转基因益生菌：预防肠道感染的新型微生态制剂

引起主要肠道疾病的许多致病菌能够特异性地利用宿主肠道细胞表面的各式寡糖, 将其作为自身黏附或者分泌毒素的受体。因此, 阻断致病菌及其分泌毒素与宿主靶细胞表面受体结合是一种可行的治疗方法。一类宿主肠道细胞表面受体基因重组益生菌在消化道内能够高效结合致病菌和所分泌的毒素, 具有良好的预防肠道疾病的应用前景。本文主要以类志贺毒素受体重组益生菌为例, 阐述转基因益生素的原理、技术及其疗效和潜在的问题与对策。     

转基因益生菌：预防肠道感染的新型微生态制剂

引起主要肠道疾病的许多致病菌能够特异性地利用宿主肠道细胞表面的各式寡糖,将其作为自身黏附或者分泌毒素的受体.因此,阻断致病菌及其分泌毒素与宿主靶细胞表面受体结合是一种可行的治疗方法.一类宿主肠道细胞表面受体基因重组益生菌在消化道内能够高效结合致病菌和所分泌的毒素,具有良好的预防肠道疾病的应用前景.本文主要以类志贺毒素受体重组益生茵为例,阐述转基因益生素的原理、技术及其疗效和潜在的问题与对策.     

Bioengineered bugs expressing oligosaccharide receptor mimics: toxin-binding probiotics for treatment and prevention of enteric infections

Many microbial pathogens recognize oligosaccharides displayed on the surface of host cells as receptors for toxins and adhesins. These ligand-receptor interactions are critical for disease pathogenesis, making them promising targets for novel anti-infectives. One strategy with particular utility against enteric infections involves expression of molecular mimics of host oligosaccharides on the surface of harmless bacteria capable of surviving in the gut. This can be achieved in Gram-negative bacteria by manipulating the outer core region of the lipopolysaccharide (LPS) through expression of cloned heterologous glycosyltransferases. The resultant chimeric LPS molecules are incorporated into the outer membrane by the normal assembly route and presented as a closely packed 2-D array of receptor mimics. Several such "designer probiotics" have been constructed, and these bind bacterial toxins in the gut lumen with very high avidity, blocking their uptake by host cells and thereby preventing disease.     

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).     

肠道微生态系统及其与宿主的协同进化

肠道微生态系统是寄生在宿主肠道内的微生物的总和。微生物进入肠道后,通过一个复杂的过程形成群落,与宿主之间相互作用,形成共生关系。宿主客观上为微生物提供生存和进化场所,微生态系统为宿主提供营养物质、刺激肠道组织的发育、刺激宿主肠道免疫系统的发育、影响宿主能量代谢、协助宿主降解有毒物质、影响宿主生殖活动和寿命等功能。作为一个进化的系统,微生态系统的物种多样性和丰富度对维持宿主正常生理功能具有重要作用,但同时又受宿主的影响,物种间相互作用和宿主-微生物间的相互作用是微生态系统进化的动力。进化主要表现在微生物和宿主基因组上发生适应性变化。因此,系统生态学的理论对理解肠道微生态系统的运行机制和临床应用具有重要指导作用。     

Coping with toxic plant compounds--the insect's perspective on iridoid glycosides and cardenolides

Specializing on host plants with toxic secondary compounds enforces specific adaptation in insect herbivores. In this review, we focus on two compound classes, iridoid glycosides and cardenolides, which can be found in the food plants of a large number of insect species that display various degrees of adaptation to them. These secondary compounds have very different modes of action: Iridoid glycosides are usually activated in the gut of the herbivores by β-glucosidases that may either stem from the food plant or be present in the gut as standard digestive enzymes. Upon cleaving, the unstable aglycone is released that unspecifically acts by crosslinking proteins and inhibiting enzymes. Cardenolides, on the other hand, are highly specific inhibitors of an essential ion carrier, the sodium pump. In insects exposed to both kinds of toxins, carriers either enabling the safe storage of the compounds away from the activating enzymes or excluding the toxins from sensitive tissues, play an important role that deserves further analysis. To avoid toxicity of iridoid glycosides, repression of activating enzymes emerges as a possible alternative strategy. Cardenolides, on the other hand, may lose their toxicity if their target site is modified and this strategy has evolved multiple times independently in cardenolide-adapted insects.     

Structure-based design of a bispecific receptor mimic that inhibits T cell responses to a superantigen

Key surface proteins of pathogens and their toxins bind to the host cell receptors in a manner that is quite different from the way the natural ligands bind to the same receptors and direct normal cellular responses. Here we describe a novel strategy for "non-antibody-based" pathogen countermeasure by targeting the very same "alternative mode of host receptor binding" that the pathogen proteins exploit to cause infection and disease. We have chosen the Staphylococcus enterotoxin B (SEB) superantigen as a model pathogen protein to illustrate the principle and application of our strategy. SEB bypasses the normal route of antigen processing by binding as an intact protein to the complex formed by the MHC class II receptor on the antigen-presenting cell and the T cell receptor. This alternative mode of binding causes massive IL-2 release and T cell proliferation. A normally processed antigen requires all the domains of the receptor complex for its binding, whereas SEB requires only the alpha1 subunit (DRalpha) of the MHC class II receptor and the variable beta subunit (TCRVbeta) of the T cell receptor. This prompted us to design a bispecific chimera, DRalpha-linker-TCRVbeta, that acts as a receptor mimic and prevents the interaction of SEB with its host cell receptors. We have adopted (GSTAPPA)(2) as the linker sequence because it supports synergistic binding of DRalpha and TCRVbeta to SEB and thereby makes DRalpha-(GSTAPPA)(2)-TCRVbeta as effective an SEB binder as the native MHC class II-T cell receptor complex. Finally, we show that DRalpha-(GSTAPPA)(2)-TCRVbeta inhibits SEB-induced IL-2 release and T cell proliferation at nanomolar concentrations.     

Sialic acid diversity in the human gut: Molecular impacts and tools for future discovery

Sialic acids are a family of structurally related sugars that are prevalent in mucosal surfaces, including the human intestine. In the gut, sialic acids have diverse biological roles at the interface of the host epithelium and the microbiota. N-acetylneuraminic acid (Neu5Ac), the best studied sialic acid, is a nutrient source for bacteria and, when displayed on the cell surface, a binding site for host immune factors, viruses, and bacterial toxins. Neu5Ac is extensively modified by host and microbial enzymes, and the impacts of Neu5Ac derivatives on host–microbe interactions, and generally on human and microbial biology, remain underexplored. In this mini-review, we highlight recent reports describing how host and microbial proteins differentiate Neu5Ac and its derivatives, draw attention to gaps in knowledge related to sialic acid biology, and suggest cutting-edge methodologies that may expand our appreciation and understanding of Neu5Ac in health and disease.     

Bacillus thuringiensis HD-73 Spores Have Surface-Localized Cry1Ac Toxin: Physiological and Pathogenic Consequences

Spores from Cry(sup+) strains of Bacillus thuringiensis bound fluorescein isothiocyanate-labeled antibodies specific for the 65-kDa activated Cry 1Ac toxin, whereas spores from Bacillus cereus and Cry(sup-) strains of B. thuringiensis did not. The Cry(sup+) spores could be activated for germination by alkaline conditions (pH 10.3), whereas Cry(sup-) spores could not. Once the surrounding exosporia had been removed or permeabilized, Cry(sup+) spores were able to bind the toxin receptor(s) from insect gut brush border membrane vesicle preparations, and their germination rates were increased ca. threefold in the presence of brush border membrane vesicles. A model is presented whereby in the soil the Cry toxins on the spore surface are protected by the exosporium while in the gut they are exposed and available for binding to the insect receptors. This model explains why the disulfide-rich C terminus of the cry genes is so highly conserved even though it is removed during the processing of the protoxin to the activated toxin. It also highlights the trade-off resulting from having Cry toxins located on the spore surface, i.e., decreased spore resistance versus enhanced insect pathogenesis.     

Current advances in aptamer‐assisted technologies for detecting bacterial and fungal toxins

Infectious diseases are among the common leading causes of morbidity and mortality worldwide. Associated with the emergence of new infectious diseases, the increasing number of antimicrobial‐resistant isolates presents a serious threat to public health and hospitalized patients. A microbial pathogen may elicit several host responses and use a variety of mechanisms to evade host defences. These methods and mechanisms include capsule, lipopolysaccharides or cell wall components, adhesions and toxins. Toxins inhibit phagocytosis, cause septic shock and host cell damages by binding to host surface receptors and invasion. Bacterial and fungal pathogens are able to apply many different toxin‐dependent mechanisms to disturb signalling pathways and the structural integrity of host cells for establishing and maintaining infections Initial techniques for analysis of bacterial toxins were based on in vivo or in vitro assessments. There is a permanent demand for appropriate detection methods which are affordable, practical, careful, rapid, sensitive, efficient and economical. Aptamers are DNA or RNA oligonucleotides that are selected by systematic evolution of ligands using exponential enrichment (SELEX) methods and can be applied in diagnostic applications. This review provides an overview of aptamer‐based methods as a novel approach for detecting toxins in bacterial and fungal pathogens.     

Membrane proteins of Aedes aegypti larvae bind toxins Cry4B and Cry11A of Bacillus thuringiensis ssp. israelensis

Proteins of molecular weight 65 and 62 kD and having affinity for toxins Cry4B and Cry11A produced by Bacillus thuringiensis ssp. israelensis have been isolated from brush border membranes of Aedes aegypti larvae using affinity chromatography. Using a ligand blotting technique, we show that the binding of these proteins to the biotinylated toxins is reversible and that the two toxins compete for binding to the two proteins. These proteins are likely to be Cry4B and Cry11A toxin receptors in gut epithelial cells of Aedes aegypti larvae.     

To translocate or not: that is the problem

The botulinum toxins (BoNTs) enter the cytosol of host cells by translocation across the limiting membrane of acidic endosomes. In this issue, Sun et?al. (2011) show that BoNT binding to one of its cell surface receptors renders it susceptible to pH-dependent conformational changes required for translocation and cellular toxicity.     

Mucin and Toll-like receptors in host defense against intestinal parasites

Gastrointestinal mucin is a constituent of luminal barrier function and is the first line of host defense against invading pathogens. Mucin carbohydrates and amino acids, as well as trapped soluble host defense molecules, serve as substrates for colonization and control or deter pathogen invasion to the underlying mucosal epithelial cells. Toll-like receptors on the surface of epithelial cells act as sensors for invading pathogens, and the ensuing host response limits parasite invasion and leads to adaptive immunity. The latest work in the field and the use of parasite model systems to illustrate the delicate host-parasite interaction at the mucosal surface of the gut are discussed here.     

Ganglioside embedded in reconstituted lipoprotein binds cholera toxin with elevated affinity

The ability to exogenously present cell-surface receptors in high-affinity conformations in a synthetic system offers an opportunity to provide host cells with protection from pathogenic toxins. This strategy requires improvement of the synthetic receptor binding affinity against its native counterpart, particularly with polyvalent toxins where clustering of membrane receptors can hinder binding. Here we demonstrate that reconstituted lipoprotein, nanometer-sized discoidal lipid bilayers bounded by apolipoprotein and functionalized by incorporation of pathogen receptors, provides a means to enhance toxin-receptor binding through molecular-level control over the receptor microenvironment (specifically, its rigidity, composition, and heterogeneity). Using a Foerster Resonance Energy Transfer (FRET)-based assay, we found that reconstituted lipoprotein incorporating low concentrations of ganglioside monosialotetrahexosylganglioside (GM1) binds polymeric cholera toxin with significantly higher affinity than liposomes or supported lipid bilayers, most likely a result of the enhanced control over receptor clustering provided by the lipoprotein platform. Using wide-area epifluorescence, we found that this enhanced binding capacity can be effectively utilized to divert cholera toxin away from populations of healthy mammalian cells. In summary, we found that reconstitutions of high-density lipoprotein can be engineered to include specific pathogen receptors; that their pathogen binding affinity is altered, presumably due to attenuation of receptor aggregation; and that these assemblies are effective at protecting cells from biological toxins.     

肠道微生物组与宿主的表观遗传修饰

高通量测序技术已经增加了人们对肠道微生物组和表观遗传学修饰的理解,将肠道微生物组和宿主表观遗传学修饰紧密联系起来,阐明了很多疾病的发生过程如免疫、代谢、心血管疾病甚至是癌症。肠道微生物组与宿主具有相互作用,与人体密不可分,相辅相成。肠道微生物组的生态失调可能诱导疾病的发生并能调控宿主表观遗传学修饰。宿主表观遗传学调控和肠道微生物组(或其代谢产物)变化的相互关系在很多疾病中都有报道。因此,肠道微生物组可作为某些疾病的诊断标记,健康肠道微生物组的移植会逆转这种微生态失调,可作为一种有效的治疗策略。本文主要探讨了肠道微生物组直接调控宿主表观修饰和通过小分子生物活性物质和其他酶辅因子间接影响表观修饰,以及基于肠道微生物组调控宿主表观修饰的诊断和治疗应用等。     

Yeasts Isolated from Neotropical Wood-Boring Beetles in SE Peru

Some temperate wood-boring cerambycid beetles harbor intracellular gut yeasts believed to augment host nutrition, but species belonging to the subfamily Lamiinae are thought to lack endosymbionts. Almost 49 percent of Neotropical cerambycid species are lamiines, therefore, comparatively few rain forest species would be expected to host symbiotic gut yeasts. This study reports the isolation of gut yeasts from closely related Neotropical lamiines. We investigated species that feed on trees in the Brazil nut family (Lecythidaceae), because host plant associations are relatively well known. Our objectives were to determine if gut yeasts were present and, if possible, infer their mode of transmission. We collected and dissected 18 beetle specimens from three tree species, including 17 cerambycids and one curculionid. Every insect specimen yielded a gut yeast. DNA sequence libraries were used for a rapid identification of the yeasts and their larval hosts. The cerambycids included five lamiine species and one cerambycine. Six ascomycete yeasts were isolated from their guts; we found no evidence of strict vertical transmission. Larval gut yeasts were genetically similar to yeasts previously isolated from insects associated with wood or fungi, implying potential habitat specificity. The yeasts have not yet been localized, and potential function is not known, but they may contribute to rapid nutrient cycling or serve as the first line of defense against plant toxins.     

Non-natural cell surface receptors: synthetic peptides capped with N-cholesterylglycine efficiently deliver proteins into Mammalian cells

Protein toxins such as shiga toxin and cholera toxin penetrate into cells by binding small molecule-based cell surface receptors localized to cholesterol and sphingolipid-rich lipid raft subdomains of cellular plasma membranes. Molecular recognition between these toxins and their receptors triggers endocytic protein uptake through endogenous membrane trafficking pathways. We report herein the synthesis of functionally related non-natural cell surface receptors comprising peptides capped with N-cholesterylglycine as the plasma membrane anchor. The peptide moieties of these receptors were based on high-affinity epitopes of anti-hemaglutinin antibodies (anti-HA), anti-Flag antibodies, and a moderate-affinity Strep Tag II peptide ligand of the streptavidin protein from Streptomyces avidini. These non-natural receptors were directly loaded into plasma membranes of Jurkat lymphocytes to display peptides from lipid rafts on the cell surface. Molecular recognition between these receptors and added cognate anti-HA, anti-Flag, or streptavidin proteins resulted in rapid clathrin-mediated endocytosis; fluorescent target proteins were completely internalized within 4-12 h of protein addition. Analysis of protein uptake by epifluorescence microscopy and flow cytometry revealed intracellular fluorescence enhancements of 100-fold to 200-fold (10 microM non-natural receptor) with typically >99% efficiency. This method enabled intracellular delivery of a functional Escherichia coli beta-galactosidase enzyme conjugated to Protein A from Staphylococcus aureus. We termed this novel delivery strategy "synthetic receptor targeting", which is an efficient method to enhance macromolecular uptake by decorating mammalian cells with chemically defined synthetic receptors that access the molecular machinery controlling the organization of cellular plasma membranes.     

Role of the RGD sequence in parasite adhesion to host cells

For many protozoan parasites, one of the first events in the process of infection is attachment to the surface of host cells. This adhesion phase usually involves ligand-receptor interactions, and has stimulated interest in the biochemical characterization of those host cell and parasite surface components involved. In this article, Ali Ouaissi discusses the strategy employed by pathogens such as Trypanosoma cruzi, Trichomonas, Leishmania and Treponema pallidum, in binding to their host cells' fibronectin receptors. Two systems appear available - to bind to the dimeric cell surface fibronectin through the Arginine-Glycine-Aspartic acid (RGD) sequence that is not occupied by the host cell surface receptors, or to present a surface antigen representing a 'fibronectin-like' molecule containing the RGD sequence directly to the host cell fibronectin receptors.     

Molecular Paths Linking Metabolic Diseases,Gut Microbiota Dysbiosis and Enterobacteria Infections

Alterations of both ecology and functions of gut microbiota are conspicuous traits of several inflammatory pathologies, notably metabolic diseases such as obesity and type 2 diabetes. Moreover, the proliferation of enterobacteria, subdominant members of the intestinal microbial ecosystem, has been shown to be favored by Western diet, the strongest inducer of both metabolic diseases and gut microbiota dysbiosis. The inner interdependence between the host and the gut microbiota is based on a plethora of molecular mechanisms by which host and intestinal microbes modify each other. Among these mechanisms are as follows: (i) the well-known metabolic impact of short chain fatty acids, produced by microbial fermentation of complex carbohydrates from plants; (ii) a mutual modulation of miRNAs expression, both on the eukaryotic (host) and prokaryotic (gut microbes) side; (iii) the production by enterobacteria of virulence factors such as the genotoxin colibactin, shown to alter the integrity of host genome and induce a senescence-like phenotype in vitro; (iv) the microbial excretion of outer-membrane vesicles, which, in addition to other functions, may act as a carrier for multiple molecules such as toxins to be delivered to target cells. In this review, I describe the major molecular mechanisms by which gut microbes exert their metabolic impact at a multi-organ level (the gut barrier being in the front line) and support the emerging triad of metabolic diseases, gut microbiota dysbiosis and enterobacteria infections.