植物防御反应与动物免疫应答的的比较及其对应性初探

动物经过数亿年的进化直到脊椎动物阶段出现了渐为完整的免疫系统。植物在与各种病原的共进化过程中亦发展了身的防御系统。随着对植物抗病性的概念及植物防御机制的不断认识,人们发现它与动物的免疫应答有着众多的对应性,这些对应性是否表明植物的防御系统与动物的免疫系统在进化具有同一性,是否表明它们在防御反应上具有类似的机制值得深思。     

植物防御信号分子β-罗勒烯的研究进展

植物为了适应复杂的生活环境,在长期的进化过程中,发展起来了一套与动物免疫系统相似的、高度复杂的防御系统。研究表明,众多的信号分子在调控植物防御反应中起着重要作用。β-罗勒烯是一种与植物防御启动密切相关的信号分子。本文综述了信号分子罗勒烯的结构组成、自然分布、化学合成、植物防御以及信号途径等方面的研究进展,为其进一步的理论研究及农业应用提供了有益参考。     

两栖类皮肤抗菌多肽及其应用

抗菌多肽广泛分布于动物、植物,用于抵御细菌、真菌、病毒和原虫,在进化上是一类非常古老而有效的天然防御物质。两栖动物的后天获得性免疫系统与哺乳动物相比极为脆弱,它们在长期的进化历程中演化形成了一套非常有效的抵御微生物侵袭的防御系统,这套系统主要就是其裸露皮肤表面的抗菌多肽(又称初级免疫或者先天免疫系统)。本文结合本实验室近年的研究工作,对两栖类皮肤抗菌多肽的结构、功能及应用作一简要综述。     

天然免疫分子及其进化趋势

识别和抗御微生物感染是多细胞生物的本能。在进化关系很远的生物中,如人类和果蝇,甚至植物,都存在这种天然免疫识别和防御机能,表明许多宿主防御基因及其产物具有共同的古老的起源,但又存在结构和功能的多样性。本文描述了一些哺乳动物和昆虫中有关于免疫识别的蛋白并调查了其同系物的进化分布情况。分析证实了哺乳动物和昆虫的天然免疫系统重要结构和功能的多样性,列举了一些关于蛋白进化趋势的例子。     

毒液主导的动物生存适应

捕食与防御是物种生态适应及生理生态学的核心内容.动物毒液系统是动物实施捕食与防御功能的典型"生化武器系统",对理解动物生态适应的生理学机制具有重要意义.各种有毒动物的毒素分子具有高度的结构和功能多样性.人们从有毒动物毒液中鉴定到了丰富多样的生物学活性,包括神经毒活性、酶活性、细胞毒活性、抗菌活性、凝集素活性、溶血活性、抗栓活性、凝血活性、免疫调节活性、酶类抑制剂活性、缓激肽增强活性和抗病毒活性等.有毒动物利用毒素的高亲和性和高选择性作用于细胞膜、离子通道、受体或酶影响神经系统、运动系统、心脑血管系统和免疫系统,从而实施快速、高效的捕食和防御.而捕食者为了捕食有毒动物,针对有毒动物的协同进化也一直在进行.本文对有毒动物捕食和防御的分子基础、药理学功能多样性和几类典型有毒动物的捕食和防御相关的适应机制进行了介绍.     

食果动物与被取食植物的相互关系:协同进化?

在种子传播过程中动植物是否存在协同进化关系一直是争论的焦点。有观点认为,植物通过食果动物对其种子的传播可能获得逃避种子捕食者、占据新的生境斑块和基因流动等好处,而动物通过消化果肉获得营养和能量作为回报,动植物彼此相互作用,进而可能建立协同进化关系。动植物之间还可能发生在种、属或科水平以上的多物种的多配协同进化,或者通过关键种的协同进化来带动其他食果动物和植物相关性状的进化。“果肉防御假说”则认为果肉原本是保护种子的防御组织,后来才进化成为吸引食果动物以促进种子传播的物质。然而,食果动物和植物一对一的协同进化的例证并不多见;适合种子萌发和生长的环境在时空上难以确定;食果动物和植物的进化速度不一致;植物与种子传播者的选择压力存在着高度的不对称和不平衡,加上环境因素的重要影响,这种选择压力受到极大的限制而有可能变得不显著。种子传播中动植物在进化意义上的关系尚需进一步研究。未来研究应对食果动物和植物关系的复杂性和多样性有足够的认识。通过对系统发育中相联系的不同种的动植物关系的比较研究来揭示动植物关系对物种分化的影响,有可能为检验食果动物和植物之间的协同进化关系提供新的证据。食果动物传播种子对植物群落动态变化的影响、动植物关系和生物多样性保护等仍将是该领域研究的热点。     

昆虫与植物的协同进化:寄主植物-铃夜蛾-寄生蜂相互作用

近数10年内,Ehrlich和Raven于1964年提出的协同进化理论及Jermy于1976年提出的顺序进化理论极大地促进了对昆虫与植物相互作用的研究。文章首先简要介绍有关理论,对植食性昆虫与植物关系研究的若干核心问题进行评述。主要问题包括(1)植食性昆虫如何选择寄主植物?(2)植物次生物质是否作为植物防御昆虫取食的重要屏障?(3)昆虫能否适应植物的化学防御?(4)植食性昆虫寄主范围是否是从广到专演化的?随之,作者结合对铃夜蛾Helicoverpa系统研究取得的结果,对上述问题做了进一步的论证和阐述。最后,在继承协同进化、顺序进化等理论精髓的基础上,根据当今三营养级相互作用领域的研究新进展,提出一个新的假说,即多营养级协同进化假说。该假说肯定植物次生物质在植物防御和昆虫识别寄主植物上的重要作用,同时把其他营养级并列放入交互作用的系统,特别强调第三营养级在昆虫与植物关系演化过程中的参与和寄主转移与昆虫食性专化和广化的联系。     

昆虫肠道防御及微生物稳态维持机制

在长期的进化过程中,昆虫形成了独特的肠道防御系统,主要由物理屏障和免疫系统共同作用来抵御外来微生物的入侵。如大部分后生动物一样,昆虫肠道上皮细胞无时无刻不与微生物接触,其种类从有益的共生菌、随食物进入的微生物到影响宿主生命的病原菌。在这样一种复杂的环境中,为了实现防御肠道病原微生物的同时又能维持共生微生物稳定的目的,宿主肠道上皮细胞必须在免疫应激和免疫耐受之间保持一种稳态平衡。Duox-ROS免疫系统和免疫缺陷(immune deficiency,Imd)信号通路作为肠道免疫反应的基本途径,必然参与调节此过程。本文从昆虫肠道防御组成、肠道免疫信号通路作用分子机制以及肠道免疫系统在肠道微生物群落稳态维持中的作用的最新研究进展进行综述。     

无颌类脊椎动物适应性免疫系统的进化

适应性免疫系统的起源与进化问题一直是人们研究的热点, 以七鳃鳗为代表的无颌类脊椎动物, 被普遍认为处在进化出适应性免疫系统的边缘。因此, 研究无颌类脊椎动物适应性免疫的机制, 对揭示适应性免疫系统的起源与进化具有重要意义。研究表明, 无颌类在一定范围内具有高等脊椎动物特有的适应性免疫特征, 并发现了一些在结构或功能上与高等脊椎动物免疫相关基因同源的免疫因子。文章就近年来对无颌类脊椎动物适应性免疫系统机制的研究进展作一概述, 为进一步深入研究脊椎动物适应性免疫系统的起源与进化提供有益的参考。     

植物警戒色的研究进展

植物为适应植食动物的取食压力而进化出物理、化学等多种防御机制,以把植食伤害降到最低程度,但动物不断的抽样尝试行为还是让有防御行为的植物受到伤害。因此,向潜在的植食动物传达自己的防御信号对植物是有益的。颜色作为一种稳定有效的视觉信号通常是花和果实的诱惑信号,某些情况下也是一种警戒防御信号,植食动物经过抽样学习后能识别这种防御信号并主动回避,从而形成了植物的警戒色。起源于猎物-捕食者关系的警戒色理论在动物界得到了充分研究,但植物警戒色却不为人所知,直到2001年Hamilton关于秋季树叶颜色的信号假说公开发表后,才引起人们对植物警戒色的初步研究。如今在早秋变色树种、幼叶、多剌植物、植物繁殖器官都发现了警戒色的一些例证,尽管有些还不太明确甚至存在争议,但至少为植物警戒色的进一步研究奠定了基础。植物营养体颜色在时空上的多态性变化值得人们更深入地研究,防御权衡假说也预示了防御有害植食动物的警戒作用存在于繁殖器官的可能性,研究它们生理和生态适应意义有利于人们更深程度地理解植物-动物之间的复杂关系。     

The Genetic and Molecular Basis of Plant Resistance to Pathogens

Plant pathogens have evolved numerous strategies to obtain nutritive materials from their host,and plants in turn have evolved the preformed physical and chemical barriers as well as sophisticated two-tiered immune system to combat pathogen attacks.Genetically, plant resistance to pathogens can be divided into qualitative and quantitative disease resistance,conditioned by major gene(s) and multiple genes with minor effects,respectively.Qualitative disease resistance has been mostly detected in plant defense against biotrophic pathogens,whereas quantitative disease resistance is involved in defense response to all plant pathogens,from biotrophs,hemibiotrophs to necrotrophs.Plant resistance is achieved through interception of pathogen-derived effectors and elicitation of defense response.In recent years,great progress has been made related to the molecular basis underlying host-pathogen interactions.In this review,we would like to provide an update on genetic and molecular aspects of plant resistance to pathogens.     

The plant hypersensitive response: concepts,control and consequences

The hypersensitive defence response is found in all higher plants and is characterized by a rapid cell death at the point of pathogen ingress. It is usually associated with pathogen resistance, though, in specific situations, it may have other consequences such as pathogen susceptibility, growth retardation and, over evolutionary timescales, speciation. Due to the potentially severe costs of inappropriate activation, plants employ multiple mechanisms to suppress inappropriate activation of HR and to constrain it after activation. The ubiquity of this response among higher plants despite its costs suggests that it is an extremely effective component of the plant immune system.     

Plant innate immunity: An updated insight into defense mechanism

Plants are invaded by an array of pathogens of which only a few succeed in causing disease. The attack by others is countered by a sophisticated immune system possessed by the plants. The plant immune system is broadly divided into two, viz. microbial-associated molecular-patterns-triggered immunity (MTI) and effector-triggered immunity (ETI). MTI confers basal resistance, while ETI confers durable resistance, often resulting in hypersensitive response. Plants also possess systemic acquired resistance (SAR), which provides long-term defense against a broad-spectrum of pathogens. Salicylic-acid-mediated systemic acquired immunity provokes the defense response throughout the plant system during pathogen infection at a particular site. Trans-generational immune priming allows the plant to heritably shield their progeny towards pathogens previously encountered. Plants circumvent the viral infection through RNA interference phenomena by utilizing small RNAs. This review summarizes the molecular mechanisms of plant immune system, and the latest breakthroughs reported in plant defense. We discuss the plant–pathogen interactions and integrated defense responses in the context of presenting an integral understanding in plant molecular immunity.     

Proteomic analysis of S-nitrosylated proteins in Arabidopsis thaliana undergoing hypersensitive response

Nitric oxide (NO) has a fundamental role in the plant hypersensitive disease resistance response (HR), and S-nitrosylation is emerging as an important mechanism for the transduction of its bioactivity. A key step toward elucidating the mechanisms by which NO functions during the HR is the identification of the proteins that are subjected to this PTM. By using a proteomic approach involving 2-DE and MS we characterized, for the first time, changes in S-nitrosylated proteins in Arabidopsis thaliana undergoing HR. The 16 S-nitrosylated proteins identified are mostly enzymes serving intermediary metabolism, signaling and antioxidant defense. The study of the effects of S-nitrosylation on the activity of the identified proteins and its role during the execution of the disease resistance response will help to understand S-nitrosylation function and significance in plants.     

Host-microbe interactions: shaping the evolution of the plant immune response

The evolution of the plant immune response has culminated in a highly effective defense system that is able to resist potential attack by microbial pathogens. The primary immune response is referred to as PAMP-triggered immunity (PTI) and has evolved to recognize common features of microbial pathogens. In the coevolution of host-microbe interactions, pathogens acquired the ability to deliver effector proteins to the plant cell to suppress PTI, allowing pathogen growth and disease. In response to the delivery of pathogen effector proteins, plants acquired surveillance proteins (R proteins) to either directly or indirectly monitor the presence of the pathogen effector proteins. In this review, taking an evolutionary perspective, we highlight important discoveries over the last decade about the plant immune response.     

肠道菌群参与宿主免疫应答的作用及机制研究进展

肠道菌群作为动物体内重要的组成部分,能够直接参与机体的免疫调控作用,促进机体免疫系统发育,维持正常免疫功能。同时,免疫系统对肠道菌群又有调控和制约作用。本文主要综述了肠道菌群的组成以及影响肠道菌群变化的因素,系统阐述了肠道菌群与疾病相互作用的机制,总结了肠道菌群在宿主感染与免疫应答中的作用,为开展肠道菌群参与机体免疫应答的机制方面的研究提供新的思路。     

Responses of Arabidopsis thaliana to challenge by Pseudomonas syringae

Plants are continually exposed to a variety of potentially pathogenic microbes, and the interactions between plants and pathogenic invaders determine the outcome, disease or disease resistance. To defend themselves, plants have developed a sophisticated immune system. Unlike animals, however, they do not have specialized immune cells and, thus all plant cells appear to have the innate ability to recognize pathogens and turn on an appropriate defense response. Using genetic, genomic and biochemical methods, tremendous advances have been made in understanding how plants recognize pathogens and mount effective defenses. The primary immune response is induced by microbe-associated molecular patterns (MAMPs). MAMP receptors recognize the presence of probable pathogens and evoke defense. In the co-evolution of plant-microbe interactions, pathogens gained the ability to make and deliver effector proteins to suppress MAMP-induced defense responses. In response to effector proteins, plants acquired R-proteins to directly or indirectly monitor the presence of effector proteins and activate an effective defense response. In this review we will describe and discuss the plant immune responses induced by two types of elicitors, PAMPs and effector proteins.     

反式-2-己烯醛在植物防御反应中的作用

反式-2-己烯醛是绿色植物释放的一种小分子挥发性物质, 在调节植物生长发育和抵抗各种环境胁迫中发挥重要作用。已有研究表明, 反式-2-己烯醛可抑制植物根系生长, 具有较高的抑菌和抗虫活性, 也可以作为植物间的“信使”来传递防御信号。该文系统综述了反式-2-己烯醛的生物合成、代谢途径及其在生物胁迫防御反应中的重要作用, 提出了研究中存在的问题及未来的研究方向和建议, 以期为深入揭示反式-2-己烯醛的作用机理提供参考。     

The function of small RNAs in plant biotic stress response

Small RNAs(s RNAs) play essential roles in plants upon biotic stress. Plants utilize RNA silencing machinery to facilitate pathogen-associated molecular pattern-triggered immunity and effector-triggered immunity to defend against pathogen attack or to facilitate defense against insect herbivores. Pathogens, on the other hand, are also able to generate effectors and s RNAs to counter the host immune response. The arms race between plants and pathogens/insect herbivores has triggered the evolution of s RNAs,RNA silencing machinery and pathogen effectors. A great number of studies have been performed to investigate the roles of s RNAs in plant defense, bringing in the opportunity to utilize s RNAs in plant protection. Transgenic plants with pathogen-derived resistance ability or transgenerational defense have been generated, which show promising potential as solutions for pathogen/insect herbivore problems in the field. Here we summarize the recent progress on the function of s RNAs in response to biotic stress, mainly in plant-pathogen/insect herbivore interaction,and the application of s RNAs in disease and insect herbivore control.     

Arabidopsis defense response against Fusarium oxysporum

The plant fungal pathogen Fusarium oxysporum (Fox) is the causal agent of root rot or wilt diseases in several plant species, including crops such as tomato (Solanum lycopersicum), banana (Musa sapientum) and asparagus (Asparagus officinalis). Colonization of plants by Fox leads to the necrosis of the infected tissues, a subsequent collapse of vascular vessels and decay of the plant. Plant resistance to Fox appears to be monogenic or oligogenic depending on the host. Perception of Fox by plants follows the concept of elicitor-induced immune response, which in turn activates several plant defense signaling pathways. Here, we review the Fox-derived elicitors identified so far and the interaction among the different signaling pathways mediating plant resistance to Fox.