA~AGUAACTCACCTGTGTGAAGUATWTATCTGCTTT CAATCSAATAGGCTTTT ATCSAATGGGCTTTAACAAAACAAG#,AWAAcGTACTTAACTGTGTC&WAAATCXUTcA~TTT
rLPL mLPL
CGCG TAAC
bT~&TTmTTTAcTATd
window
TATTTATOA TATTTATGAA TAATCAA~GTG4GTMACAACTATTTATAAA TAGTCAAG4GTG4GTGUCATTTATTTATAAA
1194 1166
1431 1752 1279 1272
TATCTCAGA Gd TGTTGCTGd &AA GTTC AAGATC TATCTCAGA%CTATAGCTGGG ATGTCAAATATCTCAG4GATAGCTGGG AAGTCAAATATTTCAG4GATTACTGAA
’
’
’
’
’
Deletion
’
1525 1646 1374 1367
1621 1942 1470 1463
GATGTA c&A TATGTCA TATGTATMTTTGTTAC G4TGTAT~TTTGTTGTTGTCUXTTTATTAATTC GTTGTGTGKTTGTaaaaaaaaa
1712 2034 1570 1539
’
’
KGAAAAACTTTG
1731 2063 1670
,&TA ATaOC-mdmA mTTdt,t,AwCT&mTGd 1620 ATGTGTGOGTATGTMWT GCTTGTAAACACT-GTCTGTT 2159 1770
&TGAGCCAA&TC
ACTCTdTCi4A
CACAGAGCCAACTC
ACTCTT
CAGC
A 2256 1921 1652
TC&.WACGTTT~ATCAT CTGKSACATTTTATCATGATAC TTGKAACATTTTATTACCaa
L
2015 2349 1946 2019 2353
of exon-10 in six species. The polyadenylation
signals are boxed. GenBank/EMBL
and that of the five other species was made using NUCALN manually
A 1334 1669
I
TGAACiUT’
'
size = 20; gap penalty = 7. Aligned
was optimized
L
TkTTCC4GAT~TOCTGTkCTACXXcTTkCTAGG4G&TTGGTTGTk!CTATGTAA+ TAGTTCCAGPITATCCTKiMTGTTAGCCCTTCCTAGOI\ATGTAAT TTGTTCCTG4TGTGCXXGCTTCG4cCCTTTCTCTG4Ci4GKNTGkTCGECCTATAAATA ACTCCTTCATCTGAGAGATACGGTTGRXCTGTACAAA GTACiUAATGGTTCCAGT@ZTjTGCCGGI\AC
A
A
T
ACi4AG AWAG
’
Fig. 3. The nt sequence the rat sequence
’
for a minimum
sequences
were transferred
rate of divergence,
respecting
(Wilbur and Lipman,
into a WingZ
spreadsheet
the choice order: transitions>
We have also sequenced another independent 2.5kb clone, that was shorter than the 3.18-kb clone at the 5’ end but identical to it at its 3’ end. It provided confirmation of the 157-bp insertion and of the 8 1-bp deletion and was also devoid of the mouse Bl element and of the homopurine stretch insert. The consequences of the presence of these inserts and deletions in the untranslated region of mRNA remain to be elucidated. (d) Particular features of rat cDNA LPL exon 10 (I) Polyadenylation signals Mouse and human LPL cDNA have two polyadenylation signals. It is likely that only one of these is functional in rat, since a single LPL mRNA species (3.6 kb) was isolated from different rat tissues (Kirchgessner et al., 1987; Semenkovich et al., 1989). However, eight AATAAA se-
accession
No. L03294.
Alignment
1983) with the following parameters: (Informix,
USA) and alignment
between
K-tuple size = 3;
of the six sequences
transversions>gaps.
quences (four of which overlap) can be found (Fig. 3). These A+T-rich sequences might be involved in mRNA stability. (2) Richness in A+T exclusive sequences Our attention focused on elements rich in A+T, such as: 22-nt: TAAATTTTATTTAAAAAAAATA (64-85); 1 lnt: AAATATTAAAA (167- 177); 20-nt: AAATAAAATAAATAAATAAA (526-545); 9-nt: ATTTTATTT (816824); 13-nt: ATAATTTTATTAT (968-980); 12-nt: ATTTTTTTTTTA (1163-l 174); 14-nt: TATAAAAAAATAAT (1304-1317); lo-nt: AATTATTTAT (1322-1331); 30-nt: AATATAAAAT(G)TTAAAAAAAAAAAATAAAA (1373-1402); 18-nt: TTTAAATTTTATTTATTA (1756-1773). The role of these A+T-rich motifs is presently unknown. It was suggested that A+T-rich motifs such as ATTTA could play some part in the instability of mRNAs (Caput et al., 1986; Shaw et al., 1986; Wilson and Treisman, 1988;
246 Brawerman 1989) or else could be repressive elements decreasing translation efficiency (Kruys et al., 1987; 1989; Han et al., 1990). They presumably play a role in the secondary or tertiary structure of RNA and might be involved, whether directly or indirectly, in the recognition of mRNA by specific degradation endonucleases. It must be pointed out that the consensus sequence AATAAATAAATAAA,
which has been described
(Reeves
and Magnuson, 1990) in the 3’-untranslated region of a variety of genes involved in cellular stimulation (lymphokines, cytokines and proto-oncogenes), is also found in rat (nt 1692-1705). The half-life of LPL mRNA in different species is poorly documented. In view of the present results, it would be interesting to study the stability of all these mRNA and to investigate
the role of their A+T-rich
Han, J., Brown, T. and Beutler, B.: Endotoxin-responsive trol cachectin/tumor necrosis factor biosynthesis level.: J. Exp. Med. 171 (1990) 465-475. Kalb, V.F., Glasser, tive elements
S., King, D. and Lingrel, J.B.: A cluster of repeti-
within a 700 base pair region in the mouse gcnome.
Nucleic Acids Res. 11 (1983) 2177-2184. Kirchgessner,
T.G.,
sequence
Svenson,
of cDNA
K.L., Lusis, A.J. and Schotz,
encoding
lipoprotein
M.C.: The
lipase. J. Biol. Chem.
262
C., Etienne, J., Guilhot,
S.,
(1987) 8463-8466. Kirchgessncr,
T.G., Chuat, J.C., Heinzmann,
Svenson,
K., Ameis, D., Pilon, C., D’Auriol,
M.C., Galibert,
L., Andalibi,
F. and Lusis, A.: Organization
A., Schotz,
of the human
lipo-
protein lipase gene and evolution of the lipase gene family. Proc. Natl. Acad.
Sci. USA 86 (1989) 9647-9651.
Kruys, V., Wathelet,
M., Poupart,
P., Contreras,
J. and Huez, G.: The 3’ untranslated beta mRNA has an inhibitory
R., Fiers, W., Content,
region of the human interferon-
effect on translation.
Proc. Natl. Acad.
Sci. USA 84 (1987) 6030. Kruys, V., Marinx,
sequences.
sequence con-
at the translational
lational
O., Shaw, G., Deschamps,
blockade
imposed
J. and Huez, G.: Trans-
by cytokines-derived
UA-rich
sequcnccs.
Science 245 (1989) 852-855. Miyamoto,
ACKNOWLEDGEMENTS
M.M.,
Slightom,
tions of humans
We thank Dr. Michel Bouillot (Genset) for his stimulating participation in the construction of the synthetic probe. This work was supported by grants from Institut National de la Sante et de la Recherche Mtdicale (grant 900 203 to J.E.) and from the Centre National de la Recherche Scientifique through UPR41. We thank Beatrice Pelletier for typing the manuscript.
globin region. Olivecrona,
J.L. and Goodman,
and African
rela-
in the $n-
Science 238 (1987) 369-373.
T. and Bcngtsson-Olivecrona,
milk-the model enzyme in lipoprotein J. (Ed.),
M.: Phylogenetic
apes from DNA sequences
Lipoprotein
Lipase.
G.: Lipoprotein lipasc research.
Evener
lipase from
In: Borensztajn,
Publishers,
Chicago,
1987,
pp. 15-28. Quentin,
Y.: Succcssivc
history. Reeves,
waves of fixation of B 1 variants
R. and Magnuson,
pression
in rodent lineage
J. Mol. Erol. 28 (1989) 299-305. N.S.:
of mammalian
Mechanisms
cytokine
regulating
transient
genes and cellular oncogenes.
exProg.
Nucleic Acid. Res. Mol. Biol. 38 (1990) 241-282. Sanger, F., Nicklen,
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Deeb, S.S. and Peng, R.: Structure of the human lipoprotein Biochemistry 28 (1989) 4131-4135.
lipase gene.
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