Residue Histidine 669 Is Essential for the Catalytic Activity of Bacillus anthracis Lethal Factor

The lethal factor (LF) of Bacillus anthracis is a Zn²⁺-dependent metalloprotease which plays an important role in anthrax virulence. This study was aimed at identifying the histidine residues that are essential to the catalytic activities of LF. The site-directed mutagenesis was employed to replace the 10 histidine residues in domains II, III, and IV of LF with alanine residues, respectively. The cytotoxicity of these mutants was tested, and the results revealed that the alanine substitution for His-669 completely abolished toxicity to the lethal toxin (LT)-sensitive RAW264.7 cells. The reason for the toxicity loss was further explored. The zinc content of this LF mutant was the same as that of the wild type. Also this LF mutant retained its protective antigan (PA)-binding activity. Finally, the catalytic cleavage activity of this mutant was demonstrated to be drastically reduced. Thus, we conclude that residue His-669 is crucial to the proteolytic activity of LF.Anthrax is a zoonotic disease caused by toxigenic strains of the Gram-positive bacterium Bacillus anthracis (24). Because infections are highly fatal, the organisms are easily produced, and the spores spread easily, B. anthracis has been used as a bioweapon in biological war and biological terrorism (38). If inhaled, the spores are phagocytosed by alveolar macrophages, where they germinate to produce vegetative bacteria (10, 24). The vegetative bacteria further release anthrax toxins, which inhibit the innate and adaptive immune responses of the hosts. This enables the capsulated bacteria to escape the lymph node defense barrier to reach the blood system, causing bacteremia and toxemia, which can rapidly kill the hosts (24, 26). The great threat posed by anthrax to the public is not only due to the highly lethal rate of inhaled anthrax, but also is due to the social panic caused by the lethality. Therefore, efficient ways to defend against anthrax infection and spreading are greatly needed. This mostly depends on a full understanding of the mechanisms of anthrax infection and toxicities.Anthrax toxins are the dominant virulence factors of Bacillus anthracis (6, 33, 37). They consist of three proteins: protective antigen (PA; 83 kDa), lethal factor (LF; 90 kDa), and edema factor (EF; 89 kDa). The 83-kDa PA (PA₈₃) directly binds to cellular membrane receptors and was cleaved to an active fragment of 63-kDa PA (PA₆₃) by cellular proteases of the furin family or by serum proteases. The receptor-bound portion of PA₆₃ self-assembles into either ring-shaped heptamers, which bind to three molecules of LF and/or EF, resulting in (PA₆₃)₇(LF/EF)₃ (21), or octamers which bind up to four molecules of these moieties, resulting in (PA₆₃)₈(LF/EF)₄ complexes (16, 17). The catalytic partners (EF and/or LF) are subsequently transported across the membrane to the cell cytosol (24, 27). EF is a Ca²⁺- and calmodulin-dependent adenylate cyclase that, together with PA, forms edema toxin. EF causes a rapid increase in intracellular cyclic AMP (cAMP) levels in host cells and alters the elaborate balance of intracellular signaling pathways (20, 23). LF is a Zn²⁺-dependent protease that, together with PA, forms lethal toxin (LT). It is a dominant virulence factor and the major cause of death for the B. anthracis-infected animals (1, 29, 30). LF specifically cleaves the N-terminal domain of mitogen-activated protein kinase kinases (MAPKKs) (11, 35). Because the N-terminal domain of MAPKKs is essential for the interaction between MAPKKs and MAPKs, the cleavage of this domain impairs the activation of MAPKs (8, 11, 15) and leads to the inhibition of three major cellular signaling pathways—the ERK (extracellular signal-regulated kinase), p38, and JNK (c-Jun N-terminal kinase) pathways (29, 31)—and thus induces the lysis of the host cells in an unknown mechanism.The crystal structure of LF with the N-terminal domain of MEK2 has been reported (28). LF has 776 amino acids and comprises four different domains. Domain I (residues 1 to 254) is a PA-binding domain which delivers the remaining domains of the LF to the cell cytoplasm (3). The interface among domains II, III, and IV creates long, deep, 40-Å-long catalytic grooves into which the N terminus of MEK fits and forms an active site complex (28). Domain IV is central to catalytic activities of LF, containing two zinc-binding motifs (residues 686 to 690 and residues E735 to E739) and bound to a single Zn ion (18). However, which residues of LF are critical for efficient catalytic activities and execute the substrate cleavage remains unclear.Histidine is the only naturally occurring amino acid to contain an imidazole residue as a side chain. The catalytic activity of histidine mostly depends on the special features of the imidazole residue. The logarithm of the proton dissociation constant of imidazolyl in the histidine residue is about 6.5; thus, under the physiological condition, it tends to form hydrogen bonds and shares donor and acceptor properties that can take part in either nucleophilic or base catalysis. The speed of the imidazole residue to give or accept protons is very fast, with a half-life of less than 10 s. So in the process of natural selection, histidine was chosen as the catalytic structure, indicating that it plays an important role in the catalysis process of enzymes (9, 12, 14). There are 21 histidines in LF, with 9 of them in LF domain I and 12 of them in domains II, III, and IV. The histidine residues important to LF activities in domain I have been identified (2, 22). The other 12 histidine residues in the remaining three domains include His-277, His-280, and His-424 in domain II; His-309 in domain III; and His-588, His-645, His-654, His-669, His-686, His-690, His-745, and His-749 in domain IV (28). His-686 and His-690 in domain IV were demonstrated to form a zinc binding site constituting a thermolysin-like zinc metalloprotease motif, HEXXH (18). The activities of the remaining 10 histidine residues in domains II, III, and IV have not been explored yet. In this study, we replaced these 10 histidine residues separately with alanine residues by site-directed mutagenesis. By the cytotoxicity assay of all these mutants, the H669A mutant was found to lose cell toxicity completely. Further assay revealed that residue His-669 was involved in neither zinc stabilization nor PA binding but participated in the substrate proteolytic activity of LF.