Genetic analysis and identification of candidate genes for two spotted-leaf mutants (spl101 and spl102) in rice.

Spotted-leaf mutants form spots in leaves or leaf sheaths under normal condition. The spotted-leaf phenotypes are similar to hypersensitive reaction of plants attacked by pathogen. Identification and characterization of the spotted-leaf mutants are helpful for understanding the mechanisms of resistance to plant diseases. Here, we identify two spotted-leaf mutants spl101 and spl102 from an EMS-treated elite japonica cultivar KYJ (Kuanyejing). spl101 and spl102 form serious spots at the late heading stage. Genetic analyses show that the spotted-leaf phenotypes of both spl101 and spl102 are caused by a single recessive mutation, respectively. By employing the Mutmap method, we reveal that both spl101 and spl102 contain mutations in the OsEDR1 gene. The spl101 mutation occurs in the 5°-splicing site of the 6th intron of OsEDR1, which causes abnormal recognition of the 6th intron and leads to the frameshift mutation. The spl102 mutant contains a mutation in the tenth exon of OsEDR1, resulting in an amino acid change from the phenylalanine (F) to the cysteine (C). OsEDR1 has been reported to regulate pathogen-resistant reaction, and loss of OsEDR1 function produces similar phenotypes to those of spl101 and spl102. Here, two newly identified alleles of OsEDR1 will be benefit for further understanding the molecular mechanisms of the OsEDR1 gene in disease resistance, and will be helpful for enriching the rice germplasm resources. In addition, our results also validate the effectiveness of the Mutmap method in cloning the candidate mutations.

[Genetic analysis and identification of candidate genes for a narrow leaf mutant (zy17) in rice].

Control of organ size by cell proliferation and cell expansion is a fundamental process in plant development, but little is known about the genetic and molecular mechanisms that determine organ size in plants. To understand the genetic and molecular mechanisms of organ growth control, we isolate a set of mutants with altered leaf size and identify the narrow leaf mutant, zhaiye 17 (zy17) (zhaiye means narrow leaf in Chinese). zy17 exhibits narrow leaves, slightly short plants, small panicles, reduced panicle branches and decreased grain numbers per panicle compared with the wild type. Our cytological analyses show that the narrow leaf phenotype of zy17 is caused by the reduced number of cells, indicating that ZY17 regulates cell proliferation. Genetic analyses show that the zy17 mutant phenotypes are controlled by a single gene. Using the whole genome resequencing approach and linkage analysis, we identify Os02g22390, Os02g28280 and Os02g29530 as candidate genes. Os02g22390 encodes a retrotransposon protein with the mutation occurring in the intronic region; Os02g28280 encodes a protein with unknown function with a base substitution resulting in non-synonymous mutation; Os02g29530 encodes a protein containing the PFAM domain related to glycosyltransferase, with a 2 bp deletion mutation causing a premature termination. Further studies on these three candidate genes will be helpful for understanding the molecular mechanism of organ size control in rice.