高寒退化草地星毛委陵菜叶大小与数量的权衡关系

植物叶大小和数量的权衡关系反映了植物对环境的高度适应性及其在复杂生境下的自我调控能力。采用标准化主轴估计(standardized major axis estimation,SMA)方法,在祁连山北坡选择未退化(Ⅰ)、轻度退化(Ⅱ)、中度退化(Ⅲ)和重度退化(Ⅳ)4种高寒草地,研究了星毛委陵菜(Potentilla acaulis)叶大小-数量的关系。结果表明:随着天然草地退化程度的加剧,草地群落的高度、盖度和土壤含水量逐渐下降,星毛委陵菜种群的高度逐渐下降、盖度逐渐上升,星毛委陵菜叶大小呈逐渐减小的趋势,而叶数量增加;各退化草地星毛委陵菜叶大小与叶数量均呈显著负相关(P0.05),星毛委陵菜分配给叶大小与叶数量的资源间存在着"此消彼长"的关系;不同退化草地间的比较显示,未退化和重度退化草地星毛委陵菜叶大小与叶数量呈显著异速生长关系(P0.05),轻度和中度退化草地二者呈近似等速生长关系。高寒退化草地星毛委陵菜植株合理权衡叶大小-数量的资源配置模式,体现了植物茎叶构型的表型可塑性机制。     

不同坡向甘肃臭草根系分叉数和连接长度的权衡关系

根系分叉数和连接长度影响植物根系分布格局, 二者的权衡关系对理解植物根系构型的生态适应策略有重要意义。利用ArcGIS建立研究区域的数字高程模型, 并提取坡向数据, 采用全根挖掘和Win-RHIZO根系分析仪相结合的方法, 研究了祁连山北坡高寒退化草地不同坡向甘肃臭草(Melica przewalskyi)根系分叉数与连接长度间的关系。结果表明: 随着坡向由北坡向东坡、西坡、南坡转变, 草地群落的密度、高度、地上生物量和土壤含水量逐渐减小, 甘肃臭草种群的密度、高度以及根系连接长度呈逐渐增大的趋势、分叉数逐渐减小; 不同坡向甘肃臭草根系分叉数与连接长度间的相关性存在差异(p < 0.05), 在南坡和北坡甘肃臭草根系分叉数和连接长度之间存在极显著的负相关关系(p < 0.01), 在东坡和西坡二者之间存在显著的负相关关系(p < 0.05), 甘肃臭草分配给根系分叉数与连接长度的资源间存在着“此消彼长”的权衡关系。不同坡向甘肃臭草根系分叉数和连接长度的资源配置模式反映了植物根系功能性状对环境的响应和适应, 以及根系构型构建的投资权衡机制。     

星毛委陵菜根系构型对草原退化的生态适应

对轻度、中度、重度和极度退化的草原群落中星毛委陵菜(Potentilla acaulis)根系构型参数及相应的土壤水分、容重和硬度等指标进行了分析, 以研究星毛委陵菜根系构型对草原退化的生态适应性。结果表明: 1)在以大针茅(Stipa grandis)为建群种的典型草原中, 随着退化程度的加剧, 星毛委陵菜在群落中的作用逐渐增强, 其根幅、根深、一级垂向根数、分蘖子株数和水平分蘖根长度显著增加; 2)根表面积、二级侧根长度、总根长和根分叉数4个根系构型参数是解释星毛委陵菜根系构型对草原退化生态适应的首选指标, 解释力依次减小, 累计贡献率为92.34%; 3)直径2 mm以下的根系对单株系星毛委陵菜的根表面积和总根长影响显著; 4)阔腰倒锥体三维根系构型是星毛委陵菜适应草原退化并使之成为建群种的优势构型。     

琵琶柴根系分叉数与连接长度权衡关系的坡向差异

权衡关系是生活史对策理论的基础,根系分叉数和连接长度的权衡关系对理解植物在不同生境下的表型可塑性有重要意义。利用Arc GIS建立研究区域的数字高程模型(DEM),采用全根系挖掘法,研究了祁连山北坡荒漠草原不同坡向琵琶柴(Reaumuria soongorica)根系分叉数和连接长度间的关系。结果表明:随着坡向由南坡转向西坡、东坡、北坡,草地群落密度、盖度、高度和土壤含水量呈逐渐增加的趋势,琵琶柴种群的高度、根冠比以及根系连接长度呈逐渐减小趋势,比根长和分叉数逐渐增加;不同坡向琵琶柴根系分叉数和连接长度的相关性存在差异,在南坡和北坡琵琶柴根系分叉数和连接长度之间存在极显著的负相关关系(P0.01),在东坡和西坡二者之间存在显著的负相关关系(P0.05);琵琶柴根系分配给根系分叉数和连接长度的资源间存在着"此消彼长"的权衡关系。不同坡向琵琶柴根系合理权衡连接长度和分叉数的资源配置模式,反映了异质生境中资源多重竞争下琵琶柴生物量分配机制和提高种群适应性的策略。     

红砂根系分叉数和分支角度权衡关系的坡向差异

根系构型是决定根系分布及其对土体搜索效率的重要因素, 是植物与资源环境异质性相互适应的结果。利用ArcGIS建立研究区域的数字高程模型(digital elevation model), 采用全根系挖掘法, 研究了祁连山北坡荒漠草原不同坡向红砂(Reaumuria songarica)根系分叉数和分支角度的关系。结果表明: 不同坡向梯度草地群落的盖度、密度、高度和土壤含水量呈不同的变化趋势(p < 0.05), 红砂种群的密度、高度和根冠比等生物学特征的变化规律存在差异(p < 0.05); 不同坡向红砂根系分叉数和分支角度的相关性存在差异(p < 0.05), 在南坡和北坡红砂根系分叉数和分支角度之间存在极显著的负相关关系(p < 0.01), 在东坡和西坡根系分叉数和分支角度之间存在显著的负相关关系(p < 0.05), 红砂根系分配给根系分叉数和分支角度的资源存在着“此消彼长”的权衡关系; 随着坡向由南坡向西坡、东坡、北坡转变, 红砂根系分叉数和分支角度回归方程的标准化主轴斜率逐渐减小(p < 0.05), 红砂根系构型模式由扩散型转向聚集型。不同坡向红砂根系合理权衡连接长度和分支角度的资源配置模式, 反映了异质生境中植物种群应对资源多重竞争的环境生态适应机制。     

尕海湿地不同密度下甘肃马先蒿根系分叉数与连接数、分支角度的关系

根系构型决定根系分布及其对养分和水分的吸收效率,是植物根系与胁迫生境相互适应的结果。采用标准化主轴估计(Standardized major axis estimation, SMA)法,并采用全根挖掘和Win-RHIZO根系分析仪相结合的方法,按照甘肃马先蒿种群密度设置I(10—31株/m~2)、Ⅱ(32—53株/m~2)、Ⅲ(54—75株/m~2)3个样地,研究了尕海湿地不同密度下甘肃马先蒿(Pedicularis kansuensis)根系分叉数与连接数及分支角度的关系。结果表明:随着种群密度由高到低转变,甘肃马先蒿的高度、盖度、地上生物量、根系分叉数及外部连接数逐渐减小,地下生物量、根系内部连接数、分支角度逐渐增大;甘肃马先蒿根系分叉数与内部连接数、外部连接数及分支角度均呈异速生长关系,随着种群密度由高到低转变,甘肃马先蒿根系内部连接数与分支角度增加的速度逐渐大于分叉数与外部连接数减小的速度,根系分叉数与内部连接数的异速斜率逐渐减小,与外部连接数、分支角度的异速斜率逐渐增大。甘肃马先蒿在高密度倾向于密集型根系构型构建模式,在低密度选择扩散型根系生长模式,体现了高寒湿地植物种群应对资源多重竞争的生态适应机制。     

金塔绿洲不同林龄多枝柽柳根系分叉数与分支角度的关系

根系构型影响根系空间分布和营养吸收效率,反映了植物适应环境胁迫的生存策略。采用标准化主轴估计（Standardized major axis estimation,SMA）的方法,分析了甘肃金塔北海子国家湿地公园3年生和6年生多枝柽柳（Tamarix ramosissima）根系分叉数与分支角度的异速生长关系。结果表明：随着林龄的增长,湿地群落盖度、高度逐渐增加,多枝柽柳种群的盖度、密度、高度和地上生物量以及根系深度、分叉数、比根长、比表面积、各级根系直径随之增加,根系分支角度和根冠比逐渐减小;多枝柽柳根系分叉数与分支角度回归方程的标准主轴斜率逐渐增大（P<0.05）,随着林龄的增长,多枝柽柳根系分叉数的增加速度逐渐大于根系分支角度的生长速度,二者在林龄间呈现出差异化的异速生长关系。随着林龄的增长,多枝柽柳根系构型模式由"扩散型"转变为"紧缩型",体现了种群应对生境胁迫和竞争的生态适应机制。     

高寒草甸主要植物地上地下生物量分布及退化对根冠比和根系表面积的影响

研究高寒草甸主要植物地上地下生物量的分布及其对退化的响应有利于了解高寒草甸的退化过程。该研究首先在西藏那曲生态环境综合观测研究站小嵩草围栏内(2009年围封)选择原生植被较好的地点随机选择小嵩草(Kobresia pygmaea)、矮嵩草(K.humilis)、紫花针茅(Stipa purpurea)、二裂委陵菜(Potentila bifurca)和青藏苔草(Carex moorcroftii)等5种植物斑块,选择退化斑块上(与原生植被相比)的二裂委陵菜和青藏苔草;然后用烘箱烘至恒重并称重,用扫描仪对根系进行扫描用于估算根系表面积;最后利用2因子方差分析检验不同物种个体、不同取样层次对地上和地下生物量的影响,利用物种和退化状态2因子方差分析检验对地上生物量的影响,以及利用物种、取样层次和退化状态3因子方差分析检验对二裂委陵菜和青藏苔草地下生物量、根冠比和根系表面积的影响。结果表明:在未退化条件下,小嵩草、矮嵩草和紫花针茅0~10cml地下生物量占0~30cm地下生物量的70%以上,0~30cm地下生物量占其地上地下总生物量的96%以上;二裂委陵菜(Potentilla bifurca)和青藏苔草(Carex moorcroftii)0~10cm地下生物量占0~30cml地下生物量的50%以上,其中二裂委陵菜0~30cm地下生物量占其地上地下总生物量的57%,青藏苔草0~30cm地下生物量占其地上地下总生物量的87%;对于退化草甸的主要植物,退化显著降低了二裂委陵菜的地上生物量、地下生物量和根冠比,对其根系表面积影响不大,但显著增加了青藏苔草的地上生物量,降低了其根冠比,对其地下生物量和根系表面积影响不大。     

城市垂直绿墙常用植物的根系构型特征和生长动态

以适应性强的2种常见藤本植物：夹竹桃科的花叶蔓长春(Vinca major‘Variegata’)和花叶络石(Trachelospermum jasminoides‘Variegatum’)为研究对象,每年随机选择5盆进行重复测试,比较它们2017—2021年的根系生物量、根冠比及根系的长度、表面积、直径、体积、根尖数等形态指标及比较各指标间的变异率和相关度,分析植物在垂直绿墙容器种植条件中根系的动态变化特征,以量化植物根系受根域限制而生长退化的时间节点和有效衡量指标,从而为延长绿墙使用寿命和开发低维护管养技术提供科学依据。结果表明：1) 2种植物的根系生物量及根长、根表面积、根体积、根分叉数、根尖数均在植物上墙后2019年达到峰值后开始下降,可作为衡量植物根系生长受根域限制而退化的时间节点;根冠比值在2020年达最低水平,反映了地下根系生长受限制早于所观测到的地上枝叶退化现象。2)根长、根表面积、根体积、根尖数均可作为衡量指标,其中,根系体积可作为典型的衡量指标,花叶蔓长春和花叶络石生长受限的根体积占比分别为2.2%、1.8%。3) 2种植物的根冠比与根长等构型特征指标呈一致的变化趋...     

高寒草地甘肃臭草根系分形结构的坡向差异性

根系分形结构是植物根系构型应对环境异质性的表型可塑性结果, 可反映植物对生长环境的适应策略。利用ArcGIS建立研究区域的数字高程模型, 并提取坡向数据, 采用全根挖掘和Win-RHIZO根系分析仪相结合的方法, 研究了祁连山北坡高寒退化草地不同坡向甘肃臭草(Melica przewalskyi)的根系分形结构。结果表明: 随着坡向由北坡向东坡、西坡、南坡转变, 草地群落的密度、高度和土壤含水量逐渐减小, 甘肃臭草种群的密度、高度以及根系分形丰度呈逐渐增大的趋势、分形维数逐渐减小; 不同坡向甘肃臭草根系分形维数和分形丰度间的相关性存在差异(p < 0.05), 南坡和北坡甘肃臭草根系分形维数分形丰度之间存在极显著负相关关系(p < 0.01), 东坡和西坡之间存在显著负相关关系(p < 0.05), 甘肃臭草根系分形维数和分形丰度存在着“此消彼长”的权衡关系; 随着坡向由北坡向东坡、西坡、南坡转变, 甘肃臭草根系分形维数和分形丰度回归方程的标准化主轴(SMA)斜率逐渐增大(p < 0.05), 说明在干旱的南坡, 根系所开发利用的相同体积的土壤内, 根系分支更少、更稀疏。不同坡向甘肃臭草合理权衡根系分形维数和分形丰度的资源配置模式, 体现了植物根系构型构建的资源投资权衡机制。     

Light-regulated protein and mRNA synthesis in root caps of maize

Illumination of maize roots initiates changes in mRNA levels and in the activities of proteins within the root cap. Using Northern analysis we showed a 5–6-fold increase in the levels of three specific mRNAs and a 14-fold increase in plastid mRNA. This increase is rapid, occurring within 30 minutes of illumination. With prolonged periods of darkness following illumination, messages return to levels observed in dark, control caps. For two species of mRNA illumination results in a reduction in message levels. Light-stimulated increases in the levels of specific mRNAs are proportionally greater than are increases in the activities of corresponding proteins. We suggest that the light-stimulated increase in protein activity in root caps may be preceded by and occur as a consequence of enhanced levels of mRNA. Our work suggests that photomorphogenesis in roots could involve changes in the levels of a wide variety of mRNAs within the root cap.     

红砂幼苗根系形态特征和水分利用效率对土壤水分变化的响应

为探讨干旱与半干旱区受损红砂种群幼苗适宜生长的土壤水分条件,采用盆栽方法,研究了红砂幼苗在充分灌溉(FI)、适度灌溉(MI)、干旱处理(DT)3个水分处理下根系形态和水分利用效率的变化特征。结果表明:(1)红砂幼苗根系形态因水分条件和根序的不同而各异;随灌溉量的减少红砂幼苗根系直径和根体积均表现为FIMIDT,但干旱处理促进了根系的伸长生长和比表面积和比根长增加,根系形态的可塑性是红砂幼苗获取水分适应干旱环境的重要策略之一。(2)随根序的升高,各处理水平下红砂幼苗根长、比根长均显著减少,而其根直径和体积却显著增加,表明红砂幼苗根系内部具有高度的形态异质性。(3)与FI处理相比,MI和DT处理下红砂幼苗根系总生物量分别增加了50.00%、19.23%,但MI和DT处理却显著降低了红砂幼苗地上生物量,特别是叶片生物量下降幅度最大,分别降低了62.15%、83.28%,导致根冠比随灌溉量的减少而逐渐增加。(4)干旱处理显著提高了红砂幼苗的水分利用效率。研究认为,在灌溉量减少的情况下,红砂幼苗可通过根长、根系表面积和体积、直径等形态变化来优化其空间分布构型,以调节植株对水分的利用,提高水分利用效率。     

Rate of differentiation and emergence of nodal maize roots

The timing of root production is one of the parameters required for modelling the root system architecture. The objectives of this study are (1) to describe the rate of appearance of adventitious root primordia of maize and their rate of emergence out of the stem; (2) to test equations for the prediction of the rank of the phytomer on which root emergence occurs, in a wide range of field situations.Maize, cultivar Dea, was grown in controlled conditions and in the field in 1987, 1988, 1989 and 1991. Plants were regularly sampled and the following data were recorded: foliar stage, number of root primordia and number of emerged roots per phytomer. Root primordia were counted in transverse thin sections in the stem.At a single plant level, root primordia differentiation occurred sequentially on the successive phytomers, with no overlapping between two phytomers. The same was true for root emergence. Roots belonging to the same phytomer emerged at approximately the same time.At a plant population level, there was a linear relationship between the rank of the phytomer on which root primordia were differentiated and cumulated degree-days after sowing. A linear relationship was also observed between the rank of the phytomer on which roots were emerging and cumulated degree-days or foliar stage. In the range of field situations tested (several years, sowing dates and planting densities), both equations gave an accurate prediction of the timing of root emergence during the plant cycle.     

光强对木麻黄幼苗根系形态、解剖结构及其碳氮含量的影响

对光环境的灵敏响应使得森林中常见的光照异质性成为影响植物自我更新的关键因素,然而植物地下根系结构对光照的响应较为难测而缺乏深入研究。为探究不同光强下木麻黄根系响应策略,以一年生木麻黄(Casuarina equisetifolia)幼苗为试验材料,模拟森林幼苗生长的林外(CK)、林缘(L1)、林窗(L2)和林下光环境(L3)设置4种光照强度,测定及分析木麻黄幼苗的生长、根系形态、细根解剖结构及碳氮含量等指标。结果表明:(1) L1下,幼苗采取维持高度,降低横向生长的方式,保证正常累积生物量,随光照强度的下降,株高、地径、叶片生物量及地上部分生物量逐渐下降。(2)在根系表型上,幼苗随光限制的加重呈现抑制纵伸但促进根系的横向生长,其中总根长、根平均直径及根体积达到显著差异。在径级结构上,细根发育程度随光照减弱而下降;而适当的遮光(L1)促进粗根生长但L3时除根尖数较CK上升外,根长度、根表面积、根体积均显著下降。(3)1-3级细根解剖变化较大,相较CK,1级细根皮层细胞面积显著增加,但根半径、维管柱结构、表皮厚度等指标则显著下降,2级细根根半径、皮层细胞面积、表皮厚度明显减少,但维管柱结构仅在L2、L3时显著下降;3级细根根半径、皮层细胞面积和维管柱面积均较CK显著增大,L1时维管柱结构下降,但随光照减弱加重,维管柱面积和中柱占比均明显增加。(4)在碳氮含量上,CK与L1无显著差异,TC在L2时显著下降,TN则在L2时显著上升,TC、TN均在L3达到最大,而C∶N随光强降低逐渐下降。综上所述,光限制时,木麻黄生物量及碳分配稳定根茎部分生长,采取“弱化吸收,强化储存”收缩型生长策略;当限制加重时,光合和呼吸作用失衡导致植物对细根投入养分的浪费,并最终造成林木死亡。研究结果为林下植被的更新提供理论参考。     

Root System Asymmetry of Mediterranean Pines

Three groups of Mediterranean pines were examined to describe the development of root symmetry on sites characterized by shallow soils and low water availability. Sampling included: (1) 3-year-old planted seedlings of Pinus halepensis Mill. taken from Sithonia Halkidiki, northern Greece, (2) 5-year-old natural regenerated seedlings of Pinus brutia Ten. taken from Kedrinos Lofos, Thessaloniki and (3) 65-year-old trees of Pinus brutia taken from Kedrinos Lofos, Thessaloniki. Root system symmetry was examined by measuring the number, the diameter, the cross-sectional area (CSA), the root area index (RAI) and the length of the lateral roots of each root system, and by analyzing their distribution around the stem. Above-ground plant symmetry was also estimated. The findings of the study indicated that there was an asymmetric root system in all three groups that is characterized by the concentration of the main laterals along the contour lines instead of uphill or downhill; however, the asymmetry was much higher in the young plants. This asymmetry was not correlated with the above-ground plant growth form, which was found to be symmetric. The asymmetric development of root can be attributed to the shallow soil and the high mechanical resistance of the underground bedrock that stopped the taproot growth, restricted the root penetration in the deeper layers and obliged the roots to elongate towards the surface soil layers, where there is more available water.     

孑遗蕨类中华水韭根系发育的研究

以发育良好的中华水韭植株为材料,用常规半薄切片法,详细观察了根的发育及其根系的特征,并讨论了水韭根的内外两种起源途径、不同粗细根的结构功能、分支及横隔的生物学意义,为探讨古老维管植物的系统演化及濒危原因提供形态学依据。结果显示:(1)中华水韭成熟植株没有主根,有近百条浅棕色管状根,既有内起源根,也有外起源根,且每条根都有多回二歧分支。(2)二歧分支的发生一般频率密集且为不均等分裂,根越细分支越早,而且分支频率越密集;二歧分支处都有由2~3层细胞组成的永久性横隔,即使在老根内这种横隔也始终存在。(3)子根尖的部分皮层细胞能够直接转化成表皮,子根尖粗细不等。研究认为,中华水韭有茎起源根和根托起源根,皮层细胞具有特殊的分化能力,横隔是古生态的高能环境所造成的适应性结构,其根系具有旺盛的再生能力及高度的复杂性。     

Nutrient uptake relationship to root characteristics of rice

Data on root parameters and distribution are important for an improved understanding of the factors influencing nutrient uptake by a crop. Therefore, a study was conducted on a Crowley silt loam at the Rice Research and Extension Center near Stuttgart, Arkansas to measure root growth and N, P and K uptake by three rice (Oryza sativa L.) cultivars at active tillering (36 days after emergence (DAE)), maximum tillering (41 DAE), 1.25 cm internode elongation (55 DAE), booting (77 DAE) and heading (88 DAE). Soil-root core samples were taken to a depth of 40 cm after plant samples were removed, sectioned into 5 cm intervals, roots were washed from soil and root lengths, dry weights and radii were measured. Root parameters were significantly affected by the soil depth × growth stage interaction. In addition, only root radius was affected by cultivar. At the 0- to 5-cm soil depth, root length density ranged from 38 to 93 cm cm^-3 throughout the growing season and decreased with depth to about 2 cm cm^-3 in the 35- to 40-cm depth increment. The increase in root length measured with each succeeding growth stage in each soil horizon also resulted in increased root surface area, hence providing more exposed area for nutrient uptake. About 90% of the total root length was found in the 0- to 20-cm soil depth throughout the season. Average root radius measured in the 0- to 5-cm and 35- to 40-cm depth increments ranged from 0.012 to 0.013 cm and 0.004 to 0.005 cm, respectively throughout the season. Total nutrient uptake by rice differed among cultivars only during vegetative growth. Differences in total nutrient uptake among the cultivars in the field appear to be related to absorption kinetics of the cultivars measured in a growth chamber study. Published with permission of the Arkansas Agricultural Experiment Station.     

Tillage and N fertilization effects on maize root growth and root:shoot ratio

Two methods for estimating the size of the maize (Zea mays l.) root system from soil cores taken in the field were compared. The spatially weighed block method of estimation accounted for variation in root density by using 18 samples per plant which varied in distance from plant and soil depth. This method was compared to an estimation which averaged all of the 18 samples together. Both methods gave surprisingly similar estimates for total root growth. Increased root growth in the surface soil layers, due to tillage and N fertilization, did not impact on the estimation of total root growth. Total root length remained unchanged or increased with N fertilization, while root weight remained the same or decreased. Root mass per length decreased with N fertilization. The estimated size of the root system was used to calculate root:shoot weight ratios. The largest root:shoot ratio was found in the vegetative stage and decreased throughout the rest of the season. In this field experiment, the estimated size of the root system at 8 weeks after planting was not significantly different from the size at silking or harvest. Nitrogen fertilization significantly decreased the root:shoot weight ratio. However, tillage did not significantly change the ratio.     

Root apical organization inArabidopsis thaliana ecotype ‘WS’ and a comment on root cap structure

Arabidopsis thaliana roots have closed apical organization with three initial tiers. The dermatogen/calyptrogen tier consists of two parts-the central initials form the columella root cap, and the peripheral initial cells form the protoderm (epidermis) and the peripheral root cap. These peripheral initials divide in a sequence to form a root cap consisting of interconnected cones. the periblem initial tier forms the ground meristem (cortex). For the first week after germination the periblem consists of one layer of initial cells. The peripheral cells of the tier divide periclinally and then anticlinally (a T-division) to form the two-layered cortex (outer cortex and endodermis). After about one week, all the peripheral cells have divided periclinally forming two initials; the outermost produces the outer cortex while the inner initial produces the endodermis and middle cortex layer. The latter two cells arise via a periclinal division. During this time, other cells within the tier divide periclinally to form a two-layered tier. The plerome forms the cells of the procambium (vascular cylinder) by simple anticlinal divisions followed by longitudinal divisions to fill out the cell files of the vascular cylinder. A survey (27 dicot species in 17 families) of roots with closed apical organization revealed that there are three different types of root cap-concentric cylinders of cells (e.g.Linum), interconnecting cones (e.g.Arabidopsis) or overlapping arcs (e.g.Gossypium). H Lambers Section editor     

Fine root architecture, morphology, and biomass of different branch orders of two Chinese temperate tree species

We have limited understanding of architecture and morphology of fine root systems in large woody trees. This study investigated architecture, morphology, and biomass of different fine root branch orders of two temperate tree species from Northeastern China—Larix gmelinii Rupr and Fraxinus mandshurica Rupr —by sampling up to five fine root branch orders three times during the 2003 growing season from two soil depths (i.e., 0–10 and.10–20 cm). Branching ratio (R _b) differed with the level of branching: R _b values from the fifth to the second order of branching were approximately three in both species, but markedly higher for the first two orders of branching, reaching a value of 10.4 for L. gmelinii and 18.6 for F. mandshurica. Fine root diameter, length, SRL and root length density not only had systematic changes with root order, but also varied significantly with season and soil depth. Total biomass per order did not change systematically with branch order. Compared to the second, third and/or fourth order, the first order roots exhibited higher biomass throughout the growing season and soil depths, a pattern related to consistently higher R _b values for the first two orders of branching than the other levels of branching. Moreover, the differences in architecture and morphology across order, season, and soil depth between the two species were consistent with the morphological disparity between gymnosperms and angiosperms reported previously. The results of this study suggest that root architecture and morphology, especially those of the first order roots, should be important for understanding the complexity and multi-functionality of tree fine roots with respect to root nutrient and water uptake, and fine root dynamics in forest ecosystems.