Island Cotton Gbve1 Gene Encoding A Receptor-Like Protein Confers Resistance to Both Defoliating and Non-Defoliating Isolates of Verticillium dahliae

Verticillium wilt caused by soilborne fungus Verticillium dahliae could significantly reduce cotton yield. Here, we cloned a tomato Ve homologous gene, Gbve1, from an island cotton cultivar that is resistant to Verticillium wilt. We found that the Gbve1 gene was induced by V. dahliae and by phytohormones salicylic acid, jasmonic acid, and ethylene, but not by abscisic acid. The induction of Gbve1 in resistant cotton was quicker and stronger than in Verticillium-susceptible upland cotton following V. dahliae inoculation. Gbve1 promoter-driving GUS activity was found exclusively in the vascular bundles of roots and stems of transgenic Arabidopsis. Virus-induced silencing of endogenous genes in resistant cotton via targeting a fragment of the Gbve1 gene compromised cotton resistance to V. dahliae. Furthermore, we transformed the Gbve1 gene into Arabidopsis and upland cotton through Agrobacterium-mediated transformation. Overexpression of the Gbve1 gene endowed transgenic Arabidopsis and upland cotton with resistance to high aggressive defoliating and non-defoliating isolates of V. dahliae. And HR-mimic cell death was observed in the transgenic Arabidopsis. Our results demonstrate that the Gbve1 gene is responsible for resistance to V. dahliae in island cotton and can be used for breeding cotton varieties that are resistant to Verticillium wilt.     

Characterization of a Novel Cotton Subtilase Gene GbSBT1 in Response to Extracellular Stimulations and Its Role in Verticillium Resistance

Verticillium wilt is a disastrous vascular disease in plants caused by Verticillium dahliae. Verticillium pathogens secrete various disease-causing effectors in cotton. This study identified a subtilase gene GbSBT1 from Gossypium babardense and investigated the roles against V. dahliae infection. GbSBT1 gene expression is responsive to V. dahliae defense signals, jasmonic acid, and ethylene treatments. Moreover, the GbSBT1 protein is mainly localized in the cell membrane and moves into the cytoplasm following jasmonic acid and ethylene treatments. Silencing GbSBT1 gene expression through virus-induced GbSBT1 gene silencing reduced the tolerance of Pima-90 (resistant genotype), but not facilitated the infection process of V. dahliae in Coker-312 (sensitive genotype). Moreover, the ectopically expressed GbSBT1 gene enhanced the resistance of Arabidopsis to Fusarium oxysporum and V. dahliae infection and activated the expression levels of defense-related genes. Furthermore, pull-down, yeast two-hybrid assay, and BiFC analysis revealed that GbSBT1 interacts with a prohibitin (PHB)-like protein expressed in V. dahliae pathogens during infection. In summary, GbSBT1 recognizes the effector PHB protein secreted from V. dahliae and is involved in Verticillium-induced resistance in cotton.     

Silencing of <Emphasis Type="Italic">GbANS</Emphasis> reduces cotton resistance to <Emphasis Type="Italic">Verticillium dahliae</Emphasis> through decreased ROS scavenging during the pathogen invasion process

Anthocyanins are secondary metabolites that play important roles in plant adaption to adverse environments. The anthocyanin biosynthetic pathway is conserved in high plants. Previous studies revealed the significant role of anthocyanins in natural-colorized cotton. However, little is known about the involvement of anthocyanins in the interaction of cotton and pathogen. In this study, a pathogen-induced gene was isolated from Gossypium barbadense that encodes an anthocyanidin synthase protein (GbANS) with dioxygenase structures. GbANS was preferentially expressed in colored tissue. Silencing of GbANS significantly reduced the production of anthocyanins, as well as the cotton’s resistance to Verticillium dahliae. Biochemical studies revealed that GbANS-silenced cotton accumulated more hydrogen peroxide compared to control plants during the V. dahliae invasion process. This accumulation of hydrogen peroxide corresponded with increased cell death around the invasion sites, which in turn accelerated the V. dahliae infection. Taken together, we found that GbANS contributes to the biosynthesis of anthocyanins in cotton and anthocyanins positively regulate cotton’s resistance to V. dahliae.     

Dynamic infection of Verticillium dahliae in upland cotton

• Verticillium wilt, an infection caused by the soilborne fungus Verticillium dahliae, is one of the most serious diseases in cotton. No effective control method against V. dahliae has been established, and the infection mechanism of V. dahliae in upland cotton remains unknown.
• GFP‐tagged V. dahliae isolates with different pathogenic abilities were used to analyse the colonisation and infection of V. dahliae in the roots and leaves of different upland cotton cultivars, the relationships among infection processes, the immune responses and the resistance ability of different cultivars against V. dahliae.
• Here, we report a new infection model for V. dahliae in upland cotton plants. V. dahliae can colonise and infect any organ of upland cotton plants and then spread to the entire plant from the infected organ through the surface and interior of the organ.
• Vascular tissue was found to not be the sole transmission route of V. dahliae in cotton plants. In addition, the rate of infection of a V. dahliae isolate with strong pathogenicity was notably faster than that of an isolate with weak pathogenicity. The resistance of upland cotton to Verticillium wilt was related to the degree of the immune response induced in plants infected with V. dahliae. These results provide a theoretical basis for studying the mechanism underlying the interaction between V. dahliae and upland cotton. These results provide a theoretical basis for studying the mechanism underlying the interaction between V. dahliae and upland cotton.

     

Expression of a wild eggplant ribosomal protein L13a in potato enhances resistance to Verticillium dahliae

The ribosomal protein L13a was recently found to play a role not only in protein synthesis, but also in modulating translation. We reported in previous study that L13a was responsive to Verticillium dahliae (V. dahliae) infection in a highly resistant eggplant species (Solanum torvum, SW). To elucidate the possible role of L13a in V. dahliae infection, we cloned and characterized its cDNA (designated StoL13a) in this study. StoL13a encodes a protein of 23.46 kDa and shows a high similarity to the L13a from other plants. Phylogenetic analysis revealed that StoL13a clearly grouped with L13a-like sequences. Expression level of StoL13a altered in response to V. dahliae infection and phytohormone treatment. We expressed StoL13a in V. dahliae sensitive potato, and found that the transgenic potato plants were more resistant to V. dahliae infection than the control plants with disease index of 15–25.2. The transgenic plants showed a lower quantity of reactive oxygen species and attenuated oxidative injury. Also, six defense and antioxidant enzyme genes were up-regulated in the StoL13a ectopic expression plants. These results suggest that the StoL13a plays a role in plant defense to V. dahliae infection.     

MiR395 Overexpression Increases Eggplant Sensibility to <Emphasis Type="Italic">Verticillium dahliae</Emphasis> Infection

Verticillium wilt (V. wilt), a notorious wilt disease caused by Verticillium dahliae, often leads to the reduction of eggplant (Solanum melongena L.) production. MiRNAs, as a class of small RNAs, can regulate gene expression and then affect growth and development in plants. MiR395 has been proven to respond to sulfate-deficient stress in Arabidopsis thaliana and sulfate is well known to have a close relationship with plant disease resistance. To explore the function of eggplant miR395, we examined its expression in V. dahliae-infected eggplant by qRT-PCR and found miR395 exhibited a gradual reduction trend with time after infection. We then expressed pre-miR395 from Arabidopsis thaliana in Suqi eggplant and resistance analysis showed that miR395 overexpressed plants were hypersensitive to V. dahliae infection. We further measured the content of GSH and activities of POD and SOD and the results indicated that the index of GSH/POD/SOD in the overexpressed plants was lower than that of the wild-type control under V. dahliae infection. These results suggest that miR395 plays a negative role in eggplant response to V. dahliae infection.     

The glycoside hydrolase 28 member VdEPG1 is a virulence factor of Verticillium dahliae and interacts with the jasmonic acid pathway-related gene GhOPR9

Glycoside hydrolase (GH) family members act as virulence factors and regulate plant immune responses during pathogen infection. Here, we characterized the GH28 family member endopolygalacturonase VdEPG1 in Verticillium dahliae. VdEPG1 acts as a virulence factor during V. dahliae infection. The expression level of VdEPG1 was greatly increased in V. dahliae inoculated on cotton roots. VdEPG1 suppressed VdNLP1-mediated cell death by modulating pathogenesis-related genes in Nicotiana benthamiana. Knocking out VdEPG1 led to a significant decrease in the pathogenicity of V. dahliae in cotton. The deletion strains were more susceptible to osmotic stress and the ability of V. dahliae to utilize carbon sources was deficient. In addition, the deletion strains lost the ability to penetrate cellophane membrane, with mycelia showing a disordered arrangement on the membrane, and spore development was affected. A jasmonic acid (JA) pathway-related gene, GhOPR9, was identified as interacting with VdEPG1 in the yeast two-hybrid system. The interaction was further confirmed by bimolecular fluorescence complementation and luciferase complementation imaging assays in N. benthamiana leaves. GhOPR9 plays a positive role in the resistance of cotton to V. dahliae by regulating JA biosynthesis. These results indicate that VdEPG1 may be able to regulate host immune responses as a virulence factor through modulating the GhOPR9-mediated JA biosynthesis.     

Interactions between Verticillium dahliae and its host: vegetative growth,pathogenicity, plant immunity

Verticillium dahliae is a soil-borne phytopathogenic fungus that causes vascular wilt diseases in a wide variety of crop plants, resulting in extensive economic losses. In the past 5 years, progress has been made in elaborating the interaction between this hemibiotrophic fungus and its host plants. Some genes responsible for the vegetative growth and/or pathogenicity in V. dahliae have been identified. Plants have accrued a series of defense mechanisms, including inducible defense signaling pathways and some resistant genes to combat V. dahliae infection. Here, we have reviewed the progress in V. dahliae–plant interaction research.