锌胁迫下小麦SSH文库的构建及初步分析

Zn是植物必需的微量元素,同时也是近年来造成环境污染的重金属元素之一.为了从基因表达水平揭示小麦Zn胁迫响应的分子机制,本研究利用抑制差减杂交(suppression subtractive hybridization,SSH)技术构建了Zn胁迫（0.5 mmol/L,1 mmol/L）下小麦的正反向SSH文库.从正反向文库中随机挑选阳性单克隆,并利用通用引物T7/Sp6对其进行验证. 结果显示,正反库中分别获得307和821个EST序列,其片段长度在200～1 000 bp之间,它们反映了Zn胁迫下特异响应的基因.利用BLASTn和BLASTx将这些EST序列进行比对分析,在正、反库中分别筛选出221和641个uniESTs,其中751个uniESTs被注释（包括正库中193个和反库中558个）.这些序列的功能主要涉及信号转导、抗氧化防御、转录与翻译、物质运输、核糖体结构、能量代谢,以及一些功能未知的基因.     

Expression and signal regulation of the alternative oxidase genes under abiotic stresses

Plants in their natural environment frequently face various abiotic stresses, such as drought, high salinity, and chilling. Plant mitochondria contain an alternative oxidase （AOX）, which is encoded by a small family of nuclear genes. AOX genes have been shown to be highly responsive to abiotic stresses. Using transgenic plants with varying levels of AOX expression, it has been confirmed that AOX genes are im- portant for abiotic stress tolerance. Although the roles of AOX under abiotic stresses have been extensively studied and there are several excellent reviews on this topic, the differential expression patterns of the AOX gene family members and the signal regulation of AOX gene（s） under abiotic stresses have not been extensively summarized. Here, we review and discuss the current progress of these two important issues.     

探讨干旱胁迫下植物的信号转导和基因表达

本文主要研究植物在外界胁迫信号的影响下经过第二信使及其下游蛋白激酶的传导反应,对基因表达进行的调控,以及在干旱胁迫信号下植物的感知、传递及其诱导基因的表达调控作用。     

浅谈在中学数学教学中如何渗透爱国教育

数学教学的目的,自然地应当表现为:通过教授数学知识,把知识的学习和能力的培养结合起来,通过知识的教学,培养学生的能力,在能力提高的基础上,不断发展和完善学生的素质。所谓爱国主义,就是一种体现人民群众对自已祖国具有深厚情感的崇高精神,是同促进历史进步密切联系在一起的。     

番茄AT-hook基因家族的鉴定及胁迫条件下的表达分析

AT-hook蛋白家族在植物生长发育、器官构建及逆境胁迫和激素信号应答中发挥重要作用。本研究在番茄基因组范围内,利用生物信息学方法对番茄AT-hook基因家族的成员、分布、结构和功能进行分析。结果表明,番茄AT-hook家族包含32个成员,分为3种类型,其中类型Ⅰ含有13个成员;遗传进化分析表明番茄AT-hook基因成员与拟南芥家族基因具有相似分类。利用实时荧光定量PCR对番茄32个基因开展组织表达分析,结果表明AT-hook基因具有表达差异,主要在根和花中表达较高。氧化胁迫分析结果表明,32个基因受ABA、SA、盐、高温和低温诱导表达,其中部分基因显著上调或下调表达,很可能参与了番茄逆境胁迫条件下的防御应答反应。本研究结果将为番茄AT-hook家族基因的深入研究提供依据,为进一步解析番茄AT-hook基因的功能奠定基础。     

不同福禄考品种对低温胁迫的生理响应及抗寒性综合评价

通过对14个福禄考品种在低温胁迫下相关生理指标进行分析,结果表明:可溶性糖含量随处理温度降低呈"升降升降"的变化趋势;可溶性蛋白含量随处理温度降低呈"降升降降"的变化趋势;不同品种脯氨酸、叶绿素、丙二醛含量和超氧化物歧化酶活性变化趋势不同,差异达到显著水平。运用主成分分析法和聚类分析法对14个福禄考品种进行抗寒性排序,将其分为3个抗寒等级:强抗寒品种为‘Sub-05’、‘Sub-Ja-03’和‘Sub-Ja-04’;中抗寒品种为‘Sub-Ja-01’、‘Sub-Ja-02’、‘Sub-06’、‘Sub-07’、‘Pan-02’和‘Pan-Ru-07’;弱抗寒品种为‘Pan-01’、‘Pan-Ru-06’、‘Pan-05’、‘Pan-04’和‘Pan-03’。丛生福禄考品种抗寒性优于锥花品种,与露地越冬观察的结果基本一致。     

盐穗木HcmiR172e和预测的靶基因HcTOE3的克隆及盐胁迫下的靶向关系分析

盐穗木(Halostachys caspica)广泛分布于新疆干旱盐碱地区,属于藜科极端耐盐的盐生灌木。从600 mmol?L-1 Na Cl处理48 h的盐穗木根的小RNA文库中筛选到差异极显著的HcmiR172e做为研究对象,利用盐穗木转录组数据预测其靶基因为HcTOE3,开展HcmiR172e-HcTOE3的分子克隆和胁迫表达相关性工作。通过同源克隆和RACE技术获得盐穗木HcmiR172e前体和HcTOE3全长序列;使用生物信息软件分析前体和靶基因信息及相关性;采用q RT-PCR技术检测了不同盐浓度(200、400和600 mmol?L-1 Na Cl)处理48 h的盐穗木HcmiR172e及预测的靶基因HcTOE3的表达变化。结果显示,克隆得到的HcmiR172e前体序列可形成颈环结构,各项指标符合前体要求。其靶基因HcTOE3 c DNA全长为1 744 bp,开放阅读框1 329 bp,在编码区有一个高度匹配HcmiR172e的结合位点(CTGCAGCATCATCAGGATTC);q RT-PCR分析结果表明HcmiR172e与其预测的靶基因HcTOE3均响应盐的处理,二者呈现一定的负相关性。后续将通过实验逐步阐明盐穗木HcmiR172e对HcTOE3在逆境中的靶向调控作用。     

高温胁迫对葡萄幼树叶绿素荧光特性和抗氧化酶活性的影响

为了探讨短期和长期高温处理后葡萄生理应答反应,本研究在人工气候室环境中模拟夏季高温发生时间段(10:00~16:00)对一年生盆栽葡萄‘夏黑’进行25°C、35°C、45°C温度处理,测定处理6 h时(短期)和150 h时(长期)功能叶片的叶绿素荧光动力学及抗氧化酶活性。结果显示:在35°C处理6 h时‘夏黑’叶片ΨEo、ΦEo、ETo/RC显著上升;45°C处理6 h时‘夏黑’各荧光参数表现出显著性差异,而在150 h时主要荧光参数恢复至原初水平;高温处理下‘夏黑’的叶绿素含量和SOD酶活增长趋势较不明显;35°C/45°C处理均导致抗氧化酶活性POD和CAT以及过氧化物产物MDA(丙二醇)表现出较强的增长趋势。综上可知,短期高温处理(6 h)‘夏黑’叶片PSII活性遭到破坏,但是长期高温处理(150 h)‘夏黑’的PSII活性得到恢复,推测‘夏黑’有较强高温逆境适应能力;高温逆境打破‘夏黑’氧化还原平衡,MDA含量增加。这些结果对于了解葡萄在高温胁迫下的耐受能力具有参考价值。     

Effects of groundwater salinity on the characteristics of leaf photosynthesis and stem sap flow in Tamarix chinensis

AimsThe objective of this study was to investigate the change pattern of leaves photosynthesis and stem sap flow of Tamarix chinensisin under different groundwater salinity, which can be served as a theoretical basis and technical reference for cultivation and management of T. chinensis in shallow groundwater table around Yellow River Delta.MethodsThree-year-old T. chinensis, one of the dominated species in Yellow River Delta, was selected. Plants were treated by four different salinity concentrations of groundwater—fresh water (0 g∙L^-1), brackish water (3.0 g∙L^-1), saline water (8.0 g∙L^-1), and salt water (20.0 g∙L^-1) under 1.2 m groundwater level. Light response of photosynthesis and the diurnal courses of leaf transpiration rate, stem sap flux velocity and environment factors under different groundwater salinity were determined via LI-6400XT portable photosynthesis system and a Dynamax packaged stem sap flow gauge based on stem-heat balance method, respectively.Important findings The result showed that groundwater salinity had a significant impact on photosynthesis efficiency and water consumption capacity of T. chinensis by influencing the soil salt. The net photosynthetic rate (P_n), maximum P_n, transpiration rate, stomatal conductance, apparent quantum yield and dark respiration rate increased first and then decreased with increasing groundwater salinity, while the water use efficiency (WUE) continuously decreased. The mean P_n under fresh water, brackish water and salt water decreased by 44.1%, 15.1% and 62.6%, respectively, compared with that under saline water (25.90 µmol∙m^-2∙s^-1). The mean WUE under brackish water, saline water and salt water decreased by 25.0%, 29.2% and 41.7%, respectively, compared with that under fresh water (2.40 µmol∙mmol^-1). With the increase of groundwater salinity from brackish water to salt water, light saturation point of T. chinensisdecreased while the light compensation point increased, which lead to the decrease of light ecological amplitude and light use efficiency. Fresh water and brackish water treatment helped T. chinensis to use low or high level light, which could significantly improve the utilization rate of light energy. The decrease in P_n of T. chinensis was mainly due to non-stomatal limitation under treatment from saline water to fresh water, while the decrease in P_n of T. chinensis was due to stomatal limitation from saline water to salt water. With increasing groundwater salinity, stem sap flux velocity of T. chinensis increased firstly and then decreased, reached the maximum value under saline water. The mean stem sap flux velocity under fresh water, brackish water and salt water decreased by 61.8%, 13.1% and 41.9%, respectively, compared with that under saline water (16.96 g·h^-1). Tamarix chinensis had higher photosynthetic productivity under saline water treatment, and could attained high WUE under severe water deprivation by transpiration, which was suitable for the growth of T. chinensis.     

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.