Analysis of genetic variability in human respiratory syncytial virus by the RNase A mismatch cleavage method: subtype divergence and heterogeneity

Utility of the Neonatal Calf Model for Testing Vaccines and Intervention Strategies for Use against Human RSV Infection

Respiratory syncytial virus (RSV) is a significant cause of pediatric respiratory tract infections. It is estimated that two-thirds of infants are infected with RSV during the first year of life and it is one of the leading causes of death in this age group worldwide. Similarly, bovine RSV is a primary viral pathogen in cases of pneumonia in young calves and plays a significant role in bovine respiratory disease complex. Importantly, naturally occurring infection of calves with bovine RSV shares many features in common with human RSV infection. Herein, we update our current understanding of RSV infection in cattle, with particular focus on similarities between the calf and human infection, and the recent reports in which the neonatal calf has been employed for the development and testing of vaccines and therapeutics which may be applied to hRSV infection in humans.

Genetic variability of respiratory syncytial virus A in hospitalized children in the last five consecutive winter seasons in Central Spain

Human respiratory syncytial virus group A (RSV-A) was detected in symptomatic hospital attended children in Central Spain for a continuous time period, September 2010 to April 2015. In order to accurately describe the epidemiology of this virus, the genetic diversity of the complete G gene and the clinical manifestations observed were jointly analyzed. Out of 3,011 respiratory specimens taken from 2,308 children, 640 were positive to RSV (21.3%) and 405 were RSV-A (63.2%). Complete G gene sequences of 166 randomly selected RSV-A virus identified NA1 and ON1 genotypes. In 2011-2012, ON1 emerged sporadically and become dominant in 2012-2013 with 38 cases (70%). In 2014-2015, all the 44 sequences contained the 72-nt duplication (100%). Clinical diagnosis of children with ON1 genotype were bronchiolitis in 55 (62.5%), recurrent wheezing or asthma exacerbations in 22 (25%), laryngotracheobronchitis in 3 (3.4%), and upper respiratory tract infections in eight. Results showed replacement and substitution of circulating NA1 genotype with the new ON1 genotype. Nevertheless, at this stage, none of the RSV-A genotypes identified have resulted in significant clinical differences. The amino acid composition of the complete G gene ON1 sequences demonstrated an accumulation of single changes not related with different clinical presentation. J. Med. Virol. 89:767-774, 2017. © 2016 Wiley Periodicals, Inc.

Molecular Evolutionary Dynamics of Respiratory Syncytial Virus Group A in Recurrent Epidemics in Coastal Kenya

The characteristic recurrent epidemics of human respiratory syncytial virus (RSV) within communities may result from the genetic variability of the virus and associated evolutionary adaptation, reducing the efficiency of preexisting immune responses. We analyzed the molecular evolutionary changes in the attachment (G) glycoprotein of RSV-A viruses collected over 13 epidemic seasons (2000 to 2012) in Kilifi (n = 649), Kenya, and contemporaneous sequences (n = 1,131) collected elsewhere within Kenya and 28 other countries. Genetic diversity in the G gene in Kilifi was dynamic both within and between epidemics, characterized by frequent new variant introductions and limited variant persistence between consecutive epidemics. Four RSV-A genotypes were detected in Kilifi: ON1 (11.9%), GA2 (75.5%), GA5 (12.3%), and GA3 (0.3%), with predominant genotype replacement of GA5 by GA2 and then GA2 by ON1. Within these genotypes, there was considerable variation in potential N-glycosylation sites, with GA2 and ON1 viruses showing up to 15 different patterns involving eight possible sites. Further, we identified 15 positively selected and 34 genotype-distinguishing codon sites, with six of these sites exhibiting both characteristics. The mean substitution rate of the G ectodomain for the Kilifi data set was estimated at 3.58 × 10(-3) (95% highest posterior density interval = 3.04 to 4.16) nucleotide substitutions/site/year. Kilifi viruses were interspersed in the global phylogenetic tree, clustering mostly with Kenyan and European sequences. Our findings highlight ongoing genetic evolution and high diversity of circulating RSV-A strains, locally and globally, with potential antigenic differences. Taken together, these provide a possible explanation on the nature of recurrent local RSV epidemics.

IMPORTANCE

The mechanisms underlying recurrent epidemics of RSV are poorly understood. We observe high genetic diversity in circulating strains within and between epidemics in both local and global settings. On longer time scales (∼7 years) there is sequential replacement of genotypes, whereas on shorter time scales (one epidemic to the next or within epidemics) there is a high turnover of variants within genotypes. Further, this genetic diversity is predicted to be associated with variation in antigenic profiles. These observations provide an explanation for recurrent RSV epidemics and have potential implications on the long-term effectiveness of vaccines.

Respiratory syncytial virus infection in cattle

Bovine respiratory syncytial virus (RSV) is a cause of respiratory disease in cattle worldwide. It has an integral role in enzootic pneumonia in young dairy calves and summer pneumonia in nursing beef calves. Furthermore, bovine RSV infection can predispose calves to secondary bacterial infection by organisms such as Mannheimia haemolytica, Pasteurella multocida, and Histophilus somni, resulting in bovine respiratory disease complex, the most prevalent cause of morbidity and mortality among feedlot cattle. Even in cases where animals do not succumb to bovine respiratory disease complex, there can be long-term losses in production performance. This includes reductions in feed efficiency and rate of gain in the feedlot, as well as reproductive performance, milk production, and longevity in the breeding herd. As a result, economic costs to the cattle industry from bovine respiratory disease have been estimated to approach $1 billion annually due to death losses, reduced performance, and costs of vaccinations and treatment modalities. Human and bovine RSV are closely related viruses with similarities in histopathologic lesions and mechanisms of immune modulation induced following infection. Therefore, where appropriate, we provide comparisons between RSV infections in humans and cattle. This review article discusses key aspects of RSV infection of cattle, including epidemiology and strain variability, clinical signs and diagnosis, experimental infection, gross and microscopic lesions, innate and adaptive immune responses, and vaccination strategies.

Genetic analysis and antigenic characterization of human respiratory syncytial virus group A viruses isolated in Germany 1996-2008

The genetic and antigenic variability of 18 human respiratory syncytial virus group A viruses isolated in Germany from 1996 to 2008 was evaluated by nucleotide sequencing of the complete G and F genes and enzyme-linked immunosorbent assay analysis with anti-G and anti-F monoclonal antibodies. Phylogenetic analyses showed that the G-proteins clustered into the two genotypes GA2 and GA5. The antigenic analysis of G-gene was carried out with a panel of anti-G and anti-F monoclonal antibodies that recognized strain-specific or variable epitopes which were originally derived against long strain (subtype GA1) and MON-3-88 strain (GA2). An amino acid substitution was found in a potential O-glycosylation site leading to a loss of reactivity with a strain-specific MAb. A score was calculated for quantifying the overall reactivity of the antibodies. If reactivity of all MAbs was totalized, a net sum loss of reactivity was seen over the time suggesting that antigenic drift due to immune selection may be occurring.

Neonatal calf infection with respiratory syncytial virus: drawing parallels to the disease in human infants

Respiratory syncytial virus (RSV) is the most common viral cause of childhood acute lower respiratory tract infections. It is estimated that RSV infections result in more than 100,000 deaths annually worldwide. Bovine RSV is a cause of enzootic pneumonia in young dairy calves and summer pneumonia in nursing beef calves. Furthermore, bovine RSV plays a significant role in bovine respiratory disease complex, the most prevalent cause of morbidity and mortality among feedlot cattle. Infection of calves with bovine RSV shares features in common with RSV infection in children, such as an age-dependent susceptibility. In addition, comparable microscopic lesions consisting of bronchiolar neutrophilic infiltrates, epithelial cell necrosis, and syncytial cell formation are observed. Further, our studies have shown an upregulation of pro-inflammatory mediators in RSV-infected calves, including IL-12p40 and CXCL8 (IL-8). This finding is consistent with increased levels of IL-8 observed in children with RSV bronchiolitis. Since rodents lack IL-8, neonatal calves can be useful for studies of IL-8 regulation in response to RSV infection. We have recently found that vitamin D in milk replacer diets can be manipulated to produce calves differing in circulating 25-hydroxyvitamin D3. The results to date indicate that although the vitamin D intracrine pathway is activated during RSV infection, pro-inflammatory mediators frequently inhibited by the vitamin D intacrine pathway in vitro are, in fact, upregulated or unaffected in lungs of infected calves. This review will summarize available data that provide parallels between bovine RSV infection in neonatal calves and human RSV in infants.

Circulating strains of human respiratory syncytial virus in central and south America

Human respiratory syncytial virus (HRSV) is a major cause of viral lower respiratory tract infections among infants and young children. HRSV strains vary genetically and antigenically and have been classified into two broad subgroups, A and B (HRSV-A and HRSV-B, respectively). To date, little is known about the circulating strains of HRSV in Latin America. We have evaluated the genetic diversity of 96 HRSV strains by sequencing a variable region of the G protein gene of isolates collected from 2007 to 2009 in Central and South America. Our results show the presence of the two antigenic subgroups of HRSV during this period with the majority belonging to the genotype HRSV-A2.

Ten years of global evolution of the human respiratory syncytial virus BA genotype with a 60-nucleotide duplication in the G protein gene

The emergence of natural isolates of human respiratory syncytial virus group B (HRSV-B) with a 60-nucleotide (nt) duplication in the G protein gene in Buenos Aires, Argentina, in 1999 (A. Trento et al., J. Gen. Virol. 84:3115-3120, 2003) and their dissemination worldwide allowed us to use the duplicated segment as a natural tag to examine in detail the evolution of HRSV during propagation in its natural host. Viruses with the duplicated segment were all clustered in a new genotype, named BA (A. Trento et al., J. Virol. 80:975-984, 2006). To obtain information about the prevalence of these viruses in Spain, we tested for the presence of the duplicated segment in positive HRSV-B clinical samples collected at the Severo Ochoa Hospital (Madrid) during 12 consecutive epidemics (1996-1997 to 2007-2008). Viruses with the 60-nt duplication were found in 61 samples, with a high prevalence relative to the rest of B genotypes in the most recent seasons. Global phylogenetic and demographic analysis of all G sequences containing the duplication, collected across five continents up until April 2009, revealed that the prevalence of the BA genotype increased gradually until 2004-2005, despite its rapid dissemination worldwide. After that date and coinciding with a bottleneck effect on the population size, a relatively new BA lineage (BA-IV) replaced all other group B viruses, suggesting further adaptation of the BA genotype to its natural host.

Genetic variability of respiratory syncytial viruses (RSV) prevalent in Southwestern China from 2006 to 2009: emergence of subgroup B and A RSV as dominant strains

Respiratory syncytial virus (RSV) is the most commonly identified viral agent in young children with acute respiratory tract infections (ARIs) and often causes repeated infections throughout life. This study investigated the genetic variability of the attachment (G) protein gene among RSV strains prevalent in southwestern China. Reverse transcription-PCR (RT-PCR) for a fragment of the RSV G gene was performed with nasopharyngeal aspirates (NPAs) collected from children with ARIs hospitalized in Chongqing Children's Hospital, Chongqing, China. A total of 1,387 NPA specimens were collected from April 2006 to March 2009, and 439 (31.7%) were positive for RSV. During the study period, subgroup A and B viruses accounted for 79.5% (349/439) and 19.8% (87/439) of the total positive samples, respectively. Both subgroup A and B viruses were identified in three samples. Subgroup A viruses were predominant during two epidemic seasons (2006 to 2008), while subgroup B strains prevailed during the 2008-2009 epidemic season. Phylogenetic analyses showed that all 30 group A strains could be clustered into one genotype, genotype GA2, and 30 group B strains could be clustered into three genotypes, genotypes GB1, GB3, and BA, among which 17 genotype BA strains were detected from 23 group B strains selected during the 2008-2009 epidemic season. The G gene of genotype BA was predicted to encode proteins of five different lengths. These data suggest that group A RSV likely predominated in southwestern China and that a new genotype of subgroup B with a 60-nucleotide insertion, named BA-like virus, became the dominant genotype in the 2008-2009 epidemic season.

Genetic variability in the G protein gene of group A and B respiratory syncytial viruses from India

Respiratory syncytial virus (RSV) is the most commonly identified viral agent of acute respiratory tract infection (ARI) of young children and causes repeat infections throughout life. Limited data are available on the molecular epidemiology of RSV from developing countries, including India. This study reports on the genetic variability in the glycoprotein G gene among RSV isolates from India. Reverse transcription-PCR for a region of the RSV G protein gene was done with nasopharyngeal aspirates (NPAs) collected in a prospective longitudinal study in two rural villages near Delhi and from children with ARI seen in an urban hospital. Nucleotide sequence comparisons among 48 samples demonstrated a higher prevalence of group A (77%) than group B (23%) RSV isolates. The level of genetic variability was higher among the group A viruses (up to 14%) than among the group B viruses (up to 2%). Phylogenetic analysis revealed that both the GA2 and GA5 group A RSV genotypes were prevalent during the 2002-2003 season and that genotype GA5 was predominant in the 2003-2004 season, whereas during the 2004-2005 season both genotype GA5 and genotype BA, a newly identified group B genotype, cocirculated in almost equal proportions. Comparison of the nonsynonymous mutation-to-synonymous mutation ratios (dN/dS) revealed greater evidence for selective pressure between the GA2 and GA5 genotypes (dN/dS, 1.78) than within the genotypes (dN/dS, 0.69). These are among the first molecular analyses of RSV strains from the second most populous country in the world and will be useful for comparisons to candidate vaccine strains.

Genetic diversity among respiratory syncytial viruses that have caused repeated infections in children from rural India

Respiratory syncytial virus (RSV) causes repeat infections throughout life. Antigenic variability in the RSV G protein may play a significant role in reinfections. A variable region of the RSV G gene was analyzed for 14 viruses from seven children who experienced initial and repeat infections. Eleven group A strains were in clades GA2 and GA5 and the three group B viruses were in the newly identified BA clade. In five children reinfections were caused by a heterologous group or genotype of RSV. Two children experienced infection and reinfection by viruses of the same clade, these virus pairs differed by only two to three amino acids in the region compared. This is the first report of RSV nucleotide sequence analysis from India and one of the few molecular characterizations of paired RSV from reinfections. Determining the molecular basis of reinfections may have important implications for RSV vaccine development.

Natural history of human respiratory syncytial virus inferred from phylogenetic analysis of the attachment (G) glycoprotein with a 60-nucleotide duplication

A total of 47 clinical samples were identified during an active surveillance program of respiratory infections in Buenos Aires (BA) (1999 to 2004) that contained sequences of human respiratory syncytial virus (HRSV) with a 60-nucleotide duplication in the attachment (G) protein gene. This duplication was analogous to that previously described for other three viruses also isolated in Buenos Aires in 1999 (A. Trento et al., J. Gen. Virol. 84:3115-3120, 2003). Phylogenetic analysis indicated that BA sequences with that duplication shared a common ancestor (dated about 1998) with other HRSV G sequences reported worldwide after 1999. The duplicated nucleotide sequence was an exact copy of the preceding 60 nucleotides in early viruses, but both copies of the duplicated segment accumulated nucleotide substitutions in more recent viruses at a rate apparently higher than in other regions of the G protein gene. The evolution of the viruses with the duplicated G segment apparently followed the overall evolutionary pattern previously described for HRSV, and this genotype has replaced other prevailing antigenic group B genotypes in Buenos Aires and other places. Thus, the duplicated segment represents a natural tag that can be used to track the dissemination and evolution of HRSV in an unprecedented setting. We have taken advantage of this situation to reexamine the molecular epidemiology of HRSV and to explore the natural history of this important human pathogen.

Intragroup antigenic diversity of human respiratory syncytial virus (group A) isolated in Argentina and Chile

The intragroup antigenic diversity of the G glycoprotein of 226 human respiratory syncytial virus (HRSV) strains isolated in Buenos Aires (Argentina) and Santiago (Chile) between 1995 and 2002 was evaluated by ELISA with a panel of 14 anti-G monoclonal antibodies (MAbs). Out of 226 strains characterized, 172 (76%) belonged to group A and 54 (24%) to group B. Strains from both groups cocirculated throughout the study period in both countries, except in 1996, 2000, and 2002 when only group A strains were isolated. Within group A 23 different antigenic patterns were found as defined by the combination of reactivities with eight strain-specific anti-G MAbs. These antigenic patterns showed different behavior regarding their circulation. Some major patterns were observed in most years with variable proportions; other minor patterns were present in low proportions during 1 or 2 years and then were apparently replaced by new patterns. Some antigenic patterns occurred both in Argentina and Chile during the same epidemics. Since no strain-specific MAbs were available for group B, we could not evidence the antigenic variability within group B. These are the first data on antigenic characterization of HRSV strains isolated in Argentina and Chile. It is shown that the ELISA with MAbs directed against the G protein of RSV is a valuable tool. These results will also provide useful information for further studies to evaluate the antigenic variability of HRSV strains in relation with genetic characteristics.

Molecular epidemiology of human respiratory syncytial virus in Uruguay: 1985-2001--a review

The variability of the G glycoprotein from human respiratory syncytial viruses (HRSV) (groups A and B) isolated during 17 consecutive epidemics in Montevideo, Uruguay have been analyzed. Several annual epidemics were studied, where strains from groups A and B circulated together throughout the epidemics with predominance of one of them. Usually, group A predominates, but in some epidemics group B is more frequently detected. To analyse the antigenic diversity of the strains, extracts of cells infected with different viruses of group A were tested with a panel of anti-G monoclonal antibodies (MAbs). The genetic variability of both groups was analyzed by sequencing the C-terminal third of the G protein gene. The sequences obtained together with previously published sequences were used to perform phylogenetic analyses. The data from Uruguayan isolates, together with those from the rest of the world provide information regarding worldwide strain circulation. Phylogenetic analyses of HRSV from groups A and B show a model of evolution analogous to the one proposed for influenza B viruses providing information that would be beneficial for future immunization programs and to design safe vaccines.

Shifting immunodominance pattern of two cytotoxic T-lymphocyte epitopes in the F glycoprotein of the Long strain of respiratory syncytial virus

Human respiratory syncytial virus (RSV) is a major cause of respiratory infection in children and in the elderly. The RSV fusion (F) glycoprotein has long been recognized as a vaccine candidate as it elicits cytotoxic T-lymphocyte (CTL) and antibody responses. Two murine H-2K(d)-restricted CTL epitopes (F85-93 and F92-106) are known in the F protein of the A2 strain of RSV. F-specific CTL lines using BCH4 fibroblasts that are persistently infected with the Long strain of human RSV as stimulators were generated, and it was found that in this strain only the F85-93 epitope is conserved. Motif based epitope prediction programs and an F2 chain deleted F protein encoded in a recombinant vaccinia virus enabled identification of a new epitope in the Long strain, F249-258, which is presented by K(d) as a 9-mer (TYMLTNSEL) or a 10-mer (TYMLTNSELL) peptide. The results suggest that the 10-mer might be a naturally processed endogenous K(d) ligand. The CD8(+) T-lymphocyte responses to epitopes F85-93 and F249-258 present in the F protein of RSV Long were found to be strongly skewed to F85-93 in in vitro multispecific CTL lines and in vivo during a secondary response to a recombinant vaccinia virus that expresses the entire F protein. However, no hierarchy in CD8(+) T-lymphocyte responses to F85-93 and F249-258 epitopes was observed in vivo during a primary response.

A model for the generation of multiple A to G transitions in the human respiratory syncytial virus genome: predicted RNA secondary structures as substrates for adenosine deaminases that act on RNA

Human respiratory syncytial virus (HRSV) escape mutants selected with antibodies specific for the attachment (G) protein contain diverse genetic alterations, including point mutations, premature stop codons, frame shift changes and A to G hypermutations. The latter changes have only been found in mutants selected with antibodies directed against the conserved central region of the G protein. This gene segment fulfils substrate requirements for adenosine deaminases that act on RNA (ADARs): i.e. it is an A+U rich region of 137 residues, and 98 or 106 of them--for A/Mon/3/88 or Long HRSV strains, respectively--are predicted to form intramolecular base pairs leading to a stable RNA secondary structure. In addition, when sequences of the G gene from natural isolates are compared in terms of pairwise substitutions, A to G+G to A changes are preferentially observed in regions where stable intramolecular dsRNA secondary structures are predicted to occur. In this study, a model is proposed in which, in addition to nucleotide misincorporations, reiterative A to G changes in HRSV are generated by ADAR activity operating in short segments (100-200 ribonucleotide residues) of the HRSV genome with high tendency for intramolecular base pairing.

RNase cleavage-based methods for mutation/SNP detection, past and present

Mutation detection based on ribonuclease cleavage of basepair mismatches in single-stranded RNA probes hybridized to DNA targets was first described over 15 years ago. The original methods relied on RNase A for mismatch cleavage; however, this enzyme fails to cleave many mismatches and has other drawbacks. More recently, a new method for RNase-cleavage-based mutation scanning has been developed, which takes advantage of the ability of RNase 1 and RNase T1 to cleave mismatches in duplex RNA targets, when these enzymes are used in conjunction with nucleic acid intercalating dyes. The method, called NIRCA, is relatively low-cost in terms of materials and equipment required. It is being used to detect mutations and SNPs in a wide variety of genes involved in human genetic disease and cancer, as well as in disease-related viral and bacterial genes. This review describes historical and recently developed RNase cleavage-based methods for mutation/SNP scanning.

Genetic variability of respiratory syncytial virus subgroup a strain in 15 successive epidemics in one city

The genetic variability of 125 respiratory syncytial virus (RSV) subgroup A isolates over 15 successive epidemics from 1980 to 1995 in an urban population of Japan was determined. Allocation of isolates into lineages was archived by reverse transcriptase-polymerase chain reaction amplification of selected regions of the nucleoprotein (NP) and attachment (G) protein gene followed by restriction fragment length polymorphism (RFLP) analysis. Three and seven distinct restriction patterns of the NP and G gene were observed, respectively. When the NP and G gene RFLP analyses were combined, ten different genetic lineages were identified in the 125 isolates. The strains with the same genotype were isolated in each epidemic and the dominant lineages were replaced by others after every one to three consecutive epidemics. Nucleotide and amino acid sequencing of the variable region of G gene of these predominant isolates revealed differences of 5--28% between strains. There was, however, no apparent accumulation of diversity with age to indicate progressive changes. The dominant strains were often closely related to those isolated in other parts of the world at a similar time. These observations suggest that dominant RSV strains are replaced frequently by others that have been co-circulating or have recently entered the community from a worldwide reservoir. The change of dominant strains may be influenced by the buildup of immunological resistance in the community to successive epidemics of the same strain.

Genetic variability among group A and B respiratory syncytial viruses in Mozambique: identification of a new cluster of group B isolates

Respiratory syncytial virus (RSV) is the major cause of acute lower respiratory tract infection in children and vulnerable adults, but little is known regarding RSV infection in Africa. In this report, a recent RSV outbreak in Mozambique was studied and results showed that 275 of 3192 (8.6%) nasopharyngeal aspirates tested were RSV-positive by ELISA. RSV presents two antigenic groups (A and B) with a high genetic and antigenic variability between and within them. Analysis by a new RFLP assay of RT-PCR amplified N protein gene products showed a higher prevalence of group B RSV than that of group A (85% versus 15%). However, genetic variability of the G protein gene was higher among group A RSV strains. The frequency and pattern of glycosylation sites were also quite different between both groups. In addition, two different phylogenetic clusters of Mozambican viruses were found within each group, but only sequences from cluster B-I were relatively distinct from previously described isolates. The implications of such differences in the antigenic and immunogenic characteristics of each group are discussed.

Electron microscopy of the human respiratory syncytial virus fusion protein and complexes that it forms with monoclonal antibodies

Full-length fusion (F) glycoprotein of human respiratory syncytial virus (HRSV) and a truncated anchorless mutant lacking the C-terminal 50 amino acids were expressed from vaccinia recombinants and purified by immunoaffinity chromatography and sucrose gradient centrifugation. Electron microscopy of full-length F protein in the absence of detergents revealed micelles, (i.e., rosettes) containing two distinct types of protein rods, one cone-shaped and the other lollipop-shaped. Analysis of membrane anchorless F molecules indicated that they were similar to the cone-shaped rods and that rosettes, which they formed on storage, were made up of lollipop-shaped rods. The two forms of F protein may represent different structures that the molecule may adopt before and after activation for its role in membrane fusion. Studies of complexes of these structures with monoclonal antibodies of known specificity provide information on the three-dimensional organization of antigenic sites on the F protein and confirm the oligomeric structure, possibly trimeric, of both full-length F and membrane anchorless F.

Respiratory syncytial virus genetic and antigenic diversity

Respiratory syncytial virus (RSV) is a major cause of viral lower respiratory tract infections among infants and young children in both developing and developed countries. There are two major antigenic groups of RSV, A and B, and additional antigenic variability occurs within the groups. The most extensive antigenic and genetic diversity is found in the attachment glycoprotein, G. During individual epidemic periods, viruses of both antigenic groups may cocirculate or viruses of one group may predominate. When there are consecutive annual epidemics in which the same group predominates, the dominant viruses are genetically different from year to year. The antigenic differences that occur among these viruses may contribute to the ability of RSV to establish reinfections throughout life. The differences between the two groups have led to vaccine development strategies that should provide protection against both antigenic groups. The ability to discern intergroup and intragroup differences has increased the power of epidemiologic investigations of RSV. Future studies should expand our understanding of the molecular evolution of RSV and continue to contribute to the process of vaccine development.

Respiratory syncytial virus genetic and antigenic diversity

Respiratory syncytial virus (RSV) is a major cause of viral lower respiratory tract infections among infants and young children in both developing and developed countries. There are two major antigenic groups of RSV, A and B, and additional antigenic variability occurs within the groups. The most extensive antigenic and genetic diversity is found in the attachment glycoprotein, G. During individual epidemic periods, viruses of both antigenic groups may cocirculate or viruses of one group may predominate. When there are consecutive annual epidemics in which the same group predominates, the dominant viruses are genetically different from year to year. The antigenic differences that occur among these viruses may contribute to the ability of RSV to establish reinfections throughout life. The differences between the two groups have led to vaccine development strategies that should provide protection against both antigenic groups. The ability to discern intergroup and intragroup differences has increased the power of epidemiologic investigations of RSV. Future studies should expand our understanding of the molecular evolution of RSV and continue to contribute to the process of vaccine development.

Priming with a secreted form of the fusion protein of respiratory syncytial virus (RSV) promotes interleukin-4 (IL-4) and IL-5 production but not pulmonary eosinophilia following RSV challenge

The attachment (G) protein of respiratory syncytial virus (RSV) is synthesized as two mature forms: a membrane-anchored form and a smaller secreted form. BALB/c mice scarified with vaccinia virus (VV) expressing the secreted form develop a greater pulmonary eosinophilic influx following RSV challenge than do mice scarified with VV expressing the membrane-anchored form. To determine if a soluble form of an RSV protein was sufficient to induce eosinophilia following RSV challenge, a cDNA that encoded a secreted form of the fusion (F) protein of RSV was constructed and expressed in VV (VV-Ftm(-)). Splenocytes and lung lymphocytes from mice primed with VV-Ftm(-) produced significantly more of the Th2 cytokines interleukin-4 (IL-4) and IL-5 than did mice vaccinated with VV expressing either the native (membrane-anchored) form of the F protein or the G protein. Although mice scarified with VV-Ftm(-) developed a slight increase in the number of pulmonary eosinophils following RSV infection, the increase was not as great as that seen in VV-G-primed mice. Despite the increased IL-4 and IL-5 production and in contrast to mice primed with VV-G, mice primed with VV-Ftm(-) developed RSV-specific cytotoxic T lymphocytes (CTL) and maintained high levels of gamma interferon production. These data demonstrate that recombinant VV strains expressing soluble forms of RSV proteins induce immune responses that are more Th2-like. However, this change alone does not appear sufficient to induce vaccine-augmented disease in the face of active CD8(+) CTL populations.

Methods for subtyping and molecular comparison of human viral genomes

The development over the past two decades of molecular methods for manipulation of RNA and DNA has afforded molecular virologists the ability to study viral genomes in detail that has heretofore not been possible. There are many molecular techniques now available for typing and subtyping of viruses. The available methods include restriction fragment length polymorphism analysis, Southern blot analysis, oligonucleotide fingerprint analysis, reverse hybridization, DNA enzyme immunoassay, RNase protection analysis, single-strand conformation polymorphism analysis, heteroduplex mobility assay, nucleotide sequencing, and genome segment length polymorphism analysis. The methods have certain advantages and disadvantages which should be considered in their application to specific viruses or for specific purposes. These techniques are likely to become more widely used in the future for epidemiologic studies and for investigations into the pathophysiology of virus infections.

Antigenic and genetic characterization of twenty-six strains of human respiratory syncytial virus (subgroup A) isolated during three consecutive outbreaks in Havana city, Cuba

Twenty-six human respiratory syncytial virus strains (subgroup A) isolated from three outbreaks in Havana City during the period 1994/95, 1995/96 and 1996/97 were analyzed to determine their antigenic and genetic relationships. Analyses were performed by monoclonal antibodies and restriction mapping (N gene) following amplification of the select region of the virus genome by polymerase chain reaction. All isolated strains were classified as subgroup A by monoclonal antibodies and they showed a restriction pattern NP4 that belonged to subgroup A. Thus the results obtained in this work, showed a close relation (100%) between antigenic and genetic characterization of the isolated strains in our laboratory. These methods permit the examination of large numbers of isolates by molecular techniques, simplifying the researchs into the molecular epidemiology of the virus.

Analysis of ruminant respiratory syncytial virus isolates by RNAse protection of the G glycoprotein transcripts

Two different respiratory syncytial virus (RSV) radiolabeled probes were used to characterize the genetic heterogeneity of 25 ruminant RSV isolates by the ribonuclease protection assay. A 32P-radiolabeled antisense RNA probe was transcribed from cloned ovine and bovine RSV G glycoprotein genes and then hybridized with total RNA isolated from infected cells with various ruminant RSV isolates. The results of this study, along with previously published nucleotide sequence data of the ovine RSV G glycoprotein gene, suggest the presence of at least 2 ruminant RSV subgroups. One subgroup is represented by RSV isolated from respiratory disease outbreaks from calves and goats, and the other is represented by RSV isolated from sheep.

Genetic variability among group A and group B respiratory syncytial viruses in a children's hospital

Respiratory syncytial (RS) viruses isolated over three epidemic periods in a children's hospital in the United States were analyzed. The viruses (n = 174) were characterized as to major antigenic group (group A or B) by a PCR-based assay. Group A RS viruses were dominant the first 2 years, followed by a year with group B dominance (ratios of group A to group B viruses for epidemic periods, 56/4 for 1993-1994, 42/3 for 1994-1995, and 19/50 for 1995-1996). Genetic variability within the groups was assessed by restriction fragment analysis of PCR products; 79 isolates were also analyzed by nucleotide sequence determination of a variable region of the glycoprotein G gene. Among the group A RS virus isolates, this G-protein variable region had amino acid differences of as great as 38%. The G-protein amino acids of the group A viruses differed by up to 31% from the G-protein amino acids of a prototype (A2) group A virus. Among the group B RS virus G proteins, amino acid differences were as great as 14%. The G-protein amino acids of the group B viruses differed by up to 27% from the G-protein amino acids of a prototype (18537) group B virus. The group A and group B RS viruses demonstrated genetic variability between years and within individual years. Phylogenetic analysis revealed that there were multiple evolutionary lineages among both the group A and group B viruses. Among the recent group B isolates, variability was less than that seen for the group A viruses. However, comparisons to prototype strains revealed that the group B RS viruses may vary more extensively than was observed over the 3 years studied in the present investigation.

Subcellular Site of Expression and Route of Vaccination Influence Pulmonary Eosinophilia Following Respiratory Syncytial Virus Challenge in BALB/c Mice Sensitized to the Attachment G Protein

The attachment glycoprotein (G) of respiratory syncytial virus (RSV) is synthesized as two mature forms: a membrane-anchored form and a smaller secreted form. Mutant cDNAs were constructed that encoded one or the other form of the protein and were expressed in recombinant vaccinia viruses (rVV). Mice were immunized with rVV by dermal scarification or i.p. injection to determine the contribution of the membrane-anchored and secreted forms of the G protein on the augmentation of pulmonary pathology seen following RSV challenge. Mice scarified with rVV expressing the membrane-anchored G protein had a markedly reduced pulmonary eosinophilic response following RSV challenge compared with mice scarified with rVV expressing either wild-type or secreted G protein. The induction of pulmonary eosinophilia in rVV-primed mice was also dependent upon the route of vaccination. An eosinophilic response was not observed in any groups of mice immunized i.p. with rVV expressing any of the different forms of the G protein The difference in pulmonary pathology observed between dermal scarification or i.p. vaccinated mice was not reflected in a difference in cytokine production by splenocytes from vaccinated and challenged mice restimulated with RSV in vitro. Both groups produced significant levels of IL-4 and IL-5. These data suggest that the local APCs and lymphoid environment, together with the form of the G protein, influence pulmonary pathology following RSV challenge.

Genetic analysis of the G and P genes in ungulate respiratory syncytial viruses by RNase A mismatch cleavage method

The G and P genes of bovine, ovine and caprine respiratory syncytial (RS) viruses were analyzed by RNase A one-dimensional fingerprinting, using A 51908 as the reference strain. Antisense G or P RNA probes of bovine RS virus strain A 51908 were hybridized to total RNA extracted from bovine turbinate cells infected with bovine, ovine or caprine RS virus strains. The RNA:RNA heteroduplexes were digested with RNase A and the resistant products were analyzed by gel electrophoresis. Comparative analysis of the cleavage patterns revealed heterogeneity among bovine, ovine and caprine RS virus isolates. Ovine RS virus strains generated RNA cleavage patterns more distantly related to the bovine or caprine RS virus strains, particularly in the G gene. Statistical analysis of the results obtained indicated that genetic differences between bovine and ovine viruses were larger, compared with the ones among bovine strains themselves. The same analysis also revealed a close genetic relation among bovine and caprine strains. These results are discussed in terms of ungulate RS virus genetic variation and vaccine development.

Recombinant vaccinia virus coexpressing the F protein of respiratory syncytial virus (RSV) and interleukin-4 (IL-4) does not inhibit the development of RSV-specific memory cytotoxic T lymphocytes, whereas priming is diminished in the presence of high levels of IL-2 or gamma interferon

In order to investigate if immune responses to the fusion (F) protein of respiratory syncytial virus (RSV) could be influenced by cytokines, recombinant vaccinia viruses (rVV) carrying both the F gene of RSV and the gene for murine interleukin-2 (IL-2), IL-4, or gamma interferon (IFN-gamma) were constructed. In vitro characterization of rVV revealed that insertion of the cytokine gene into the VP37 locus of the vaccinia virus genome resulted in 100- to 1,000-fold higher expression than insertion of the same gene into the thymidine kinase (TK) locus. In comparison, only a two- to fivefold difference in the level of expression of the F protein was observed when the gene was inserted into either of these two loci. Mice vaccinated with rVV expressing the F protein and high levels of IL-2 or IFN-gamma cleared rVV more rapidly than mice inoculated with a control rVV and developed only low levels of RSV-specific serum antibody. In addition, these recombinants were much less effective at priming RSV-specific memory cytotoxic T lymphocytes (CTL) and IFN-gamma production by spleen cells than rVV expressing the F protein alone. In contrast, mice vaccinated with rVV expressing high levels of IL-4 showed signs of delayed rVV clearance. RSV-specific serum antibody responses were biased in favor of immunoglobulin G1 (IgG1) in these mice, as there was a significant reduction in IgG2a antibody responses compared with serum antibody responses in mice vaccinated with rVV expressing the F protein alone. However, vaccination with rVV expressing the F protein together with high levels of IL-4 did not alter the development of RSV-specific memory CTL or IFN-gamma production by RSV-restimulated splenocytes.

Genetic variation in populations of kennedya yellow mosaic tymovirus

Kennedya yellow mosaic tymovirus (KYMV) occurs along the eastern Australian seaboard in the perennial legumes Desmodium triflorum and D. scorpiurus in the north, and Kennedya rubicunda in the south. The genetic variation of more than 100 isolates of KYMV, most of them from the north, has been studied using an RNA hybrid mismatch polymorphism (RHMP) method. The method clearly separated the isolates into two groups; all the northern Desmodium isolates formed one group and all the Kennedya isolates from the south another. These sub-populations were themselves variable and the Desmodium population alone was more variable than that of the related turnip yellow mosaic tymovirus in the Kosciusko alpine area.

Rapid diagnosis of Argentine hemorrhagic fever by reverse transcriptase PCR-based assay

Argentine hemorrhagic fever (AHF) is an endemo-epidemic disease caused by Junín virus. This report demonstrates that a reverse transcriptase (RT) PCR-based assay developed in our laboratory to detect Junín virus in whole blood samples is sensitive and specific. The experiments were conducted in a double-blinded manner using 94 clinical samples collected in the area in which AHF is endemic. The RT-PCR-based assay was compared with traditional methodologies, including enzyme-linked immunosorbent assay, plaque neutralization tests, and occasionally viral isolation. The calculated parameters for RT-PCR diagnosis, with seroconversion as the "gold standard," were 98% sensitivity and 76% specificity. It is noteworthy that 94% of the patients with putative false-positive results (RT-PCR positive and no seroconversion detected) exhibited febrile syndromes of undefined etiology. These results could be interpreted to mean that most of those patients with febrile syndromes were actually infected with Junín virus but did not develop a detectable immune response. Furthermore, 8 laboratory-fabricated samples and 25 blood samples of patients outside the area in which AHF is endemic tested in a similar way were disclosed correctly (100% match). The RT-PCR assay is the only laboratory test available currently for the early and rapid diagnosis of AHF. It is sensitive enough to detect the low viremia found during the period in which immune plasma therapy can be used effectively, reducing mortality rates from 30% to less than 1%.

Comparative study of the genetic variability in thymidine kinase and glycoprotein B genes of herpes simplex viruses by the RNase A mismatch cleavage method

The variability of herpes simplex viruses has been measured using the RNAse A mismatch cleavage method in two genes: thymidine kinase and glycoprotein B of both HSV-1 and HSV-2. This technique permitted us to study the variability of the virus with a greater level of resolution than restriction endonuclease analysis. The phylogenetic trees obtained for the different genes allowed us to identify consistent clusters of viruses circulating in the same geographical area. Our results showed that thymidine kinase is more heterogeneous than glycoprotein B for both subtypes of HSV, and confirmed that HSV-1 is more heterogeneous than HSV-2 for both genes. This is the first time that this kind of analysis has been applied to DNA viruses.

Hyperimmune globulins in prevention and treatment of respiratory syncytial virus infections

Respiratory syncytial virus (RSV) is an important community and nosocomial respiratory pathogen for infants and young children. RSV causes especially severe disease in the prematurely born or those with chronic cardiopulmonary diseases. Elderly persons and those with T-cell deficiencies, such as bone marrow transplant recipients, are also at high risk for serious lower respiratory tract infections. To date, prevention of RSV infections by vaccination has proven elusive and no preventive drugs exist. Studies in animals and humans have shown that the lower respiratory tract can be protected from RSV infection by sufficient circulating RSV neutralizing antibody levels. Recently, an RSV hyperimmune immune globulin (RSVIG) was developed and tested for the prevention of RSV infections or reduction of disease severity. Passive immunization of high-risk children with RSVIG during the respiratory disease season effected significant reductions in RSV infections, hospitalizations, days of hospitalization, intensive care unit admissions, days in the intensive care unit, and ribavirin use. Studies in cotton rats and owl monkeys show that RSV infections can also be treated with inhalation of immune globulin at doses substantially smaller than required for parenteral treatment. Therapeutic trials of parenteral RSVIG have been completed and are pending analysis. The use of polyclonal, hyperimmune globulins and perhaps human monoclonal antibodies provides an additional approach to the prevention and perhaps the treatment of certain viral lower respiratory tract infections such as those caused by RSV.

Genetic heterogeneity of the attachment glycoprotein G among group A respiratory syncytial viruses

Fifteen independent group A respiratory syncytial virus (RSV) isolates were compared by sequencing a 300-nucleotide interval encoding a variable region of the attachment glycoprotein G. The viruses compared included the reference strains Long (USA 1956), A2 (Australia 1961), and 669 (Sweden 1959), along with 13 clinical isolates obtained at different times and locations throughout the United States. Representatives of all six antigenic subgroups, recognized by reactivity patterns with monoclonal antibodies, were compared. The maximum sequence heterogeneity within the G glycoprotein region compared was 15.7% of nucleotide sequences and 26% of amino acid sequences, more than twice the difference observed between Long and A2. Half of the nucleotide changes encoded amino acid substitutions, possibly indicating that the protein interval compared was subject to immune selection. Because the ratio of nucleotide to amino acid substitutions was nearly constant for all degrees of genetic divergence, the potential range of sequence divergence among group A RSV has probably not yet been attained. There was little correlation between the patterns of reactivity against a panel of monoclonal antibodies and sequence relationships among the 15 isolates. The sequence information showed multiple genotypes circulating simultaneously in the same community and very similar genotypes circulating in widely separated communities and during different years. Genetic analyses of RSV strains can provide important information about the relationships between RSV infections.

Evolutionary pattern of human respiratory syncytial virus (subgroup A): cocirculating lineages and correlation of genetic and antigenic changes in the G glycoprotein

The genetic and antigenic variability of the G glycoproteins from 76 human respiratory syncytial (RS) viruses (subgroup A) isolated during six consecutive epidemics in either Montevideo, Uruguay, or Madrid, Spain, have been analyzed. Genetic diversity was evaluated for all viruses by the RNase A mismatch cleavage method and for selected strains by dideoxy sequencing. The sequences reported here were added to those published for six isolates from Birmingham, United Kingdom, and for two reference strains (A2 and Long), to derive a phylogenetic tree of subgroup A viruses that contained two main branches and several subbranches. During the same epidemic, viruses from different branches were isolated. In addition, closely related viruses were isolated in distant places and in different years. These results illustrate the capacity of the virus to spread worldwide, influencing its mode of evolution. The antigenic analysis of all isolates was carried out with a panel of anti-G monoclonal antibodies that recognized strain-specific (or variable) epitopes. A close correlation between genetic relatedness and antigenic relatedness in the G protein was observed. These results, together with an accumulation of amino acid changes in a major antigenic area of the G glycoprotein, suggest that immune selection may be a factor influencing the generation of RS virus diversity. The pattern of RS virus evolution is thus similar to that described for influenza type B viruses, expect that the level of genetic divergence among the G glycoproteins of RS virus isolates is the highest reported for an RNA virus gene product.

Estimates by computer simulation of genetic distances from comparisons of RNAse A mismatch cleavage patterns

The RNAse A mismatch cleavage method was used to analyze genomic variability in RNA and DNA systems. However, there is no method which relates the digestion patterns observed to the extent of genetic variation. Here we report computer simulations which provide a simple estimator of genetic distances from the comparison of RNAse A digestion patterns. The results show that the number of non-shared fragments is proportional to the number of mutations between each pair of sequences compared. This prediction is supported by the comparison of the RNAse A mismatch patterns and the nucleotide sequences of a set of influenza A (H3N2) hemagglutinin genes. The procedure allows a quantitative and reliable use of the RNAse A mismatch cleavage method.

Analysis of respiratory syncytial virus genetic variability with amplified cDNAs

Antigenic and genetic heterogeneities exist within the two major antigenic groups of respiratory syncytial (RS) virus. We developed a polymerase chain reaction (PCR)-based assay that not only differentiates the two RS virus groups but allows distinctions within groups on the basis of changes in the nucleotide sequences, as revealed by restriction fragment analysis. In this assay, viral RNA served as a template for cDNA synthesis with extension from a synthetic oligonucleotide primer complementary to bases 164 to 186 in the F protein mRNA. For PCR amplification, two group-specific 5' primers were added. The two primers corresponded to the G protein mRNA sequence of group B (bases 10 to 30) or group A (bases 247 to 267) RS virus. Agarose gel electrophoresis readily discriminated the 1.1-kb group B and the 0.9-kb group A virus amplification products. All 47 viruses tested were assigned to the same group by both PCR and monoclonal antibody reaction pattern analysis. Restriction fragment analysis of the amplified DNAs revealed 12 restriction patterns for group A viruses and 7 restriction patterns for group B viruses, while the monoclonal antibody reaction patterns revealed seven patterns for group A viruses and 3 patterns for group B viruses. Most viruses with the same monoclonal antibody reaction patterns had different restriction patterns, and some viruses with the same restriction patterns had different monoclonal antibody reaction patterns. Thus, the results of the PCR assay concurred with the monoclonal antibody reaction pattern analysis for group classification of RS viruses, while the restriction fragment analysis identified greater diversity within groups than was seen with the monoclonal antibody analysis.

RNA hybrid mismatch polymorphisms in Australian populations of turnip yellow mosaic tymovirus

In the Mt. Kosciusko alpine area of Australia there are three well-separated populations of Cardamine lilacina, an endemic sward-forming perennial brassica, and these are infected with turnip yellow mosaic tymovirus. The genetic variation in these viral populations has been assessed by an RNA hybrid mismatch polymorphism method. About 100 isolates were examined; the genomic RNA of each isolate was prepared from a shoot of a single wild C. lilacina plant. RNA hybrid mismatch polymorphisms (RHMPs) were assessed in six regions of the genomes using labelled negative-strand probes transcribed from selected portions of a cloned TYMV genome. The probed region at the 3' end of the genome showed little variation and over 95% of the isolates gave the same pattern. However, other parts of the genome, including the 5' non-coding region, were much more variable. There was no significant correlation between groupings based on the RHMP patterns, and the location from which the isolates were collected, nor with the symptom type or severity shown by their host plants. The patterns of variation suggested that all three populations of the virus are a single quasi-species; at most one tenth of the isolates gave similar RHMP patterns, those of the "master copy".

Geographical clusters of dengue virus type 2 isolates based on analysis of infected cell RNA by the chemical cleavage at mismatch method

Genetic variation in 12 strains of dengue virus type 2, isolated from several epidemic areas in different years, was studied by chemical cleavage at mismatched cytosine in DNA:RNA heteroduplexes. End-labelled cDNA probes derived from the E and NS2A genes of the New Guinea C strain were hybridized to total RNA extracted from cells infected by individual isolates. Following modification of mismatched cytosine by hydroxylamine and nucleic acid strand cleavage by piperidine, the resulting fragments of radiolabelled probe were analysed by electrophoresis and autoradiography. The patterns of bands generated corresponded to the geographical groupings of the isolates. Thus this method is suitable in epidemiological studies for rapidly surveying a large number of isolates for genetic variation in a particular gene of interest.

Distinguishing between respiratory syncytial virus subgroups by protein profile analysis

We subgrouped 75 strains of respiratory syncytial virus by a protein profile method (PPM) which relies on different mobilities of the phosphoprotein in one-dimensional polyacrylamide gel electrophoresis and does not require monoclonal antibodies. When compared with enzyme immunoassay, PPM correctly subgrouped 54 of 56 subgroup A and all 19 subgroup B strains.

Genetic diversity of the attachment protein of subgroup B respiratory syncytial viruses

Respiratory syncytial (RS) virus causes repeated infections throughout life. Between the two main antigenic subgroups of RS virus, there is antigenic variation in the attachment protein G. The antigenic differences between the subgroups appear to play a role in allowing repeated infections to occur. Antigenic differences also occur within subgroups; however, neither the extent of these differences nor their contributions to repeat infections are known. We report a molecular analysis of the extent of diversity within the subgroup B RS virus attachment protein genes of viruses isolated from children over a 30-year period. Amino acid sequence differences as high as 12% were observed in the ectodomains of the G proteins among the isolates, whereas the cytoplasmic and transmembrane domains were highly conserved. The changes in the G-protein ectodomain were localized to two areas on either side of a highly conserved region surrounding four cysteine residues. Strikingly, single-amino-acid coding changes generated by substitution mutations were not the only means by which change occurred. Changes also occurred by (i) substitutions that changed the available termination codons, resulting in proteins of various lengths, and (ii) a mutation introduced by a single nucleotide deletion and subsequent nucleotide insertion, which caused a shift in the open reading frame of the protein in comparison to the other G genes analyzed. Fifty-one percent of the G-gene nucleotide changes observed among the isolates resulted in amino acid coding changes in the G protein, indicating a selective pressure for change. Maximum-parsimony analysis demonstrated that distinct evolutionary lineages existed. These data show that sequence diversity exists among the G proteins within the subgroup B RS viruses, and this diversity may be important in the immunobiology of the RS viruses.

Evolution of the G and P genes of human respiratory syncytial virus (subgroup A) studied by the RNase A mismatch cleavage method

The G and P genes of human respiratory syncytial viruses (subgroup A), isolated between 1961 and 1989, were analyzed by RNase A one-dimensional fingerprinting, using the Long strain as the reference. Total RNA extracted from cells infected with the different isolates was hybridized to radiolabeled antisense G or P RNA probes of the Long virus. The RNA:RNA heteroduplexes were digested with RNase A and the resistant products analyzed by gel electrophoresis. Comparative analysis of the cleavage patterns revealed extensive genetic heterogeneity in both genes among viruses isolated in different epidemics. In contrast, 13 viruses isolated in Montevideo during a 3-month period showed much more restricted heterogeneity; thus, 11 viruses represented the predominant type of this outbreak and only 2 other viruses generated different RNA cleavage patterns distantly related to the major type. Statistical analysis of the results obtained indicated progressive accumulation of genetic changes with time along cocirculating evolutionary lineages within the same antigenic subgroup of RS virus. The results are discussed in terms of a model for RS virus evolution.

Premature stop codons in the G glycoprotein of human respiratory syncytial viruses resistant to neutralization by monoclonal antibodies

Mutants of human respiratory syncytial (RS) virus which escaped neutralization by monoclonal antibodies directed against the G glycoprotein were selected from the Long strain. Most mutants showed drastic antigenic changes, reflected in the lack of reactivity with several anti-G antibodies, including the one used for selection. Sequence analysis revealed the presence of in-frame premature stop codons in the mutated G genes which shortened the G polypeptide by between 11 and 42 amino acids. In contrast, two mutants selected with monoclonal antibody 25G contained two amino acid substitutions (Phe-265----Leu and Leu-274----Pro) and had lost only the capacity to bind the antibody used in their selection. These results demonstrate that the carboxy-terminal end of the G molecule is dispensable for infectivity in tissue culture and indicate the importance of this part of the G protein in determining its antigenicity.

Characterization of genetic variation and 3'-azido-3'-deoxythymidine- resistance mutations of human immunodeficiency virus by the RNase A mismatch cleavage method

The RNase A mismatch cleavage method has been applied to the characterization of natural genetic variation of human immunodeficiency virus (HIV) from different geographical areas. The approach provides a rapid and simple assay for the analysis of differences in closely related viral isolates and allows the establishment of phylogenetic relationships between epidemiologically distinct viruses. Our results show a broad clustering of circulating viruses according to their geographical distribution. We also have analyzed the temporal appearance of mutations associated with the acquisition of resistance to 3'-azido-3'-deoxythymidine (AZT). The results show that mutations in codon 215 of the viral reverse transcriptase can be detected readily by this method in HIV isolates and also directly in peripheral blood from HIV-infected individuals after in vitro amplification of viral sequences with the polymerase chain reaction. The specific recurrence of identical double-nucleotide substitutions in epidemiologically and geographically distant viruses suggests that the restricted amino acid substitutions at this position selected by drug exposure are a critical, rate-limiting step in the acquisition of drug resistance.