JGV Papers in Press. Published August 28, 2014 as doi:10.1099/vir.0.067736-0
Infection of influenza virus NA vaccinated mice with homologous influenza virus leads to strong protection against heterologous influenza viruses
Biao He1, Haiyan Chang1, Zhihua Liu1, Chaoyang Huang1, Xueying Liu2, Dan Zheng2, Fang Fang1, Bing Sun3 and Ze Chen1,2 * 1
College of Life Sciences, Hunan Normal University, Changsha 410081, Hunan,
China 2
Shanghai Institute of Biological Products, Shanghai 200052, China
3
Institute Pasteur of Shanghai, Shanghai Institutes for Biological Sciences, Chinese
Academy of Sciences, Shanghai 200025, China Footnotes: *
Correspondence should be addressed to Ze Chen
E-mail: [email protected]; [email protected] Phone/Fax: (00) 86-(0) 21-62826658 Address: Shanghai Institute of Biological Products, Shanghai 200052, China
Running title: NA vaccine and influenza infection lead to protection The Contents Category for the paper: Animal Viruses – Negative-strand RNA The word count of the summary: 217 The word count of the main text: 5409 The number of tables and figures: 8
1
1
Summary
2
Vaccination is the best measure to prevent influenza pandemics. Here we studied the
3
protective
4
A/reassortant/NYMC
5
A/Chicken/Jiangsu/7/2002 (H9N2) and A/Guizhou/54/89xA/PR/8/34 (A/Guizhou-X)
6
(H3N2), in mice first vaccinated with a DNA vaccine of hemagglutinin (HA) or
7
neuraminidase (NA) of A/PR/8/34 (PR8) and then infected with the homologous
8
virus. We showed that PR8 HA or NA vaccination both protected mice against a
9
lethal dose of the homologous virus; PR8 HA or NA vaccination and then PR8
10
infection in mice respectively offered poor or excellent protection against a second,
11
heterologous influenza virus challenge. In addition, before the second heterologous
12
influenza infection, the highest antibody level against the NP, M1 and M2 was found
13
in PR8 NA DNA vaccinated and PR8 infected group. The level of induced cellular
14
immunity against NP and M1 showed a trend consistent with that seen in antibody
15
levels. However, PR8HA+NA and then PR8 infection resulted in limited protection
16
against heterologous influenza virus challenges. Results of the present study
17
demonstrated that infection of the homologous influenza virus in mice already
18
immunized with a NA vaccine could provide excellent protection against subsequent
19
infection of a heterologous influenza virus. These findings suggest that NA, a major
20
antigen of influenza virus, could be an important candidate antigen for universal
21
influenza vaccines.
22
Keywords: influenza; hemagglutinin; neuraminidase; cross-protection
effect
against X-179A
heterologous (pH1N1),
23 2
influenza
viruses,
A/chicken/Henan/12/2004
including (H5N1),
24
Introduction
25
In 2009, a new influenza A (H1N1) virus epidemic broke out in humans worldwide.
26
This virus was easy to spread among humans and resulted in infections in a large
27
number of people. Fortunately, the mortality was not high (Garten et al., 2009;
28
Neumann et al., 2009). The influenza A (H5N1) virus also has brought huge threat to
29
humans; the virus has high mortality in humans but has difficulty to transmit among
30
humans and has not caused a pandemic (Sambhara and Poland, 2010).
31
In addition, in March of 2013, the first influenza A (H7N9) virus human infection
32
occurred in China (Gao et al., 2013). So far a total of 355 persons have been
33
confirmed H7N9 infection, of which 112 died (World Health Oganization,2014).
34
There has not been any solid evidence to demonstrate that H7N9 is capable of
35
human-to-human transmission. However, given the high mutation rates of influenza
36
viruses, it is possible that an influenza virus with high mortality and high
37
transmissibility will reemerge and bring a huge disaster to humans.
38
Currently the most effective method for preventing influenza virus infection is
39
influenza vaccination. Influenza virus surface proteins hemagglutinin (HA) and
40
neuraminidase (HA) are the most important antigens for eliciting immune responses
41
(Johansson et al., 1989). We have reported that in mouse models, DNA vaccines
42
based on influenza virus HA and NA proteins could provide well protection against
43
the homologous influenza virus, and the protective effects were better than other
44
influenza viral proteins (Chen et al., 2009; Chen et al., 2000; Chen et al., 1998).
45
However, HA and NA-based influenza virus vaccines have limited protection against
3
46
heterologous viruses. The influenza virus NP, M1 and M2 proteins are highly
47
conserved, and vaccines based on these proteins showed some protection against
48
heterologous influenza viruses in mouse models (Epstein et al., 2005; Guo et al.,
49
2010; Neirynck et al., 1999; Sui et al., 2010a; Sui et al., 2010b). Existing influenza
50
vaccines mainly rely on HA and NA of influenza viruses. The World Health
51
Organization must regularly change vaccine composition in response to immune
52
escape of HA and NA proteins (Carrat and Flahault, 2007), which not only increases
53
the burden of vaccine production, but also places people in a passive position in the
54
face of new influenza viruses.
55
Previously, it has been reported that influenza virus infection could result in
56
cross-protection. For example, H3N2 infection of mice could induce protective
57
immunity against H5N1 (Kreijtz et al., 2009). In another study, infection of mice with
58
H1 and H3 influenza viruses could protect them against a challenge by the
59
heterologous 2009 H1N1 A/CA/04/09 influenza virus, and it has been demonstrated
60
that the protection is mediated by T-cell immunity (Guo et al., 2011). In addition,
61
cross-protection mediated by T cell immunity against influenza viruses has also been
62
confirmed in pigs, chickens, ducks and ferrets (Carter et al., 2013; Fereidouni et al.,
63
2009; Heinen et al., 2001; Seo and Webster, 2001).
64
In the present study, we demonstrated in mouse model that vaccination with a DNA
65
vaccine of influenza virus NA gene could not only protect mice against infection by
66
the homologous influenza virus, but also protect well against infection by a second,
67
heterologous influenza virus. However, mice vaccinated with a DNA vaccine of
4
68
influenza virus HA gene offered limited protection against infection of a second,
69
heterologous influenza virus. These results suggest that NA, a major antigen of
70
influenza virus, could be used as an important candidate antigen for universal
71
influenza vaccines.
72 73
Results
74
Protection of DNA vaccines based on PR8 HA, NA, and HA+NA against a lethal
75
dose of PR8 infections
76
Mice were divided into eight groups. The group names, vaccination contents and
77
schedule, and challenge schedule are shown in Table 1. On day 3 and 5 after PR8
78
infections, mice lung lavage fluids were collected for virus titer detection. The
79
survival rates for the HAP, NAP and HNP groups was all 100 % (Table 2), and no
80
symptoms of influenza virus infection were observed. All of the C1 group mice died
81
within 10 days post-infection. For the lung virus load at day 3 post infection, no
82
influenza virus was detected in MDCK cells using lung lavage from the HAP and
83
HNP group, while lung virus titer for the NAP group and C1 group mice were 1.4 ±
84
0.1 log10TCID50/ml and 4.35 ± 0.35 log10TCID50/ml, respectively, but the titer in NAP
85
group was significantly lower (P
Infection of influenza virus NA vaccinated mice with homologous influenza virus leads to strong protection against heterologous influenza viruses
Biao He1, Haiyan Chang1, Zhihua Liu1, Chaoyang Huang1, Xueying Liu2, Dan Zheng2, Fang Fang1, Bing Sun3 and Ze Chen1,2 * 1
College of Life Sciences, Hunan Normal University, Changsha 410081, Hunan,
China 2
Shanghai Institute of Biological Products, Shanghai 200052, China
3
Institute Pasteur of Shanghai, Shanghai Institutes for Biological Sciences, Chinese
Academy of Sciences, Shanghai 200025, China Footnotes: *
Correspondence should be addressed to Ze Chen
E-mail: [email protected]; [email protected] Phone/Fax: (00) 86-(0) 21-62826658 Address: Shanghai Institute of Biological Products, Shanghai 200052, China
Running title: NA vaccine and influenza infection lead to protection The Contents Category for the paper: Animal Viruses – Negative-strand RNA The word count of the summary: 217 The word count of the main text: 5409 The number of tables and figures: 8
1
1
Summary
2
Vaccination is the best measure to prevent influenza pandemics. Here we studied the
3
protective
4
A/reassortant/NYMC
5
A/Chicken/Jiangsu/7/2002 (H9N2) and A/Guizhou/54/89xA/PR/8/34 (A/Guizhou-X)
6
(H3N2), in mice first vaccinated with a DNA vaccine of hemagglutinin (HA) or
7
neuraminidase (NA) of A/PR/8/34 (PR8) and then infected with the homologous
8
virus. We showed that PR8 HA or NA vaccination both protected mice against a
9
lethal dose of the homologous virus; PR8 HA or NA vaccination and then PR8
10
infection in mice respectively offered poor or excellent protection against a second,
11
heterologous influenza virus challenge. In addition, before the second heterologous
12
influenza infection, the highest antibody level against the NP, M1 and M2 was found
13
in PR8 NA DNA vaccinated and PR8 infected group. The level of induced cellular
14
immunity against NP and M1 showed a trend consistent with that seen in antibody
15
levels. However, PR8HA+NA and then PR8 infection resulted in limited protection
16
against heterologous influenza virus challenges. Results of the present study
17
demonstrated that infection of the homologous influenza virus in mice already
18
immunized with a NA vaccine could provide excellent protection against subsequent
19
infection of a heterologous influenza virus. These findings suggest that NA, a major
20
antigen of influenza virus, could be an important candidate antigen for universal
21
influenza vaccines.
22
Keywords: influenza; hemagglutinin; neuraminidase; cross-protection
effect
against X-179A
heterologous (pH1N1),
23 2
influenza
viruses,
A/chicken/Henan/12/2004
including (H5N1),
24
Introduction
25
In 2009, a new influenza A (H1N1) virus epidemic broke out in humans worldwide.
26
This virus was easy to spread among humans and resulted in infections in a large
27
number of people. Fortunately, the mortality was not high (Garten et al., 2009;
28
Neumann et al., 2009). The influenza A (H5N1) virus also has brought huge threat to
29
humans; the virus has high mortality in humans but has difficulty to transmit among
30
humans and has not caused a pandemic (Sambhara and Poland, 2010).
31
In addition, in March of 2013, the first influenza A (H7N9) virus human infection
32
occurred in China (Gao et al., 2013). So far a total of 355 persons have been
33
confirmed H7N9 infection, of which 112 died (World Health Oganization,2014).
34
There has not been any solid evidence to demonstrate that H7N9 is capable of
35
human-to-human transmission. However, given the high mutation rates of influenza
36
viruses, it is possible that an influenza virus with high mortality and high
37
transmissibility will reemerge and bring a huge disaster to humans.
38
Currently the most effective method for preventing influenza virus infection is
39
influenza vaccination. Influenza virus surface proteins hemagglutinin (HA) and
40
neuraminidase (HA) are the most important antigens for eliciting immune responses
41
(Johansson et al., 1989). We have reported that in mouse models, DNA vaccines
42
based on influenza virus HA and NA proteins could provide well protection against
43
the homologous influenza virus, and the protective effects were better than other
44
influenza viral proteins (Chen et al., 2009; Chen et al., 2000; Chen et al., 1998).
45
However, HA and NA-based influenza virus vaccines have limited protection against
3
46
heterologous viruses. The influenza virus NP, M1 and M2 proteins are highly
47
conserved, and vaccines based on these proteins showed some protection against
48
heterologous influenza viruses in mouse models (Epstein et al., 2005; Guo et al.,
49
2010; Neirynck et al., 1999; Sui et al., 2010a; Sui et al., 2010b). Existing influenza
50
vaccines mainly rely on HA and NA of influenza viruses. The World Health
51
Organization must regularly change vaccine composition in response to immune
52
escape of HA and NA proteins (Carrat and Flahault, 2007), which not only increases
53
the burden of vaccine production, but also places people in a passive position in the
54
face of new influenza viruses.
55
Previously, it has been reported that influenza virus infection could result in
56
cross-protection. For example, H3N2 infection of mice could induce protective
57
immunity against H5N1 (Kreijtz et al., 2009). In another study, infection of mice with
58
H1 and H3 influenza viruses could protect them against a challenge by the
59
heterologous 2009 H1N1 A/CA/04/09 influenza virus, and it has been demonstrated
60
that the protection is mediated by T-cell immunity (Guo et al., 2011). In addition,
61
cross-protection mediated by T cell immunity against influenza viruses has also been
62
confirmed in pigs, chickens, ducks and ferrets (Carter et al., 2013; Fereidouni et al.,
63
2009; Heinen et al., 2001; Seo and Webster, 2001).
64
In the present study, we demonstrated in mouse model that vaccination with a DNA
65
vaccine of influenza virus NA gene could not only protect mice against infection by
66
the homologous influenza virus, but also protect well against infection by a second,
67
heterologous influenza virus. However, mice vaccinated with a DNA vaccine of
4
68
influenza virus HA gene offered limited protection against infection of a second,
69
heterologous influenza virus. These results suggest that NA, a major antigen of
70
influenza virus, could be used as an important candidate antigen for universal
71
influenza vaccines.
72 73
Results
74
Protection of DNA vaccines based on PR8 HA, NA, and HA+NA against a lethal
75
dose of PR8 infections
76
Mice were divided into eight groups. The group names, vaccination contents and
77
schedule, and challenge schedule are shown in Table 1. On day 3 and 5 after PR8
78
infections, mice lung lavage fluids were collected for virus titer detection. The
79
survival rates for the HAP, NAP and HNP groups was all 100 % (Table 2), and no
80
symptoms of influenza virus infection were observed. All of the C1 group mice died
81
within 10 days post-infection. For the lung virus load at day 3 post infection, no
82
influenza virus was detected in MDCK cells using lung lavage from the HAP and
83
HNP group, while lung virus titer for the NAP group and C1 group mice were 1.4 ±
84
0.1 log10TCID50/ml and 4.35 ± 0.35 log10TCID50/ml, respectively, but the titer in NAP
85
group was significantly lower (P
