Phenotypic and genetic analyses of the heterogeneous population present in the cold-adapted master donor strain: A/Leningrad/134/17/57 (H2N2)

For the past three decades the cold-adapted (ca) and temperature sensitive (ts) master donor strain, A/Leningrad/134/17/57 (H2N2) has been successfully used as the basis for the live attenuated reassortant influenza A vaccine. This donor strain was developed from A/Leningrad/134/57 (H2N2) wild-type (wt) virus following 17 passages in eggs at 25 degrees C. Our detailed investigation has revealed that the A/Leningrad/134/17/57 (Len/17) master donor stock is a mixed population comprised of numerous variants of the ca/ts Len/17 influenza virus. We have identified these variants to exhibit a broad range in their temperature sensitive phenotype when assayed on Madin-Darby canine kidney (MDCK) cells at 37 degrees C. A selection of these variant clones has been fully characterized by sequencing in order to understand the variability in the ts phenotype. This study has also addressed the feasibility of using cell culture technology for the propagation and subsequent manufacturing of the cold-adapted influenza vaccine (CAIV), particularly with respect to retaining the defined mutations that contribute toward the ca/ts phenotype.     

Reassortment and evolution of current human influenza A and B viruses

During the 2001-2002 influenza season, human influenza A (H1N2) reassortant viruses were detected globally. The hemagglutinin (HA) of these H1N2 viruses was similar to that of the A/New Caledonia/20/99 (H1N1) vaccine strain both antigenically and genetically, while their neuraminidase (NA) was antigenically and genetically related to that of recent human influenza H3N2 reference viruses such as A/Moscow/10/99. All six internal genes of the H1N2 reassortants originated from an H3N2 virus. After being detected only in eastern Asia during the past 10 years, Influenza B/Victoria/2/87 lineage viruses reappeared in many countries outside of Asia in 2001. Additionally, reassortant influenza B viruses possessing an HA similar to that of B/Shandong/7/97, a recent B/Victoria/2/87 lineage reference strain, and an NA closely related to that of B/Sichuan/379/99, a recent B/Yamagata/16/88 lineage reference strain, were isolated globally and became the predominant influenza B epidemic strain. The current influenza vaccine is expected to provide good protection against H1N2 viruses because it contains A/New Caledonia/20/99 (H1N1) and A/Panama/2007/99 (H3N2) like viruses whose H1 HA or N2 NA are antigenically similar to those of recent circulating H1N2 viruses. On the other hand, widespread circulation of influenza B Victoria lineage viruses required inclusion of a strain from this lineage in influenza vaccines for the 2002-2003 season.     

Phenotypic properties resulting from directed gene segment reassortment between wild-type A/Sydney/5/97 influenza virus and the live attenuated vaccine strain

Widespread use of a live-attenuated influenza vaccine (LAIV) in the United States (licensed as FluMist) raises the possibility that vaccine viruses will contribute gene segments to the type A influenza virus gene pool. Progeny viruses possessing new genotypes might arise from genetic reassortment between circulating wild-type (wt) and vaccine strains, but it will be difficult to predict whether they will be viable or exhibit novel properties. To begin addressing these uncertainties, reverse-genetics was used to generate 34 reassortant viruses derived from wt influenza virus A/Sydney/5/97 and the corresponding live vaccine strain. The reassortants contained different combinations of vaccine and wt PB2, PB1, PA, NP, M, and NS gene segments whereas all strains encoded wt HA and NA glycoproteins. The phenotypes of the reassortant strains were compared to wt and vaccine viruses by evaluating temperature-sensitive (ts) plaque formation and replication attenuation (att) in ferrets following intranasal inoculation. The results demonstrated that the vaccine virus PB1, PB2, and NP gene segments were dominant when introduced into the wt A/Sydney/5/97 genetic background, producing recombinant viruses that expressed the ts and att phenotypes. A dominant attenuated phenotype also was evident when reassortant strains contained the vaccine M or PA gene segments, even though these polypeptides are not temperature-sensitive. Although the vaccine M and NS gene segments typically are not associated with temperature sensitivity, a number of reassortants containing these vaccine gene segments did exhibit a more restricted ts phenotype. Overall, no reassortant strains were more virulent than wt, and in fact, 33 of the 34 recombinant viruses replicated less efficiently in infected ferrets. These results suggest that genetic reassortment between wt and vaccine strains is unlikely to produce viruses having novel properties that differ substantially from either progenitor, and that the likely outcome of reassortment will be attenuated viruses.     

Cell-based assay for the determination of temperature sensitive and cold adapted phenotypes of influenza viruses

The determination of temperature sensitive (ts) and cold adapted (ca) phenotype for influenza A and B strains has been conducted traditionally using embryonated chicken eggs. As attempts are made to move away from the use of eggs in the manufacturing process of influenza vaccines, it will become useful to develop cell-based assays to support cell culture-based vaccine production. In this study, MDCK cells have been evaluated as a tool for determining the ts and ca phenotypes associated with live attenuated influenza viruses. Direct comparisons were made of these phenotypes carried out in eggs. Reassortants made from the Russian live attenuated influenza donor strains A/Leningrad/134/17/57 (H2N2) and B/USSR/60/69 were prepared entirely in MDCK cells and their phenotypes evaluated using the MDCK cell-based assay. It is concluded that MDCK cells are more sensitive than eggs for the measurement of ts and ca phenotype of influenza viruses (particularly for influenza A) and they provide an alternative means for screening candidate reassortants prior to determining their genome composition.     

Live cold-adapted influenza A vaccine produced in Vero cell line

The African green monkey kidney (Vero) cell line was used as a substrate for the development of a live cold-adapted (ca) reassortant influenza vaccine. For that purpose, a new master strain was generated by an adaptation of the wild type (wt) A/Singapore/1/57 virus to growth at 25 degrees C in a Vero cell line. The resulting cold-adapted (ca) muster strain A/Singapore/1/57ca showed temperature sensitive (ts) phenotype and was attenuated in animal models and protective in the challenge experiments in ferrets. Two vaccine candidates of influenza A(H1N1) and A(H3N2) subtypes (6/2 reassortants) inheriting six genes coding internal proteins from the new master strain and the surface antigens hemagglutinin (HA) and neuraminidase (NA) from the epidemic viruses were obtained by a standard method of genetic reassortment. All steps of the vaccine preparation were done exclusively in Vero cells, including the isolation of the epidemic viruses. Both vaccine strains were used for immunization of young adult volunteers in a limited clinical trial and appeared to be safe, well tolerated and immunogenic after intranasal administration.     

Analysis of mutations in the genome of cold-adapted strains of influenza A virus using extended modification of polymerase chain restriction method

Cold-adapted influenza viruses A/Leningrad/13 4/17/5 7 (H2N2) (Len/17) and A/Leningrad/I 34/4 7/57 (H2N2) (Len/47) are used in Russia to prepare live reassortant cold-adapted influenza vaccines (LIV) for adults and children, respectively. Comparison between the nucleotide sequences of the Len/17 strain and the initial wild-type strain A/Leningrad/13 4/5 7 (H2N2) revealed ten nucleotide substitutions (eight of them encoding). Four additional substitutions (three encoding) were found in the genome of the Len/47 virus. Gene segment restriction site (PCR-restriction) analysis was used for identification of the genotype of reassortant influenza viruses. Conventional methods of PCR-restriction analysis detect only five encoding nucleotides substitutions in the internal genes of the Len/17 and seven substitutions in the internal genes of the Len/47 virus. An extended modification of the PCR-restriction method detect all encoding mutations in the internal genes of the Len/17 and Len/47 viruses (eight and eleven encoding substitutions, respectively). This method is advantageous for genome composition analysis of reassortant influenza vaccine strains and for investigating the genetic stability of LIV during replication in vaccines.     

An evaluation of the genetic stability and pathogenicity of the Russian cold-adapted influenza A donor strains A/Leningrad/134/17/57 and A/Leningrad/134/47/57 in ferrets

The influenza A components of live attenuated vaccines used in Russia have been prepared as reassortants of the cold-adapted (ca) H2N2 viruses, A/Leningrad/134/17/57-ca (Len/17) and A/Leningrad/134/47/57-ca (Len/47), and virulent epidemic strains. The lesions responsible for attenuation within the six internal genes of each donor strain have been sequenced and described, but relatively little is known as to their stability before and after passage in susceptible hosts. In the work reported in this paper, RT-PCR restriction analysis and limited sequencing of individual genes were used to evaluate the stability of lesions in stocks of the both donor strains after passage in ferrets, which have been used widely as susceptible hosts for assessment of the virulence of influenza strains. Len/47 was shown to possess expected lesions by RT-PCR and restriction analysis. Substitution at position 1066 of the NP gene, which has been previously reported to be unique to Len/47 [Klimov et al., Virology 186 (1992) 795], was also shown to be present in all clones of Len/17. This change was confirmed by limited sequence analysis and was shown to be retained in progeny viruses isolated from the lungs and turbinates of inoculated ferrets. Two other changes in the PB2 and PB1 genes that were present in Len/47 were detected by limited sequence analysis alone. Further previously unreported minor changes were shown to be present for Len/17 and Len/47, but not both, and their significance is unknown. Limited replication of each donor strain occurred in ferrets and minimal clinical signs and histopathology were present. By contrast, the parental strain Len/57 and the recent epidemic strain A/Sydney/6/97 induced clinical signs and histopathology that were typical of influenza disease.     

Restriction analysis of genome composition of live influenza vaccine

Live attenuated cold-adapted influenza vaccine (LIV) has been used in Russia for over 50 years and proved to be safe and effective. Currently, Russian reassortant LAIV is based on influenza AILeningrad/134/17/57 (H2N2) and B/USSR/60/69 Master Donor Viruses (MDVs) which are cold-adapted (ca), temperature-sensitive (ts), and attenuated (att), respectively. The MDVs are used to generate attenuated reassortant vaccine viruses containing the surface antigens of current wild type (wt) influenza A (HINI) and A (H3N2) viruses and wt influenza B virus. The ca/ts/att phenotype of these viruses limits replication in the upper respiratory tract. Reassortment typically yields numerous viruses with different genome constellations, rapid screening is needed to select proper vaccine viruses. In this study, screening of reassortant vaccine strains for live attenuated influenza vaccine generated from currently circulating influenza A and B viruses by RFLP assay is described.     

Sequence changes in the live attenuated, cold-adapted variants of influenza A/Leningrad/134/57 (H2N2) virus.

Nucleotide sequences were determined for the RNA segments coding for proteins other than the hemagglutinin and neuraminidase of the A/Leningrad/134/57 (H2N2) wild-type (A/Len/wt) virus and its two cold-adapted (ca) and attenuated variants, A/Leningrad/134/17/57 (A/Len/17/ca) and A/Leningrad/134/47/57 (A/Len/47/ca) that are used in the U.S.S.R. in the preparation of reassortant live attenuated vaccines. Ten nucleotide differences were detected between the sequences of the A/Len/wt and A/Len/17/ca viruses; of these, eight were deduced to encode amino acid (aa) substitutions. One aa substitution each was predicted for the PB2, M1, M2, and NS2 proteins, whereas two aa substitutions each were predicted for the PB1, and PA proteins of the A/Len/17/ca virus. Four additional nucleotide changes were found in the genome of the A/Len/47/ca virus; three of these were detected to code for one additional aa substitution each for the PB2, PB1, and NP proteins.     

A live attenuated cold-adapted influenza A H7N3 virus vaccine provides protection against homologous and heterologous H7 viruses in mice and ferrets

The appearance of human infections caused by avian influenza A H7 subtype viruses underscores their pandemic potential and the need to develop vaccines to protect humans from viruses of this subtype. A live attenuated H7N3 virus vaccine was generated by reverse genetics using the HA and NA genes of a low pathogenicity A/chicken/BC/CN-6/04 (H7N3) virus and the six internal protein genes of the cold-adapted A/Ann Arbor/6/60 ca (H2N2) virus. The reassortant H7N3 BC 04 ca vaccine virus was temperature sensitive and showed attenuation in mice and ferrets. Intranasal immunization with one dose of the vaccine protected mice and ferrets when challenged with homologous and heterologous H7 viruses. The reassortant H7N3 BC 04 ca vaccine virus showed comparable levels of attenuation, immunogenicity and efficacy in mice and ferret models. The safety, immunogenicity, and efficacy of this vaccine in mice and ferrets support the evaluation of this vaccine in clinical trials.     

Characterization of Reverse Genetics-Derived Cold-Adapted Master Donor Virus A/Leningrad/134/17/57 (H2N2) and Reassortants with H5N1 Surface Genes in a Mouse Model

Live attenuated influenza vaccines (LAIV) offer significant advantages over subunit or split inactivated vaccines to mitigate an eventual influenza pandemic, including simpler manufacturing processes and more cross-protective immune responses. Using an established reverse genetics (rg) system for wild-type (wt) A/Leningrad/134/1957 and cold-adapted (ca) A/Leningrad/134/17/1957 (Len17) master donor virus (MDV), we produced and characterized three rg H5N1 reassortant viruses carrying modified HA and intact NA genes from either A/Vietnam/1203/2004 (H5N1, VN1203, clade 1) or A/Egypt/321/2007 (H5N1, EG321, clade 2) virus. A mouse model of infection was used to determine the infectivity and tissue tropism of the parental wt viruses compared to the ca master donor viruses as well as the H5N1 reassortants. All ca viruses showed reduced replication in lungs and enhanced replication in nasal epithelium. In addition, the H5N1 HA and NA enhanced replication in lungs unless it was restricted by the internal genes of the ca MDV. Mice inoculated twice 4 weeks apart with the H5N1 reassortant LAIV candidate viruses developed serum hemagglutination inhibition HI and IgA antibody titers to the homologous and heterologous viruses consistent with protective immunity. These animals remained healthy after challenge inoculation with a lethal dose with homologous or heterologous wt H5N1 highly pathogenic avian influenza (HPAI) viruses. The profiles of viral replication in respiratory tissues and the immunogenicity and protective efficacy characteristics of the two ca H5N1 candidate LAIV viruses warrant further development into a vaccine for human use.     

Genetics of cold-adapted B/Ann Arbor/1/66 influenza virus reassortants: the acidic polymerase (PA) protein gene confers temperature sensitivity and attenuated virulence

The cold-adapted B/Ann Arbor/1/66 influenza virus (ca B/AA/1/66) expresses temperature-sensitive (ts), cold-adapted (ca) and attenuation phenotypes. Reassortants which inherit one or more genes from ca B/AA/1/66 and all other genes from a virulent, wild-type influenza virus, B/Houston/1732/76, were produced and evaluated in order to identify the gene(s) responsible for the ts, ca and attenuation phenotypes. Only reassortants which inherited the PA gene from ca B/AA/1/66 expressed the ts phenotype in MDCK cells at 39 degrees C. None of the reassortants tested expressed the ca phenotype in embryonated eggs at 25 degrees C. The virulence of several reassortants was evaluated in ferrets. Inheritance of the PA gene from ca B/AA/1/66 was correlated with significant febrile attenuation and the apparent restriction of viral replication in the lower respiratory tract. Isolation of a virulent, non-ts revertant virus inheriting only the PA gene from ca B/AA/1/66 established a direct relationship between expression of the ts phenotype and attenuated virulence. Evidence for the contribution of at least one other gene from ca B/AA/1/66 to attenuation was observed. Thus, based on the methods used to determine reassortant gene compositions, these results indicate that the PA gene is primarily responsible for attenuation of ca B/AA/1/66 and its reassortants.     

Live influenza vaccine: laboratory markers of attenuation

Screening for candidate reassortants is an important step in the development of live influenza vaccine (LIV). The temperature-sensitive (ts) and cold-adapted (ca) phenotypes of vaccine strains are generally determined, by employing chicken embryos, and used as ts and ca attenuation markers. However, it is difficult to use the egg-determined ts phenotypes of vaccine candidate reassortants as an attenuation marker due to a wide circulation of natural ts epidemic influenza viruses. This study used two new alternative ts and ca attenuation markers in MDCK cells. The MDCK cell line was shown to be able to differentiate cold-adapted influenza viruses from any epidemic strains whereas they were undistinguishable when using eggs. The reduced ability of influenza type A vaccine viruses to grow in the MDCK cell culture at temperatures above 37 degrees C can be successfully used as a "cell-culture" ts marker. The similar marker for influenza B viruses may serve their reduced activity in the MDCK cells at 38 degrees C. The high reproductive activity of cold-adapted viruses in the MDCK cells at 26 degrees C was shown to be a suitable ca attenuation marker. The presented attenuation markers may be included into the standard scheme of primary screening of ts reassortant candidates for commercial live influenza vaccine as additional selection factors and may be used as basic markers in the design of culture vaccine.     

Evaluation of live avian-human reassortant influenza A H3N2 and H1N1 virus vaccines in seronegative adult volunteers.

An avian-human reassortant influenza A virus deriving its genes coding for the hemagglutinin and neuraminidase from the human influenza A/Washington/897/80 (H3N2) virus and its six "internal" genes from the avian influenza A/Mallard/NY/6750/78 (H2N2) virus (i.e., a six-gene reassortant) was previously shown to be safe, infectious, nontransmissible, and immunogenic as a live virus vaccine in adult humans. Two additional six-gene avian-human reassortant influenza viruses derived from the mating of wild-type human influenza A/California/10/78 (H1N1) and A/Korea/1/82 (H3N2) viruses with the avian influenza A/Mallard/NY/78 virus were evaluated in seronegative (hemagglutination inhibition titer, less than or equal to 1:8) adult volunteers for safety, infectivity, and immunogenicity to determine whether human influenza A viruses can be reproducibly attenuated by the transfer of the six internal genes of the avian influenza A/Mallard/NY/78 virus. The 50% human infectious dose was 10(4.9) 50% tissue culture infectious doses for the H1N1 reassortant virus and 10(5.4) 50% tissue culture infectious doses for the H3N2 reassortant virus. Both reassortants were satisfactorily attenuated with only 5% (H1N1) and 2% (H3N2) of infected vaccines receiving less than 400 50% human infectious doses developing illness. Consistent with this level of attenuation, the magnitude of viral shedding after inoculation was reduced 100-fold (H1N1) to 10,000-fold (H3N2) compared with that produced by wild-type virus. The duration of virus shedding by vaccines was one-third that of controls receiving wild-type virus. At 40 to 100 50% human infectious doses, virus-specific immune responses were seen in 77 to 93% of volunteers. When vaccinees who has received 10(7.5) 50% tissue culture infectious doses of the H3N2 vaccine were experimentally challenged with a homologous wild-type human virus only 2 of 19 (11%) vaccinees became ill compared with 7 of 14 (50%) unvaccinated seronegative controls ( P < 0.025; protective efficacy, 79%). Thus, three different virulent human influenza A viruses have been satisfactorily attenuated by the acquisition of the six internal genes of the avian influenza A/Mallard/NY/78 virus. The observation that this donor virus can reproducibly attenuate human influenza A viruses indicates that avian-human influenza A reassortants should be further studied as potential live influenza A virus vaccines.     

Nucleotide sequences of the neuraminidase genes of influenza A/Leningrad/134/57 (H2N2) virus and two of its live,attenuated, cold-adapted variants

The nucleotide sequences of the neuraminidase (NA) genes of the A/Leningrad/134/57 (H2N2) wild-type (Len/wt) virus as well as two of its live attenuated, cold-adapted (ca) variants, A/Leningrad/134/17/57 (Len/17) and A/Leningrad/134/47/57 (Len/47), were determined. In comparison with Len/wt, one nucleotide change (C-225 to A) was found in the NA gene of Len/17. This change codes for a Thr-to-Asn substitution at position 69 of NA. The NA gene of the more attenuated Len/47 ca virus has one silent (T-814 to C) and two coding nucleotide substitutions, C-78 to T (Ala-20 to Val) and C-225 to A (Thr-69 to Asn). These sequence data were used to design a PCR-restriction technique to determine the origin of the NA gene in candidate live, attenuated vaccine reassortants made by reassorting these ca strains with current field viruses.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned accession numbers L37329-L37331.     

Genetic and phenotypic analysis of heterogeneous population of a cold-adapted donor of the A/Leningrad/134/17/57 (H2N2) attenuation and of the donor-based reassortant influenza vaccine strains

Cold-adapted (CA) temperature sensitive and attenuated virus A/Leningrad/134/17/57 (H2N2) (Len/17) has been recently used in Russia as a donor of internal genes in the preparation of reassortant vaccine strains of CA live influenza vaccine (LIV) for all age groups. The Len/17 population was found to be heterogeneous and to be made up of clones, which differ by combinations of mutations in internal genes. Around 50% of the Len/17 population had clones with all 8 coding mutations in internal genes. The others were made up of clones with mutation combinations, which were different from the original Len/17. The PCR restriction method was used to analyze 5 clones of Len/17 and 8 LIV vaccine strains. There were no Ala-86-Thr mutation in the M2 protein in 4 clones and 3 vaccine strains. The PB-1 gene of 4 clones and 3 vaccine strains had a mutation encoding Met-317-IIe more typical of a more attenuated virus A/Leningrad/134/47/57 (H2N2) (Len/47). The NP protein of a clone had a mutation Leu-341-IIe also typical of Len/47. However, neither the absence of mutation in the M2 gene nor an extra mutation in the PB1 gene affected the attenuation extent of reassortant CALIV.     

A 36 nucleotide deletion mutation in the coding region of the NS1 gene of an influenza A virus RNA segment 8 specifies a temperature-dependent host range phenotype

Previously a spontaneous 36 nucleotide deletion in the coding region of NS1 was detected in the NS gene of a reassortant virus (CR43-3) recovered from a dual infection by the influenza A/Ann Arbor/6/60 cold-adapted (ca) mutant and wild-type (wt) influenza A/Alaska/6/77 (H3N2). The hemagglutinin, neuraminidase and NS genes were derived from the wild type virus parent while the other 5 genes were derived from the ca parent. The CR43-3 reassortant virus exhibited: (i) a host range (hr) phenotype, i.e. the reassortant replicated efficiently in avian cells in tissue culture but failed to grow in mammalian (MDCK) cell culture and (ii) an attenuation (att) phenotype, i.e., the reassortant was restricted in replication in the upper and lower respiratory tract of ferrets and hamsters. Since the CR43-3 reassortant possessed 5 genes from the ca parent which are each known to contain one or more mutations, it was not possible to assign the hr and att phenotypes solely to the NS deletion mutant gene. In order to determine the phenotype(s) specified solely by the mutant NS gene, it was transferred into a reassortant virus (143-1) which derived its seven other genes from the homologous wild type A/Alaska/6/77 virus. The deletion mutant NS gene specified only a partial hr phenotype manifested by a reduction in plaque size in MDCK tissue, but not a reduction in plaque number. Thus, the complete hr manifested by the CR43-3 parent virus is specified by the mutant NS1 gene acting in concert with one or more genes derived from the ca virus. The clone 143-1 virus exhibited the ts phenotype and was restricted in plaque formation at 37 degrees C in MDCK cells, a level of temperature sensitivity previously shown with other ts mutants to correlate with significant restriction of viral replication in the lower respiratory tract of hamsters. However, the clone 143-1 virus grew almost as well as the wt virus in the upper and lower respiratory tracts of hamsters and chimpanzees and thus did not possess the att phenotype. The finding that the ts phenotype was not manifest in vivo in animals with a 37 degrees C core temperature indicates that the mutated NS1 gene specifies a host dependent ts phenotype with replication restricted in vitro (MDCK tissue culture) at 37 degrees C but not in vivo in the lungs of hamsters and chimpanzees. ts+ virus was readily recovered from infected hamsters and chimpanzees indicating that the ts phenotype specified by the 36-base deletion was not stable following replication in vivo.(ABSTRACT TRUNCATED AT 400 WORDS)     

Elicitation of broadly neutralizing influenza antibodies in animals with previous influenza exposure

The immune system responds to influenza infection by producing neutralizing antibodies to the viral surface protein, hemagglutinin (HA), which regularly changes its antigenic structure. Antibodies that target the highly conserved stem region of HA neutralize diverse influenza viruses and can be elicited through vaccination in animals and humans. Efforts to develop universal influenza vaccines have focused on strategies to elicit such antibodies; however, the concern has been raised that previous influenza immunity may abrogate the induction of such broadly protective antibodies. We show here that prime-boost immunization can induce broadly neutralizing antibody responses in influenza-immune mice and ferrets that were previously infected or vaccinated. HA stem-directed antibodies were elicited in mice primed with a DNA vaccine and boosted with inactivated vaccine from H1N1 A/New Caledonia/20/1999 (1999 NC) HA regardless of preexposure. Similarly, gene-based vaccination with replication-defective adenovirus 28 (rAd28) and 5 (rAd5) vectors encoding 1999 NC HA elicited stem-directed neutralizing antibodies and conferred protection against unmatched 1934 and 2007 H1N1 virus challenge in influenza-immune ferrets. Indeed, previous exposure to certain strains could enhance immunogenicity: The strongest HA stem-directed immune response was observed in ferrets previously infected with a divergent 1934 H1N1 virus. These findings suggest that broadly neutralizing antibodies against the conserved stem region of HA can be elicited through vaccination despite previous influenza exposure, which supports the feasibility of developing stem-directed universal influenza vaccines for humans.     

Identification of PR8 M1 protein in influenza virus high-yield reassortants by M1-specific monoclonal antibodies

A panel of monoclonal antibodies to the M1 protein of A/PR8/34 (H1N1) (PR8) influenza A virus was found to distinguish in ELISA high-yielding reassortant viruses derived from reassortment of PR8 and X-31 (H3N2) viruses with recently prevalent field strains of H1N1 or H3N2 subtype. These findings are concordant with results of genotyping that demonstrated the presence of PR8 RNA 7 or M1 protein in high-yield reassortants by RNA or protein PAGE. All high-yield vaccine candidate reassortants Application of the M1 monoclonal antibody panel facilitates the isolation of high-yield vaccine candidate reassortants bearing the PR8 M1 gene, and should aid in epidemiologic strain tracking as well.     

Development of a live culture of cold-adapted reassortant influenza vaccines

Optimal conditions for the cultivation of the MDCK cell lines in the laboratory spinner or by using the Eagle-MEM with or without fetal serum were worked out. The cold-adapted reassortant vaccine strains of virus influenza A/H1N1, A/H3N2 and B are well replicated in the MDCK cells both in a monolayer and in the spinner by using the serum-free medium. A maximum virus titer depends on a multiplicity of infection used in a fetal medium and on the addition of trypsin. Under the optimal conditions, the titer of the studied cold-adapted reassortants, while using a serum-free medium, reaches as much as 10(9.0)-10(9.5) EID50/ml.