Bottle gourd (Lagenaria siceraria) is an important vegetable crop as well as a rootstock for other cucurbit crops. In this study, we report a high-quality 313.4-Mb genome sequence of a bottle gourd inbred line, USVL1VR-Ls, with a scaffold N50 of 8.7 Mb and the longest of 19.0 Mb. About 98.3% of the assembled scaffolds are anchored to the 11 pseudomolecules. Our comparative genomic analysis identifies chromosome-level syntenic relationships between bottle gourd and other cucurbits, as well as lineage-specific gene family expansions in bottle gourd. We reconstructed the genome of the most recent common ancestor of Cucurbitaceae, which revealed that the ancestral Cucurbitaceae karyotypes consisted of 12 protochromosomes with 18 534 protogenes. The 12 protochromosomes are largely retained in the modern melon genome, while have undergone different degrees of shuffling events in other investigated cucurbit genomes. The 11 bottle gourd chromosomes derive from the ancestral Cucurbitaceae karyotypes followed by 19 chromosomal fissions and 20 fusions. The bottle gourd genome sequence has facilitated the mapping of a dominant monogenic locus, Prs, conferring Papaya ring-spot virus (PRSV) resistance in bottle gourd, to a 317.8-kb region on chromosome 1. We have developed a cleaved amplified polymorphic sequence (CAPS) marker tightly linked to the Prs locus and demonstrated its potential application in marker-assisted selection of PRSV resistance in bottle gourd. This study provides insights into the paleohistory of Cucurbitaceae genome evolution, and the high-quality genome sequence of bottle gourd provides a useful resource for plant comparative genomics studies and cucurbit improvement.
A rice cDNA library was screened by a galactosidase 4 (Gal4)-based yeast two-hybrid system with Rice stripe virus (RSV) p2 as bait. The results revealed that RSV p2 interacted with a rice protein exhibiting a high degree of identity with Arabidopsis thaliana suppressor of gene silencing 3 (AtSGS3). The interaction was confirmed by bimolecular fluorescence complementation assay. SGS3 has been shown to be involved in sense transgene-induced RNA silencing and in the biogenesis of trans-acting small interfering RNAs (ta-siRNAs), possibly functioning as a cofactor of RNA-dependent RNA polymerase 6 (RDR6). Given the intimate relationships between virus and RNA silencing, further experiments were conducted to show that p2 was a silencing suppressor. In addition, p2 enhanced the accumulation and pathogenicity of Potato virus X in Nicotiana benthamiana. Five genes that have been demonstrated to be targets of TAS3-derived ta-siRNAs were up-regulated in RSV-infected rice. The implications of these findings are discussed.
Rice dwarf virus (RDV) replicates in and is transmitted by a leafhopper vector in a persistent-propagative manner. Previous cytopathologic and genetic data revealed that tubular structures, constructed by the nonstructural viral protein Pns10, contain viral particles and are directly involved in the intercellular spread of RDV among cultured leafhopper cells. Here, we demonstrated that RDV exploited these virus-containing tubules to move along actin-based microvilli of the epithelial cells and muscle fibers of visceral muscle tissues in the alimentary canal, facilitating the spread of virus in the body of its insect vector leafhoppers. In cultured leafhopper cells, the knockdown of Pns10 expression due to RNA interference (RNAi) induced by synthesized dsRNA from Pns10 gene strongly inhibited tubule formation and prevented the spread of virus among insect vector cells. RNAi induced after ingestion of dsRNA from Pns10 gene strongly inhibited formation of tubules, preventing intercellular spread and transmission of the virus by the leafhopper. All these results, for the first time, show that a persistent-propagative virus exploits virus-containing tubules composed of a nonstructural viral protein to traffic along actin-based cellular protrusions, facilitating the intercellular spread of the virus in the vector insect. The RNAi strategy and the insect vector cell culture provide useful tools to investigate the molecular mechanisms enabling efficient transmission of persistent-propagative plant viruses by vector insects.
BackgroundThe multifunctional cylindrical inclusion (CI) protein of potyviruses contains ATP binding and RNA helicase activities. As part of the viral replication complex, it assists viral genome replication, possibly by binding to RNA and unwinding the RNA duplex. It also functions in viral cell-to-cell movement, likely via the formation of conical structures at plasmodesmata (PD) and the interaction with coat protein (CP).MethodsTo further understand the role of CI in the viral infection process, we employed the alanine-scanning mutagenesis approach to mutate CI in the infectious full-length cDNA clone of Turnip mosaic virus (TuMV) tagged by green fluorescent protein. A total of 40 double-substitutions were made at the clustered charged residues. The effect of these mutations on viral genome amplification was determined using a protoplast inoculation assay. All the mutants were also introduced into Nicotiana benthamiana plants to assess their cell-to-cell and long-distance movement. Three cell-to-cell movement-abolished mutants were randomly selected to determine if their mutated CI protein targets PD and interacts with CP by confocal microscopy.ResultsTwenty CI mutants were replication-defective (5 abolished and 15 reduced), one produced an elevated level of viral genome in comparison with the parental virus, and the remaining 19 retained the same replication level as the parental virus. The replication-defective mutations were predominately located in the helicase domains and C-terminal region. All 15 replication-reduced mutants showed delayed or abolished cell-to-cell movement. Nine of 20 replication-competent mutants contained infection within single cells. Five of them distributed mutations within the N-terminal 100 amino acids. Most of replication-defective or cell-to-cell movement-abolished mutants failed to infect plants systemically. Analysis of three randomly selected replication-competent yet cell-to-cell movement-abolished mutants revealed that the mutated CI failed to form regular punctate structures at PD and/or to interact with CP.ConclusionsThe helicase domain and C-terminal region of TuMV CI are essential for viral genome replication, and the N-terminal sequence modulates viral cell-to-cell movement. TuMV CI plays both interlinked and distinct roles in replication and intercellular movement. The ability of CI to target PD and interact with CP is associated with its functional role in viral cell-to-cell movement.Electronic supplementary materialThe online version of this article (doi:10.1186/s12985-015-0369-2) contains supplementary material, which is available to authorized users.
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