Complete genome sequencing and construction of full-length infectious cDNA clone of papaya ringspot virus-HYD isolate and its efficient in planta expression.

Papaya ringspot virus (PRSV) is a devastating Potyvirus that causes papaya ringspot disease in Carica papaya plantations globally. In this study, the complete genome sequence of a PRSV isolate from Shankarpalli, Telangana, India, was reported and designated as PRSV-HYD (KP743981.1). The genome is a single-stranded positive-sense RNA comprising 10,341 nucleotides. Phylogenetic analysis revealed that PRSV-HYD is closely related to PRSV Pune (Aundh) isolate with 92 and 95% nucleotide and amino acid sequence identity, respectively. To develop infectious cDNA (icDNA), the complete nucleotide sequence of PRSV-HYD was cloned between the right and left borders in the binary vector pCB301 using BglII and XmaI restriction sites. Cauliflower mosaic virus (CaMV) double promoter (35S) was fused at the 5'-end and Avocado sunblotch viroid (ASBVd) ribozyme (RZ) sequence was fused to the 3' end to generate an authentic 3' viral end in the transcribed mRNAs. The icDNA generated was mobilized into the Agrobacterium tumefaciens EHA 105, and the agrobacterial cultures were infiltrated into the natural host C. papaya and a non-host Nicotiana benthamiana plants; both did not show any symptoms. In RT-PCR analysis of RNAs isolated from N. benthamiana, we could detect viral genes as early as 3 days and continued up to 28 days post infiltration. Alternatively, virion particles were purified from agroinfiltrated N. benthamiana plants and introduced into C. papaya by mechanical inoculation as well as by pinprick method. In both cases, we could see visible systemic symptoms similar to that of wild type by 40 days. Additionally, we studied the expression patterns of the genes related to plant defense, transcription factors (TFs), and developmental aspects from both C. papaya and N. benthamiana.

Highly conserved Asp-204 and Gly-776 are important for activity of the quinoprotein glucose dehydrogenase of Escherichia coli and for mineral phosphate solubilization.

Gram-negative bacteria membrane-bound glucose dehydrogenase (m-GDH) has pyrroloquinoline quinone [PQQ (2,7,9,-tricarboxyl-1H-pyrrolo[2,3-f]quinoline-4,5-dione)] as its prosthetic group, transferring electrons to ubiquinone (UQ) in the membrane. Based on the sequence homology of the C-terminal catalytic domain (151-796 amino acid residues) we have modeled the 3D structure of Escherichia coli GDH. The geometrical parameters of the homology model structure, validated using the Ramachandran plot, revealed 95.8% of residues in the allowed regions and 2.2% of the residues in disallowed regions. From the model, we have identified five different amino acids that are specifically involved in maintaining the PQQ in the correct configuration along with a Ca(2+) ion in the active site, and two amino acids on the surface of the protein that might be involved in UQ binding or transfer of electrons to the UQ. Site-directed mutants R201A, D204A, E217L, E217A, R266Q, R266E, E591L, E591Q, E591K, L712W, L712R, G776K, G776D and G776L lost their GDH activity, while E217Q and G776A retained their function similar to that of wild-type GDH, both in terms of specific activity and mineral phosphate solubilization. Our conclusions are consistent with those previously based on model GDH produced by a different method and using a different template X-ray structure.

Replication-independent long-distance trafficking by viral RNAs in Nicotiana benthamiana.

Viruses with separately encapsidated genomes could have their genomes introduced into different leaves of a plant, thus necessitating long-distance trafficking of the viral RNAs for successful infection. To examine this possibility, individual or combinations of genome segments from the tripartite Brome mosaic virus (BMV) were transiently expressed in leaves of Nicotiana benthamiana plants using engineered Agrobacterium tumefaciens. BMV RNA3 was found to traffic from the initial site of expression to other leaves of the plant, as detected by RNA gel blot analyses and also by the expression of an endoplasmic reticulum-targeted green fluorescent protein. When RNA3 trafficked into leaves containing the BMV replication enzymes, RNA replication, transcription, and virion production were observed. RNA3 trafficking occurred even when it did not encode the movement or capsid proteins. However, coexpression of the movement protein increased the trafficking of BMV RNAs. BMV RNA1 and RNA2 could also traffic throughout the plant, but less efficiently than RNA3. All three BMV RNAs trafficked bidirectionally to sink leaves near the apical meristem as well as to the source leaves at the bottom of the stem, suggesting that trafficking used the phloem. These results demonstrate that BMV RNAs can use a replication-independent mechanism to traffic in N. benthamiana.

RNA-binding proteins that inhibit RNA virus infection.

Arrays of >5,000 Saccharomyces cerevisiae proteins were screened to identify proteins that can preferentially bind a small RNA hairpin that contains a clamped adenine motif (CAM). A CAM is required for the replication of Brome Mosaic Virus (BMV), a plant-infecting RNA virus that can replicate in S. cerevisiae. Several hits were selected for further characterization in Nicotiana benthamiana. Pseudouridine Synthase 4 (Pus4) and the Actin Patch Protein 1 (App1) modestly reduced BMV genomic plus-strand RNA accumulation, but dramatically inhibited BMV systemic spread in plants. Pus4 also prevented the encapsidation of a BMV RNA in plants and the reassembly of BMV virions in vitro. These results demonstrate the feasibility of using proteome arrays to identify specific RNA-binding proteins for antiviral activities. Furthermore, the effects of Pus4 suggest that the CAM-containing RNA motif provides a regulatory link between RNA replication and encapsidation.

Core-controlled polymorphism in virus-like particles.

This study concerns the self-assembly of virus-like particles (VLPs) composed of an icosahedral virus protein coat encapsulating a functionalized spherical nanoparticle core. The recent development of efficient methods for VLP self-assembly has opened the way to structural studies. Using electron microscopy with image reconstruction, the structures of several VLPs obtained from brome mosaic virus capsid proteins and gold nanoparticles were elucidated. Varying the gold core diameter provides control over the capsid structure. The number of subunits required for a complete capsid increases with the core diameter. The packaging efficiency is a function of the number of capsid protein subunits per gold nanoparticle. VLPs of varying diameters were found to resemble to three classes of viral particles found in cells (T=1, 2, and 3). As a consequence of their regularity, VLPs form three-dimensional crystals under the same conditions as the wild-type virus. The crystals represent a form of metallodielectric material that exhibits optical properties influenced by multipolar plasmonic coupling.

Viral RNA silencing suppressors inhibit the microRNA pathway at an intermediate step.

RNA silencing suppressors from different plant viruses are structurally diverse. In addition to inhibiting the antiviral silencing response to condition susceptibility, many suppressors are pathogenicity factors that cause disease or developmental abnormalities. Here, unrelated suppressors from multiple viruses were shown to inhibit microRNA (miRNA) activities and trigger an overlapping series of severe developmental defects in transgenic Arabidopsis thaliana. This suggests that interference with miRNA-directed processes may be a general feature contributing to pathogenicity of many viruses. A normally labile intermediate in the miRNA biogenesis/RNA-induced silencing complex (RISC) assembly pathway, miRNA*, accumulated specifically in the presence of suppressors (P1/HC-Pro, p21, or p19) that inhibited miRNA-guided cleavage of target mRNAs. Both p21 and p19, but not P1/HC-Pro, interacted with miRNA/miRNA* complexes and hairpin RNA-derived short interfering RNAs (siRNAs) in vivo. In addition, p21 bound to synthetic miRNA/miRNA* and siRNA duplexes in vitro. We propose that several different suppressors act by distinct mechanisms to inhibit the incorporation of small RNAs into active RISCs.

Suppressor of RNA silencing encoded by Beet yellows virus.

Using an Agrobacterium-mediated transient assay, we screened the 15.5-kb genome of the Beet yellows virus for proteins with RNA silencing suppressor activity. Among eight proteins tested, only a 21-kDa protein (p21) was able to suppress double-stranded (ds) RNA-induced silencing of the green fluorescent protein (GFP) mRNA. Restoration of GFP expression by p21 under these conditions had no apparent effect on accumulation of the small interfering RNAs. In addition, p21 elevated the transient expression level of the GFP mRNA in the absence of dsRNA inducer. Similar activities were detected using homologs of p21 encoded by other members of the genus Closterovirus. Computer analysis indicated that p21-like proteins constitute a novel protein family that is unrelated to other recognized suppressors of RNA silencing. Examination of the subcellular distribution in BYV-infected plants revealed that p21 is partitioned between soluble cytoplasmic form and proteinaceous inclusion bodies at the cell periphery.

Subcellular location of the helper component-proteinase of Cowpea aphid-borne mosaic virus.

The helper component-proteinase (HC-Pro) of Cowpea aphid-borne mosaic virus (CABMV) was expressed in Escherichia coli and used to obtain HC-Pro antiserum that was used as an analytical tool for HC-Pro studies. The antiserum was used in immunofluorescence assays to study the subcellular location of HC-Pro expressed with other viral proteins in cowpea protoplasts in a natural CABMV infection, or in protoplasts transfected with a transient expression construct expressing HC-Pro separately from other viral proteins under the control of the 35S promoter. In both cases the protein showed a diffuse cytoplasmic location. Similar localisation patterns were shown in live protoplasts when the transient expression system was used to express HC-Pro as a fusion with the green fluorescent protein as a reporter. In an alternative expression system, the HC-Pro coding region was subcloned in-frame between the movement protein and large coat protein genes of RNA2 of Cowpea mosaic virus (CPMV). Upon transfection of protoplasts with this construct, HC-Pro was expressed as part of the RNA2 encoded polyprotein from which it was fully processed. In this case, the protein localised in broad cytoplasmic patches reminiscent of the typical CPMV induced cytopathic structures in which CPMV replication occurs, suggesting an interaction of HC-Pro with CPMV proteins or host factors in these structures. Finally, recombinant CPMV expressing HC-Pro showed a strongly enhanced virulence on cowpea and Nicotiana benthamiana consistent with the role of HC-Pro as a pathogenicity determinant, a phenomenon now known to be linked to its role as a suppressor of host defense responses based on post-transcriptional gene silencing.