A global assembly of cotton ESTs.

Approximately 185,000 Gossypium EST sequences comprising >94,800,000 nucleotides were amassed from 30 cDNA libraries constructed from a variety of tissues and organs under a range of conditions, including drought stress and pathogen challenges. These libraries were derived from allopolyploid cotton (Gossypium hirsutum; A(T) and D(T) genomes) as well as its two diploid progenitors, Gossypium arboreum (A genome) and Gossypium raimondii (D genome). ESTs were assembled using the Program for Assembling and Viewing ESTs (PAVE), resulting in 22,030 contigs and 29,077 singletons (51,107 unigenes). Further comparisons among the singletons and contigs led to recognition of 33,665 exemplar sequences that represent a nonredundant set of putative Gossypium genes containing partial or full-length coding regions and usually one or two UTRs. The assembly, along with their UniProt BLASTX hits, GO annotation, and Pfam analysis results, are freely accessible as a public resource for cotton genomics. Because ESTs from diploid and allotetraploid Gossypium were combined in a single assembly, we were in many cases able to bioinformatically distinguish duplicated genes in allotetraploid cotton and assign them to either the A or D genome. The assembly and associated information provide a framework for future investigation of cotton functional and evolutionary genomics.

Fusarium wilt (Fusarium oxysporum f. sp. vasinfectum) genes expressed during infection of cotton (Gossypium hirsutum)dagger.

SUMMARY We sought to identify Fusarium oxysporum f. sp. vasinfectum (Fov) genes that may be associated with pathogenicity. Initially we utilized microarray and Q-PCR technology to identify Fov genes expressed in root and hypocotyl tissues during a compatible infection of cotton. We identified 218 fungal clones representing 174 Fov non-redundant genes as expressed in planta. The majority of the expressed sequences were expressed in infected roots, with only six genes detected in hypocotyl tissue. The Fov genes identified were predominately of unknown function or associated with fungal growth and energy production. We then analysed the expression of the identified fungal genes in infected roots and in saprophytically grown mycelia and identified 11 genes preferentially expressed in plant tissue. A putative oxidoreductase gene (with homology to AtsC) was found to be highly preferentially expressed in planta. In Agrobacterium tumefaciens, AtsC is associated with virulence. Inoculation of a susceptible and a partially resistant cotton cultivar with either a pathogenic or a non-pathogenic isolate of Fov revealed that the expression of the Fov AtsC homologue was associated with pathogenicity and disease symptom formation.

Gene expression profile changes in cotton root and hypocotyl tissues in response to infection with Fusarium oxysporum f. sp. vasinfectum.

Microarray analysis of large-scale temporal and tissue-specific plant gene expression changes occurring during a susceptible plant-pathogen interaction revealed different gene expression profile changes in cotton root and hypocotyl tissues. In hypocotyl tissues infected with Fusarium oxysporum f. sp. vasinfectum, increased expression of defense-related genes was observed, whereas few changes in the expression levels of defense-related genes were found in infected root tissues. In infected roots, more plant genes were repressed than were induced, especially at the earlier stages of infection. Although many known cotton defense responses were identified, including induction of pathogenesis-related genes and gossypol biosynthesis genes, potential new defense responses also were identified, such as the biosynthesis of lignans. Many of the stress-related gene responses were common to both tissues. The repression of drought-responsive proteins such as aquaporins in both roots and hypocotyls represents a previously unreported response of a host to pathogen attack that may be specific to vascular wilt diseases. Gene expression results implicated the phytohormones ethylene and auxin in the disease process. Biochemical analysis of hormone level changes supported this observation.

Large-scale expression and purification of high-molecular-weight glutenin subunits.

The high-molecular-weight glutenin subunits (HMW-GSs) are considered to be one of the most important components of wheat gluten, contributing to the unique viscoelastic properties of wheat dough. The HMW-GSs are highly homologous in sequence and structure and a mixture of subunits is usually present in wheat flours. Consequently, it is difficult to purify these proteins separately in appreciable amounts. Expression in heterologous systems provides a clear opportunity to produce large amounts of single HMW-GS proteins, amounts (up to 100 mg) which are required for in vitro analysis of these proteins. However, since the first expression studies of HMW-GSs, over 10 years ago, this technology has not been widely utilized. Previous studies have been analytical or small scale (5-100 ml) and in most cases only partial purity was obtained. In the present paper, we describe in detail the expression of the HMW-GSs Glu1-Dx2, Dx5, Dy10, and Dy12 for the first time on a large scale, producing up to 100 mg of target protein from a 2-liter bacterial culture, using a Biostat fermenter. Our results include optimization of expression conditions to increase yield and stability of proteins. Results also include localization, differences between x- and y-type expression and small-scale versus large-scale expression. We also developed a large-scale purification procedure. The bacterially expressed proteins have the same molecular weight on SDS-PAGE and the same retention times on RP-HPLC as their native counterparts extracted from flour. Functionality tests, on the bacterially produced proteins, have shown a clear correlation with the equivalent native proteins from flour. These results provide a clear opportunity to produce protein in amounts necessary for more detailed studies of the structure and function of the HMW-GSs and glutenin polymers on dough development and quality.