Abstract
Two class I family teosinte branched1/cycloidea/proliferating cell factor1 (TCP) proteins from allotetraploid cotton are involved in cotton fiber cell differentiation and elongation and root hair development. However, the biological function of most class II TCP proteins is unclear. This study sought to reveal the characteristics and functions of the sea-island cotton class II TCP gene GbTCP4 by biochemical, genetic, and molecular biology methods. GbTCP4 protein localizes to nuclei, binding two types of TCP-binding cis-acting elements, including the one in its promoter. Expression pattern analysis revealed that GbTCP4 is widely expressed in tissues, with the highest level in flowers. GbTCP4 is expressed at different fiber development stages and has high transcription in fibers beginning at 5 days post anthesis (DPA). GbTCP4 overexpression increases primary root hair length and density and leaf and stem trichomes in transgenic Arabidopsis relative to wild-type plants (WT). GbTCP4 binds directly to the CAPRICE (CPC) promoter, increasing CPC transcript levels in roots and reducing them in leaves. Compared with WT plants, lignin content in the stems of transgenic Arabidopsis overexpressing GbTCP4 increased, and AtCAD5 gene transcript levels increased. These results suggest that GbTCP4 regulates trichome formation and root hair development in Arabidopsis and may be a candidate gene for regulating cotton fiber elongation.
Highlights
Cotton is one of the most important fiber crops worldwide
Arabidopsis overexpressing GbTCP4 increased, and AtCAD5 gene transcript levels increased. These results suggest that GbTCP4 regulates trichome formation and root hair development in Arabidopsis and may be a candidate gene for regulating cotton fiber elongation
Cotton fiber quality is measured in terms of length and strength, which mainly depend on the cell elongation and secondary cell wall biosynthesis growth stages [3]
Summary
Cotton fiber quality directly affects the market competitiveness of textiles [1]. Fiber development can be divided into four distinct yet overlapping stages: initiation, cell elongation, secondary cell wall biosynthesis, and maturation [1,2]. Cotton fiber quality is measured in terms of length and strength, which mainly depend on the cell elongation and secondary cell wall biosynthesis growth stages [3]. Upland cotton (Gossypium hirsutum L.) and sea-island cotton (G. barbadense L.), which are widely grown, are allotetraploid cultivars [4]. Sea-island cotton fiber is superior to upland cotton in length, fineness, and strength [3]. Exploring the molecular mechanisms involved in fiber development in sea-island cotton can provide useful information to generate superior fiber quality traits of upland cotton species through molecular breeding [6]
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