Matrix protein 2 vaccination and protection against influenza viruses, including subtype H5N1.Changes in influenza viruses require regular reformulation of strain-specific influenza vaccines. Vaccines based on conserved antigens provide broader protection. Influenza matrix protein 2 (M2) is highly conserved across influenza A influenza A n. Influenza caused by infection with a strain of influenza virus type A. influenza A Infectious disease An avian virus, especially of ducks–which in China live near the pig reservoir and 'vector'; subtypes. To evaluate its efficacy as a vaccine candidate, we vaccinated mice with M2 peptide of a widely shared consensus sequence. This vaccination induced antibodies that cross-reacted with divergent M2 peptide from an H5N1 subtype (programming) subtype - If S is a subtype of T then an expression of type S may be used anywhere that one of type T can and an implicit type conversion will be applied to convert it to type T. . A DNA DNA: see nucleic acid. DNA or deoxyribonucleic acid One of two types of nucleic acid (the other is RNA); a complex organic compound found in all living cells and many viruses. It is the chemical substance of genes. vaccine expressing full-length consensus-sequence M2 (M2-DNA) induced M2-specific antibody responses and protected against challenge with lethal influenza. Mice primed with M2-DNA and then boosted with recombinant adenovirus adenovirus Any of a group of spheroidal viruses, made up of DNA wrapped in a protein coat, that cause sore throat and fever in humans, hepatitis in dogs, and several diseases in fowl, mice, cattle, pigs, and monkeys. expressing M2 (M2-Ad) had enhanced antibody responses that cross-reacted with human and avian M2 sequences and produced T-cell responses. This M2 prime-boost vaccination conferred broad protection against challenge with lethal influenza A, including an H5N1 strain. Vaccination with M2, with key sequences represented, may provide broad protection against influenza A. ********** Yearly development of influenza vaccines that are antigenically matched to circulating strains poses extraordinary challenges. A rapidly developing pandemic pandemic /pan·dem·ic/ (pan-dem´ik) 1. a widespread epidemic of a disease. 2. widely epidemic. pan·dem·ic adj. Epidemic over a wide geographic area. n. would shorten the time for strain identification and vaccine preparation; meanwhile, antigenic changes would continue. Moreover, the need to immunize im·mu·nize v. 1. To render immune. 2. To produce immunity in, as by inoculation. im an entirely naive population would exacerbate problems with vaccine production and supply. Vaccines based on conserved antigens would not require prediction of which strains would circulate during an approaching season and could avoid hurried manufacturing in response to outbreaks. Test vaccination with DNA constructs that express conserved influenza A nucleoprotein nucleoprotein Macromolecular complex consisting of a protein linked to a nucleic acid, either DNA or RNA. The proteins that combine with DNA are generally of characteristic types called histones and protamines. (NP) or NP plus matrix (M) induced antibody and T-cell responses and protected against heterosubtypic viruses (1,2). Despite the virulence and rapid kinetics of challenge infection, DNA vaccination with NP and M achieved limited protection against an H5N1 virus strain isolated from the 1997 human outbreak in Hong Kong (3). The M gene of influenza A encodes 2 proteins, both highly conserved: M1, the capsid capsid /cap·sid/ (kap´sid) the shell of protein that protects the nucleic acid of a virus; it is composed of structural units, or capsomers. cap·sid n. protein, and M2, an ion channel ion channel n. See channel. protein. M2 contains a small ectodomain (4), M2e, which makes it a target for antibody-based immunity. The ability of anti-M2 monoclonal antibody monoclonal antibody, an antibody that is mass produced in the laboratory from a single clone and that recognizes only one antigen. Monoclonal antibodies are typically made by fusing a normally short-lived, antibody-producing B cell (see immunity) to a fast-growing (MAb) to reduce viral replication (5) implicates M2, in particular M2e, as a vaccine target. M2 vaccine candidates that have been explored include peptide-carrier conjugates (6), baculovirus-expressed M2 (7), fusion proteins (8,9), multiple antigenic peptides (10), and M DNA constructs that potentially express M2 (11,12). In those studies, mice were protected against challenge with homologous or heterosubtypic viruses, but even the heterosubtypic viruses had an M2e sequence identical to the vaccine constructs or differed by only 1 amino acid amino acid (əmē`nō), any one of a class of simple organic compounds containing carbon, hydrogen, oxygen, nitrogen, and in certain cases sulfur. These compounds are the building blocks of proteins. . Although most human influenza viruses of H1, H2, or H3 subtypes share identity with the M2e consensus sequence (M2e-con) (9,13), some influenza A viruses do not. In a study of M2e-carrier conjugate vaccines, serum antibodies specific for M2e-con or M2e-A/PR/8/34 (H1N1) did not cross-react with M2e peptides from H5 and H7 subtype avian viruses that have 3 or 4 mismatches (6). In another study, monoclonal and polyclonal antibodies reacted with a subset of avian sequences (14). Although a recent study used M2e peptide-liposome vaccines of subtypes including H5N1 with matched challenge viruses (15), no prior work has documented protection against challenge with influenza viruses in which M2e sequences differed substantially from those of the immunizing antigen. Priority is being given to developing vaccines that offer broad protection against multiple influenza subtypes, including H5N1. Indeed, development of conserved-antigen vaccines, and specifically M2-based vaccines, is part of the US Department of Health and Human Services Noun 1. Department of Health and Human Services - the United States federal department that administers all federal programs dealing with health and welfare; created in 1979 Health and Human Services, HHS Pandemic Influenza Plan (www.hhs.gov/pandemicflu/ plan/). We therefore evaluated M2-based vaccine efficacy against divergent challenge viruses. Methods Mice Female BALB/cAnNCR mice were purchased from Division of Cancer Treatment, National Cancer Institute, Frederick, Maryland, USA. The institutions' Animal Care and Use Committees approved all protocols for animal experiments. Viruses Influenza viruses used were A/PR/8/34 (H1N1) (3), A/FM/1/47-MA (H1N1) (16), and A/Thailand/SP-83/2004 (H5N1) (17). Some virus stocks were propagated in the allantoic allantoic /al·lan·to·ic/ (al?an-to´ik) pertaining to the allantois. allantoic pertaining to the allantois. allantoic fluid see fetal fluids. cavity of embryonated hen eggs at 34[degrees]C for 48-72 h (A/PR/8) or 37[degrees]C for 24 h (SP-83). A/FM A/FM Air/Firing Mechanism was prepared as a pooled homogenate homogenate /ho·mog·e·nate/ (ho-moj´in-at) material obtained by homogenization. homogenate material obtained by homogenization. of lungs from BALB/c mice infected 4 days previously. All experiments with H5N1 subtypes were conducted under biosafety level biosafety level Epidemiology A classification for the degree of caution required when working with specific groups of pathogens. See Maximum containment facility. 3, enhanced containment. Peptides and Peptide Conjugates M2e 2-24 peptides (no NH2-terminal methionine methionine (mĕthī`ənēn), organic compound, one of the 20 amino acids commonly found in animal proteins. Only the L-stereoisomer appears in mammalian protein. ) were synthesized with COOH-terminal cystine cystine: see cysteine. residues and conjugated conjugated adj. Conjugate. estrogens, conjugated Warning - Hazardous drug! C.E.S. to maleimide-activated keyhole limpet limpet, marine gastropod mollusk with a simple, flattened, conical shell, found in cooler waters of the Atlantic and the Pacific oceans. Certain species creep over rocks, feeding on algae during high tides, but when the tide recedes they return instinctively to the hemocyanin hemocyanin /he·mo·cy·a·nin/ (-si´ah-nin) a blue copper-containing respiratory pigment occurring in the blood of mollusks and arthropods. (KLH KLH Keyhole Limpet Hemocyanin KLH Knight of the Legion of Honour KLH Kloss, Lowe and Hoffman (audio equipment brand) KLH Korea Light Helicopter ) for vaccines. The same peptides were also synthesized without COOH-terminal cystine and used for antibody and T-cell assays. Influenza A NP147-155 and M2e peptides were synthesized in the core facility of the Center for Biologics Evaluation and Research The Center for Biologics Evaluation and Research (CBER) is one of six main centers for the Food and Drug Administration, which is in the United States Department of Health and Human Services. , US Food and Drug Administration. Severe acute respiratory syndrome Severe Acute Respiratory Syndrome (SARS) Definition Severe acute respiratory syndrome (SARS) is the first emergent and highly transmissible viral disease to appear during the twenty-first century. (SARS) matrix peptide (209-221) was provided by the National Institutes of Health. Vectors Plasmid and recombinant adenoviral (rAd) vectors that express B/NP and A/NP have been described (18), as has the plasmid containing the entire M gene of A/PR/8 (2). The plasmid VR1012-M2 (termed M2-DNA above) was generated as follows. The plasmid pCR3-M2 was derived by PCR from the vector pCR3-M previously generated from A/PR/8 virus by reverse transcription-PCR (19). To modify the sequence to the widely shared M2e sequence, full-length consensus M2 eDNA with Kozak sequence at its 5' end was generated from 2 overlapping M2 DNA fragments and subcloned into VR-1012, obtained under material transfer agreement from Vical, Inc., San Diego, CA, USA. The sequence of the M2 insert was confirmed by restriction digestion and sequence analysis. The replication-incompetent adenovirus that expresses the M2 protein with the consensus sequence (M2-Ad) was constructed by using Gateway cloning and the ViraPower Adenoviral Expression System (both from Invitrogen, Carlsbad, CA, USA) according to manufacturer's instructions. Briefly, the M2 eDNA from VR1012-M2 was cloned by PCR into the pENTR/D-TOPO Gateway vector and then transferred into the pAd/CMV/V5-DEST adenoviral Gateway vector by LR Clonase (Invitrogen) reaction to give pAd/CMV-M2. Integrity and proper insertion of the cloned M2 eDNA were confirmed by sequencing. M2-Ad was generated by transfection trans·fec·tion n. Infection of a bacterium or cell with DNA or RNA isolated from a bacteriophage or from an animal or a plant virus, resulting in replication of the complete virus. of 293A cells with pAd/CMV-M2. M2 expression was confirmed by immunohistochemical staining of M2-Ad-infected Madin-Darby canine kidney cells with M2-specific polyclonal polyclonal /poly·clo·nal/ (-klon´'l) 1. derived from different cells. 2. pertaining to several clones. polyclonal derived from different cells; pertaining to several clones. sera (data not shown). High-titered stocks of rAd were prepared by ViraQuest, Inc. (North Liberty, IA, USA). Adenovirus stocks were stored in 3% sucrose/phosphate-buffered saline (PBS PBS in full Public Broadcasting Service Private, nonprofit U.S. corporation of public television stations. PBS provides its member stations, which are supported by public funds and private contributions rather than by commercials, with educational, cultural, ) at 1-2 x [10.sup.12] particles/mL and confirmed as negative for replication-competent adenovirus by passage on nonpermissive cells. Immunization immunization: see immunity; vaccination. Mice were given an intraperitoneal injection of 40 [micro]g peptide-KLH or unconjugated KLH in complete Freund's adjuvant Freund's adjuvant n. A substance consisting of killed microorganisms, such as mycobacteria, in an oil and water emulsion that is administered to induce and enhance the formation of antibodies. (emulsified 1:1 with antigen in PBS). Three weeks later, the mice were given an intraperitoneal booster injection with peptide-KLH in incomplete Freund's adjuvant; 13 days later blood was collected. Injections were started at 8-10 weeks of age for peptide and 6 weeks of age for DNA. DNA vaccination at doses of 50 [micro]g/mouse (unless noted otherwise in a figure legend) in low-endotoxin PBS (AccuGENE, Cambrex, East Rutherford, NJ, USA) was given intramuscularly in·tra·mus·cu·lar adj. Within a muscle: an intramuscular injection. in in the quadriceps, half to each leg, in 3 doses 2 weeks apart. In some experiments, mice were given a booster injection of rAd intramuscularly at a dose of [10.sup.10] particles/mouse, 2-3 weeks after the last dose of DNA. Challenge Challenge virus in 50 [micro]L of PBS was administered intranasally to anesthetized a·nes·the·tize also a·naes·the·tize tr.v. a·nes·the·tized, a·nes·the·tiz·ing, a·nes·the·tiz·es To induce anesthesia in. a·nes mice. Isoflurane or ketamine/xylazine was used for mice challenged with H1N1 subtype. Reported 50% lethal dose lethal dose n. Abbr. LD The dose of a chemical or biological preparation that is likely to cause death. ([LD.sub.50]) for H1N1 subtype was determined for 8-week-old naive BALB/c mice for each anesthetic (and may vary from the actual [LD.sub.50] for the older vaccinated mice that were challenged). Subtype H5N1 was administered intranasally to mice anesthetized with 2,2,2-tribromoethanol in tert-amyl alcohol (Avertin; Aldrich Chemical Co., Milwaukee, WI, USA). Some mice were killed so their lungs could be harvested; others were monitored for body weight and death. Monitoring continued until all animals died or were recovering, as indicated by body weight. In Vivo in vivo /in vi·vo/ (ve´vo) [L.] within the living body. in vi·vo adj. Within a living organism. in vivo adv. T-Cell Depletion Acute depletion of lymphocyte populations by MAb treatment on days -3, +2, +8 relative to day of challenge was performed as described previously (18) and used MAbs GK1.5, specific for mouse CD4; 2.43, specific for mouse CD8; and SFR SFR Swiss Franc (national currency) SFR Société Française du Radiotéléphone (French cellular provider) SFR Single Family Residence SFR Single Family Residence (real estate) 3-DR5, specific for a human leukocyte antigen human leukocyte antigen n. Abbr. HLA A gene product of the major histocompatibility complex; these antigens have been shown to have a strong influence on human allotransplantation, transfusions in refractory patients, and certain disease as a negative control. Splenocytes were analyzed 2 days after challenge (before the next injection) by flow cytometry flow cytometry (flōˑ sī·t  ˑ·m to confirm
completeness of in vivo T-cell depletion, as described (2).
ELISA ELISA (e-li´sah) Enzyme-Linked Immuno-Sorbent Assay; any enzyme immunoassay using an enzyme-labeled immunoreactant and an immunosorbent. ELISA n. ELISA for M2-specific antibodies was performed on plates coated with 15 [micro]g/mL of synthetic peptides in 0.007 mol/L borate borate /bo·rate/ (bor´at) a salt of boric acid. bo·rate n. A salt or ester of boric acid. borate any salt of boric acid. buffer and 0.025 mol/L saline; the rest of the procedure was as described (20). Passive Serum Transfer Naive mice were given intraperitoneal injections of pooled serum pooled serum n. Serum obtained from a number of individuals and mixed together. Also called pooled blood serum. , 1 mL per mouse, from mice immunized with M2-DNA plus matched Ad booster or from control mice (B/NP-DNA, M2-H5[HK] peptide-KLH conjugate conjugate /con·ju·gate/ (kon´jdbobr-gat) 1. paired, or equally coupled; working in unison. 2. a conjugate diameter of the pelvic inlet; used alone usually to denote the true conjugate diameter; see , or A/PR/8 virus). Mice were challenged with a moderate dose of A/PR/8 virus the day after serum transfer; antibody levels in recipients were not measured. Spleen Cell Fractionation T cells were enriched by negative selection that used magnetic beads. Briefly, splenocytes were depleted of erythrocytes Erythrocytes Red blood cells. Mentioned in: Bartonellosis erythrocytes (ē·rithˑ·rō·sīts), n.pl red blood cells. and labeled with biotinylated antimouse B220, CD11b, and PanNK antibodies (BD Pharmingen, San Diego, CA, USA). After labeling, cells were incubated with Streptavidin MicroBeads (Miltenyi Biotec, Aubum, CA, USA). Unlabeled T cells and labeled non--T cells were separated through the Miltenyi AutoMACS system according to the manufacturer's instructions. Enzyme-linked immunosorbent immunosorbent /im·mu·no·sor·bent/ (-sor´bent) an insoluble support for antigen or antibody used to absorb homologous antibodies or antigens, respectively, from a mixture; the antibodies or antigens so removed may then be eluted in pure Spot (ELISPOT ELISPOT Enzyme-Linked Immunospot Assay ELISPOT Interferon-Gamma Enzyme-Linked Immunospot ) Assay This assay detected T-cell responses to M2 peptides. ELISPOT IP plates (Millipore; Billerica, MA, USA) were coated with 50 [micro]L of Hank's balanced salt solution (Hyclone, Logan, UT, USA) containing 5 [micro]g/mL of anti-interferon-[gamma] (IFN-[gamma]) MAb AN18 (BD Pharmingen) and incubated overnight at 4[degrees]C. The membrane was washed and then blocked with medium containing 10% fetal bovine serum Fetal bovine serum ( or foetal bovine serum) is serum taken from the fetuses of cows. Fetal Bovine Serum (or FBS) is the most widely used serum in the culturing of cells. In some papers the expression foetal calf serum is used. for 60-90 min at room temperature. Splenocytes depleted of erythrocytes were added to wells in 2-fold dilutions, starting at 250,000 cells/well in 50 [micro]L. Peptides (SARS-M-209-221, NP147-155 of A/PR/8, or M2-2-24 of A/PR/8) were added at a final concentration of 1 [micro]g/mL. After incubation for 36-48 h at 37[degrees]C, bound IFN-[gamma] was detected with 50 [mciro]L of biotinylated MAb R4-6A2 (BD Pharmingen) at 1 [micro]g/mL. Spots were developed by using alkaline phosphatase--labeled streptavidin and 5-bromo, 4-chloro, 3-indolylphosphate/nitroblue tetrazolium substrate (Kirkegaard and Perry Laboratories, Gaithersburg, MD, USA) and counted with an ELISPOT reader (Zeiss; Thornwood, NY, USA). Virus Quantitation Lungs were homogenized ho·mog·e·nize v. ho·mog·e·nized, ho·mog·e·niz·ing, ho·mog·e·niz·es v.tr. 1. To make homogeneous. 2. a. To reduce to particles and disperse throughout a fluid. b. in 1 mL of sterile PBS, clarified by centrifugation Centrifugation A mechanical method of separating immiscible liquids or solids from liquids by the application of centrifugal force. This force can be very great, and separations which proceed slowly by gravity can be speeded up enormously in centrifugal , and titrated ti·trate tr. & intr.v. ti·trat·ed, ti·trat·ing, ti·trates To determine the concentration of (a solution) by titration or perform the operation of titration. for virus infectivity by 50% egg infectious dose ([EID EID Emerging Infectious Diseases (journal) EID Electronic Identification EID Endpoint Identifier EID Employee Identification EID Ecological Interface Design EID Earned Income Disregard EID Education and Information Division .sub.50]) assay as described (3). The limit of virus detection is 1.2 [log.sub.10] [EID.sub.50]/mL. Challenge virus stocks were titrated on Madin-Darby canine kidney cells as described previously (18). Statistical Analysis The serologic se·rol·o·gy n. pl. se·rol·o·gies 1. The science that deals with the properties and reactions of serums, especially blood serum. 2. assays and detection of M2-specific T cells were performed multiple times with comparable results. Some vaccinations were repeated with independent groups (as noted in the figure legends); those performed once used numbers of animals per group adequate for statistical significance. Lung virus titers were compared by using 1-way analysis of variance on log-transformed data, followed by pairwise multiple comparison (Holm-Sidak method). Weight loss after challenge was compared for survivors on each day by also using 1-way analysis of variance followed by pairwise multiple comparison (Holm-Sidak). This method overestimates body weight in groups with deaths because the animals that died would have had very low body weights, affecting the average, especially in the negative control groups. Nonetheless, differences between vaccinated groups were significant in the instances stated. Comparison of cumulative survival rates used the log-rank test, followed by pairwise multiple comparison, again by using the Holm-Sidak method. Overall significance level for Holm-Sidak tests was p = 0.05. All statistical analyses were performed with SigmaStat Software v3.11 (Systat Software, Point Richmond, CA, USA). Results M2e-KLH Vaccination For proof-of-concept studies, peptides representing M2e-con (9) and additional viral M2 ectodomains (Table) were conjugated to KLH and used to immunize BALB/c mice. Immune serum samples were analyzed for M2-specific antibodies by ELISA on plates coated with synthetic M2e peptides with sequences from 2 viruses of H1N1 and 2 of H5N1 subtype. Serum from KLH-immune mice did not react with any of the peptides, but each M2e-immune serum sample reacted with M2e-PR8, M2e-FM, and M2e-H5(SP-83) peptides (Figure 1A-C A-C Air Conditioning ). Cross-reactions were lower on the M2e-H5(HK) peptide (Figure 1D). [FIGURE 1 OMITTED] M2e-vaccinated mice were then challenged with either A/PR/8 or A/FM and monitored for weight loss (as a measure of illness) and death. Weight losses were consistent with a hierarchy of protection based on sequence similarity (data not shown), and differences from control mice were statistically significant. In the same groups, 100% of mice vaccinated with M2e-con or M2e-FM survived challenge with A/PR/8 and A/FM, but M2e-H5(HK)/KLH vaccination provided incomplete protection (Figure 2A and B). [FIGURE 2 OMITTED] M2-DNA Vaccination To investigate whether, like M2e peptide, DNA vaccination could protect against viruses with quite divergent M2e sequence, we tested M- and M2-DNA for efficacy. M-DNA with the A/PR/8 sequence protected against challenge with A/PR/8 (Figure 3A). M2-DNA with the consensus sequence also protected against this A/PR8 challenge; however, M1-DNA did not (data not shown). For challenge with A/FM, M2-DNA was more efficacious than MDNA MDNA Machinery Dealers National Association MDNA Martin Drive Neighborhood Association (Milwaukee, WI) MDNA Mobilehome Dealers National Association (Figure 3B). [FIGURE 3 OMITTED] M2-DNA Vaccination Followed by M2-Ad Boost Previously, we have shown for NP vaccination that boosting with rAd induces more potent antibody and T-cell (especially [CD8.sup.+]) responses than does DNA vaccination alone and can protect against challenge with highly pathogenic H5N1 subtype (18). We investigated whether boosting with rAd would also enhance immunity to M2. The A/M A/M Away Message (AOL Instant Messaging) A/M Automatic / Manual A/M Aeromobile (Italian: airplane) A/M Ampere Per Meter A/M approach and moor (US DoD) 2 gene with the consensus sequence was cloned into a replication-deficient Ad construct (M2-Ad). Mice were primed with DNA as before and boosted with M2-Ad or control B/NP-Ad. Two weeks later, serum samples were collected and assayed for M2-specific immunoglobulin (Ig) G by ELISA on peptides as above (Figure 4A-D A-D Advance-Decline, or measurement of the number of issues trading above their previous closing prices less the number trading below their previous closing prices over a particular period. ). Mice given the booster of M2-DNA+M2-Ad had dramatically greater M2e-PR8--specific IgG antibody responses than mice given either component alone (M2-DNA+B/NP-Ad or B/NP-DNA+M2-Ad; Figure 4A). Moreover, IgG cross-reactivity with M2e-FM (3 amino acid differences; Figure 4B) and M2e-H5(SP-83) (3 amino acid differences; Figure 4C) was found with serum from mice given M2-Ad; cross-reactivity was even greater with serum from mice given M2-DNA+M2-Ad. These serum samples, however, did not cross-react with M2e-H5(HK) (4 amino acid differences; Figure 4D), although serum from mice immunized with M2e-H5(HK)-KLH as positive controls reacted strongly (data not shown). [FIGURE 4 OMITTED] Protective immunity due to vaccination with M2-DNA+M2-Ad was tested by challenge with A/PR/8 (high-dose) or A/FM (moderate dose) virus. Of mice vaccinated with M2-DNA+M2-Ad, 100% survived challenge with A/PR/8 and A/FM virus; of mice vaccinated with B/NP-DNA+B/NP-Ad, 20% survived challenge with A/PR/8 and none survived challenge with A/FM (Figure 5A,B). Thus, the prime-boost vaccination protected against challenge viruses in which M2e sequences were similar to or divergent from those of the vaccine. [FIGURE 5 OMITTED] T-cell Response T-cell responses to M2 have been observed (7). Immunization with cDNA expressing full-length M2 protein might induce, in addition to antibody, M2-specific T-cell responses not induced by peptides. To address the contribution of T-cell responses, we immunized mice to M2 by prime-boost and acutely depleted them of T cells just before and during the challenge period. Lymphocyte depletion was confirmed to be complete; residual splenic splenic /splen·ic/ (splen´ik) pertaining to the spleen. splen·ic adj. Of, in, near, or relating to the spleen. splenic pertaining to the spleen. [CD4.sup.+] or [CD8.sup.+] cells were <1% (data not shown). Of the B/NP control mice, 100% died of A/PR/8 infection by day 8 after challenge, while 100% of M2-immune mice treated with a control MAb (SFR) survived (Figure 6A). Individual depletion of [CD4.sup.+] or [CD8.sup.+] T cells did not abrogate abrogate v. to annul or repeal a law or pass legislation that contradicts the prior law. Abrogate also applies to revoking or withdrawing conditions of a contract. (See: repeal) protection. Depletion of [CD4.sup.+] and [CD8.sup.+] T cells together partially, but statistically significantly, abrogated M2-induced protection (Figure 6A) but left some protection significantly different from that in the B/NP control mice. Thus, under these challenge conditions, T cells are important. M2e-specific immunity has been reported to be natural killer (NK)-cell dependent (21). We found that mice depleted of NK cells with anti--asialo-GM1 antibody were protected similarly to controls (data not shown). Thus, while NK cells may play a role, they were not required under the conditions we studied. [FIGURE 6 OMITTED] Given the effect of T-cell depletion, we tested for in vitro M2-specific IFN-[gamma]-producing T cells. The IFN-[gamma] ELISPOT assay showed positive responses to an aminoterminal M2 peptide in spleen cells from mice immune to M2-DNA+M2-Ad (Figure 6B) and to A/PR/8 (data not shown). After spleen cells were fractionated by magnetic bead separation (see Methods), the non-T-cell fraction did not respond, while the unfractionated cells and T-cell fraction maintained a strong M2-specific IFN-[gamma] response (Figure 6B). Role of M2-specific Antibody On the basis of information from previous studies (see Discussion), we tested the ability of antibodies induced by DNA prime--Ad boost to passively transfer protection. All (100%) mice given serum from M2-immune or A/PR/8-infected mice survived, while only 50% given control B/NP-immune serum survived (Figure 6C; p<0.001, log rank). Passive serum antibody from M2 prime-boost immune mice also conferred significant protection against weight loss (Figure 6D). Heterologous heterologous /het·er·ol·o·gous/ (het?er-ol´ah-gus) 1. made up of tissue not normal to the part. 2. xenogeneic. het·er·ol·o·gous adj. 1. Challenge, Including SP-83 (H5N1) Because protection against challenge with A/FM virus that has an M2e sequence quite divergent from that of the immunizing sequence was encouraging, we tested whether M2-DNA+M2-Ad vaccination could protect against challenge with H5N1 subtype. Mice were immunized 3x with B/NP-DNA (negative control), A/NP-DNA (positive control), or consensus M2-DNA, and boosted with matched rAd. Mice were challenged with a lethal dose of A/Thailand/SP-83/2004 (H5N1) virus in which M2e differed from the consensus by 3 amino acids. On day 5 after infection, a random subset of animals was killed and their lung virus titers were measured. Virus titers of mice vaccinated with A/NP or with M2 were significantly reduced compared with those of control mice (Figure 7A). The remaining mice were monitored for weight loss and survival. Weight loss was less in mice vaccinated with A/NP and M2 than in control mice (Figure 7B). All the B/NP-immune mice died of SP-83 infection by day 11 postchallenge. All (100%) A/NP-immune mice and all but l M2-immune mouse survived (Figure 7C). [FIGURE 7 OMITTED] Discussion Our results indicate that M2 vaccination can induce cross-reactive antibody responses, virus-specific T-cell responses, and protection against challenge with lethal heterologous virus. As has been found in previous studies of M2-based vaccines, we found strong antibody responses to the conserved M2e region. Anti-M2 antibodies in the serum of mice immunized with M DNA suggest expression of M2 from this plasmid (not shown). However, reactivity could be due to the 9 amino acid portion shared with the M1 sequence, and we did not explore this possibility. Fan et al. used A/PR/8 and Aichi M2e-carrier conjugates for immunization, and the resulting antibodies did not cross-react with the avian M2e sequences tested (6). We found cross-reactivity with M2e peptides that had considerable sequence divergence from the human influenza M2 consensus. Immunization with M2e-con/KLH induced antibodies that were reactive with M2e-H5(SP-83) peptide but less reactive with M2e-H5(HK). However, immunization with M2e-H5(HK)/KLH induced antibodies that were reactive with all the M2e peptides. This pattern parallels the results of Liu et al. (14). However, neither Fan et al. nor Liu et al. investigated protection against challenge with H5N1 subtype. In our lethal challenge studies, M2e peptide conjugates protected against not only a 1934 subtype H1N1 virus (A/PR/8) but also a 1947 subtype H1N1 virus (A/FM). The latter virus, which is virulent in mice, has an M2e sequence with 3 amino acid differences from the consensus and thus is as divergent from the consensus sequence as some M2-H5 sequences. Encouraged by this broad cross-reactivity and cross-protection, we expanded the study to DNA vaccination and DNA prime--Ad boost regimens. These approaches have the advantage of providing more epitopes than peptide immunization and relevant T-cell immunity. Using M2 consensus DNA vaccination with or without Ad boost, we again saw cross-reactivity on avian peptides M2e-H5(SP-83) and M2e-H5(HK), although cross-reactivity was low on the HK peptide. T-cell responses to M2 peptides were detected by ELISPOT. Several studies have shown that M2e-specific antibodies can mediate protection against influenza infection in vivo (9,10,13). In agreement with those studies, we found that serum antibodies induced by peptide conjugates or by prime-boost vaccination could transfer protection to naive recipients. We found that T cells were also important because depletion of [CD4.sup.+] and [CD8.sup.+] T cells during the challenge period reduced protection against a higher challenge dose. This could reflect M2e-specific memory T cells, which we have demonstrated in spleen and peripheral blood by ELISPOT, or a concurrent T-cell response to challenge virus supplementing the protective effects of antibodies. In lethal challenge studies, the M2 consensus DNA and rAd constructs could protect against not only A/PR/8 but also against A/FM, a virus quite divergent in the M2e sequence. Furthermore, they could protect mice against challenge with SP-83 (H5N1) isolated from a fatal human case, at a dose lethal to control mice. Virus replication in lungs and illness reflected by loss of body weight were also reduced by M2 immunization. Protection against challenge with other H5N1 subtypes remains to be explored, and serologic results on M2e-H5(HK) peptide suggest results of such studies might differ on the basis of sequence variations. M2 expression constructs with various M2e sequences could be used as vaccines. Our observation of protection across substantial sequence divergence means that H5-derived vaccines might also protect against circulating H1N1 and H3N2 subtypes. An additional advantage of protection across substantial divergence is potential protection by an M2 vaccine against an unexpected subtype that could cause a pandemic. One concern about M2 vaccines is the possibility of escape mutants. A study of forced escape mutants found limited diversity (13), which indicates that structural constraints, perhaps due to requirements of the M1 structure encoded by the same segment, may limit drift. The cross-reactivity and protective efficacy of M2-specific antibodies suggest that M2-specific MAbs could be useful for antiviral therapy. These features, combined with constraints on M2 structure, highlight the potential of M2-specific MAbs to inhibit replication of influenza viruses, including some H5N1 strains. Although traditional M2-directed drugs (e.g., amantadine amantadine /aman·ta·dine/ (ah-man´tah-den) an antiviral compound used as the hydrochloride salt to treat influenza A; also used as an antidyskinetic in the treatment of parkinsonism and drug-induced extrapyramidal reactions. ) have led to drug resistance, the mutations that confer resistance are within the transmembrane transmembrane /trans·mem·brane/ (trans-mem´bran) extending across a membrane, usually referring to a protein subunit that is exposed on both sides of a cell membrane. trans·mem·brane adj. region (22), which may have fewer structural constraints than the ectodomain. An M2 prime-boost regimen is intended to be combined with vaccination against additional antigens rather than acting as a standalone vaccine. For example, prime-boost vaccination against conserved NP is highly protective ([18]; Figure 7). The use of multiple antigens has several advantages: reduced likelihood of escape mutants, better coverage of human leukocyte antigen haplotypes in the genetically diverse human population, and a broader spectrum of immune response mechanisms (with antibodies perhaps dominating for M2 and cytotoxic T lymphocytes for NP). Vaccines based on conserved antigens are not intended to replace strain-matched vaccines that induce neutralizing antibodies and thus prevent infection. However, strain-matched vaccines may be difficult to produce in adequate quantities in short time periods, and continued antigenic drift may render them ineffective. Vaccinations as described here, based on M2, might reduce deaths and severity of disease while strain-matched vaccines were being prepared and could enhance protection afforded by inactivated inactivated rendered inactive; the activity is destroyed. inactivated viruses treated so that they are no longer able to produce evidence of growth or damaging effect on tissue. vaccines. Immunogenicity immunogenicity /im·mu·no·ge·nic·i·ty/ (-je-nis´it-e) the property enabling a substance to provoke an immune response, or the degree to which a substance possesses this property. and safety studies in people are needed to evaluate this approach. Acknowledgments We thank Andrew Byrnes for critical review of the manuscript, the staff of the Center for Biologics Evaluation and Research animal facility for animal care, Earl Brown for providing influenza virus A/FM/1/47-MA (A/FM [H1N1]), and Wing-Pui Kong and Gary Nabel for providing SARS matrix peptide (209-221). This work was supported in part by grants from the National Vaccine Program Office and from the Advanced Development of Medical Countermeasures program of the Office of Research and Development Coordination to S.L.E. The MAbs used for in vivo depletion studies were prepared and purified from tissue culture supernatants by the National Cell Culture Center, Minneapolis, Minnesota, USA. Dr Tompkins is an assistant professor in the Department of Infectious Diseases, College of Veterinary Medicine, University of Georgia Organization The President of the University of Georgia (as of 2007, Michael F. Adams) is the head administrator and is appointed and overseen by the Georgia Board of Regents. , His research expertise is in immunology and animal models of autoimmune disease. His current research interests include pathogenesis of viral respiratory diseases, and development of new vaccines and therapeutics for these diseases. References (1.) Ulmer JB, Donnelly JJ, Parker SE, Rhodes GH, Feigner PL, Dwarki V J, et el. Heterologous protection against influenza by injection of DNA encoding a viral protein. Science. 1993;259:1745-9. (2.) Epstein SL, Stack A, Misplon JA, Lo CY, Mostowski H, Bennink J, et el. Vaccination with DNA encoding internal proteins of influenza virus does not require [CD8.sup.+] cytotoxic T lymphocytes: either [CD4.sup.+] or [CD8.sup.+] T cells can promote survival and recovery after challenge. Int Immunol. 2000;12:91-101. (3.) Epstein SL, Tumpey TM, Misplon JA, Lo CY, Cooper LA, Subbarao K, et el. DNA vaccinc expressing conserved influenza virus proteins protective against H5N1 challenge infection in mice. Emerg Infect Dis. 2002;8:796-801. (4.) Lamb RA, Krug RM. Orthomyxoviridae: the viruses and their replication. In: Knipe DM, Howley, PM, Griffin DE, Martin MA, Lamb RA, Roizman B, et el., editors. Fields Virology virology, study of viruses and their role in disease. Many viruses, such as animal RNA viruses and viruses that infect bacteria, or bacteriophages, have become useful laboratory tools in genetic studies and in work on the cellular metabolic control of gene expression . 4th ed. Philadelphia: Lippincott Williams & Wilkins; 2001. p. 1487-503. (5.) Zebedee SL, Lamb RA. Influenza A virus M2 protein: monoclonal antibody restriction of virus growth and detection of M2 in virions. J Virol. 1988;62:2762-72. (6.) Fan J, Liang X, Horton MS, Perry HC, Citron citron (sĭt`rən), name for a tree (Citrus medica) of the family Rutaceae (orange family), and for its fruit, the earliest of the citrus fruits to be introduced to Europe from Asia. MP, Heidecker GJ, et al. Preclinical study of influenza virus A M2 peptide conjugate vaccines in mice, ferrets, and rhesus monkeys. Vaccine. 2004;22: 2993-3003. (7.) Slepushkin VA, Katz JM, Black RA, Gamble WC, Rota PA, Cox NJ. Protection of mice against influenza A virus challenge by vaccination with baculovirus-expressed M2 protein. Vaccine. 1995;13:1399-402. (8.) Frace AM, Klimov AI, Rowe T, Black RA, Katz JM. Modified M2 proteins produce heterotypic heterotypic /het·ero·typ·ic/ (-tip´ik) pertaining to, characteristic of, or belonging to a different type. het·er·o·typ·ic or het·er·o·typ·i·cal adj. immunity against influenza A virus. Vaccine. 1999;17:2237-44. (9.) Neirynck S, Deroo T, Saelens X, Vanlandschoot P, Jou WM, Fiers W. A universal influenza A vaccine based on the extracellular domain of the M2 protein. Nat Med. 1999;5:1157-63. (10) Mozdzanowska K, Feng J, Eid M, Kragol G, Cudic M, Otvos JL, et al. 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. Vaccine. 2003;21:2616-26. (11.) Okuda K, Ihata A, Watabe S, Okada E, Yamakawa T, Hamajima K, et al. Protective immunity against influenza A virus induced by immunization with DNA plasmid containing influenza M gene. Vaccine. 2001;19:3681-91. (12.) Watabe S, Xin K-Q, Ihata A, Liu L-J, Honsho A, Aoki I, et al. Protection against influenza virus challenge by topical application of influenza DNA vaccine. Vaccine. 2001; 19:4434-44. (13.) Zharikova D, Mozdzanowska K, Feng J, Zhang M, Gerhard W. Influenza type A virus escape mutants emerge in vivo in the presence of antibodies to the ectodomain of matrix protein 2. J Virol. 2005;79:6644-54. (14.) Liu W, Zou P, Ding J, Lu Y, Chen YH. Sequence comparison between the extracellular domain of M2 protein human and avian influenza A virus provides new information for bivalent bivalent /bi·va·lent/ (bi-va´lent) 1. divalent. 2. the structure formed by a pair of homologous chromosomes by synapsis along their length during the zygotene and pachytene stages of the first meiotic prophase. influenza vaccine design. Microbes Infect. 2005;7:171-7. (15.) Ernst WA, Kim HJ, Tumpey TM, Jansen AD, Tai W, Cramer DV, et al. Protection against H1, H5, H6 and H9 influenza A infection with liposomal matrix 2 epitope epitope: see immunity. vaccines. Vaccine. 2006:24:5158-68. (16.) Smeenk CA, Brown EG. The influenza virus variant A/FM/I/47-MA possesses single amino acid replacements in the hemagglutinin hemagglutinin /he·mag·glu·ti·nin/ (-gloo´ti-nin) an antibody that causes agglutination of erythrocytes. cold hemagglutinin one which acts only at temperatures near 4° C. , controlling virulence, and in the matrix protein, controlling virulence as well as growth. J Virol. 1994;68:530-4. (17.) World Health Organization Global Influenza Program Surveillance Network. Evolution of H5N1 avian influenza viruses in Asia. Emerg Infect Dis. 2005;11:1515-21. (18.) Epstein SL, Kong WP, Misplon JA, Lo CY, Tumpey TM, Xu L, et al. Protection against multiple influenza A subtypes by vaccination with highly conserved nucleoprotein. Vaccine. 2005;23:5404-10. (19.) Huang X, Liu T, Muller J, Levandowski RA, Ye Z. Effect of influenza virus matrix protein and viral RNA RNA: see nucleic acid. RNA in full ribonucleic acid One of the two main types of nucleic acid (the other being DNA), which functions in cellular protein synthesis in all living cells and replaces DNA as the carrier of genetic on ribonucleoprotein ribonucleoprotein /ri·bo·nu·cleo·pro·tein/ (-noo?kle-o-pro´ten) a substance composed of both protein and ribonucleic acid. Abbreviated RNP. ri·bo·nu·cle·o·pro·tein n. Abbr. formation and nuclear export. Virology. 2001 ;287:405-16. (20.) Benton KA, Misplon JA, Lo CY, Brutkiewicz RR, Prasad Prasāda (Sanskrit: प्रसाद), prasād/prashad (Hindi), Prasāda in (Kannada), prasādam (Tamil), or prasadam SA, Epstein SL. Heterosubtypic immunity to influenza A virus in mice lacking IgA, all Ig, NKT NKT New Kadampa Tradition NKT Natural killer T-cells (lymphocytes) NKT Nederlands Keuringsinstituut voor Telecommunicatieapparatuur (Dutch Regulatory Branch) NKT Non-Kinetic Technology NKT Northern Kentucky Transit, Inc. cells, or gamma delta T cells. J Immunol. 2001;166:7437-45. (21.) Jegerlehner A, Schmitz N, Storni T, Bachmann MF. Influenza A vaccine based on the extracellular domain of M2: weak protection mediated via antibody-dependent NK cell activity. J Immunol. 2004;172:5598-605. (22.) Shiraishi K, Mitamura K, Sakai-Tagawa Y, Goto H, Sugaya N, Kawaoka Y. High frequency of resistant viruses harboring different mutations in amantadine-treated children with influenza. J Infect Dis. 2003;188:57-61. Address for correspondence: Stephen Mark Tompkins, Department of Infectious Diseases, University of Georgia, 111 Carlton St., Athens, GA 30602, USA; email: tompkins@vet.uga.edu Stephen Mark Tompkins, * (1) Zi-Shan Zhao, * Chia-Yun Lo, * Julia A. Misplon, * Teresa Liu, * Zhiping Ye, * Robert J. Hogan Robert J. Hogan (born September 28 1933) is an American actor best known for his recurring characters on soap operas, including Peyton Place, Another World, As the World Turns, and One Life to Live. , ([dagger]) Zhengqi Wu, * Kimberly A. Benton, * Terrence M. Tumpey, ([double dagger]) and Suzanne L. Epstein * * Food and Drug Administration, Bethesda, Maryland, USA; ([dagger]) University of Georgia, Athens, Georgia, USA; and ([double dagger]) Centers for Disease Control and Prevention Centers for Disease Control and Prevention (CDC), agency of the U.S. Public Health Service since 1973, with headquarters in Atlanta; it was established in 1946 as the Communicable Disease Center. , Atlanta, Georgia, USA (1) Current affiliation: University of Georgia, Athens, Georgia, USA
Table. Sequences of matrix protein 2 (M2) ectodomains
Strain Abbreviation Subtype
Consensus M2e-con ([double
dagger])
A/PR/8 M2e-PR8 H1N1
A/FM/1/47-MA M2e-FM H1N1
A/Hong Kong/156/97 M2e-H5(HK) H5N1
A/Thailand/SP-83/04 M2e-H5(SP-83) H5N1
Strain M2e Sequence
([dagger])
Consensus MSLLTEVETPIRNEWGCRCNDSSD
A/PR/8 MSLLTEVETPIRNEWGCRCNG#SSD
A/FM/1/47-MA MSLLTEVETPTK#NEWE#CRCNDSSD
A/Hong Kong/156/97 MSLLTEVETLT#RNG#WGCRC#SDSSD
A/Thailand/SP-83/04 MSLLTEVETPT#RNEWE#CRCS#DSSD
Note: Variations from the M2e consensus sequence
are indicated with #.
* Variations from the M2e consensus sequence
are in boldface and underlined.
([dagger]) Virus sequences available at
www.ncbi.nlm.nih.gov/genomes/FLU and
www.flu.lanl.gov.
([double dagger]) Consensus sequence derived from
human influenza viruses of H1, H2, and
H3 subtypes (9,13).
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