Chloroplast phosphoglycerate kinase, a gluconeogenetic enzyme, is required for efficient accumulation of Bamboo mosaic virus

The tertiary structure in the 3′-untranslated region (3′-UTR) of Bamboo mosaic virus (BaMV) RNA is known to be involved in minus-strand RNA synthesis. Proteins found in the RNA-dependent RNA polymerase (RdRp) fraction of BaMV-infected leaves interact with the radio labeled 3′-UTR probe in electrophoretic mobility shift assays (EMSA). Results derived from the ultraviolet (UV) cross-linking competition assays suggested that two cellular factors, p43 and p51, interact specifically with the 3′-UTR of BaMV RNA. p43 and p51 associate with the poly(A) tail and the pseudoknot of the BaMV 3′-UTR, respectively. p51-containing extracts specifically down-regulated minus-strand RNA synthesis when added to in vitro RdRp assays. LC/MS/MS sequencing indicates that p43 is a chloroplast phosphoglycerate kinase (PGK). When the chloroplast PKG levels were knocked down in plants, using virus-induced gene silencing system, the accumulation level of BaMV coat protein was also reduced.     

Susceptibility and symptom development in Arabidopsis thaliana to Tobacco mosaic virus is influenced by virus cell-to-cell movement

To identify host factors that regulate susceptibility to Tobacco mosaic virus (TMV), 14 Arabidopsis thaliana ecotypes were screened for their ability to support TMV systemic movement. The susceptibility phenotypes observed included one ecotype that permitted rapid TMV movement accompanied by symptoms, nine ecotypes that allowed a slower intermediate rate of systemic movement without symptoms, and four ecotypes that allowed little or no systemic TMV movement. Molecular comparisons between ecotypes representing the rapid (Shahdara), intermediate (Col-1), and slow (Tsu-1) movement phenotypes revealed a positive correlation between the ability of TMV to move cell to cell and its speed of systemic movement. Additionally, protoplasts prepared from all three ecotypes supported similar levels of TMV replication, indicating that viral replication did not account for differences in systemic movement. Furthermore, induction of the pathogenesis-related genes PR-1 and PR-5 occurred only in the highly susceptible ecotype Shahdara, demonstrating that reduced local and systemic movement in Col-1 and Tsu-1 was not due to the activation of known host defense responses. Genetic analysis of F2 progeny derived from crosses made between Shahdara and Tsu-1 or Col-1 and Tsu-1 showed the faster cell-to-cell movement phenotypes of Shahdara and Col-1 segregated as single dominant genes. In addition, the Shahdara symptom phenotype segregated independently as a single recessive gene. Taken together, these findings suggest that, within Arabidopsis ecotypes, at least two genes modulate susceptibility to TMV.     

Two key arginine residues in the coat protein of Bamboo mosaic virus differentially affect the accumulation of viral genomic and subgenomic RNAs

The interactions between viral RNAs and coat proteins (CPs) are critical for the efficient completion of infection cycles of RNA viruses. However, the specificity of the interactions between CPs and genomic or subgenomic RNAs remains poorly understood. In this study, Bamboo mosaic virus (BaMV) was used to analyse such interactions. Using reversible formaldehyde cross‐linking and mass spectrometry, two regions in CP, each containing a basic amino acid (R99 and R227, respectively), were identified to bind directly to the 5′ untranslated region of BaMV genomic RNA. Analyses of the alanine mutations of R99 and R227 revealed that the secondary structures of CP were not affected significantly, whereas the accumulation of BaMV genomic, but not subgenomic, RNA was severely decreased at 24 h post‐inoculation in the inoculated protoplasts. In the absence of CP, the accumulation levels of genomic and subgenomic RNAs were decreased to 1.1%–1.5% and 33%–40% of that of the wild‐type (wt), respectively, in inoculated leaves at 5 days post‐inoculation (dpi). In contrast, in the presence of mutant CPs, the genomic RNAs remained about 1% of that of wt, whereas the subgenomic RNAs accumulated to at least 87%, suggesting that CP might increase the accumulation of subgenomic RNAs. The mutations also restricted viral movement and virion formation in Nicotiana benthamiana leaves at 5 dpi. These results demonstrate that R99 and R227 of CP play crucial roles in the accumulation, movement and virion formation of BaMV RNAs, and indicate that genomic and subgenomic RNAs interact differently with BaMV CP.     

Host range and symptom differences between isolates of turnip mosaic virus obtained fromSisymbrium loeselii

Twenty-four isolates of turnip mosaic virus (TuMV) from spontaneously infectedSisymbriutn loeselii plants were collected in Bohemian localities. Single lesions on leaves ofNicotiana tabacum cv. Samsun served for inoculating petunia plants used as infection sources for twelve host species. In no case were two identical isolates obtained. 15 isolates could be transmitted toVicia faba, a new TuMV host. Almost all isolates infectedPhaseolus vulgaris cv. Prince locally andTrifolium incarnatum systemically. Seven isolates were transmissible toPisum sativum. No substantial differences between isolates were observed with infectedAn aranthus caudatus, Chenopodium quinoa, Datura innoxia andSinapis alba plants. Several isolates could not infectNicotiana glutinosa at all, other isolates caused in it latent systemic infection and some isolates only local infection contrary to normal local and systemic infections ofN. glutinosa. Attempts to transmit one isolate to cereals failed.     

Evolutionary relationship of alfalfa mosaic virus with cucumber mosaic virus and brome mosaic virus

The amino acid sequences of the non-structural protein (molecular weight 35,000; 3a protein) from three plant viruses — cucumber mosaic, brome mosaic and alfalfa mosaic have been systematically compared using the partial genomic sequences for these three viruses already available. The 3a protein of cucumber mosaic virus has an amino acid sequence homology of 33.7% with the corresponding protein of brome mosaic virus. A similar protein from alfalfa mosaic virus has a homology of 18.2% and 14.2% with the protein from brome mosaic virus and cucumber mosaic virus, respectively. These results suggest that the three plant viruses are evolutionarily related, although, the evolutionary distance between alfalfa mosaic virus and cucumber mosaic virus or brome mosaic virus is much larger than the corresponding distance between the latter two viruses.     

Inheritance of resistance to zucchini yellow mosaic virus and watermelon mosaic virus in watermelon

High resistance to zucchini yellow mosaic virus-China strain (ZYMV-CH) and moderate resistance to watermelon mosaic virus (WMV) were found in a selection of PI 595203 (Citrullus lanatus var. lanatus), an Egusi type originally collected in Nigeria. Mixed inoculations showed primarily that these two viruses have no cross-protection. This fact may explain the high frequency of mixed infection often observed in commercial fields. When plants were inoculated with a mixture of the two viruses, the frequency of plants resistant to ZYMV was lower than expected, indicating that WMV infection may reduce the ability of a plant to resist ZYMV. We studied inheritance of resistance to ZYMV-CH and WMV, using crosses between a single-plant selection of PI 595203 and the ZYMV-susceptible watermelon inbreds 9811 and 98R. According to virus ratings of the susceptible parents, the resistant parent, and the F1, F2, and BC1 generations, resistance to ZYMV-CH was conferred by a single recessive gene, for which the symbol zym-CH is suggested. The high tolerance to WMV was controlled by at least two recessive genes.     

The conserved 5' apical hairpin stem loops of bamboo mosaic virus and its satellite RNA contribute to replication competence

Satellite RNAs associated with Bamboo mosaic virus (satBaMVs) depend on BaMV for replication and encapsidation. Certain satBaMVs isolated from natural fields significantly interfere with BaMV replication. The 5' apical hairpin stem loop (AHSL) of satBaMV is the major determinant in interference with BaMV replication. In this study, by in vivo competition assay, we revealed that the sequence and structure of AHSL, along with specific nucleotides (C(60) and C(83)) required for interference with BaMV replication, are also involved in replication competition among satBaMV variants. Moreover, all of the 5' ends of natural BaMV isolates contain the similar AHSLs having conserved nucleotides (C(64) and C(86)) with those of interfering satBaMVs, suggesting their co-evolution. Mutational analyses revealed that C(86) was essential for BaMV replication, and that replacement of C(64) with U reduced replication efficiency. The non-interfering satBaMV interfered with BaMV replication with the BaMV-C64U mutant as helper. These findings suggest that two cytosines at the equivalent positions in the AHSLs of BaMV and satBaMV play a crucial role in replication competence. The downregulation level, which is dependent upon the molar ratio of interfering satBaMV to BaMV, implies that there is competition for limited replication machinery.     

Chloroplast Phosphoglycerate Kinase Is Involved in the Targeting of Bamboo mosaic virus to Chloroplasts in Nicotiana benthamiana Plants

The Bamboo mosaic virus (BaMV) is a positive-sense, single-stranded RNA virus. Previously, we identified that the chloroplast phosphoglycerate kinase (chl-PGK) from Nicotiana benthamiana is one of the viral RNA binding proteins involved in the BaMV infection cycle. Because chl-PGK is transported to the chloroplast, we hypothesized that chl-PGK might be involved in viral RNA localization in the chloroplasts. To test this hypothesis, we constructed two green fluorescent protein (GFP)-fused mislocalized PGK mutants, the transit peptide deletion mutant (NO TRANSIT PEPTIDE [NOTP]-PGK-GFP) and the nucleus location mutant (nuclear location signal [NLS]-PGK-GFP). Using confocal microscopy, we demonstrated that NOTP-PGK-GFP and NLS-PGK-GFP are localized in the cytoplasm and nucleus, respectively, in N. benthamiana plants. When NOTP-PGK-GFP and NLS-PGK-GFP are transiently expressed, we observed a reduction in BaMV coat protein accumulation to 47% and 27% that of the wild-type PGK-GFP, respectively. To localize viral RNA in infected cells, we employed the interaction of NLS-GFP-MS2 (phage MS2 coat protein) with the modified BaMV RNA containing the MS2 coat protein binding sequence. Using confocal microscopy, we observed that BaMV viral RNA localizes to chloroplasts. Furthermore, elongation factor1a fused with the transit peptide derived from chl-PGK or with a Rubisco small subunit can partially restore BaMV accumulation in NbPGK1-knockdown plants by helping BaMV target chloroplasts.Bamboo mosaic virus (BaMV) is a single-stranded, positive-sense RNA virus. The genomic RNA of BaMV contains five open reading frames (ORFs) and is 6,366 nucleotides in length with a 5′ cap and a 3′ poly(A) tail (Lin et al., 1994; Yang et al., 1997). ORF1 encodes a 155-kD replicase comprised of a capping enzyme domain that exhibits S-adenosylmethionine-dependent guanylyltransferase activity (Li et al., 2001a; Huang et al., 2004), a helicase-like domain with RNA 5′-triphosphatase activity (Li et al., 2001b), and an RNA-dependent RNA polymerase domain (Li et al., 1998; Cheng et al., 2001). The three overlapping ORFs (i.e. ORF2, ORF3, and ORF4) are known as the triple gene block. They encode for proteins involved in viral movement (Lin et al., 2004, 2006; Vijaya Palani et al., 2006). ORF5 encodes the viral capsid protein (CP), required for virion assembly and viral movement (Cruz et al., 1998).The genomes of positive-strand RNA viruses are templates for both translation and replication. Viral replication complexes are likely to be assembled using host factors to synthesize the minus-strand RNA and then the plus-strand progeny RNA. Recent studies have shown that host factors play important roles in assembling the viral RNA replication complex, selecting and recruiting viral replication templates, activating the complex for RNA synthesis, and other steps (Ahlquist et al., 2003; Patarroyo et al., 2012). The translation and the minus-strand RNA synthesis of poliovirus are regulated by host poly(C) and poly(A) binding proteins and viral polymerase precursor 3CD (Waggoner and Sarnow, 1998; Herold and Andino, 2001; Walter et al., 2002). A number of host genes required for Brome mosaic virus replication have been identified systemically by the yeast (Saccharomyces cerevisiae) genetic approach (Ishikawa et al., 1997; Kushner et al., 2003; Mas et al., 2006; Gancarz et al., 2011). The same approach was used to identify the host factors involved in the replication of Tomato bushy stunt virus (TBSV; Panavas et al., 2005; Li et al., 2009b). A heat shock protein90 homolog (Huang et al., 2012) and the Nicotiana benthamiana glutathione transferase U4 (NbGSTU4; Chen et al., 2013), were identified to interact with the 3′ untranslated region (UTR) of BaMV RNA and enhanced the minus-strand RNA synthesis at the early replication step. The Ser/Thr kinase-like protein localized on cell membrane facilitates the BaMV intercellular movement (Cheng et al., 2013).Previously, we have identified two host proteins (i.e. p51 and p43) interacting specifically with the 3′ UTRs of BaMV by using electrophoretic mobility shift assay (EMSA) and the UV cross-linking competition technique. The results of liquid chromatography-tandem mass spectrometry (LC-MS/MS) and BLAST indicate that the protein sequences of p43 and p51 match the chloroplast phosphoglycerate kinase (chl-PGK) and elongation factor1a (EF1a) of Nicotiana benthamiana, respectively (Lin et al., 2007). Phosphoglycerate kinase is an ATP-generating enzyme that acts in the glycolytic, gluconeogenic, and photosynthetic pathways (Banks et al., 1979; McHarg et al., 1999). chl-PGK is encoded in the nucleus and translated to produce a 50-kD precursor protein and is then processed into mature 43 kD in the chloroplast. In a knockdown experiment through virus-induced gene silencing, the reduction of PGK decreased the accumulation of BaMV coat protein (Lin et al., 2007).Eukaryotic EF1a has been shown to play a role in binding to the tRNA-like structure and upstream pseudoknot in the 3′ UTR of Tobacco mosaic virus to regulate the gene expression and viral replication (Pathak et al., 2008). EF1a has also been involved in the recruitment of viral RNA and has facilitated the replicase complex assembly of TBSV (Pogany et al., 2008). The 3′ UTR of BaMV cannot only bind its replicase but also the EF1a and has been proposed to regulate viral RNA replication (Lin et al., 2007).In this study, we transiently expressed two mislocalized PGK mutants to study the possible functions of chl-PGK that is involved in viral RNA replication. In addition, we used confocal microscopy to investigate the localization of BaMV RNA. Finally, we provided evidence that the down-regulation of BaMV accumulation in PGK-knockdown plants can be restored by the expression of the BaMV RNA binding protein EF1a that is fused to a chloroplast transit peptide.     

Vascular invasion routes and systemic accumulation patterns of tobacco mosaic virus in Nicotiana benthamiana

Plant viruses must enter the host vascular system in order to invade the young growing parts of the plant rapidly. Functional entry sites into the leaf vascular system for rapid systemic infection have not been determined for any plant/virus system. Tobacco mosaic virus (TMV) entry into minor, major and transport veins from non-vascular cells of Nicotiana benthamiana in source tissue and its exit from veins in sink tissue was studied using a modified virus expressing green fluorescent protein (GFP). Using a surgical procedure that isolated specific leaf and stem tissues from complicating vascular tissues, we determined that TMV could enter minor, major or transport veins directly from non-vascular cells to produce a systemic infection. TMV first accumulated in abaxial or external phloem-associated cells in major veins and petioles of the inoculated leaf and stems below the inoculated leaf. It also initially accumulated exclusively in internal or adaxial phloem-associated cells in stems above the inoculated leaf and petioles or major veins of sink leaves. This work shows the functional equivalence of vein classes in source leaves for entry of TMV, and the lack of equivalence of vein classes in sink leaves for exit of TMV. Thus, the specialization of major veins for transport rather than loading of photoassimilates in source tissue does not preclude virus entry. During transport, the virus initially accumulates in specific vascular-associated cells, indicating that virus accumulation in this tissue is highly regulated. These findings have important implications for studies on the identification of symplasmic domains and host macromolecule vascular transport.     

Interaction of cucumber mosaic virus and potato virus y with tobacco mosaic virus

A study was performed on the interaction of cucumber mosaic virus (CMV) of potato virus Y (PVY) with tobacco mosaic virus (TMV). Interference was evaluated using tobacco plantsNicotiana tabacum cv. Java responding to CMV and PVY with a systemic infection and to TMV with local necrotic lesions. The decrease in TMV — induced lesion number gave evidence of a decrease in susceptibility caused by the previous infection with CMV or PVY, the decrease of lesion enlargement demonstrated a decreased TMV reproduction in the plants previously infected with CMV or PVY. The interference concerned was incomplete, as evaluated from reproduction of the challenging TMV and from the decrease in susceptibility of the host to TMV brought about by the first infection with CMV or PVY.     

TOM1 family conservation within the plant kingdom for tobacco mosaic virus accumulation

The susceptibility factor TOBAMOVIRUS MULTIPLICATION 1 (TOM1) is required for efficient multiplication of tobacco mosaic virus (TMV). Although some phylogenetic and functional analyses of the TOM1 family members have been conducted, a comprehensive analysis of the TOM1 homologues based on phylogeny from the most ancient to the youngest representatives within the plant kingdom, analysis of support for tobamovirus accumulation and interaction with other host and viral proteins has not been reported. In this study, using Nicotiana benthamiana and TMV as a model system, we functionally characterized the TOM1 homologues from N. benthamiana and other plant species from different plant lineages. We modified a multiplex genome editing tool and generated a sextuple mutant in which TMV multiplication was dramatically inhibited. We showed that TOM1 homologues from N. benthamiana exhibited variable capacities to support TMV multiplication. Evolutionary analysis revealed that the TOM1 family is restricted to the plant kingdom and probably originated in the Chlorophyta division, suggesting an ancient origin of the TOM1 family. We found that the TOM1 family acquired the ability to promote TMV multiplication after the divergence of moss and spikemoss. Moreover, the capacity of TOM1 orthologues from different plant species to promote TMV multiplication and the interactions between TOM1 and TOM2A and between TOM1 and TMV-encoded replication proteins are highly conserved, suggesting a conserved nature of the TOM2A–TOM1–TMV Hel module in promoting TMV multiplication. Our study not only revealed a conserved nature of a gene module to promote tobamovirus multiplication, but also provides a valuable strategy for TMV-resistant crop development.     

Expression of the tobacco mosaic virus movement protein alters starch accumulation inNicotiana benthamiana

Nicotiana benthamiana plants were transformed with the movement protein (MP) gene of tobacco mosaic virus (TMV), usingAgrobacterium-mediated transformation. Plants regenerated from the transformed cells accumulated 30-kDa MP and complemented the activity of TMV MP when infected with chimeric TMVs containing defective MR These transgenic plants displayed stunting, pale-green leaves, and starch accumulations, indicating that TMV MP altered the carbon partitioning for leaves involved in TMV cell-to-cell movement.