This disclosure concerns compositions and methods for promoting transcription of a nucleotide sequence in a plant or plant cell, employing a Zea mays GRMZM2G047720 promoter. Some embodiments relate to a Zea mays GRMZM2G047720 promoter that functions in plants to promote transcription of operably linked nucleotide sequences. Other embodiments relate to a Zea mays GRMZM2G047720 3′UTR that functions in plants to terminate transcription of operably linked nucleotide sequences.

The present disclosure relates to regulatory sequences. In particular, the disclosure relates to a regulatory nucleic acid molecule, at least part of which has a transcription initiation function directing expression of an operably associated protein encoding polynucleotide of interest to non-tassel tissue in maize, but not or substantially not to tassel. The disclosure further relates to chimeric genes and expression cassettes comprising the regulatory nucleic acid molecule and to transgenic plants comprising the chimeric genes and expression cassettes.

The invention relates to plants with increased resistance to plant pathogens, wherein the intracellular concentration of inositol pyrophosphate InsP.sub.7 and/or InsP.sub.8 in said plants is increased in comparison to the wild-type plant. In particular, the invention involves plants with increased expression of at least one protein involved in the synthesis of inositol pyrophosphates InsP.sub.7 and/or InsP.sub.8, such as, for example, proteins VIH2 and VIH1. The plants according to the invention are particularly resistant to the following plant pathogens: herbivore insects, for example larvae of agriculturally relevant pests, pathogenic fungi, such as necrotrophic fungi, or other plant pests, such as biotrophic pathogens. The invention further relates to the method for increasing plant resistance to plant pathogens, wherein the intracellular concentration of inositol pyrophosphates InsP.sub.7 and/or InsP.sub.8 is increased in comparison to the wild-type plant.

This disclosure concerns compositions and methods for promoting transcription of a nucleotide sequence in a plant or plant cell, employing a Zea mays GRMZM2G144030 promoter. Some embodiments relate to a Zea mays GRMZM2G144030 promoter that functions in plants to promote transcription of operably linked nucleotide sequences. Other embodiments relate to a Zea mays GRMZM2G144030 3′UTR that functions in plants to terminate transcription of operably linked nucleotide sequences.

This disclosure concerns compositions and methods for promoting transcription of a nucleotide sequence in a plant or plant cell, employing a Zea mays GRMZM2G138258 promoter. Some embodiments relate to a Zea mays GRMZM2G138258 promoter that functions in plants to promote transcription of operably linked nucleotide sequences. Other embodiments relate to a Zea mays GRMZM2G138258 3′UTR that functions in plants to terminate transcription of operably linked nucleotide sequences.

The present invention relates to regulatory sequences. In particular, the invention relates to a regulatory nucleic acid molecule, at least part of which has a transcription initiation function directing expression of an operably associated protein encoding polynucleotide of interest to non-tassel tissue in maize, but not or substantially not to tassel. The invention further relates to chimeric genes and expression cassettes comprising the regulatory nucleic acid molecule and to transgenic plants comprising the chimeric genes and expression cassettes.

The invention provides recombinant DNA molecules and constructs, as well as their nucleotide sequences, useful for modulating gene expression in plants. The invention also provides transgenic plants, plant cells, plant parts, and seeds comprising the recombinant DNA molecules operably linked to heterologous transcribable DNA molecules, as are methods of their use.

The present disclosure identifies new genes which have the potential to increase broad acre yield in crops. This disclosure is based upon our fundamental knowledge of light signal transduction and our understanding of tile roles these genes play in regulating plant growth and development in response to light. Transgenic plants with gain- or loss-of-function of one of these genes, or in combination, are expected to show significant improvements in broad acre yield and stress tolerance.

The invention relates to methods of increasing stomatal function in plants, which as a result leads to an increase in carbon assimilation and/or water use efficiency and ultimately an increase in yield. In particular the methods of the invention relate to the expression of light-gated potassium channels in the stomatal complex. Also described are genetically altered plants characterised by the above phenotype as well as methods of producing such plants.

The present disclosure provides cotton plants with reduced gossypol levels in the seed, and in further embodiments provides cotton plants with increased gossypol levels in the leaves. Also provided are methods for reducing gossypol content in seeds of a cotton plant by down-regulation of CGF2 expression, and in certain embodiments CGF1 and/or CGF3 expression, in the plant, and methods for increasing gossypol content in leaves of a cotton plant by tissue-specific overexpression of CGF2, and in certain embodiments CGF1 and/or CGF3, in the plant.