Compositions and methods for modulating male fertility in a plant are provided. Compositions comprise nucleotide sequences, and fragments and variants thereof, which modulate male fertility. Further provided are expression cassettes comprising the male fertility polynucleotides, or fragments or variants thereof, operably linked to a promoter, wherein expression of the polynucleotides modulates the male fertility of a plant. Various methods are provided wherein the level and/or activity of the sequences that influence male fertility is modulated in a plant or plant part. In certain embodiments, the plant is polyploid.

A method for increasing fungal resistance in a plant, a plant part, or a plant cell wherein the method comprises the step of increasing the production and/or accumulation of scopoletin and/or a derivative thereof in the plant, plant part, or plant cell in comparison to a wild type plant, wild type plant part, or wild type plant cell.

A method for increasing fungal resistance in a plant, a plant part, or a plant cell wherein the method comprises the step of increasing the production and/or accumulation of scopoletin and/or a derivative thereof in the plant, plant part, or plant cell in comparison to a wild type plant, wild type plant part, or wild type plant cell.

Transgenic plants that have enhanced yield-related traits, such as increased seed oil production, are produced by genetically engineering the plants to down-regulate the expression of at least one BPM protein. Such transgenic plants can, for example, be cultivated and yield higher seed oil production than control plants which have not been genetically engineered for down regulation of a BPM protein.

Transgenic plants that have enhanced yield-related traits, such as increased seed oil production, are produced by genetically engineering the plants to down-regulate the expression of at least one BPM protein. Such transgenic plants can, for example, be cultivated and yield higher seed oil production than control plants which have not been genetically engineered for down regulation of a BPM protein.

The present invention provides a new plant gene-rice high temperature resistance 1 gene (Rice High Temperature Resistance 1, HTR1) and encoded protein thereof. Also disclosed is the use of the high temperature resistance gene, especially for the enhancement of high-temperature resistance of plants in plant variety improvement and cross breeding.

The present invention provides a new plant gene-rice high temperature resistance 1 gene (Rice High Temperature Resistance 1, HTR1) and encoded protein thereof. Also disclosed is the use of the high temperature resistance gene, especially for the enhancement of high-temperature resistance of plants in plant variety improvement and cross breeding.

This document relates to materials and methods for domesticating oilseed (e.g., pennycress) plants. For example, oilseed plants having reduced seedpod shatter, as well as materials and methods for making and using oilseed plants having reduced seedpod shatter are provided.

This document relates to materials and methods for domesticating oilseed (e.g., pennycress) plants. For example, oilseed plants having reduced seedpod shatter, as well as materials and methods for making and using oilseed plants having reduced seedpod shatter are provided.

A gene LBA5 for regulating lateral shoot angles, growth habits, and a plant architecture of Arachis hypogaea L., and use thereof are provided. In the present disclosure, a major gene LBA5 for controlling lateral shoot angles, growth habits, and a plant architecture of Arachis hypogaea L. is mapped and cloned from Arachis hypogaea L., which includes two homologous genes LBA5b and LBA5a and promoters thereof. The allelic variations of the gene can be selected through crossbreeding and backcrossing to achieve the genetic improvement on an angle between an Arachis hypogaea L. lateral shoot and a main stem. Through a genetic engineering operation for the gene and a change for a promoter sequence of the gene, the function or expression level of this gene in a procumbent Arachis hypogaea L. variety can be adjusted to further regulate an angle between an Arachis hypogaea L. lateral shoot and a main stem.