Discovery and identification of a novel Ligon lintless-like mutant (Lix) similar to the Ligon lintless (Li1) in allotetraploid cotton.

Mutants are a powerful resource for studying gene structure, function, and evolution. In this present study, a novel Ligon lintless-like mutant (Lix), that has short fibers and deformed leaves and stems, was isolated from the progeny of transgenic cottons. The Lix mutant is similar in morphology to the Ligon lintless (Li1) mutant. Genetic analysis and molecular mapping were performed for the Lix and Li1 mutants. These two mutants are monogenic dominant mutants with distorted growth of vegetative and reproductive structures. Seedlings of the dominant homozygote Li 1 Li 1 genotype are lethal, while LixLix plants are viable but show no reproductive growth. Molecular tagging showed that the Lix gene is located on Chr. 04 in a 30.9-cM region spanned by NAU8376 and NAU3469. In a previous study, the Li 1 gene was mapped to Chr. 22, and Chr. 04 and Chr. 22 are homoelogous chromosomes in tetraploid cotton. So, we propose that Lix and Li1 mutants have similar mutated morphology, and Lix is mapped to a homoelogous chromosome carrying Li 1 . The identification and genetic mapping of Lix/Li 1 genes using mutants provides a foundation for isolating these genes. In turn, this will permit studies to elucidate the functional and evolutionary roles for these genes in cotton growth and development.

Molecular evolution and phylogenetic analysis of genes related to cotton fibers development from wild and domesticated cotton species in Gossypium.

The domestication of both diploid and tetraploid cotton species was carried out for fiber utilization. To understand the origin and domestication of fibers, 18 genes related to fiber development were individually cloned and sequenced from 22 different cotton species. Their structures, phylogenetic relationship and molecular evolution were further studied. In the orthologous and homeologous loci of the 18 genes, the sequence and structure of 72.22% were conserved and 27.78% were diverse. Tree topologies constructed based on the combined sequences showed that all 13 D-genome species were congruent with Fryxell's subsection taxonomy, the A- and D-subgenomes independently evolved in the allopolyploid after polyploid formation, and Gossypium raimondii had the closest relationship with all allotetraploids of D-subgenomes. The molecular evolutionary rates revealed approximately equivalent rates among different D-genome species, and purifying selection acted on all genes in the wild D-genome species. Among orthologs and homeologs, the D-subgenomes had higher evolutionary rates than the A-subgenomes in tetraploid cotton species, and the cultivars had higher evolutionary rates than either the semi-domesticated or wild species. Our study revealed that human domestication altered the molecular evolutionary pattern of genes related to fiber development, and Gossypium hirsutum endured greater selective pressures than Gossypium barbadense during the domestication process.