A single amino acid change in the glycoprotein of lymphocytic choriomeningitis virus is associated with the ability to cause growth hormone deficiency syndrome.

Persistent infection of C3H/St mice with certain strains of lymphocytic choriomeningitis virus (LCMV) causes a growth hormone (GH) deficiency syndrome (GHDS) manifested as growth retardation and hypoglycemia. Infected mice show high levels of viral replication in the GH-producing cells in the anterior pituitary leading to decreased synthesis of GH mRNA and protein despite the absence of detectable virus-induced cell structural damage. Virus clones isolated from the GHDS-negative LCMV WE strain can cause the disease, while others cannot. The genetic basis of this phenotypic difference is a nucleotide substitution resulting in a single amino acid difference in the viral glycoprotein. Reassortant studies indicate that the single amino acid substitution (Ser-153 to Phe) is sufficient to allow infection of the GH-producing cells and cause GHDS. These results show that a single change in the genome can affect viral pathogenicity by altering the tropism of the virus.     

Construction and characterization of two infectious molecular clones of encephalomyocarditis virus.

We constructed and characterized two infectious molecular clones of encephalomyocarditis (EMC) virus. Both constructs, pDL and pDA, were assembled from five overlapping cDNA clones derived from the diabetogenic variant of EMC virus (EMC-D) and from two synthetic oligonucleotide cartridges. pDA contained a single point mutation at position 1720 within the "puff" region of capsid protein 1AB that was derived from the nondiabetogenic variant of EMC virus (EMC-B). This point mutation resulted in an amino acid substitution of arginine (EMC-B) for lysine (EMC-D). Our construction illustrates two novel findings: (i) that the problem of stably cloning long poly(C) tracts of EMC virus can be circumvented by the use of a shortened, synthetic, poly(dC-dG) oligonucleotide cartridge, and (ii) that a single point mutation in the puff region of the capsid protein 1AB leads to change in its electrophoretic mobility and to a change in the plaque size of recombinant virus.     

Molecular determinants of macrophage tropism and viral persistence: importance of single amino acid changes in the polymerase and glycoprotein of lymphocytic choriomeningitis virus.

This study documents that the immunosuppressive lymphocytic choriomeningitis virus (LCMV) variant, clone 13, shows a specific predilection for enhanced infection of macrophages both in vitro and in vivo and that single amino acid changes in the viral polymerase and glycoprotein are responsible for macrophage tropism. The growth difference seen between variant clone 13 and the parental Armstrong strain was specific for macrophages, since both clone 13 and Armstrong grew equally well in fibroblasts and neither isolate infected lymphocytes efficiently. Complete sequencing of the clone 13 genome, along with genetic analysis, showed that a single amino acid change in the polymerase (K-->Q at position 1079) was the major determinant of virus yield in macrophages. This was proven unequivocally by comparing the sequences of parental and reassortant viruses, which were identical at all loci except for the single mutation in the polymerase gene. This finding was further strengthened by showing that reversion at this site back to lysine (Q-->K) resulted in loss of macrophage tropism. In addition, an independently derived macrophage-tropic variant of LCMV, clone 28b, had a K-->N mutation at the same position. Thus, these results show that substitution of the positively charged amino acid K with a neutral amino acid (either Q or N) at residue 1079 of the polymerase resulted in enhanced viral replication in macrophages. In addition to the polymerase change, a mutation in the glycoprotein was also associated with macrophage tropism. This single amino acid change in the glycoprotein (F-->L at position 260) did not affect virus yield per macrophage but was critical in determining the number of macrophages infected. Our previous studies have shown that the same two mutations in the polymerase and glycoprotein are essential for establishing a chronic infection in adult mice. Since the same mutations confer macrophage tropism and ability to persist in vivo, these studies provide compelling evidence that infection of macrophages is a critical determinant of viral persistence and immune suppression.     

Intra-strain biological and epidemiological characterization of plum pox virus

Plum pox virus (PPV) is one of the most important plant viruses causing serious economic losses. Thus far, strain typing based on the definition of 10 monophyletic strains with partially differentiable biological properties has been the sole approach used for epidemiological characterization of PPV. However, elucidating the genetic determinants underlying intra-strain biological variation among populations or isolates remains a relevant but unexamined aspect of the epidemiology of the virus. In this study, based on complete nucleotide sequence information of 210 Japanese and 47 non-Japanese isolates of the PPV-Dideron (D) strain, we identified five positively selected sites in the PPV-D genome. Among them, molecular studies showed that amino acid substitutions at position 2,635 in viral replicase correlate with viral titre and competitiveness at the systemic level, suggesting that amino acid position 2,635 is involved in aphid transmission efficiency and symptom severity. Estimation of ancestral genome sequences indicated that substitutions at amino acid position 2,635 were reversible and peculiar to one of two genetically distinct PPV-D populations in Japan. The reversible amino acid evolution probably contributes to the dissemination of the virus population. This study provides the first genomic insight into the evolutionary epidemiology of PPV based on intra-strain biological variation ascribed to positive selection.     

A point mutation within the replicase gene differentially affects coronavirus genome versus minigenome replication

During the construction of the transmissible gastroenteritis virus (TGEV) full-length cDNA clone, a point mutation at position 637 that was present in the defective minigenome DI-C was maintained as a genetic marker. Sequence analysis of the recovered viruses showed a reversion at this position to the original virus sequence. The effect of point mutations at nucleotide 637 was analyzed by reverse genetics using a TGEV full-length cDNA clone and cDNAs from TGEV-derived minigenomes. The replacement of nucleotide 637 of TGEV genome by a T, as in the DI-C sequence, or an A severely affected virus recovery from the cDNA, yielding mutant viruses with low titers and small plaques compared to those of the wild type. In contrast, T or A at position 637 was required for minigenome rescue in trans by the helper virus. No relationship between these observations and RNA secondary-structure predictions was found, indicating that mutations at nucleotide 637 most likely had an effect at the protein level. Nucleotide 637 occupies the second codon position at amino acid 108 of the pp1a polyprotein. This position is predicted to map in the N-terminal polyprotein papain-like proteinase (PLP-1) cleavage site at the p9/p87 junction. Replacement of G-637 by A, which causes a drastic amino acid change (Gly to Asp) at position 108, affected PLP-1-mediated cleavage in vitro. A correlation was found between predicted cleaving and noncleaving mutations and efficient virus rescue from cDNA and minigenome amplification, respectively.     

A single amino acid mutation at position 170 of human parainfluenza virus type 1 fusion glycoprotein induces obvious syncytium formation and caspase-3-dependent cell death

An escape mutant of human parainfluenza virus type 1 (hPIV1), which was selected by serial passage in the presence of a sialidase inhibitor, 4-O-thiocarbamoylmethyl-2-deoxy-2,3-didehydro-N-acetylneur-aminic acid (TCM-Neu5Ac2en), exhibited remarkable syncytium formation and virus-induced cell death in LLC-MK2 cells but no difference in susceptibility for the sialidase inhibitor TCM-Neu5Ac2en from that of wild-type hPIV1 strain C35 (WT). The mutant virus also had higher replication and plaque formation abilities. The mutant virus acquired two amino acid mutations, Glu to Gly at position 170 and Ala to Glu 442 in fusion (F) glycoprotein, but no mutations in haemaggulutinin-neuraminidase (HN) glycoprotein. Using cells co-expressing F and HN genes with site-specific mutagenesis, we demonstrated that a point mutation of Glu to Gly at position 170, which was estimated to be located in hPIV1 F glycoprotein heptad repeat 1, was required for obvious syncytium formation and caspase-3-dependent cell death. In contrast, wild-type F glycoprotein induced no synctium formation or cell death. The findings suggest that a single amino acid mutation of hPIV1 F glycoprotein promotes syncytium formation that is followed by caspase-3-dependent cell death.     

Nuclear retention of M1 protein in a temperature-sensitive mutant of influenza (A/WSN/33) virus does not affect nuclear export of viral ribonucleoproteins.

We investigated the properties of ts51, an influenza virus (A/WSN/33) temperature-sensitive RNA segment 7 mutant. Nucleotide sequence analysis revealed that ts51 possesses a single nucleotide mutation, T-261----C, in RNA segment 7, resulting in a single amino acid change. Phenylalanine (position 79) in the wild-type M1 protein was substituted by serine in ts51. This mutation was phenotypically characterized by dramatic nuclear accumulation of the M1 protein and interfered with some steps at the late stage of virus replication, possibly affecting the assembly and/or budding of viral particles. However, although M1 protein was retained within the nucleus, export of the newly synthesized viral ribonucleoprotein containing the minus-strand RNA into the cytoplasm was essentially the same at both permissive and nonpermissive temperatures. The roles of M1 in the export of viral ribonucleoproteins from the nucleus into the cytoplasm and in the virus particle assembly process are discussed.     

新分离的副粘病毒Tianjin株的全基因组序列分析

副粘病毒Tianjin株是一株对普通棉耳狨猴具有高致病性,并可能与人类下呼吸道感染密切相关的毒株.为了明确其基因结构、变异特点及种系进化地位,采用RT PCR、测序和拼接,获得了副粘病毒Tianjin株全基因组序列,与GenBank登录的副粘病毒科7个属和尚未分类的28株病毒及7株仙台病毒代表株,进行同源性比较及系统进化分析.结果表明,副粘病Tianjin株属于副粘病毒科、副粘病毒亚科、呼吸道病毒属,与仙台病毒关系最近.基因组全长及组成规律与仙台病毒相似,只是L基因末尾A15240C变异而使L蛋白增加了一个谷氨酸残基.副粘病毒Tianjin株存在440个独特的核苷酸变异位点,导致110个氨基酸残基的改变,系统进化上构成独立的分支.副粘病毒Tianjin株在基因组序列、宿主亲嗜性和致病性等方面与已知仙台病毒存在较大的差异,可能代表仙台病毒的一个新基因型.     

Guanidine-selected mutants of poliovirus: mapping of point mutations to polypeptide 2C.

Sequence analysis of the genomic RNA of interstrain guanidine-resistant and antibody-resistant variant recombinants of poliovirus type 1 mapped the resistance of mutants capable of growth in 2.0 mM guanidine hydrochloride to a region located 3' of nucleotide 4444. This region of the viral genome specifies the nonstructural protein 2C. The sequence of genomic RNA encoding 2C from six independently isolated mutants resistant to 2.0 mM guanidine was determined. All six isolates contained a mutation in 2C at the same position in all cases, resulting in two types of amino acid changes. Dependent mutants were examined and found to contain two amino acid changes each within 2C. Mutants resistant to 0.53 mM guanidine were isolated and found to lack the mutations seen in variants resistant to 2.0 mM guanidine. A comparison of the amino acid sequences of the 2C proteins of poliovirus, foot-and-mouth disease virus, rhinovirus types 2 and 14, and encephalomyocarditis virus revealed a strong homology over regions totaling 115 residues. All of the mutations observed in guanidine-selected mutants were contained within this region. The amino acid region containing the mutations observed in poliovirus mutants resistant to 2.0 mM guanidine was compared with the homologous region in the other picornaviruses; a strong correlation was found between the amino acid present at this position and the sensitivity of the virus to 2.0 mM guanidine.     

Vaccine-related mumps infections in Thailand and the identification of a novel mutation in the mumps fusion protein

An outbreak of nine cases of mumps was reported from a total of 97 vaccinated nursing students at two medical colleges in Thailand in 2010, 16–26 days after administration of MMR vaccine containing the L-Zagreb mumps strain. Symptoms ranged in severity from fever and parotid swelling to orchitis. Clinical samples were obtained from seven patients and three were suitable for further study.Sequencing confirmed that the SH gene of the mumps virus in the unpassaged clinical specimens was identical to the L-Zagreb SH gene in the vaccine. Further analysis of the viral genome identified nucleotide position 5170 as a novel mutation which corresponds to an amino acid change in the fusion protein.This study provides another virologically confirmed example of mumps resulting from the L-Zagreb vaccine strain.     

Increased genetic and phenotypic stability of a promising live-attenuated respiratory syncytial virus vaccine candidate by reverse genetics

Human respiratory syncytial virus (RSV) is the most important viral cause of serious pediatric respiratory illness worldwide. Currently, the most promising live-attenuated vaccine candidate is a temperature-sensitive (ts) cDNA-derived virus named rA2cp248/404/1030ΔSH, in reference to its set of attenuating mutations. In a previous clinical study, more than one-third of postvaccination nasal wash isolates exhibited partial loss of the ts phenotype. Most of this instability appeared to be due to reversion at a missense point mutation called 1030. This 1030 mutation is a single-nucleotide tyrosine-to-asparagine substitution at position 1321 (Y1321N) of the polymerase L protein that contributes to the ts and attenuation phenotypes of the vaccine candidate. The goals of the present study were to identify a reversion-resistant codon at position 1321 conferring a comparable level of attenuation and to use this to develop a genetically stable version of the vaccine virus. We modified wild-type (wt) RSV to insert each of the 20 possible amino acids at position 1321; 19 viruses were recoverable. We also investigated small deletions at or near this position, but these viruses were not recoverable. Phenotypic analysis identified alternative attenuating amino acids for position 1321. Several of these amino acids were predicted, based on the genetic code, to be refractory to deattenuation. Classical genetics, using temperature stress tests in vitro combined with nucleotide sequencing, confirmed this stability but identified a second site with a compensatory mutation at position 1313. It was possible to stabilize the 1313 site as well, providing a stable 1030 mutation. Further stress tests identified additional incidental mutations, but these did not reverse the ts/attenuation phenotype. An improved version of the vaccine candidate virus was constructed and validated in vitro by temperature stress tests and in vivo by evaluation of attenuation in seronegative chimpanzees. In addition to developing an improved version of this promising live-attenuated RSV vaccine candidate, this study demonstrated the propensity of an RNA virus to escape from attenuation but also showed that, through systematic analysis, genetics can be used to cut off the routes of escape.     

Map locations of mouse hepatitis virus temperature-sensitive mutants: confirmation of variable rates of recombination.

Using standard genetic recombination techniques, studies in our laboratory suggest that recombination rates are very high and vary in different portions of the mouse hepatitis virus (MHV) genome. To determine the actual recombination frequencies in the MHV genome and localize the nucleotide boundaries of individual viral genes, we have sequenced temperature-sensitive and revertant viruses to identify the location of specific mutant alleles. Complementation group F RNA+ ts mutants (LA7, NC6, and NC16) each contained a unique mutation which was tightly linked to the ts phenotype and resulted in a conservative or nonconservative amino acid change in the MHV S glycoprotein gene. In agreement with previous recombination mapping studies, the mutation in LA7 and NC6 mapped within the S1 domain while NC16 mapped within the S2 domain. To determine the map coordinates of the MHV polymerase genes, several RNA- mutants and their revertants belonging to complementation groups C (NC3 and LA9) and E (LA18 and NC4) were also sequenced. Mutations were identified in each virus that were tightly linked to the ts phenotype and resulted in either a conservative or nonconservative amino acid change. The group C allele spanned the ORF 1a/ORF 1b junction, while the group E mutants mapped at the C terminus of ORF 1b about 20 to 22 kb from the 5' end of the genome. Mutation rates, calculated from the reversion frequencies of plaque-purified ts viruses requiring a single nucleotide alteration for reversion, approached 1.32 (+/- 0.89) x 10(-4) substitutions per nucleotide site per round of template copying. Detailed recombination mapping studies across known distances between these different ts alleles has confirmed that homologous recombination rates approached 25% and varied within different portions of the MHV genome.     

Alteration of encephalomyocarditis virus pathogenicity due to a mutation at position 100 of VP1

Encephalomyocarditis virus (EMCV) infection leads to many diseases including encephalitis, myocarditis and diabetes in its natural host, the mouse. In this study, we generated four cDNA clones with a point mutation at position 100 of VP1. The amino acids isoleucine, alanine, serine and proline were substituted with threonine in the four different clones of EMCV strain BJC3 by site-specific mutagenesis, and viable viruses were rescued. Although all mutants and wild-type viruses display different plaque morphologies, they replicate comparably in BHK-21 cells. The pathogenicity of the mutated viruses was systematically analyzed to investigate the importance of this amino acid in the viral pathogenicity and disease phenotype of EMCV infection in mice. The results showed that the isoleucine- (T1100I) and proline-mutated viruses (T1100P) exhibited a reduced mortality, lower cerebral virus loads and alleviated brain damage while the viruses with serine (T1100S) and alanine (T1100A) substitutions displayed similar properties as the wild-type virus. These findings indicate that the amino acid at position 100 of VP1 is important for EMCV in vivo infection, and its mutation alters the pathogenicity of viral infection in mice.     

Restriction of viral replication by mutation of the influenza virus matrix protein

The matrix protein (M1) of influenza virus plays an essential role in viral assembly and has a variety of functions, including association with influenza virus ribonucleoprotein (RNP). Our previous studies show that the association of M1 with viral RNA and nucleoprotein not only promotes formation of helical RNP but also is required for export of RNP from the nucleus during viral replication. The RNA-binding domains of M1 have been mapped to two independent regions: a zinc finger motif at amino acid positions 148 to 162 and a series of basic amino acids (RKLKR) at amino acid positions 101 to 105, which is also involved in RNP-binding activity. To further understand the role of the RNP-binding domain of M1 in viral assembly and replication, mutations in the coding sequences of RKLKR and the zinc finger motif of M1 were constructed using a PCR technique and introduced into wild-type influenza virus by reverse genetics. Altering the zinc finger motif of M1 only slightly affected viral growth. Substitution of Arg with Ser at position 101 or 105 of RKLKR did not have a major impact on nuclear export of RNP or viral replication. In contrast, deletion of RKLKR or substitution of Lys with Asn at position 102 or 104 of RKLKR resulted in a lethal mutation. These results indicate that the RKLKR domain of M1 protein plays an important role in viral replication.     

Suboptimal nucleotides in the infectious, pathogenic simian immunodeficiency virus clone SIVmac239

We analyzed virus sequences in two monkeys infected with SIVmac239 and two monkeys infected with SHIVnef that maintained high, persisting viral loads. Sequence changes were observed consistently at four loci in all four animals: a single nucleotide change in the Lys-tRNA primer binding site in the 5' long terminal repeat; two nucleotide changes that resulted in two amino acid changes in the pol gene product; and a single nucleotide change in the region of the simian immunodeficiency virus genome where the rev and env genes overlap, resulting in changes in the predicted amino acid sequences of both gene products. None of these mutations were seen in short-term cultures of CEMx174 cells infected with SIVmac239 or SHIVnef. At all four positions in all four animals, the new sequences represented consensus sequences for primate lentiviruses, whereas the inoculum sequences at these four loci have either never been or rarely been reported outside of SIVmac239. Thus, although cloned SIVmac239 is consistently pathogenic and consistently induces high viral load set points, it is clearly less than optimal at these four nucleotide positions.     

Suppression of a VP1 mutant of simian virus 40 by missense mutations in serine codons of the viral agnogene.

We isolated second-site revertants of a partially defective VP1 mutant of simian virus 40. The suppressing mutation in each of these pseudorevertants was mapped to the viral agnogene. Of six independently isolated pseudorevertants, all had a missense mutation in a serine codon, near the beginning of the agnogene, that would cause replacement of serine at position 7, 11, or 17 in the agnoprotein by a hydrophobic amino acid. Our results suggest that the agnoprotein interacts in a specific way with VP1 during the late stages of viral development.