Streptococcal invasion

The genus Streptococcus consists of large number of species many of which are pathogenic to humans and animals. Although streptococci have long been considered as extracellular pathogens, they are capable of causing serious invasive infections such as necrotizing fasciitis and meningitis. Streptococcal invasion, therefore, has been a focus of many studies in recent years. Streptococci are efficiently internalized by nonprofessional phagocytes and the current research interest has shifted to determine the role of this invasion in the natural infection process. Moreover, characterization of bacterial and eukaryotic components involved in the uptake process might be useful in developing new strategies for combating streptococcal infections.     

沙门菌侵袭研究进展

鼠伤寒沙门菌表达两个不同的Ⅲ型分泌系统(typeⅢsecretion/translocation systems, TTSS),分别由致病岛1和2(pathogenicityi slands 1 and 2, SPI-1 and SPI-2)编码。细菌依赖TTSS将效应蛋白转运至宿主细胞,通过“触发”机制诱导细菌进入宿主细胞。这些效应蛋白可诱导细胞骨架重排,导致“巨吞饮”,促使细菌入侵。本综述依据多种沙门菌效应蛋白的功能,建立沙门菌侵袭模型。TTSS活化并转运效应蛋白进入宿主细胞发挥功能(Ⅰ)。小G蛋白交换因子SopE和肌醇磷酸酯酶SopB通过激活CDC42和Rac1,诱导内陷相关的蛋白聚集(Ⅱ)。SipA和SipC通过降低肌动蛋白临界浓度、刺激网素成束、稳定纤维状肌动蛋白(fibrousactin, F-actin)以及使肌动蛋白核化等功能,促使细菌入侵(Ⅲ)。SopB可使膜内陷区PIP2的浓度降低以及VAMP8聚集,促使细胞膜分裂(Ⅳ)。这些效应蛋白的联合作用,使膜皱褶在局部向外显著延伸,使沙门菌被细胞内形成的特殊膜结构包裹。沙门菌的另一种效应蛋白SptP,通过刺激小G蛋白内源性GTPase的活性,抑制小G蛋白的活化,使细胞膜恢复至原有状态(Ⅴ)。     

Spatial invasion of cooperation

The evolutionary puzzle of cooperation describes situations where cooperators provide a fitness benefit to other individuals at some cost to themselves. Under Darwinian selection, the evolution of cooperation is a conundrum, whereas non-cooperation (or defection) is not. In the absence of supporting mechanisms, cooperators perform poorly and decrease in abundance. Evolutionary game theory provides a powerful mathematical framework to address the problem of cooperation using the prisoner's dilemma. One well-studied possibility to maintain cooperation is to consider structured populations, where each individual interacts only with a limited subset of the population. This enables cooperators to form clusters such that they are more likely to interact with other cooperators instead of being exploited by defectors. Here we present a detailed analysis of how a few cooperators invade and expand in a world of defectors. If the invasion succeeds, the expansion process takes place in two stages: first, cooperators and defectors quickly establish a local equilibrium and then they uniformly expand in space. The second stage provides good estimates for the global equilibrium frequencies of cooperators and defectors. Under hospitable conditions, cooperators typically form a single, ever growing cluster interspersed with specks of defectors, whereas under more hostile conditions, cooperators form isolated, compact clusters that minimize exploitation by defectors. We provide the first quantitative assessment of the way cooperators arrange in space during invasion and find that the macroscopic properties and the emerging spatial patterns reveal information about the characteristics of the underlying microscopic interactions.     

The paradox of invasion

It is paradoxical that exotic species invade and displace native species that are well adapted to local environments. Yet, even those exotics that eventually become abundant and widespread, often do so only after having failed to establish following multiple earlier introductions. The first pattern, while not generally discussed in this context, is usually explained by exotic species pre‐adaptations for human‐altered environments and by a release from enemies. It can be understood further by examining the superior quality of colonists from large species‐rich regions and the historical contingency of evolution. The second pattern is generally explained by invoking demographic and environmental stochasticity; however, it can be understood further by examining the role of environmental variation over space and by metapopulation dynamics. These processes provide a context in which these patterns of invasion are not paradoxical, but instead, expected.     

A silent invasion

Invasions mediated by humans have been reported from around the world, and ships’ ballast water has been recognized as the main source of marine invaders worldwide. Some invasions have dramatic economic and ecological consequences. On the other hand, many invasions especially in the marine realm, can go unnoticed. Here we identify a human mediated, worldwide introduction of the hydrozoan species Turritopsis dohrnii. The normal life cycle of hydrozoans involves the asexual budding of medusae from colonial polyps. Medusae of Turritopsis, however, when starved or damaged, are able to revert their life cycle, going back to the polyp stage through a process called transdifferentiation. They can thus easily survive through long journeys in cargo ships and ballast waters. We have identified a clade of the mitochondrial 16S gene in Turritopsis which contains individuals collected from Japan, the Pacific and Atlantic coasts of Panama, Florida, Spain, and Italy differing from each other in only an average of 0.31% of their base-pairs. Fifteen individuals from Japan, Atlantic Panama, Spain, and Italy shared the same haplotype. Turritopsis dohrnii medusae, despite the lack of genetic differences, are morphologically different between the tropical and temperate locations we sampled, attesting to a process of phenotypic response to local conditions that contributes to making this grand scale invasion a silent one.     

Small-step invasion research

Recent invasion research can be categorized broadly into two types: studies of the spatial spread, and those of the biological impact the invader has on the native biota. The first type is the most factual, and the second the most theoretical. So far, however, it is difficult to connect the two, implying that neither the spatial spread nor the species interactions can be explained in terms of each other. Recent models, analysing spatial spread, progress steadily by making small steps.     

Human cytotrophoblast invasion

During early pregnancy, fetal chorionic villi that contact the uterine wall give rise to columns of mononuclear cytotrophoblasts that penetrate the superficial portion of the uterus. From these columns emanate cytotrophoblasts that invade deeply into the uterus and its arterioles. To investigate the molecular basis of this unusual, regulated invasive behavior, we used a combination of approaches that included an in vitro model of cytotrophoblasts invasion and immunocytochemistry on uterine biopsy sections containing invading cytotrophoblasts. Our results showed interesting roles for: matrix-degrading metalloproteinases, adhesion receptors and their extracellular matrix ligands, and the class I molecule HLA-G.     

Campylobacter jejuni--microtubule-dependent invasion

Campylobacter jejuni is the leading bacterial cause of food-borne illness worldwide and a major cause of Guillain-Barré paralysis. Recent molecular and cellular studies of one well-characterized C. jejuni strain have begun to unravel the details of an unusual microtubule-dependent (actin-filament-independent) gut-invasion mechanism, through which at least some C. jejuni initiate disease. Although responsible for causing a human dysenteric syndrome remarkably similar to that triggered by Shigella spp., current evidence suggests that C. jejuni use some markedly different molecular mechanisms of pathogenesis compared with shigellae.     

Habitat invasion research: where vegetation science and invasion ecology meet

In the last decade, habitat‐oriented studies of plant invasions, performed at broad scales and using large data sets of vegetation plots, have focused on quantifying the representation of alien species in vegetation or habitat types, identifying factors underlying invasions, and exploring the pools of species available for invasion into particular habitats. In this essay we summarize what we have learned, discuss constraints associated with this kind of data and outline promising research topics to which a macroecological perspective of habitat invasions can contribute. Such topics include, among others: integrating species‐specific information on invasion status, residence time in the region, biological and ecological traits and phylogenetic relationships into habitat invasion research to better capture the context‐dependence of invasions; focusing on the functional role that alien species, relative to natives, play in plant communities; and obtaining insights into the role of pre‐adaptation for invasion by comparing the functional composition of habitat species pools in the native range. There is still a strong geographic bias, with detailed assessments across broader ranges of habitat types in large regions available only from Europe, the United States and New Zealand, which call for extension of this research to other continents.     

细胞受体介导的疱疹病毒侵入机制

疱疹病毒(Herpesviruses)是一类较大的双链DNA囊膜病毒,广泛感染人和多种动物,以皮肤、粘膜和神经组织的疱疹性病变为特征。病毒侵入宿主细胞为整个复制周期的首要环节,而受体是介导病毒吸附、内化以及膜融合等侵入过程的关键宿主因子。因此,对受体的研究已经成为了解病毒侵入机制以及开发抗病毒制剂的突破口。本综述介绍了与疱疹病毒侵入相关的受体分子以及在这些分子介导下的跨膜机制,同时讨论了目前疱疹病毒侵入方面仍存在的问题和未来的研究方向。     

Biochemistry of red cell invasion

We are still far from an explicit understanding of the events that characterize the invasion of red cells by malarial parasites at the structural and biochemical levels. The nature of the interaction between the attached parasite and the host cell; the origin of the parasitophorous vacuole; the identity, disposition, and arrangement of the propulsive proteins of the parasite; the functions of the rhoptry organelles; and the rearrangement of the host cell membrane to permit entry of the parasite remain to be elucidated. A hypothetical scheme is presented that pursues the processes involved in invasion from the biochemical events generated by attachment of the parasite, to the steric rearrangement of red cell membrane proteins, which culminates in invasion.     

Fungal invasion of epithelial cells

Interaction between host cells and invasive Candida plays a large role in the pathogenicity of Candida species. Fungal-induced endocytosis and active penetration are the two distinct, yet complementary invasion mechanisms of invasive candidiasis. Induced endocytosis is a microorganism-triggered, epithelial-driven, clathrin-mediated and actin-dependent process. During the fundamental pathological process of induced endocytosis, invasins (Als3 and Ssa1), which mediate the binding of host epithelial surface proteins, are expressed by Candida species on the hyphal surface. Sequentially, the interaction between invasins and host epithelial surface proteins stimulates the recruitment of clathrin, dynamin and cortactin to the sites where Candida enters epithelial cells, which in turn induce the actin cytoskeleton reorganization. Actin cytoskeleton provides the force required for fungal internalization. Parallely, active penetration of Candida can directly pass through epithelial cells possibly due to progressive elongation of hyphae and physical forces. Several molecules, such as secreted hydrolases and Als3, can affect the protective barrier of the epithelium and make Candida actively penetrate into epithelial cells through intercellular gaps of epithelial layers.     

Malaria invasion of human erythrocytes

The invasion of human red blood cells (RBC) by plosmodiol merozoites is a key event during malaria infection, and the inhibition o f invasion is regarded as a crucial goal of malaria vaccine development. For Plasmodium falciparum it has been suggested that the red cell sialoglycoproteins, glycophorins A, B and C, are receptors for invasion and that O-linked or N-linked carbohydrate structures may be involved as receptor sites(1-3). However, recent evidence suggests that the role o f these sialoglycoproteins and carbohydrates may have been overestimated. In this article, Peter Hermentin discusses the contradictory findings and presents a revised model for the invasion process.     

Physical aspects of cancer invasion

Invasiveness, one of the hallmarks of tumor progression, represents the tumor's ability to expand into the host tissue by means of several complex biochemical and biomechanical processes. Since certain aspects of the problem present a striking resemblance with well-known physical mechanisms, such as the mechanical insertion of a solid inclusion in an elastic material specimen (G Eaves 1973 The invasive growth of malignant tumours as a purely mechanical process J. Pathol. 109 233; C Guiot, N Pugno and P P Delsanto 2006 Elastomechanical model of tumor invasion Appl. Phys. Lett. 89 233901) or a water drop impinging on a surface (C Guiot, P P Delsanto and T S Deisboeck 2007 Morphological instability and cancer invasion: a 'splashing water drop' analogy Theor. Biol. Med. Model 4 4), we propose here an analogy between these physical processes and a cancer system's invasive branching into the surrounding tissue. Accounting for its solid and viscous properties, we then arrive, as a unifying model, to an analogy with a granular solid. While our model has been explicitly formulated for multicellular tumor spheroids in vitro, it should also contribute to a better understanding of tumor invasion in vivo.