Mutational analysis of the capsid protein of Leishmania RNA virus LRV1-4.

The virion of Leishmania RNA virus is predicted to be composed of a 742-amino-acid major capsid protein and a small percentage of capsid-polymerase fusion molecules. Recently, the capsid protein alone was expressed and shown to spontaneously assemble into viruslike particles. Since the major structural protein of the virion shell self-assembles into viruslike particles when expressed in the baculovirus expression system, assembly of the virion can be studied by mutational analysis and expression of a single open reading frame. In this study, several deletions and one addition of the capsid protein of Leishmania RNA virus LRV1-4 were generated. These mutants show different degrees of assembly. Assembly domains are being identified such that the capsid protein may be used as a macromolecular packaging and delivery system for Leishmania species.     

Suppression of Leishmania RNA virus replication by capsid protein overexpression.

Some strains of the protozoan parasite genus Leishmania are persistently infected with single-segmented double-stranded RNA viruses, which are termed LRV. The function of these cytoplasmic viruses is unknown. In order to address the question of whether LRV affects the parasite's phenotype, pairs of isogenic LRV(+)-LRV- lines are required. Since the persistent nature of these viruses precludes de novo infection of virus-negative strains, LRV(+)-LRV- strains were transformed with a Leishmania expression vector expressing the LRV capsid protein with the aim of determining if LRV- promastigotes support capsid assembly and if LRV replication is affected by excess capsid protein. I found that in LRV- promastigotes, capsid protein was capable of self-assembly into virus-like capsids and that capsid overexpression in a naturally infected LRV+ line resulted in a progressive reduction in LRV copy number. Clonal lines derived from an LRV+ capsid overexpressor had no detectable levels of LRV. These results demonstrate that LRV replication can be inhibited and that a significant reduction of viral copy number has no effect on the parasite's viability in liquid medium.     

Intracellular Localization of LRV1 in Infected Leishmania Cells and Epitope Conservation of the Coat Protein

ABSTRACT. Polyclonal antibodies were raised against a recombinant fragment of the coat protein of LRV1-1 to determine the epitope conservation of the coat protein among LRV1 isolates, and the intracellular localization of LRV1 particles in promastigote cells of Leishmania braziliensis . Western blot analysis showed that specific epitopes of the coat protein are highly conserved among isolates from different geographic areas. Using indirect immunofluorescence assays LRV1 viral particles were observed as fluorescent granules, limited to the cytoplasm and with no apparent association to the host organelles or the cell membrane, characteristic of a persistent, non-infectious virus.     

LRV1 viral particles in Leishmania guyanensis contain double-stranded or single-stranded RNA.

The 32-nm-diameter spherical viral particles found in the cytoplasm of Leishmania guyanensis CUMC1-1A sediment at 130S and have a buoyant density of approximately 1.4 g/ml in cesium chloride gradients. These particles contain a 5.3-kb double-stranded RNA, while single-stranded RNA that corresponds to the viral positive strand is associated with less-dense particles. These results suggest a conservative and sequential mode of LRV1 viral RNA replication that is exemplified by the ScV L-A virus of yeast.     

The 3' end of Norwalk virus mRNA contains determinants that regulate the expression and stability of the viral capsid protein VP1: a novel function for the VP2 protein

Norwalk virus (NV) is the prototype strain of a group of noncultivable human caliciviruses responsible for epidemic outbreaks of acute gastroenteritis. The capsid protein VP1 is synthesized from a subgenomic RNA that contains two open reading frames (ORFs), ORF2 and ORF3, and the 3' untranslated region (UTR). ORF2 and ORF3 code for the capsid protein (VP1) and a small structural basic protein (VP2), respectively. We discovered that the yields of virus-like particles (VLPs) composed of VP1 are significantly reduced when this protein is expressed from ORF2 alone. To determine how the 3' terminus of the NV subgenomic RNA regulates VP1 expression, we compared VP1 expression levels by using recombinant baculovirus constructs containing different 3' elements. High VP1 levels were detected by using a recombinant baculovirus that contained ORF2, ORF3, and the 3'UTR (ORF2+3+3'UTR). In contrast, expression of VP1 from constructs that lacked the 3'UTR (ORF2+3), ORF3 (ORF2+3'UTR), or both (ORF2 alone) was highly reduced. Elimination of VP2 synthesis from the subgenomic RNA by mutation resulted in VP1 levels similar to those obtained with the ORF2 construct alone, suggesting a cis role for VP2 in upregulation of VP1 expression levels. Comparisons of the kinetics of RNA and capsid protein expression levels by using constructs with or without ORF3 or the 3'UTR revealed that the 3'UTR increased the levels of VP1 RNA, whereas the presence of VP2 resulted in increased levels of VP1. Furthermore, VP2 increased VP1 stability and protected VP1 from disassembly and protease degradation. The increase in VP1 expression levels caused by the presence of VP2 in cis was also observed in mammalian cells.     

Two independent pathways of expression lead to self-assembly of the rabbit hemorrhagic disease virus capsid protein.

The rabbit hemorrhagic disease virus capsid protein was expressed in insect cells either as an individual protein species, from a mRNA analogous to the viral subgenomic RNA, or as part of a polyprotein that included the viral 3C-like protease and the RNA polymerase. Both pathways of expression led to the assembly of viruslike particles morphologically and antigenically similar to purified virus.     

An umbraviral protein,involved in long-distance RNA movement,binds viral RNA and forms unique,protective ribonucleoprotein complexes

Umbraviruses are different from most other viruses in that they do not encode a conventional capsid protein (CP); therefore, no recognizable virus particles are formed in infected plants. Their lack of a CP is compensated for by the ORF3 protein, which fulfils functions that are provided by the CPs of other viruses, such as protection and long-distance movement of viral RNA. When the Groundnut rosette virus (GRV) ORF3 protein was expressed from Tobacco mosaic virus (TMV) in place of the TMV CP [TMV(ORF3)], in infected cells it interacted with the TMV RNA to form filamentous ribonucleoprotein (RNP) particles that had elements of helical structure but were not as uniform as classical virions. These RNP particles were observed in amorphous inclusions in the cytoplasm, where they were embedded within an electron-dense matrix material. The inclusions were detected in all types of cells and were abundant in phloem-associated cells, in particular companion cells and immature sieve elements. RNP-containing complexes similar in appearance to the inclusions were isolated from plants infected with TMV(ORF3) or with GRV itself. In vitro, the ORF3 protein formed oligomers and bound RNA in a manner consistent with its role in the formation of RNP complexes. It is suggested that the cytoplasmic RNP complexes formed by the ORF3 protein serve to protect viral RNA and may be the form in which it moves through the phloem. Thus, the RNP particles detected here represent a novel structure which may be used by umbraviruses as an alternative to classical virions.     

Detection of Leishmania RNA virus 1 proteins.

Polyclonal antiserum was raised against the peak viral fraction of a sucrose gradient from LRV1-4-infected cells and used in Western immunoblot analysis to identify viral proteins from various isolates. Consistent with this result, in vitro-translated protein from cloned RNA was immunoprecipitated with the same antiserum. The putative capsid at times appeared as a doublet; relative amounts of the two species varied, depending on the method of purification.     

Purification,identification, and biochemical characterization of a host-encoded cysteine protease that cleaves a leishmaniavirus gag-pol polyprotein

Leishmania RNA virus (LRV) is a double-stranded RNA virus that infects some strains of the protozoan parasite leishmania As with other totiviruses, LRV presumably expresses its polymerase by a ribosomal frameshift, resulting in a capsid-polymerase fusion protein. We have demonstrated previously that an LRV capsid-polymerase polyprotein is specifically cleaved by a Leishmania-encoded cysteine protease. This study reports the purification of this protease through a strategy involving anion-exchange chromatography and affinity chromatography. By using a Sepharose-immobilized lectin, concanavalin A, we isolated a fraction enriched with LRV polyprotein-specific protease activity. Analysis of the active fraction by sodium dodecyl sulfate-polyacrylamide gel electrophoreses and silver staining revealed a 50-kDa protein that, upon characterization by high-pressure liquid chromatography electrospray tandem mass spectrometry (electrospray ionization/MS/MS), was identified as a cysteine protease of trypanosomes. A partial amino acid sequence derived from the MS/MS data was compared with a protein database using BLAST software, revealing homology with several cysteine proteases of Leishmania and other trypanosomes. The protease exhibited remarkable temperature stability, while inhibitor studies characterized the protease as a trypsin-like cysteine protease-a novel finding for leishmania. To elucidate substrate preferences, a panel of deletion mutations and single-amino-acid mutations were engineered into a Gag-Pol fusion construct that was subsequently transcribed and translated in vitro and then used in cleavage assays. The data suggest that there are a number of cleavage sites located within a 153-amino-acid region spanning both the carboxy-terminal capsid region and the amino-terminal polymerase domain, with LRV capsid exhibiting the greatest susceptibility to proteolysis.     

The 41-amino-acid C-terminal region of the hepatitis E virus ORF3 protein interacts with bikunin, a kunitz-type serine protease inhibitor

Hepatitis E virus (HEV), a human plus-stranded RNA virus, contains three open reading frames (ORF). Of these, ORF1 encodes the viral nonstructural polyprotein, ORF2 encodes the major capsid protein, and ORF3 codes for a phosphoprotein of undefined function. Recently, using the yeast two-hybrid system to screen a human cDNA liver library, we have isolated and characterized AMBP (alpha1-microglobulin/bikunin precursor), which specifically interacts with the ORF3 protein of HEV. The ORF3 protein expedites the processing and secretion of alpha1-microglobulin. When checked individually for interaction, the second processed protein from AMBP, bikunin, strongly interacted with the full-length ORF3 protein. This protein-protein interaction has been validated by immunoprecipitation in both COS-1 and Huh7 cells and by His6 pull-down assays. In dual-labeling immunofluorescent staining, followed by fluorescence microscopy of transfected human liver cells, ORF3 colocalized with endogenously expressed bikunin. Finally, a 41-amino-acid C-terminal region of ORF3 has been found to be responsible for interacting with bikunin. The importance of this virus-host protein-protein interaction, with reference to the viral life cycle, has been discussed.     

The double-stranded RNA genome of yeast virus L-A encodes its own putative RNA polymerase by fusing two open reading frames

The L-A double-stranded RNA virus of Saccharomyces cerevisiae encodes its major coat protein (80 kDa) and a minor single-stranded RNA binding protein (180 kDa) that has immunological cross-reactivity with the major coat protein. The sequence of L-A cDNA clones revealed two open reading frames (ORF), ORF1 and ORF2. These two reading frames overlap by 130 base pairs and ORF2 is in the -1 reading frame with respect to ORF1. Although the major coat protein of the viral particles is encoded by ORF1, the 180-kDa protein is derived from the entire double-stranded RNA genome by fusing ORF1 and ORF2, probably by a -1 translational frameshift. Within the overlapping region is a sequence similar to that producing a -1 frameshift by "simultaneous slippage" in retroviruses. The coding sequence of ORF2 shows a pattern characteristic of viral RNA-dependent RNA polymerases of icosahedral (+)-strand RNA viruses. Thus, the 180-kDa protein is analogous to gag-pol fusion proteins.     

The ORF3 protein of hepatitis E virus interacts with hemopexin by means of its 26 amino acid N-terminal hydrophobic domain II

Hepatitis E virus (HEV) is a nonenveloped plus-stranded RNA virus that is a major cause of acute hepatitis in many developing countries. Recent work has shown HEV may be endemic in developed countries also. The 5' two-thirds of the 7.2 kb single-stranded RNA genome of HEV encodes ORF1, and the 3' end encodes the structural proteins ORF2 and ORF3. ORF1 is the nonstructural protein involved in viral RNA synthesis, and ORF2 is the major capsid protein, whereas ORF3 is a very small protein of only 123 amino acids. The precise cellular functions of ORF3 protein remain obscure, although it has been postulated to be a viral regulatory protein. To elucidate the role of ORF3 in viral pathogenesis, the yeast two-hybrid system was used to screen a human liver cDNA library for proteins interacting with ORF3. One of the ORF3-interacting partners thus isolated and identified was hemopexin, a 60 kDa acute-phase plasma glycoprotein with a high binding affinity to heme. The two-hybrid result was validated by in vitro pull-down and co-immunoprecipitation assays and finally by intracellular fluorescence resonance energy transfer. Using a deletion mapping approach, the hydrophobic domain II of ORF3 (spanning amino acids 37 to 62) was found to be responsible for binding to Hpx, with amino acids 63 to 77 possibly contributing to the strength of the interaction. The biological significance of this interaction in the virus life cycle has been discussed.     

A circular dichroism study of the structure of Penicillium chrysogenum mycovirus

We have examined the absorption and circular dichroism spectra of intact Penicillium chrysogenum virus, empty capsid particles, and isolated double-stranded RNA. The absorbance at 260 nm of intact virus was less than 4% hypochromic relative to the absorbances of the free double-stranded RNA and free viral protein, indicating very little change in the base stacking interactions of the RNA. Circular dichroism studies of intact virus indicate that the capsid protein consists of 45% alpha-helix. Empty capsids, containing a protein of the same molecular weight as intact virus protein, were found to have 30% alpha-helix, suggesting a conformational change in the capsid upon assembly with RNA. The conformation of double-stranded RNA in the virus was slightly altered from the solution structure of the RNA in 0.01 M Na+ and resembled the conformation of double-stranded RNA partially bound with spermidine. However, the virus does not appear to contain polyamines. Electrophoretic experiments indicate a pH- and salt-titratable RNA binding site on the capsid protein in virus disrupted by urea or non-ionic detergents. The results are consistent with significant ionic interactions between the RNA and the capsid protein in the virus.     

II型鲤疱疹病毒ORF4的多克隆抗体制备及其组织分布

【目的】制备II型鲤疱疹病毒(Cy HV-2)ORF4多克隆抗体,利用免疫学方法研究ORF4编码蛋白在病毒感染过程中的组织表达特征。【方法】利用在线软件SMART和BLASTx分析Cy HV-2 ORF4序列,采用PCR技术从Cy HV-2基因组中扩增得到ORF4基因,克隆至表达载体PGEX-4T-3中,将获得的重组表达质粒转化到大肠杆菌BL21(DE3)中,用IPTG诱导表达,表达产物经过SDS-PAGE和Western blot鉴定,再利用亲和层析法纯化出重组蛋白。用纯化的重组ORF4蛋白免疫新西兰兔,收集兔血,分离兔血清获得抗ORF4蛋白的多克隆抗体,再利用Western blot检测抗体与ORF4蛋白之间的特异性。提取攻毒后的异育银鲫肌肉、脑、鳃、脾脏、肝胰脏、心脏、肾脏等组织DNA,用荧光定量PCR技术监测其病毒在各组织的复制水平。使用RIPA裂解液提取上述各组织总蛋白,再利用Western blot技术检测ORF4在感染Cy HV-2的异育银鲫各组织中的表达情况。【结果】原核表达的重组ORF4蛋白分子量为65 k D,与预期大小一致;获得的ORF4抗血清能特异性识别重组ORF4蛋白。病毒感染的异育银鲫体内ORF4主要表达在肾脏、脾脏和鳃上;荧光定量PCR证明Cy HV-2主要在肾脏、脾脏和鳃上富集。【结论】Cy HV-2的非结构蛋白ORF4可能参与病毒的复制,是病毒复制感染周期的特征性指示蛋白之一,这为深入研究ORF4在Cy HV-2感染过程中的作用机制提供参考。