A rice cultivar designated FRC-22 is disclosed. The invention relates to the seeds of rice cultivar FRC-22, to the plants of rice FRC-22 and to methods for producing a rice plant produced by crossing the cultivar FRC-22 with itself or another rice variety. The invention further relates to hybrid rice seeds and plants produced by crossing the cultivar FRC-22 with another rice cultivar. The invention further relates to methods for producing a rice plant containing in its genetic material one or more transgenes and to the transgenic plants produced by that method and to methods for producing other rice cultivars derived from rice cultivar FRC-22.

The present disclosure provides a method for treating rice. The method comprises the steps of: providing a domestic rice crop plant and at least one ACCase-inhibiting aryloxyphenoxypropanoate herbicide selected from the group consisting of quizalofop or an ester thereof, haloxyfop, fluazifop or an ester thereof, clodinafop, clodinafop-propargyl, diclofop, and diclofop-methyl; applying an effective amount (measured in g Al/Ha) of the at least one aryloxyphenoxypropanoate herbicide to the domestic rice crop plant, post-emergence; thereby creating a treated rice plant; and growing the resulting treated rice plant.

The present invention relates to rice grain with thickened aleurone. Also provided is a rice plant comprising at least one genetic variation which reduces the activity of at least one ROS1a gene in the plant. Grain of the invention, or aleurone therefrom, has improved nutritional properties, and hence is particularly useful for human and animal feed products.

A method for breeding a small-grain male-sterile rice line and a simple method for producing a hybrid rice seed are provided. The method for breeding the small-grain sterile rice line includes the following steps: crossing a female parent C815S with a male parent Qigui B to obtain a hybrid seed F1; planting the F1 and crossing the F1 with a female parent H155S to obtain a crossed hybrid seed F1′; planting the crossed hybrid seed F1′ to obtain a F2′ generation; planting an individual plant with ideal plant type, strong tillering, plant dwarf and small grain type from the F2′ generation and a F3′ generation, and then directional breeding more than two generations to obtain a seed with more than F5′ generation as the small-grain sterile rice line.

The present invention relates to novel methods for discovering traits and generating cellular systems having improved phenotypes. In particular, the present invention provides methods for the development of plants having agronomically optimized phenotypes by using targeted mutagenesis with few or no off-target effects. Targeted mutagenesis is achieved by the introduction of a base editor complex or of a STEME complex comprising an array of guide RNAs targeting a nucleic acid sequence of interest. The present invention also relates to cellular systems obtained by the methods described herein and to the use of a base editor complex or the STEME complex comprising an array of guide RNAs for generating a cellular system having an agronomically important phenotype and for identification of an agronomically important phenotype.

The present invention relates to plants having resistance to PPO inhibiting herbicides such as the herbicide oxyfluorfen conferred by a loss of function of one or more sulfolipid biosynthesis enzymes involved in the sulfolipid biosynthesis pathway and methods of producing said plants. The invention also relates to methods of producing a plant having resistance to PPO inhibiting herbicides, including but not limited to the herbicide oxyfluorfen, by modulating the expression of one or more sulfolipid biosynthesis genes and/or function of one or more sulfolipid biosynthesis enzymes involved in the sulfolipid biosynthesis pathway, and to plants produced by the methods.

The present disclosure provides a method for treating rice. The method comprises the steps of: providing a domestic rice crop plant and at least one ACCase-inhibiting aryloxyphenoxypropanoate herbicide selected from the group consisting of quizalofop or an ester thereof, haloxyfop, fluazifop or an ester thereof, clodinafop, clodinafop-propargyl, diclofop, and diclofop-methyl; applying an effective amount (measured in g AI/Ha) of the at least one aryloxyphenoxypropanoate herbicide to the domestic rice crop plant, post-emergence; thereby creating a treated rice plant; and growing the resulting treated rice plant.

A method for breeding a new variety of a ratoon rice crop and a cultivation method for the new variety of a ratoon rice crop. The method comprises: breeding a photosensitive variety of a rice crop; growing a ratoon rice crop under conditions of a long photoperiod; and taking corresponding cultivation measures to extend the growth duration of the ratoon rice crop. The invention increases grain yield while also permitting more uniform maturity of a ratoon rice crop. When compared to existing methods for cultivating ratoon rice crops, the invention greatly improves the grain yield and quality of a ratoon rice crop, and has economic and social benefits.

A rice cultivar designated CLL16 is disclosed herein. The present invention provides seeds, plants, and plant parts of or derived from rice cultivar CLL16. Further, it provides methods for producing a rice plant by crossing CLL16 with itself or another rice variety and methods for controlling weeds in the vicinity of a rice plant of rice cultivar CLL16 using an AHAS-inhibiting herbicide. The invention also encompasses any rice seeds, plants, and plant parts produced by the methods disclosed herein, including those in which additional traits have been transferred into CLL16 through the introduction of a transgene or by breeding CLL16 with another rice cultivar.

This invention describes a new method to increase grain yields in any crop plant by modifying pollination to effect an increase in grain yield, a change in grain content or characteristics, a decrease in contamination, or a combination of these attributes. The process involves the intentional delivery of pollen of the male plant at will to designated male-sterile female plants as available either in a preserved pollen bank, or real-time collection from male plants as they become available, in a growth chamber for example. Desired pollen is delivered to fertile females. The delivered pollen.sup.M is in such amounts and fortuitously timed that it preferentially pollinates the females and pollination from neighboring male-fertile plants. The intentional delivery of genetically different pollen will result in increased heterosis and accompanying grain yield increases resulting from increased grain size and the potential to influence grain content and constituents. The invention also permits real-time agronomic decision making in order to maximize grain yield by overcoming biotic and abiotic challenges in the growing season which may or may not have been anticipated.