深挖垦复对锥栗重要农艺性状及土壤理化性质的影响

为探索锥栗林地高效的土壤管理方式,提升我国锥栗栽培管理技术水平,进而提高其产量、品质以及经济效益。该研究采用全垦和环垦两种方式对锥栗林地进行连续4年的深挖垦复,通过测定垦复前后土壤理化性质变化以及锥栗树体生长、叶片表型和生理特征、结果性状、产量及品质等重要农艺性状,统计数据并进行对比分析。结果表明:(1)深挖垦复对锥栗林地土壤理化性质改善效果显著,两种垦复方式土壤容重较垦复前降低31.21%及以上(0～30 cm处),土壤含水率、土壤孔隙度、有机质含量以及各种大量元素含量较垦复前和对照均有不同程度的增加,土壤肥力及其保水保肥能力显著增强。(2)环垦区土壤有机质含量、有效磷含量以及交换性镁含量高于全垦区,其土壤有机质含量较垦复前增加40.59%,远高于全垦增加幅度(17.76%),从土壤保肥能力的角度来看,环垦效果优于全垦。(3)土壤肥力的提升增强了其对锥栗叶片的供肥能力,使得叶片含水率、叶绿素含量以及各种矿质元素含量显著增加,从而提升其光合作用能力。(4)深挖垦复对锥栗树体生长、结实能力、产量及品质同样具有显著的提升效果,其中全垦和环垦区单位面积产量分别是对照的1.75倍和1.33倍,且栗苞总重、单果质量、出籽率、可溶性糖含量以及磷、钾元素含量显著高于对照,而空苞率显著低于对照。综上,深挖垦复是改良林地土壤和提高锥栗生产力的有效举措。     

栗属杂交F1代生长与枝条性状遗传变异及杂种优势分析

为探索栗属杂交F₁代幼林期生长、枝条性状遗传变异规律及杂种优势,并为栗属育种亲本选配及早期选择指标筛选奠定理论基础,该研究以锥栗、板栗种内和种间9个杂交组合子代及其亲本为材料,在分析F₁代幼林期生长、枝条性状遗传变异规律及杂种优势的基础上,利用SSR分子标记检测7个亲本的遗传距离,进而分析栗属杂交子代生长、枝条性状杂种优势与亲本遗传距离间的关系。结果显示：(1)栗属杂交F₁代生长、枝条性状均存在较高的遗传变异,各性状组合间F值的变动范围为5.08~22.03,组合内的变异系数范围为6.60%~27.69%;各性状广义遗传力均在0.5以上,性状受遗传影响较大;除地径外,其他性状遗传传递力均大于100%,性状遗传稳定性较高;各性状中亲优势率为-6.01%~44.40%,且F₁代生长、枝条性状存在普遍的超亲分离现象。(2)28对引物在7个亲本中共检测出115个多态性等位位点,每对引物的等位基因数3~5个不等,平均每对引物等位基因数为4.1个,多态性程度较高;Shannons 指数(I)、多态性信息含量(PIC)的平均值分别为1.25、0.674,亲本遗传多样性较为丰富。(3)相关分析表明,杂交子代一年生枝长、一年生枝粗及节间距的杂种优势与亲本遗传距离均存在显著的线性关系,并随遗传距离增大杂种优势增强。     

Photosynthesis-Related Proteins Play Crucial Role During Senescence Stage in Flue-Cured Tobacco Plants: A Combine iTRAQ-PRM Study

Leaf aging is a significant process during herbaceous plant senescence, which is influenced by various internal and external factors. During leaf aging, chlorophyll catabolism is one of the most important metabolism pathways and results in leaf yellowing. Understanding the underlying mechanism is important for the regulation of senescence in tobacco leaf. However, there are few studies on explaining tobacco leaf senescence from the proteomics level. Here, photosynthesis experiments, cell ultrastructure, and proteomics were used to study tobacco leaves of different growth stages. We applied iTRAQ-based quantitative proteomics and parallel reaction monitoring (PRM) to determine the accumulation of proteins in aging tobacco leaves. Overall, we screened 4747 proteins. The result of KEGG pathways analysis showed that differently expressed proteins (DEPs) were involved in four pathways: metabolic pathways, biosynthesis of secondary metabolites, microbial metabolism in diverse environments, and starch and sucrose metabolism. This would be first report based on iTRAQ-PRM technique, in which we identified proteins related to photosynthesis showed a differently expressed during senescence stage in flue-cured tobacco plants.