CHIMERIC FLORAL ORGANS1, encoding a monocot-specific MADS box protein, regulates floral organ identity in rice.

The control of floral organ identity by homeotic MADS box genes is well established in eudicots. However, grasses have highly specialized outer floral organs, and the identities of the genes that regulate the highly specialized outer floral organs of grasses remain unclear. In this study, we characterized a MIKC-type MADS box gene, CHIMERIC FLORAL ORGANS (CFO1), which plays a key role in the regulation of floral organ identity in rice (Oryza sativa). The cfo1 mutant displayed defective marginal regions of the palea, chimeric floral organs, and ectopic floral organs. Map-based cloning demonstrated that CFO1 encoded the OsMADS32 protein. Phylogenetic analysis revealed that CFO1/OsMADS32 belonged to a monocot-specific clade in the MIKC-type MADS box gene family. The expression domains of CFO1 were mainly restricted to the marginal region of the palea and inner floral organs. The floral organ identity gene DROOPING LEAF (DL) was expressed ectopically in all defective organs of cfo1 flowers. Double mutant analysis revealed that loss of DL function mitigated some of the defects of floral organs in cfo1 flowers. We propose that the CFO1 gene plays a pivotal role in maintaining floral organ identity through negative regulation of DL expression.

Genetic analysis and fine mapping of a dynamic rolled leaf gene, RL10(t), in rice (Oryza sativa L.).

A dynamically rolled leaf mutant (rl10) was identified from a spontaneous mutation in an Oryza sativa L. subsp. indica line, II-32B. The leaf chlorophyll content of rl10 is higher than that of the wild type. Genetic analysis using 3 F2 segregating populations derived from crosses between rl10 and the rice lines Mian5B, II-32B, and D62B, respectively, confirmed that the rolled leaf trait of rl10 is controlled by a single recessive gene. Of 719 SSR primer pairs that showed polymorphism between D62B and rl10, 151 were adopted to map the RL10(t) gene using an F2 segregating population of the cross rl10 x D62B, which contained 352 recessive plants. RL10(t) was primarily mapped on the long arm of chromosome 9, 5.09 cM from marker RM105 and 5.13 cM from marker RM3912. Using a novel set of 22 primer pairs between RM105 and RM3912, RL10(t) was further mapped between markers rlc3 (0.72 cM in distance) and rlc12 (0.1 cM in distance) using an F2/F3 population containing 1172 recessive individuals. Mapped position analysis and homology analysis of the 20 genes within the 194-kb region between these 2 markers both indicated that a gene encoding a Myb-like domain transcription factor with homology to Arabidopsis KANADI (annotated in PAC clone AP005904) is the most probable candidate for RL10(t). This study enables further investigation of whether KANADI-like Myb genes are involved in leaf polarity modeling in monocots, as they are in dicots.