Barbara A. Triplett

Repeated polyploidization of Gossypium genomes and the evolution of spinnable cotton fibres

Polyploidy often confers emergent properties, such as the higher fibre productivity and quality of tetraploid cottons than diploid cottons bred for the same environments. Here we show that an abrupt five- to sixfold ploidy increase approximately 60 million years (Myr) ago, and allopolyploidy reuniting divergent Gossypium genomes approximately 1–2 Myr ago, conferred about 30–36-fold duplication of ancestral angiosperm (flowering plant) genes in elite cottons (Gossypium hirsutum and Gossypium barbadense), genetic complexity equalled only by Brassica among sequenced angiosperms. Nascent fibre evolution, before allopolyploidy, is elucidated by comparison of spinnable-fibred Gossypium herbaceum A and non-spinnable Gossypium longicalyx F genomes to one another and the outgroup D genome of non-spinnable Gossypium raimondii. The sequence of a G. hirsutum AtDt (in which ‘t’ indicates tetraploid) cultivar reveals many non-reciprocal DNA exchanges between subgenomes that may have contributed to phenotypic innovation and/or other emergent properties such as ecological adaptation by polyploids. Most DNA-level novelty in G. hirsutum recombines alleles from the D-genome progenitor native to its New World habitat and the Old World A-genome progenitor in which spinnable fibre evolved. Coordinated expression changes in proximal groups of functionally distinct genes, including a nuclear mitochondrial DNA block, may account for clusters of cotton-fibre quantitative trait loci affecting diverse traits. Opportunities abound for dissecting emergent properties of other polyploids, particularly angiosperms, by comparison to diploid progenitors and outgroups.

Toward Sequencing Cotton (Gossypium) Genomes

Despite rapidly decreasing costs and innovative technologies, sequencing of angiosperm genomes is not yet undertaken lightly. Generating larger amounts of sequence data more quickly does not address the difficulties of sequencing and assembling complex genomes de novo. The cotton ( Gossypium spp.)

Genome-wide analysis reveals rapid and dynamic changes in miRNA and siRNA sequence and expression during ovule and fiber development in allotetraploid cotton (Gossypium hirsutum L.)

BackgroundCotton fiber development undergoes rapid and dynamic changes in a single cell type, from fiber initiation, elongation, primary and secondary wall biosynthesis, to fiber maturation. Previous studies showed that cotton genes encoding putative MYB transcription factors and phytohormone responsive factors were induced during early stages of ovule and fiber development. Many of these factors are targets of microRNAs (miRNAs) that mediate target gene regulation by mRNA degradation or translational repression.ResultsHere we sequenced and analyzed over 4 million small RNAs derived from fiber and non-fiber tissues in cotton. The 24-nucleotide small interfering RNAs (siRNAs) were more abundant and highly enriched in ovules and fiber-bearing ovules relative to leaves. A total of 31 miRNA families, including 27 conserved, 4 novel miRNA families and a candidate-novel miRNA, were identified in at least one of the cotton tissues examined. Among 32 miRNA precursors representing 19 unique miRNA families identified, 7 were previously reported, and 25 new miRNA precursors were found in this study. Sequencing, miRNA microarray, and small RNA blot analyses showed a trend of repression of miRNAs, including novel miRNAs, during ovule and fiber development, which correlated with upregulation of several target genes tested. Moreover, 223 targets of cotton miRNAs were predicted from the expressed sequence tags derived from cotton tissues, including ovules and fibers. The cotton miRNAs examined triggered cleavage in the predicted sites of the putative cotton targets in ovules and fibers.ConclusionsEnrichment of siRNAs in ovules and fibers suggests active small RNA metabolism and chromatin modifications during fiber development, whereas general repression of miRNAs in fibers correlates with upregulation of a dozen validated miRNA targets encoding transcription and phytohormone response factors, including the genes found to be highly expressed in cotton fibers. Rapid and dynamic changes in siRNAs and miRNAs may contribute to ovule and fiber development in allotetraploid cotton.

Cotton Fiber Chemistry and Technology

Cotton fiber chemistry and technology , Cotton fiber chemistry and technology , مرکز فناوری اطلاعات و اطلاع رسانی کشاورزی

Cotton fiber germin-like protein. I. Molecular cloning and gene expression

The presence of cotton (Gossypium hirsutum L.) fiber transcripts coding for a germin-like protein (GLP) was revealed by differential display analysis in which early stages of cotton fiber development between a wild type line, Texas Marker-1 (TM1) and a near isogenic mutant, Naked Seed (N1) were compared. Transcripts of the cotton GLP (GhGLP1) accumulated specifically in TM1, but did not accumulate in the mutant although the GhGLP1 gene was present in both lines. The deduced protein sequence of GhGLP1 is similar to Prunus persica auxin-binding proteins, a barley ADP-glucose pyrophosphatase/phosphodiesterase and two different classes of hydrogen peroxide-producing enzymes: wheat germin oxalate oxidase and moss extracellular Mn-superoxide dismutase. Cotton GLPs constitute a multigene family like those of Arabidopsis, rice, soybean, and barley. GhGLP1 transcripts accumulated to their highest levels during the period of fiber expansion, followed by a sharp decline when the rate of cell expansion decreased. While germins and GLPs appear to be involved in defense mechanisms in some plants, both biotic and abiotic stress down-regulated the expression of GhGLP1. Numerous functions have been proposed for dicot GLPs. However, to date, there is little direct evidence for how these proteins function in vivo. The association of maximal GhGLP1 expression with stages of maximal cotton fiber elongation suggests that some GLPs may be important for cell wall expansion.

Changes in the Accumulation of [alpha]- and [beta]-Tubulin Isotypes during Cotton Fiber Development

The expression of [alpha]- and [beta]-tubulin proteins in developing fibers and several other tissues of cotton (Gossypium hirsutum, cv Texas Marker 1) have been analyzed by immunoblots of one- and two-dimensional gels utilizing anti-tubulin antibodies as probes. As a percentage of total protein, fibers had greater amounts of tubulin than did hypocotyls, roots, leaves, or cotyledons. Both [alpha]- and [beta]-tubulin, having apparent molecular masses of approximately 50 kD and isoelectric points between pH 5 and pH 6, were resolved on a single two-dimensional gel. Under the conditions used, [alpha]-tubulin was less acidic in the isoelectric focusing dimension and migrated slightly faster in the sodium dodecyl sulfate dimension than did [beta]-tubulin. Nine [alpha]-tubulin isotypes that formed two distinct groups were identified on immunoblots of two-dimensional gels. The three most abundant [alpha]-tubulin isotypes were common to all tissues examined. Seven distinct [beta]-tubulin isotypes were also identified. Although their level of accumulation differed, four of the [beta]-tubulin isotypes were common to all tissues. Preferential accumulation of isotypes was more apparent in fibers than in the other tissues examined. Two [alpha]-tubulin isotypes and two [beta]-tubulin isotypes showed preferential accumulation in 10- and 20-d postanthesis fibers, respectively.

Analysis of cell-wall polymers during cotton fiber development

Although the fibers of cotton (Gossypium hirsutum L.) are single cells with a secondary wall composed primarily of cellulose, the cell-wall polymers of the fibers are technically difficult to characterize with respect to molecular weights. This limitation hinders understanding how the fiber wall composition changes during development, particularly with respect to genotypic variations, and how the molecular composition is related to physical properties. We analyzed cell-wall polymers from cotton fibers (cultivar, Texas Marker-1) at several developmental stages (8–60 days post-anthesis; DPA) by gel-permeation chromatography of components soluble in dimethyl acetamide and lithium chloride. This procedure solubilizes fiber cell-wall components directly without prior extraction or derivatization, processes that could lead to degradation of high-molecular-weight components. Cellwall polymers from fibers at primary cell-wall stages had lower molecular weights than the cellulose from fibers at the secondary wall stages; however, the high-molecularweight cellulose characteristic of mature cotton was detected as early as 8 DPA. High-molecular-weight material decreased during the period of 10–18 DPA with concomitant increase in lower-molecular-weight wall components, possibly indicating hydrolysis during the later stages of elongation.

Cu/Zn superoxide dismutases in developing cotton fibers: evidence for an extracellular form

Hydrogen peroxide and other reactive oxygen species are important signaling molecules in diverse physiological processes. Previously, we discovered superoxide dismutase (SOD) activity in extracellular protein preparations from fiber-bearing cotton (Gossypium hirsutum L.) seeds. We show here, based on immunoreactivity, that the enzyme is a Cu/Zn-SOD (CSD). Immunogold localization shows that CSD localizes to secondary cell walls of developing cotton fibers. Five cotton CSD cDNAs were cloned from cotton fiber and classified into three subfamilies (Group 1: GhCSD1; Group 2: GhCSD2a and GhCSD2b; Group 3: GhCSD3 and GhCSD3s). Members of Group 1 and 2 are expressed throughout fiber development, but predominant during the elongation stage. Group 3 CSDs are also expressed throughout fiber development, but transiently increase in abundance at the transition period between cell elongation and secondary cell wall synthesis. Each of the three GhCSDs also has distinct patterns of expression in tissues other than fiber. Overexpression of cotton CSDs fused to green fluorescent protein in transgenic Arabidopsis demonstrated that GhCSD1 localizes to the cytosol, GhCSD2a localizes to plastids, and GhCSD3 is translocated to the cell wall. Subcellular fractionation of proteins from transgenic Arabidopsis seedlings confirmed that only c-myc epitope-tagged GhCSD3 co-purifies with cell wall proteins. Extracellular CSDs have been suggested to be involved in lignin formation in secondary cell walls of other plants. Since cotton fibers are not lignified, we suggest that extracellular CSDs may be involved in other plant cell wall growth and development processes.

Near-isogenic cotton germplasm lines that differ in fiber-bundle strength have temporal differences in fiber gene expression patterns as revealed by comparative high-throughput profiling

Gene expression profiles of developing cotton (Gossypium hirsutum L.) fibers from two near-isogenic lines (NILs) that differ in fiber-bundle strength, short-fiber content, and in fewer than two genetic loci were compared using an oligonucleotide microarray. Fiber gene expression was compared at five time points spanning fiber elongation and secondary cell wall (SCW) biosynthesis. Fiber samples were collected from field plots in a randomized, complete block design, with three spatially distinct biological replications for each NIL at each time point. Microarray hybridizations were performed in a loop experimental design that allowed comparisons of fiber gene expression profiles as a function of time between the two NILs. Overall, developmental expression patterns revealed by the microarray experiment agreed with previously reported cotton fiber gene expression patterns for specific genes. Additionally, genes expressed coordinately with the onset of SCW biosynthesis in cotton fiber correlated with gene expression patterns of other SCW-producing plant tissues. Functional classification and enrichment analysis of differentially expressed genes between the two NILs revealed that genes associated with SCW biosynthesis were significantly up-regulated in fibers of the high-fiber quality line at the transition stage of cotton fiber development. For independent corroboration of the microarray results, 15 genes were selected for quantitative reverse transcription PCR analysis of fiber gene expression. These analyses, conducted over multiple field years, confirmed the temporal difference in fiber gene expression between the two NILs. We hypothesize that the loci conferring temporal differences in fiber gene expression between the NILs are important regulatory sequences that offer the potential for more targeted manipulation of cotton fiber quality.

Characterization of cell-wall polymers from cotton ovule culture fiber cells by gel permeation chromatography

SummaryCotton (Gossypium hirsutum, Texas Marker-1) fiber cells originating from ovule culture have been analyzed by gel permeation chromatography of dimethyl acetamide/lithium chloride-soluble components and compared within planta-grown fibers. The profile of cell-wall polymer molecular weights indicated that fibers grown for 21 d in culture more closely resembled fibers growingin planta for 30 d post-anthesis than fully mature fibers. The weight average molecular weight was 3 400 000 and number average molecular weight of polymers from ovule culture fibers was 109 000. Analysis of the polymer weight fraction distribution revealed that ovule culture fibers were similar to 30 d post-anthesis immature fibers but lacked a low molecular weight (log M 3–4) polymer fraction. Assessment of the polymer branching frequency showed that ovule culture fibers were intermediate in branching between 30 d post-anthesis fiber and maturein planta fiber. In summary, polymers deposited in cell walls of ovule culture fibers appear to grossly mimic the polymers accumulated during normal fiber biogenesisin planta, yet subtle differences may explain why ovule culture fibers rarely reach their full genetic potential in length.