Making better influenza virus vaccines?Killed and live influenza virus vaccines are effective in preventing and curbing the spread of disease, but new technologies such as reverse genetics reverse genetics methods such as antisense nucleic acids and site-directed mutagenesis that are used to selectively study gene function. Contrasts with classical genetics which depends on the isolation and analysis of cells (animals) with random mutations that can be identified. could be used to improve them and to shorten the lengthy process of preparing vaccine seed viruses. By taking advantage of these new technologies, we could develop live vaccines that would be safe, cross-protective against variant strains, and require less virus per dose than conventional vaccines. Furthermore, 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. vaccines against highly virulent strains such as the H5N1 virus can only be generated by reverse genetics techniques. Other technologic breakthroughs should result in effective adjuvants for use with killed and live vaccines, increasing the number of available doses. Finally, universal influenza virus vaccines seem to be within reach. These new strategies will be successful if they are supported by regulatory agencies and if a robust market for influenza virus vaccines against interpandemic and pandemic threats is made and sustained. ********** Influenza virus vaccines were first developed in the 1940s and consisted of partially purified preparations of influenza viruses grown in embryonated eggs. Because of substantial contamination by egg-derived components, these killed (formaldehyde-treated) vaccines were highly pyrogenic pyrogenic /py·ro·gen·ic/ (pi?ro-jen´ik) febrifacient; causing fever. py·ro·gen·ic or py·rog·e·nous adj. 1. Producing or produced by fever. 2. and lacking in efficacy. A major breakthrough came with the development of the zonal ultracentrifuge ul·tra·cen·tri·fuge n. A centrifuge that uses high-velocity rotations to achieve the separation of colloidal or submicroscopic particles. ul in the 1960s (invented by Norman G. Anderson) (1). This technology, which originated from uses for military purposes, revolutionized the purification process and industrial production of many viruses for vaccines. To this day, it remains the basis for the manufacturing process of our influenza virus vaccines. Current influenza virus vaccines consist of 3 components: an H1N1 (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. [HA] 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. 1; neuraminidase neuraminidase /neu·ra·min·i·dase/ (-ah-min´i-das) an enzyme of the surface coat of myxoviruses that destroys the neuraminic acid of the cell surface during attachment, thereby preventing hemagglutination. [NA] subtype 1), an H3N2 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'; virus, and an influenza B influenza B n. Influenza caused by infection with influenza virus type B. influenza B Infectious disease An influenza virus which causes epidemics in 3-5 yr cycles. Cf Influenza A, Influenza C. virus. Specifically, the 2005 2006 vaccine formulation is made up of the A/New Caledonia/20/99 (H1N1), A/California/7/2004 (H3N2), and B/Shanghai/ 361/2002 viruses. Changes in the HA of circulating viruses (antigenic drift antigenic drift (an´tējen´ik), n the ability of viruses to alter their genetic makeup, thereby creating mutant antigens and bypassing the antibody barrier of the host. ) require periodic replacement of the vaccine strains during interpandemic periods. The World Health Organization publishes semiannual recommendations for the strains to be included for the Northern and Southern Hemispheres (2). To allow sufficient time fbr manufacture, in the United States the US Food and Drug Administration (FDA FDA abbr. Food and Drug Administration FDA, n.pr See Food and Drug Administration. FDA, n.pr the abbreviation for the Food and Drug Administration. ) determines in February which vaccine strains should be included in the following winter's vaccine. Unfortunately, FDA recommendations are not always optimal. For example, in 2003 FDA rejected the use of the most appropriate H3N2 strain, A/Fujian/411/ 2002, and instead again used the same strain as in the 2002 formulation. This decision was made primarily because the A/Fujian/411/2002 strain had first been isolated in Madin Darby canine kidney (MDCK MDCK Madin-Darby Canine Kidney Cells (virus tissue culture) ) cells rather than in embryonated eggs. Use of MDCK cells for virus isolation is not allowed by FDA's rules, which do not yet encompass advanced technologies or scientifically sound purification procedures based on limiting dilutions or cloning with 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. . Because of this bureaucratic roadblock, the H3N2 component of the 2003 2004 influenza virus vaccine was antigenically "off" and showed suboptimal Suboptimal A solution is called suboptimal if a part of the solution has been optimized without regards to the overall objective. efficacy. One hundred fifty-three pediatric pediatric /pe·di·at·ric/ (pe?de-at´rik) pertaining to the health of children. pe·di·at·ric adj. Of or relating to pediatrics. deaths were associated with influenza infections during the 2003-2004 season in 40 states, whereas only 9 such deaths had been reported in the following season (3). Also, because the cumbersome classical reassomnent technique used for preparing the appropriate seed strains makes the yearly process of manufacturing influenza virus vaccines unnecessarily lengthy, new variants first appearing early in the season are rarely considered for the vaccine formulation of the following winter. Currently Licensed Influenza Virus Vaccines Most influenza virus vaccines used in the United States and Europe consist of embryonated egg-grown and formaldehyde-inactivated preparations, which, after purification, are chemically disrupted with a nonionic detergent (for example, Triton X-100). The split virus preparations show lower pyrogenicity than whole virus vaccines. In general, 1 dose for adults contains the equivalent of 45 [micro]g HA (15 [micro]g HA for each of the 3 antigenic components). This dose is approximately the amount of purified virus obtained from 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. fluid of 1 infected embryonated egg. If 100 million doses of killed influenza virus vaccine are prepared, the manufacturer has to procure 100 million embryonated eggs. Clearly, this manufacturing process is dependent on the timely availability of embryonated eggs and the vaccine seed strains to be used in a particular season. Most of these prototype seed strains are provided to the manufacturers by government agencies, which create high-yielding strains through classical reassortment with a high-yielding laboratory strain, A/PR/8/34, following the procedures designed by Kilbourne (4). Unfortunately, only (high-yielding) influenza A viruses can be made in this way, and even with the A types, the 6:2 reassortants (HA and NA from recently circulating strains and the remaining 6 genes from A/PR/8/34 virus) are sometimes not easily obtained. This time-consuming process of reassortment is then followed by repeated passaging of the strain in embryonated eggs to allow for egg adaptation and growth enhancement. Influenza B virus prototype strains with good growth characteristics are usually obtained by direct and repeated passaging in embryonated eggs without attempting to generate reassortants. Although the manufacturing process is time-consuming, these killed influenza A and B virus vaccines are the workhorses for vaccination against influenza and have been shown time and again to be highly effective. The second major class of viral vaccines consists of live viruses. The only FDA-licensed product against influenza is the cold-adapted attenuated Attenuated Alive but weakened; an attenuated microorganism can no longer produce disease. Mentioned in: Tuberculin Skin Test attenuated having undergone a process of attenuation. vaccine. It is based on work originally done by Maassab's laboratory (5) and later by Murphy and colleagues (6). Influenza virus was passaged at 25[degrees]C in tissue culture (chicken kidney cells) and in embryonated eggs. This modified Jennerian approach resulted in a cold-adapted, temperature-sensitive, and highly attenuated master strain. The annually updated vaccine strains are generated in the laboratory by reassortment with viruses more closely related to the currently circulating ones. The resulting vaccine strains (both A and B types) are 6:2 reassortants with the 6 nonsurface protein genes derived from the cold-adapted master strains and the HA and NA from circulating A and B viruses, reflecting the changing antigenicity. These cold-adapted influenza virus vaccines are easily administered by nasal spray. They induce local mucosal neutralizing immunity and cell-mediated responses that may be longer lasting and more cross-protective than those elicited by chemically 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. (killed) vaccine preparations. Vaccine efficacy in vaccine-naive children 6 months to 18 years of age is high (range 73% 96%). In children revaccinated for a second season, vaccine efficacy climbs to 82% to 100% (7). Need for Improvement? Despite the obvious efficacy of both killed and live influenza virus vaccines, there is room for new developments. Among the critical issues in developing new and better vaccines are the following: price per dose, speed of production, ease of production, choice of substrates to grow the virus in or to express viral antigens, cross-protection for variant strains, efficacy in general and in immunologically naive populations, safety, and acceptance by the regulatory agencies and the public. New Adjuvants Most of the current inactivated influenza virus vaccines do not contain an adjuvant adjuvant /ad·ju·vant/ (aj?dbobr-vant) (a-joo´vant) 1. assisting or aiding. 2. a substance that aids another, such as an auxiliary remedy. 3. . To stretch the available supply, antigen-sparing adjuvant approaches should be considered (8). Alum is an adjuvant that has been approved by the FDA for use in several vaccines. MF59, a proprietary adjuvant from Chiron (Emeryville, CA, USA), has also been successfully used in several countries (other than the United States). If, under adjuvant conditions, a fifth or a tenth of the antigenic mass currently present per vaccine dose (45 [micro]g of HA protein) would suffice to stimulate an adequate protective response, a big supply problem would be solved. Many adjuvants are now under investigation. Liposome-like preparations containing cholesterol and viral particles (immune-stimulating complexes) have been successfully used in mice (9) by subcutaneous and mtranasal administration. Another adjuvant strategy involves the use of heat-labile Escherichia coli Escherichia coli (ĕsh'ərĭk`ēə kō`lī), common bacterium that normally inhabits the intestinal tracts of humans and animals, but can cause infection in other parts of the body, especially the urinary tract. toxin complexed with lecithin lecithin Any of a class of phospholipids (also called phosphatidyl cholines) important in cell structure and metabolism. They are composed of phosphate, choline, glycerol (as the ester), and two fatty acids. Various fatty acids pairs distinguish the various lecithins. vesicles and killed trivalent trivalent /tri·va·lent/ (tri-va´lent) having a valence of three. tri·va·lent adj. Having valence 3. tri·va influenza virus preparations for intranasal in·tra·na·sal adj. Within the nose. administration (10). Although this specific vaccine has been withdrawn because of Bell's palsy Bell's palsy n. See facial palsy. Bell's palsy Facial paralysis or weakness with a sudden onset, caused by swelling or inflammation of the seventh cranial nerve, which controls the facial muscles. cases associated with its administration, similar approaches may become more acceptable in the future if these safety issues can be resolved. Much work is also currently being conducted on synthetic adjuvants, such as synthetic lipid A, muramyl peptide derivatives, and cationic cationic having qualities dependent on having free cations available. cationic detergents are wetting agents that disrupt or damage cell membranes, denature proteins and inactivate enzymes. molecules (11). Also, Ichinohe et al. showed that poly (I:C) is a promising new and effective intranasal adjuvant for influenza virus vaccines (12). Genetically Engineered genetically engineered adjective Recombinant, see there Live and Killed Influenza Virus Vaccines As indicated, current FDA-licensed influenza vaccines are based on technologies developed in the 1960s and earlier. Through the breakthrough of reverse genetics techniques (13-15), infectious influenza viruses from plasmid DNAs transfected into tissue culture cells can now be rescued. This technology permits the construction of high-yield 6:2 seed viruses by mixing the 6 plasmid DNAs from a good-growing laboratory strain with the HA and NA DNAs obtained by cloning relevant genes from currently circulating viruses. Thus, within a 1- to 2-week period, the appropriate seed viruses could be generated for distribution to the manufacturers. The backbones of the 6:2 recombinant viruses could be prepared, tested, and distributed in advance. Similar approaches can be envisioned for the manufacturing of live, cold-adapted influenza virus vaccines. In this case, the backbone would consist of the 6 genes of the cold-adapted master strain. Again, the HA and NA of the currently circulating strains would be cloned and used for rescue in the plasmid-only reverse genetics system. Such an approach would have several advantages over the present manufacturing process. First, it would dramatically accelerate the timeframe for obtaining seed viruses for annual production and thus allow more time to select the appropriate antigenic seed strains. Second, it would standardize the seed viruses to be used. Regulatory agencies do not insist on a sequenced product to be given to humans but instead allow only partially characterized products for annual immunization immunization: see immunity; vaccination. . Third, DNA cloning may eliminate any adventitious ADVENTITIOUS, adventitius. From advenio; what comes incidentally; us adventitia bona, goods that, fall to a man otherwise than by inheritance; or adventitia dos, a dowry or portion given by some other friend beside the parent. agents present in the throat washings of the original isolate. Finally, in the case of the current highly pathogenic H5 strains, viruses with that HA (containing a multibasic HA1/HA2 cleavage site cleavage site n. See restriction site. ) kill embryonated eggs, making it difficult to use eggs as growth substrate. Also personnel involved in manufacturing those vaccines might be in danger of becoming infected. Thus, the HA of these virulent strains will need to be modified. Removal of the basic cleavage peptide by reverse genetics results in a virus that is attenuated for embryonated eggs, thus allowing high yields to be attained. Modification by reverse genetics results in a product that is easier to manufacture and safer to handle (this includes safety considerations for all persons working with the virus). Live Influenza Virus Vaccines with Altered Nonstructural Protein 1 Genes The ability to site specifically engineering changes in the influenza virus genome also allows us to consider novel vaccine approaches. We have demonstrated that the nonstructural protein 1 (NS1) of influenza viruses has interferon antagonist activity (16). Influenza viruses that lack NS1 cannot counter the interferon response of the host. Thus, infection of cells with a virus that lacks NS1 results in the induction of interferon and blockage of virus replication. When truncations are made in NS1, viruses are generated with an intermediate activity, which enables them to replicate in the host and also to induce an interferon response. By engineering a virus with intermediate virulence and ability to induce interferon, one can construct ideal influenza virus vaccines that are both attenuated and highly immunogenic im·mu·no·gen·ic adj. Producing an immune response. immunogenic producing immunity; evoking an immune response. (17-20). Interferon appears to be an excellent adjuvant that enhances production of immunoglobulins and contributes to the activation of dendritic cells required for antigen presentation (21-23). We thus believe that, per virus particle made oz antigen molecule delivered, the immune response immune response n. An integrated bodily response to an antigen, especially one mediated by lymphocytes and involving recognition of antigens by specific antibodies or previously sensitized lymphocytes. will be enhanced compared to that of conventional live or killed virus vaccines. This process should translate into lower doses of live virus vaccine required to induce a robust and protective immune response. If a hundredfold lower dose is required, many more people could have access to influenza virus vaccines. This issue is clearly of paramount importance in the event of a new pandemic virus. Moreover, a live virus vaccine may give protective immunity in immunologically naive populations after a single administration, while killed virus vaccines may require high antigenic doses and a prime-boost regimen to protect against a pandemic strain. It may turn out that only live influenza virus vaccines can provide the necessary protection in case of a new pandemic. Because live influenza virus vaccines appear to be more effective in immunologically naive populations and they can be intranasally administered, they would represent a more economical way of vaccinating large numbers of people. Replication-defective Vaccines Other promising approaches concern the use of replication-deficient preparations. For example, virus particles that lack the gene for the nuclear export protein (NEP NEP: see New Economic Policy. ; formerly NS2) will go through a single cycle of replication (without forming infectious particles) (24). Virus particles without the M2 gene may also fit this formula (25). Mass production of defective viruses can be achieved by using complementing cell lines. The administration of virosomes (consisting of reconstituted viral envelopes that lack 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 ), and the use of viruslike particles made by expression of viral proteins have also been shown to be effective immunization strategies against influenza (26,27). Yet another approach concerns DNA vaccination in humans by using plasmids that express [greater than or equal to] 1 foreign gene. Unfortunately, this approach has been less than convincing since it appears to work best in mice and other small mammals (28). Thus, the jury is still out as to whether this approach is reasonable for improving influenza virus vaccines in humans. Universal Vaccines? Influenza viruses continue to undergo antigenic drift, which is mostly reflected in accumulating changes in the HA. This fact requires us to change the vaccine formulation or at least to reexamine re·ex·am·ine also re-ex·am·ine tr.v. re·ex·am·ined, re·ex·am·in·ing, re·ex·am·ines 1. To examine again or anew; review. 2. Law To question (a witness) again after cross-examination. the seed strains on an annual basis. Unfortunately, predicting the evolutionary change of the viral HA has not been reliable (29). Thus, short of developing 20/20 foresight, predicting strain variation or the emergence of a particular pandemic strain (avian or otherwise) is unlikely (30). A more realistic approach is the design of more cross-protective vaccines for use in interpandemic years and during pandemics. Neirynck et al. have designed vaccines based on the conserved extracellular portion of the M2 protein fused to the hepatitis B Hepatitis B Definition Hepatitis B is a potentially serious form of liver inflammation due to infection by the hepatitis B virus (HBV). It occurs in both rapidly developing (acute) and long-lasting (chronic) forms, and is one of the most common chronic core protein (31). Such an immunogen may induce a cross-reactive response in the vaccinated host. Similarly, immunization with the NA antigen is likely to induce responses that are more cross-reactive than those by the more variable HA (32). In both cases, however, protection will require immune responses that are more vigorous than what is seen after natural infection. Antibodies against NA and M2 proteins in infected humans are generally not protective. Thus vaccines consisting of NA or M antigens would need to be adjuvanted or otherwise made to induce a dramatically enhanced immune response. Alternatively, genetically engineered viruses could be generated, which would express several variant antigens or epitopes, thereby achieving a more cross-protective immunization. Chimeric chi·mer·ic adj. 1. Relating to a chimera. 2. Composed of parts of different origin. HA recombinant viruses that express an additional 140 amino acids have recently been described (33). Such genetically engineered viruses may present several conserved immunogenic epitopes on the viral surface, which would be a first step toward a more universal influenza vaccine. Conclusions Technologies are now in place to design and construct new influenza virus vaccines that have the potential to be cheaper and more cross-protective than current vaccine preparations, while at the same time being equally safe. The greatest problems for new and better vaccines appear to be associated with regulatory hurdles and the lack of an adequate market. Regarding the bureaucratic restrictions levied on vaccines by licensing agencies, the message has to come through "that small risks have to be tolerated for larger ones to be avoided" (34). Also, the message needs to be disseminated to the general public that vaccines have the best cost-benefit ratio Cost-benefit ratio The net present value of an investment divided by the investment's initial cost. Also called the profitability index. of any medical treatment and that limitations of the tort law A body of rights, obligations, and remedies that is applied by courts in civil proceedings to provide relief for persons who have suffered harm from the wrongful acts of others. should be considered where vaccines are concerned. The public often views vaccines and prophylactic treatments in general as being of low priority. Many people also believe they should be free. Thus, the absence of a robust commercial market is a major difficulty, resulting in slow progress for research and development of new influenza vaccines and in dangerously thin supply lines. In fact, we are far from being prepared to deal with regular influenza outbreaks, and adequate measures to cope with a pandemic outbreak are only now being considered, but are not yet in place (35,36; and http://www. washingtonpost.com/wp-dyn/content/article/2005/11/01/ AR2005110101100.html). Work in Dr Palese's laboratory is supported by NIH "Not invented here." See digispeak. NIH - The United States National Institutes of Health. . Mount Sinai School of Medicine
Mount Sinai School of Medicine is a medical school found in the borough of Manhattan in New York City. holds intellectual property generated by the author in the area of reverse genetics. Dr Palese is also a consultant for several biotech and vaccine companies. References (1.) Gerin JL, Anderson NG. Purification of influenza virus in the K-II zonal centrifuge centrifuge (sĕn`trəfy  j), device using centrifugal force to separate two or more substances of different density, e.g., two liquids or a liquid and a solid. . Nature. 1969;221:1255 6. (2.) World Health Organization. Recommendations for influenza vaccine composition. [cited 2005 Nov 10]. Available from http://www.who. int/csr/disease/influenza/vaccinerecommendations1/en/ (3.) 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. . Update: Influenza Activity United States, 2004 05 Season. [cited 2005 Nov 10]. Available from hnp://www.cdc.gov/mmwr/preview/mmwrhtml/ nnn5408a1.htm (4.) Kilbourne ED. Future influenza vaccines and the use of genetic recombinants. Bull World Health Organ. 1969;41:643-5. (5.) Maassab H, Heilman C, Herlocher M. Cold-adapted influenza viruses for use as live vaccines for man. Adv Biotechnol Processes. 1990: 14:2034-2. (6.) Murphy BR, Coelingh K. Principles underlying the development and use of live attenuated cold-adapted influenza A and B virus vaccines. Viral Immunol. 2002;15:295 323. (7.) Stoddard J, Lee M-S M-S Master-Slave M-S Mid-Side (stereo recording technique) M-S Miznay-Shardin (mine plate charge) , Walker RE, Kemble G, Mendelman PM. Cross-protection against antigenic variants induced by live-attenuated influenza vaccine in children. In: Pediatric Academic Societies Annual Meeting, 2005 May 14-17, Washington, DC. (8.) Fedson DS. Preparing for pandemic vaccination: an international policy agenda for vaccine development. J Public Health Policy. 2005:26:4-29. (9.) Sambhara S, Kurichh A, Miranda R, Tumpey T, Rowe T, Renshaw M, et al. Heterosubtypic immunity against human influenza A viruses, including recently emerged avian H5 and H9 viruses, induced by FLU-ISCOM vaccine in mice requires both cytotoxic T-lymphocyte and macrophage macrophage /mac·ro·phage/ (mak´ro-faj) any of the large, mononuclear, highly phagocytic cells derived from monocytes that occur in the walls of blood vessels (adventitial cells) and in loose connective tissue (histiocytes, phagocytic function. Cell Immunol. 2001;211:143 53. (10.) Glueck R. Review of intranasal influenza vaccine. Adv Drug Deliv Rev. 2001:51:203-11. (11.) Fritz JH, Brunner S. Birnstiel ML, Buschle M, Gabain A, Mattner F, et al. The artificial antimicrobial peptide KLKLLLLLKLK induces predominantly a Th2-lypc immune response to co-injected antigens. Vaccine. 2004;22:3274-84. (12.) Ichinohe T, Watanabe I, Ito S, Fujii H, Moriyama M, Tamura S, et al. Synthetic double-stranded RNA poly(I:C) combined with mucosal vaccine protects against influenza virus infection. J Virol. 2005:79:2910-9. (13.) Neumann G, Watanabe T, Ito H, Watanabe S, Goto H, Gao P, et al. Generation of influenza A viruses entirely from cloned cDNAs. Proc Natl Acad Sci U S A. 1999;96:9345 50. (14.) Fodor E, Devenish, LJ, Palese P, Brownlee GG, Garcia-Sastre A. Rescue of influenza A virus from recombinant DNA recombinant DNA n. Genetically engineered DNA prepared by transplanting or splicing one or more segments of DNA into the chromosomes of an organism from a different species. Such DNA becomes part of the host's genetic makeup and is replicated. . J Virol. 1999;73:9679 82. (15.) Hoffmann E, Neumann G, Kawaoka Y, Hobom G, Webster RG. A DNA 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. system for generation of influenza A virus from eight plasmids. Proc Natl Acad Sci. U S A. 2000;97:6108 13. (16.) Garcia-Sastre A, Egorov A, Matassov D, Brandt S, Levy DE, Durbin JE, et al. Influenza A virus lacking the NS1 gene replicates in interferon-deficient systems. 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 . 1998;252:324-30. (17.) Talon J, Salvatore M, O'Neill RE, Nakaya Y, Zheng H, Muster T, et al. Influenza A and B viruses expressing altered NS1 proteins: A vaccine approach. Proc Natl Acad Sci U S A. 2000;97:4309 14. (18.) Solorzano A, Webby RJ, Lager KM, Janke BH, Garcia-Sastre A, Richt JA. Mutations in the NS1 protein of swine influenza swine influenza n. A highly contagious form of human influenza caused by a filterable virus identical or related to a virus formerly isolated from infected swine. Also called swine flu. vials impair anti-interferon activity and confer attenuation Loss of signal power in a transmission. Attenuation The reduction in level of a transmitted quantity as a function of a parameter, usually distance. It is applied mainly to acoustic or electromagnetic waves and is expressed as the ratio of power densities. in pigs. J Virol. 2005;79:7535-43. (19.) Quinlivan M, Zamarin D, Garcia-Sastre A, Cullinane A, Chambers T, Palese P. Attenuation of equine influenza viruses through truncations of the NS1 protein. J Virol. 2005;79:8431-9. (20.) Ferko B, Stasakova J, Romanova J, Kittel C, Sereinig S, Katinger H, et al. 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 protection efficacy of replication-deficient influenza A viruses with altered NS1 genes. J Virol. 2004;78:13037-45. (21.) LeBon A, Schiavoni G., D'Agostino G, Gresser I, Belardelli F, Tough DF. Type 1 interferons potently enhance humoral immunity humoral immunity n. The component of the immune response involving the transformation of B cells into plasma cells that produce and secrete antibodies to a specific antigen. and can promote isotype i·so·type n. An antigenic marker that occurs in all members of a subclass of an immunoglobulin class. i switching by stimulating dendritic cells in vivo. Immunity. 2001; 14:461-70. (22.) Proietti E, Bracci L, Puzelli S, Di Pucchio T, Sestili P, DeVincenzi E, et al. Type I IFN IFN abbr. interferon IFN interferon. IFN Interferon, see there as a natural adjuvant for a protecvie immune response: lessons from the influenza vaccine model. J Immunol. 2002;169:375-83. (23.) Bracci L, Canini I, Puzelli S, Sestili P, Venditti M, Spada M, et al. Type I IFN is a powerful mucosal adjuvant for a selective intranasal vaccination against influenza virus in mice and affects antigen capture at mucosal level. Vaccine. 2005;23:2994-3004. (24.) Watanabe T, Watanabe S, Neumann G,, Kida H, Kawaoka Y. Immunogenicity and protective efficacy of replication-incompetent influenza virus-like particles. J Virol. 2002;76:767-73. (25.) Watanabe T, Watanabe S, Kida H, Kawaoka Y. Influenza A virus with detective M2 ion channel activity as a live vaccine. Virology. 2002;299:266 70. (26.) Huckricde A, Bungener L, Stegmann T, Daemen T, Medema J, Palache AM, Wilschut J. The virosome concept for influenza vaccines [review]. Vaccine. 2005;23 Suppl 1:S26-8. (27.) Galarza JM, Latham T, Cupo A. Virus-like particle (VLP VLP Virus-like particles, see there ) vaccine conferred complete protection against a lethal influenza virus challenge. Viral Immunol. 2005;18:244-1. (28.) Singh DK, Liu Z, Sheffer D, Mackay GA, Smith M, Dhillon S, et al. A noninfectious simian/human immunodeficiency virus DNA vaccine that protects macaques against AIDS. J Virol. 2005;79:3419-28. (29.) Ferguson NM, Anderson RM. Predicting evolutionary change in the influenza A virus. Nat Med. 2002;8:562 63. (30.) Palese P. Influenza: old and new threats. Nat Med. 2004;10:S82-7. (31.) 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. (32.) Kilbourne ED, Couch RB, Kasel JA, Keitel WA, Cate TR, Quarles JH, et al. Purified influenza A virus N2 neuraminidase vaccine is immunogenic and non-toxic in humans. Vaccine. 1995;13:1799-803. (33.) Li ZN, Mueller SN, Ye L, Bu Z, Yang C, Ahmed R, et al. Chimeric influenza virus hemagglutinin proteins containing large domains of the Bacillus anthracis protective antigen: protein characterization, incorporation into infectious influenza viruses, and antigenicity. J Virol. 2005;79:10003-12. (34.) Epstein RA. It did happen here: fear and loathing fear and loathing - (Hunter S. Thompson) A state inspired by the prospect of dealing with certain real-world systems and standards that are totally brain-damaged but ubiquitous - Intel 8086s, COBOL, EBCDIC, or any IBM machine except the Rios (also known as the RS/6000). on the vaccine trail. Health Affairs. 2005;24:740-3. (35.) Webby RJ, Webster RG. Are we ready for pandemic influenza? Science. 2003;302:1519-22. (36.) Check E. Avan flu special: is this our best shot'? Nature. 2005;435: 404-6. Address for correspondence: Peter Palese, 1 Gustave Levy Place, New York, NY, 10029, USA; tax: 212-722-3634; email: peter.palese@ mssm.edu Use of trade names is for identification only and does not imply endorsement by the Public Health Service or by the U.S. 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 . Peter Palese, Mount Sinai School of Medicine, New York, New York, USA Dr Palese is a professor of microbiology and chairman of the Department of Microbiology at Mount Sinai School of Medicine. His research interests are the replication of RNA-containing viruses, especially influenza viruses, and the genetic analysis of influenza viruses to determine the functions of genes and gene products. He elucidated the genetic maps of influenza A, B, and C viruses and the precise measurements of their mutation rates and also developed the first reverse genetics technology that enabled the manipulation and analysis of influenza and other negative-strand RNA viruses. Dr. Palese is a member of the National Academy of Sciences and currently president of the American Society for Virology. He is also a senior scholar of the Ellison Medical Foundation. |
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