Sequential mutations in the NS genes of influenza virus field strains

Correlation of polymerase replication fidelity with genetic evolution of influenza A/Fujian/411/02(H3N2) viruses

Influenza virus evolves continuously through mutations presumed to result from evolutionary pressure driving viral replication. This study examined the relationship between the genetic evolution and replication fidelity of influenza viruses. Analysis of influenza sequences from National Centre for Biotechnology Information (NCBI) database revealed a gradual decrease in the rate of genetic evolution of A/Fujian/411/02(H3N2)-like variants after the emergence and predominance of the A/H3N2 Fujian strain in 2002. This decrease may be related to an increase in replication fidelity, which was investigated by assessing mutation frequencies of reassortant viruses carrying the PB1 segment of Fujian variants isolated between 2003 and 2005 in a sequencing-based plaque assay. The data revealed a threefold decrease in substitution per site of the reassortant viruses carrying the Fujian PB1 segments isolated in 2004-2005 compared with those circulating in 2003. The decrease in mutation frequency paralleled a decrease in genetic evolution of the Fujian variants from the NCBI database. This correlation implicates changes in the polymerase replication fidelity as contributing to altered genetic evolution of influenza viruses.

A Closer Look at the NS1 of Influenza Virus

The Non-Structural 1 (NS1) protein is a multifactorial protein of type A influenza viruses that plays an important role in the virulence of the virus. A large amount of what we know about this protein has been obtained from studies using human influenza isolates and, consequently, the human NS1 protein. The current global interest in avian influenza, however, has highlighted a number of sequence and functional differences between the human and avian NS1. This review discusses these differences in addition to describing potential uses of NS1 in the management and control of avian influenza outbreaks.

Oral administration of heat-killed Lactobacillus plantarum L-137 enhances protection against influenza virus infection by stimulation of type I interferon production in mice

We have previously reported that heat-killed Lactobacillus plantarum L-137 (HK-LP) stimulates macrophage/dendritic cells to produce T helper (Th) 1-related cytokines in vitro and in vivo in mice. We here examined the effect of oral administration of HK-LP on protection against influenza virus infection in mice. C57BL/6 mice were orally given HK-LP from day -7 to 7 and intranasally infected with influenza virus A/FM/1/47 (H1N1, a mouse-adapted strain) at 100 pfu on day 0. The survival time was significantly prolonged in mice treated with HK-LP than that in mice treated with PBS as controls. The viral titers in the lung were significantly lower in mice treated with HK-LP than controls at the early stage after influenza virus infection. An appreciable level of interferon (IFN)-beta was detected in the serum of mice treated with HK-LP, while no IFN-beta was detected in controls after influenza infection. Our results suggest that HK-LP, a potent IFN-beta inducer, is useful for prevention against influenza infection.

Genetic analysis of human H2N2 and early H3N2 influenza viruses, 1957-1972: evidence for genetic divergence and multiple reassortment events

Phylogenic analysis of all gene segments of human H2N2 viruses isolated from 1957 to 1968 was undertaken to better understand the evolution of this virus subtype. Human H3N2 viruses isolated from 1968 to 1972 were also examined to investigate genetic events associated with their emergence in humans and to identify the putative H2N2 ancestral virus. All gene segments of human H2N2 viruses demonstrated divergent evolution into two distinct clades (I and II) among late H2N2 isolates. All gene segments of 1968 H3N2 viruses that were retained from human H2N2 viruses were most similar to clade I H2N2 genes. However, genes of both clades were found among H3N2 isolates of 1969-1971. Unique phylogenic topologies reflected multiple reassortment events among late H2N2 or H3N2 viruses that resulted in a variety of different genome constellations. These results suggest that H2N2 viruses continued to circulate after 1968 and that establishment of H3N2 viruses in humans was associated with multiple reassortment events that contributed to their genetic diversity.

Phylogenetic analysis of the entire genome of influenza A (H3N2) viruses from Japan: evidence for genetic reassortment of the six internal genes

Nucleotide sequences of all eight RNA segments of 10 human H3N2 influenza viruses isolated during a 5-year period from 1993 to 1997 were determined and analyzed phylogenetically in order to define the evolutionary pathways of all genes in a parallel fashion. It was evident that the hemagglutinin and neuraminidase genes of these viruses evolved essentially in a single lineage and that amino acid changes accumulated sequentially with respect to time. In contrast, amino acid differences in the internal proteins were erratic and did not accumulate over time. Parallel analysis of the phylogenetic patterns of all genes revealed that the evolutionary pathways of the six internal genes were not linked to the surface glycoproteins. Genes coding for the basic polymerase-1, nucleoprotein, and matrix proteins of 1997 isolates were closest phylogenetically to those of earlier isolates of 1993 and 1994. Furthermore, all six internal genes of four viruses isolated in the 1995 epidemic season consistently divided into two distinct branch clusters, and two 1995 isolates contained PB2 genes apparently originating from those of viruses before 1993. It was apparent that the lack of correlation between the topologies of the phylogenetic trees of the genes coding for the surface glycoproteins and internal proteins was a reflection of genetic reassortment among human H3N2 viruses. This is the first evidence demonstrating the occurrence of genetic reassortment involving the internal genes of human H3N2 viruses. Furthermore, internal protein variability coincided with marked increases in the activity of H3N2 viruses in 1995 and 1997.

Influence of host species on the evolution of the nonstructural (NS) gene of influenza A viruses

The matrix (M) and nonstructural (NS) genes of influenza A viruses each encode two overlapping proteins. In the M gene, evolution of one protein affects that of the other. To determine whether or not this evolutionary influence operating between the two M proteins also occurs in the NS gene, we sequenced the NS genes of 36 influenza A viruses isolated from a broad spectrum of animal species (wild and domestic birds, horses, pigs, humans, and sea mammals) and analyzed them phylogenetically, together with other previously published sequences. These analyses enabled us to conclude the following host species-related points that are not found in the other influenza A virus genes and their gene products. (1) The evolution of the two overlapping proteins encoded by the NS gene are lineage-dependent, unlike the M gene where evolutionary constraints on the Ml protein affect the evolution of the M2 protein (Ito et al.. J. Virol. 65 (1991) 5491 5498). (2) The gull-specific lineage contained nonH13 gull viruses and the non-gull avian lineage contained H13 gull viruses, indicating that the gull-specific lineage does not link to the H13 HA subtype in the NS gene unlike findings with other genes. (3) The branching topology of the recent equine lineage (H7N7 viruses isolated after 1973 and H3N8) indicates recent introduction of the NS, M, and PB2 genes into horses from avian sources by genetic reassortment.

The origin and evolution of human T-cell lymphotropic virus types I and II

Studies on human T-cell lymphotropic virus types I (HTLV-I) and II (HTLV-II) are briefly reviewed from the viewpoint of molecular evolution, with special reference to the evolutionary rate and evolutionary relationships among these viruses. In particular, it appears that, in contrast to the low level of variability of HTLV-I among different isolates, individual isolates form quasispecies structures. Elucidating the mechanisms connecting these two phenomena will be one of the future problems in the study of the molecular evolution of HTLV-I and HTLV-II.

Expression of the nonstructural protein NS1 of equine influenza A virus: detection of anti-NS1 antibody in post infection equine sera

The nucleotide sequence of the nonstructural protein NS1 of the influenza virus A/equine 2/Suffolk/89 was determined and found to be 97% identical to that of A/equine 2/Miami/63. A similar level of identity was shown for the deduced NS1 amino acid sequence. The NS1 gene was expressed, in its entirety and in part, as fusion proteins with glutathione S-transferase using the pGEX-3X expression vector. Antibodies to NS1 protein were detected in serum samples from ponies experimentally infected with influenza virus, but not in animals vaccinated with whole inactivated virus or in unprimed control animals. The antigenic determinant(s) of NS1 protein appear to be located in the C-terminal half of the protein. The implications of these findings are discussed with reference to the use of NS1 protein as a differential diagnostic marker for influenza virus infection in the presence of high levels of circulating antibody to influenza haemagglutinin generated by recent vaccination.

Naturally occurring NS gene variants in an avian influenza virus isolate

The A/Turkey/Wisconsin/68 (H5N9) isolate of avian influenza (AI) consists of two virus populations which have different NS genes and differ in their biological responses in chicken embryos. They were classified as being either rapidly embryo-lethal (REL) or slowly embryo-lethal (SEL), (Avian Dis., 33 (1989) 695-706). In this study, sequence analysis identified only two nucleotide differences between the two NS genes, creating single amino acid differences in both the NS1 and the NS2 protein. The difference in the NS1 protein appears to be neutral, while the differences in the NS2 places a phenylalanine at position 48. This amino acid has not been previously demonstrated at this position in an NS2 sequence and its presence results in a distinct hydrophobic shift in the region. The sequence specifying the phenylalanine also creates an EcoRI site in the cDNA of the REL NS gene. Analysis of several clones showed that this site appears to co-segregate with the REL characteristic. Molecular differences between the two NS gene variants were reflected by differences in the kinetics of early protein synthesis in infected cells. In particular, the NS2 protein is in higher concentration (relative to the NS1) in SEL-infected cells than in REL-infected cells. No differences were detectable, however, in the rates of viral replication, either in cell culture or in embryos. Also, the REL or SEL rate was established early during infection of the embryo and could not be competed out by the other variant population 3 h after inoculation. Thus, these two natural NS gene variants appear to specify early differences which influence the time of death of an infected embryo but the differences do not appear to influence virus replication.

Evolution of the fusion protein gene of human parainfluenza virus 3

The nucleotide sequences of the fusion (F) gene of 15 clinical strains of human parainfluenza virus 3 (HPIV3) isolated between 1959 and 1987 were compared with the F gene sequence of the prototype strain, Wash/47885/57. Nucleotide sequence diversity was greatest in the noncoding regions of the F gene; however, regions believed to function as transcriptional signals were completely conserved. Amino acid sequences were highly conserved and all but a few amino acid substitutions were conservative in nature. Sequence comparisons indicate heterogeneity in HPIV3 F genes; however, a significant proportion of nucleotide changes are maintained after they first appear and seem to be accumulating with time. Phylogenetic analysis suggests that there are 2 lineages of HPIV3 in North America. The two lineages can be distinguished by specific amino acid differences in the F protein, which correlate with differences in antigenic properties and neutralization patterns of HPIV3. The pattern of HPIV3 evolution, based on the analysis of F gene sequences, most closely resembles that of influenza virus B, vesicular stomatitis virus and Newcastle disease virus.

Phylogenetic relationship of the nonstructural (NS) genes of influenza A viruses

Phylogenetic trees were constructed using 38 sequences of the A group and 10 sequences of the B group of the NS gene of influenza A viruses. Within the A group we found avian as well as mammalian influenza a viruses, while within the B group exclusively avian strains were found. The avian and human NS genes of the A group were derived from a common ancestor existing at about 1912. At 13 positions of the amino acid sequences of the NS1 protein two subtypes of the A group can be differentiated, a human and a non-human subtype. Starting at the time of the introduction of an avian PB1 gene into human strains during the antigenic shift at 1957 the NS1 protein of the human strains came under an enhanced selection pressure which might indicate a cooperation of the NS1 protein with and adaptation of the NS1 protein on the newly introduced PB1 gene. Such a selection pressure on the NS2 protein is completely missing. Comparison of all sequences of the NS1 protein revealed four highly conserved regions within the amino-terminal half of the molecule. One of this regions seems to contain the nuclear migration signal. The carboxy-terminal half is completely variable and seems to be dispensable.

New viruses and new disease: mutation, evolution and ecology

Given the extraordinarily high mutation rate of viruses, particularly those with RNA genomes, it is not surprising that new viruses are continually evolving. However, the symptomatology of old viral diseases has remained stable for centuries. The combination of genetic and ecological factors that constrain as well as facilitate the emergence of new viruses is analyzed.

Evolution of pig influenza viruses

There is evidence that the nucleoprotein (NP) gene of the classical swine virus (A/Swine/1976/31) clusters with the early human strains at the nucleotide sequence level, while at the level of the amino acid sequence, as defined by consensus amino acids and in functional tests, its NP is clearly "avian like." Therefore it was suggested that the Sw/31 NP had been recently under strong selection pressure, possibly caused by reassortment with other avian influenza genes, whose gene products have to cooperate intimately with NP (Gammelin et al., 1989. Virology 170, 71-80). This suggestion has been investigated by sequencing the genes of internal and nonstructural proteins of Sw/31. The data on these sequences and on the phylogenetic trees are not in accordance with that suggestion: all these genes cluster with the early human strains at the nucleotide level while, at the level of the amino acid sequence, most of them are more closely related to the avian strains, thus resembling NP in this respect. This indicates that these genes rather evolved concomitantly with the NP gene. Our data are in agreement with the suggestion that, at about the time of the Spanish Flu (1918/19), a human influenza A (H1N1) virus entered the pig population. Furthermore, it is known that the NP of the human influenza A viruses--in contrast to that of the avian and swine strains--has been under strong selection pressure to change (Gammelin et al., 1990. Mol. Biol. Evol. 7, 194-200. Gorman et al., 1990a. J. Virol. 64, 1487-1497). Thus, after transfer of a human strain into pigs, the selection pressure might be released, enabling the NP and the other genes of the swine virus to evolve back to the optimal avian sequences, especially at the functionally important consensus positions. The swine influenza viruses circulating since 1979 in Northern Europe--represented by A/Swine/Germany/2/81 (H1N1)--have all genes, so far examined, derived from an avian influenza virus pool and are different from the classical swine viruses.

Antigenic and genetic variation in influenza A (H1N1) virus isolates recovered from a persistently infected immunodeficient child

Antigenic and genetic variations have been analyzed in eight consecutive isolates recovered from a child with severe combined immunodeficiency syndrome persistently infected with naturally acquired type A (H1N1) influenza virus over a 10-month period. Hemagglutination inhibition reactions and T1 oligonucleotide fingerprinting demonstrated that these viruses were related to strains causing outbreaks in the United States at that time (1983 to 1984) but that antigenic and genetic differences between consecutive isolates could be detected. This variation between isolates was examined further by sequencing the RNAs encoding the HA1 region of the hemagglutinin (HA) and the nucleoprotein (NP) in five of the consecutive isolates. Multiple point mutations were detected in both genes, and a deletion of one amino acid was detected in the HA. Depending on the isolates compared, 5.8 x 10(-3) to 17 x 10(-3) substitutions per nucleotide site per year were detected in the RNAs encoding the HA1, and 3.5 x 10(-3) to 24 x 10(-3) substitutions per nucleotide site per year were detected in the NP gene. Fifty-four percent of the base changes in the HA1 and 73% in the NP led to amino acid substitutions. A progressive accumulation of mutations over time was not observed, suggesting that the genetic diversity of these viruses may best be interpreted as the result of shifts in the population equilibrium (quasi-species) of replicating variant genomes.

Evolution of the NS genes of the influenza A viruses. I. The genetic relatedness of the NS genes of animal influenza viruses

We compared the nucleotide sequences of the NS genes of 13 animal influenza viruses belonging to human, swine, avian, and equine viruses for the study of the genetic relatedness of the NS genes in animal influenza viruses. The NS genes of three virus strains A/chicken/Brescia/02, A/equine/Prague/56, and A/equine/Miami/63 were newly sequenced. The base sequence homologies between the NS genes of avian, human, swine, and the A/equine/Miami/63 viruses were 87.8% or higher. On the other hand, the base sequence of the NS gene of the A/equine/Prague/56 virus differed widely from those of other viruses analyzed in the present study. We constructed a model of the genetic tree of the NS genes of avian and equine influenza viruses by a modified Farris method. For comparison of the NS genes between human and avian viruses, we estimated the speed of the nucleotide substitutions of the avian influenza NS genes. It was roughly constant, even though the substitutions did not occur sequentially. The nucleotide substitution rate of the NS genes of avian influenza viruses was one-third to one-fourth that of human influenza viruses. We deduced the time of separation between the NS genes of human and avian influenza viruses during evolution.

Evolutionary pattern of the hemagglutinin gene of influenza B viruses isolated in Japan: cocirculating lineages in the same epidemic season

The unexpectedly low efficacy of influenza vaccine during school outbreaks of influenza B virus in the spring of 1987 in Japan was probably attributable to a poor antibody response of vaccinees to the epidemic viruses. An antigenic analysis of the causative B viruses isolated in 1987 and 1988 showed much variation in hemagglutination inhibition patterns. The nucleotide sequences that code for the HA1 domain of B/Fukuoka/c-27/81, B/Ibaraki/2/85, B/Nagasaki/1/87, and B/Yamagata/16/88 viruses were determined and compared with those of the previously reported hemagglutinin genes. The nucleotide sequences of the hemagglutinin gene of a new variant, B/Yamagata/16/88, had only 93.4% homology with those of two other viruses from the same epidemic. An analysis of nucleotide and amino acid substitutions of the hemagglutinin genes of influenza B viruses revealed that new and some old variants could cocirculate in the same epidemic. A phylogenetic tree constructed by the neighbor-joining method allowed estimation of an evolutionary rate of 2.3 x 10(-3) synonymous (silent) substitutions per nucleotide site per year in the hemagglutinin gene.

The B allele of the NS gene of avian influenza viruses, but not the A allele, attenuates a human influenza A virus for squirrel monkeys

The nonstructural (NS) genes of avian influenza A viruses have been divided into two groups on the basis of nucleotide sequence homology, which we have referred to here as alleles A and B. We sequenced the NS genes of eight additional avian influenza A viruses in order to define the differences between these two alleles more thoroughly. Four of the viruses had NS gene sequences which resembled that of A/FPV/Rostock/34 and belonged to allele A while the other four viruses had NS gene sequences more similar to that of A/Duck/Alberta/76 and belonged to allele B. There was approximately 90% sequence homology within alleles and 72% homology between alleles. As previously reported the NS genes of human influenza A viruses belong to allele A. We constructed single gene avian-human reassortant influenza A viruses containing an allele A or B NS gene segment from an avian influenza A virus and all other genes from a human influenza A virus and tested these reassortants for their ability to grow in the respiratory tract of a nonhuman primate. Reassortants containing an avian NS gene segment of allele B were significantly restricted in growth in the respiratory tract of squirrel monkeys while reassortants with an allele A NS gene segment were not. The divergent evolution of the B NS allele in birds may have resulted in gene products which do not function optimally in cooperation with genes from a human virus in viral replication in primate respiratory epithelium.

Newcastle disease virus evolution. I. Multiple lineages defined by sequence variability of the hemagglutinin-neuraminidase gene

We compared the hemagglutinin-neuraminidase gene sequence among 13 strains of Newcastle disease virus (NDV) isolated over the last 50 years. Although overall homology was remarkably high, the sequence variability demonstrated the existence of at least three distinct lineages, which must have co-circulated for considerable periods. The sequence variability also appears to reflect some accumulation of mutations over time. Strictly correlating with the lineages, the translation products could be classified into three size classes. One class lacked the interchain disulfide bond, and another represented unusual precursor protein of biologically inactive form. The lineages correlated to some extent with virulence and place of isolation of the strains. However, antigenic variations, which were neither cumulative nor progressive, did not correlate with the lineages. These analyses showing multiple lineages were greatly facilitated by a precise calculation of synonymous substitutions, which had been largely free from selective pressures and had occurred frequently and evenly throughout the coding region.

The role of RNA segment 1 in an in vitro host restriction occurring in an avian influenza virus mutant

A temperature sensitive mutant, ts C47, derived from A/FPV/Rostock/34 and with a ts mutation in RNA segment 8, fails to form plaques in MDCK cells. From data obtained with reassortant viruses using the human influenza isolate A/FM/1/47 it was apparent that more than one mutation contributed to the temperature-sensitive (ts) and host range (hr) phenotypes of ts C47, and the phenotype of reassortants containing RNA segment 1 from A/FM/1/47 indicated that this segment was involved. A single nucleotide substitution at nucleotide 1961, resulting in valine instead of methionine in the predicted amino acid sequence of polypeptide PB2, was found in RNA segment 1 of ts C47, but this mutation did not segregate with the attenuated phenotype on gene reassortment. The following conclusions are drawn: (a) that ts C47 has at least two mutations in addition to that already known to exist in RNA segment 8, one of which (that in RNA segment 1) does not contribute to the observed ts hr phenotypes and (b) that the hr phenotype can be suppressed by substitution of RNA segment 1 by that of another strain.

Biological functions of the NS1 protein of an influenza B virus mutant which has a long carboxyl terminal deletion

To clarify the function of the NS gene of a highly cytolytic mutant of influenza virus B/Yamagata/1/73 which expresses an NS1 protein with a long carboxyl terminal deletion (clone 201), we prepared a single gene reassortant (201 L-77) and a control reassortant (YL-20) in which all the genes were of wild type influenza virus B/Lee/40 origin except NS gene which was derived from either clone 201 or wild type B/Yamagata. Comparative studies have revealed that 201 L-77 destructed infected cells more severely and much earlier after infection than did YL-20, although both produced comparable amount of infectious virus. The highly cytolytic reassortant 201 L-77 produced a small plaque, while the weakly cytolytic reassortant YL-20 produced a large plaque in MDCK cells. There was little difference between the two reassortants in the time course and the amount of synthesis of viral proteins within the infected cells. However, the mode of synthesis of viral RNA (vRNA) by 201 L-77 was greatly altered compared with YL-20.

Two nuclear location signals in the influenza virus NS1 nonstructural protein

The NS1 protein of influenza A virus has been shown to enter and accumulate in the nuclei of virus-infected cells independently of any other influenza viral protein. Therefore, the NS1 protein contains within its polypeptide sequence the information that codes for its nuclear localization. To define the nuclear signal of the NS1 protein, a series of recombinant simian virus 40 vectors that express deletion mutants or fusion proteins was constructed. Analysis of the proteins expressed resulted in identification of two regions of the NS1 protein which affect its cellular location. Nuclear localization signal 1 (NLS1) contains the stretch of basic amino acids Asp-Arg-Leu-Arg-Arg (codons 34 to 38). This sequence is conserved in all NS1 proteins of influenza A viruses, as well as in that of influenza B viruses. NLS2 is defined within the region between amino acids 203 and 237. This domain is present in the NS1 proteins of most influenza A virus strains. NLS1 and NLS2 contain basic amino acids and are similar to previously defined nuclear signal sequences of other proteins.

Influenza B virus evolution: co-circulating lineages and comparison of evolutionary pattern with those of influenza A and C viruses

Sequence analyses and comparison of the genes coding for the nonstructural (NS) and hemagglutinin (HA) proteins of different influenza B viruses isolated between 1940 and 1987 reveal that the number of substitutions is not always proportional to the time between isolates. Examination of 14 influenza B virus NS gene and 10 HA gene sequences by the maximum parsimony method suggested that--as with influenza C viruses--there are multiple evolutionary lineages which can coexist for considerable periods of time. Comparison of the sequence divergence among genes of viruses belonging to type A, B, and C virus suggests that, in man, influenza B viruses evolve slower than A viruses and faster than C viruses. We propose an evolutionary model for influenza B viruses that is intermediate between the pattern for human influenza A viruses and that for influenza C viruses.

Molecular evolutionary rates of oncogenes

Using nine sets of viral and cellular oncogenes, the rates of nucleotide substitutions were computed by using Gojobori and Yokoyama's (1985) method. The results obtained confirmed our previous conclusion that the rates of nucleotide substitution for the viral oncogenes are about a million times higher than those for their cellular counterparts. For cellular oncogenes and most viral oncogenes, however, the rate of synonymous substitution is higher than that of nonsynonymous substitution. Moreover, the pattern of nucleotide substitutions for viral oncogenes is more similar to that for functional genes (such as cellular oncogenes) than for pseudogenes. This implies that nucleotide substitutions in viral oncogenes may be functionally constrained. Thus, our observation supports that nucleotide substitutions for the oncogenes in those DNA and RNA genomes are consistent with Kimura's neutral theory of molecular evolution (Kimura 1968, 1983).

A new concept of the epidemic process of influenza A virus

Influenza A virus was discovered in 1933, and since then four major variants have caused all the epidemics of human influenza A. Each had an era of solo world prevalence until 1977 as follows: H0N1 (old style) strains until 1946, H1N1 (old style) strains until 1957, H2N2 strains until 1968, then H3N2 strains, which were joined in 1977 by a renewed prevalence of H1N1 (old style) strains. Serological studies show that H2N2 strains probably had had a previous era of world prevalence during the last quarter of the nineteenth century, and had then been replaced by H3N2 strains from about 1900 to 1918. From about 1907 the H3N2 strains had been joined, as now, by H1N1 (old style) strains until both had been replaced in 1918 by a fifth major variant closely related to swine influenza virus A/Hswine1N1 (old style), which had then had an era of solo world prevalence in mankind until about 1929, when it had been replaced by the H0N1 strains that were first isolated in 1933. Eras of prevalence of a major variant have usually been initiated by a severe pandemic followed at intervals of a year or two by successive epidemics in each of which the nature of the virus is usually a little changed (antigenic drift), but not enough to permit frequent recurrent infections during the same era. Changes of major variant (antigenic shift) are large enough to permit reinfection. At both major and minor changes the strains of the previous variant tend to disappear and to be replaced within a single season, worldwide in the case of a major variant, or in the area of prevalence of a previous minor variant. Pandemics, epidemics and antigenic variations all occur seasonally, and influenza and its viruses virtually disappear from the population of any locality between epidemics, an interval of many consecutive months. A global view, however, shows influenza continually present in the world population, progressing each year south and then north, thus crossing the equator twice yearly around the equinoxes, the tropical monsoon periods. Influenza arrives in the temperate latitudes in the colder months, about 6 months separating its arrival in the two hemispheres. None of this behaviour is explained by the current concept that the virus is surviving like measles virus by direct spread from the sick providing endless chains of human influenza A.(ABSTRACT TRUNCATED AT 400 WORDS)

Genetic divergence of the NS genes of avian influenza viruses

The nucleotide sequences of the NS genes of avian influenza A viruses, A/Chicken/Japan/24, A/Duck/England/56, A/Tern/South Africa/61, A/Duck/Ukraine/1/63, and A/Mynah/Haneda-Thai/76, were determined and compared among themselves and with two reported NS sequences of the avian viruses, A/FPV/Rostock/34 and A/Duck/Alberta/60/76. Thirty-six to two hundred forty base differences in the NS genes were found in pairwise comparisons among the viruses. The numbers of base differences in the NS genes increased with time, except A/Duck/Alberta/60/76 virus. However, the NS genes of the avian viruses did not change sequentially with time and were arranged in separate evolutionary lineages. When the NS genes of avian viruses employed in the present study were compared with those of human viruses, sequence similarity was confirmed (M. Baez, R. Taussig, J. J. Zarza, J. F. Young, P. Palese, A. Reisfield, and A. M. Skalka, 1980, Nucleic Acids Res. 8, 5845-5858). The numbers of base differences in the NS genes between avian viruses and the A/PR/8/34 virus were 61 to 83, and the NS gene of the oldest avian isolate, A/Chicken/Japan/24, was most closely related to that of the A/PR/8/34 virus. It was hypothesized that NS genes of human influenza viruses and those of some avian influenza viruses had been derived from a common ancestor gene.

Molecular analyses of the hemagglutinin genes of H5 influenza viruses: origin of a virulent turkey strain

Comparative sequence analysis of the hemagglutinin (HA) genes of a highly virulent H5N8 virus isolated from turkeys in Ireland in 1983 and a virus of the same subtype detected simultaneously in healthy ducks showed only four amino acid differences between these strains. Partial sequencing of six of the other genes and antigenic similarity of the neuraminidases established the overall genetic similarity of these two viruses. Comparison of the complete sequence of two H5 gene sequences and partial sequences of other virulent and avirulent H5 viruses provides evidence for at least two different lineages of H5 influenza virus in the world, one in Europe and the other in North America, with virulent and avirulent members in each group. In vivo studies in domestic ducks showed that all of the H5 viruses that are virulent in chickens and turkeys replicate in the internal organs of ducks but did not produce any disease signs. Additionally, both viruses isolated from turkeys and ducks in Ireland were detected in the blood. These studies provide the first conclusive evidence for the possibility that fully virulent influenza viruses in domestic poultry can arise directly from viruses in wild aquatic birds. Studies on the cleavability of the HA of virulent and avirulent H5 viruses showed that the principles established for H7 viruses (F. X. Bosch, M. Orlich, H. D. Klenk, and R. Rott, 1979, Virology 95, 197-207; F. X. Bosch, W. Garten, H. D. Klenk, and R. Rott, 1981, Virology 113, 725-735) also apply to the H5 subtype. These are (1) only the HAs of virulent influenza viruses were cleaved in tissue culture in the absence of trypsin and (2) virulent H5 influenza viruses contain a series of basic amino acids at the cleavage site of the HA, whereas avirulent strains contain only a single arginine with the exception of the avirulent Chicken/Pennsylvania virus. Thus, a series of basic amino acids at the cleavage site probably forms a recognition site for the enzyme(s) responsible for cleavage.

Molecular evolution and phylogeny of the human AIDS viruses LAV, HTLV-III, and ARV

A phylogenetic tree for the human lymphadenopathy-associated virus (LAV), the human T-cell lymphotrophic virus type III (HTLV-III), and the acquired immune deficiency syndrome (AIDS)-associated retrovirus (ARV) has been constructed from comparisons of the amino acid sequences of their gag proteins. A method is proposed for estimating the divergence times among these AIDS viruses and the rates of nucleotide substitution for their RNA genomes. The analysis indicates that the LAV and HTLV-III strains diverged from one another after 1977 and that their common ancestor diverged from the ARV virus no more than 10 years earlier. Hence, the evolutionary diversity among strains of the AIDS viruses apparently has been generated within the last 20 years. It is estimated that the genome of the AIDS virus has a nucleotide substitution rate on the order of 10(-3) per site per year, with the rate in the second half of the genome being double that in the first half.

Nucleotide sequence analysis of the nucleoprotein gene of an avian and a human influenza virus strain identifies two classes of nucleoproteins

The nucleotide sequences of RNA segment 5 of an avian influenza A virus, A/Mallard/NY/6750/78 (H2N2), and a human influenza A virus, A/Udorn/307/72 (H3N2), were determined and the deduced amino acid sequences of the nucleoprotein (NP) of these viruses were compared to two other avian and two other human influenza A NP sequences. The results indicated that there are separate classes of avian and human influenza A NP genes that can be distinguished on the basis of sites containing amino acids specific for avian and human influenza viruses and also by amino acid composition. The human influenza A virus NP genes appear to follow a linear pathway of evolution with the greatest homology (96.9%) between A/NT/60/68 (H3N2) and A/Udorn/72, isolated only 4 years apart, and the least homology (91.1%) between A/PR/8/34 (H1N1) and A/Udorn/72, isolated 38 years apart. Furthermore, 84% of the nucleotide substitutions between A/PR/8/34 and A/NT/60/68 are preserved in the NP gene of the A/Udorn/72 strain. In contrast, a distinct linear pathway is not present in the avian influenza NP genes since the homology (90.3%) between the two avian influenza viruses A/Parrot/Ulster/73 (H7N1) and A/Mallard/78 isolated only 5 years apart is not significantly greater than the homology (90.1%) between strains A/FPV/Rostock/34 and A/Mallard/78 isolated 44 years apart and only 49% of the nucleotide substitutions between A/FPV/34 and A/Parrot/73 are found in A/Mallard/78. A determination of the rate of evolution of the human influenza A virus NP genes suggested that there were a greater number of nucleotide substitutions per year during the first several years immediately following the emergence of a new subtype in 1968.

Direct characterization of influenza viral NS1 mRNA and related sequences from infected HeLa cells and a cell-free transcription system

The NS1 mRNA of the influenza A virus WSN (H0N1) strain was isolated from a cell-free transcription system, and from the cytoplasm of virus-infected HeLa cells. The 32P-labeled NS1 mRNA derived from the infected cell cytoplasm was characterized by the secondary enzymatic analysis of sixteen of its large or distinct RNAase T1-resistant oligonucleotides. Several WSN strain-specific nucleotide differences from the previously-determined sequence of NS1 mRNA from the PR8 (H0N1) strain of influenza A virus, were located within these sequences. The RNAase T1-resistant oligonucleotides were placed within the primary sequence of NS1 mRNA, using the PR8 strain sequence data. The resulting linear map was then used to identify NS2 mRNA isolated from the infected cell cytoplasm, and an NS-related RNA species generated from NS1 mRNA incubated in a HeLa cell-free extract.

Measurement of the mutation rates of animal viruses: influenza A virus and poliovirus type 1

Epidemiologic and genetic evidence suggests that influenza A viruses evolve more rapidly than other viruses in humans. Although the high mutation rate of the virus is often cited as the cause of the extensive variation, direct measurement of this parameter has not been obtained in vivo. In this study, the rate of mutation in tissue culture for the nonstructural (NS) gene of influenza A virus and for the VP1 gene in poliovirus type 1 was assayed by direct sequence analysis. Each gene was repeatedly sequenced in over 100 viral clones which were descended from a single virion in one plaque generation. A total of 108 NS genes of influenza virus were sequenced, and in the 91,708 nucleotides analyzed, seven point changes were observed. A total of 105 VP1 genes of poliovirus were sequenced, and in the 95,688 nucleotides analyzed, no mutations were observed. We then calculated mutation rates of 1.5 X 10(-5) and less than 2.1 X 10(-6) mutations per nucleotide per infectious cycle for influenza virus and poliovirus, respectively. We suggest that the higher mutation rate of influenza A virus may promote the rapid evolution of this virus in nature.

Epidemiology of influenza C virus in man: multiple evolutionary lineages and low rate of change

The nucleotide sequences of nonstructural protein (NS) genes of human influenza C viruses isolated between 1947 and 1983 were determined and compared. Assuming constant evolutionary rates, the extent of nucleotide differences among NS genes does not correspond to the isolation years of the strains. This suggests that more than one gene lineage is present in the population. Furthermore, examination of the eight C virus NS gene sequences by the maximum parsimony method (W. M. Fitch, 1971, Syst. Zool. 20, 406-416) yielded phylogenetic trees that were grossly different from those obtained using the hemagglutinin genes for the same eight isolates. This result is compatible with the idea of reassortment of genes in nature across lineages of influenza C viruses. The sequence analysis also suggests that nucleotide substitutions occur at a lower rate in the C virus NS genes than in influenza A virus NS genes.

Genetic variation in HTLV-III/LAV over time in patients with AIDS or at risk for AIDS

In a study of genetic variation in the AIDS virus, HTLV-III/LAV, sequential virus isolates from persistently infected individuals were examined by Southern blot genomic analysis, molecular cloning, and nucleotide sequencing. Four to six virus isolates were obtained from each of three individuals over a 1-year or 2-year period. Changes were detected throughout the viral genomes and consisted of isolated and clustered nucleotide point mutations as well as short deletions or insertions. Results from genomic restriction mapping and nucleotide sequence comparisons indicated that viruses isolated sequentially had evolved in parallel from a common progenitor virus. The rate of evolution of HTLV-III/LAV was estimated to be at least 10(-3) nucleotide substitutions per site per year for the env gene and 10(-4) for the gag gene, values a millionfold greater than for most DNA genomes. Despite this relatively rapid rate of sequence divergence, virus isolates from any one patient were all much more related to each other than to viruses from other individuals. In view of the substantial heterogeneity among most independent HTLV-III/LAV isolates, the repeated isolation from a given individual of only highly related viruses raises the possibility that some type of interference mechanism may prevent simultaneous infection by more than one major genotypic form of the virus.

Evolution of human influenza A viruses over 50 years: rapid, uniform rate of change in NS gene

Variation in influenza A viruses was examined by comparison of nucleotide sequences of the NS gene (890 bases) of 15 human viruses isolated over 53 years (1933 to 1985). Changes in the genes accumulate with time, and an evolutionary tree based on the maximum parsimony method can be constructed. The evolutionary rate is approximately 2 X 10(-3) substitution per site per year in the NS genes, which is about 10(6) times the evolutionary rate of germline genes in mammals. This uniform and rapid rate of evolution in the NS gene is a good molecular clock and is compatible with the hypothesis that positive selection is operating on the hemagglutinin (or perhaps some other viral genes) to preserve random mutations in the NS gene.

Detection of single base substitutions in influenza virus RNA molecules by denaturing gradient gel electrophoresis of RNA-RNA or DNA-RNA heteroduplexes

Single point mutations in the NS gene of influenza virus were detected by electrophoresis of double-stranded RNA heteroduplexes in denaturing gradient gels. The heteroduplex RNAs were made by hybridization of virion RNA with SP6-derived RNA probes of varying length. Mutations located at different positions along the NS gene (890 nucleotides long) were all detected in a predictable fashion. The method of heteroduplex analysis was also successfully used in detecting single point mismatches in DNA-RNA hybrids.

Evolution of enterovirus 70 in nature: all isolates were recently derived from a common ancestor

The data of large RNase T1-resistant oligonucleotide mapping of enterovirus 70 (EV 70) previously reported (Takeda et al., Virology 134, 375-388, 1984) were subjected to further genetical analysis to estimate the evolutionary rate of genome RNA of EV 70 and to clarify the phylogenetic relationship among isolates. A proportion of common spots between strains decreased as the year elapsed and eventually, only seven spots were common to all the 16 isolates tested, indicating that the substitution is scattered throughout the genome. On the other hand, some specific sets of spots were conserved among geographically or epidemiologically related strains. Base sequence variation of the isolates was deduced according to Aaronson et al. (Nucleic Acids Res. 10, 237-246, 1982) from pariwise comparison of the common spots and used as a genetic distance between them. The base substitution rate of virus genome was estimated by regression analysis of the genetic distance of the isolates against the sampling time. A fairly constant and rapid rate was obtained; it was 1.83 X 10(-3)/base/year. Based on the substitution rate, genetic distance and sampling time of the strains, the phylogenetic tree of EV 70 was constructed using Unweighted Pair Group Method Using Arithmetic Averages (UPGMA) (Nei, Molecular Population Genetics and Evolution, North Holland, Amsterdam, 1975). The tree supports the previous hypothesis that evolution of EV 70 started from a single common ancestor. The time of its emergence was estimated to be 1967 +/- 15 months. The virus branched into many strains early during the first pandemic and has evolved in a divergent fashion, yielding genetically polymorphic viruses in the world.

Noncumulative sequence changes in the hemagglutinin genes of influenza C virus isolates

Sequence analysis and comparison of hemagglutinin (HA) genes of different influenza C viruses isolated between 1947 and 1983 reveals that (1) the extent of difference among the HA genes is independent of the year in which these viruses were isolated and that (2) changes in the HA genes do not appear to accumulate with time. These results suggest that epidemiologically dominant variants of influenza C viruses do not emerge successively with time and that C virus variants derived from multiple evolutionary pathways cocirculate at any one time. Thus the epidemiology of influenza C viruses differs markedly from that of influenza A viruses, which is characterized by the emergence of successive variants. Based on the nucleotide sequence data, we propose different evolutionary models for influenza A and influenza C viruses.

Evolution of the A/Chicken/Pennsylvania/83 (H5N2) influenza virus

The epidemiological features of the H5N2 outbreak of influenza in poultry were studied by sequencing the HA genes of several viruses isolated during the epidemic. Comparison of the nucleotide sequences of the HA genes indicated there was a single introduction of virulent virus. The variation rate (silent mutations) in the HA gene of the virulent Ck/Penn virus was 9.0 or 14.4% per 10 years depending on the viruses compared and was similar to that in H3 HA gene of human influenza A virus. The virulent and avirulent viruses isolated after October 1983 were derived from a common ancestoral virus and the virulent virus did not supersede the avirulent virus, instead, the virulent and avirulent viruses coexisted and evolved separately during the course of the epidemic. The evolutionary changes in the HA of H5N2 viruses that occurred during the epidemic permitted us to establish that a virus (A/Chick/Washington/84) that was isolated 8 months after the last H5N2 virus had been isolated from poultry in Pennsylvania belonged to the family of potentially dangerous H5N2 viruses and was a direct descendent of the virus that spread to Maryland and Virginia. All of the virulent Ck/Penn viruses retained the amino acid changes at residues 13 and 69 in the HA.

Analysis of the genome of influenza A virus strains (H3N2) isolated during the epidemic season of 1982-1983

The cRNA:vRNA hybridization technique was used to analyse H3N2 influenza virus isolates obtained from influenza patients in the United Kingdom and the U.S.A. (Alaska) during the epidemic season of 1982-1983. The majority of isolates differed from reference H3N2 influenza virus strains A/Bangkok/1/79 and A/Philippines/2/82 as well as from one another in the homology of nearly all the genes. No identical strains were detected among the isolates including the ones isolated in the same town and at the same time.

Protein and nucleic acid analyses of influenza C viruses isolated from pigs and man

The virus-coded proteins and the genomes of influenza C virus isolates obtained from Chinese pigs in 1981-1982 and of human influenza C virus strains isolated between 1947 and 1981 were compared. Using SDS polyacrylamide gel electrophoresis and one-dimensional peptide mapping we found the virus-coded proteins of the pig influenza C viruses to be similar to those of human influenza C virus strains. The sizes of the genomes of human and pig influenza C viruses were indistinguishable. Genome analysis by oligonucleotide (ON) mapping revealed that the genomes of the pig influenza C viruses were very similar to but not identical with those of human influenza C virus strains. ON changes were found scattered over the whole genome. ON mapping of isolated segments of several influenza C virus strains suggested that two pig strains (C/P/B/10/81 and C/P/B/32/81) are related by a reassortment event which is likely to have occurred in nature. The rate of genome variation in influenza C viruses seemed to be similar to that seen in influenza B, and slower than that recorded for influenza A viruses.

Sequence homology between certain viral proteins and proteins related to encephalomyelitis and neuritis

Post-infectious or post-vaccinal demyelinating encephalomyelitis and neuritis may be due to immunological cross-reactions evoked by specific viral antigenic determinants (epitopes) that are homologous to regions in the target myelins of the central and peripheral nervous systems. Such homologies have been found by computer searches in which decapeptides in two human myelin proteins were compared with proteins of viruses known to infect humans. These viruses include measles, Epstein-Barr, influenza A and B, and others that cause upper respiratory infections. Several regions identified in myelin basic protein and P2 protein can be related to experimental allergic encephalomyelitis or neuritis in laboratory animals.

Rates of evolution of the retroviral oncogene of Moloney murine sarcoma virus and of its cellular homologues

A method is proposed for computing the rates of nucleotide substitution for an oncogene of a retrovirus (v-onc), its cellular homologue (c-onc), and the retrovirus genome simultaneously. The method has been applied to DNA sequences of the v-mos gene of Moloney murine sarcoma virus (Mo-MuSV) and the c-mos and gag genes of Mo-MuSV and Moloney murine leukemia virus (Mo-MuLV). The rates of nucleotide substitution for c-mos, the gag gene, and v-mos are estimated to be 1.71 X 10(-9), 6.3 X 10(-4), and 1.31 X 10(-3) per site per year, respectively. The rate of evolution of c-mos is comparable to that of many functional genes in DNA genomes, suggesting some important biological function played by cellular oncogenes. The rates of nucleotide substitution in the v-mos and gag genes are very high and are similar to those of RNA viral genes such as the hemagglutinin and neuraminidase genes in the influenza A virus. Thus, oncogenes seem to exemplify a general feature of genome evolution: the rate of evolution of RNA genomes can be more than a million times greater than that of DNA genomes because of a high mutation rate in the RNA genome.

Expression of influenza virus NS2 nonstructural protein in bacteria and localization of NS2 in infected eucaryotic cells

The nonstructural NS2 protein of influenza A/PR/8/34 virus was efficiently expressed in bacteria, and monospecific antisera were prepared against the bacterially synthesized polypeptide. These antisera were cross-reactive among the NS2 proteins of various influenza A viruses. However, they did not react with the NS2 of influenza B/Lee/40 virus nor with other proteins of influenza A viruses such as NS1. Antisera against NS2 were used to determine that the NS2 protein is localized in the cell nucleus during influenza virus infection, as shown by immunofluorescence microscopy. Cells infected with simian virus 40 recombinants containing the influenza virus NS gene revealed that both the NS1 and NS2 proteins appeared in the nucleus, even in the absence of expression of other influenza virus-specific components.

Pattern of nucleotide substitution and the extent of purifying selection in retroviruses

The patterns of point mutation and nucleotide substitution are inferred from nucleotide differences in three coding and two noncoding regions of retroviral genomes. Evidence is presented in favor of the view that the majority of mutations accumulate at the reverse transcription stage. Purifying selection is apparently very weak at the amino acid level, and almost nonexistent between synonymous codons. The pattern of purifying selection obeys the rules previously established in vertebrates [Gojobori T, Li W-H, Graur D (1982) J Mol Evol 18:360-369]; i.e., the magnitude of purifying selection at the amino acid level is negatively correlated with Grantham's [Grantham R (1974) Science 185: 862-864] chemical distances between the amino acids interchanged. We refute Modiano et al.'s [Modiano G, Battistuzzi G, Motulsky AG (1981) Proc Natl Acad Sci USA 78:1110-1114] hypothesis, according to which the pattern of mutation is preadapted to buffer against deleterious mutations. On the contrary, the pattern of mutation reduces the level of conservativeness from that imposed on the amino acid substitution pattern by the structure of the genetic code. The extraordinarily high rate of nucleotide substitution in retroviruses in comparison with that in other organisms is apparently caused by an extremely high rate of mutation coupled with a lack of stringent purifying selection at both the codon and the amino acid levels.

Genetic relatedness between A/Swine/Iowa/15/30(H1N1) and human influenza viruses

The nucleotide sequences of the M and NS1 genes of influenza virus A/Swine/Iowa/15/30 (A/SW/IW/30)(H1N1) were determined with cloned DNAs and compared with reported sequences of human and avian influenza viruses. A/SW/IW/30 virus was found to be closely similar to A/PR/8/34(H1N1) virus in the nucleotide sequences of the M and NS1 genes, the base differences between the two strains being 64 out of 1027 nucleotides in the M gene and 52 out of 740 in the NS1 gene. Based on the assumptions that these two viruses were derived from a common ancestor and that the rate of base changes per year was the same in man and in swine, it was estimated that the progenitor virus was in circulation during the period from 1915 to 1920. This estimation was compatible with the epidemiological findings suggesting that the progenitor of the swine influenza virus was the agent of the 1918 influenza pandemic. Furthermore, the M and NS1 gene sequences of A/FPV/Rostock/34(H7N6) virus were much closer to those of A/SW/IW/30 and A/PR/8/34 viruses than to A/duck/Alberta/60/76(H12N5) virus, but not as close as the A/SW/IW/30 virus was to A/PR/8/34 virus.

Influenza B virus genome: complete nucleotide sequence of the influenza B/lee/40 virus genome RNA segment 5 encoding the nucleoprotein and comparison with the B/Singapore/222/79 nucleoprotein

The complete nucleotide sequence of a cloned full-length DNA copy of genome RNA segment 5 of influenza B/Lee/40 virus has been determined. The genome segment is 1841 nucleotides in length and is capable of coding for a nucleoprotein (NP) of 560 amino acids. Comparison with the only other known sequence of an influenza B virus nucleoprotein gene (B/Singapore/222/79) indicates striking homology. Only 113 nucleotide substitutions are present between the two strains in their protein coding region and these lead to only 22 amino acid substitutions between nucleoproteins of identical polypeptide chain length. Assuming a common lineage, this reflects a calculated rate of amino acid sequence divergence of 0.1% per year. Like its influenza A virus counterpart, the influenza B/Lee/40 nucleoprotein is a basic protein with a relatively even distribution of its charged residues. The remarkable conservation of nucleoprotein primary structure over a 39-year period probably reflects both selection for performance of specific functions and protection from antigenic selection by the host immune system.

Analysis of an influenza A virus mutant with a deletion in the NS segment

The influenza virus host range mutant CR43-3, derived by recombination from the A/Alaska/6/77 and the cold-adapted and temperature-sensitive A/Ann Arbor/6/60 viruses, has previously been shown to possess a defect in the NS gene. To characterize this defect, nucleotide sequence data were obtained from cloned cDNAs. The CR43-3 NS gene was found to be 854 nucleotides long and to derive from the NS gene of the A/Alaska/6/77 parent virus by an internal deletion of 36 nucleotides. Direct sequencing of RNA 8 of CR43-3 virus confirmed that the deletion in the NS1-coding region was not an artifact that was generated during the cloning procedure. Protein analysis indicated that the NS1 protein of CR43-3 virus was synthesized in equal amounts in the restrictive (MDCK) cells as well as in the permissive (PCK) host cells. Also, indirect immunofluorescence studies of virus-infected cells showed that the NS1 protein of CR43-3 virus, like that of the parent viruses, accumulates in the nuclei of both cell systems. Although no differences in synthesis or localization of the NS1 protein could be detected, a consistent reduction in M1 protein was noted in CR43-3 virus-infected, nonpermissive cells as compared with that of the permissive host. Since analysis of the CR43-3 virus required us to obtain the NS nucleotide sequence of the 1977 isolate A/Alaska/6/77, we were able to compare this sequence with those of corresponding genes of earlier strains. The result of this analysis supports the idea of a common lineage of human influenza A viruses isolated over a 43-year period.