The 64-kilodalton capsid protein homolog of Beet yellows virus is required for assembly of virion tails

The filamentous virion of the closterovirus Beet yellows virus (BYV) consists of a long body formed by the major capsid protein (CP) and a short tail composed of the minor capsid protein (CPm) and the virus-encoded Hsp70 homolog. By using nano-liquid chromatography-tandem mass spectrometry and biochemical analyses, we show here that the BYV 64-kDa protein (p64) is the fourth integral component of BYV virions. The N-terminal domain of p64 is exposed at the virion surface and is accessible to antibodies and mild trypsin digestion. In contrast, the C-terminal domain is embedded in the virion and is inaccessible to antibodies or trypsin. The C-terminal domain of p64 is shown to be homologous to CP and CPm. Mutation of the signature motifs of capsid proteins of filamentous RNA viruses in p64 results in the formation of tailless virions, which are unable to move from cell to cell. These results reveal the dual function of p64 in tail assembly and BYV motility and support the concept of the virion tail as a specialized device for BYV cell-to-cell movement.     

Putative 65 kDa protein of beet yellows closterovirus is a homologue of HSP70 heat shock proteins

A portion of the RNA genome of beet yellows closterovirus (BYV) has been sequenced encompassing a complete long open reading frame (ORF) potentially encoding a 65 kDa protein. The sequence of this putative protein was strikingly similar to those of HSP70-related heat shock proteins. The counterparts of all the eight segments strongly conserved in HSP70s could be confidently identified in the BYV 65 kDa protein. It is suggested that some of these segments might be the ATP-binding site(s) and that, similarly to the heat shock proteins, the 65 kDa is probably ATP-binding. Generally, however, the divergence between the 65 kDa sequence and the sequences of the HSP70s was much more pronounced than that between any two members of the latter family, allowing a clearer delineation of clusters of conserved residues that might be crucial for protein function. It is suggested that these observations will be helpful in functional dissection of the proteins of the HSP70 family. Analysis of the sequence of a portion of the ORF found upstream from the 65 kDa ORF showed that the C-terminal domain of the encoded protein could be an RNA-dependent RNA polymerase closely related to those of tricornaviruses, a family of RNA plant viruses with three component genomes.     

Cell-to-cell movement and assembly of a plant closterovirus: roles for the capsid proteins and Hsp70 homolog.

Diverse animal and plant viruses are able to translocate their virions between neighboring cells via intercellular connections. In this work, we analyze the virion assembly and cell-to-cell movement of a plant closterovirus and reveal a strong correlation between these two processes. The filamentous virions of a closterovirus possess a long body formed by the major capsid protein (CP) and a short tail formed by the minor capsid protein (CPm). Genetic and biochemical analyses show that the functions of these virion components are distinct. A virion body is required primarily for genome protection, whereas a tail represents a specialized device for cell-to-cell movement. Furthermore, tail assembly is mediated by the viral Hsp70 homolog (Hsp70h) that becomes an integral part of the virion. Inactivation of the ATPase domain of Hsp70h results in assembly of tailless virions that are incapable of translocation. A dual role for the viral molecular chaperone Hsp70h in virion assembly and transport, combined with the previous finding of this protein in intercellular channels, allowed us to propose a model of closteroviral movement from cell to cell.     

Molecular Analysis of ORF6, ORF7 and ORF8 of Beet yellows virus Iranian Isolate

Beet yellows virus (BYV), a member of the Closteroviridae family, is one of the most important sugar beet yellowing viruses. The nine ORFs of BYV genome encode different proteins required for BYV life cycle. We sequenced a part of the genome of BYV Iranian isolate consisting of ORF6, ORF7 and ORF8. The primer pair BYVA/Z was used for amplification of this region in RT‐PCR. The amplicon (1615 bp) was cloned and sequenced. Comparisons showed the amplified segment is corresponding to ORF6, ORF7 and ORF8 of BYV genome encoding coat protein, p20 and p21 proteins, respectively. The ORF7 of BYV Iranian isolate overlaps with ORF6 and ORF8 in four and 26 nucleotides at 5′ and 3′ ends, respectively. The ORF7 of Iranian isolate of BYV was sequenced completely. However, approximately 24 nt. from the beginning of ORF6 and 23 nt. from end of ORF8, including the stop codon, were not determined. ORF6, ORF7 and ORF8 showed the highest similarity at nucleotide (98.3, 99.4 and 99.2%) and amino acid (97.4, 98.9 and 100%) sequence levels, with BYV Ukrainian isolate. Phylogenetic analysis of the deduced amino acid sequences of ORF6, ORF7 and ORF8 revealed closer relationship of Iranian isolate of BYV with BYV Ukrainian isolate than other BYV isolates available at GenBank.     

Functional Characterization of a Strong Bi-directional Constitutive Plant Promoter Isolated from Cotton Leaf Curl Burewala Virus

Cotton leaf curl Burewala virus (CLCuBuV), belonging to the genus Begomovirus, possesses single-stranded monopartite DNA genome. The bidirectional promoters representing Rep and coat protein (CP) genes of CLCuBuV were characterized and their efficacy was assayed. Rep and CP promoters of CLCuBuV and 35S promoter of Cauliflower mosaic virus (CaMV) were fused with β-glucuronidase (GUS) and green fluorescent protein (GFP) reporter genes. GUS activity in individual plant cells driven by Rep, CP and 35S promoters was estimated using real-time PCR and fluorometric GUS assay. Histochemical staining of GUS in transformed tobacco (Nicotiana tabacum cv. Xanthi) leaves showed highest expression driven by Rep promoter followed by 35S promoter and CP promoter. The expression level of GUS driven by Rep promoter in transformed tobacco plants was shown to be two to four-fold higher than that of 35S promoter, while the expression by CP promoter was slightly lower. Further, the expression of GFP was monitored in agroinfiltrated leaves of N. benthamiana, N. tabacum and cotton (Gossypium hirsutum) plants using confocal laser scanning microscopy. Rep promoter showed strong consistent transient expression in tobacco and cotton leaves as compared to 35S promoter. The strong constitutive CLCuBuV Rep promoter developed in this study could be very useful for high level expression of transgenes in a wide variety of plant cells.     

A novel robust heat-inducible promoter for heterologous gene expression in Tetrahymena thermophila

An increasing amount of data has revealed the importance of inducible promoters in ciliate research and in ciliate-related industries. However, knowledge about these promoters and related genes is relatively sparse. Here we report a novel inducible promoter from a Tetrahymena cytoplasmic Hsp70 gene member, HSP70-2. The reported promoter was able to induce the endogenous gene up to ～9000-fold after a short heat shock treatment and this remarkable feature has been retained when a relatively short region of the promoter was introduced into a reporter construct followed by transformation. During the recovery period following a short heat shock, both the mRNA and protein levels of the reporter gene were maintained high up to two hours. A constant heat shock treatment to the transformed cells led to a stabilization of the reporter mRNA up to at least six hours and the reporter protein continued to accumulate up to around three hours. The promoter strength appears to be similar to that of the cadmium-induced metallothionein gene (MTT1) promoter. Therefore, the HSP70-2 promoter represents an attractive alternative for the over-expression of proteins in Tetrahymena, and the promoter-reporter gene construct used in this study is an ideal tool to help in understanding the regulation mechanisms of heat shock genes in ciliates.     

Temporal and spatial control of transgene expression using a heat-inducible promoter in transgenic wheat

Constitutive promoters are widely used to functionally characterise plant genes in transgenic plants, but their lack of specificity and poor control over protein expression can be a major disadvantage. On the other hand, promoters that provide precise regulation of temporal or spatial transgene expression facilitate such studies by targeting over-expression or knockdown of target genes to specific tissues and/or at particular developmental stages. Here, we used the uidA (beta-glucuronidase, GUS) reporter gene to demonstrate that the barley Hvhsp17 gene promoter can be induced by heat treatment of 38-40 °C for 1-2 h in transgenic wheat. The GUS enzyme was expressed only in those tissues directly exposed to heat and not in neighbouring leaf tissues. The induction of HSP::GUS was demonstrated in all organs and tissues tested, but expression in older tissues was lower. Generally, proximal root sections showed less GUS activity than in root tips. This heat-inducible promoter provides the ability to investigate the function of candidate genes by overexpression or by down-regulation of target gene expression (for example by RNAi) in selected tissues or developmental stages of a transgenic plant, limited only by the ability to apply a heat shock to the selected tissues. It also allows the investigation of genes that would be lethal or reduce fertility if expressed constitutively.     

Interaction between long-distance transport factor and Hsp70-related movement protein of Beet yellows virus

Systemic spread of viruses in plants involves local movement from cell to cell and long-distance transport through the vascular system. The cell-to-cell movement of the Beet yellows virus (BYV) is mediated by a movement protein that is an Hsp70 homolog (Hsp70h). This protein is required for the assembly of movement-competent virions that incorporate Hsp70h. By using the yeast two-hybrid system, in vitro coimmunoprecipitation, and in planta coexpression approaches, we show here that the Hsp70h interacts with a 20-kDa BYV protein (p20). We further demonstrate that p20 is associated with the virions presumably via binding to Hsp70h. Genetic and immunochemical analyses indicate that p20 is dispensable for assembly and cell-to-cell movement of BYV but is required for the long-distance transport of virus through the phloem. These results reveal a novel activity for the Hsp70h that provides a molecular link between the local and systemic spread of a plant virus by docking a long-distance transport factor to virions.     

A Mutation in the Lettuce Infectious Yellows Virus Minor Coat Protein Disrupts Whitefly Transmission but Not In Planta Systemic Movement

The Lettuce infectious yellows virus (LIYV) RNA 2 mutant p1-5b was previously isolated from Bemisia tabaci-transmitted virus maintained in Chenopodium murale plants. p1-5b RNA 2 contains a single-nucleotide deletion in the minor coat protein (CPm) open reading frame (ORF) that is predicted to result in a frameshift and premature termination of the protein. Using the recently developed agroinoculation system for LIYV, we tested RNA 2 containing the p1-5b CPm mutant genotype (agro-pR6-5b) in Nicotiana benthamiana plants. We showed that plant infection triggered by agro-pR6-5b spread systemically and resulted in the formation of virions similar to those produced in p1-5b-inoculated protoplasts. However, virions derived from these mutant CPm genotypes were not transmitted by whiteflies, even though virion concentrations were above the typical transmission thresholds. In contrast, and as demonstrated for the first time, an engineered restoration mutant (agro-pR6-5bM1) was capable of both systemic movement in plants and whitefly transmission. These results provide strong molecular evidence that the full-length LIYV-encoded CPm is dispensable for systemic plant movement but is required for whitefly transmission.Members of the genus Crinivirus are emerging plant viruses in many parts of the world. An important factor contributing to the increase in the incidence of these viruses is their association with and transmission by whitefly vectors that have increased in distribution in the last several decades. Lettuce infectious yellows virus (LIYV), the type member of the genus Crinivirus (family Closteroviridae), is specifically transmitted by the sweet potato whitefly, Bemisia tabaci biotype A, in a semipersistent, noncirculative manner (6). The virus is confined to phloem cells within infected plants and is not transmissible to plants by leaf rub inoculation. The bipartite single-stranded positive-sense LIYV genome components, consisting of RNA 1 (approximately 8.1 kb) and RNA 2 (approximately 7.2 kb), are separately encapsidated in flexuous filamentous particles that are characteristic of the family Closteroviridae (8, 11). These virions are comprised of four protein components: the major coat protein (CP), the minor coat protein (CPm), an Hsp70 homolog (Hsp70h), and a 59-kDa protein (P59). Like other viruses in the family Closteroviridae, LIYV has bipolar virions with a “body” composed mainly of the CP and a “head” that is formed by the assembly of CPm subunits (2, 4, 7, 22, 28). Hsp70h and P59 are detected in LIYV virions (22), but their locations have not been identified, as they are not readily detected by immunogold labeling and transmission electron microscopy (IGL-TEM). For two members of the family Closteroviridae, Citrus tristeza virus (CTV) and Beet yellows virus (BYV), the combination of Hsp70h, P61 (the homolog of LIYV P59 in CTV) or P64 (the homolog of LIYV P59 in BYV), and CPm encapsidates the 5′ end (∼630 to 650 nucleotides [nt]) of the RNA genome, demonstrating the complex interactions that exist among the capsid proteins and the genomic RNA (15, 21).In our previous studies, we demonstrated the transmission of LIYV using an in vitro acquisition and whitefly transmission system (13, 22). Results from previous work implicated a role for LIYV CPm in whitefly transmission. Antibodies to CPm blocked the in vitro acquisition/transmission of LIYV virion preparations by B. tabaci biotype A, while antibodies to CP, Hsp70h, and P59 did not (22). The in vitro whitefly membrane-feeding system had also been used to demonstrate B. tabaci biotype A transmission of virions that were derived from cloned infectious cDNAs of LIYV RNA 1 and RNA 2 of several genotypes, including pR6 (the first cloned wild-type [WT] infectious cDNA of LIYV RNA 2 [10]), establishing for the first time that these cloned constructs contained all of the information necessary for protoplast infection, virion formation, whitefly transmission, and infection in plants (12). In that study, the mutant p1-5b was among the cloned LIYV RNA 2 cDNAs derived from B. tabaci biotype A-transmitted virus maintained in Chenopodium murale plants.p1-5b contains a single-adenine-residue deletion in the CPm open reading frame (ORF) at nucleotide 592, a deletion that is predicted to result in a frameshift, 14 new amino acids, and premature termination of the protein (12). The predicted p1-5b CPm has 211 amino acids, compared to 453 amino acids in the wild-type (pR6 genotype) protein. The p1-5b genotype also contains three other nucleotide changes in the CPm ORF relative to the pR6 infectious clone sequence (27), all of which result in amino acid changes. In contrast, the p1-5b CP, Hsp70h, and P59 sequences are identical to that of pR6 (12). Possible polymorphisms throughout the rest of the p1-5b clone were not characterized. In a prior study, B. tabaci biotype A transmission of p1-5b virions was not observed, even though the mutation did not affect its infectivity in protoplasts (as determined by virion yields) and apparent particle morphology (12). However, those studies were disadvantaged by the necessity of propagation in protoplasts to obtain specific genotypes from infectious cloned cDNAs. Protoplasts yield low quantities of virion relative to plants, and virion concentration is a critical parameter in whitefly transmission (13). Although virion concentrations in those experiments were above typical thresholds for whitefly transmission (12, 13), low concentrations may still be limiting for transmission, making negative transmission results difficult to interpret. Obtaining adequate virion concentrations of specific genotypes for whitefly transmission to plants has therefore been a significant hurdle to LIYV transmission studies.The recently developed agroinoculation method for LIYV (24) permits the study of systemic plant infection by distinct LIYV genotypes, including those that are whitefly transmission deficient, and the recovery of higher virion yields than were possible using protoplasts. The objective of this study was to further examine the function of the LIVY CPm by extending our observations of p1-5b. We constructed mutants with the CPm frameshift restored to determine if engineered mutations that either restored or disrupted the formation of an intact CPm also affected systemic plant infection, virion formation, and B. tabaci biotype A transmission. Our study revealed that a mutant engineered with the restored CPm ORF produced a WT infection profile characterized by systemic virus movement within agroinoculated plants and the generation of CPm-containing virions that were whitefly transmissible. Intriguingly, systemic virus movement was also observed for a mutant engineered to express the 1-5b CPm, but the virions lacked an identifiable CPm and were defective in whitefly transmission. These results represent a significant advance in addressing challenging questions and hypotheses about Crinivirus whitefly transmission properties not testable using earlier systems.     

Development of a rubella virus vaccine expression vector: use of a picornavirus internal ribosome entry site increases stability of expression

Rubella virus (RUB) is a small plus-strand RNA virus classified in the Rubivirus genus of the family Togaviridae. Live, attenuated RUB vaccines have been successfully used in vaccination programs for over 25 years, making RUB an attractive vaccine vector. In this study, such a vector was constructed using a recently developed RUB infectious cDNA clone (Robo). Using a standard strategy employed to produce expression and vaccine vectors with other togaviruses, the subgenomic promoter was duplicated to produce a recombinant construct (termed dsRobo) that expressed reporter genes such as chloramphenicol acetyltransferase and green fluorescent protein (GFP) under control of the second subgenomic promoter. However, expression of the reporter genes, as exemplified by GFP expression by dsRobo/GFP virus, was unstable during passaging, apparently due to homologous recombination between the subgenomic promoters leading to deletion of the GFP gene. To improve the stability of the vector, the internal ribosome entry site (IRES) of a picornavirus, encephalomyocarditis virus, was used instead of the second subgenomic promoter to eliminate homology. Construction was initiated by first replacing the subgenomic promoter in the parent Robo infectious clone with the IRES. Surprisingly, viable virus resulted; this virus did not synthesize a subgenomic RNA. The subgenomic promoter was then reintroduced in an orientation such that a single subgenomic RNA was produced, GFP was the initial gene on this RNA, while the RUB structural protein open reading frame was downstream and under control of the IRES element. GFP expression by this vector was significantly improved in comparison to dsRobo/GFP. This strategy should be applicable to increase the stability of other togavirus vectors.     

Pollen- and anther-specific chi promoters from petunia: tandem promoter regulation of the chiA gene.

We have analyzed the spatial and temporal activities of chalcone flavanone isomerase (chi) A and B gene promoters from petunia. To study the tandem promoter regulation of chiA, various chiA promoter fragments were fused with the beta-glucuronidase (GUS) reporter gene. Analysis of transgenic plants containing these chimeric genes provided definitive proof that the chiA coding region is regulated by two distinct promoters (designated PA1 and PA2). We also showed that both promoters can function independently and that the chiA PA1 promoter is expressed in limb (epidermal and parenchyma cells), tube (inner epidermal and parenchyma cells), seed (seed coat, endosperm, and embryo), sepal, leaf, and stem. The use of chiA and chiB promoters in the regulation of anther- and pollen-specific gene expression has been studied. By analyzing transgenic plants containing chimeric genes consisting of chiA and B promoter fragments and the GUS reporter gene, we were able to identify a 0.44-kilobase chiA PA2 promoter fragment that drives pollen-specific gene expression and a 1.75-kilobase chiB PB promoter fragment that confers anther-specific (pollen and tapetum cells) expression to the GUS gene.     

Evidence for a Dual Strategy in the Expression of Cauliflower Mosaic Virus Open Reading Frames I and IV

Studies have indicated that cauliflower mosaic virus (CaMV) gene expression is mediated by the translation of polycistronic 35S pregenomic RNA, but the involvement of some minor subgenomic RNA species is also suspected. We examined the involvement of the 35S promoter in the expression of CaMV open reading frames (ORFs) I and IV using both 35S RNA-driven and promoter-less ORF I- and ORF IV-β-glucuronidase (GUS) fusion constructs. In addition to the 35S promoter-dependent expression of both ORF I- and IV-GUS fusions, we detected the 35S promoter-independent expression of both fusion genes via subgenomic mRNAs, which were detected by Northern blotting in the protoplasts transfected with the 35S promoter-driven constructs as well as in those transfected with the promoter-less constructs. These results suggest the involvement of subgenomic RNAs in the expression of CaMV ORFs I and IV, and the operation of a dual strategy in the expression of two viral genes.