Biological transmission of vesicular stomatitis virus (New Jersey) by Simulium vittatum (Diptera: Simuliidae).

Simulium vittatum females were shown to be competent vectors for the New Jersey serotype (VSNJ) of vesicular stomatitis virus (Camp Verde strain). Seventy percent of females infected intrathoracically transmitted infectious virions in their saliva after a 10-d incubation period. When infected with virus per os, 63% of the flies tested were positive at day 10, and 45% of flies infected in this manner also secreted virus in their saliva by day 9 or 10 after infection. When ingested by S. vittatum females, VSNJ virus readily replicated and increased from a mean baseline titer of 1.2 x 10(4) pfu per fly to 3 x 10(4) pfu per fly on day 10. An eclipse phase was demonstrated between approximately 18 and 48 h postinfection. This experimental evidence supports the hypothesis that black flies play a major role in the epizootic transmission of VSNJ. This is also the first confirmed example of biological transmission of an arbovirus by a member of the Simuliidae.     

Bite transmission of vesicular stomatitis virus (New Jersey serotype) to laboratory mice by Simulium vittatum (Diptera: Simuliidae).

Laboratory-reared female black flies (Simulium vittatum Zetterstedt) were infected experimentally with a 1997 vesicular stomatitis virus New Jersey serotype isolate and allowed to feed on susceptible laboratory mice. All mice exposed to black fly bite seroconverted by day 21 after infection, an indication of virus transmission. In addition, viral RNA was detected in the spleen of several mice. These findings are consistent with the hypothesis that black flies are involved in VSV-NJ transmission during epizootics in the western USA and represent the 1st confirmed example of biological transmission of an arbovirus by a member of the Simuliidae using an animal model.     

Simulium vittatum (Diptera: Simuliidae) and Lutzomyia longipalpis (Diptera: Psychodidae) salivary gland hyaluronidase activity

Hyaluronidase activity in the salivary gland homogenates of Simulium vittatum (Zetterstedt) is described, and its optimal pH determined. Salivary activity was reduced significantly after a blood meal, indicating that it was secreted after blood feeding. Phlebotomus papatasi (Scopoli) also exhibited salivary hyaluronidase activity. These results indicate that hematophagous pool-feeding insects may secrete this enzyme to help the spread of salivary antihemostatic agents in the vicinity of the feeding lesion, and perhaps to increase the size of the feeding lesion itself. Additionally, this enzyme may affect local host immune reactions and promote arboviral transmission.     

Chromosomal localization of two antihemostatic salivary factors in Simulium vittatum (Diptera: Simuliidae)

The chromosomal locations of two genes encoding the salivary protein products Simulidin (SVAT) and Simulium vittatum erythyma protein (SVEP) were identified using high-resolution cytogenetic mapping. Chromosomal subsection levels were determined from larval and adult salivary gland polytene chromosomes and adult Malphigian tubule chromosomes. Syntenic relationships occurred for both loci from a wild population of Simulium vittatum IIIL-1 collected in central Alabama and the colonized IS-7 S. vittatum sibling. cSVAT mapped to the short arm of chromosomes III, IIIS-72a4.5 and cSVEP mapped to the long arm of chromosome III, IIIL-96b1. cSVAT sits proximal to a common IIIS-2 paracentric inversion, which occurs predominately as the standard sequence in the IIIL-1 sibling and as the inverted sequence in the IS-7 sibling. cSVEP sits close to the differentiated X chromosomes in the IIIL-1 sibling.     

Transmission of vesicular stomatitis New Jersey virus to cattle by the biting midge Culicoides sonorensis (Diptera: Ceratopogonidae)

Laboratory-reared Culicoides sonorensis Wirth & Jones were infected with vesicular stomatitis virus serotype New Jersey (family Rhabdoviridae, genus Vesiculovirus, VSNJV) through intrathoracic inoculation. After 10-d incubation at 25 degrees C, these insects were allowed to blood feed on four steers. Two other steers were exposed to VSNJV through intralingual inoculation with 10(8) tissue culture infective dose50 VSNJV. All six steers became seropositive for VSNJV. The results demonstrate the ability of C. sonorensis to transmit VSNJV to livestock. Only the animals intralingually inoculated with VSNJV showed clinical signs in the form of vesicles at the site of inoculation. Uninfected C. sonorensis allowed to feed on the exposed animals did not become infected with VSNJV. Animals infected by C. sonorensis showed a slower antibody response compared with intralingually inoculated animals. This is probably because of different amounts of virus received via insect transmission and syringe inoculation. A significant difference was found in the serum acute-phase protein alpha-1-acid glycoprotein in animals that received VSNJV through C. sonorensis transmission. These animals had previously been exposed to insect attack in the field compared with intralingually inoculated animals and C. sonorensis-infected animals that had been protected from insect attack. The failure to observe clinical signs of vesicular stomatitis through transmission of VSNJV by C. sonorensis may explain widespread subclinical infections during vesicular stomatitis epidemics.     

RNA synthesis by temperature-sensitive mutants of vesicular stomatitis virus, New Jersey serotype.

We report the results of studies using temperature-sensitive mutants of Rous sarcoma virus (ts RSV) to study the alterations in surface proteins occurring on transformation. A large external transformation-sensitive (LETS) protein is detected by lactoperoxidase-catalyzed iodination on normal chicken embryo fibroblasts (CEF) but is reduced on RSV-transformed cells. The LETS protein is temperature sensitive in ts RSV-infected CEF and the kinetics of the alterations occurring on shifts between permissive and restrictive temperature are reported. During reversion to normality on shift-up, the LETS protein appears at the surface quite rapidly and in parallel with the morphological changes, although the change is less rapid than that in glucose transport. On transformation during shift-down, the disappearance of the LETS protein lags behind the morphological change. Cycloheximide does not inhibit reappearance of iodinatable LETS protein on shift-up, suggesting that the LETS protein is synthesized in transformed cells, although it is not present at the surface. Hypotheses to explain the absence of the LETS protein at the surface are discussed and evidence is presented for an increased rate of turnover after transformation.     

Infection of guinea pigs with vesicular stomatitis New Jersey virus Transmitted by Culicoides sonorensis (Diptera: Ceratopogonidae)

Intrathoracically inoculated Culicoides sonorensis Wirth & Jones were capable of transmitting vesicular stomatitis New Jersey virus (family Rhabdoviridae, genus Vesiculovirus, VSNJV) during blood feeding on the abdomen of six guinea pigs. None of the guinea pigs infected in this manner developed clinical signs of vesicular stomatitis despite seroconversion for VSNJV. Guinea pigs infected by intradermal inoculations of VSNJV in the abdomen also failed to develop clinical signs of vesicular stomatitis. Three guinea pigs given intradermal inoculations of VSNJV in the foot pad developed lesions typical of vesicular stomatitis. Transmission by the bite of C. sonorensis may have facilitated guinea pig infection with VSNJV because a single infected C. sonorensis caused seroconversion and all guinea pigs infected by insect bite seroconverted compared with 50% of the guinea pigs infected by intradermal inoculation with a higher titer VSNJV inoculum. The role of C. sonorensis in the transmission of VSNJV is discussed.     

Complete nucleotide sequence of the matrix protein mRNA of vesicular stomatitis virus (New Jersey serotype)

The complete nucleotide sequence of the mRNA of the matrix (M) protein of vesicular stomatitis virus [New Jersey serotype, VSV(NJ)] was derived from a cDNA clone and mRNA. The mRNA is 758 nucleotides long (excluding polyadenylic acid) and encodes a protein of 229 amino acids. The predicted amino acid sequence was compared with that of the corresponding protein of Indiana serotype [VSV(IND)] and a fish rhabdovirus, spring viremia of carp virus (SVCV). An amino acid identity of 62% was found between the M proteins of VSV(NJ) and VSV(IND) while only 24% was present between VSV(NJ) and SVCV. A highly basic NH2-terminal domain followed by a proline-proline-X-tyrosine sequence was present in all the three M polypeptides. Except for the L gene sequence, the complete nucleotide sequence of the four genes of VSV(NJ) are now known. The comparison of the amino acid sequences between the Indiana and New Jersey serotypes demonstrates a high degree of homology between these genes except for the phosphoprotein gene, NS.     

Functional analysis of hypomethylation variants of the New Jersey serotype of vesicular stomatitis virus

The ts mutant F1 of vesicular stomatitis virus, New Jersey serotype, directs the synthesis of undermethylated 5'-terminal cap structures in vitro. In order to determine the relationship between the ts and hypomethylation phenotypes, a spontaneous revertant rev(ts)F1 of the ts phenotype was analyzed. The revertant retained the hypomethylation phenotype. The four cap structures (GpppA, 7mGpppA, GpppAm, and 7mGpppAm) synthesized in mutant and revertant-directed reactions in the presence of low as well as high concentrations of AdoMet were resolved by HPLC. Quantitation of the data and analysis of cap substrate to product ratios revealed that despite apparent similarities between the two hypomethylation phenotypes, the functional lesions in F1 and rev(ts)F1 were different. F1 displayed an AdoMet concentration-dependent alteration in the GpppA----GpppAm reaction and an AdoMet concentration-independent alteration in the GpppA----7mGpppA reaction. In contrast, rev(ts)F1 displayed AdoMet concentration-dependent alterations in the reactions GpppA----7mGpppA and GpppAm----7mGpppAm.     

Glycoprotein evolution of vesicular stomatitis virus New Jersey

A T1 ribonuclease fingerprinting study of a large number of virus isolates had previously demonstrated that considerable genetic variability existed among natural isolates of the vesicular stomatitis virus (VSV) New Jersey (NJ) serotype [S.T. Nichol (1988) J. Virol. 62, 572-579]. Based on these results, 34 virus isolates were chosen as representing the extent of genetic diversity within the VSV NJ serotype. We report the entire glycoprotein (G) gene nucleotide sequence and the deduced amino acid sequence for each of these viruses. Up to 19.8% G gene sequence differences could be seen among NJ serotype isolates. Analysis of the distribution of nucleotide substitutions relative to nucleotide codon position revealed that third position changes were distributed randomly throughout the gene. Third base changes constituted 84% of the observed nucleotide substitutions and affected 89% of the third base positions located in the G gene. Only three short oligonucleotide stretches of complete sequence conservation were observed. The remaining nucleotide changes located in the first and second positions were not distributed randomly, indicating that most of the amino acids coded by the G gene cannot be altered without reducing the fitness of the VSV NJ serotype viruses. Despite these constraints, up to 8.5% amino acid differences were observed between virus isolates. These differences were located throughout the G protein including regions adjacent to defined major antibody neutralization epitopes. Apparent clusters of amino acid substitutions were present in the hydrophobic signal sequence, transmembrane domain, and within the cytoplasmic domain of the G protein. A maximum parsimony analysis of the G gene nucleotide sequences allowed construction of a phylogram indicating the evolutionary relationship of these viruses. The VSV NJ serotype appears to contain at least three distinct lineages or subtypes. All recent virus isolates from the United States and Mexico are within subtype I and appear to have evolved from an ancestor more closely related to the Hazelhurst historic strain than other older strains. The implications of these findings for the evolution, epizootiology, and classification of these viruses are discussed.     

Point mutations in glycoprotein gene of vesicular stomatitis virus (New Jersey serotype) selected by resistance to neutralization by epitope-specific monoclonal antibodies

Antigenic variants of the New Jersey serotype of vesicular stomatitis virus (VSV-NJ) were isolated and cloned by selecting virus plaques resistant to neutralization by high-titered monoclonal antibodies (MAbs) directed to glycoprotein (G) epitopes V, VI, VII, or VIII. The G proteins of each neutralization-resistant virus variant also exhibited markedly reduced antigenic reactivity with each corresponding epitope-specific MAb as determined by enzyme-linked immuno-absorbent assay and by Western blot analysis. Loss of antigenic reactivity of certain mutant G proteins to a MAb other than the one used to select the mutant virus suggested close antigenic proximity, particularly for epitopes VI and VII. The virion RNAs coding for the entire G gene of the wild-type virus and 10 MAb-induced mutants were sequenced by primer DNA extension using the dideoxy method. Each mutant G gene exhibited only a single nucleotide change, leading in each case to a single amino acid substitution, as follows: Glu210----Lys for all three mutants selected by MAb14 (epitope VII); Pro268----Thr for one mutant selected by MAb12 (epitope VI); Ser277----Lys for all three mutants selected by MAb15 (epitope VIII); and Glu364----Lys for all three mutants selected by MAb11 (epitope V). These neutralizing MAb-selected mutations are clustered in the middle third of the 517-amino acid VSV-NJ G protein, presumably resulting in conformational changes that alter recognition of one or more antigenic determinants by a specific monoclonal antibody.     

Monoclonal antibodies to the glycoprotein of vesicular stomatitis virus (New Jersey serotype): a method for preliminary mapping of epitopes

Of the nine antigenic determinants on the glycoprotein (G) of the New Jersey serotype of vesicular stomatitis virus (VSV) identified by competitive binding of 25 monoclonal antibodies (MAbs), those relegated to epitopes I, II, III, and IV exhibited no significant ability to neutralize virus infectivity but some nonneutralizing MAbs cross-reacted by ELISA with the G protein of VSV-Indiana. High-titered neutralization of homotypic virus was exhibited by epitope V, VI, and VII MAbs but quite variable neutralizing activity was found among MAbs of epitope "family" VIII and particularly the heterogeneous epitope "family" IX. Peptide mapping of the epitopes was not feasible because most MAbs would not bind by Western blotting to G protein under standard conditions of proteolysis or disulfide bond reduction. Therefore, a technique was devised for roughly locating epitopes by protease footprinting of G protein partially protected by individual MAbs complexed with staphylococcal protein A-Sepharose beads. Under these conditions, MAbs to all nine epitopes protected a similar 12-kDa fragment of the G protein from proteolysis by Staphylococcus aureus V8 protease. N-Terminal amino acid sequencing mapped two of these 12-kDa peptide footprints to a position on the G protein extending from amino acid 219 to about 100 amino acids downstream. Although MAbs to only one epitope bound to the 12-kDa fragment by Western blotting, these data suggest, but do not prove, that all nine epitopes of the undenatured VSV-New Jersey G protein are clustered at the middle 20% of a highly structured protein. This method may help to identify the general regions for epitopes on complex proteins of as yet unknown three-dimensional structure.     

中国黑龙江省蚋属一新种(双翅目:蚋科)

本文记述黑龙江省饶河县五林洞蚋属Simulium 蚋亚属Simulium一新种,以虞以新教授的姓氏命名为虞氏蚋S.(Simulium)yui sp.nov.该蚋与S.(S.)hirtipannus Puri,1932,S.(S.)jacuticum Rubtsov,1940,S.(S.)decimatum Dorogostaisky,Rubtsov and Vlasenko,1935和S.(S.)cholodkovskii Rubtsov,1940 相似,但是,本新种蛹的呼吸丝10条,与6条呼吸丝的前两种蚋不同.该新种的生殖叉突为倒Y形,后两种蚋的生殖叉突两臂弯曲,基半部上抬,后半部斜前伸,不呈倒Y形,肛上板的形状和蛹呼吸丝的排列均有明显差异.模式标本保存于军事医学科学院微生物流行病研究所医学昆虫标本馆.     

Titers of vesicular stomatitis virus, New Jersey serotype, in naturally infected male and female Lutzomyia shannoni (Diptera: Psychodidae) in Georgia.

Seven isolates of the New Jersey serotype of vesicular stomatitis (VSNJ) virus were obtained from pooled specimens of phlebotomine sand flies, Lutzomyia shannoni Dyar, collected on Ossabaw Island, Chatham County, Ga., in 1989 and 1990. Three isolates, including two from males, were obtained from light-trapped sand flies in 1989. Four isolates were obtained from pools of sand flies collected from hollow trees in 1990. Three of the latter pools contained from 4.0 to 4.7 log10 of plaque-forming units of virus per ml, suggesting that the positive flies in these pools had supported VSNJ virus replication. One of these high-titered isolates was obtained from a pool of male sand flies. These data provide further support for the hypotheses that L. shannoni is a biological vector of VSNJ virus at this enzootic focus and that transovarial transmission of the virus occurs in nature.     

窄手蚋的重新描述（双翅目：蚋科）

窄手蚋 （Simulium （Simulium） omorii）是Takahasi（1942）发表的新种,当时放在短蚋属（Omiadag）,该蚋标本是采自我国黑龙江省.Takahasi 仅描述了两性成虫和蛹,缺幼虫,况前者也不甚详细 1983年,虞以新和安继尧在我国黑龙江省饶河县珍宝岛地区,采到窄手蚋的两性成虫、幼虫和蛹,描述于后供同道者参考.窄手蚋与Rubzov（1956）描述的S. （S.） tenuimanus Enderlein, 1920很近似,不同的是：1. 足色：雌虫,窄手蚋前、中足股节黑色,后足股节基段1/5棕黄色.tenuimanus蚋,前、中、后足股节巧克力棕黑色,仅基部有点黄色.雄虫,窄手蚋后足转节、股节基端部、胫节基端部和中足基节1/2棕黄色,而tenuimanus 除前足基节和后足胫节基部褐色外,余部黑色.2. 窄手蚋中骨圆形或弹头形,前端圆形,后端凹入呈八字形 tenuimanu 中骨箭形,末端尖.标本保存于军事医学科学院医学昆虫标本馆.     

Complete nucleotide sequence of the mRNA coding for the N protein of vesicular stomatitis virus (New Jersey serotype)

The nucleotide sequence of the mRNA encoding the nucleocapsid protein of the New Jersey serotype (Ogden strain) of vesicular stomatitis virus (VSV) was determined from two overlapping cDNA clones spanning almost entirely the coding region of the mRNA. The 5'-terminal noncoding sequence present in the mRNA but not in the cDNA clones was determined from a primer extended to the 5' terminus of the mRNA. The mRNA is 1329 nucleotides long (excluding polyadenylic acid) and encodes a protein of 422 amino acids. The nucleotide sequence was compared with the previously determined nucleotide sequence of the nucleocapsid protein of the Indiana serotype. An overall identity of 67.7% was found between the two serotypes. The only place where insertions and/or deletions have occurred during the evolution of the two viral genes from their presumed common ancestor is in the untranslated region. The nonidentical nucleotides are distributed throughout the length of the mRNA although not in an entirely random manner. The predicted amino acid sequence demonstrates that both proteins are initiated from the initiator codon located at the same distance from the 5' end (nucleotides 14 to 16) and contain the same number of amino acids. An overall identity of more than 80% of the amino acid sequence was observed between the two proteins when conservative replacements of amino acids were considered.