抗病原菌植物基因工程进展

植物病原菌给农林生产带来巨大的损失,植物基因工程在培育抗病原菌植物方面是传统育种技术的补充和发展,短短几年,在抗细菌和抗真菌植物基因工程方面出现了一些全新的成功策略,这些范例都是针对病原菌的生理结构、致病机理及与植物的相互关系。本文概括论述了这些策略的基本思路并对其局限性加以探讨。随着植物病理学、植物分子生物学和病原菌分子生物学的研究进展,新的抗性策略将会出现。     

植物与病原菌互作的蛋白质组学研究进展

深入认识植物与病原菌的识别方式、亲和性或非亲和性的互作模式,对于揭示植物-病原菌互作机制研究具有重要意义.利用蛋白质组学方法研究病原菌侵染植物过程,分析相关的基因和蛋白,有助于从分子水平上探究植物-病原菌相互作用机制.本文概述了植物-病原菌的互作机制,系统介绍了差异蛋白质组学分析方法在植物-病原真菌、植物-病原细菌两类互作系统中的应用,分析了植物与病原菌互作过程中可能涉及的差异表达功能蛋白,并对当前蛋白质组学技术在植物与病原菌互作研究中存在的诸多问题进行了探讨.     

Purification of bacterial exotoxins. The case of botulinum, tetanus, anthrax, pertussis and cholera toxins.

Bacterial protein toxins and their fragments have been isolated and purified for various reasons, including the development of efficient vaccines and for methods of identification of bacterial agents causing disease. This activity continues today but a new area of bacterial protein toxin research has recently emerged. Since it was shown that toxin molecules comprise several types of biological activity within their structural domains, it was suggested to use these domains (and their combinations) as biochemical tools for developing novel agents for disease imaging and and/or relieving. In this way eukaryotic cell-receptor specific fusion toxins have been developed to prevent malignancy in human. While human clinical trials of these preparations have only recently begun, the preliminary clinical findings are promising. Also fusion proteins which combine independent immunodominant epitopes from different antigens have also been developed thus opening a way for the generation of new vaccines for both human and veterinary use. Receptor binding fragments of microbial toxins when combined with other molecules may be useful in delivering these molecules into the cell. In this way novel agents may be developed with a potential for inducing specific changes at the molecular level for the correction of metabolic disorders causing human and animal diseases. Bacterial protein toxins such as anthrax, botulinum, cholera, pertussis and tetanus for which considerable progress has been achieved in structure-function analysis are promising candidates for such research. Particularly exciting appears the idea of extending this research to the cells of the nervous system, exploiting the unique specificity of the botulinum or tetanus toxin fragments which may bring long desired methods for treatment of various disorders of the nervous system. Data on functional domains of these toxins as well as methods of purification of the whole toxins and their fragments are considered in this review as they form a base for their further structure-function analysis and engineering applications.     

农杆菌-植物间基因转移的分子基础

植物病原细菌多以Ⅲ型分泌系统运送毒性因子或无毒基因产物到植物细胞,但根癌农杆菌利用Ⅳ型分泌系统转移致瘤基因片断T-DNA到植物细胞核,并整合到植物基因组,使植物产生肿瘤,作者将介绍vir基因的诱导、T-DNA的加工、T-DNA的转移,以及T-复合体运输的装备等方面的最新研究进展,以探讨农杆菌-植物间基因转移的分子基础,研究该系统转移基因的分子基础将有利于开发和改良植物遗传工程的载体工具;另外,农杆菌-植物作为一种模式植物病害系统,其研究也为植物-病原菌的基础理论研究提供参考。由于有些人体病原细菌也采用Ⅳ型分泌系统运送毒性因子到人体细胞,研究农杆菌-植物间的基因转移系统也有利于医学研究。     

Population level virulence in polymicrobial communities associated with chronic disease

Renewed studies of chronic infection have shifted the focus from single pathogens to multi-microbial communities as culture-independent techniques reveal complex consortia of microbes associated with c...     

RhoGTPases and inflammasomes: Guardians of effector-triggered immunity

Pathogens have evolved smart strategies to invade hosts and hijack their immune responses. One such strategy is the targeting of the host RhoGTPases by toxins or virulence factors to hijack the cytoskeleton dynamic and immune processes. In response to this microbial attack, the host has evolved an elegant strategy to monitor the function of virulence factors and toxins by sensing the abnormal activity of RhoGTPases. This innate immune strategy of sensing bacterial effector targeting RhoGTPase appears to be a bona fide example of effector-triggered immunity (ETI). Here, we review recently discovered mechanisms by which the host can sense the activity of these toxins through NOD and NOD-like receptors (NLRs).     

Helicobacter pylori VacA, a paradigm for toxin multifunctionality

Bacterial protein toxins alter eukaryotic cellular processes and enable bacteria to successfully colonize their hosts. In recent years, there has been increased recognition that many bacterial toxins are multifunctional proteins that can have pleiotropic effects on mammalian cells and tissues. In this review, we examine a multifunctional toxin (VacA) that is produced by the bacterium Helicobacter pylori. The actions of H. pylori VacA represent a paradigm for how bacterial secreted toxins contribute to colonization and virulence in multiple ways.     

From soil to gut: Bacillus cereus and its food poisoning toxins

Bacillus cereus is widespread in nature and frequently isolated from soil and growing plants, but it is also well adapted for growth in the intestinal tract of insects and mammals. From these habitats it is easily spread to foods, where it may cause an emetic or a diarrhoeal type of food-associated illness that is becoming increasingly important in the industrialized world. The emetic disease is a food intoxication caused by cereulide, a small ring-formed dodecadepsipeptide. Similar to the virulence determinants that distinguish Bacillus thuringiensis and Bacillus anthracis from B. cereus, the genetic determinants of cereulide are plasmid-borne. The diarrhoeal syndrome of B. cereus is an infection caused by vegetative cells, ingested as viable cells or spores, thought to produce protein enterotoxins in the small intestine. Three pore-forming cytotoxins have been associated with diarrhoeal disease: haemolysin BL (Hbl), nonhaemolytic enterotoxin (Nhe) and cytotoxin K. Hbl and Nhe are homologous three-component toxins, which appear to be related to the monooligomeric toxin cytolysin A found in Escherichia coli. This review will focus on the toxins associated with foodborne diseases frequently caused by B. cereus. The disease characteristics are described, and recent findings regarding the associated toxins are discussed, as well as the present knowledge on virulence regulation.     

The alphaviruses: gene expression, replication, and evolution.

The alphaviruses are a genus of 26 enveloped viruses that cause disease in humans and domestic animals. Mosquitoes or other hematophagous arthropods serve as vectors for these viruses. The complete sequences of the +/- 11.7-kb plus-strand RNA genomes of eight alphaviruses have been determined, and partial sequences are known for several others; this has made possible evolutionary comparisons between different alphaviruses as well as comparisons of this group of viruses with other animal and plant viruses. Full-length cDNA clones from which infectious RNA can be recovered have been constructed for four alphaviruses; these clones have facilitated many molecular genetic studies as well as the development of these viruses as expression vectors. From these and studies involving biochemical approaches, many details of the replication cycle of the alphaviruses are known. The interactions of the viruses with host cells and host organisms have been exclusively studied, and the molecular basis of virulence and recovery from viral infection have been addressed in a large number of recent papers. The structure of the viruses has been determined to about 2.5 nm, making them the best-characterized enveloped virus to date. Because of the wealth of data that has appeared, these viruses represent a well-characterized system that tell us much about the evolution of RNA viruses, their replication, and their interactions with their hosts. This review summarizes our current knowledge of this group of viruses.     

The Chondrus crispus-Acrochaete operculata host-pathogen association, a novel model in glycobiology and applied phycopathology

A review is presented of ongoing research on the oligosaccharide signalsinvolved in cell-cell recognition in the Chondrus crispus-Acrochaete operculata host-pathogen association. In this pathosystem,the host gametophytes are resistant to the pathogen, whereas thesporophytic generation is susceptible to infection. The virulence of thegreen algal pathogen is mediated by the recognition of carrageenanoligosaccharides released from its red algal host: kappa-carrageenanoligosaccharides inhibit A. operculata virulence while lambdacarrageenan oligosaccharides enhance its pathogenicity. It appears that therecognition of A. operculata by C. crispus also involves anoligosaccharidic signal. This signal is present in the non-virulent form of thepathogen whereas it is absent from the virulent form. Altogether thispathosystem offers a unique model to investigate the recognition ofoligosaccharide signals in plant-pathogen interactions. The possibleapplications of this research to develop new strategies for disease controlin maricultured algal crops are discussed.     

New insights into the functions of anthrax toxin

Anthrax is the disease caused by the Gram-positive bacterium Bacillus anthracis. Two toxins secreted by B. anthracis - lethal toxin (LT) and oedema toxin (OT) - contribute significantly to virulence. Although these toxins have been studied for half a century, recent evidence indicates that LT and OT have several roles during infection not previously ascribed to them. Research on toxin-induced effects other than cytolysis of target cells has revealed that LT and OT influence cell types previously thought to be insensitive to toxin. Multiple host factors that confer sensitivity to anthrax toxin have been identified recently, and evidence indicates that the toxins probably contribute to colonisation and invasion of the host. Additionally, the toxins are now known to cause a wide spectrum of tissue and organ pathophysiologies associated with anthrax. Taken together, these new findings indicate that anthrax-toxin-associated pathogenesis is much more complex than has been traditionally recognised.     

Yeast and yeast-like fungi associated with dry indehiscent fruits of Nothofagus nervosa in Patagonia, Argentina

Nothofagus nervosa (Raulí) is a native tree species that yields valuable timber. It was overexploited in the past and is currently included in domestication and conservation programs. Several research programs have focused on the characterization of epiphytic microorganisms because it has been demonstrated that they can affect plant-pathogen interactions and/or promote plant growth. Although the microbial ecology of leaves has been well studied, less is known about microorganisms occurring on seeds and noncommercial fruits. In this work, we analyzed the yeast and yeast-like fungi present on N.?nervosa fruits destined for the propagation of this species, as well as the effects of fruit preservation and seed dormancy-breaking processes on fungal diversity. Morphological and molecular methods were used, and differences between fungal communities were analyzed using a similarity index. A total of 171 isolates corresponding to 17 species were recovered, most of which belong to the phylum Ascomycota. The majority of the species develop mycelia, produce pigments and mycosporines, and these adaptation strategies are discussed. It was observed that the preservation process considerably reduced yeast and yeast-like fungal diversity. This is the first study concerning microbial communities associated with this ecologically and economically important species, and the information presented is relevant to domestication programs.     

Cellular microbiology: Bacterial toxin interference drives understanding of eukaryotic cell function

Intimate interactions between the armament of pathogens and their host dictate tissue and host susceptibility to infection also forging specific pathophysiological outcomes. Studying these interactions at the molecular level has provided an invaluable source of knowledge on cellular processes, as ambitioned by the Cellular Microbiology discipline when it emerged in early 90s. Bacterial toxins act on key cell regulators or membranes to produce major diseases and therefore constitute a remarkable toolbox for dissecting basic biological processes. Here, we review selected examples of recent studies on bacterial toxins illustrating how fruitful the discipline of cellular microbiology is in shaping our understanding of eukaryote processes. This ever‐renewing discipline unveils new virulence factor biochemical activities shared by eukaryotic enzymes and hidden rules of cell proteome homeostasis, a particularly promising field to interrogate the impact of proteostasis breaching in late onset human diseases. It is integrating new concepts from the physics of soft matter to capture biomechanical determinants forging cells and tissues architecture. The success of this discipline is also grounded by the development of therapeutic tools and new strategies to treat both infectious and noncommunicable human diseases.     

Designer probiotics for prevention of enteric infections

Many microbial pathogens, including those responsible for major enteric infections, exploit oligosaccharides that are displayed on the surface of host cells as receptors for toxins and adhesins. Blocking crucial ligand-receptor interactions is therefore a promising therapeutic strategy. One approach is to express molecular mimics of host receptors on the surface of harmless recombinant bacteria that can survive in the gut. These 'designer probiotics' bind bacterial toxins in the gut lumen with very high avidity, thereby preventing disease. This article discusses recent progress with this strategy.     

The Leeuwenhoek Lecture, 1991. The influence of the host on microbes that cause disease.

Microbial pathogenicity or virulence, the capacity to cause disease, depends on microbial gene products that promote infection and penetration of mucous membranes, multiplication in the tissues, interference with host defence and sickness. Formation of these virulence determinants by microbes is influenced by the environment of the host, which differs from that in laboratory cultures. Studies of microorganisms grown in vivo, and of the host's influence on the production of virulence determinants, are increasing. In most studies, however, the complex conditions in vivo are not dissected to show the influence of particular factors. In future we should define specific host factors that are responsible for producing identified virulence determinants. There are three studies which point the way. Iron limitation in vivo causes production of bacterial siderophores, outer membrane receptors and some toxins. Erythritol, a growth stimulant for brucellae, causes intense placentitis and hence abortion in cattle, sheep and pigs. Cytidine 5'-monophospho-N-acetyl neuraminic acid (CMP-NANA) sialylates a conserved component of gonococcal lipopolysaccharide (LPS), thereby rendering gonococci in patients resistant to complement-mediated killing by serum. Although the lecture uses bacteria for examples, the principle applies equally to studies of viral and fungal pathogenicity.     

New insights into the biological effects of anthrax toxins: linking cellular to organismal responses

The anthrax toxins lethal toxin (LT) and edema toxin (ET) are essential virulence factors produced by Bacillus anthracis. These toxins act during two distinct phases of anthrax infection. During the first, prodromal phase, which is often asymptomatic, anthrax toxins act on cells of the immune system to help the pathogen establish infection. Then, during the rapidly progressing (or fulminant) stage of the disease bacteria disseminate via a hematological route to various target tissues and organs, which are typically highly vascularized. As bacteria proliferate in the bloodstream, LT and ET begin to accumulate rapidly reaching a critical threshold level that will cause death even when the bacterial proliferation is curtailed by antibiotics. During this final phase of infection the toxins cause an increase in vascular permeability and a decrease in function of target organs including the heart, spleen, kidney, adrenal gland, and brain. In this review, we examine the various biological effects of anthrax toxins, focusing on the fulminant stage of the disease and on mechanisms by which the two toxins may collaborate to cause cardiovascular collapse. We discuss normal mechanisms involved in maintaining vascular integrity and based on recent studies indicating that LT and ET cooperatively inhibit membrane trafficking to cell-cell junctions we explore several potential mechanisms by which the toxins may achieve their lethal effects. We also summarize the effects of other potential virulence factors secreted by B. anthracis and consider the role of toxic factors in the evolutionarily recent emergence of this devastating disease.     

Plant physiology meets phytopathology: plant primary metabolism and plant-pathogen interactions

Phytopathogen infection leads to changes in secondary metabolism based on the induction of defence programmes as well as to changes in primary metabolism which affect growth and development of the plant. Therefore, pathogen attack causes crop yield losses even in interactions which do not end up with disease or death of the plant. While the regulation of defence responses has been intensively studied for decades, less is known about the effects of pathogen infection on primary metabolism. Recently, interest in this research area has been growing, and aspects of photosynthesis, assimilate partitioning, and source-sink regulation in different types of plant-pathogen interactions have been investigated. Similarly, phytopathological studies take into consideration the physiological status of the infected tissues to elucidate the fine-tuned infection mechanisms. The aim of this review is to give a summary of recent advances in the mutual interrelation between primary metabolism and pathogen infection, as well as to indicate current developments in non-invasive techniques and important strategies of combining modern molecular and physiological techniques with phytopathology for future investigations.     

一种体内研究病原体致病机理的新方法——信号标签诱变技术

信号标签诱变技术是以整个基因组为基础的研究病原体致病机制,可在体内对毒力基因进行高通量筛选的一种新方法。近几年应用该技术已对十多种病原微生物进行了筛选。这些筛选中除了找到已知的毒力基因外,还都鉴定到了未知的毒力因子。本文就该技术的原理、优缺点、应用的必要条件、技术的改进及应用该技术鉴定到的毒力基因等作一综述。 A Novel Approach to Study Pathogenesis of Pathogens in vivo——Signature-tagged Mutagenesis YAO Xiao1,2,HUANG Liu-yu1,YANG Bo-lun2,SU Guo-fu1 1.Beijing Institute of Biotechnoloy,Beijing 100071,China; 2.College of Environmental and Chemical Engineering,Xi'an Jiaotong University,Xi'an 710049,China Abstract:Signature-tagged mutagenesis (STM) is a novel approach to study pathogenesis of pathogens and to screen virulence genes with high throughput in vivo,which is based on whole genome of pathogen in question.In resent years,more than ten species of microbial pathogens have been screened with this technology.There are also unknown virulence factors being identified with exception of known virulence genes identified in all these screens.This article reviews the principle,advantages and current limitations,the requirements,modifications of STM,and to date virulence genes identified by this technology. Key words：signature-tagged mutagenesis;virulence genes;pathogens;in vivo