外生菌根真菌对植物根病原菌拮抗作用的研究

■的15株外生菌根真菌在琼脂平板上对6株植物病原菌的拮抗作用试验结果表明,美味红菇、劣味乳菇、毛边滑锈伞、大毒滑锈伞等菌根菌对试验病原菌的营养菌丝具有明显的拮抗作用。菌根菌的培养液中含有抑制根病原菌的活性物质,且对高温稳定。外生菌根菌在纯培养条件下对病原菌的拮抗作用包括菌丝体对峙生长作用,重寄生作用和拮抗活性物质作用。其中菌丝体的重寄生作用在抗病效应中起重要作用。     

儿茶酚胺激动剂和阻断剂对大鼠胃粘膜适应性细胞保护作用的影响

本文观察了儿茶酚胺激动剂和阻断剂对大鼠慢性应激诱发的胃粘膜适应性细胞保护作用的影响,并分析内源性生长抑素与保护作用的关系。结果表明,慢性应激诱导的大鼠胃粘膜适应性保护作用在交感神经切除后完全消失,多巴胺或异丙肾上腺素使保护作用部分恢复,去甲肾上腺素无作用;在交感神经完整大鼠,心得安或氟哌啶醇可抑制慢性应激诱发的保护作用,酚妥拉明无作用。血浆生长抑素在应激及交感神经切除后均无显著变化。提示慢性应激时交感肾上腺系统的激活参与了大鼠胃粘膜适应性保护作用,且可能通过多巴胺及肾上腺能β受体介导。     

内吞作用和外排作用

在细胞内,内吞作用和外排作用是2种非常重要的运输物质的方式,而其中受体介导的内吞作用更是一个不可忽视的过程,就内吞作用和外排作用的机制做一综述。     

陷窝蛋白-1在肿瘤发生发展中的双重性

陷窝蛋白-1(caveolin-1)是陷窝(caveolae)的主要结构成分,在细胞内吞、胆固醇运输、信号传导、肿瘤发生中发挥重要作用。陷窝蛋白-1在肿瘤中发挥抑癌作用还是促癌作用一直存在争论:在乳腺癌、肺癌、卵巢癌中发挥抑癌基因样作用,而在前列腺癌中则发挥癌基因样作用。这一现象提示,陷窝蛋白-1在不同肿瘤中发挥作用可能不同,其生物学作用具有双重性。本文将对陷窝蛋白-1的结构、分布、表达及与肿瘤的关系作一综述。     

冷暴露小鼠尾动脉舒缩功能变化以及血管活性药物的作用特征

目的：研究不同温度条件下血管舒缩功能变化及哌唑嗪、山莨菪碱扩张血管作用变化特征,评价VitE在低温条件下的内皮保护作用,探讨上述药物在冻伤预防过程中的应用前景。方法：利用血管条技术,观察小鼠尾动脉血管在8℃、16℃、25℃、37℃四个温度条件下的收缩及舒张反应特点,比较哌唑嗪、山莨菪碱在不同温度条件下扩血管作用差异。在冷暴露处理的同时预敷Vit E,观察其对低温条件下血管内皮依赖性舒张功能的改善作用。结果：①不同温度条件下苯肾上腺素诱发的血管收缩反应存在明显差异,温度越低,收缩幅度越小;②硝普钠浓度依赖的扩血管作用随着温度的降低明显增强;③与硝普钠作用特点类似,哌唑嗪、山莨菪碱在低温条件下的扩血管作用强于37℃组;④低温能够降低乙酰胆碱内皮依赖的扩血管作用,Vit E能够剂量依赖地对抗低温的影响。结论：随着温度的降低,苯肾上腺素作用下的血管收缩明显减弱,平滑肌靶点扩血管药物的作用显著增强。乙酰胆碱内皮依赖的扩血管作用随温度的下降有所降低,Vit E能够在一定程度上减小低温对乙酰胆碱扩血管作用的影响。     

植物春化作用的分子机制及应用

植物能响应环境中的低温信号实现开花调控，这种经历低温促使植物开花的作用即为春化作用。本文结合国内外春化作用的研究进展，概述春化作用的发现和特点，阐述模式植物拟南芥及单子叶作物的春化作用分子机制，并举例说明春化作用在农业、园艺等方面的应用。     

马缨丹乙醇提取物对美洲斑潜蝇种群的控制作用

应用作用因子生命表方法以及在此基础上提出的干扰作用控制指数法评价了马缨丹(LantanacamaraL.)乙醇提取物(干重1g·100mL-1)在美洲斑潜蝇LiriomyzasativaeBlanchard种群控制中的作用。结果表明,马缨丹乙醇提取物对保护菜豆(PhaseolusvagarisL.)免受美洲斑潜蝇为害起着明显的作用。处理区的干扰作用控制指数为0.135,即对美洲斑潜蝇的防治效果可达86.5%。马缨丹乙醇提取物对美洲斑潜蝇寄生性天敌的作用无影响。     

Aβ中枢及外周清除机制

β淀粉样蛋白(amyloid-βpeptide,Aβ)沉积是阿尔兹海默病(Alzheimer's disease,AD)的病理特征之一。Aβ在体内的清除途径包括:蛋白酶的降解作用、细胞的清除作用、血脑屏障的转运作用、脑脊液和组织间液淋巴引流作用和外周细胞及组织的清除作用。结合最新进展,本文综述了Aβ在中枢和外周的清除机制。     

植物防御反应中活性氧的产生和作用

活性氧在植物抗病性中起着重要的作用。本文将对其在防御反应中的产生和作用进行简要的论述。     

新型趋化因子CXCL17

趋化因子是一类具有趋化作用的细胞因子。CXCL17是2006年发现的CXC族趋化因子中的一个新成员。该因子有明显的促血管生成作用,由此可促进多种肿瘤的生长;然而在胰腺肿瘤中却通过抗肿瘤免疫等作用而抑制肿瘤的发生。除了在血管生成和肿瘤发生中的作用外,CXCL17还有抗菌抗炎作用,且在粘膜中有恒定表达,推测其在维持粘膜的无菌性中起一定作用。CXCL17如此多样的功能日益引起了人们的关注。本文介绍有关CXCL17的最新研究进展。     

The role of reactive oxygen species in cell growth: lessons from root hairs

Reactive oxygen species (ROS) play a diversity of roles in plants. In recent years, a role for NADPH oxidase-derived ROS during cell growth and development has been discovered in a number of plant model systems. These studies indicate that ROS are required for cell expansion during the morphogenesis of organs such as roots and leaves. Furthermore, there is evidence that ROS are required for root hair growth where they control the activity of calcium channels required for polar growth. The role of ROS in the control of root hair growth is reviewed here and results are highlighted that may provide insight into the mechanism of plant cell growth in general.     

Oxidative stress tolerance in plants: Novel interplay between auxin and reactive oxygen species signaling

Biotic and abiotic stress conditions produce reactive oxygen species (ROS) in plants causing oxidative stress damage. At the same time, ROS have additional signaling roles in plant adaptation to the stress. It is not known how the two seemingly contrasting functional roles of ROS between oxidative damage to the cell and signaling for stress protection are balanced. Research suggests that the plant growth regulator auxin may be the connecting link regulating the level of ROS and directing its role in oxidative damage or signaling in plants under stress. The objective of this review is to highlight some of the recent research on how auxin’s role is intertwined to that of ROS, more specifically H₂O₂, in plant adaptation to oxidative stress conditions.     

植物活性氧的产生及其作用和危害

活性氧(ROS)是一类由O2转化而来的自由基或具有高反应活性的离子或分子。植物消耗的O2约有1%在叶绿体、线粒体、过氧化物酶体等多种亚细胞单位中被转化成了ROS。ROS有益或有害取决于它在植物体内的浓度。低浓度的ROS作为第二信使能在植物细胞信号转导途径中介导多种应答反应,高浓度的ROS则引起生物大分子的氧化损伤甚至细胞死亡。植物体内ROS产生和清除之间的平衡十分重要,并由一套有效的酶促和非酶促抗氧化系统来监控。该文主要系统介绍了植物ROS的种类、产生部位、在信号转导中的作用及其对植物细胞造成的主要伤害等方面的研究进展,为利用基因工程手段来提高植物对环境胁迫的抗性提供信息和思路。     

Reactive oxygen species and temperature stresses: A delicate balance between signaling and destruction

Temperature stress can have a devastating effect on plant metabolism, disrupting cellular homeostasis, and uncoupling major physiological processes. A direct result of stress-induced cellular changes is the enhanced accumulation of toxic compounds in cells that include reactive oxygen species (ROS). Although a considerable amount of work has shown a direct link between ROS scavenging and plant tolerance to temperature stress, recent studies have shown that ROS could also play a key role in mediating important signal transduction events. Thus, ROS, such as superoxide (O₂^–), are produced by NADPH oxidases during abiotic stress to activate stress-response pathways and induce defense mechanisms. The rates and cellular sites of ROS production during temperature stress could play a central role in stress perception and protection. ROS levels, as well as ROS signals, are thought to be controlled by the ROS gene network of plants. It is likely that in plants this network is interlinked with the different networks that control temperature stress acclimation and tolerance. In this review paper, we attempt to summarize some of the recent studies linking ROS and temperature stress in plants and propose a model for the involvement of ROS in temperature stress sensing and defense.     

NO and ROS implications in the organization of root system architecture

Over the past decades the role of nitric oxide (NO) and reactive oxygen species (ROS) in signaling and cellular responses to stress has witnessed an exponential trend line. Despite advances in the subject, our knowledge of the role of NO and ROS as regulators of stress and plant growth and their implication in signaling pathways is still partial. The crosstalk between NO and ROS during root formation offers new domains to be explored, as it regulates several plant functions. Previous findings indicate that plants utilize these signaling molecules for regulating physiological responses and development. Depending upon cellular concentration, NO either can stimulate or impede root system architecture (RSA) by modulating enzymes through post-translational modifications. Similarly, the ROS signaling molecule network, in association with other hormonal signaling pathways, control the RSA. The spatial regulation of ROS controls cell growth and ROS determine primary root and act in concert with NO to promote lateral root primordia. NO and ROS are two central messenger molecules which act differentially to upregulate or downregulate the expression of genes pertaining to auxin synthesis and to the configuration of root architecture. The investigation concerning the contribution of donors and inhibitors of NO and ROS can further aid in deciphering their role in root development. With this background, this review provides comprehensive details about the effect and function of NO and ROS in the development of RSA.     

活性氧对植物自噬调控的研究进展

自噬是一种在真核生物中高度保守的降解细胞组分的生物过程, 在饥饿、衰老和病菌感染等过程中起关键作用。而活性氧是有氧生物在正常或胁迫条件下产生的一种代谢副产物, 在植物的生长发育、胁迫适应和程序性细胞死亡过程中起重要作用。最新研究结果表明, 当植物受到病菌感染产生超敏反应时活性氧和自噬在程序性细胞死亡、生长发育和胁迫适应过程中起重要调控作用。因此, 该文结合最新的研究进展, 从活性氧的种类及特点、自噬的分子基础以及活性氧在植物自噬中的作用等方面, 探讨了活性氧与植物自噬之间的信号转导关系。     

Reactive oxygen species and their role in plant defence and cell wall metabolism

Harnessing the toxic properties of reactive oxygen species (ROS) to fight off invading pathogens can be considered a major evolutionary success story. All aerobic organisms have evolved the ability to regulate the levels of these toxic intermediates, whereas some have evolved elaborate signalling pathways to dramatically increase the levels of ROS and use them as weapons in mounting a defence response, a process commonly referred to as the oxidative burst. The balance between steady state levels of ROS and the exponential increase in these levels during the oxidative burst has begun to shed light on complex signalling networks mediated by these molecules. Here, we discuss the different sources of ROS that are present in plant cells and review their role in the oxidative burst. We further describe two well-studied ROS generating systems, the NADPH oxidase and apoplastic peroxidase proteins, and their role as the primary producers of ROS during pathogen invasion. We then discuss what is known about the metabolic and proteomic fluxes that occur in plant cells during the oxidative burst and after pathogen recognition, and try to highlight underlying biochemical processes that may provide more insight on the complex regulation of ROS in plants.     

New insights into an old story: Pollen ROS also play a role in hay fever

Reactive oxygen species (ROS) can exhibit negative and benign traits. In plants, ROS levels increase markedly during periods of environmental stress, and defense against pathogen attack. ROS form naturally as a by-product of normal oxygen metabolism, and evenly play an essential role in cell growth. The short ROS lifespan makes them ideal molecules to act in cell signaling, a role they share in both plants and animals. A particular plant organism, the pollen grain, may closely interact with human mucosa and an allergic inflammatory response often results. Pollen grain ROS represent a first, crucial signal which primes and magnifies a cascade of events in the allergic response.