Krystyna Mozdzanowska

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.

Induction of influenza type A virus-specific resistance by immunization of mice with a synthetic multiple antigenic peptide vaccine that contains ectodomains of matrix protein 2.

Matix protein 2 (M2) is a transmembrane protein of influenza type A virus. It contains a 23 aa long ectodomain (M2e) that is highly conserved amongst human influenza type A viruses. M2e-specific antibodies have been shown to restrict virus growth in vitro and in vivo and thus have the potential of providing cross-reactive resistance to influenza type A virus infection. We attempted to induce M2e-specific protection with synthetic multiple antigen peptide (MAP) constructs that contained covalently linked M2e- and Th-determinant peptides. Mice, vaccinated twice by the intranasal (i.n.) route with adjuvanted M2e-MAPs exhibited significant resistance to virus replication in all sites of the respiratory tract. Compared to mice primed by two consecutive heterosubtypic infections, resistance was of similar strength in nasal and tracheal tissue but lower in pulmonary tissue. Importantly, the protection in M2e-MAP- and infection-immunized mice appeared to be mediated by distinct immune mechanisms. This suggests that stronger protection may be achievable by combining both protective activities.

Prospects for universal influenza virus vaccine.

The current vaccination strategy against influenza A and B viruses is vulnerable to the unanticipated emergence of epidemic strains that are poorly matched by the vaccine. A vaccine that is less sensitive to the antigenic evolution of the virus would be a major improvement. The general feasibility of this goal is supported by studies in animal models that show that immunologic activities directed against relatively invariant viral determinants can reduce illness and death. The most promising approaches are based on antibodies specific for the relatively conserved ectodomain of matrix protein 2 and the intersubunit region of hemagglutinin. However, additional conserved determinants for protective antibodies are likely to exist, and their identification should be encouraged. Most importantly, infection and current vaccines do not appear to effectively induce these antibodies in humans. This finding provides a powerful rationale for testing the protective activity of these relatively conserved viral components in humans.

Influenza A virus infection engenders a poor antibody response against the ectodomain of matrix protein 2

BackgroundMatrix protein 2 (M2) is an integral tetrameric membrane protein of influenza A virus (IAV). Its ectodomain (M2e) shows remarkably little diversity amongst human IAV strains. As M2e-specific antibodies (Abs) have been shown to reduce the severity of infection in animals, M2e is being studied for its capability of providing protection against a broad range of IAV strains. Presently, there is little information about the concentration of M2e-specific Abs in humans. Two previous studies made use of ELISA and Western blot against M2e peptides and recombinant M2 protein as immunosorbents, respectively, and reported Ab titers to be low or undetectable. An important caveat is that these assays may not have detected all Abs capable of binding to native tetrameric M2e. Therefore, we developed an assay likely to detect all M2e tetramer-specific Abs.ResultsWe generated a HeLa cell line that expressed full length tetrameric M2 (HeLa-M2) or empty vector (HeLa-C10) under the control of the tetracycline response element. These cell lines were then used in parallel as immunosorbents in ELISA. The assay was standardized and M2e-specific Ab titers quantified by means of purified murine or chimeric (mouse variable regions, human constant regions) M2e-specific Abs in the analysis of mouse and human sera, respectively. We found that the cell-based ELISA was substantially more effective than immobilized M2e peptide in detecting M2e-specific Abs in sera of mice that had recovered from repetitive IAV infections. Still, titers remained low (< 5 μg/ml) even after two consecutive infections but increased to ~50 μg/ml after the third infection. Competition with free M2e peptide indicated that ~20% of M2e-specific Abs engendered by infection reacted with M2e peptide. In humans presenting with naturally acquired influenza virus infection, 11 of 24 paired sera showed a ≥ 4-fold increase in M2e-specific Ab titer. The Ab response appeared to be of short duration as titers were very low (average 0.2 μg/ml) in all patients at onset of infection and in controls, in spite of evidence for previous exposure to IAV.ConclusionThe results provide convincing evidence that M2e-specific Ab-mediated protection is currently lacking or suboptimal in humans.

Influenza Type A Virus Escape Mutants Emerge In Vivo in the Presence of Antibodies to the Ectodomain of Matrix Protein 2

ABSTRACT The ectodomain of matrix protein 2 (M2e) of human influenza type A virus strains has remained remarkably conserved since 1918. Because M2e-specific immunity has been shown to decrease morbidity and mortality associated with influenza virus infection in several animal models and because natural infection and current vaccines do not appear to induce a good M2e-specific antibody (Ab) response, M2e has been considered as potential vaccine for inducing cross-reactive protection against influenza type A viruses. The high degree of structural conservation of M2e could in part be the consequence of a poor M2e-specific Ab response and thus the absence of pressure for change. To assess this possibility, we studied the course of infection in SCID mice in the presence or absence of passive M2e-specific monoclonal Abs (MAbs). We found that virus mutants with antigenic changes in M2e emerged in 65% of virus-infected mice treated with M2e-specific but not control MAbs. However, the diversity of escape mutants was highly restricted since only two types were isolated from 22 mice, one with a proline-to-leucine and the other with a proline-to-histidine interchange at amino acid position 10 of M2e. The implications of these findings for the use of M2e as a broadly protective vaccine are discussed.

Th Cell-Deficient Mice Control Influenza Virus Infection More Effectively Than Th- and B Cell-Deficient Mice: Evidence for a Th-Independent Contribution by B Cells to Virus Clearance

The notion that MHC class I- restricted CD8+ T (Tc) cells are capable of resolving autonomously infections with influenza virus is based largely on studies testing virus strains of low pathogenicity in CD4+ T (Th) cell-deficient/depleted mice. To test whether this holds also for pathogenic strains and to exclude possible contributions by B cells, we analyzed PR8 infection in Th cell-depleted B cell-deficient (μMT) mice. These mice, termed μMT (−CD4), showed 80% mortality after infection with a small dose of PR8, which resulted in insignificant mortality in intact or Th cell-depleted BALB/c mice. Infection of μMT(−CD4) mice with a virus of low pathogenicity was resolved without mortality, but, compared with intact BALB/c mice, with delay of ∼5 and ∼20 days from lung and nose, respectively. The low mortality of Th cell-depleted BALB/c mice suggested that B cells contributed to recovery in a Th-independent manner. This was verified by showing that transfer of 8–10 million T cell-depleted naive spleen cells into μMT(−CD4) mice 1 day before infection reduced mortality to 0%. The mechanism by which B cells improved recovery was investigated. We found no evidence that they operated by improving the lung-associated Tc response. Treatment of infected μMT(−CD4) mice with normal mouse serum spiked with hemagglutinin-specific IgM did not reduce mortality. Taken together, the data show that 1) the Tc response is capable of resolving autonomously (in conjunction with innate defenses) influenza virus infections, although with substantial delay compared with intact mice, and 2) B cells can contribute to recovery by a Th-independent mechanism.

Complement Component C1q Enhances the Biological Activity of Influenza Virus Hemagglutinin-Specific Antibodies Depending on Their Fine Antigen Specificity and Heavy-Chain Isotype

ABSTRACT We have previously observed that selected influenza virus hemagglutinin (HA)-specific monoclonal antibodies (MAbs) with poor virus-neutralizing (VN) activity in vitro exhibited greatly enhanced VN activity in vivo after administration to SCID mice. The same Abs displayed improved VN activity also when tested in vitro in the presence of noninactivated serum from SCID mice. To identify Ab-dependent properties and serum components that contributed to enhancement of Ab activity, we screened a large panel of HA-specific MAbs for hemagglutination inhibition (HI) in the presence of noninactivated serum from naive mice (NMS). We found that HI activity was enhanced by NMS depending on the Ab’s fine specificity (antigenic region Cb/E > Ca/A,D > Sa,Sb/B), its heavy-chain isotype (immunoglobulin G2 [IgG2] > IgG3; IgG1 and IgM negative), and to some extent also on its derivation (primary response > memory response). On average, the HI activity of Cb/E-specific MAbs of the IgG2 isotype isolated from the primary response was enhanced by 20-fold. VN activity was enhanced significantly but less strongly than HI activity. Enhancement (i) was destroyed by heat inactivation (30 min, 56°C); (ii) did not require C3, the central complement component; (iii) was abolished by treatment of serum with anti-C1q; and (iv) could be reproduced with purified C1q, the binding moiety of C1, the first complement component. We believe that this is the first description of a direct C1q-mediated enhancement of antiviral Ab activities.

Cooperativity Between CD8+ T Cells, Non-Neutralizing Antibodies, and Alveolar Macrophages Is Important for Heterosubtypic Influenza Virus Immunity

Seasonal epidemics of influenza virus result in ∼36,000 deaths annually in the United States. Current vaccines against influenza virus elicit an antibody response specific for the envelope glycoproteins. However, high mutation rates result in the emergence of new viral serotypes, which elude neutralization by preexisting antibodies. T lymphocytes have been reported to be capable of mediating heterosubtypic protection through recognition of internal, more conserved, influenza virus proteins. Here, we demonstrate using a recombinant influenza virus expressing the LCMV GP33-41 epitope that influenza virus-specific CD8+ T cells and virus-specific non-neutralizing antibodies each are relatively ineffective at conferring heterosubtypic protective immunity alone. However, when combined virus-specific CD8 T cells and non-neutralizing antibodies cooperatively elicit robust protective immunity. This synergistic improvement in protective immunity is dependent, at least in part, on alveolar macrophages and/or other lung phagocytes. Overall, our studies suggest that an influenza vaccine capable of eliciting both CD8+ T cells and antibodies specific for highly conserved influenza proteins may be able to provide heterosubtypic protection in humans, and act as the basis for a potential “universal” vaccine.

Roles of CD4+ T-cell-independent and -dependent antibody responses in the control of influenza virus infection: evidence for noncognate CD4+ T-cell activities that enhance the therapeutic activity of antiviral antibodies.

ABSTRACT Previous studies have indicated that B cells make a significant contribution to the resolution of influenza virus infection. To determine how B cells participate in the control of the infection, we transferred intact, major histocompatibility complex class II (MHC-II)-negative or B-cell receptor (BCR)-transgenic spleen cells into B-cell-deficient and CD8+ T-cell-depleted μMT mice, termed μMT(−8), and tested them for ability to recover from infection. μMT(−8) mice that received no spleen cells invariably succumbed to the infection within 20 days, indicating that CD4+ T-cell activities had no significant therapeutic activity on their own; in fact, they were harmful and decreased survival time. Interestingly, however, they became beneficial in the presence of antiviral antibody (Ab). Injection of MHC-II(−/−) spleen cells, which can provide CD4+ T-cell-independent (TI) but not T-cell-dependent (TD) activities, delayed mortality but only rarely resulted in clearance of the infection. By contrast, 80% of μMT(−8) mice injected with normal spleen cells survived and resolved the infection. Transfer of BCR-transgenic spleen cells, which contained ∼10 times fewer virus-specific precursor B cells than normal spleen cells, had no significant impact on the course of the infection. Taken together, the results suggest that B cells contribute to the control of the infection mainly through production of virus-specific Abs and that the TD Ab response is therapeutically more effective than the TI response. In addition, CD4+ T cells appear to contribute, apart from promoting the TD Ab response, by improving the therapeutic activity of Ab-mediated effector mechanisms.

Roles of adjuvant and route of vaccination in antibody response and protection engendered by a synthetic matrix protein 2-based influenza A virus vaccine in the mouse

BackgroundThe M2 ectodomain (M2e) of influenza A virus (IAV) strains that have circulated in humans during the past 90 years shows remarkably little structural diversity. Since M2e-specific antibodies (Abs) are capable of restricting IAV replication in vivo but are present only at minimal concentration in human sera, efforts are being made to develop a M2e-specific vaccine. We are exploring a synthetic multiple antigenic peptide (MAP) vaccine and here report on the role of adjuvants (cholera toxin and immunostimulatory oligodeoxynucleotide) and route of immunization on Ab response and strength of protection.ResultsIndependent of adjuvants and immunization route, on average 87% of the M2e-MAP-induced Abs were specific for M2e peptide and a variable fraction of these M2e(pep)-specific Abs (average 15%) cross-reacted with presumably native M2e expressed by M2-transfected cells. The titer of these cross-reactive M2e(pep-nat)-specific Abs in sera of parenterally immunized mice displayed a sigmoidal relation to level of protection, with EC50 of ~20 μg Ab/ml serum, though experiments with passive M2e(pep-nat) Abs indicated that serum Abs did not fully account for protection in parenterally vaccinated mice, particularly in upper airways. Intranasal vaccination engendered stronger protection and a higher proportion of G2a Abs than parenteral vaccination, and the strength of protection failed to correlate with M2e(pep-nat)-specific serum Ab titers, suggesting a role of airway-associated immunity in protection of intranasally vaccinated mice. Intranasal administration of M2e-MAP without adjuvant engendered no response but coadministration with infectious IAV slightly enhanced the M2e(pep-nat) Ab response and protection compared to vaccination with IAV or adjuvanted M2e-MAP alone.ConclusionM2e-MAP is an effective immunogen as ~15% of the total M2e-MAP-induced Ab response is of desired specificity. While M2e(pep-nat)-specific serum Abs have an important role in restricting virus replication in trachea and lung, M2e-specific T cells and/or locally produced Abs contribute to protection in upper airways. Intranasal vaccination is preferable to parenteral vaccination, presumably because of induction of local protective immunity by the former route. Intranasal coadministration of M2e-MAP with infectious IAV merits further investigation in view of its potential applicability to human vaccination with live attenuated IAV.