Molecular Diversities of Sugarcane mosaic virus and Sorghum mosaic virus Isolates from Yunnan Province,China

Degenerate Potyviridae primers were used to amplify and sequence the 3′‐terminal regions of viruses from traditional and modern cultivars of sugarcane with mosaic disease growing in different areas of Yunnan province, China. Seven samples contained Sugarcane mosaic virus (SCMV), 11 contained Sorghum mosaic virus (SrMV) and two contained both viruses. SCMV was only isolated from traditional cultivars. In a phylogenetic analysis of the partial NIb and complete coat protein coding regions, most SCMV isolates formed a distinctive phylogenetic cluster (named SO) that otherwise contained only three Vietnamese isolates. SCMV variation seems mostly related to host genotype. In the same analysis, the SrMV isolates formed three major groups, one of which is reported for the first time, but the significance of the grouping is unclear.     

Molecular insights into the origin of the brown rust resistance gene <Emphasis Type="Italic">Bru</Emphasis>1 among <Emphasis Type="Italic">Saccharum</Emphasis> species

Key message

Analysis of 387 sugarcane clones using Bru 1 diagnostic markers revealed two possible sources of Bru 1 in Chinese cultivars: one from Saccharum spontaneum and another from Saccharum robustum of New Guinea.

Abstract

Sugarcane brown rust (SBR) is an important fungal disease in many sugarcane production areas around the world, and can cause considerable yield losses in susceptible sugarcane cultivars. One major SBR resistance gene, named Bru1, initially identified from cultivar R570, was shown to be a major SBR resistance source in most of the sugarcane producing areas of the world. In this study, by using the two Bru1-associated markers, R12H16 and 9O20-F4, we surveyed the presence of Bru1 in a Chinese sugarcane germplasm collection of 387 clones, consisting of 228 hybrid cultivars bred by different Chinese sugarcane breeding establishments, 54 exotic hybrid cultivars introduced from other countries and 105 clones of sugarcane ancestral species. The Bru1-bearing haplotype was detected in 43.4% of Chinese sugarcane cultivars, 20.4% of exotic hybrid cultivars, and only 3.8% of ancestral species. Among the 33 Chinese cultivars for which phenotypes of resistance to SBR were available, Bru1 was present in 69.2% (18/26) of the resistant clones. Analyses of the allelic sequence variations of R12H16 and 9O20-F4 suggested two possible sources of Bru1 in Chinese cultivars: one from S. spontaneum and another from S. robustum of New Guinea. In addition, we developed an improved Bru1 diagnostic marker, 9O20-F4-HaeIII, which can eliminate all the false results of 9O20-F4-RsaI observed among S. spontaneum, as well as a new dominant Bru1 diagnostic marker, R12E03-2, from the BAC ShCIR12E03. Our results provide valuable information for further efforts of breeding SBR-resistant varieties, searching new SBR resistance sources and cloning of Bru1 in sugarcane.

     

Genetic diversity and population structure of Sorghum mosaic virus infecting Saccharum spp. hybrids

Sugarcane mosaic disease is widespread in many countries and has been identified to be caused by Sugarcane mosaic virus (SCMV), Sorghum mosaic virus (SrMV) and Sugarcane streak mosaic virus (SCSMV). Viral surveys of SCMV, SrMV and SCSMV were performed from 104 leaf samples of Saccharum spp. hybrid growing in China and two leaf samples in Myanmar. Sorghum mosaic virus was a major causal agent for sugarcane mosaic disease in China whereby 72.1% (75/104) of samples had SrMV infection alone, 6.7% (7/104) were mixed with SCMV and 17.3% (18/104) were mixed with SCSMV. Sugarcane streak mosaic virus infection alone occurred in 3.8% (4/104) of samples, but no single infections were observed for SCMV. Two viruses (SrMV and SCSMV) were detected in sugarcane mosaic samples in Myanmar. Phylogenetic analysis revealed that all of the SrMV isolates were clustered into three major lineages encompassing six phylogroups/genotypes based on the CP sequences (825 nucleotides) of 113 Chinese and 2 Burmese isolates from this study and 73 isolates reported worldwide. Six clearly distinct SrMV phylogroups (G1–G6) were formed and shared 74.3–94.1% nucleotide identity and 84.7–98.1% amino acid identity of CP sequences. SrMV‐G5 was identified to be new distinct phylogroup that was restricted to the Fujian and Guangxi provinces. The unique SrMV‐G6 phylogroup only occurred in Yunnan province. Insertion/deletion mutations, negative selection and frequent gene flow are factors driving the genetic evolution and population structure of SrMV in China.     

Transformation and evaluation of different transgenic lines for Glyphosate tolerance and cane borer resistance genes in sugarcane (<Emphasis Type="Italic">Saccharum officinarum</Emphasis> L.)

The aim of this study was to ensure the systematic protein expression of two genes (GTG and Cry1Ac) under the influence of two different constitutive promoters i.e. Ubiquitin-1 and CaMV 35S promoters in different sugarcane lines. PCR amplification of GTG and Cry1Ac was achieved from putative transgenic plants through gene specific primers. Qualitative comparisons of GTG and Cry1Ac genes expression under two different promoters were obtained through protein dot blot and dipstick assay. The appearance of comparatively dark color dots in dot blot and dark color bands on dipstick with Ubiquitin as compared to light color bands with CaMV35S promoter, qualitatively confirmed high protein expression of two genes under Ubiquitin promoter. In quantitative gene expression comparisons maximum optical density (OD) at 450 nm of UV-light was obtained for GTG (3.7 OD) and Cry1Ac (3 OD) under Ubiquitin promoter, while for GTG (1.6 OD) and Cry1Ac (2.5 OD) with CaMV 35S promoter. The results indicated higher expression of two genes under Ubiquitin-1 promoter in sugarcane was found as compared to CaMV 35S promoter. This study provides a guide for stable and high expression of transgenes with reference to Ubiquitin-1 promoter which can be utilize in sugarcane as well as in other monocots.     

Characterization of a Sorghum mosaic virus (SrMV) isolate in China

Sorghum mosaic virus (SrMV), a causal agent of the destructive sugarcane mosaic disease, has a global presence. An isolate of SrMV infecting a commercially-grown sugarcane plant was recovered from the Hainan province of China. The virions were visualized by an electron microscope, and the coat proteins (CPs) were sequenced by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry and tandem mass spectrometry. Discrepancies between the CP predicted and actual amino acid sequences were noted, which confounded the phylogenetic assignment of the isolate. The apparent variations may have physiological effects on the pathogenicity and virulence of SrMV.     

Subcellular localization and detection of <Emphasis Type="Italic">Tobacco mosaic virus</Emphasis> ORF6 protein by immunoelectron microscopy

Members of the genus Tobamovirus represent one of the best-characterized groups of plant positive, single stranded RNA viruses. Previous studies have shown that genomes of some tobamoviruses contain not only genes coding for coat protein, movement protein, and the cistron coding for different domains of RNA-polymerase, but also a gene, named ORF6, coding for a poorly conserved small protein. The amino acid sequences of ORF6 proteins encoded by different tobamoviruses are highly divergent. The potential role of ORF6 proteins in replication of tobamoviruses still needs to be elucidated. In this study, using biochemical and immunological methods, we have shown that ORF6 peptide is accumulated after infection in case of two isolates of Tobacco mosaic virus strain U1 (TMV-U1 common and TMV-U1 isolate A15). Unlike virus particles accumulating in the cytoplasm, the product of the ORF6 gene is found mainly in nuclei, which correlates with previously published data about transient expression of ORF6 isolated from TMV-U1. Moreover, we present new data showing the presence of ORF6 genes in genomes of several tobamoviruses. For example, in the genomes of other members of the tobamovirus subgroup 1, including Rehmannia mosaic virus, Paprika mild mottle virus, Tobacco mild green mosaic virus, Tomato mosaic virus, Tomato mottle mosaic virus, and Nigerian tobacco latent virus, sequence comparisons revealed the existence of a similar open reading frame like ORF6 of TMV.