Influence of human gastrointestinal tract bacterial pathogens on host cell apoptosis

Several pathogenic bacteria are able to trigger apoptosis in the host cell, but the mechanisms by which it occurs differ, and the resulting pathology can take different courses. Induction and/or blockage of programmed cell death upon infection is a result of complex interaction of bacterial proteins with cellular proteins involved in signal transduction and apoptosis. In this review we focus on pro/anti-apoptotic activities exhibited by two enteric pathogens Salmonella enterica, Yersinia spp. and gastric pathogen Helicobacter pylori. We present current knowledge on how interaction between mammalian and bacterial cell relates to the molecular pathways of apoptosis, and what is the role of apoptosis in pathogenesis.     

常见致病菌糖基转移酶的结构与功能

糖基转移酶(glycosyltransferases,GTs)将糖基从活化的供体转移到糖、脂、蛋白质和核酸等受体,其参与的蛋白质糖基化是最重要的翻译后修饰(post-translational modifications,PTMs)之一。近年来越来越多的研究证明,糖基转移酶与致病菌毒力密切相关,在致病菌的黏附、免疫逃逸和定殖等生物学过程中发挥关键作用。目前,已鉴定的糖基转移酶根据其蛋白质三维结构特征分为3种类型GT-A、GT-B和GT-C,其中常见的是GT-A和GT-B型。在致病菌中发挥黏附功能的糖基转移酶,在结构上属于GT-B或GT-C型,对致病菌表面蛋白质(黏附蛋白、自转运蛋白等)进行糖基化修饰,在致病菌黏附、生物被膜的形成和毒力机制发挥具有重要作用。糖基转移酶不仅参与致病菌黏附这一感染初始过程,其中属于GT-A型的一类致病菌糖基转移酶会进入宿主细胞,通过糖基化宿主蛋白质影响宿主信号传导、蛋白翻译和免疫应答等生物学功能。本文就常见致病菌糖基转移酶的结构及其糖基化在致病机制中的作用进行综述,着重介绍了特异性糖基化高分子量(high-molecular-weight,HMW)黏附蛋白的糖基转移酶、针对富丝氨酸重复蛋白(serine-rich repeat proteins,SRRP)糖基化修饰的糖基转移酶、细菌自转运蛋白庚糖基转移酶(bacterial autotransporter heptosyltransferase,BAHT)家族、N-糖基化蛋白质系统和进入宿主细胞发挥毒力作用的大型梭菌细胞毒素、军团菌(Legionella)葡萄糖基转移酶以及肠杆菌科的效应子NleB。为揭示致病菌中糖基转移酶致病机制的系统性研究提供参考,为未来致病菌的诊断、药物设计研发以及疫苗开发等提供科学依据和思路。     

Importance of probiotics in the prevention and treatment of colorectal cancer

Colorectal cancer (CRC) remains one of the most common and deadly cancers. Intestinal gut microflora is important to maintain and contributes to several intestinal functions, including the development of the mucosal immune system, absorption of complex macromolecules, synthesis of amino acids/vitamins and the protection against pathogenic microorganisms. It is well known that the gut microbiota changes or dysbiosis may have an essential impact in the initiation and promotion of chronic inflammatory pathways and also have a profound different genetic and epigenetic alterations leading to dysplasia, clonal expansion, and malignant transformation. Probiotic bacteria has antitumor activity with various mechanisms such as nonspecific physiological and immunological mechanisms. This review evaluates the effects of microbiota and probiotics in clinical trials, in vitro and animal model studies that have explored how probiotic against cancer development and also discusses the possible immunomodulatory mechanisms. Several mechanisms alteration of the intestinal microflora; inactivation of cancerogenic compounds; competition with putrefactive and pathogenic microbiota; improvement of the host's immune response; antiproliferative effects via regulation of apoptosis and cell differentiation; fermentation of undigested food; inhibition of tyrosine kinase; reduces the enteropathogenic complications before and after colon cancer surgery and improve diarrhea and it's have been able to create the integrity of gut mucosal and have stimulatory effects on the systemic immune system and prevent the CRC metastasis. Research in clinical trials encouraging findings that support a role of probiotics in CRC prevention and improve the safety and effectiveness of cancer therapy even though additional clinical research is still necessary.     

胞内致病菌入侵宿主细胞分子机理研究进展

胞内致病菌,指能够侵入宿主细胞且在宿主细胞内存活并繁殖的病原菌。其入侵宿主细胞的过程主要涉及细菌黏附宿主细胞、侵袭、细菌在细胞内存活以及引起宿主细胞损伤等。先前的研究表明大多数胞内致病菌是通过吞噬细胞被动地摄取,而随着分子生物学和免疫学的发展,越来越多的胞内致病菌被证明能主动入侵到宿主细胞体内,并进化出各种调控宿主细胞信号通路的方式。本文讨论了胞内致病菌在入侵宿主细胞时各阶段的共同的分子机制以及常见的胞内致病菌所采取的入侵策略,并对近年来国内外主要相关研究进展做一总结。     

Molecular mechanisms underlying the emergence of bacterial pathogens: an ecological perspective

The rapid emergence of new bacterial diseases negatively affects both human health and agricultural productivity. Although the molecular mechanisms underlying these disease emergences are shared between human‐ and plant‐pathogenic bacteria, not much effort has been made to date to understand disease emergences caused by plant‐pathogenic bacteria. In particular, there is a paucity of information in the literature on the role of environmental habitats in which plant‐pathogenic bacteria evolve and on the stress factors to which these microbes are unceasingly exposed. In this microreview, we focus on three molecular mechanisms underlying pathogenicity in bacteria, namely mutations, genomic rearrangements and the acquisition of new DNA sequences through horizontal gene transfer (HGT). We briefly discuss the role of these mechanisms in bacterial disease emergence and elucidate how the environment can influence the occurrence and regulation of these molecular mechanisms by directly impacting disease emergence. The understanding of such molecular evolutionary mechanisms and their environmental drivers will represent an important step towards predicting bacterial disease emergence and developing sustainable management strategies for crops.     

食源性致病菌激活NLRP3炎症小体及食源性功能物质的抑制机理研究进展

食源性致病菌感染是引起食源性疾病的首要因素,严重影响人类健康。炎症小体通过识别受体感知入侵宿主的危险信号进而组装形成多聚蛋白复合物,从而诱导炎症反应,是先天免疫系统中识别食源性病原菌感染和清除病原体的重要防线。NLRP3炎症小体是位于胞内的炎症反应平台,可以感知多种病原微生物的侵袭,在先天性免疫反应中起着至关重要的作用。食源性致病菌感染常引起NLRP3炎症小体的异常激活,介导多种炎症性疾病的发生和发展,因此,许多抗炎研究中常常以NLRP3炎症小体作为靶点。本文总结了食源性致病菌及其代谢产物激活NLRP3炎症小体的分子机制,以及天然产物和膳食功能物质抑制NLRP3炎症小体激活的机理,为治疗炎症性疾病、开发缓解致病菌诱导的炎症反应的功能化合物提供新的思路。     

革兰氏阴性菌血红素转运系统结构及功能特点

铁是大多数生物包括细菌生存的必需营养元素．对于感染宿主的致病细菌,血红素(heme/haem)可作为一种主要的铁来源．血红素转运系统在革兰氏阴性菌和革兰氏阳性菌中均有发现和鉴定,其转运机制在革兰氏阴性菌中有较为深入研究．革兰氏阴性菌血红素转运系统主要由分泌于细胞外的血红素载体(hemophore)、血红素受体、TonB ExbB ExbD复合物、ABC转运体、血红素降解蛋白和调控蛋白等结构单元组成．对参与该系统的各个蛋白结构特点以及它们之间的相互作用机制的讨论,有助于对病原菌致病机制的深入研究和抗菌新药的研发．     

细菌生物被膜分散及分子调控机制研究进展

生物被膜分散(Biofilm Dispersal)是生物被膜发展后期细菌响应营养物、低浓度的一氧化氮、D-氨基酸、自诱导肽(Autoinducing Peptide,AIP)、酰基高丝氨酸内酯(Acyl Homoserine Lactones,AHL)、腺苷三磷酸(Adenosine Triphosphate,ATP)等信号变化而做出的一种程序性反应,有利于细菌从恶劣的生物被膜内部环境中脱离出来寻找新的定殖位点。此外,由生物被膜引起的细菌短暂的抗生素耐受性在分散过程中会恢复正常水平,这有助于治疗由致病菌引起的难治愈的生物被膜相关疾病。目前生物被膜分散的相关研究正处于起步阶段,本文希望通过综述生物被膜分散现象、信号分子及调控机制,可以更好地了解细菌生物被膜分散对于防控病原微生物和应用有益微生物的重要意义。     

Threats and opportunities of plant pathogenic bacteria

Plant pathogenic bacteria can have devastating effects on plant productivity and yield. Nevertheless, because these often soil-dwelling bacteria have evolved to interact with eukaryotes, they generally exhibit a strong adaptivity, a versatile metabolism, and ingenious mechanisms tailored to modify the development of their hosts. Consequently, besides being a threat for agricultural practices, phytopathogens may also represent opportunities for plant production or be useful for specific biotechnological applications. Here, we illustrate this idea by reviewing the pathogenic strategies and the (potential) uses of five very different (hemi)biotrophic plant pathogenic bacteria: Agrobacterium tumefaciens, A. rhizogenes, Rhodococcus fascians, scab-inducing Streptomyces spp., and Pseudomonas syringae.     

Wake of the flood: ascribing functions to the wave of type III effector proteins of phytopathogenic bacteria

Plant pathogenic bacteria use waves of type III effector proteins, delivered into the eukaryotic host cell, to modulate the host cell for the pathogen's benefit. This is evidenced by the flood of effector genes that have recently been uncovered from the genome sequence of several plant pathogenic bacteria. However, pathogens are unwilling to easily reveal the mechanisms by which these effectors function. Nevertheless, persistent scrutiny has led to the successful characterization of a handful of effectors and it is beginning to provide insights into how phytopathogenic bacteria cause disease on their hosts.     

Molecular approach for development of new medicaments for chronic infections treatment

Owing to the progress in cellular microbiology it has been evidently proved that inflammation induced by infectious agents forms the basis of many chronic conditions. Therefore a microbial infection can be considered as a triggering factor of such widespread and significant diseases as infertility, arthritis, atherosclerosis, asthma, gastritis, stomach ulcer and cancer, neurological syndromes and some oncological formations. Practically all pathogenic and conditionally pathogenic bacteria can induce chronic infections of different organs and tissues. It has been revealed that in spite of differences of clinical syndromes and participation of different bacteria in their induction the several general mechanisms of chronic infections are detected. Failure in chronic infections therapy is due to the absence of medicaments to eradicate persistent forms of pathogens. The development of new medicaments for chronic infections treatment should be based on the selection of new specific targets, influence on which would to inhibit the mechanism of chronic infections induction.     

Starvation survival of the fish pathogenic bacteria Vibrio anguillarum and Vibrio salmonicida in marine environments

Abstract The possible fate in sea water of the two fish pathogenic bacteria Vibrio anguillarum and Vibrio salmonicida is discussed on the basis of microcosm experiments with these and other copiotrophic bacteria. Recent articles dealing with the survival of fish pathogens are reviewed, and the reported survival capacities are discussed in relation to ecological mechanisms, such as death, and predation, leading to the removal of bacteria from the water column.     

Plant models for animal pathogenesis

Several bacteria that are pathogenic to animals also infect plants. Mechanistic studies have proven that some human/animal pathogenic bacteria employ a similar subset of virulence determinants to elicit disease in animals, invertebrates and plants. Therefore, the results of plant infection studies are relevant to animal pathogenesis. This discovery has resulted in the development of convenient, cost-effective, and reliable plant infection models to study the molecular basis of infection by animal pathogens. Plant infection models provide a number of advantages in the study of animal pathogenesis. Using a plant model, mutations in animal pathogenic bacteria can easily be screened for putative virulence factors, a process which if done using existing animal infection models would be time-consuming and tedious. High-throughput screening of plants also provides the potential for unravelling the mechanisms by which plants resist animal pathogenic bacteria, and provides a means to discover novel therapeutic agents such as antibiotics and anti-infective compounds. In this review, we describe the developing technique of using plants as a model system to study Pseudomonas aeruginosa, Enterococcus faecalis and Staphylococcus aureus pathogenesis, and discuss ways to use this new technology against disease warfare and other types of bioterrorism.     

Pumping iron: a potential target for novel therapeutics against schistosomes

Parasites, as with the vast majority of organisms, are dependent on iron. Pathogens must compete directly with the host for this essential trace metal, which is sequestered within host proteins and inorganic chelates. Not surprisingly, pathogenic prokaryotes and eukaryotic parasites have diverse adaptations to exploit host iron resources. How pathogenic bacteria scavenge host iron is well characterized and is reasonably well known for a few parasitic protozoa, but is poorly understood for metazoan parasites. Strategies of iron acquisition by schistosomes are examined here, with emphasis on possible mechanisms of iron absorption from host serum iron transporters or from digested haem. Elucidation of these metabolic mechanisms could lead to the development of new interventions for the control of schistosomiasis and other helminth diseases.     

Bacteria used in the biological control of plant-parasitic nematodes: populations, mechanisms of action, and future prospects

As a group of important natural enemies of nematode pests, nematophagous bacteria exhibit diverse modes of action: these include parasitizing; producing toxins, antibiotics, or enzymes; competing for nutrients; inducing systemic resistance of plants; and promoting plant health. They act synergistically on nematodes through the direct suppression of nematodes, promoting plant growth, and facilitating the rhizosphere colonization and activity of microbial antagonists. This review details the nematophagous bacteria known to date, including parasitic bacteria, opportunistic parasitic bacteria, rhizobacteria, Cry protein-forming bacteria, endophytic bacteria and symbiotic bacteria. We focus on recent research developments concerning their pathogenic mechanisms at the biochemical and molecular levels. Increased understanding of the molecular basis of the various pathogenic mechanisms of the nematophagous bacteria could potentially enhance their value as effective biological control agents. We also review a number of molecular biological approaches currently used in the study of bacterial pathogenesis in nematodes. We discuss their merits, limitations and potential uses.     

Signal transduction and virulence regulation in human and animal pathogens

Abstract Pathogens have developed many strategies for survival in animals and humans which possess very effective defense mechanisms. Although there are many different ways, in which pathogenic bacteria solved the problem to overcome the host defense, some common features of virulence mechanisms can be detected even in phylogenetically very distant bacteria (Finlay and Falkow (1989) Microb. Rev. 6 1375–1383). One important feature is that the regulation of expression of virulence factors and the exact timing of their expression is very important for many of the pathogenic bacteria, as most of them have to encounter different growth situations during an infection cycle, which require a fast adaptation to the new situation by the expression of different factors. This review gives an overview about the mechanisms used by pathogenic bacteria to accomplish the difficult task of regulation of their virulence potential in response to environmental changes. In addition, the relationship of these virulence regulatory systems with other signal transduction mechanisms not involved in pathogenicity is discussed.     

Modulation of eukaryotic cell apoptosis by members of the bacterial order Actinomycetales

Apoptosis, or programmed cell death, is normally responsible for the orderly elimination of aged or damaged cells, and is a necessary part of the homeostasis and development of multicellular organisms. Some pathogenic bacteria can disrupt this process by triggering excess apoptosis or by preventing it when appropriate. Either event can lead to disease. There has been extensive research into the modulation of host cell death by microorganisms, and several reviews have been published on the phenomenon. Rather than covering the entire field, this review focuses on the dysregulation of host cell apoptosis by members of the order Actinomycetales, containing the genera Corynebacterium, Mycobacterium, Rhodococcus, and Nocardia.     

A battle for iron: host sequestration and Staphylococcus aureus acquisition

The use of iron as an enzymatic cofactor is pervasive in biological systems. Consequently most living organisms, including pathogenic bacteria, require iron to survive and replicate. To combat infection vertebrates have evolved sophisticated iron sequestration systems against which, pathogenic bacteria have concomitantly evolved equally elaborate iron acquisition mechanisms.     

The impact of iron on Listeria monocytogenes; inside and outside the host

As iron is vital for all cells, host sequestration of iron provides a significant barrier to bacterial infection. The absolute requirement for iron has driven the evolution of refined systems by which pathogenic bacteria such as Listeria monocytogenes can competitively acquire this element during host infection. This process is coordinated, at least partly, by the Ferric Uptake Regulator (Fur). Recent studies have identified loci within the listerial Fur-regulon and have characterized specific systems involved in iron uptake from various sources. This work has greatly advanced our knowledge of the mechanisms underpinning iron homeostasis in L. monocytogenes. A greater understanding of the molecular mechanisms by which pathogenic bacteria acquire iron is significant from both a food safety and public-health perspective.