Role of IgM antibodies versus B cells in influenza virus-specific immunity

We have compared the role of IgM antibodies with the role of B cells in control of primary influenza virus infection. Mice deficient in IgM (IgM(-/-)), but capable of producing other Igisotypes, exhibited increased pulmonary virus titers compared to wild-type mice. However, IgM(-/-) mice were less susceptible compared to B cell-deficient micro MT) mice. CD4(+) T cells from spleen and lung draining lymph nodes of infected micro MT mice showed reduced proliferation upon virus re-stimulation in vitro. Furthermore, numbers of IFN-gamma-producing CD4(+) effector T cells were reduced in the alveolar lavage (BAL) of micro MT mice but not IgM(-/-) mice. In contrast, total number of virus-specific CTL was almost comparable in BAL of micro MT and wild-type mice. Pulmonary recruitment of inflammatory macrophages and neutrophils occurred normally in both micro MT and IgM(-/-) mice. Interestingly, virus-specific IgG2a and IgG2b antibody responses were affected locally in the BAL and in the serum of IgM(-/-) mice, while IgG1 responses remained largely normal. Taken together, our data suggest a role for B cells to promote effector T cell responses and a role of both IgM and IgG antibodies in the defense against acute influenza virus infection.     

Anti-viral immunity induced by recombinant nucleoprotein of influenza A virus. II. Protection from influenza infection and mechanism of protection

Protection against influenza A virus infection in mice immunized with recombinant nucleoprotein (rNP) was studied. Nucleoprotein-immune mice were protected against a lethal challenge with A/Puerto Rico/8/34 (A/PR8) virus but showed considerable morbidity before recovery. Local boosting of the immune system with rNP by intranasal immunization improved the protection in NP-immune mice, and the decrease in morbidity after infection was reflected in accelerated clearance of virus from lungs. However, immune, boosted mice also rapidly cleared an antigenically unrelated influenza B virus from their lungs. Mice immunized with rNP precipitated with alhydrogel, that subsequently developed significant resistance to virus infection, failed to generate detectable levels of class I major histocompatibility complex (MHC)-restricted killer cells. Furthermore, B10.A(5R) mice that are non-responders for NP-specific class I killer cells could also be protected by immunization with rNP. In contrast, rNP-immunized mice developed strong proliferative T-cell responses to rNP. These data argue for an important role for helper T cells rather than virus-specific class I cytotoxic T cells in protection against influenza virus infection induced by rNP.     

Antibody production and protection against influenza virus in immunodeficient mice.

The roles of T and B cells in the immune response to influenza virus were studied by using mice deficient in either T cells (athymic nude) or immunoglobulin production (CBA/N). The serological responses of these mice to either whole or disrupted A/Aichi/2/68 influenza virus vaccines were examined, and the protective effect of these inoculations was tested by challenge infection with mouse-adapted A/Aichi/2/68 influenza virus. In contrast to normal mice, neither strain of immunodeficient mouse produced detectable serum antibody after inoculation with either type of vaccine. CBA/N mice immunized with intact virus vaccine were protected, however, against subsequent lethal challenge. CBA/N mice inoculated with disrupted virus vaccine and nude mice inoculated with either disrupted or whole virus vaccine were not protected against viral challenge. Evidence of immunological memory was observed in CBA/N and nude mice that had survived live virus challenge after immunization with inactivated vaccine.     

Influence of type 2 T cell responses on the severity of encephalitis associated with influenza virus infection

The role of type 2 T cell responses on the severity of post-infectious encephalitis was investigated in a mouse model of influenza virus infection. When mice were infected intracerebrally with 3.0 LD(50) of A/NWS33 strain of influenza virus, they all showed clinical signs of encephalitis, and 90% of them died within 10 days of the infection. However, the post-infectious encephalitis was not demonstrated in mice exposed to 0.5 LD50 of the same virus. The mortality rates of mice infected with 0.5 LD(50) of the virus were increased to levels observed in mice exposed to 3.0 LD(50) of influenza virus infection, after the administration of a mixture of interleukin (IL)-4 and IL-10 (2 ng/mouse each; immediately, 1 and 2 days after the infection). In contrast, mortality rates of mice exposed to 3.0 LD(50) of influenza virus were substantially decreased when these mice were treated with a mixture of monoclonal antibodies directed against IL-4 and IL-10. A predominance of type 2 T cell responses was demonstrated in splenic T cells of mice infected with 3.0 LD(50) of influenza virus, although these responses were minimal in mice infected with 0.5 LD(50) of the virus. After the treatment with the mixture of type 2 cytokines, an increase in the type 2 T cell responses in mice exposed to 0.5 LD(50) of the virus was shown. These results indicate that type 2 T cell responses associated with the viral infection play an important role in the severity of post-infectious encephalitis induced in mice by the intracerebral infection of influenza A virus.     

Immunoglobulin A-deficient mice exhibit altered T helper 1-type immune responses but retain mucosal immunity to influenza virus

We have previously demonstrated that immunoglobulin A (IgA)(-/-) knockout (KO) mice exhibit levels of susceptibility to influenza virus infection that are similar to those of their normal IgA(+/+) littermates. To understand the mechanism of this apparent mucosal immunity without IgA, immunoglobulin isotype and T helper 1 (Th1)-type [interferon-gamma (IFN-gamma)] and Th2-type [interleukin (IL)-4, IL-5)] cytokine responses to influenza vaccine were evaluated. Intranasal immunization with influenza virus subunit vaccine plus cholera toxin/cholera toxin B subunit (CT/CTB) induced significant influenza virus-specific immunoglobulin G (IgG) antibody in the serum and nasal passages of both IgA(-/-) and IgA(+/+) mice, while IgA antibodies were induced only in IgA(+/+) mice. IgA KO mice exhibited an IgG1 subclass haemagglutinin (HA)-specific response but no detectable IgG2a and IgG2b responses. In contrast, IgA(+/+) mice exhibited significant IgG1 as well as IgG2a responses. This indicates a predominant Th2-type response in IgA KO mice compared to normal mice. Following stimulation with influenza virus in vitro, splenic lymphocytes from immunized IgA(-/-) mice produced significantly lower levels of IFN-gamma than IgA(+/+) mice (P < 0.001), but elaborated similar levels of IL-4 and IL-5. This was true at both protein and mRNA levels. Immunized mice were challenged intranasally with a small inoculum of influenza virus to allow deposition of virus in the nasal mucosal passages. Compared to non-immunized mice, immunized IgA(-/-) and IgA(+/+) mice exhibited significant, but similar levels of reduction in virus titres in the nose and lung. These results demonstrate that in addition to IgA deficiency, IgA gene deletion also resulted in down-regulated Th1-type immune responses and confirm our previous data that IgA antibody is not indispensable for the prevention of influenza virus infection.     

Distinct requirements for IL-6 in polyclonal and specific Ig production induced by microorganisms

The role of IL-6 in Ig production induced in the mouse by lactate dehydrogenase-elevating virus (LDV), Toxoplasma gondii or lipopolysaccharide (LPS) was assessed. Following infection with LDV, a strong activator of B cells, an early and transient IL-6 production was observed, that originated predominantly from macrophages. Whereas LDV-induced B lymphocyte proliferation appeared independent of IL-6, mice deficient for this cytokine showed a marked reduction in their total T-dependent IgG2a production when compared to their normal counterparts. By contrast, specific responses directed against either LDV or non-viral antigens administered at the time of infection were not decreased in the absence of IL-6. Similarly, polyclonal, but not anti-parasite IgG2a production triggered by T. gondii infection was strongly dependent on the presence of IL-6. Finally, T-independent total IgG3 secretion triggered by LPS was also markedly reduced in IL-6-deficient mice. These results suggest that IL-6 plays a major role in T-dependent and T-independent polyclonal Ig production following B lymphocyte activation by viruses, and parasites, but not in specific antibody responses induced by the same microorganisms.     

Enhanced resistancy of thioredoxin-transgenic mice against influenza virus-induced pneumonia

Thioredoxin (TRX) is a small redox-active protein with anti-oxidant effect and redox-regulating functions. Using TRX transgenic (Tg) mice in which human TRX is overexpressed systemically under the control of beta-actin promoter, the effects of influenza virus infection were examined in TRX Tg mice and wild type C57BL/6 mice. (1) Median lethal dose (LD50) against influenza virus infection in wild-type C57BL/6 mice was 10(-5.3) dilution, while that of TRX Tg mice was 10(-4.2) dilution. Thus, TRX Tg mice were more resistant against the virus infection than wild-type mice. (2) The body weights of wild-type mice 7 days after infection with a sublethal dose of the virus (10(-6) dilution) decreased significantly, whereas those of TRX Tg mice increased slightly. (3) Histopathology of the lung at 3 weeks after sublethal infection of influenza virus showed that severe alveolar or bronchiolar destruction was observed in wild-type mice, while mild viral pneumonia was seen in the TRX Tg mice. (4) Local (IgA) and systemic (IgG) antibody productions against influenza virus hemagglutinin in mice surviving 3 weeks after infection were similar between wild-type and TRX Tg mice. These results indicate that overexpression of TRX in Tg mice suppresses the inflammatory overshoot of viral pneumonia caused by influenza virus infection, resulting in the reduction of mortality without affecting the host's systemic immune responses to the infection. TRX may play some important roles in regulating the inflammatory process in the primary host defense against infection.     

APRIL facilitates viral-induced erythroleukemia but is dispensable for T cell immunity and lymphomagenesis

The TNF family member, a proliferation-inducing ligand (APRIL), has been suggested to act as a costimulatory molecule in T cell responses. However, studies addressing this role in vivo are largely lacking. Here, we evaluated the effects of APRIL on physiological T cell responses in vivo. Although receptors for APRIL are expressed on a subset of T cells, neither TCR transgenic (Tg) T cell responses nor endogenous TCR responses were affected by Tg APRIL expression in vivo. Moreover, APRIL did not significantly enhance the induction of T cell lymphomas upon Moloney murine leukemia virus (MLV) infection. This clearly contrasts current belief and indicates that APRIL does not serve a major role in T cell immunity or lymphomagenesis. However, we did observe a strong increase in erythroleukemia formation after MLV inoculation of APRIL Tg mice. Strikingly, this erythroleukemia-facilitating property of APRIL was confirmed using the erythroleukemogenic Friend-MLV. Erythroleukemia in APRIL Tg mice was characterized by low hematocrits and grossly enlarged spleens with an increased percentage of erythroid precursors. Altogether, these results unveil new proerythroleukemogenic properties of APRIL.     

Role of the B-cell response in recovery of mice from primary influenza virus infection

Recovery from influenza virus infection has long been known to require an intact T-cell compartment. More recent studies revealed that CD8 and CD4Tcells can promote recovery through independent mechanisms. The CD4 T-cell-dependent recovery process appears to operate primarily through promotion of the T-dependent antibody response as B-cell-deficient μMT mice cannot recover from infection if they have been depleted of CDS T cells. The potential therapeutic activity of the B-cell response was further studied by transfer of antibodies into infected SCID mice. At the dose of 200 μg/mouse. most antibodies (of IgG2a isotype) to the viral transmembrane protein HA cured the infection, while those to the transmembrane proteins NA and M2 suppressed virus titers in the lung but failed to clear the infection. The ability of passive antibody to resolve the-infection was closely related to its prophylactic activity, suggesting that neutralization of progeny virus (VN) played an important role in the process of virus clearance in vivo, while reaction of antibodies with infected host cells contributed to but was insufficient, on its own for cure. HA-specific antibodies of IgM and IgA isotypes were therapeutically ineffective against pulmonary infection, presumably because of a preferential delivery into the upper respiratory tract, while IgG exhibited highest activity against pulmonary and minimal activity against nasal infection. B cells appear to be of similar importance for recovery from primary infection as CDS T cells.     

Mucosal immunization of CD4+ T cell-deficient mice with an inactivated virus induces IgG and IgA responses in serum and mucosal secretions

Immunoglobulin (Ig) class switching can occur in the absence of alphabeta+ or gammadelta+ T cells when mice are infected with certain live viruses, although CD4 T helper cells are believed to be essential for induction of a high-affinity antibody response and for efficient isotype switching from IgM to IgG and IgA production. However, little information is available about the immune responses after mucosal immunization of CD4+ T cell-deficient mice with inactivated virus. In this study, we show that intranasal immunization with formalin-inactivated influenza A/PR8/34 virus induces IgG and IgA responses in serum and IgA responses in mucosal secretions in CD4+ T cell-deficient mice. All four subclasses of IgG were produced. IgG1/IgG2a ratios were found to be from 1 to 1.75, indicating that both Th1 and Th2 immune responses are induced by the inactivated influenza virus. The sera and mucosal secretions were found to have neutralizing activity against influenza virus in vitro. In addition, the mucosally immunized CD4+ T cell-deficient mice were protected completely from challenge with a lethal dose of live, pathogenic influenza virus. To our knowledge, this is the first demonstration that mucosal immunization with an inactivated virus induces immune responses in serum and mucosal secretions in CD4+ T cell-deficient mice.     

Cross-protection in mice infected with influenza A virus by the respiratory route is correlated with local IgA antibody rather than serum antibody or cytotoxic T cell reactivity

Mice previously infected with an aerosol of A/Rec 31 influenza virus were strongly protected against an aerosol challenge with A/Vic influenza as judged by lung virus titers recovered 2 days after the challenge infection. Such complete homotypic immunity was not achieved by priming with live Rec 31 virus injected i.v. or UV-inactivated Rec 31 virus administered s.c. together with Al(OH)₃ and saponin. The reason for the superior protective effect of the natural infection was investigated. The protection induced by respiratory infection with Rec 31 virus was specific for influenza A viruses. It was not correlated with specific serum hemagglutination inhibition antibody titer or cross-reactive cytotoxic T (T_c) cell reactivity. Moreover, the transfer of splenic and lymphoid T cell populations with strong secondary T_c activity did not significantly reduce lung virus titers in recipient mice 3 days after infection. The protection however occurred in parallel with the presence of cross-reactive IgA antibody in the lung washings. It thus appears that local secretory IgA plays a causal role in the prevention of cross-infection by influenza A virus. Serum antibody and T_c cells, on the other hand, may be crucial for recovery from such infection. All mice primed with live Rec 31 virus, administered i.v. or by aerosol and expressing equally high levels of T_c reactivity, survived a lethal challenge with A/PR8 virus. The same challenge, however, killed half of the mice immunized s.c. with inactivated Rec 31 virus which induced only a low level of T_c reactivity.     

Cross-protection against influenza A virus infection by passively transferred respiratory tract IgA antibodies to different hemagglutinin molecules.

Mice that were intranasally immunized with different influenza A virus hemagglutinins (HA), derived from PR8 (H1N1), A/Yamagata (H1N1) or A/Fukuoka (H3N2) virus, together with cholera toxin B subunit as an adjuvant, were examined for protection against PR8 infection; PR8 HA and A/Yamagata HA immunization conferred complete protection, while A/Fukuoka HA immunization failed to confer protection. In parallel with protection, PR8 HA-, A/Yamagata HA-, and A/Fukuoka HA-immunized mice produced a high, a moderate and a low level of PR8 HA-reactive IgA in the respiratory tract, respectively. These IgA antibodies were not only higher in content in the nasal secretions, but also more cross-reactive than IgG. The purified IgA antibodies from respiratory tract washings of PR8 HA-immunized mice, which contained the HA-specific IgA corresponding to the amount detected in the nasal wash, were able to protect mice from PR8 challenge when transferred to the respiratory tract of naive mice. The transfer of IgA from A/Yamagata HA-immunized mice also afforded cross-protection against PR8 infection, whereas the IgA from A/Fukuoka HA-immunized mice failed to provide protection. The ability of transferred IgA to prevent viral infection was dependent on the amount of HA-reactive IgA remaining in the respiratory tract of the host at the time of infection. These experiments directly demonstrate that IgA antibodies to influenza A virus HA by themselves play a pivotal role in defence not only against homologous virus infection, but also against heterologous drift virus infection at the respiratory mucosa, the portal of entry for the viruses.     

Critical role of TSLP-responsive mucosal dendritic cells in the induction of nasal antigen-specific IgA response

Thymic stromal lymphopoietin (TSLP) is an interleukin-7 (IL-7)-like cytokine involved in T helper 2 type immune responses. The primary target of TSLP is myeloid dendritic cells (DCs), however, little is known about the mechanism by which TSLP elicits respiratory IgA immune responses upon mucosal immunization. Here, we found that the levels of TSLP and TSLPR were upregulated in the mucosal DCs of mice nasally immunized with pneumococcal surface protein A (PspA) plus cholera toxin (CT) compared with those immunized with PspA alone. PspA-specific IgA responses, but not IgG Ab responses were significantly reduced in both serum and mucosal secretions of TSLPR knockout mice compared with wild-type mice after nasal immunization with PspA plus CT. Furthermore, CD11c⁺ mucosal DCs isolated from TSLPR knockout mice nasally immunized with PspA plus CT were less activated and exhibited markedly reduced expression of IgA-enhancing cytokines (e.g., APRIL, BAFF, and IL-6) compared with those from equivalently immunized wild-type mice. Finally, exogenous TSLP promoted production of IgAs in an in vitro DC–B cell co-culture system as exhibited by enhanced IL-6 production. These results suggest that TSLP–TSLPR signaling is pivotal in the induction of nasal respiratory immunity against pathogenic pneumococcal infection.     

Regulation of the T-independent humoral response by TACI

TACI is a TNFR homolog expressed by mature B lymphocytes that has been implicated in the positive regulation of B cell growth and antibody production, as well as in the development of autoimmune disease. Its biology is complex due to the existence of two ligands, BLyS and APRIL, and a homologous receptor, BCMA, that similarly binds both ligands. To determine its critical biological role, we generated TACI knockout mice. Surprisingly, these mice demonstrated a 2-fold increase in numbers of circulating and splenic B cells, apparently due to increased proliferation rate. Maturation of B cells and T-dependent antibody production was normal, but responses to T-independent type II antigens were almost completely abolished. It appears that TACI provides an essential costimulatory signal for the T-independent humoral response.     

穿孔素介导的细胞凋亡机制在抗流感病毒感染免疫防御中作用的研究

目的：穿孔素介导的细胞凋亡机制在流感病毒初次感染中作用的研究。方法：用流感病毒A／PR／8／34经鼻感染穿孔素基因敲除鼠和同源对照C57BL／6小鼠，采用PFU方法测定肺内流感病毒增殖状况；免疫组织化学染色方法观察小鼠病毒感染后感染细胞的凋亡情况；利用乳酸脱氢酶释放法检测感染鼠脾淋巴细胞NK活性及CTL杀伤活性。结果：穿孔素基因缺乏导致流感病毒在小鼠肺内大量增殖；小鼠清除感染病毒所需时间延长；病毒感染细胞发生凋亡的时间亦因穿孔素的缺乏而延迟；感染小鼠脾淋巴细胞NK活性及CTL杀伤活性均显著降低。结论：穿孔素依赖的细胞介导的细胞毒效应在控制流感病毒初次感染，快速清除感染病毒方面起重要作用。     

CD59a deficiency exacerbates influenza-induced lung inflammation through complement-dependent and -independent mechanisms

Influenza-specific immune activity not only promotes virus clearance but also causes immunopathology, thereby underlining the importance of mounting a measured anti-viral immune response. Since complement bridges both the innate and adaptive immune systems and has been implicated in defence against influenza, the role of the complement regulator CD59a in modulating the response to influenza was explored. For this purpose, immune responses to influenza virus, strain E61-13-H17, in mice deficient in the complement regulator protein CD59a (Cd59a(-/-) mice) were compared to those in wild-type mice. The severity of lung inflammation was significantly enhanced in the lungs of Cd59a(-/-) mice with increased numbers of infiltrating neutrophils and CD4(+) T cells. When complement was inhibited using soluble complement receptor 1, the frequency of lung-infiltrating neutrophils in influenza-infected Cd59a(-/-) mice was much reduced whilst numbers of CD4(+) T cells remained unchanged. These results demonstrate that CD59a, previously defined as a complement regulator, modulates both the innate and adaptive immune response to influenza virus by both complement-dependent and -independent mechanisms.     

Secretory IgA antibodies provide cross-protection against infection with different strains of influenza B virus

This study examined whether secretory IgA (S-IgA) antibodies (Abs) could confer cross-protective immunity against infection with influenza B viruses of antigenically distinct lineages. Wild-type or polymeric Ig receptor (pIgR)-knockout (KO) mice were immunized by infection with different B viruses or by intranasal (i.n.) administration with different inactivated vaccines. Four weeks later mice were challenged with either the B/Ibaraki/2/85 virus, representative of the B/Victoria/2/87 (B/Victoria)-lineage, or B/Yamagata/16/88 virus, representative of the B/Yamagata-lineage. Three days after challenge, nasal wash and serum specimens were assayed for IgA and IgG Abs specific for challenge viral antigens and for protection against challenge viruses. In wild-type mice, B/Ibaraki (or B/Yamagata) cross-reactive IgA Abs were detected at higher levels when infected or immunized with homologous-lineage viruses and at lower levels when infected or immunized with heterologous-lineage viruses. There was a correlation between the amount of nasal cross-reactive IgA Ab and the efficacy of cross-protection with a homologous-lineage virus. In mice lacking the pIgR, nasal cross-protective IgA Abs were only marginally detected in vaccinated mice and an accumulation of IgA in the serum was observed. This reduction of nasal IgA was accompanied by inefficient cross-protection against the B/Ibaraki (or B/Yamagata) virus infection. These results suggest that challenge viral-antigen cross-reactive S-IgA in nasal secretions induced by i.n. infection or vaccination is involved in providing cross-protection against challenge infection with virus within either the B/Victoria- or B/Yamagata-lineage.     

Selective induction of immunological tolerance in antiviral T killer cells of inbred mice after treatment with cyclosporin A.

Primary anti-influenza A cytotoxic thymus-derived (T) and bone marrow (B) lymphocyte-dependent responses in inbred mice were used as an in vivo model system to study the effects of the immunosuppressive fungus metabolite cyclosporin A (CyA). Five consecutive daily oral applications of CyA, with the first being given 1 or 2 h before virus inoculation of the animals, caused a complete blockage of induction of anti-influenza T killer cells and a partial reduction of cytotoxic B lymphocyte activities. Adoptive cell transfer experiments revealed that incapability to respond was due neither to humoral factors nor to the generation of suppressor cells. The tolerance state appeared to be specific for influenza A; cytotoxic T lymphocytes against allogeneic cell surface determinants could be stimulated in immunosuppressed mice. CyA treatment abolished virus-specific and cross-reactive anti-influenza killer T cell responses. Suppression was of short duration: less than 1 week for B cell-dependent functions, and between 1 and 2 weeks for T killer cell responses. Animals appeared to be normal with regard to both of these cellular activities for 4 weeks after tolerance induction. Thus, the data indicate that CyA exerted preferential effects on killer T cells. Moreover, evidence was presented that CyA treatment during an ongoing influenza infection did not increase sensitivity to that virus. Mice with no measurable cytolytic anti-influenza T killer cell activities but significant B cell responses, although partially diminished by the drug, were completely protected against the lethal effects of influenza infection.     

Humoral immune responses during asthma and influenza co-morbidity in mice

Humoral immunity serve dual functions of direct pathogen neutralization and enhancement of leukocyte function. Antibody classes are determined by antigen triggers, and the resulting antibodies can contribute to disease pathogenesis and host defense. Although asthma and influenza are immunologically distinct diseases, since we have found that allergic asthma exacerbation promotes antiviral host responses to influenza A virus, we hypothesized that humoral immunity may contribute to allergic host protection during influenza. C57BL/6J mice sensitized and challenged with Aspergillus fumigatus (or not) were infected with pandemic influenza A/CA/04/2009 virus. Negative control groups included naïve mice, and mice with only ‘asthma’ or influenza. Concentrations of antibodies were quantified by ELISA, and in situ localization of IgA- and IgE-positive cells in the lungs was determined by immunohistochemistry. The number and phenotype of B cells in spleens and mediastinal lymph nodes were determined by flow cytometry at predetermined timepoints after virus infection until viral clearance. Mucosal and systemic antibodies remained elevated in mice with asthma and influenza with prominent production of IgE and IgA compared to influenza-only controls. B cell expansion was prominent in the mediastinal lymph nodes of allergic mice during influenza where most cells produced IgG₁ and IgA. Although allergy-skewed B cell responses dominated in mice with allergic airways inflammation during influenza virus infection, virus-specific antibodies were also induced. Future studies are required to identify the mechanisms involved with B cell activation and function in allergic hosts facing respiratory viral infections.     

Critical role of CXCL4 in the lung pathogenesis of influenza (H1N1) respiratory infection

Annual epidemics and unexpected pandemics of influenza are threats to human health. Lung immune and inflammatory responses, such as those induced by respiratory infection influenza virus, determine the outcome of pulmonary pathogenesis. Platelet-derived chemokine (C-X-C motif) ligand 4 (CXCL4) has an immunoregulatory role in inflammatory diseases. Here we show that CXCL4 is associated with pulmonary influenza infection and has a critical role in protecting mice from fatal H1N1 virus respiratory infection. CXCL4 knockout resulted in diminished viral clearance from the lung and decreased lung inflammation during early infection but more severe lung pathology relative to wild-type mice during late infection. Additionally, CXCL4 deficiency decreased leukocyte accumulation in the infected lung with markedly decreased neutrophil infiltration into the lung during early infection and extensive leukocyte, especially lymphocyte accumulation at the late infection stage. Loss of CXCL4 did not affect the activation of adaptive immune T and B lymphocytes during the late stage of lung infection. Further study revealed that CXCL4 deficiency inhibited neutrophil recruitment to the infected mouse lung. Thus the above results identify CXCL4 as a vital immunoregulatory chemokine essential for protecting mice against influenza A virus infection, especially as it affects the development of lung injury and neutrophil mobilization to the inflamed lung.