Adenylate cyclase toxin is a virulence factor produced by some members of the genus Bordetella . Together with the pertussis toxin it is the most important virulence factor of the causative agent of whooping cough, Bordetella pertussis . Bordetella bronchiseptica and Bordetella parapertussis, also able to cause pertussis-like symptoms, also produce adenylate cyclase toxin. [1] It is a toxin secreted by the bacteria to influence the host immune system.
Adenylate cyclase toxin from Bordetella pertussis is a 1706 amino acid residue long protein. The protein consists of three domains: from the N-terminus up to roughly residue 400, there is an adenylate-cyclase domain; between residues 500 and 700, there is a hydrophobic domain; and from residue 1000 to the C-terminus, there are calcium binding repeats. Two acylation sites are located at lysine residues K860 and K983. [2] [3] The part of the toxin from residue 400 to the C-terminus, called hemolysin, is structurally related to a large family of bacterial toxins - RTX toxins. [3] Differences between the toxins of different Bordetella species are mainly in the calcium-binding domain. [4]
The toxin is secreted by the Type I secretion system, which spans both membranes and periplasm space, allowing the toxin to be secreted from the cytoplasm straight outside the cell. [1] [2] A large proportion of the toxin remains associated with the bacterium exterior proteins, mainly filamentous haemagglutinin, but these toxin molecules are not active. [5] [1] Besides attachment to bacterial proteins, aggregation also inactivates the toxin. [5] This quick inactivation highlights the necessity of close contact between secreting bacterium and target cell. [1]
RTX stands for 'repeats in toxins,' but not all members of the family are toxins. Repeating aspartate and glycine rich nonapeptides (repeats 9 amino acids long) are a characteristic feature of this family of proteins, and are able to bind calcium ions. [3] A feature of the RTX proteins is their ability to form pores in cell membranes, allowing ions to leak. This may manifest as a hemolytic activity on erythrocytes, leading to this group of toxins being called 'hemolysins'. The cell types which are vulnerable to this pore-forming activity varies among the toxins. The acylation of lysines is required for the pore-forming cytotoxic effects of all the RTX proteins. [6]
Toxins from many known gram-negative pathogenic bacteria are in the RTX family. An example is α-hemolysin from Escherichia coli or RtxA from Vibrio cholerae. [6]
Adenylate cyclese toxin binds to target cells by the complement receptor 3 (CD11b/CD18, or Mac-1). [7] Target cell are therefore myeloid lineage cells, mainly phagocytes, such as neutrophils. [1] Binding to cells without the CR3 also happens, but at a much lower rate. [5] The portion responsible for binding to the receptor is inside the calcium binding repeats, from residues 1166 to 1287. [3] The hemolysin portion of the protein then binds to the target membrane and inserts itself into the bilayer. [3] [5] The adenylate cyclase (AC) domain is then translocated across the cytoplasmic membrane into the cytoplasm. Translocation of the AC domain is independent of cytotoxic pore-forming activity, as these two activities require to toxin to adopt different conformations. [5] [2] The transiently opened pores do, however, contribute to AC domain function by potassium leakage and calcium influx into the target cell, which slows endocytosis of CR3/adenylate cyclase toxin clusters, [2] also, the CR3/toxin complex is mobilized by detachment from the cytoskeleton. The complex is then recruited into cholesterol-rich lipid rafts. [3] Calcium influx by itself has many negative effects on target cells, such as deregulation of cellular signalling. [5]
The adenylate cyclase domain has intrinsic enzymatic activity. Translocation of the AC domain into the cell starts the main process by which this toxin influences target cells: the AC domain binds calmodulin, and catalyzes unregulated production of cAMP from ATP. [7] cAMP is an important second messenger molecule and its massive overproduction affects many cellular processes. In phagocytes, most of the bactericidal functions are stopped by cAMP-mediated activation of PKA and Epac. [7]
The above described effects of the adenylate cyclase toxin, mainly the cAMP overproduction, have a profound effect on target cells. Although phagocytic immune cells migrate to the site of infection in the lungs, they are not able to mount an effective response. Not only the phagocytic uptake of bacteria is blocked, but subsequent production of ROS by neutrophils and monocytes, NETs by neutrophils, and NO by macrophages, is also inhibited. [5] [7] [3] The effect on neutrophils is most important in early infection with Bordetella, impairing most of their antimicrobial functions. [3] Intoxication with the adenylate cyclase toxin leads to shift in polarization of macrophages from M1 (proinflammatory) phenotype to M2 (immunoregulatory) phenotype and may lead to macrophage apoptosis. [7] [3] cAMP accumulation after adenylate cyclase intoxication also interferes with IRF signalling in dendritic cells, which leads to lower IL-12 production. IL-12 is important for T-cell response polarization. [7] Other effects of cAMP on dendritic cell interaction with T-cells are also detrimental to the immune response. Although cAMP induces dendritic cell migration into lymph nodes, it lowers their capacity to interact with T-cells and present antigen. This has a tolerogenic effect on the T-cell population. [7]
Vaccination against Bordetella pertussis is used in infancy to prevent whooping cough. The recent switch from whole-cell pertussis vaccine to acellular component vaccine in many countries has led to the fact that adenylate cyclase toxin is not present in most vaccines. [4] Although not included in current vaccines, research shows that immunization with adenylate cyclase toxin elicits neutralizing antibodies. Neutralizing antibodies can block binding of the toxin to CR3. [3] Antibodies against adenylate cyclase toxin are also present in the serum of humans infected with B. pertussis. [4]
Adenylate cyclase toxin based constructs have been proven to elicit the production of neutralizing antibodies, but lack the cytotoxicity associated with the complete toxin. Genetically detoxified adenylate cyclase toxin also serves in promoting the Th1/Th17 response, acting as an adjuvant. [4]
Adenylate cyclase toxin, or its parts, also serve as a tool for cell biologists. The AC domain finds use as a reporter protein. This reporter activity is based on activating cAMP production if translocated into a cell, conjugated to a studied protein. The AC domain consists of two subdomains, both are required for cAMP production. Conjugating each subdomain to a different protein allows protein-protein interactions to be studied, because cAMP production indicates close interaction of the proteins. Similarly, the two subdomains can be linked by a studied protein, which is then digested by proteases. Loss of cAMP production indicates cleavage by protease. [8]
Adenylyl cyclase is an enzyme with key regulatory roles in essentially all cells. It is the most polyphyletic known enzyme: six distinct classes have been described, all catalyzing the same reaction but representing unrelated gene families with no known sequence or structural homology. The best known class of adenylyl cyclases is class III or AC-III. AC-III occurs widely in eukaryotes and has important roles in many human tissues.
Cyclic adenosine monophosphate is a second messenger important in many biological processes. cAMP is a derivative of adenosine triphosphate (ATP) and used for intracellular signal transduction in many different organisms, conveying the cAMP-dependent pathway.
An exotoxin is a toxin secreted by bacteria. An exotoxin can cause damage to the host by destroying cells or disrupting normal cellular metabolism. They are highly potent and can cause major damage to the host. Exotoxins may be secreted, or, similar to endotoxins, may be released during lysis of the cell. Gram negative pathogens may secrete outer membrane vesicles containing lipopolysaccharide endotoxin and some virulence proteins in the bounding membrane along with some other toxins as intra-vesicular contents, thus adding a previously unforeseen dimension to the well-known eukaryote process of membrane vesicle trafficking, which is quite active at the host-pathogen interface.
In molecular biology, pertactin (PRN) is a highly immunogenic virulence factor of Bordetella pertussis, the bacterium that causes pertussis. Specifically, it is an outer membrane protein that promotes adhesion to tracheal epithelial cells. PRN is purified from Bordetella pertussis and is used for the vaccine production as one of the important components of acellular pertussis vaccine.
Bordetella is a genus of small, gram-negative coccobacilli of the phylum Pseudomonadota. Bordetella species, with the exception of B. petrii, are obligate aerobes, as well as highly fastidious, or difficult to culture. All species can infect humans. The first three species to be described ; are sometimes referred to as the 'classical species'. Two of these are also motile.
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Bordetella pertussis is a Gram-negative, aerobic, pathogenic, encapsulated coccobacillus of the genus Bordetella, and the causative agent of pertussis or whooping cough. Like B. bronchiseptica, B. pertussis is motile and expresses a flagellum-like structure. Its virulence factors include pertussis toxin, adenylate cyclase toxin, filamentous hæmagglutinin, pertactin, fimbria, and tracheal cytotoxin.
Oncomodulin is a parvalbumin-family calcium-binding protein expressed and secreted by macrophages.
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Anthrax toxin is a three-protein exotoxin secreted by virulent strains of the bacterium, Bacillus anthracis—the causative agent of anthrax. The toxin was first discovered by Harry Smith in 1954. Anthrax toxin is composed of a cell-binding protein, known as protective antigen (PA), and two enzyme components, called edema factor (EF) and lethal factor (LF). These three protein components act together to impart their physiological effects. Assembled complexes containing the toxin components are endocytosed. In the endosome, the enzymatic components of the toxin translocate into the cytoplasm of a target cell. Once in the cytosol, the enzymatic components of the toxin disrupts various immune cell functions, namely cellular signaling and cell migration. The toxin may even induce cell lysis, as is observed for macrophage cells. Anthrax toxin allows the bacteria to evade the immune system, proliferate, and ultimately kill the host animal. Research on anthrax toxin also provides insight into the generation of macromolecular assemblies, and on protein translocation, pore formation, endocytosis, and other biochemical processes.
Cytolysin refers to the substance secreted by microorganisms, plants or animals that is specifically toxic to individual cells, in many cases causing their dissolution through lysis. Cytolysins that have a specific action for certain cells are named accordingly. For instance, the cytolysins responsible for the destruction of red blood cells, thereby liberating hemoglobins, are named hemolysins, and so on. Cytolysins may be involved in immunity as well as in venoms.
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Gi protein alpha subunit is a family of heterotrimeric G protein alpha subunits. This family is also commonly called the Gi/o family or Gi/o/z/t family to include closely related family members. G alpha subunits may be referred to as Gi alpha, Gαi, or Giα.
Alpha-toxin, also known as alpha-hemolysin (Hla), is the major cytotoxic agent released by bacterium Staphylococcus aureus and the first identified member of the pore forming beta-barrel toxin family. This toxin consists mostly of beta-sheets (68%) with only about 10% alpha-helices. The hly gene on the S. aureus chromosome encodes the 293 residue protein monomer, which forms heptameric units on the cellular membrane to form a complete beta-barrel pore. This structure allows the toxin to perform its major function, development of pores in the cellular membrane, eventually causing cell death.
The RTX toxin superfamily is a group of cytolysins and cytotoxins produced by bacteria. There are over 1000 known members with a variety of functions. The RTX family is defined by two common features: characteristic repeats in the toxin protein sequences, and extracellular secretion by the type I secretion systems (T1SS). The name RTX refers to the glycine and aspartate-rich repeats located at the C-terminus of the toxin proteins, which facilitate export by a dedicated T1SS encoded within the rtx operon.
Adenylate cyclase toxin (CyaA) is released from bacterium Bordetella pertussis by the T1SS and released in the host’s respiratory tract in order to suppress its early innate and subsequent adaptive immune defense.
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Cry6Aa is a toxic crystal protein generated by the bacterial family Bacillus thuringiensis during sporulation. This protein is a member of the alpha pore forming toxins family, which gives it insecticidal qualities advantageous in agricultural pest control. Each Cry protein has some level of target specificity; Cry6Aa has specific toxic action against coleopteran insects and nematodes. The corresponding B. thuringiensis gene, cry6aa, is located on bacterial plasmids. Along with several other Cry protein genes, cry6aa can be genetically recombined in Bt corn and Bt cotton so the plants produce specific toxins. Insects are developing resistance to the most commonly inserted proteins like Cry1Ac. Since Cry6Aa proteins function differently than other Cry proteins, they are combined with other proteins to decrease the development of pest resistance. Recent studies suggest this protein functions better in combination with other virulence factors such as other Cry proteins and metalloproteinases.>