Sequence-function analysis of the Sendai virus L protein domain VI

The large (about 2200 amino acids) L polymerase protein of nonsegmented negative-strand RNA viruses (order Mononegavirales) has six conserved sequence regions (“domains”) postulated to constitute the specific enzymatic activities involved in viral mRNA synthesis, 5′-end capping, cap methylation, 3′ polyadenylation, and genomic RNA replication. Previous studies with vesicular stomatitis virus identified amino acid residues within the L protein domain VI required for mRNA cap methylation. In our recent study we analyzed four amino acid residues within domain VI of the Sendai virus L protein and our data indicated that there could be differences in L protein sequence requirements for cap methylation in two different families of Mononegavirales — rhabdoviruses and paramyxoviruses. In this study, we conducted a more comprehensive mutational analysis by targeting the entire SeV L protein domain VI, creating twenty-four L mutants, and testing these mutations for their effects on viral mRNA synthesis, cap methylation, viral genome replication and virus growth kinetics. Our analysis identified several residues required for successful cap methylation and virus replication and clearly showed the importance of the K-D-K-E tetrad and glycine-rich motif in the SeV cap methylation. This study is the first extensive sequence analysis of the L protein domain VI in the family Paramyxoviridae, and it confirms structural and functional similarity of this domain across different families of the order Mononegavirales.     

Nucleotide sequence of the glycoprotein gene and intergenic region of the Lassa virus S genome RNA

Two overlapping cDNA clones corresponding to the 5' region of the Lassa virus S genome RNA were isolated and their nucleotide sequences determined. Similar to Pichinde and lymphocytic choriomeningitis viruses (LCMV), Lassa virus has an ambisense S RNA. The precursor to the viral glycoproteins (GPC) is encoded in viral RNA sequence originating at position 56 and terminating at position 1529 from the 5' terminus of the S RNA. A short, noncoding, intergenic region capable of forming a hairpin structure separates the termination codons of the nucleoprotein (N) and GPC genes. Hydropathic analysis of the GPC gene product of Lassa virus indicates the presence of hydrophobic domains near the amino and carboxy termini as previously noted in the corresponding proteins of Pichinde and LCM viruses. A comparison of the nucleotide sequences on the 3' termini of the viral and viral-complimentary S RNA species of Lassa, LCM, and Pichinde viruses reveals slight sequence differences that may possibly be involved in the regulation of RNA synthesis and gene expression.     

Nucleotide sequence of the S RNA of Lassa virus (Nigerian strain) and comparative analysis of arenavirus gene products

The nucleotide sequence of the small (S) genomic RNA of Lassa virus (strain GA391, of Nigerian origin) has been determined. The RNA has features which conform to those seen in most other arenavirus S RNAs which have been characterised, including conserved terminal sequences, an ambisense arrangement of the coding regions for the precursor glycoprotein (GPC) and nucleocapsid (N) proteins and an intergenic region capable of forming a base-paired "hairpin" structure. Comparison of the nucleotide sequence with that of the Josiah strain of Lassa virus (from Sierra Leone) reveals considerable nucleotide divergence in the third base of codons in the reading frames of all three proteins, although the resulting protein sequences are highly conserved, with 92, 94 and 91% identical residues for the mature glycoproteins G1 and G2 and the N protein, respectively. Sequence alignments of the available arenavirus structural proteins and dendrograms summarising the relationships between the viral proteins are presented.     

Two domains distantly related to protein-tyrosine kinases in the vesicular stomatitis virus polymerase

We have carried out an exhaustive search for amino acid sequence similarities between vesicular stomatitis virus (VSV) proteins and database entries. Unexpectedly, we found that the L polymerase protein contains two blocks of sequence (residues 725-1102 and 1291-1671) with distant but statistically significant similarity to the catalytic domain of tyrosine-specific protein kinases. The first kinase-like region is most similar to members of the Abl subfamily, Fes and Fps (26.6% and 27.3% identity, respectively), whereas the second region is closest to members of the platelet-derived growth factor receptor (PDGFR) subfamily, PDGFR and Kit (30.4% and 25.9% identity, respectively). Multiple alignment of the catalytic domain of these kinases to all three rhabdovirus L protein sequences available (VSV Indiana, VSV New Jersey, and rabies) revealed that the polymerases contain many but not all residues well conserved in the protein kinase family. Similarity was highest for VSV Indiana and lowest for rabies. We conclude that the kinase-like regions in the rhabdoviral L proteins are probably very distantly related to the protein kinase family. The similarities could either reflect contemporary protein kinase activity or represent some other function(s) associated with these large multifunctional polymerase proteins. Our findings also shed new light on questions of the origins and evolution of RNA viruses.     

Molecular characterization of a reassortant virus derived from Lassa and Mopeia viruses

In this article we describe two new complete genomic sequences of Old World Arenaviruses: the Mopeia (MOP) virus and the reassortant MOP/LAS virus, clone 29, or ML29. This reassortant has the large (L) RNA from MOP virus and the small (S) RNA from Lassa (LAS) virus, Josiah strain. Recent studies showed that the ML29 virus is not pathogenic for mice, guinea pigs, or macaques, can completely protect guinea pigs from Lassa virus, and elicit vigorous cell-mediated immunity in immunized monkeys (Lukashevich, I. S., Patterson, J., Carrion, R., Moshkoff, D., Ticer, A., Zapata, J., Brasky, K., Geiger, R., Hubbard, G. B., Bryant, J., and Salvato, M. S., J Virol 79, 13934–13942, 2005). This is a molecular characterization of a reassortant virus, which has been put forward as a live attenuated vaccine candidate against Lassa Fever. Sequence analysis of this reassortant virus revealed 5 non-conservative amino acid substitutions that distinguished it from the parental LAS and MOP viruses. Three substitutions were found outside the conserved RNA-dependent RNA polymerase (RdRp) motifs. A fourth substitution was located between the glycoprotein (GPC)-cleavage site and the putative fusion peptide of GP2. The nucleocapsid protein (NP) contained a fifth substitution in the carboxyl-terminal region of the protein. Two mutations were found within each non-coding terminus of the L segment and one mutation was located in the 3′ non-coding region of the S segment of the MOP/LAS virus. ML29 mutations in its genomic termini may have implications for the genetic stability and replication efficiency of ML29 reassortant. The nucleotide sequence data for the of the S and L RNAs of the ML29 and Mopeia virus strains reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession numbers: NC_006572-75.     

汉坦病毒A9株全长L片段cDNA克隆和核苷酸序列测定

目的克隆我国分离的汉坦病毒A9株L片段全长cDNA,并测定其核苷酸序列.方法用逆转录-聚合酶链反应(RT-PCR)技术分段扩增汉坦病毒A9株全部L片段,用T-A克隆方法进行PCR产物克隆,测定PCR产物的核苷酸序列.通过亚克隆将分段的L片段连接成全长cDNA克隆.结果A9株的基因组L片段长度为6533个核苷酸,腺嘌呤核苷酸和尿嘧啶核苷酸丰富(%A+U=62.47).包含有一个单一的开放读码框架(ORF),编码一个标准的质量为2.46×105的蛋白,含有2151个氨基酸.A9株与76-118、C1-1和C1-2株的同源性最高,达到83.8%.与TULA病毒的关系较远,其核酸序列的同源性为65.8%.将推导的A9株编码的氨基酸序列与其他21种负链RNA病毒的依赖RNA的RNA聚合酶的氨基酸序列以及汉坦病毒几个代表株的L片段氨基酸序列进行比较,显示A9编码的RNA聚合酶也有6个比较保守的区域以及几个极端保守的氨基酸残基.结论汉坦病毒A9株L片段具有和其他汉坦病毒RNA聚合酶相似的核苷酸一级结构,通过对推导的氨基酸分析,该片段具有一些在RNA病毒聚合酶中都存在的保守区域.     

Sequence analysis of the S RNA of the African Arenavirus Mopeia: An unusual secondary structure feature in the intergenic region

Mopeia virus is an apparently nonpathogenic African arenavirus which can protect animals from subsequent challenge by the closely related Lassa virus. As a step toward understanding these differences in pathogenicity and the means by which Mopeia virus infection can protect against subsequent Lassa virus infection, cDNA clones corresponding to 3419 nucleotides of Mopeia virus S RNA were isolated and sequenced. Two open reading frames, encoding the glycoprotein precursor (GPC) and nucleocapsid (N) proteins, were located in the ambisense arrangement characteristic of the arenaviruses. Comparison of the amino acid sequences of the translation products with those of two Lassa virus strains showed considerable conservation, with 74 and 80% identity for the two glycoproteins G1 and G2, and 74% identity for the N protein. The putative dibasic site of GPC cleavage (R-R) was conserved, as were the potential N-linked glycosylation sites. A striking difference between Mopeia virus and Lassa virus was identified in the noncoding intergenic region. Instead of the single hairpin structure formed by base-pairing of complementary sequences which is usually found, the Mopeia virus S RNA has the potential to form two hairpins. These hairpins were similar in sequence and may have been formed in a duplication event during RNA replication. The possible contribution of this secondary structure feature to differences in pathogenicity between Mopeia and Lassa viruses is discussed.     

Identification of aromatic amino acid residues in conserved region VI of the large polymerase of vesicular stomatitis virus is essential for both guanine-N-7 and ribose 2'-O methyltransferases

Non-segmented negative-sense RNA viruses possess a unique mechanism for mRNA cap methylation. For vesicular stomatitis virus, conserved region VI in the large (L) polymerase protein catalyzes both guanine-N-7 (G-N-7) and ribose 2'-O (2'-O) methyltransferases, and the two methylases share a binding site for the methyl donor S-adenosyl-l-methionine. Unlike conventional mRNA cap methylation, the 2'-O methylation of VSV precedes subsequent G-N-7 methylation. In this study, we found that individual alanine substitutions in two conserved aromatic residues (Y1650 and F1691) in region VI of L protein abolished both G-N-7 and 2'-O methylation. However, replacement of one aromatic residue with another aromatic residue did not significantly affect the methyltransferase activities. Our studies provide genetic and biochemical evidence that conserved aromatic residues in region VI of L protein essential for both G-N-7 and 2'-O methylations. In combination with the structural prediction, our results suggest that these aromatic residues may participate in RNA recognition.     

Two N-terminal regions of the Sendai virus L RNA polymerase protein participate in oligomerization

The RNA dependent RNA polymerase of Sendai virus consists of a complex of the large (L) and phosphoprotein (P) subunits where L is thought to be responsible for all the catalytic activities necessary for viral RNA synthesis. We previously showed that the L protein forms an oligomer [Smallwood, S., Cevik, B., Moyer, S.A., 2002. Intragenic complementation and oligomerization of the L subunit of the Sendai virus RNA polymerase. Virology 304, 235-245] and mapped the L oligomerization domain between amino acids 1 and 174 of the protein [Cevik, B., Smallwood, S., Moyer, S.A., 2003. The oligomerization domain resides at the very N-terminus of the Sendai virus L RNA polymerase protein. Virology 313, 525-536]. An internal deletion encompassing amino acids 20 to 178 of the L protein lost polymerase activity but still formed an L-L oligomer. The first 25 amino acids of paramyxovirus L proteins are highly conserved and site-directed mutagenesis within this region eliminated the biological activity of the L protein but did not have any effect on P-L or L-L interactions. Moreover deletion of amino acids 2-18 in L abolished biological activity, but again the L-L binding was normal demonstrating that the oligomerization domain of L protein resides in two N-terminal regions of the protein. Therefore, sequences between both aa 2-19 and aa 20-178 can independently mediate Sendai L oligomerization, however, both are required for the activity of the protein.     

RNA polymerase (L) gene and genome terminal sequences of ephemeroviruses bovine ephemeral fever virus and Adelaide River virus indicate a close relationship to vesiculoviruses

The sequence of the RNA genome of bovine ephemeral fever virus (BEFV) was determined from the start of the L (polymerase) gene to the end of the untranslated 5′ trailer sequence, completing the sequence of the 14 900 nucleotide (nt) genome. The 6470 nt L gene encodes a single long ORF of 2144 amino acids with a deduced molecular weight of 249 766 Da. The 70 nt BEFV 5′ trailer region displays partial terminal complementarity with the 3′ leader sequence and contains a 26 nt direct repeat of the U-rich domain of the 3′ leader region. The 47 nt 5′ trailer region of Adelaide River virus (ARV) displays terminal sequence similarity to the BEFV trailer and partial terminal complementarity with the ARV 3′ leader sequence, but does not contain the direct repeat sequence. The BEFV L protein contains all characteristic sequence motifs of amino acid blocks I–VI, conserved among RNA polymerase proteins of single-stranded (−) RNA viruses, separated by regions of lower homology. Phylogenetic analysis using the complete BEFV L protein sequence indicated a closer relationship to vesicular stomatitis virus than to rabies virus. Sequence comparison of two conserved central domains encompassing blocks II and III and block VI of the BEFV and ARV L proteins indicated they are closely related. An extended phylogenetic analysis using the block III sequence, confirmed the relationship of these ephemeroviruses to vesiculo- and lyssaviruses and to other single-stranded (−) RNA viruses.     

Complete nucleotide sequence of the Japanese encephalitis virus genome RNA

The complete nucleotide sequence of the Japanese encephalitis virus (JEV) genome RNA was determined. The JEV genome contains 10,976 nucleotides and encodes a single long open reading frame (ORF) of 10,296 nucleotides corresponding to 3432 amino acid residues. This long polypeptide is thought to be cleaved into three structural proteins and several nonstructural proteins of the virus. The genetic location of the three structural proteins was determined by comparing the deduced amino acid sequence from the nucleotide sequence with the N-terminal amino acid sequences that were determined from the three purified structural proteins. The C-terminal region of the ORF may encode a RNA-dependent RNA polymerase which has significant sequence homology with those of other RNA viruses.     

Two regions of the P protein are required to be active with the L protein for human parainfluenza virus type 1 RNA polymerase activity

The paramyxovirus P protein is an essential component of the viral RNA polymerase composed of P and L proteins. In this study, we characterized the physical and functional interactions between P and L proteins using human parainfluenza virus type 1 (hPIV1) and its counterpart Sendai virus (SV). The hPIV1 P and SV L proteins or the SV P and hPIV1 L proteins formed complexes detected by anti-P antibodies. Functional analysis using the minigenome SV RNA containing CAT gene indicated that the hPIV1 P--SV L complex, but not the SV P--hPIV1 L complex, was biologically active. Mutant SV P or hPIV1 P cDNAs, which do not express C proteins, showed the same phenotype with wild-type P cDNAs, indicating that C proteins are not responsible for the dysfunction of SV P--hPIV1 L polymerase complex. Using the chimeric hPIV1/SV P cDNAs, we identified two regions (residues 387--423 and 511--568) on P protein, which are required for the functional interaction with hPIV1 L. These regions overlap with a previously identified domain for oligomer formation and binding to nucleocapsids. Our results indicate that in addition to a P--L binding domain, hPIV1 L requires a specific region on P protein to be biologically functional as a polymerase.     

Generation of reassortants between African arenaviruses.

Lassa (LAS) and Mopeia (MOP) viruses are African arenaviruses which are carried by wild rodents and occasionally transferred to humans. In humans and nonhuman primates, Lassa causes mortality in 60% of untreated cases, whereas Mopeia does not cause mortality and has been known to protect monkeys from lethal challenge with Lassa. These two African arenaviruses also differ in their lethality for suckling outbred mice and in their plaque sizes under agar overlay. MOP virus induces small plaques and lethal infection after intracerebral (ic) inoculation. In contrast, LAS inoculation does not kill mice and the virus induces large plaques. After coinfection of Vero cells with LAS and MOP viruses some phenotypic reassortants which produced small plaques and were not lethal for outbred mice were isolated and plaque-purified. Dot-blot hybridization using LAS and MOP cDNA probes specific for L and S RNA segments revealed a genotype consisting of the L RNA of MOP and the S RNA of LAS (MOP/LAS reassortant). Adoptive transfer experiments demonstrated an ability of immune splenocytes from CBA mice intraperitoneally infected with the MOP/LAS reassortants to protect recipient mice against lethal disease after ic inoculation with LAS virus.     

Characterization of the Lassa virus matrix protein Z: electron microscopic study of virus-like particles and interaction with the nucleoprotein (NP)

Lassa virus is the causative agent of a hemorrhagic fever endemic in west Africa. The RNA genome of Lassa virus encodes the glycoprotein precursor GP-C, a nucleoprotein (NP), the viral polymerase L and a small protein Z (11 kDa). Here, we analyze the role of Z protein for virus maturation. We have recently shown that expression of Z protein in the absence of other viral proteins is sufficient for the release of enveloped Z-containing particles. In this study, we examined particles secreted into the supernatant of a stably Z protein-expressing CHO cell line by electron microscopy. The observed Z-induced virus-like particles did not significantly differ in their morphology and size from Lassa virus particles. Mutation of two proline-rich domains within Z which are known to drastically reduce the release of virus-like particles, had no effect on the cellular localization of the protein nor on its membrane-association. Furthermore, we present evidence that Z interacts with the NP. We assume that Z recruits NP to cellular membranes where virus assembly takes place. We conclude from our data that Lassa virus Z protein plays an essential role in Lassa virus maturation.