异质低磷胁迫下马尾松家系根构型和磷效率的遗传变异

以7个马尾松(Pinus massoniana)一代种子园自由授粉家系为材料, 设置同质低磷(P)胁迫和异质低P胁迫模拟的盆栽试验, 系统研究马尾松家系对不同类型低P胁迫的适应机制和P效率变异规律。结果表明, 参试马尾松家系的苗高、地径和生物量等P效率指标均表现出显著的家系变异, 主要P效率指标的家系遗传力均较高, 干物质积累量的广义遗传力大于0.80, 揭示了马尾松P营养效率的较大遗传改良潜力。马尾松对不同类型低P胁迫的适应机制有所差异。在同质低P胁迫下, ‘3201’、‘1217’等高P效率家系的根系主要参数均高于低P效率家系, 表明整体根系参数的适应性变化是P效率和生物量形成的决定因素。在异质低P胁迫下, 高P效率马尾松家系在表层富P介质的根系分布量、分布比例均显著增加, 表层根系参数与马尾松家系P效率呈显著正相关, 揭示根系空间构型的适应性变化是决定马尾松高P效率的重要生物学基础。表层根系生物量、表层根相对比例的家系遗传力达0.88和0.72, 证实了以马尾松根构型的适应变化为突破口, 选育具有理想根构型和较高P效率的马尾松家系。     

菜豆根构型对低磷胁迫的适应性变化及基因型差异

利用特殊设计的营养袋纸培养和分层式磷控释砂培等根系生长系统结合计算机图像分析技术,以基根根长在生长介质各层的相对分布和基根平均生长角度为指标,定量测定菜豆（Ｐｈａｓｅｏｌｕｓ ｖｕｌｇａｒｉｓ Ｌ．）根构型在低磷胁迫下的适应性变化及其与磷效率的关系。结果表明,菜豆根构型对低磷胁迫具有适应性反应,在缺磷条件下基根向地性减弱,基根在生长介质表层相对分布增多、基根平均生长角度（与水平线夹角）变小,从而导     

磷有效性对大豆菌根侵染的调控及其与根构型、磷效率的关系

以30个不同根构型的大豆基因型为材料,通过盆栽试验,研究了生长介质磷有效性对大豆接种摩西球囊霉属丛枝菌根真菌的影响及其与根构型、磷效率的关系.结果表明：生长介质磷有效性显著地影响大豆菌根真菌的接种效果.低磷条件下接种菌根真菌效果明显,菌根侵染率较高,菌根对大豆磷吸收的贡献率较大;高磷条件下接种菌根真菌效果不显著,菌根侵染率较低,菌根对大豆磷吸收的贡献率较低.磷有效性和大豆根构型对菌根真菌接种的影响具有交互作用.低磷条件下,中间型和深根型大豆的菌根侵染率最高,浅根型最小.高磷条件下,根构型与菌根侵染率间的关系不明显.根构型和菌根侵染状况对大豆磷效率的贡献存在互利互补关系,磷效率高的大豆基因型一般具有较好的根构型或较高的菌根侵染率.     

植物根构型特性与磷吸收效率

植物根构型,即根系在生长介质中的空间造型和分布,与磷吸收效率密切相关;认识植物根构型,可为植物磷效率的遗传改良提供依据。长期以来,人们试图定量描述植物根构型,确立一个能客观全面地描述根系三维立体构型的综合指标。试验指出,植物主要通过向地性变化和根冠之间的碳源分配来改变根构型,从而影响磷吸收效率;根系向地性变化可由缺磷等因素所诱导,且存在着一定的遗传变异性。有证据表明,根构型对低磷胁迫的适应性变化是     

植物根构型特性与磷吸收效率

植物根构型，即根系在生长介质中的空间造型和分布，与磷吸收效率密切相关；认识植物根构型，可为植物磷效率的遗传改良提供依据。长期以来，人们试图定量描述植物根构型，确立一个能客观全面地描述根系三维立体构型的综合指标。试验指出，植物主要通过向地性变化和根冠之间的碳源分配来改变根构型, 从而影响磷吸收效率；根系向地性变化可由缺磷等因素所诱导，且存在着一定的遗传变异性。有证据表明，根构型对低磷胁迫的适应性变化是受基因调控的一个生理过程，其中乙烯可能是一种重要的生理调节物质。迄今已在一些植物上定位到了部分控制根构型的数量性状座位，为该性状的分子生物学改良提供了基础。随着现代技术的进展，植物根构型研究将取得更大的突破。     

模拟氮沉降对低磷胁迫下马尾松无性系细根形态和氮磷效率的影响

根系是植物吸收土壤营养的关键部位, 不同径级根系的形态和功能差异不仅与植株自身的遗传因素有关, 而且受到土壤中营养元素分布和水平的影响。在我国亚热带高氮沉降和酸性红壤磷匮乏及不均一的土壤环境下, 研究林木不同径级根系对外界营养环境变化的响应有利于深入了解林木根系的觅养机制及规律。该文以马尾松(Pinus massoniana)无性系19-5 (高磷效率)和21-3 (低磷效率)为材料, 在同质低磷和异质低磷两种盆栽处理下, 设置3个氮水平(对照、中氮和高氮)的模拟氮沉降实验。结果表明: 1)马尾松无性系苗木的生长受磷环境、氮水平和无性系三因素共同影响, 模拟氮沉降显著促进了异质低磷下马尾松苗高和整株干物质量的增加, 而在同质低磷下氮效应不显著; 在异质低磷、高氮下, 无性系19-5的苗高和整株干物质量分别是无性系21-3的1.1倍和1.6倍。2)马尾松各径级细根长度和表面积随径级增大而减小, 模拟氮沉降促进了直径≤1.5 mm的细根的增生发育, 直径1.5-2.0 mm的细根和>2.0 mm的较粗根无明显变化; 另外, 直径≤1.5 mm的细根长度占总根长的比例保持在90.4%-92.8%范围内, 受氮影响较小。3)模拟氮沉降显著提高了异质低磷下无性系19-5≤1.5 mm的细根长度和表面积, 同时, 其根系氮、磷吸收效率较对照分别高出93.3%和148.4%; 无性系21-3的根系氮、磷吸收效率受氮影响较小; 根系氮、磷利用效率均无显著变化。上述结果表明, ≤1.5 mm的细根的增生发育和氮、磷吸收效率的提高可能是磷高效马尾松无性系应对高氮低磷环境的重要响应机制。     

甘蔗幼苗对难溶性磷的吸收及其根系对低磷胁迫的响应

为明确甘蔗适应低磷胁迫的生理生化机制,挖掘甘蔗对磷素的利用潜力,揭示甘蔗对低磷胁迫适应的可能机制,该研究以ROC22和ROC10两个甘蔗品种为材料,采用水培和土培的方法研究了甘蔗幼苗对难溶性磷的吸收及其在低磷胁迫下根构型和根系的生理反应。结果表明:(1)培养在以难溶性磷(Ca-P和Al-P)为磷源的培养液中的甘蔗的叶片数、地上部干重、生物量较缺磷(-P)处理显著增加,与对照(+P)的相当,甘蔗总磷积累量也显著提高,达到对照(+P)处理磷积累量的30%～77%。(2)在低磷条件下,甘蔗幼苗的根系有向土壤深层分布的趋势,根的总体积增大、最长根长变长、浅根系分布增多。(3)甘蔗幼苗在低磷环境下,根际环境明显酸化,且根系分泌物能溶解难溶性的铝磷,植株体内酸性磷酸酶的活性也明显增强。以上表明甘蔗幼苗有较强的吸收利用难溶性磷的能力,而低磷条件下根系数量增加、主根的向地性、浅根系分布增多、根际酸化以及植株体内酸性磷酸酶活性的增强可能是甘蔗幼苗适应缺磷环境的重要机制。     

低磷胁迫下甘蓝型油菜酸性磷酸酶对磷效率的贡献分析

为探讨低磷胁迫下甘蓝型油菜酸性磷酸酶活性的基因型差异及其与磷效率的关系, 采用土培实验研究了磷高效基因型102和磷低效基因型105对有机磷和无机磷的利用及其根际土壤酸性磷酸酶活性差异; 并采用水培实验研究了甘蓝型油菜根系分泌的酸性磷酸酶及不同叶片酸性磷酸酶的活性差异. 结果表明, 低磷胁迫能诱导根系及根系分泌的酸性磷酸酶活性升高; 土培条件下, 由于酸性磷酸酶的有效性受较多因素影响, 植物的磷营养和磷吸收效率与根系分泌的酸性磷酸酶活性并不直接相关; 缺磷胁迫下重组自交系群体叶片酸性磷酸酶活性与磷利用效率呈显著正相关, 进一步表明低磷诱导的植株叶片酸性磷酸酶活性升高能促进体内磷的再利用, 从而提高磷利用效率.     

低磷供应对拟南芥根系构型的影响

在人工气候箱中,采用Johnson培养基对拟南芥在低磷供应条件下根系构型的变化进行了研究,结果表明：拟南芥在磷饥饿诱导下,主根缩短,侧根密度、根毛的数量和长度显著增加,并且,根尖到第一侧根和第一根毛的距离也大大缩短。这些改变增加了根系比表面积,并且使得根系分布更加靠近土壤表层,有利于提高植物吸收土壤中有机磷的效率。低磷胁迫还导致拟南芥根系分生组织区细胞形状变异,柱细胞数量减少;主根生长和细胞伸长的动力学分析显示,磷饥饿促使拟南芥主根生长变缓,细胞长度随磷饥饿程度的加深迅速缩小。CycB1;1:GUS染色分析结果表明,低磷破坏拟南芥根系分生组织细胞分裂能力,这些结果说明磷胁迫同时抑制了细胞的伸长和分裂,从而引起拟南芥主根的缩短。     

低磷和干旱胁迫对大豆植株干物质积累及磷效率的影响

土壤缺磷和季节性干旱已经成为南方酸性红壤地区大豆生产的主要限制因素之一。选取2个大豆品种巴西10号(磷高效)和本地2号(磷低效),研究其在不同磷素(0,15, 30 mg/kg P)和水分处理(分别在开花期和结荚期进行干旱胁迫)下的反应,从植株生物量、叶绿素含量、磷效率指标等方面研究不同基因型大豆对水磷耦合胁迫的适应机制。研究结果表明,随着土壤磷素水平的增加,两个品种的生物量和叶片叶绿素含量显著增加,根冠比则显著下降。在同一磷素水平处理下,干旱胁迫则导致较高的根冠比,对叶片叶绿素含量影响不大,两个品种表现一致。两个基因型大豆受到干旱胁迫后,其产量均显著低于正常水分处理。中等施磷能显著提高两个大豆品种的产量,但高磷处理对产量的增加幅度有限,甚至高磷处理还造成本地2号减产。巴西10号的产量随土壤中磷素的增加而增加,而本地2号的产量则为中磷>高磷>低磷,不管是磷处理还是水分处理,巴西10号的产量均高于本地2号。无论是花期干旱还是结荚期干旱,巴西10号和本地2号的根磷效率比、磷吸收效率及磷转移效率均随土壤磷浓度的增加而增加,磷利用效率则降低。总体上来讲,巴西10号的磷吸收效率和利用效率高于本地2号,而根磷效率比、磷转移效率则小于本地2号。     

模拟氮沉降对低磷胁迫下马尾松不同家系根系分泌和磷效率的影响

近年来大气氮(N)沉降的增加, 导致森林土壤中有效N含量增加、N:P发生改变, 研究N沉降对低磷(P)胁迫下林木根系分泌和P效率的影响具有重要意义。该文以马尾松(Pinus massoniana)家系作为试验材料, 设置模拟N沉降与同质低P (介质表层与深层均缺P)、异质低P (介质表层P丰富、深层缺P)耦合的二年生盆栽实验, 系统研究了模拟N沉降对低P胁迫下马尾松根系分泌性酸性磷酸酶(APase)活性、有机酸分泌以及P效率的影响。结果表明: (1)同质低P和异质低P下, 模拟N沉降均显著提高了植株N:P化学计量比、增加了P素的相对匮乏程度, 从而诱导根系增加了APase和有机酸的分泌, 而同质低P比异质低P下增加幅度更大, 其中有机酸分泌均与马尾松生长呈正相关关系, 而APase活性与P效率相关性较小; (2)同质低P下, N沉降虽然增加了根系分泌, 但未提高马尾松P素吸收和生长量, 其原因在于, 同质低P下植株N:P过高, 因而植株对N沉降敏感性低; 在异质低P下, 植株表现为N、P共同限制, 因而对N敏感性较高, N沉降增加了根系分泌, 同时提高了N和P吸收效率、增加了生物量; (3)马尾松根系分泌对模拟N沉降的响应存在较大的家系差异。同质低P下, 家系71×20的有机酸分泌和生物量对N沉降的响应幅度较大; 异质低P下, 家系36×29、71×20和73×23对N沉降的响应幅度较大。     

低温胁迫下内源脱落酸对马尾松优良种源抗寒性的调节作用

以2个马尾松优良种源苗期的叶片为材料,对系列低温梯度条件下不同种源叶片的内源ABA、内源保护酶系统的动态变化的规律以及相互作用进行研究.结果表明:在降温过程中通过内源ABA的变化来调控内源保护酶的变化趋势,并协调多种酶的相互作用来抵抗低温.内源ABA、SOD对零上低温敏感,属冷害敏感型调节物质,它们在零上低温前达到最高...     

Effects of simulated nitrogen deposition on fine root morphology,nitrogen and phosphorus efficiency of Pinus massoniana clone under phosphorus deficiency

Aims In forest ecosystems with phosphorus (P) deficiency, the impact of atmospheric nitrogen (N) deposition on nutritional traits related to N and P uptake potentially affect plant growth and vegetation productivity. The objective of this study was to explore the effects of simulated N deposition on fine root morphological characteristics and effiency of N and P absorption in Pinus massoniana under under low P stress.
Methods Two clones of P. massoniana seedling with different P efficiency (high P efficiency 19-5 vs. low P efficiency 21-3) were used. A two-year pot experiment was applyed with treatments of two P conditions, (i.e. homogeneous low P availability vs. heterogeneous low P availability) and three N deposition levels (0, 30 and 120 kg N·hm^-2·a^-1; i.e., N0, N30, or N120, respectively) .
Important findings 1) The growth of P. massoniana seedling was interactively affected the three factors: simulated N deposition, P condition and genotypes. Simulated N deposition increased the seedling height and dry mass under heterogeneous P deficiency, but did not significantly affect those traits under homogeneous P deficiency. Under heterogeneous P deficiency and N120 treatment, the seedling height and dry mass of clone 19-5 were 1.1 times and 1.6 times higher than that of clone 21-3, respectively. 2) Fine root length and surface area decreased as root diameter increased. N deposition significantly stimulated proliferation of fine root with diameter ≤1.5 mm, while roots with diameters ranged from 1.5 to 2.0 mm and over 2.0 mm were not influenced. The length of fine root ≤1.5 mm in diameter accounted for 90.4%-92.8% of the total root length and was not affected by N deposition. 3) Under the heterogeneous low P condition, clone 19-5 was found to respond to the simulated N deposition with increased root length and surface area in fine-root diameter class of ≤1.5 mm. Additionally, in compared with control, its N and P absorption efficiency were significantly enhanced 93.3% and 148.4%, respectively under N120 treatment. However, the N and P absorption efficiency of clone 21-3 was less affected by the simulated N deposition. The N and P use efficiency had no notable variation. Finally, we found that the proliferation of fine-root ≤1.5 mm in diameter and high N (P) absorption efficiency maybe the adaptive mechanisms of P. massoniana responding to atmospheric N deposition under P deficiency.     

低磷胁迫下磷高效基因型大麦的根系形态特征

在根袋土培盆栽条件下,以磷高效基因型DH110+、DH147和低效基因型DH49大麦为试验材料,利用根系分析系统分析不同施磷(P₂O₅)水平(极低磷25 mg·kg^-1、低磷50 mg·kg^-1和正常磷75 mg·kg^-1)下,磷高效基因型大麦的根系形态特征及其与植株磷素吸收的关系.结果表明： 低磷胁迫显著降低大麦生物量和磷吸收量,其中磷高效基因型的生物量和磷吸收量在各施磷水平下分别为低效基因型的1.24～1.70和1.18～1.83倍;大麦的总根长、总根表面积、平均根系直径、不定根长及其根表面积、侧根长及其根表面积均随施磷水平的降低而显著降低,其中磷高效基因型大麦在各施磷水平下的总根长、总根表面积、比根长、侧根长及根表面积分别为低效基因型的1.46～2.06、1.12～1.51、1.35～1.72、1.69～2.42和1.40～1.78倍,而平均根系直径为低效基因型的70.6%～90.2%;主成分分析表明,平均根系直径、比根表面积和比根长受基因型差异的影响较为明显,是区分两类磷效率基因型大麦根系形态差异的主要指标;偏最小二乘回归分析表明,各施磷水平下,总根长、总根表面积对大麦植株磷素吸收贡献均较大,随施磷水平降低,不定根长、不定根表面积对大麦植株磷素吸收的贡献明显降低,而平均根系直径、比根长、侧根长及其根表面积的贡献明显增加.磷高效基因型大麦可通过维持侧根的生长、根细度和比根长的增加来适应低磷胁迫.     

Effects of localized nitrogen supply treatments on growth and root parameters in Pinus massoniana families under phosphorus deficiency

Aims A heterogeneous spatially distribution of nutrients in natural soil may affect plant growth. The objective of this study was to determine the effects of localized nitrogen (N) supply treatments on growth traits and root parameters among different families in Pinus massoniana.Methods Five families of P. massoniana seedlings from full-sib progenies were used as test materials (1, 25, 49, 52, and 57). This study included two conditions, (i.e. homogeneous phosphorus (P) deficiency vs. heterogeneous P efficiency) among soil layers in combination with four N supply treatments in a one-year pot experiment. These N supply treatments were: (1) Homogeneously high N along the soil profile (HHH); (2) high N-high N-low N (HHL); (3) low N-low N-high N (LLH); (4) low N-low N-on side with N addition and the other side without N supply (LLH/L).Important findings This study indicated that localized N supply treatment did enhance the growth of P. massoniana, and this enhancement mainly happened in the pattern of N applied to deep soil. The results showed: 1) Compared to the homogeneous low P condition, there were increase in the growth traits and root parameters of P. massoniana under heterogeneous low P condition. Particularly, the root length and root surface area under the heterogeneous P deficiency condition were 1.95 times and 2.11 times higher than that subjected to the homogeneous P deficiency. 2) Localized N supply treatment affected seedling growth, and there was a significant interaction among N supply pattern and P condition. In compared with homogeneous N supply treatment, the height, basal diameter and dry weight of seedlings increased significantly by localized N supply treatments (LLH and/or LLH/L) under both two P deficiency conditions. But when the seedlings parameters were enhanced under homogeneous P deficiency, they were inhibited under heterogeneous P deficiency subjected to HHL. 3) Within the two P conditions, LLH and LLH/L stimulated root proliferation significantly, and root parameters were significantly enhanced under the heterogeneous P deficiency condition. Specifically, the root length and root surface area subjected to LLH/L rather than HHH were significantly enhanced by 29.2% and 32.3%, respectively. However, the length and surface area of the roots were suppressed by HHL treatment. 4). There were significant differences in response to different N supply treatments among P. massoniana families Seedlings in the families of 49, 52, and 57 responded to the localized N supply treatments with increased root proliferation, which enhanced seedling dry mass. On the other hand, the seedling growth in the family of 25 were stimulated by N and (or) P concentration, while the response of seedlings in the family of 1 to local nitrogen supply was relatively slow and exhibited growth retardation.     

马尾松地理种源遗传变异规律研究的综述与分析

对我国重要的亚热带林木树种马尾松的分布范围及地理种源遗传变异研究,从形态水平、生态生态水平、染色体水平、分子水平等方面进行综述,并对马尾松遗传多样性各种研究方法和马尾松地理种源遗传变异规律进行综合分析,对马尾松分子生态学研究的有关问题进行讨论。     

马尾松不同种源矿质营养与生长相关性分析

运用电感耦合等离子直读光谱仪（ＩＣＰ）,测定相同立地上马尾松（ＰｉｎｕｓｍａｓｏｎｉａｎａＬａｍｂ．）１０个种源针叶内２５种矿质营养元素含量的变异,分析矿质元素含量与树高、胸径生长量的相关性,认为利用常绿针叶树种休眠期内矿质元素含量的相对稳定性研究马尾松矿质营养水平是可靠的。矿质营养与产地经、纬度呈负相关。广东和广西的种源可作为江苏地区今后推广马尾松的主要种源。马尾松针叶内钙和锌含量可作为马尾松树高和胸径生长量的预测因子。初步认为马尾松属于高钙吸收和高锌利用型树种。