The present invention relates to a modified FBXL13 gene which leads to a plant showing resistance to a virus belonging to the Torradovirus genus. The invention also relates to a plant belonging to the Solanaceae family comprising the modified FBXL13 gene. The modified FBXL13 gene of the invention provides a plant showing resistance to a virus belonging to the Torradovirus genus when compared to plants not comprising the modified FBXL13 gene. The invention further relates to the use of the modified FBXL13 gene for the identification and development of a plant belonging to the Solanaceae family showing resistance to a virus belonging to the Torradovirus genus.

The present invention relates to a tomato plant (Solanum lycopersicum L.) which may comprise a genetic determinant that confers resistance to Pepino Mosaic Virus (PepMV), wherein the resistance is characterised by the presence of at least QTL1 and/or QTL2. The invention also relates to sources for obtaining said genetic determinant, representative seed of which were deposited with the NCIMB under accession numbers NCIMB 41927, NCIMB 41928, NCIMB 42068, and NCIMB 42069. The invention further relates to seeds and progeny of the plant and to its fruits and processed fruits. In addition the invention relates to molecular markers linked to PepMV resistance conferring QTLs and the use thereof.

The present invention relates to a tomato plant which carries at least one QTL in its genome that leads to its fruits comprising higher levels of anthocyanins when compared to fruits produced by a tomato plant not carrying said QTL in its genome, wherein said fruits are not purple at the red-ripe harvest stage. A tomato plant of the invention may also comprise all QTLs, each either in homozygous or heterozygous form. The invention further relates to progeny of the plant, propagation material for the plant and to markers for identifying the QTLs and their use.

Compositions and methods are provided for the use of pollen-inhibitor genes and/or color marker genes in accelerated trait introgression. Compositions and methods are also provided for introducing a pollen-inhibitor gene and/or a color marker gene in close proximity to a trait locus of interest. Breeding methods and methods for selecting plants comprising a trait locus of interest in close proximity to at least one pollen-inhibitor gene and/or color marker gene are also disclosed. The methods and compositions employ at least one pollen-inhibitor gene and/or color marker gene to provide an effective system for accelerated trait introgression in the genome of a plant.

The present disclosure provides for unique onion plants with disease resistance and desirable bulb color and their progeny. Such plants may comprise an introgressed QTL associated with multiple disease resistance coupled with a desirable bulb color. In certain aspects, compositions, including distinct polymorphic molecular markers, and methods for producing, breeding, identifying, selecting, and the like of plants or germplasm with disease resistance and/or desirable bulb color are provided.

Systems and methods that integrate breeding and agronomy by employing genotype (G) by environment (E) by management (M) practice to improve synchronized breeding for crop yield gain are provided. Methods to perform G×E×M through machine learning, simulation, crop models, quantitative models and other prediction techniques are provided.

Systems and methods that integrate breeding and agronomy by employing genotype (G) by environment (E) by management (M) practice to improve synchronized breeding for crop yield gain are provided. Methods to perform G×E×M through machine learning, simulation, crop models, quantitative models and other prediction techniques are provided.

This invention describes a new, high-efficiency method of selecting and advancing pollen donator strains in a breeding or product advancement program, wherein the pollen donator strains are specifically selected to maximize product attributes. Embodiments of this invention relate to the use of a mix of pollen including a cross-pollination source and self-pollen, allowing for single-plant performance comparisons. The comparisons of products from the single plant or less experimental unit allow for the selection of those pollen donator strains that maximize desirable results.

The present invention relates to non-transgenic and transgenic plants, preferably crop plants, comprising at least one mutation of the KINTEOCHORE NULL2 (KNL2) protein, especially a mutation causing a substitution of an amino acid within the KNL2 protein, preferably within the C-terminal region of the KNL2 protein, which preferably have the biological activity of a haploid inducer. Further, the present invention provides methods of generating the plants of the present invention and haploid and double haploid plants obtainable by crossing the plants of the present invention with wildtype plants as well as methods of facilitating cytoplasm exchange.

The present disclosure provides Capsicum annuum plants exhibiting increased resistance to Leveillula taurica. Such plants comprise novel introgressed genomic regions associated with disease resistance on chromosome 6. In certain aspects, compositions and methods for producing, breeding, identifying, and selecting plants or germplasm with an increased disease resistance phenotype are provided.