Molecular Cloning and Analysis of LEA14L2 Gene from Rubber Tree( Hevea brasiliensis Muell. Arg. )

Using an isotig encoding a putative polypeptide with high similarity to Arabidopsis LEA14 as a query, a 613 bp long cDNA was in silico cloned from the transeriptome data of rubber tree. The sequence nominated as HbLEA14L2 contains an ORF of 456 bp with 3 bp 5＇ UTR and 154 bp 3＇ UTR. Subsequently, a 464 bp eDNA and an 834 bp genome sequence containing this ORF was amplified and sequenced. Sequence analysis suggested that HbLEA14L2 has one intron and encodes 151 amino acids with a theoretical molecular weight of 16.55 kDa, isoleetric point of 4.93 and GRAVY value of -0.022, indicating a cytoplasmle localization pattern; HbLEA14L2 protein contains a conserved LEA_2 domain and belongs to LEA_2 subfamily, sharing 91%, 76%, 75%, 72% and 63% similarity with the homologous proteins in castor bean, leafy spurge, poplar, cotton, and Arabidopsis, respectively. Swiss-Model indicated that the tertiary structure of HbLEA14L2 is consisted of one α-helix and seven β-sheets, which was proposed to serve as a regulatory protein to prevent cellular desiccation.

Studies on Rubber (<i>Hevea brasiliensis</i>) Trees Exist Plant Type after Planting and Available Tapping Tree of Rubber Plantation in China

Existing plant types of rubber tree after planting and available tapping tree were investigated, and there were about 28 rubber plantations with different tapping years of 8 varieties “CATAS7-33-97”, “CATAS8-79”, “CATAS7-20-59”, “PR107”, “RRIM600”, “GT1”, “INA873”, “93-114”in South China. The results showed that there were six kinds of existing plant types of rubber tree after planting of rubber plantations, which were available tapping trees, wind damaged trees, cold damaged trees, tapping panel dryness trees, absent trees and weak trees, respectively. These data investigated also showed rubber trees under available tapping, stoppage due to tapping panel dryness, absence, wind damage, cold damage and weakness were counted and calculated and made up for 72.21%, 14.75%, 5.61%, 3.86%, 2.68% and 1.89%. Tapping panel dryness trees, wind damage and absent trees are major factors for the loss of tapping rubber trees in the rubber plantations. Of these investigated varieties, available tapping trees per 100 trees of rubber plantation of “PR107”at the 1st, 12th, 14th, 16th, 20th, 24th tapping year were 96, 67, 70, 75, 66, 46 trees in Hainan planting zone, respectively. Available tapping trees per 100 trees of rubber plantation of “RRIM600”at the 9th, 15th, 20th, 22nd tapping year were 88, 62, 55, 36 trees in Yunnan planting zone, respectively. Available tapping trees per 100 trees of rubber plantation of “93-114” at the 10th, 19th, tapping year were 94, 62 trees in Guangdong planting zone. These results showed that available tapping trees of rubber plantation decreased with increasing tapping age under different planting zones in China.

Exploration and Practice of Rubber Based Agroforestry Complex Systems in China

Agroforestry ecosystems are constructed by simulating natural ecosystems, applying the principles of symbiosis in nature, and organizing multiple plant populations to coexist, while conducting targeted cultivation and structural control scientifically. Rubber agroforestry complex ecosystems aim for sustainable development in terms of industry, ecology, resource utilization, and the livelihoods of producers. Rubber agroforestry complex ecosystems create a complex production structure system that integrates biology, society, and the economy through species combinations. Rubber trees and associated biological components coordinate with each other, mutually promote growth, and yield a variety of products for producers. Cultivation techniques and patterns of rubber agroforestry are essential components of these ecosystems. This study analyzes the production practices of rubber agroforestry complex cultivation, with a focus on the development and characteristics (complexity, systematicity, intensity, and hierarchy) of rubber agroforestry systems using a literature analysis and a survey approach. It explores the types and scales of complex planting, specifications and forms, and major effects of complex cultivation. This study identifies successful rubber agroforestry cultivation patterns and practical techniques, as well as the potential benefits of developing rubber agroforestry cultivation. It also points out the shortcomings in the development of complex planting, including an emphasis on production practices but insufficient theoretical research, a focus on production but inadequate attention to the market, and an emphasis on yield while overlooking the improvement of standards, brands, and added value. There are various complex patterns for young rubber plantations, but relatively fewer for mature plantations. Based on this analysis, this study suggests that future efforts should focus on in-depth research on interspecies and environmental interactions in rubber agroforestry ecosystems, clearly define key roles, accelerate the innovation of development patterns, and strengthen the foundation for development. It recommends promoting and demonstrating successful rubber agroforestry complex patterns and providing technical training, developing product branding for rubber agroforestry patterns, enhancing product value, expanding the application functions of rubber-forest mixed crop products, and establishing a stable and sustainable industry chain. This study provide practical experience and theoretical insights in rubber agroforestry complex systems from China the potential to enrich the knowledge of rubber agroforestry composite systems, provide practical experience to improve the operating income of smallholders, and even promote the sustainable development of rubber plantations.

橡胶/香露兜间作对香露兜香气成分的影响

香露兜是中国热带地区特色香料作物之一,其叶片香气成分含量是鉴定香露兜品质的关键指标。香露兜适宜在遮阴条件下种植,其中在橡胶林下间作香露兜是海南地区常见的栽培模式,但橡胶间作香露兜后对香露兜叶片香气成分的影响仍未探明。本研究拟通过盆栽试验,对比橡胶/香露兜间作处理和香露兜单作条件下土壤理化性质和香露兜叶片香气成分种类与含量的差异。结果表明,橡胶/香露兜间作处理与香露兜单作相比,显著提高土壤容重13.63%,土壤碱解氮含量59.71%,土壤速效磷含量193.03%、土壤速效钾含量9.78%,土壤pH降低1.00(P<0.05);间作和单作处理共检测出10类68种香气成分,间作与单作相比,酮类、呋喃类、呋喃酮类、烃类和酚类的物质种类数量分别减少56.52%、14.29%、33.33%、20.00%、28.57%(P<0.05);尽管呋喃类、烃类和酮类的香气成分含量分别显著减少65.28%、20.88%和69.00%,但醇类、呲咯类、酯类和呋喃酮类香气成分含量分别增加31.50%、597.56%、122.78%、96.89%(P<0.05)。土壤pH降低是香露兜叶片酮类、呋喃类、呋喃酮类、烃类和酚类香气成分组成减少的主要原因;间作模式通过降低pH、提高土壤速效磷和碱解氮含量显著提高醇类、呲咯类、酯类含量,减少呋喃类、烃类含量;吡咯类物质是香露兜叶片主要香气成分物质,因此,橡胶/香露兜间作模式显著促进香露兜香品质提升。研究结果对优化和推广橡胶间作香露兜具有积极作用,有助于促进胶农增收以及相关产业的可持续发展。

茉莉酸刺激的橡胶树胶乳cDNA消减文库的构建及其序列分析

采用抑制性消减杂交(suppression subtractive hybridization,SSH)技术,构建了外源茉莉酸刺激条件下橡胶树胶乳与未处理橡胶树胶乳差异表达的cDNA消减文库,经蓝白斑筛选共得到121个含有插入片段的阳性克隆。通过菌落PCR的方法分别对阳性克隆的插入片段进行扩增,结果表明,95％左右阳性克隆插入片段的大小在200-600 bp之间。随机选取25个克隆进行测序,并对所得的25条表达序列标签(EST)序列用Blastn(基本局域联配搜寻工具)检索基因文库(genbank),其中10条EST片断可找到碱基序列相似性大于80％以上的同源基因序列,其余15条EST为没有任何功能线索的未知序列。外源茉莉酸刺激条件下橡胶树胶乳cDNA消减文库的构建和在此基础上克隆橡胶树胶乳中JA信号的候选应激基因,将为开展茉莉酸调控橡胶树胶乳代谢和橡胶生物合成的分子机理研究打下基础。

天然橡胶胶清化学成分的研究

对天然橡胶胶清的化学成分进行了研究。运用硅胶柱色谱及葡聚糖凝胶LH-20柱色谱进行化学成分的分离和纯化,用理化方法及波谱手段解析其化学结构。从天然橡胶胶清中分离得到13个化合物,鉴定了其中12个化合物的结构,分别为:木栓酮(Ⅰ)、羽扇豆醇(Ⅱ)、β-谷甾醇(Ⅲ)、棕榈酸(Ⅳ)、硬脂酸(Ⅴ)、胡萝卜苷(Ⅵ)、尼古丁酸(Ⅶ)、琥珀酸(Ⅷ)、没食子酸(Ⅸ)、果糖(Ⅹ)、白坚木皮醇(Ⅺ)和6-hydroxy-cleistopholine(Ⅻ)。经检索,其中化合物Ⅰ、Ⅱ、Ⅵ、Ⅶ、Ⅸ和Ⅻ为首次从天然橡胶胶清中分得。

季节、采胶和外源茉莉酸对成龄橡胶树乳管分化的影响

橡胶树树干树皮中的乳管列数目与橡胶产量密切相关。为了建立成龄橡胶树乳管分化的调控技术，笔者采用实验形态学的手段，研究季节、采胶和外源茉莉酸对成龄橡胶树乳管分化的影响。结果表明，在海南岛自然条件下，乳管分化开始于6-7月份，在11月～翌年的5月没有乳管分化：割胶包括正式割胶前的预割能显著提高橡胶树形成层分化乳管的能力，其影响的范围相当大；外施茉莉酸对未开割树和割胶树的乳管分化都有促进作用。这些知识对于发展高效合理的采胶技术可能具有指导意义。

西双版纳地区三叶橡胶树异戊二烯和单萜烯排放机理初步研究

对云南省西双版纳地区三叶橡胶 (Heveabrasiliensis(H .B .K)Muell. Arg)异戊二烯和单萜烯排放的研究发现 ,三叶橡胶排放很少量的异戊二烯 (排放速率大约 0～ 1μgC·g-1h-1) ,而排放大量的单萜烯 (排放速率大约 10～ 10 0 μgC·g-1h-1)。造成这种排放特征的原因可能是橡胶树树叶叶绿体中合成异戊二烯所必需的异戊二烯合成酶 (IsopreneSynthase)缺乏所致。

橡胶树死皮病胶乳C-乳清差异表达蛋白质的筛选与鉴定

橡胶树死皮病(tapping panel dryness,TPD)在世界各橡胶种植园普遍发生,给橡胶种植业带来严重的危害。为了更好地了解和阐明死皮病发生、发展的分子机制,应用双向凝胶电泳技术(2-DE)比较橡胶树死皮株与健康株胶乳C-乳清蛋白质组表达的差异。采用固相pH梯度双向凝胶电泳分离橡胶树死皮株与健康株C-乳清的总蛋白质,凝胶经考染显色后,用PDQuest7.40图像分析软件进行比较分析,识别差异表达的蛋白质。这些点经过胶内酶切后进行基质辅助激光解析电离飞行时间质谱(MALDI-TOF-MS)分析获取肽质指纹图谱(PMF),Mascot软件搜索SWISS-PROT和NCBInr数据库鉴定蛋白质。结果:(1)橡胶树死皮株与健康株C-乳清凝胶的平均蛋白质点数分别为1075±35和1134±27,其平均匹配的点数分别为982±38和1008±22,组内图像匹配率达91.89%和88.72%。(2)橡胶树死皮株与健康株C-乳清组间的平均匹配蛋白点数为970±25。利用MALDI-TOF-MS质谱技术对40个差异明显的蛋白点进行分析鉴定,通过查询数据库鉴定了27个蛋白质。建立了分辨率高且重复性较好的橡胶树死皮株与健康株胶乳C-乳清的双向凝胶电泳图谱,并应用质谱技术鉴定了其中表达差异的蛋白质点,这些差异表达的蛋白质可能参与了死皮发生和发展的过程。

割胶、机械伤害和外源茉莉酸对橡胶树乳管细胞防卫蛋白基因表达的影响

为了进一步探明巴西橡胶树乳管的防卫功能,笔者采用RT-PCR和Northern-blot技术分析割胶、机械伤害和外源茉莉酸对胶乳几丁质酶、β-1,3-葡聚糖酶和橡胶素基因表达的影响,结果表明:(1)外源茉莉酸和机械伤害均能上调几丁质酶、β-1,3-葡聚糖酶和橡胶素的基因表达,但机械伤害的效应滞后于外源茉莉酸;(2)几丁质酶、β-1,3-葡聚糖酶和橡胶素的基因在割胶树中的表达明显强于在未开割树中的表达;(3)割胶树胶乳中内源茉莉酸含量显著高于未开割树。

巴西橡胶树SSR遗传图谱的构建

以热研88-13×IAN873的94个F1群体为试材,利用简单序列重复(Simple sequence repeat,SSR)标记,采用FsLinkage MAP 1.0软件,构建了巴西橡胶树热研88-13×IAN873的遗传连锁图谱。从441对SSR引物中筛选出160对具有多态信息的引物,在分离群体中共检测到206个多态性位点,176个位点用于遗传图谱的构建;χ2检验结果显示,有147个位点符合1:1分离比例,有12个符合1:2:1分离比例,有17个符合1:1:1:1的分离比例,共有13个偏分离位点,偏分离率低(7.38%);91个SSR位点被分为18个连锁群,覆盖橡胶树基因组1 937.06 cM,每个连锁群包含2～16个位点,标记间的平均距离为21.29 cM。

橡胶籽资源的潜在开发利用价值研究

橡胶树（Hevea brasiliensis）是一种重要的经济树种,广泛种植于海南、广东、广西、福建、云南和台湾,其副产物橡胶籽（rubber seed）产量十分丰富。橡胶籽油（rubber seed oil）不仅是一种保健食用油,也是一种重要的工业原料;压榨取油后的饼粕（rubber seed meal）中粗蛋白含量可达25%～30%,是一种高品质饲料蛋白源,且氨基酸组成平衡,微量元素含量较高,但所含抗营养因子使其在饲料中的用量受限。我国橡胶籽资源来源广泛且价格低廉,开发橡胶籽资源对解决我国蛋白饲料短缺和实现资源综合利用具有重要意义。

不同旱害级别对开割和未开割橡胶树形态和生理特性的影响

干旱会导致巴西橡胶树生长迟缓、落叶和死皮率增加。本研究对比分析巴西橡胶树RRIM600不同旱害级别开割树和未开割树胶乳产量、形态、土壤含水量和叶片叶绿素含量等生理指标的变化规律。结果表明,随着旱害级别的升高,开割树胶乳干胶含量和总固形物维持在较高水平,不适于割胶。未开割树和开割树生理响应规律一致,均表现叶片面积呈现逐渐显著减小,叶片中的色素含量逐渐减少,但Chla/Chlb的值没有明显变化。叶片中PRO、SS、SOD和POD对干旱有保护作用的规律。说明干旱条件下橡胶树表现出的特性是叶面积减小,渗透调节物质含量和抗氧化物酶活性增加。本研究为建立橡胶树新干旱分级标准和筛选抗旱诊断指标奠定基础。

乙烯利刺激对橡胶树热研7-33-97幼龄开割树的乳胶生理影响

通过对未开割胶树进行2％乙烯利刺激，在刺激后的6 h、12 h、24 h、48 h、72 h和CK （未用乙烯利刺激）割胶，分析对橡胶树无性系热研7-33-97幼龄开割树的乳胶生理影响。结果表明，乙烯利刺激稀释胶乳后72 h发生强烈稀释，蔗糖在刺激后48 h开始大量转运进入乳管；乙烯利刺激不同时间后割胶，与对照CK相比：随着割胶刀次递增，干胶含量递减，蔗糖、无机磷（除刺激24 h和72 h外）和硫醇含量在第2刀出现1个最低点，随后逐步升高。差异显著性分析表明，刺激72 h后割胶与短时间刺激干胶含量差异显著，长时间刺激（24 h）后割胶与短时间刺激（6～12 h）割胶蔗糖含量差异显著，72 h内刺激割胶无机磷含量差异不显著。故涂乙烯利刺激72 h后割胶较合适。

干旱胁迫下橡胶树叶片差异表达蛋白的鉴定与功能解析

干旱是影响橡胶树生长和产胶的重要非生物胁迫。以橡胶树无性系热研7-33-97为试验材料,通过干旱胁迫处理后,提取并纯化样品叶片的总蛋白质,经双向凝胶电泳(2-DE)和胶图分析。结果表明,干旱胁迫与对照样品相比,干旱胁迫10d和15d的橡胶树叶片蛋白中共存在38个差异表达蛋白点。采用MALDI-TOFMS分析和数据库检索,对差异表达的蛋白进行鉴定和功能注释,依照功能分类,这些蛋白主要参与胁迫应激响应、能量代谢、光合作用、信号转导以及细胞定位等生物学过程。

巴西橡胶树次生乳管分化能力的早期评价方法研究

天然橡胶产量是通过测量割胶收集从次生乳管中流出的胶乳而得到,具有连续收获和累进计产的特点,这也是目前橡胶树的产量构成性状难于剖析和橡胶树产量育种周期长且效率低的主要原因。橡胶树次生乳管分化能力是决定橡胶产量的关键因子之一,通过对幼树的次生乳管分化能力进行早期预测对于缩短橡胶树产量育种周期具有重要意义。本研究采用实验形态学技术,以不同树龄和不同次生乳管分化能力的橡胶树种质为材料,系统地分析机械伤害、割胶和茉莉酸类物质处理对其次生乳管分化能力的影响。研究发现,割胶处理相同种质的二年生幼树与八年生成龄未开割树,得到次生乳管分化能力的效应是一致的,所以使用二年生幼树就可以较好地区分出橡胶树种质间的次生乳管分化能力差异。因此,割胶处理二年生幼树的方法可以作为橡胶树次生乳管分化能力的早期评价的有效方法。这些研究结果不仅丰富了橡胶树产胶潜力的早期预测技术,而且为产胶潜力相关分子标记研发打下良好基础。

热研7-33-97幼龄开割树对低频刺激割制的适应性研究初报

研究了速生高产优良无性系热研7-33-97在幼龄开割期对低频刺激割制的适应性。3a结果表明,该品种在幼龄开割期使用低频乙烯利刺激割胶表现出胶乳再生能力强、用于生长的干物质分配率高、排胶速度快等生理特性。采用低频、短线、少药等技术措施,有利于胶树的产胶与生长。

水肥耦合对橡胶树根系垂直分布的影响

水分和养分是限制橡胶树生长和产胶量的重要因子。以17 a树龄的热研7-33-97橡胶树为试验材料,通过田间小区试验研究了不同水肥耦合水平对橡胶树根系垂直分布特征的影响,结果表明:橡胶树吸收根系主要分布在0～20 cm土层,随土壤层次的加深,橡胶根系干重在垂直分布上呈递减趋势,可用乘幂函数模型表示。适量增施氮、磷肥均能促进0～20 cm土层根系的生长;氮肥施用量过大,深层根系比重增大;轻度降低土壤水分能够促进根系扎深。水肥耦合对根系生长和分布具有调节作用,本试验条件下,各土层根系干重总量以丰氮丰水和丰磷丰水组合处理最高,分别达0.33和0.31 kg/m3,并且根系在土壤剖面上的分布与养分分布具有一致性。

橡胶树DELLA蛋白编码基因HbGAI的克隆与表达分析

该研究采用RT-PCR与RACE技术,从橡胶树‘热研7-33-97’胶乳中克隆了1个DELLA蛋白编码基因HbGAI(GenBank登录号为KT696439)。HbGAI全长cDNA序列2 050bp,包含1个长1 842bp的完整开放阅读框。序列分析显示,HbGAI基因编码613个氨基酸,其推导的蛋白含有DELLA和GRAS结构域,分子量为66.476kD,理论等电点为5.19,无跨膜结构域,属于亲水性蛋白。进化树分析表明,HbGAI蛋白与其他植物中DELLA蛋白具有较高的相似性,与麻疯树JcGAI和蓖麻RcGAI亲缘关系较近。荧光定量PCR结果显示,割胶和茉莉酸甲酯处理下调胶乳中HbGAI基因的表达,乙烯利处理4h内显著上调胶乳中HbGAI基因的表达,表明HbGAI基因可能在橡胶树割胶、茉莉酸、乙烯响应中发挥作用。

橡胶树胶乳黄色体死皮相关蛋白的鉴定及分析

本实验通过双向凝胶电泳技术(2-DE)比较橡胶死皮树与健康树胶乳黄色体蛋白表达谱的差异,通过软件分析比较获得37个差异表达的蛋白点,经基质辅助激光解析电离飞行时间质谱(MALDI-TOF MS)分析后,搜索NCBInr数据库,结果表明,有11个蛋白点被成功鉴定,其中7个为未知蛋白,其余4个蛋白分别为chloroplast 23 kDa polypeptide of photosystem II、ATP synthase beta chain、NADP-dependent sorbitol-6-phosphate dehydrogenase和vitamin-b12 independent methionine synthase。这4个蛋白在死皮树中表达量均下调,可能在死皮发生过程中起着重要作用。本研究将为进一步阐明橡胶树死皮发生的分子机制提供理论依据。