The present invention relates to a modified gene that provides resistance to Cucurbit Yellow Stunting Disorder virus (CYSDV) when present in a plant of the Cucurbitaceae family. The invention further relates to progeny, seed, and fruit of the plant that is resistant against CYSDV. The invention also relates to propagation material suitable for producing the plant that is resistant to CYSDV. Additionally, the invention relates to methods for producing, identifying, and selecting a plant of the Cucurbitaceae family having resistance against CYSDV.

A method according to an embodiment of the present disclosure is for enhancing disease resistance of a plant against Soybean mosaic virus compared to a non-transformant. The method may include transforming a plant cell of the plant with a recombinant vector containing a gene encoding Glycine max purple acid phosphatase 2.1 (GmPAP2.1) protein from Glycine max to overexpress the gene encoding GmPAP2.1 protein. As the GmPAP2.1 gene from Glycine max of the present invention can modulate disease resistance against Soybean mosaic virus, it is expected to be applied for development of new cultivars with enhanced resistance to Soybean mosaic virus to thereby increase soybean productivity.

The invention relates to a Solanum lycopersicum plant comprising in its genome QTLs confering to the plant an improved phenotype corresponding to foliar and/or fruit tolerance and/or resistance to Tomato Brown Rugose Fruit virus, with respect to a corresponding plant devoid of said QTLs, and wherein said QTLs are chosen from those present in the genome of a plant of the seeds HAZTBRFVRES1 NCIMB accession number 42758. The QTL are preferably characterized by defined alleles of different SNPs on chromosome 6, 9 and 11. The invention is also directed to parts of these plants with improved phenotype, as well as progeny, to the use of these plants for introgressing the improved phenotype in another genetic background, as well as to different methods for obtaining tomato plants or seeds with increased foliar and/or fruit tolerance or resistance to Tomato Brown Rugose Fruit virus.

Isolated cDNA sequences encoding for highly conserved domains of plant viral pathogen genomes. The cDNA sequences are selected from the group consisting of those listed in Table I (SEQ ID NOs: 1-68). cDNA fusion constructs or chimeric transgene constructs comprising at least two different cDNA sequences selected from the list in Table I, and more specifically cDNA corresponding to at least two different viruses is described, along with methods of creating transgenic plants with broad-spectrum, durable resistance to multiple viral pathogens using these cDNA sequences.

The present application discloses an application of OsAO gene for improving rice resistance to rice stripe disease, rice black-streaked dwarf disease or other rice or corn virus diseases caused by homologous virus of rice black-streaked dwarf virus. The present application also provides an application of OsAO gene, the protein encoded by the gene or a recombinant vector containing the gene in regulating plant resistance to rice stripe disease, rice black-streaked dwarf disease or other rice and corn virus diseases caused by homologous virus of rice black-streaked dwarf virus, said protein has the amino acid sequence as shown in Seq 4. The experiment proved that the plant disease resistance is increased in rice overexpressing OsAO gene, indicating that the OsAO protein encoded by this gene plays an important role in rice resistance to rice stripe disease and rice black-streaked dwarf disease.

The disclosure provides a loss-of-function gene of eIFiso4E-S. The loss-of-function gene is resistant to tobacco vein banding mosaic virus (TVBMV) and represented by the sequence of SEQ ID NO: 1.

Cucumber plants (Cucumis sativus) exhibiting increased resistance to Cumber Green Mottle Mosaic Virus (CGMMV) are provided, together with methods of producing, identifying, or selecting plants or germplasm with a CGMMV resistance phenotype. Such plants include cucumber plants comprising recombinant chromosomal segments conferring CGMMV resistance. Compositions, including novel polymorphic markers for detecting plants comprising introgressed virus resistance alleles, are further provided.

Disclosed are hypersensitive-response eliciting peptides that exhibit improved solubility, stability, resistance to chemical degradation, or a combination of these properties. Use of these peptides or fusion polypeptides, or DNA constructs encoding the same, for modulating plant biochemical signaling, imparting disease resistance to plants, enhancing plant growth, imparting tolerance to biotic stress, imparting tolerance and resistance to abiotic stress, imparting desiccation resistance to cuttings removed from ornamental plants, imparting post-harvest disease or post-harvest desiccation resistance to a fruit or vegetable, or enhancing the longevity of fruit or vegetable ripeness are also disclosed.

Compositions and methods for enhancing disease resistance in plants are disclosed.

The present invention provides tomato plants exhibiting resistance to the TOSPO (GBNV) Virus exhibiting the traits of healthy and evenly ripened fruits without brown spots, reduced wilting of the top portion of the tomato plants and reduced dark spots on the leaves and stems of the tomato plant, and materials useful for improving tomato yield. In particular, the present invention provides a path to the development of hybrid tomato plants exhibiting resistance to TOSPO (GBNV) virus infection, seed of hybrid tomato plants exhibiting TOSPO (GBNV) virus resistance, and methods of producing the same. Methods described herein involve the use of marker-assisted selection and marker-assisted backcrossing utilizing molecular markers associated with a tomato TOSPO Resistance phenotype.