R. Veltman

Bio: R. Veltman is an academic researcher from University of Groningen. The author has contributed to research in topics: Thermolysin & Protease. The author has an hindex of 1, co-authored 1 publications receiving 25 citations.

Characteristics of the biologically active 35-kDa metalloprotease virulence factor from Listeria monocytogenes

Abstract: Listeria monocytogenes, a facultative intracellular pathogen, synthesizes an extracellular protease which is responsible for the maturation of phosphatidylcholine phospholipase C (lecithinase), a virulence factor involved in cell-to-cell spread. This work describes the environmental parameters necessary for increased production of mature, 35-kDa active protease in strains of L. monocytogenes, and its detection using polyclonal antibodies raised against Bacillus subtilis neutral protease. High performance liquid affinity chromatography was exploited to isolate the biologically active form of the mature protease, which was then subjected to biochemical characterization using casein as a substrate. The protease is a zinc-dependent metalloprotease which degrades casein over a wide range of temperatures and pH values. It can also degrade actin, the most abundant protein in many eukaryotic cells. The Listeria protease was shown to exhibit a high thermal stability and a relatively narrow substrate specificity. A three-dimensional model built on the basis of the homology with thermolysin was used to understand the structural basis of these characteristics.

Pathogen, host and environmental factors contributing to the pathogenesis of listeriosis.

Abstract: Listeriosis is a severe human and animal disease caused by two species of pathogenic bacteria from the genus Listeria, L. monocytogenes and L. ivanovii. In humans, listeriosis is overwhelmingly a foodborne disease, yet much remains to be learned regarding the transmission dynamics of pathogenic Listeria from the environment, through food, to humans. Similarly, our understanding of the various host, pathogen and environmental factors that impact the pathogenesis of listeriosis at the cellular and molecular level is incomplete. This review will summarize what is currently known about animal and human listeriosis, detail the pathogen, host and environmental factors that contribute to pathogenesis and, finally, examine the interactions among those factors that influence the occurrence of human infection.

Bacterial protease inhibitors

Abstract: Serine-, cysteine-, and metalloproteases are widely spread in many pathogenic bacteria, where they play critical functions related to colonization and evasion of host immune defenses, acquisition of nutrients for growth and proliferation, facilitation of dissemination, or tissue damage during infection. Since all the antibiotics used clinically at the moment share a common mechanism of action, acting as inhibitors of the bacterial cell wall biosynthesis or affecting protein synthesis on ribosomes, resistance to these pharmacological agents represents a serious medical problem, which might be resolved by using new generation of antibiotics, possessing a different mechanism of action. Bacterial protease inhibitors constitute an interesting such possibility, due to the fact that many specific as well as ubiquitous proteases have recently been characterized in some detail in both gram-positive as well as gram-negative pathogens. Few potent, specific inhibitors for such bacterial proteases have been reported at this moment except for some signal peptidase, clostripain, Clostridium histolyticum collagenase, botulinum neurotoxin, and tetanus neurotoxin inhibitors. No inhibitors of the critically important and ubiquitous AAA proteases, degP or sortase have been reported, although such compounds would presumably constitute a new class of highly effective antibiotics. This review presents the state of the art in the design of such enzyme inhibitors with potential therapeutic applications, as well as recent advances in the use of some of these proteases in therapy.

The thermolysin family (M4) of enzymes: therapeutic and biotechnological potential.

Abstract: Zinc containing peptidases are widely distributed in nature and have important roles in many physiological processes. M4 family comprises numerous zinc-dependent metallopeptidases that hydrolyze peptide bonds. A large number of these enzymes are implicated as virulence factors of the microorganisms that produce them and are therefore potential drug targets. Some enzymes of the family are able to function at the extremes of temperatures, and some function in organic solvents. Thereby enzymes of the thermolysin family have an innovative potential for biotechnological applications.

Differential Proteomic Analysis of the Bacillus anthracis Secretome: Distinct Plasmid and Chromosome CO2-Dependent Cross Talk Mechanisms Modulate Extracellular Proteolytic Activities

Abstract: Bacillus anthracis is a gram-positive spore-forming bacterium that is the etiological agent of anthrax, a lethal disease sporadically affecting humans and animals, in particular herbivores. In its most severe manifestation, B. anthracis infection is initiated by inhalation of spores, which are taken up by alveolar macrophages and germinate into fast-dividing vegetative cells which secrete toxins and virulence factors during growth (81, 99). If untreated by prompt antibiotic administration, the bacteria invade the bloodstream, resulting in massive bacteremia and consequently generalized systemic failure and death. B. anthracis is considered to represent a potential biothreat agent, owing to the severity of the anthrax disease, the ease of respiratory contamination, and the perpetual environmental stability of the infective spores. The recent deliberate dissemination of B. anthracis (15) accelerated the efforts to identify new B. anthracis virulence-related determinants for the design of novel diagnostic, preventive, and/or therapeutic strategies. Fully virulent B. anthracis strains harbor two native plasmids, pXO1 and pXO2, which encode critical pathogenicity factors. The absence of either one of the two plasmids results in a pronounced attenuation of B. anthracis virulence. The pXO2 plasmid encodes proteins involved in the biosynthesis of the poly-d-glutamic acid capsule, which may inhibit phagocytosis of bacteria during infection; pXO1 encodes the three toxin components protective antigen (PA), lethal factor (LF) (a zinc-dependent metalloprotease which proteolytically inactivates protein kinase kinases 1 and 2), and edema factor (EF) (a calmodulin-dependent adenylate cyclase), which form two binary toxins, lethal toxin and edema toxin. PA, the common component of both toxins, is not toxic by itself, yet it plays the central role of binding a specific receptor on the host cells and translocating LF and EF into the cytosol of infected cells, where they exert their detrimental activities. Anthrax is acknowledged as a toxinogenic disease, owing to the lethality of pure toxin preparations (77); on the other hand, additional B. anthracis secreted proteins are most probably involved in the onset and course of the disease and in survival of the bacteria in the host. The regulatory circuits governing the virulence of B. anthracis are still to be fully deciphered, yet certain observations suggest that the virulence of the bacteria entails cross talk mechanisms which link expression of plasmid-encoded and chromosomally encoded genes. The regulatory AtxA protein, encoded by pXO1, is essential for expression of the toxin and capsule synthesis genes in vivo (a situation which can be mimicked by growing the bacteria in minimal medium under high bicarbonate-CO2 conditions) (75). Two additional regulatory proteins, AcpA and AcpB, encoded by pXO2, were suggested to act downstream of AtxA and to affect capsule synthesis (35, 36). AtxA was found also to influence expression of chromosomal genes, either directly or via AcpA and AcpB. In addition, the protein AbrB, which is a chromosomally encoded transition state regulator, was suggested to negatively control the activity of the toxin gene promoters (123, 131) via AtxA. Secreted proteins include factors involved in pathogenicity, in particular in gram-positive bacteria (79). Such proteins may serve as possible targets for diagnostic purposes and/or therapeutic intervention. Bacteria of the Bacillus cereus phylogenetic group (B. cereus and Bacillus thuringiensis), to which B. anthracis belongs, secrete a diversity of factors that are essential for virulence, including toxins, hemolysins, proteases, and lecithinases. Notably, in these bacteria the secretion of certain virulence factors is regulated by a pleiotropic regulator, PlcR (2, 82, 87, 110), which is inactive in B. anthracis (2). It has been suggested that the evolutionary inactivation of the PlcR regulon in B. anthracis was due to incompatibility with the AtxA-controlled regulon and reflects the fact that the PlcR target genes are not essential for anthrax pathogenicity (96). Several studies have postulated that secreted proteases, other than those belonging to the silenced PlcR regulon, are responsible for some clinical manifestations of anthrax (1, 9, 117, 140). Such proteases could damage host tissues, interfere with immune effectors of the host, and/or provide nutrients for bacterial survival (103). Some chromosomally encoded B. anthracis extracellular proteases were suggested to be controlled by Cot43, a novel regulatory gene encoded by pXO1 (9). The availability of the B. anthracis genomic DNA sequence (109, 121) paved the way for high-throughput genomic, transcriptomic, and proteomic analyses of B. anthracis (6, 7, 8, 17, 25, 41, 50, 64, 78, 85, 121, 144) in an effort to elucidate pathogenicity mechanisms by identification of novel virulence factors or in search for specific therapeutic and/or diagnostic targets. Indeed, bioinformatic surveys of the B. anthracis genome (7, 8, 121) suggested that proteins other than PA, LF, and EF, may participate in anthrax pathogenesis. Furthermore, many B. anthracis open reading frames (ORFs) encode potentially secreted or membrane-bound proteins exhibiting homology to known virulence factors from other bacteria (7, 8). A preliminary proteomic study carried out in our laboratory examined membrane proteins prepared from a nonvirulent B. anthracis strain and led to the recognition of a number of immunodominant exposed proteins (8, 25). Here, we document an extended proteomic study, focusing on B. anthracis secreted proteins, which expands the data set of expressed B. anthracis proteins from both virulent and nonvirulent strains (6, 25, 41, 50, 64, 78, 85, 144). Based on identification of more than 400 two-dimensional electrophoresis (2-DE)-separated protein spots, we report the expression of 64 proteins which represent the most abundant B. anthracis secreted proteins, many of which resemble factors involved in the virulence of other pathogens. Comparison of the relative abundances of proteins in pXO1- and pXO2-containing and plasmid-cured strains reveals about 30 ORFs which are either preferentially expressed or repressed in the virulent B. anthracis strain under conditions which are considered to simulate those encountered within the mammalian host. The pattern of expression of these specific proteins demonstrates that B. anthracis possesses distinct regulatory pathways which involve plasmid- or chromosome-encoded CO2-inducible responsive factors.

Bacterial proteases: current therapeutic use and future prospects for the development of new antibiotics

Abstract: Proteases of the serine-, cysteine- and metallo- type are widely spread in many pathogenic bacteria, where they play critical functions related to colonisation and evasion of host immune defences, acquisition of nutrients for growth and proliferation, facilitation of dissemination, or tissue damage during infection. Since all the antibiotics currently used clinically share a common mechanism of action, i.e., inhibition of bacterial cell wall biosynthesis, resistance to these pharmacological agents represents a serious medical problem, which might be resolved by using a new generation of antibiotics with a different mechanism of action. Bacterial protease inhibitors constitute an interesting possibility, due to the fact that many specific and ubiquitous proteases have recently been characterised in some detail in both Gram-positive and Gram-negative pathogens. Unfortunately, at this moment few potent, specific inhibitors for such bacterial proteases have been reported, except for signal peptidase, clostrip...