The invention provides a methods and materials for producing and selecting plants with at least one dwarfing-associated phenotype. The methods and materials relate to altering the expression, or activity, of an ARF3 polypeptide in the plant, and selecting plants with altered the expression, or activity, of an ARF3 polypeptide. The invention also provides plants produced or selected by the methods. The methods also involve crossing plants of the invention with other plants to produce further plants with at least one dwarfing-associated phenotype.

Various methods and compositions are provided for identifying and/or selecting a soybean plant or soybean germplasm with one or more preferred or desired reproductive growth phenotypes. In certain embodiments, the method comprises detecting at least one allele of one or more marker locus within or linked to a QTL associated with days to initiation of flowering. In other embodiments, the method additionally comprises detecting at least one allele of one or more marker locus within or linked to a QTL associated with days to maturity. In further embodiments, the method comprises crossing a selected soybean plant with a recurrent soybean parent plant. Further provided herein are marker loci, marker alleles, primers, probes, and kits suitable for identifying and/or selecting soybean plants or soybean germplasms with one or more reproductive growth phenotypes.

Provided herein is the identification and markers and genes associated with day-neutral autoflowering in plants and their use in selecting plants, including Cannabis plants, having autoflowering activity. The markers are useful for breeding autoflowering plants by obtaining nucleic acids, detecting one or more markers that indicate autoflowering activity, and establishing plant lines having such characteristics. Also provided are methods of editing plants to establish plant lines having autoflowering allelic variations.

The present invention relates to methods for controlling hybridization in plants and producing hybrid plants. The present invention also relates to nucleic acids encoding amino acid sequences for self-incompatibility (SI) proteins in plants, and the use thereof for the manipulation of SI, including seed production, in plants, particularly of the Poaceae family. The present invention also relates to kits, compositions, constructs and vectors including such nucleic acids, and related polypeptides, regulatory elements and methods. The present invention also relates to expression of self-gamete recognition genes in plants and to related nucleic acids, constructs, molecular markers and methods.

The present invention provides recombinant DNA constructs, vectors and molecules comprising a polynucleotide sequence encoding a florigenic FT protein operably linked to a vegetative stage promoter, which may also be a meristem-preferred or meristem-specific promoter. Transgenic plants, plant cells and tissues, and plant parts are further provided comprising a polynucleotide sequence encoding a florigenic FT protein. Transgenic plants comprising a florigenic FT transgene may produce more bolls, siliques, fruits, nuts, or pods per node on the transgenic plant, particularly on the main stem of the plant, relative to a control or wild type plant. Methods are further provided for introducing a florigenic FT transgene into a plant, and planting transgenic FT plants in the field including at higher densities. Transgenic plants of the present invention may thus provide greater yield potential than wild type plants and may be planted at a higher density due to their altered plant architecture.

Methods and compositions to modulate maturity of a rice plant are disclosed. The disclosure further discloses compositions, polynucleotide constructs, transformed host cells, plants and seeds exhibiting altered stature characteristics or produce plants that exhibit altered maturity parameters.

Novel sugarcane-derived flowering-inducing genes each encoding a protein comprising the amino acid sequence of SEQ ID NO: 2 or 4 (the ScFT6 gene and the ScZCN16 gene), by which the flowering time is accelerated more slowly than conventionally known flowering-inducing genes, are provided.

The present invention relates to methods of increasing the cold tolerance of a plant or part thereof and/or preventing or inhibiting bolting of a plant, comprising deregulating phloem flux and plants or parts thereof having deregulated phloem flux. The invention also extends to the use of genes for deregulating phloem flux in a plant or part thereof; and/or increasing cold tolerance of a plant or part thereof; and/or preventing or inhibiting bolting in a plant. The invention also provides methods of selecting and/or producing a plant with deregulated phloem flux and/or increased cold tolerance and/or delayed or inhibited bolting. The invention also extends to constructs, isolated polynucleotides and polypeptides which can be used to deregulate phloem flux, plant cells transformed with such constructs, and to plants or parts thereof having deregulated phloem flux.

The disclosure relates to gene edited wheat plants, seeds, and compositions, as well as improvements to wheat plant breeding and methods for creating modifications in wheat plant genomes.

The present disclosure provides the identification of promoters that are preferentially active in tobacco axillary buds. Also provided are tobacco plants comprising reduced or no sucker growth. Also provided are methods and compositions for producing tobacco plants comprising reduced or no sucker growth.