棉纤维发育响应高温胁迫的关键时间窗口

以温度弱敏感性棉花品种(科棉1号)和温度敏感性棉花品种(苏棉15)为材料,在人工气候室模拟自然温周期设置高温(34 ℃\[38/30 ℃\],HT)和对照(26 ℃\[30/22 ℃\],CK)2个温度处理,研究了花铃期不同时段进行高温胁迫后纤维发育重要相关物质的变化及其与纤维品质的关系.结果表明： 在花后不同时间开始高温胁迫持续处理5 d,苏棉15纤维长度、纤维比强度、马克隆值响应高温胁迫的关键时间窗口分别为花后0～18.3 d,花后10.9～26.1 d和花后10.5～34.0 d.因此,花后11～18 d左右是棉花综合纤维品质形成响应高温胁迫的关键时间窗口.在关键时间窗口对棉花进行高温处理5 d后,苏棉15纤维中的蔗糖含量相对常温条件下呈先降低后增加的变化趋势,胼胝质含量上升,纤维素含量下降4.2%,纤维长度变短(最大变幅为23.3%),纤维比强度上升(最大变幅为4.3%),马克隆值下降(最大变幅为10.5%)并偏离最适范围,纤维品质变差.科棉1号的上述纤维发育主要相关物质含量及纤维品质与苏棉15变化趋势一致、最敏感时间相近,仅变化幅度相对较小.     

天然棕色棉纤维色素光谱学特性及其化学结构初步推断

在纯化棕色棉纤维色素的基础上, 测定了天然棕色棉纤维色素的紫外-可见光谱(UV光谱)、红外光谱(IR光谱)以及分析了pH值、浓度、诊断试剂对天然棕色棉纤维色素UV光谱的影响, 发现天然棕色棉纤维色素UV光谱随着pH值和浓度不同而变化, 诊断试剂对纤维色素UV光谱也有影响, 但并不符合黄酮类化合物对诊断试剂的反应规律, 红外光谱的主要吸收波数是3 554、3 477、3 414、3 289、1 638、1 618、1 386、1 073、617、478 cm-1。结合化学性质鉴定, 以及和已知的白色棉种皮色素比较, 初步推断棕色棉色素的化学结构, 认为棕色棉纤维中的色素是由单宁物质氧化形成的醌类化合物。最后解释了棕色棉纤维 具有颜色是因为棉纤维发育后期缩合单宁接触空气后氧化的结果。     

天然棕色棉纤维色素光谱学特性及其化学结构初步推断

在纯化棕色棉纤维色素的基础上,测定了天然棕色棉纤维色素的紫外-可见光谱（UV光谱）、红外光谱（IR光谱）以及分析了pH值、浓度、诊断试剂对天然棕色棉纤维色素UV光谱的影响,发现天然棕色棉纤维色素UV光谱随着pH值和浓度不同而变化,诊断试剂对纤维色素UV光谱也有影响,但并不符合黄酮类化合物对诊断试剂的反应规律,红外光谱的主要吸收波数是3554、3477、3414、3289、1638、1618、1386、1073、617、478cm^-1。结合化学性质鉴定,以及和已知的白色棉种皮色素比较。初步推断棕色棉色素的化学结构,认为棕色棉纤维中的色素是由单宁物质氧化形成的醌类化合物。最后解释了棕色棉纤维具有颜色是因为棉纤维发育后期缩合单宁接触空气后氧化的结果。     

Regulation of cotton fiber elongation by xyloglucan endotransglycosylase/hydrolase genes

Ligon lintless mutant (li1li1) with super-short fibers (5-8 mm in length) and its wild type (Li1Li1) with normal fibers (30 mm in length) were used to study the function of xyloglucan endotransglycosylase/hydrolase (XTH) genes during fiber elongation in cotton. Wild-type cotton attained the fiber elongation stage earlier (5 days post-anthesis, DPA), than the Ligon lintless mutant (12 DPA) with a higher fiber elongation velocity of about 1.76 mm/day. Xyloglucan contents in Ligon lintless mutant fibers were 5-fold higher than the wild type during 9-15 DPA. It was also observed that the activity of XTH in wild-type cotton fibers was about 2-fold higher than that of the Ligon lintless mutant with a peak at 12 DPA. DNA blot analysis indicated that the XTH gene in the Ligon lintless mutant and its wild type belonged to a multiple allelic series. However, RNA blot analysis and quantitative real-time PCR exhibited an earlier expression (10 DPA) of XTH in wild type as compared to delayed (15 DPA) expression in the Ligon lintless mutant. The study also revealed that 9-15 DPA might be a key phase for upregulation of fiber elongation via increasing XTH activity. Higher XTH activity can cleave down the xyloglucan-cellulose chains thus loosening fiber cell wall and promoting fiber cell elongation in wild type as compared to its mutant.     

Simulating in ovulo osmotic potentials and O<Subscript>2</Subscript> tensions normalize growth and pigmentation of immature cotton embryos

Oxygen tensions and osmotic potentials are important physiological factors of plant growth and development. To optimize these variables for cotton (Gossypium hirsutum L.) embryo culture, we quantified dissolved O₂ (dO₂) tensions, osmotic potentials, and pH at several locations in cotton ovules during embryony. Clark O₂ microelectrodes were micromanipulated into intact ovules at an angle lateral to the developing embryo, and dO₂ tensions were determined in integuments, nucelli and embryos. Ovular osmotic potentials and pH were determined from extracted ovule sap using vapor pressure osmometers and pH microelectrodes. Dissolved O₂ tensions near or in embryos decreased from 104 mmol m⁻³ at 5 days post-anthesis (DPA) to 83 mmol m⁻³ at 18 DPA. Osmotic potentials of ovule sap decreased from −0.70 megapascals (MPa) at 2 DPA to −1.12 MPa at 8 DPA but then increased to −0.84 MPa by 17 DPA. Ovule sap pH at 5–17 DPA varied inconsistently and ranged from 5.4 to 6.5. Based on these results, a factorial experiment with two osmotic and three O₂ treatments was designed. Immature embryos of cotton cultivar HS-26 were randomly assigned to the treatment combinations and cultured for 33 days. Oxygen treatments did not affect embryo growth, and there were no differences among treatments with regard to percentage of embryos that progressed to a more advanced stage of embryo development. However, cotyledons of embryos grown without osmotic adjustment were abnormally large, and embryos exposed to these treatments were abnormally brown. Browning was less severe for embryos exposed to low O₂ tensions. Growth and pigmentation were most normal for embryos simultaneously exposed to O₂ tensions and osmotic potentials that best simulated the observed in ovulo conditions.     

Exogenous Jasmonic Acid Inhibits Cotton Fiber Elongation

Jasmonic acid (JA) is a well-characterized phytohormone that acts in various ways to influence plant development. Its role in cotton fiber development, however, has not yet been thoroughly explored. In this study, JA was proven to be an inhibitor of ovule and fiber development in vitro. Continuous exogenous JA application inhibited fiber elongation. This effect was dependent on development stage and dosage. Fibers and ovules at three different stages of development and different JA dosages were compared. The most serious suppression was detected when ovules 1?day before anthesis (–1?DPA) were cultured in medium with 2.5?μM JA. Genes related to trichome and fiber development responded differently to JA treatment between –1?DPA and 1?day post anthesis (1 DPA). JAs (JA and JA-Ile) quantification showed that JAs content was sharply decreased from –1?DPA to 5?DPA ovules, which indicated that JA was negatively associated with fiber elongation in vivo. In addition, gene expression analysis showed the same trend. Our results demonstrate that there was a negative relationship of JA with fiber elongation in vitro and in vivo. These results are meaningful for uncovering the mechanism of fiber elongation in cotton.     

棕色棉与白色棉缩合单宁单体儿茶素动态变化的比较

以棕色棉ANL-1’和白色棉‘泗棉3号’为材料,利用HPLc检测棉纤维发育过程中儿茶素的动态变化,结果表明：棉种皮中的儿茶素含量高于棉纤维中的,各种儿茶素单体（EGC、C、EC、EGCG、GCG、ECG、cG）的含量在花后30d迅速下降,其中在白色棉纤维中的下降幅度最大;棕色棉和白色棉发育期棉纤维中儿茶素存在很大差异,如棕色棉纤维中有Ec、CG,但在白色棉纤维中却没有发现。初步推断棕色棉与白色棉纤维中缩合单宁结构有较大不同,可能导致棉纤维颜色发生差异。     

Polysaccharide and glycoprotein distribution in the epidermis of cotton ovules during early fiber initiation and growth

The cotton fiber is a model system to study cell wall biosynthesis because the fiber cell elongates (∼3 cm in ∼20 days) without mitosis. In this study, developing cotton ovules, examined from 1 day before anthesis (DBA) to 2 days post-anthesis (DPA), that would be difficult to investigate via classical carbohydrate biochemistry were probed using a battery of antibodies that recognize a large number of different wall components. In addition, ovules from these same stages were investigated in three fiberless lines. Most antibodies reacted with at least some component of the ovule, and several of the antibodies reacted specifically with the epidermal layer of cells that may give clues as to the nature of the development of the fibers and the neighboring, nonfiber atrichoblasts. Arabinogalactan proteins (AGPs) labeled the epidermal layers more strongly than other ovular tissue, even at 1 DBA. One of the AGP antibodies, CCRC-M7, which recognizes a 1➔6 galactan epitope of AGPs, is lost from the fiber cells by 2 DPA, although labeling in the atrichoblasts remained strong. In contrast, LM5 that recognizes a 1➔4 galactan RGI side chain is unreactive with sections until the fibers are produced and only the fibers are reactive. Dramatic changes also occur in the homogalacturonans (HGs). JIM5, which recognizes highly de-esterified HGs, only weakly labels epidermal cells of 1 DBA and 0 DPA ovules, but labeling increases in fibers cells, where a pectinaceous sheath is produced around the fiber cell and stronger reaction in the internal and external walls of the atrichoblast. In contrast, JIM7-reactive, highly esterifed HGs are present at high levels in the epidermal cells throughout development. Fiberless lines displayed similar patterns of labeling to the fibered lines, except that all of the cells had the labeling pattern of atrichoblasts. That is, CCRC-M7 labeled all cells of the fiberless lines, and LM5 labeled no cells at 2 DPA. These data indicate that a number of polysaccharides are unique in quantity or presence in the epidermal cell layers, and some of these might be critical participants in the early stages of initiation and elongation of cotton fibers.     

天然彩棉棕色素稳定性及其机理研究

测定了阳光、温度、洗衣粉和金属离子等因素对棕色棉纤维稳定性的影响,并分析了不同pH和不同浓度的纯化色素水溶液色彩的特性,观察纯化色素液与金属离子反应,来探索彩棉棕色素的稳定性机理。实验发现棕色棉纤维色调值位于38度,饱和度为29%,亮度为53%,探明了阳光、温度、洗衣粉和金属离子等因素对棕色棉纤维色彩均产生影响以及pH和浓度对纯化色素的色彩产生影响的规律。     

天然棕色棉色素提取、纯化及其UV光谱研究

选用16种溶剂对天然棕色棉色素进行溶解性试验,发现蒸馏水和pH=9的氢氧化钠溶液是最为经济有效的色素提取溶剂(60℃)。在此基础上,对棕色素进行粗提、纯化、UV光谱测定和化学性质初步鉴定,其中5种纯化方法效果显著,分别是：乙醇沉淀法、重结晶法、铅盐法或铜盐法、纸层析法和柱层析法,并设计了几种纯化方法综合应用的工艺流程。对色素进行UV光谱检测,以218nm附近强吸收、264nm附近弱吸收。根据溶解性试验和化学性质鉴定,推断棕色素化学结构含有双键和酚羟基的存在。     

Up‐regulation of GhTT2‐3A in cotton fibres during secondary wall thickening results in brown fibres with improved quality

Brown cotton fibres are the most widely used naturally coloured raw materials for the eco‐friendly textile industry. Previous studies have indicated that brown fibre pigments belong to proanthocyanidins (PAs) or their derivatives, and fibre coloration is negatively associated with cotton productivity and fibre quality. To date, the molecular basis controlling the biosynthesis and accumulation of brown pigments in cotton fibres is largely unknown. In this study, based on expressional and transgenic analyses of cotton homologs of ArabidopsisPA regulator TRANSPARENT TESTA 2 (TT2) and fine‐mapping of the cotton dark‐brown fibre gene (Lc1), we show that a TT2 homolog, GhTT2‐3A, controls PA biosynthesis and brown pigmentation in cotton fibres. We observed that GhTT2‐3A activated GhbHLH130D, a homolog of ArabidopsisTT8, which in turn synergistically acted with GhTT2‐3A to activate downstream PA structural genes and PA synthesis and accumulation in cotton fibres. Furthermore, the up‐regulation of GhTT2‐3A in fibres at the secondary wall‐thickening stage resulted in brown mature fibres, and fibre quality and lint percentage were comparable to that of the white‐fibre control. The findings of this study reveal the regulatory mechanism controlling brown pigmentation in cotton fibres and demonstrate a promising biotechnological strategy to break the negative linkage between coloration and fibre quality and/or productivity.