苹果褐斑病菌侵染对苹果叶片光合机构功能的影响

为了探究苹果褐斑病菌侵染对苹果叶片光合机构的伤害机制,以‘寒富’苹果为试材,研究苹果褐斑病菌侵染对苹果叶片光合作用和光系统功能的影响。结果表明：随褐斑病菌侵染加重（叶片感病程度分0、1、2、3、4和5级）,叶片的叶绿素a含量和总叶绿素含量持续下降,其中2～5级与对照相比差异显著,病菌侵染提高了叶片类胡萝卜素含量,但仅以2级与对照差异显著。苹果褐斑病菌侵染显著降低了叶片的净光合速率（Pn）,3～5级病叶的Pn分别较对照下降44．9％、56．6％和70．3％,而胞间CO2浓度（Ci）上升,说明非气孔因素是光合作用的主要限制因子。褐斑病菌侵柒影响了光合电子传递效率,随病菌侵染程度加重,光系统Ⅱ反应中心、供体侧放氧复合体（Wk）和受体侧（Vj）受到的伤害加重,并引起苹果叶片PSII的光合性能指数用PIABS和PSI受体侧末端电子受体的量子产额（φRo）急剧下降。褐斑病菌侵染加重了苹果叶片的膜脂过氧化程度,1～5级感病叶片的丙二醛（MDA）含量均显著高于对照,引发超氧化物歧化酶（SOD）及过氧化物酶（POD）活性的上调。以上结果表明,苹果褐斑病菌侵染引起叶片光合色素降解,对PSII反应中心、受体侧和供体侧造成伤害,进一步影响了PSI的电子传递效率,并导致叶片膜脂过氧化,造成苹果叶片光合能力下降。     

Does the photosynthetic light‐acclimation need change in leaf anatomy?

There is a strong correlation between leaf thickness and the light‐saturated rate of photosynthesis per unit leaf area (P_max). However, when leaves are exposed to higher light intensities after maturation, P_max often increases without increasing leaf thickness. To elucidate the mechanism with which mature leaves increase P_max, the change in anatomical and physiological characteristics of mature leaves of Chenopodium album, which was transferred from low to high light condition, were examined. When compared with leaves subjected to low light continuously (LL leaves), the leaves transferred from low to high light (LH leaves) significantly increased P_max. The transfer also increased the area of chloroplasts facing the intercellular space (S_c) and maintained a strong correlation between P_max and S_c. The mesophyll cells of LL leaves had open spaces along cell walls where chloroplasts were absent, which enabled the leaves to increase P_max when they were exposed to high light (LH). However, the LH leaves were not thick enough to allow further increase in P_max to the level in HH leaves. Thus leaf thickness determines an upper limit of P_max of leaves subjected to a change from low to high light conditions. Shade leaves would only increase P_max when they have open space to accommodate chloroplasts which elongate after light conditions improve.     

特定化合物同位素分析技术在树木非结构性碳水化合物研究中的应用

特定化合物同位素分析(CSIA)可以实现对复杂基质中特定化合物稳定碳同位素组成(δ¹³C)的精确测定。应用此方法测定树木非结构性碳水化合物(NSC)中特定成分(如糖类、有机酸和糖醇)的δ¹³C,不仅能够追踪新同化的光合产物在树木中的运移及与外界的碳交换,还能够更敏感地指示树木生理状况对环境变化的响应。本文首先系统介绍了CSIA从样品采集、处理到δ¹³C测定的方法,然后综述了树木NSC中各成分之间及各成分在不同器官之间的δ¹³C差异,阐述了树木NSC的δ¹³C时间动态变化特征及内在机制,最后分析了NSC作为主要呼吸底物,其δ¹³C与树木呼吸释放CO₂的δ¹³C(δ¹³C_R)之间的联系,并针对CSIA分析技术在后光合分馏、树木逆境生理和年轮δ¹³C形成机制等研究的应用前景提出了展望。     

两种热带木质藤本幼苗形态、生长和光合能力对光强和养分的响应

比较了两种不同攀援习性,卷须缠绕种薄叶羊蹄甲（Bauhinia tenuiflora）和茎缠绕种刺果藤（Byttneria aspera）,木质藤本植物的形态、生长及光合特性对不同光强（4％、35％和全光照）和土壤养分（高和低）的响应。两种藤本植物大部分表型特征主要受光照的影响,而受土壤养分的影响较小。弱光促进地上部分生长,弱光下两种植物均具有较大的比叶面积（specific leaf area,SLA）、茎生物量比（stem mass ratio,SMR）和平均叶面积比（mean leaf area ratio,LARm）。高光强下,两种植物的总生物量和投入到地下部分的比重增加,具有更大的根生物量比（root mass ratio,RMR）、更多的分枝数、更高的光合能力（maximum photosynthetic rate,Pmax）和净同化速率（net assimilation rate,NAR）,综合表现为相对生长速率（relative growth rate,RGR）增加。两种藤本植物的Pmax与叶片含氮量的相关性均未达显著水平,但刺果藤的Pmax与SU志间呈显著的正相关,而薄叶羊蹄甲的Pmax与SLA之间相关性不显著。在相同光照强度和土壤养分条件下,卷须缠绕种薄叶羊蹄甲的RGR显著高于茎缠绕种刺果藤。薄叶羊蹄甲的RGR与NAR呈显著正相关,其RGR与SLA、平均叶面积比（EARm）及Pmax之间相关性不显著。刺果藤的RGR与NAR呈显著的正相关,而与SLA存在显著的负相关。上述结果表明,与土壤养分相比,光照强度可能是决定木质藤本分布更为重要的生态因子。卷须缠绕种薄叶羊蹄甲由于具有特化的攀援器官,在形态上和生理上具有更大的可塑性,这使得卷须缠绕种木质藤本在与其它植物的竞争中更具优势。     

Cytokinin Profiles in the Conifer Tree <Emphasis Type="Italic">Abies nordmanniana</Emphasis>: Whole-Plant Relations in Year-Round Perspective

Conifer trees are routinely manipulated hormonally to increase flowering, branching, or adjust crown shape for production purposes. This survey of internal cytokinin levels provides a background for such treatments in Abies nordmanniana, a tree of great economic interest. Reference points in the crown and root system were sampled destructively in 4- and 6-year-old trees and analyzed for a range of cytokinins by LC-MS/MS. No seasonal patterns were detected in the root samples, and a major portion of cytokinin was in conjugated forms. Dramatic and consistent seasonal changes occurred in the crown, at levels 17–65 times higher than in the root. Predominant among crown cytokinins was ZR, except in the needles where IPR was also prominent. Within the crown, cytokinin profiles in different organs differed consistently. The leader bud showed a pronounced mid-June minimum, and a maximum later in summer. Subapical buds showed the same June minimum but peaked in mid autumn at a much lower level. Maxima in these buds were preceded by peaks in the subapical stem. Parallel patterns were observed in homologous tissues on branches.This pattern is consistent with two surges beginning in the uppermost stem tissues leading to subsequent accumulation or stimulated production within the buds. Strong differential hormonal profiles between adjacent buds with different fates agree with recent evidence of localized cytokinin production. The data suggest a reduced role of root-derived cytokinins in crown development. Practical cytokinin treatments for crown-shape regulation require close attention to dosage as well as precise timing and positioning.     

Photosynthetic characteristics and effect of ATP in transgenic rice with phospho<Emphasis Type="Italic">enol</Emphasis>pyruvate carboxylase and pyruvate orthophosphate dikinase genes

In the untransformed rice (WT) and transgenic rice with the PEPC and PPDK genes (CK) we determined activities of C₄ photosynthetic enzymes, photosynthetic response to irradiance and temperature, the metabolic index of active oxygen, and the yield component factors. The activities of C₄ photosynthetic enzymes in WT were very low, while those of corresponding enzymes in CK were highly observable. Moreover, after adenosine triphosphate (ATP) treatment, and under high irradiance and high temperature, the net photosynthetic rate of CK increased by 17 and 12 %, respectively, as compared to that achieved without ATP treatment. The resistance of CK against photo-oxidation was enhanced under these conditions, and CK yield increased by 15 %. ATP treatment enhanced the photosynthetic productivity of CK, thereby proving that ATP is the key factor in enhancing the photosynthetic capacity of transgenic rice with C₄ gene. Our new technical approach can be used in breeding rice with high photosynthetic efficiency and high grain yield.     

Patch-clamp Capacitance Measurements and Ca2+ Imaging at Single Nerve Terminals in Retinal Slices

Visual stimuli are detected and conveyed over a wide dynamic range of light intensities and frequency changes by specialized neurons in the vertebrate retina. Two classes of retinal neurons, photoreceptors and bipolar cells, accomplish this by using ribbon-type active zones, which enable sustained and high-throughput neurotransmitter release over long time periods. ON-type mixed bipolar cell (Mb) terminals in the goldfish retina, which depolarize to light stimuli and receive mixed rod and cone photoreceptor input, are suitable for the study of ribbon-type synapses both due to their large size (~10-12 μm diameter) and to their numerous lateral and reciprocal synaptic connections with amacrine cell dendrites. Direct access to Mb bipolar cell terminals in goldfish retinal slices with the patch-clamp technique allows the measurement of presynaptic Ca²⁺ currents, membrane capacitance changes, and reciprocal synaptic feedback inhibition mediated by GABA_A and GABA_C receptors expressed on the terminals. Presynaptic membrane capacitance measurements of exocytosis allow one to study the short-term plasticity of excitatory neurotransmitter release ^14,15. In addition, short-term and long-term plasticity of inhibitory neurotransmitter release from amacrine cells can also be investigated by recordings of reciprocal feedback inhibition arriving at the Mb terminal ²¹. Over short periods of time (e.g. ~10 s), GABAergic reciprocal feedback inhibition from amacrine cells undergoes paired-pulse depression via GABA vesicle pool depletion ¹¹. The synaptic dynamics of retinal microcircuits in the inner plexiform layer of the retina can thus be directly studied.The brain-slice technique was introduced more than 40 years ago but is still very useful for the investigation of the electrical properties of neurons, both at the single cell soma, single dendrite or axon, and microcircuit synaptic level ¹⁹. Tissues that are too small to be glued directly onto the slicing chamber are often first embedded in agar (or placed onto a filter paper) and then sliced ^{20, 23, 18, 9}. In this video, we employ the pre-embedding agar technique using goldfish retina. Some of the giant bipolar cell terminals in our slices of goldfish retina are axotomized (axon-cut) during the slicing procedure. This allows us to isolate single presynaptic nerve terminal inputs, because recording from axotomized terminals excludes the signals from the soma-dendritic compartment. Alternatively, one can also record from intact Mb bipolar cells, by recording from terminals attached to axons that have not been cut during the slicing procedure. Overall, use of this experimental protocol will aid in studies of retinal synaptic physiology, microcircuit functional analysis, and synaptic transmission at ribbon synapses.     

水稻亚种间杂种F1光合特性研究

用绵恢725、蜀恢527和蜀恢881三个籼型恢复系、1个美国稻Lemont和1个爪哇稻香大粒作母本,与1个日本特早熟粳稻Kitaake杂交,研究了5个杂种F1及其亲本的光合生理表现.结果表明,在高光通量密度(Photosynthetic flux density,PFD)条件下,5个杂种F1净光合速率(Pn)明显高于双亲或双亲之一,推测亲本与杂种F1之间不同的Pn同叶片中Rubsico活性有关.杂种F1的比较中,在表观量子效率(ψ)、羧化效率(CE)、CO2补偿点(T)等方面,籼粳亚种间杂种F1(绵恢725/Kitaake、蜀恢527/Kitaake、蜀恢881/Kitaake)对2个亚种内杂种F1香大粒/Kitaake(粳爪交)、Lemont/Kitaake(不同生态型的粳粳交,美国稻属于特殊粳稻)具有明显的优势,而蜀恢881含有粳型血缘,蜀恢881/Kitaake也比典型籼粳亚种间杂种F1绵恢725/Kitaake、蜀恢527/Kitaake优势稍逊一筹.5个杂种F1因为具有不同的遗传差异而表现出不同的光合优势,在这方面,典型籼粳亚种间杂交蜀恢527/Kitaake、绵恢725/Kitaake要优于其他杂交种,说明亲本间遗传差异越大,其杂种F1的光合优势越强.