Guy R. Cornelis

The type III secretion injectisome

The type III secretion injectisome is a complex nanomachine that allows bacteria to deliver protein effectors across eukaryotic cellular membranes. In recent years, significant progress has been made in our understanding of its structure, assembly and mode of operation. The principal structural components of the injectisome, from the base located in the bacterial cytosol to the tip of the needle protruding from the cell surface, have been investigated in detail. The structures of several constituent proteins were solved at the atomic level and important insights into the assembly process have been gained. However, despite the ongoing concerted efforts of molecular and structural biologists, the role of many of the constituent components of this nanomachine remain unknown.

A wide-host-range suicide vector for improving reverse genetics in Gram-negative bacteria: inactivation of the blaA gene of Yersinia enterocolitica

A new suicide vector (pKNG101) that facilitates the positive selection of double recombination events in Gram-bacteria has been developed. It contains a conditional origin of replication (oriR6K), the strAB genes encoding the streptomycin phosphotransferase (SmR), an origin of transfer (mobRK2), the sacB gene mediating sucrose sensitivity, and multiple cloning sites. It was used to mutate the blaA gene of Yersinia enterocolitica, by marker-exchange mutagenesis. To do this, we have first cloned into the suicide vector pKNG101, a 2.5-kb fragment of Y. enterocolitica chromosomal DNA encoding the 20-kDa beta-lactamase A. Gene blaA was then mutated in vitro by insertion of luxAB, which resulted in pKNG105. The disrupted blaA gene was then reintroduced into Y. enterocolitica chromosome by homologous recombinations in two steps. First, E. coli SM10 lambda pir (pKNG105) was mated with strains of Y. enterocolitica. This led to the integration of pKNG105 into the chromosome, by a single homologous recombination event. The transconjugants, selected for SmR, were sensitive to sucrose due to the synthesis of levans (toxic compounds), catalysed by levansucrase, the product of sacB. For the second step, a single colony from the first step was grown in rich medium deprived of antibiotic, allowing the occurrence of a second crossing-over that replaced the wild-type allele blaA with the mutant one, and then excised the plasmid-borne sacB from the chromosome. Such blaA mutants were selected on their ability to grow on TSA medium containing 5% sucrose.(ABSTRACT TRUNCATED AT 250 WORDS)

The Yersinia Yop virulon: a bacterial system for subverting eukaryotic cells

The Yop virulon enables Yersinia spp. (Y. pestis, Y. pseudotuberculosis and Y. enterocolitica) to survive and multiply in the lymphoid tissues of their host. It is an integrated system allowing extracellular bacteria to communicate with the host cells cytosol by the injection of effector proteins. It is composed of the following four elements. (i) A contact or type III secretion system called Ysc, which is devoted to the secretion of Yop proteins. This secretion apparatus, comprising some 22 proteins recognizes the Yops by a short N‐terminal signal that is not cleaved off during secretion. (ii) A system designed to deliver bacterial proteins into eukaryotic target cells. This system is made of YopB, YopD and possibly other Yops such as LcrV. (iii) A control element (YopN). (iv) A set of effector Yop proteins designed to disarm these cells or disrupt their communications (YopE, YopH, YpkA/YopO, and YopM). The whole virulon is encoded by a 70 kb plasmid designated pYV. Transcription of the genes is controlled both by temperature and by contact with a eukaryotic cell.

TRANSLOCATION OF A HYBRID YOPE-ADENYLATE CYCLASE FROM YERSINIA ENTEROCOLITICA INTO HELA CELLS

Pathogenic bacteria of the genus Yersinia release in vitro a set of antihost proteins called Yops. Upon infection of cultured epithelial cells, extracellular Yersinia pseudotuberculosis transfers YopE across the host cell plasma membrane. To facilitate the study of this translocation process, we constructed a recombinant Yersinia enterocolitica strain producing YopE fused to a reporter enzyme. As a reporter, we selected the calmodulin‐dependent adenylate cyclase of Borde‐tella pertussis and we monitored the accumulation of cyclic AMP (cAMP). Since bacteria do not produce calmodulin, cyclase activity marks the presence of hybrid enzyme in the cytoplasmic compartment of the eukaryotic cell. Infection of a monolayer of HeLa cells by the recombinant Y. enterocolitica strain led to a significant increase of cAMP. This phenomenon was dependent not only on the integrity of the Yop secretion pathway but also on the presence of YopB and/or YopD. It also required the presence of the adhesin YadA at the bacterial surface. In contrast, the phenomenon was not affected by cytochalasin D, indicating that internalization of the bacteria themselves was not required for the translocation process. Our results demonstrate that Y. enterocolitica is able to transfer hybrid proteins into eukaryotic cells. This system can be used not only to study the mechanism of YopE translocation but also the fate of the other Yops or even of proteins secreted by other bacterial pathogens.

YopT, a new Yersinia Yop effector protein, affects the cytoskeleton of host cells.

Extracellular Yersinia disarm the immune system of their host by injecting effector Yop proteins into the cytosol of target cells. Five effectors have been described: YopE, YopH, YpkA/YopO, YopP and YopM. Delivery of these effectors by Yersinia adhering at the cell surface requires other Yops (translocators) including YopB. Effector and translocator Yops are secreted by the type III Ysc secretion apparatus, and some Yops also need a specific cytosolic chaperone, called Syc. In this paper, we describe a new Yop, which we have called YopT (35.5 kDa). Its secretion required an intact Ysc apparatus and SycT (15.0 kDa, pI 4.4), a new chaperone resembling SycE. Infection of macrophages with a Yersinia, producing a hybrid YopT–adenylate cyclase, led to the accumulation of intracellular cAMP, indicating that YopT is delivered into the cytosol of eukaryotic cells. Infection of HeLa cells with a mutant strain devoid of the five known Yop effectors (ΔHOPEM strain) but producing YopT resulted in the alteration of the cell cytoskeleton and the disruption of the actin filament structure. This cytotoxic effect was caused by YopT and dependent on YopB. YopT is thus a new effector Yop and a new bacterial toxin affecting the cytoskeleton of eukaryotic cells.

The outer membrane component, YscC, of the Yop secretion machinery of Yersinia enterocolitica forms a ring‐shaped multimeric complex

The YscC protein of Yersinia enterocolitica is essential for the secretion of anti‐host factors, called Yops, into the extracellular environment. It belongs to a family of outer membrane proteins, collectively designated secretins, that participate in a variety of transport processes. YscC has been shown to exist as a stable oligomeric complex in the outer membrane. The production of the YscC complex is regulated by temperature and is reduced in strains carrying mutations in the yscN‐U operon or in the virG gene. The VirG lipoprotein was shown to be required for efficient targeting of the complex to the outer membrane. Electron microscopy revealed that purified YscC complexes form ring‐shaped structures of ≈20 nm with an apparent central pore. Because of the architecture of the multimer, YscC appears to represent a novel type of channel‐forming proteins in the bacterial outer membrane.

Unified nomenclature for broadly conserved hrp genes of phytopathogenic bacteria

Genes of plant-pathogenic bacteria controlling hypersensitive response (HR) elicitation and pathogenesis were designated ‘hrp’ by Lindgren et al. in 1986 (J Bacteriol 168: 512–522). hrp genes have been characterized in several species of the four major genera of Gramnegative plant pathogens, Erwinia, Pseudomonas, Ralstonia (a new proposed genus including Pseudomonas solanacearum) and Xanthomonas. To date, hrp genes have been found mainly in large clusters, and they have been shown to be conserved physically and, in many cases, functionally among different bacteria. Hybridization studies and genetic analyses have revealed the presence of functional hrp genes even in species that are not typically observed to elicit an HR, such as Erwinia chrysanthemi and Erwinia stewartii, suggesting that hrp genes may be common to all Gram-negative plant pathogens, possibly excluding Agrobacterium spp. Current knowledge of hrp genes has been reviewed by Bonas (1994, Curr Top Microbiol Immunol 192: 79–98) and by Van Gijsegem et al. (1995, In Pathogenesis and Host–Parasite Specificity in Plant Diseases: Histopathological, Biochemical, Genetic and Molecular Basis. Volume 1. (Kohmoto et al., eds); Oxford: Pergamon Press, pp. 273–292). The nucleotide sequences of four hrp gene clusters, those of Ralstonia solanacearum (previously P. solanacearum) (Genin et al., 1992, Mol Microbiol 6: 3065–3076; Gough et al., 1992, Mol Plant–Microbe Interact 5: 384–389; Gough et al., 1993, Mol Gen Genet 239: 378–392; Van Gijsegem et al., 1995, Mol Microbiol 15: 1095–1114), Erwinia amylovora (Bogdanove et al., 1996, J Bacteriol 178: 1720– 1730; Wei and Beer, 1993, J Bacteriol 175: 7958–7967; Wei and Beer, 1995, J Bacteriol 177: 6201–6210; Wei et al., 1992, Science 257: 85–88; S. V. Beer, unpublished), Pseudomonas syringae pv. syringae (Huang et al., 1992, J Bacteriol 174: 6878–6885; Huang et al., 1993, Mol Plant–Microbe Interact 6: 515–520; Huang et al., 1995, Mol Plant–Microbe Interact 8: 733–746; Lidell and Hutcheson, 1994, Mol Plant–Microbe Interact 7: 488–497; Preston et al., 1995, Mol Plant–Microbe Interact 8: 717–732; Xiao et al., 1994, J Bacteriol 176: 1025–1036), and Xanthomonas campestris pv. vesicatoria (Fenselau et al., 1992, Mol Plant–Microbe Interact 5: 390–396; Fenselau and Bonas, 1995, Mol Plant–Microbe Interact 8: 845–854; U. Bonas, unpublished), have been largely determined. These clusters each contain more than twenty genes, many of which encode components of a novel proteinsecretion pathway designated ‘type III’. It has been shown directly that various extracellular proteins involved in pathogenesis and defence elicitation by plantpathogenic bacteria utilize this pathway (Arlat et al., 1994, EMBO J 13: 543–553; He et al., 1993, Cell 73: 1255–1266; Wei and Beer, 1993, ibid.), and the pathway is known to function in the export of virulence factors from the animal pathogens Salmonella typhimurium, Shigella flexneri, and Yersinia entercolitica, Yersinia pestis, and Yersinia pseudotuberculosis (for reviews, see Salmond and Reeves, 1993, Trends Biochem Sci 18: 7–12; and Van Gijsegem et al., 1993, Trends Microbiol 1: 175– 180). Nine type III secretion genes are conserved among all four of the plant pathogens listed above and among the animal pathogens. Based on sequence analysis and some experimental evidence, they are believed to encode one outer-membrane protein, one outer-membrane-associated lipoprotein, five inner-membrane proteins, and two cytoplasmic proteins, one of which is a putative ATPase. All of the predicted gene products, except the outer-membrane protein, show significant similarity to components of the flagellar biogenesis complex (for reviews see Blair, 1995, Annu Rev Microbiol 49: 489–522; and Bischoff and Ordal, 1992, Mol Microbiol 6: 23–28). We herein refer to the hrp-encoded type III pathway as the ‘Hrp pathway’. Because hrp genes have been characterized independently in diverse plant-pathogenic bacteria, hrp gene nomenclature differs in different species, and it is not always consistent even within the same organism. Different designations are used for homologous genes, and, even worse, the same designation is used for different genes in different organisms. For example, hrpI of E. amylovora is homologous with hrpC2 of X. campestris pv. vesicatoria and hrpO of R. solanacearum, and the homologue in P. syringae pv. syringae appears in the literature both as hrpI and as hrpJ2. Also, ‘hrpN ’ in R. solanacearum designates a secretion-pathway gene, whereas in E. amylovora, ‘hrpN ’ designates the gene encoding the elicitor harpin. Furthermore, in many bacteria the number of known hrp genes approaches 26. In anticipation of exhausting the alphabet, some authors chose to designate hrp genes with a letter and a number, creating the potential for confusion of distinct genes with alleles of the same gene. For hrp gene researchers, the current nomenclature is at best inconvenient; for other scientists, it is bewildering. Another problem exists: accumulation of knowledge about the structure of hrp loci has outpaced the accumulation of Molecular Microbiology (1996) 20(3), 681–683

Insertion of a Yop translocation pore into the macrophage plasma membrane by Yersinia enterocolitica : requirement for translocators YopB and YopD, but not LcrG

The Yersinia survival strategy is based on its ability to inject effector Yops into the cytosol of host cells. Translocation of these effectors across the eukaryotic cell membrane requires YopB, YopD and LcrG, but the mechanism is unclear. An effector polymutant of Y. pseudotuberculosis has a YopB‐dependent contact haemolytic activity, indicating that YopB participates in the formation of a pore in the cell membrane. Here, we have investigated the formation of such a pore in the plasma membrane of macrophages. Infection of PU5‐1.8 macrophages with an effector polymutant Y. enterocolitica led to complete flattening of the cells, similar to treatment with the pore‐forming streptolysin O from Streptococcus pyogenes. Upon infection, cells released the low‐molecular‐weight marker BCECF (623 Da) but not the high‐molecular‐weight lactate dehydrogenase, indicating that there was no membrane lysis but, rather, insertion of a pore of small size into the macrophage plasma membrane. Permeation to lucifer yellow CH (443 Da) but not to Texas red‐X phalloidin (1490 Da) supported this hypothesis. All these events were found to be dependent not only on translocator YopB as expected but also on YopD, which was required equally. In contrast, LcrG was not necessary. Consistently, lysis of sheep erythrocytes was also dependent on YopB and YopD, but not on LcrG.

Customized secretion chaperones in pathogenic bacteria

Pathogenic yersiniae secrete about a dozen anti‐host proteins, the Yops, by a pathway which does not involve cleavage of a classical signal peptide. The Yop secretory apparatus, called Ysc, for Yop secretion, is the archetype of type III secretion systems (which serve for the secretion of virulence proteins by several animal and plant pathogens) and is related to the flagellar assembly apparatus. The Yop secretion signal is N‐terminal but has not been defined to date. Apart from the Ysc machinery, secretion of at least four Yops requires cytoplasmic proteins called Syc (for specific Yop chaperone). Each Syc protein binds to its cognate Yop. Unlike most cytoplasmic chaperones, these proteins do not have an ATP‐binding domain, and are presumably devoid of ATPase activity. They share a few common properties: an acidic pl, a size in the range of 15–20 kDa, and a putative amphipathic α‐helix in the C‐terminal portion. They were recently shown to have counterparts in other pathogenic bacteria, where they appear to have a similar function.

Role of Yops and adhesins in resistance of Yersinia enterocolitica to phagocytosis.

ABSTRACT Yersinia enterocolitica is a pathogen endowed with two adhesins, Inv and YadA, and with the Ysc type III secretion system, which allows extracellular adherent bacteria to inject Yop effectors into the cytosol of animal target cells. We tested the influence of all of these virulence determinants on opsonic and nonopsonic phagocytosis by PU5-1.8 and J774 mouse macrophages, as well as by human polymorphonuclear leukocytes (PMNs). The adhesins contributed to phagocytosis in the absence of opsonins but not in the presence of opsonins. In agreement with previous results, YadA counteracted opsonization. In every instance, the Ysc-Yop system conferred a significant level of resistance to phagocytosis. Nonopsonized single-mutant bacteria lacking either YopE, -H, -T, or -O were phagocytosed significantly more by J774 cells and by PMNs. Opsonized bacteria were phagocytosed more than nonopsonized bacteria, and mutant bacteria lacking either YopH, -T, or -O were phagocytosed significantly more by J774 cells and by PMNs than were wild-type (WT) bacteria. Opsonized mutants lacking only YopE were phagocytosed significantly more than were WT bacteria by PMNs but not by J774 cells. Thus, YopH, -T, and -O were involved in all of the phagocytic processes studied here but YopE did not play a clear role in guarding against opsonic phagocytosis by J774. Mutants lacking YopP and YopM were, in every instance, as resistant as WT bacteria. Overexpression of YopE, -H, -T, or -O alone did not confer resistance to phagocytosis, although it affected the cytoskeleton. These results show that YopH, YopT, YopO, and, in some instances, YopE act synergistically to increase the resistance of Y. enterocolitica to phagocytosis by macrophages and PMNs.