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Metabolomic and transcriptomic insights into how cotton fiber transitions to secondary wall synthesis, represses lignification, and prolongs elongation.

Tuttle JR, Nah G, Duke MV, Alexander DC, Guan X, Song Q, Chen ZJ, Scheffler BE, Haigler CH - BMC Genomics (2015)

Bottom Line: Oxidative stress was lower in the fiber of G. barbadense cv Phytogen 800 as compared to G. hirsutum cv Deltapine 90.Correspondingly, the G. barbadense cultivar had enhanced capacity for management of reactive oxygen species during its prolonged elongation period, as indicated by a 138-fold increase in ascorbate concentration at 28 DPA.The data showed how lignification can be transcriptionally repressed during secondary cell wall synthesis, and they implicated enhanced capacity to manage reactive oxygen species through the ascorbate-glutathione cycle as a positive contributor to fiber length.

View Article: PubMed Central - PubMed

Affiliation: Department of Crop Science, North Carolina State University, Raleigh, NC, 27695, USA. jrtuttle@ncsu.edu.

ABSTRACT

Background: The morphogenesis of single-celled cotton fiber includes extreme elongation and staged cell wall differentiation. Designing strategies for improving cotton fiber for textiles and other uses relies on uncovering the related regulatory mechanisms. In this research we compared the transcriptomes and metabolomes of two Gossypium genotypes, Gossypium barbadense cv Phytogen 800 and G. hirsutum cv Deltapine 90. When grown in parallel, the two types of fiber developed similarly except for prolonged fiber elongation in the G. barbadense cultivar. The data were collected from isolated fibers between 10 to 28 days post anthesis (DPA) representing: primary wall synthesis to support elongation; transitional cell wall remodeling; and secondary wall cellulose synthesis, which was accompanied by continuing elongation only in G. barbadense fiber.

Results: Of 206 identified fiber metabolites, 205 were held in common between the two genotypes. Approximately 38,000 transcripts were expressed in the fiber of each genotype, and these were mapped to the reference set and interpreted by homology to known genes. The developmental changes in the transcriptomes and the metabolomes were compared within and across genotypes with several novel implications. Transitional cell wall remodeling is a distinct stable developmental stage lasting at least four days (18 to 21 DPA). Expression of selected cell wall related transcripts was similar between genotypes, but cellulose synthase gene expression patterns were more complex than expected. Lignification was transcriptionally repressed in both genotypes. Oxidative stress was lower in the fiber of G. barbadense cv Phytogen 800 as compared to G. hirsutum cv Deltapine 90. Correspondingly, the G. barbadense cultivar had enhanced capacity for management of reactive oxygen species during its prolonged elongation period, as indicated by a 138-fold increase in ascorbate concentration at 28 DPA.

Conclusions: The parallel data on deep-sequencing transcriptomics and non-targeted metabolomics for two genotypes of single-celled cotton fiber showed that a discrete developmental stage of transitional cell wall remodeling occurs before secondary wall cellulose synthesis begins. The data showed how lignification can be transcriptionally repressed during secondary cell wall synthesis, and they implicated enhanced capacity to manage reactive oxygen species through the ascorbate-glutathione cycle as a positive contributor to fiber length.

No MeSH data available.


Related in: MedlinePlus

Expression patterns of genes encoding secondary wall related transcription factors in Gb and Gh fibers. The heat map parameters are explained in the legend of Fig. 6
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Fig7: Expression patterns of genes encoding secondary wall related transcription factors in Gb and Gh fibers. The heat map parameters are explained in the legend of Fig. 6

Mentions: The genetic program for cotton fiber SCW synthesis resembles the ancient hierarchical gene network that regulates the differentiation of sclerenchyma cells [6, 15, 76, 77]. However, unlike those cell types in the plant body, cotton fiber represses hemicellulose, protein, and lignin biosynthesis during SCW synthesis so that cellulose becomes predominant. Our data show that cotton fiber expresses 92 primary loci that are homologous to 45 transcriptional regulators of Arabidopsis sclerenchyma cell differentiation [19, 20] (Additional file 17). Of these, 39 cotton homologs have fold-change ≥2 between 10 to 28 DPA in either Gh or Gb fiber, and the expression patterns are highly similar in both genotypes (Fig. 7).Fig. 7


Metabolomic and transcriptomic insights into how cotton fiber transitions to secondary wall synthesis, represses lignification, and prolongs elongation.

Tuttle JR, Nah G, Duke MV, Alexander DC, Guan X, Song Q, Chen ZJ, Scheffler BE, Haigler CH - BMC Genomics (2015)

Expression patterns of genes encoding secondary wall related transcription factors in Gb and Gh fibers. The heat map parameters are explained in the legend of Fig. 6
© Copyright Policy - open-access
Related In: Results  -  Collection

License 1 - License 2
Show All Figures
getmorefigures.php?uid=PMC4482290&req=5

Fig7: Expression patterns of genes encoding secondary wall related transcription factors in Gb and Gh fibers. The heat map parameters are explained in the legend of Fig. 6
Mentions: The genetic program for cotton fiber SCW synthesis resembles the ancient hierarchical gene network that regulates the differentiation of sclerenchyma cells [6, 15, 76, 77]. However, unlike those cell types in the plant body, cotton fiber represses hemicellulose, protein, and lignin biosynthesis during SCW synthesis so that cellulose becomes predominant. Our data show that cotton fiber expresses 92 primary loci that are homologous to 45 transcriptional regulators of Arabidopsis sclerenchyma cell differentiation [19, 20] (Additional file 17). Of these, 39 cotton homologs have fold-change ≥2 between 10 to 28 DPA in either Gh or Gb fiber, and the expression patterns are highly similar in both genotypes (Fig. 7).Fig. 7

Bottom Line: Oxidative stress was lower in the fiber of G. barbadense cv Phytogen 800 as compared to G. hirsutum cv Deltapine 90.Correspondingly, the G. barbadense cultivar had enhanced capacity for management of reactive oxygen species during its prolonged elongation period, as indicated by a 138-fold increase in ascorbate concentration at 28 DPA.The data showed how lignification can be transcriptionally repressed during secondary cell wall synthesis, and they implicated enhanced capacity to manage reactive oxygen species through the ascorbate-glutathione cycle as a positive contributor to fiber length.

View Article: PubMed Central - PubMed

Affiliation: Department of Crop Science, North Carolina State University, Raleigh, NC, 27695, USA. jrtuttle@ncsu.edu.

ABSTRACT

Background: The morphogenesis of single-celled cotton fiber includes extreme elongation and staged cell wall differentiation. Designing strategies for improving cotton fiber for textiles and other uses relies on uncovering the related regulatory mechanisms. In this research we compared the transcriptomes and metabolomes of two Gossypium genotypes, Gossypium barbadense cv Phytogen 800 and G. hirsutum cv Deltapine 90. When grown in parallel, the two types of fiber developed similarly except for prolonged fiber elongation in the G. barbadense cultivar. The data were collected from isolated fibers between 10 to 28 days post anthesis (DPA) representing: primary wall synthesis to support elongation; transitional cell wall remodeling; and secondary wall cellulose synthesis, which was accompanied by continuing elongation only in G. barbadense fiber.

Results: Of 206 identified fiber metabolites, 205 were held in common between the two genotypes. Approximately 38,000 transcripts were expressed in the fiber of each genotype, and these were mapped to the reference set and interpreted by homology to known genes. The developmental changes in the transcriptomes and the metabolomes were compared within and across genotypes with several novel implications. Transitional cell wall remodeling is a distinct stable developmental stage lasting at least four days (18 to 21 DPA). Expression of selected cell wall related transcripts was similar between genotypes, but cellulose synthase gene expression patterns were more complex than expected. Lignification was transcriptionally repressed in both genotypes. Oxidative stress was lower in the fiber of G. barbadense cv Phytogen 800 as compared to G. hirsutum cv Deltapine 90. Correspondingly, the G. barbadense cultivar had enhanced capacity for management of reactive oxygen species during its prolonged elongation period, as indicated by a 138-fold increase in ascorbate concentration at 28 DPA.

Conclusions: The parallel data on deep-sequencing transcriptomics and non-targeted metabolomics for two genotypes of single-celled cotton fiber showed that a discrete developmental stage of transitional cell wall remodeling occurs before secondary wall cellulose synthesis begins. The data showed how lignification can be transcriptionally repressed during secondary cell wall synthesis, and they implicated enhanced capacity to manage reactive oxygen species through the ascorbate-glutathione cycle as a positive contributor to fiber length.

No MeSH data available.


Related in: MedlinePlus