[The generation and characteristics of reassortant influenza A virus with H5 hemagglutinin and other genes from the apathogenic virus H6N2].

The experimental reassortant vaccine strain VN-gull (H5N2) containing H5 hemagglutinin (HA) with a removed polybasic site in the connecting peptide and other genes from the apathogenic H6N2 virus A/gull/Moscow/3100/2006 (gull/M) was obtained using a two-step protocol. At Step 1, the reassortant with HA of A/Vietnam/1203/04-PR8/ CDC-RG and other genes from cold-adapted A/Leningrad/17/47 (VN-Len) viruses was generated due to selection with antibody to H2N2 at 26 degrees C. At Step 2, the reassortant VN-gull was obtained by replacing all genes from Len with those from gull/M due to selection with antibody to H6N2 at 39 degrees C. The reassortant VN-Len was apathogenic and the reassortant VN-gull was weakly virulent in mice. Both gave rise to specific antibodies and 4 weeks after single inoculation they provided complete protection against further challenge with highly pathogenic HSN1 virus A/chicken/Kurgan/3/05 (H5N1) (Ku-Len). The chickens infected with live VN-gull virus showed neither clinical symptoms, nor fecal virus excretion; nevertheless, they gave rise to antibodies and were protected from the further challenge with A/chicken/Kurgan/3/2005. The high yield, safety, and protectivity of VN-Len and Ku-Len made them promising strains for the production of inactivated and live vaccines against H5N1 viruses.

[A possible association of fatal pneumonia with mutations of pandemic influenza A/H1N1 sw1 virus in the receptor-binding site of the HA1 subunit].

The paper gives the results of sequence analysis of 150 positive samples in real-time RT-PCR, including 47 autopsy materials from patients (including 10 pregnant women), who died from fatal pneumonia mainly in November-December 2009, in whom the lifetime etiological diagnosis had not been made and hence no early etiotropic therapy performed. 70% of the primary materials from the deceased patients were found to have pandemic influenza A(H1N1) v mutants in the lung tissue with D222G (15%), D222N (15%), D222E (2%) substitutions, as well as a mixture of mutants (38%). Nasopharyngeal lavages from 3 Chukotka deceased patients exhibited only consensus (nonmutant) D222 virus variants; there was a mixture of consensus and mutant virus variants in the trachea and a mixture of mutant ones in the lung. Preliminary data from the study of the interaction of the hemagglutinin of two strains having D222G and D222N mutations with 9 oligosaccharides imitating the variants of cell receptors for influenza A virus suggest that there is a double receptor specificity for alpha2'-3' and alpha2'-6'-sialosides with a preponderance of alpha2'-3'-specificity. Further spread of the mutants that have acquired a high virulence and preserved their capacity for the respiratory route of human infection may lead to the situation similar to that seen in the 1918-1919 pandemic. Another scenario for evolution of the virus is to preserve its receptor specificity for alpha2'-3'-sialosides and high virulence with losses of alpha2'-6' specificity and capacity for aerosol transmission, by damping the pandemic.

[The study of the nonpathogenic influenza virus A/gull/Moscow/3100/2006 (H6N2) isolated in Moscow].

The influenza virus A/gull/Moscow/3100/2006 (H6N2) was isolated from gull feces within the precincts of Moscow in autumn 2006. The nucleotide sequence of the complete genome (GenBank, EU152234-EU152241) and genotype (K, G, D, 6B, F, 2D, F, 1E) for this virus were determined. Phylogenetic analysis suggests that the H6N2 virus derived by numerous reassortment between viruses that have been circulating among different birds in Europe since 1999 and in South-East Asia (NA gene) for last years. Migratory birds probably introduced some of these viruses from South-East Asia earlier. The strain A/gull/Moscow/3100/2006 is nonpathogenic for chicken embryos and mice and induces specific antibody production in mice. Similar to all avian influenza viruses A/gull/Moscow/3100/ 2006 it binds to Neu5Ac(2-3Gal receptors, but reveals higher affinity for fucosylated sialosugars (SLex) in contrast to the duck viruses, as was shown in receptor specificity assay and clarified due to modeling the accommodation of SLex into receptor binding site of duck and gull influenza virus hemagglutinin.

[Development of a diagnostic test system on the basis of sandwich ELISA for the detection of avian influenza A virus].

A panel of hybridomas producing monoclonal antibodies (MAbs) to nucleocapsid protein (NP) of avian influenza A virus was obtained. On the basis of 2 MAbs, the authors designed an antigen-bound ELISA (sandwich ELISA), in which NP3 MAbs were used as antigen-bound antibodies and NP MAbs conjugated with horse radish peroxidase as antigen detection antibodies. The specificity of the test system to avian influenza virus was determined. The developed test system was ascertained to specifically detect influenza A virus of all study subtypes and to yield no cross reactions with other tested virus pathogens. The sensitivity of the sandwich ELISA was 30 ng/ml of NP in the urine-treated virus preparations. The assay was tested on experimental H5N1-infected mice. The findings positively correlated with the results of postmortem studies and with the virus isolation method in the chick embryos. The developed test system may be used to detect avian influenza A virus as an alternative or supplement to other diagnostic techniques.

[A/H13 and A/H16 influenza viruses: different lines of one precursors].

Analysis of the data of annual (1980-2005) monitorings of influenza A viruses in the North Caspian Sea basin and the Volga river delta, as well as the primary hemagglutinin structure of isolates of different years revealed the circulation of A/H13 and A/H16 viruses among gulls since 1976. Phylogenetic analysis revealed 3 significantly different evolutionary lines: an American line, a European line, and a line comprising the isolates from America and Eurasia. The H13N6 and H16N3 viruses isolated in Russia replicated in the respiratory and intestinal tracts of ducks and induced the production of antibodies; the H16N3 viruses induced the antibodies neutralizing viruses of subtype H16 only. The use of glycoconjugate polymers showed that the receptor phenotype of the study H16 viruses differed from that of the H13 viruses in its capacity to bind to 3'SL with a higher affinity than alphaNANA. The comparative phylogenetic analysis suggests the existence of the common precursor of H13 and H16 viruses and their further evolution in relation to environmental conditions, including their adaptation to a new host.

[Infection of pigs with influenza A/H4 and A/H5 viruses isolated from wild birds on the territory of Russia].

Pigs were intranasally infected with avian influenza A/H5 (H5N1, H5N3) and A/H4 (H4N6, H4N8) viruses in mono- and coinfection. Infection with both apathogenic and pathogenic strains caused no clinical manifestations. A virus and/or fragments of its genome retained in nasopharyngeal fluid as long as 6-8 days after infection. During monoinfection, the structure of the hemagglutinin (HA) receptor site of isolates from the pigs infected with A/H5N1 strains (A/chicken/Kurgan/3/2005, A/duck/Russia/5354-vac/2005) and A/H5N3 (A/duck/Primorje/2633/01) remained unchanged during 6-7 days. When two animals infected with avirulent A/H5N3 viruses (A/duck/Primorje/2633/01, A/duck/Altai/1285/91) that differed in immunogenic properties were kept together, the A/duck/Altai/1285/91 virus that induced a later IgG generation was prevalent in the nasopharyngeal fluid of both animals. Moreover, 4 significant nucleotide replacements were detected in the HA gene on days 7-8. Infection of pigs with avian influenza A/H4 viruses yielded the similar results. The joint keeping of animals infected with Algarganey teal/Astrakhan/309/102 (H4N8) strain and A/ musk beaver/Buryatia/944/00 (H4N6) isolated from musk beaver exhibited fragments of "a variant" of the identical structure in the nasal swabs of both animals on days 7-8. A nucleotide sequence from 37 nucleotide replacements differing from both baseline sequences was revealed in the HA 364-1045 gene region. The amino acid sequence of the variant was similar to Algarganey teal/Astrakhan/3091/02, other than one position 264 < Lys > (numeration by H3), which coincided with the A/ musk beaver/Buryatia/1944/00 strain. The latter induced the antibody generation on day 5 after infection while the A/garganey teal/Astrakhan/3091/02 strain did only on day 14. It is possible that under co-circulation of two different influenza A viruses, the virus causing a slower development of an immune response showed a higher probability of transiting to another host (specimen) and changing the HA receptor site in the organism of a new host.

[Isolation of influenza virus A (Orthomyxoviridae, Influenza A virus), Dhori virus (Orthomyxoviridae, Thogotovirus), and Newcastle's disease virus (Paromyxoviridae, Avulavirus) on the Malyi Zhemchuzhnyi Island in the north-western area of the Caspian Sea].

The paper presents the results of the 2003 and 2006 environmental virological monitoring surveys on the Malyi Zhemchuzhnyi Island where a large breeding colony of sea gull (Laridae) is located. In the past several years, expansion of cormorants (Phalacrocorax carbo) has enhanced the intensity of populational interactions. The investigators isolated 13 strains of influenza A virus (Orthomyxoviridae, Influenza A virus) subtype H13N1 (from sea gulls (n = 4), cormorants (n = 9) 1 strain of Dhori virus (Orthomyxoviridae, Thogotovirus) from a cormorantwith clinical symptoms of the disease, 3 strains of Newcastle disease virus (Paramyxoviridae, Avulavirus) from cormorants. RT-PCR revealed influenza A virus subtype H5 in 3.1% of the cloacal lavages from cormorants. Neutralization test indicated that sera from cormorants contained specific antibodies against West Nile (Flaviviridae, Flavivirus) (15.0%), Sindbis (Togaviridae, Alphavirus) (5.0%), Dhori (10.0%), and Tahini (Bunyaviridae, Orthobunyavirus) (5.0%); sera from herring gulls had antibodies against Dhori virus (16.7%); there were no specific antibodies to Inco (Bunyaviridae, Orthobunyavirus) and mountain hare (Lepus timidus) (Bunyaviridae, Orthobunyavirus) virus.

[Complex environmental and virological monitoring in the Primorye Territory in 2003-2006].

The paper presents the results of monitoring of viruses of Western Nile (WN), Japanese encephalitis (JE), tick-borne encephalitis (TBE), Geta, Influenza A, as well as avian paramicroviruses type I (virus of Newcastle disease (ND)) and type 6 (APMV-6) in the Primorye Territory in 2003-2006. Totally throughout the period, specific antibodies to the viruses were detected by neutralization test in wild birds (7.3%, WN; 8.0%, Geta; 0.7% Batai; 2.8%, Alpine hare (Lepus timidus); by hemagglutination-inhibition test in cattle (11.4% WN; 5.9%, JE; j 3.0%, TBE; 11.6%, Geta), horses (6.1, 6.8, 0, and 25.3%, respectively), and pigs (5.4, 1.5, 0, and 5.9%, respectively) by enzyme immunoassay (IgG) in human beings (0.8, 0.5, 6.8, and 3.2%, respectively. Reverse-transcription polymerase chain reaction (RT-PCR) was used to reveal RNA of the NP segment of influenza A virus in 57.9 and 65% of the cloacal swabs from wild and domestic birds, respectively; and the HA-segment of subtype HH was not detected in 2005. HA/H5 RNA was recorded in 5.5 and 6.7% of the swabs from wild and domestic birds, respectively; 6% of the specimens from domestic birds were M-segment positive in 2006. RNA of influenza A virus NA/H7 and RNA was not detected throughout the years. In 2004, the cloacal swabs 8 isolated influenza A strains: two H3N8 and two H4N8 strains from European teals (Anas crecca), two (H3N8 and H6N2) strains from Baikal teals (A. formosa), one (H10N4) strain from shovelers (A. clypeata), and one (H4N8) from garganeys (A. querquedula). In 2004, one ND virus strain was isolated from the cloacal swabs from European teals (A. crecca). RT-PCR revealed RNA of this virus in some 8 more cloacal swabs from black ducks (A. poecilorhyncha) (3 positive specimens), pheasants (Phasianus colchicus) (n = 2), garganeys (A. querquedula) (n = 1), gadwalls (A. strepera) (n = 1), and geese (Anser anser domesticus) (n = 1). Sequencing of the 374-member fragment of the ND virus F gene, which included a proteolytic cleavage site, could assign two samples to the weakly pathogenetic variants of genotype 1, one sample to highly pathogenic variants of genotype 3a, five to highly pathogenic ones of genotype 5b. Isolation of APMV-6 (2003) from common egrets (Egretta alba) and geese (Ans. anser domesticus) is first described.

[Molecular genetic characteristics of the Newcastle Sterna/Astrakhan/Z275/2001 virus isolated in Russia].

The genome of the NDV strain Sterna/Astrakhan/2755/2001 isolated from a wild bird of the Volga River delta in 2001 was completely sequenced. The phylogenetic analysis of the strain investigated and other NDV strains clearly demonstrated that Sterna/Astrakhan/2755/ 2001 belonged to the lineage 5b. Comparative analysis of molecular genetic markers of pathogenicity of strain Sterna/Astrakhan/2755/ 2001 allows its velogenic character to be suggested.

[Molecular virological monitoring of Newcastle disease virus strains (Paramyxoviridae, Avulavirus) in the populations of wild birds in the Volga estuary (the 2001 data)].

The paper analyzes the results of isolation of Newcastle disease virus (NDV) strains from 336 swaps of 31 wild bird species collected in the 2001 summer in the Volga estuary (Astrakhan Region). Twenty-seven NDV strains were isolated from little terns (Sterna albifrons) (n=11; infection rate, 24.4%), great cormorants (Phalacrocorax carbo) (n=6; 11.1%), coots (Fulica atra) (n=8; 6.5%), sandwich terns (Sterna sandvicensis) (n=1; 100%), and common redshanks (Tringa totanus) (n=1; 50.0%). Four strains were sequenced by the 374 n. a. residue fragment from the beginning of the F gene, one of them was by the full F gene, and another (Stemal/Astrakhan/2755/2001) was by the full genome. Nucleotide sequences have allowed the authors to classify corresponding NDV strains as 5b genotype and the analysis of the amino acid sequence of the F-protein cleavage site has shown them to belong to a non-pathogenic group.

[Different receptor specificity of influence viruses from ducks and chickens and its reflection in the composition of sialosides on host cells and mucins].

The ability of influenza viruses from different hosts to bind to the intestinal epithelium of various birds (Anseriformes (Anatidae), Galliformes, Charadriiformes (sandpipers and sea gulls), Ciconiiformes (storks), Podicipediformes (grebes), and Gruiformes was studied. The composition of sialo-containing receptors on the epithelia was examined, by using lectins. Intestinal epitheliocytes of the Anatidae (Anseriformes) family was shown to have a low content of receptors binding both Sambucus nigra agglutinin (SNA) lectin specific to Siaalpha-6Gal, and Maackia amurensis agglutinin (MAA) lection specific to Siaalpha2-2Gal. Nevertheless, these cells well bound duck influenza viruses. The intestinal epithelium of Ciconiiformes, Podicipediformes, and Gruiformes well bound MMA lection, but avian influenza viruses weakly bound the latter. The intestinal cells of Gallinaceae bound both MMA and SNA lectins and avian and human influenza viruses. Thus, the composition of natural sialosides is different in various avian species whereas the receptor specificity of influenza viruses from various hosts reflects these differences. This can be accounted for by the differences in the ability of influenza viruses from different birds to break through the interspecies barrier, infecting mammals and human beings in particular.

[Newcastle disease virus in the populations of wild birds in the south of the Primorye Territory in the period of autumn migrations in 2001-2004].

The paper presents the results of molecular virological monitoring of Newcastle disease virus (NDV) by reverse-polymerase chain reaction (followed by sequence of F-gene fragment 374 p.n.) and chick embryo isolation of samples from the avian cloacal swabs collected in the south of the Primorye Territory in September-October 2001-2004. It shows that before 2004, there were only slightly pathogenic variants of NDV of genotype 1 in this region and in 2004 they were added by highly pathogenic variants of subtypes 3a and 5b. The impact of landscaping features of the south of the Primorye Territory on the environment of NDV is discussed.

[Cross-population interactions of influenza A viruses in man and animals].

The paper considers the molecular mechanisms of host specificity of influenza A viruses, which are associated with the crossing of host-specificity barriers, which may give rise to new pathogenic variants and a subsequent risk of a pandemic.

[Effects of antiviral agents on the reproduction of avian influenza virus A/H5 isolated in Russia].

The antiviral agents rimantadine, ribavirine, and tamiflu were tested for the effects on the reproduction of avian influenza virus A/H5 in in vitro experiments. The findings evidence the selective inhibitory effect of these agents on the reproduction of these viruses in the cultured MDCK cells.

[Sensitivity of influenza A/H5 viruses isolated from wild birds on the territory of Russia to arbidol in the cultured MDCK cells].

The effect of the antiviral drug arbidol on the reproduction of avian influenza A/H5 viruses was studied in in vitro experiments. The strains were isolated from the wild birds of Eastern Siberia and they were closely related to the 1997-2000 viruses from South-Eastern Asia. Arbidol was shown to exert a selective inhibiting effect on the reproduction of these viruses in the MDCH cell cultures.

[Differences in receptor specificity between the influenza A viruses isolated from the duck, chicken, and human]. / Sravnenie retseptornoi spetsifichnosti virusov grippa A, vydelennykh ot utok, kur i cheloveka.

The affinity of the duck, chicken, and human influenza viruses to the host cell sialosides was determined, and considerable distinctions between duck and chicken viruses were found. Duck viruses bind to a wide range of sialosides, including the short-stem gangliosides. Most of the chicken viruses, like human ones, lose the ability to bind these gangliosides, which strictly correlates with the appearance of carbohydrate at position 158-160. The affinity of the chicken viruses to sialoglycoconjugates of chicken intestine as well as chicken, monkey, and human respiratory epithelial cells exceeds that of the duck viruses. The human influenza viruses have high affinity to the same cells but do not bind at all to the duck epithelial cell. This testifies to the absence of 6'-sialylgalactose residues from the duck cells, in contrast to chicken and monkey cells. The alteration of the receptor specificity of chicken viruses in comparison with duck ones results in the similarity of the patterns of accessible cells for chicken and human influenza viruses. This may be the cause of the appearance of the line of H9N2 viruses from Hong Kong live bird markets with receptor specificity similar to that of H3N2 human viruses, and of the ability of H5N1 and H9N2 chicken influenza viruses to infect humans.

[Intracellular "sorting" of highly marked (3H)-v-RNA during maturation of influenza virus]. / Vnutrikletochnaia "vybrakovka" vysokomechennykh [3H]-v-RNK pri sozrevanii virusa grippa.

In the presence of [3H]-nucleosides the high-labeled viral [3H]-RNAs are shown to be sorted out and not included into maturing viral particles in the cells infected by influenza virus. Finding of the "sorting out" mechanism came to be possible due to storing cells in the cold for a long time and thus permitting to accumulate [3H]-decays under the conditions of temporary interruption of infectious process. Most probably, the high-labeled [3H]-RNAs are not included into the maturing viral particles due to their radiolytic damages. The "sorting out" of high-labeled viral RNAs is evidently compensated by comparatively low-labeled RNAs from the redundant intracellular pool of v-RNAs.

[Study of the host glycosyl component of the influenza virus using monoclonal antibodies]. / Izuchenie glikozil'nogo khoziaiskogo komponenta virusa grippa s ispol'zovaniem monoklonal'nykh antitel.

The crossreacting glycosylated host component (COHC) of influenza virus propagated in chick embryo has been studied using the monoclonal antibodies (MA). The specificity of MA to COHC has been demonstrated by different methods. Both MA of clones A9 and B7 react with the spatially overlapping antigenic sites of oligosaccharide chain, but only MA of B7 are active in hemagglutination inhibition test. The COHC is shown to be associated with both surface glycoprotein adsorbing on the surface of the virion. The study of the components from the allantonic fluid has shown the COHC to be associated with the sole embryo glycoprotein with the mol. mass around 150 kD and p1 9.0-9.5. Thus, the glycoprotein is possibly identical with the glycoprotein adsorbing on the virion surface. The content of COHC in various preparations of influenza virions has been also studied. The relative content of COHC is shown to increase during the purification of viral preparation. The COHC effect on the characteristics of vaccine preparations is discussed.

[Radioimmunological analysis of the antigenic variability of influenza virus nucleoprotein]. / Radioimmunologicheskii analiz antigennoi variabel'nosti nukleoproteina virusa grippa.

Influenza A virus ability to bind anti-NP monoclonal antibodies to two viral strains has been studied by radioimmunoassay on polyethylene film with the subsequent autoradiographic registration of results. Monoclonal antibodies were obtained to the viral strains differing in antigenic formula of outer glycoproteids and isolated at different time. The studied influenza viruses were divided into seven groups due to their ability to bind monoclonal antibodies. The absence of correlation between the antigenic properties of nucleoprotein and glycoproteids has been registered. Variability of some antigenic sites has been analyzed. The human epidemic strains of influenza virus are different in ability to bind monoclonal antibodies from the viral strains that are connected with animals in nature or laboratory practice.

[Formation of mixed hemagglutinin trimers during double infection with influenza virus strains of the same subtype]. / Formirovanie smeshannykh trimerov gemaggliutinina pri dvoinoi infektsii, vyzvannoi shtammami virusa grippa, prinadlezhashchikh k odnomu podtipu.

Formation of hemagglutinin spikes in the course of the mixed infection of cell culture by two influenza virus strains belonging to the same antigenic subtype or to different subtypes was studied by means of immunoprecipitation of [14C]-labelled hemagglutinins from cell lysates. The immunoprecipitates were further analysed by polyacrylamide gel electrophoresis. Lysates of separately infected cells mixed before lysis were used as control samples. The analysis of immunoprecipitates revealed the formation of chimeric hemagglutinin spikes in the cells infected by the strains possessing hemagglutinins of the same subtype but not in the cells infected by the strains of different subtypes (H1 and H3). The results are discussed in connection with the homology of amino-acid sequences of influenza virus hemagglutinins.