A panel of variants with alanine substitutions in the small loop of anthrax toxin protective antigen domain 4 was created to determine individual amino acid residues critical for interactions with the cellular receptor and with a neutralizing monoclonal antibody, 14B7. Substituted protective antigen proteins were analyzed by cellular cytotoxicity assays, and their interactions with antibody were measured by plasmon surface resonance and analytical ultracentrifugation. Residue Asp 683 was the most critical for cell binding and toxicity, causing an ϳ1000-fold reduction in toxicity, but was not a large factor for interactions with 14B7. Substitutions in residues Tyr 681 , Asn 682 , and Pro 686 also reduced toxicity significantly, by 10 -100-fold. Of these, only Asn 682 and Pro 686 were also critical for interactions with 14B7. However, residues Lys 684 , Leu 685 , Leu 687 , and Tyr 688 were critical for 14B7 binding without greatly affecting toxicity. The K684A and L685A variants exhibited wild type levels of toxicity in cell culture assays; the L687A and Y688A variants were reduced only 1.5-and 5-fold, respectively.Bacillus anthracis secretes two toxins: edema toxin and lethal toxin. Each is composed of a common binding component, protective antigen (PA), 1 together with an enzymatic component, edema factor (EF), in the case of edema toxin and lethal factor (LF) in the case of lethal toxin (1-3). The current model for toxin entry into the cell illustrates the centrality of PA for toxin action. PA binds to cellular receptors, recently identified as splice variants of either tumor endothelial marker 8 (TEM8) (4 -6) or the closely related capillary morphogenesis protein 2 (CMG2) (7). Furin cleaves PA, releasing a 20-kDa fragment and leaving behind a 63-kDa portion (PA 63 ) capable of forming a heptamer, which has a newly exposed surface that binds . Heptamer complexes enter the endocytic pathway by receptor-mediated endocytosis (13), and upon acidification of the vesicle, the PA 63 heptamer undergoes a conformational change to form a pore through which EF and LF translocate into the cytoplasm (10, 11, 14 -16). Once in the cytoplasm, EF and LF exert their toxic effects.The PA protein can be divided into four domains based on its crystal structure, and functions can be attributed to the different domains based on mutational and biochemical analyses (16). Domain 1 (residues 1-258) contains the furin cleavage site as well as the hydrophobic portion of PA, which is exposed upon furin cleavage to allow EF and LF to bind (16,17). Several lines of evidence indicate that domain 2 (residues 259 -487) is involved in oligomerization and contains the loop that inserts into the membrane to form the channel through which the LF and EF enter the cytosol (16, 18 -20). Various amino acids in domain 3 (residues 488 -595) are necessary for oligomerization, and this has been the only function attributed to domain 3 to date (21,22). Domain 4 (residues 596 -735) is essential for binding to cellular receptor as indicated by several lines of...
Anthrax lethal toxin produced by the bacterium Bacillus anthracis is the major cause of death in animals infected with anthrax. One component of this toxin, lethal factor (LF), inactivates members of the mitogen-activated protein kinase kinase or MEK family through proteolysis of their NH 2 termini. However, neither the substrate requirements for LF cleavage nor the mechanism by which proteolysis inactivates MEK have been demonstrated. By means of deletion mutant analysis and site-directed mutagenesis, we have identified an LFIR (LF interacting region) in the COOH-terminal kinase domain of MEK1 adjacent to the proline-rich region, which is essential for LF-mediated proteolysis of MEK. Point mutations in this region block proteolysis but do not alter the kinase activity of MEK. Similar mutations in MEK6 also prevent proteolysis, indicating that this region is functionally conserved among MEKs. In addition, NH 2 -terminal proteolysis of MEK1 by LF was found to reduce not only the affinity of MEK1 for its substrate mitogen-activated protein kinase but also its intrinsic kinase activity, indicating that the NH 2 -terminal end of MEK is important not only for substrate interaction but also for catalytic activity.The lethal effects of Bacillus anthracis have been attributed to an exotoxin, which it produces (1). This exotoxin is composed of three proteins: protective antigen (PA), 1 edema factor, and lethal factor (LF) (for recent reviews see Refs. 2 and 3). PA binds to a cell surface receptor (4) and, upon proteolytic activation to a 63-kDa fragment, heptamerizes to form a membrane channel that mediates the entry of three molecules of LF or edema factor into the cell (5-7). Edema factor is an adenylate cyclase and, together with PA, forms a toxin referred to as edema toxin (8). LF is a Zn 2ϩ -metalloprotease, which together with PA forms a toxin referred to as lethal toxin. Lethal toxin is the dominant virulence factor produced by B. anthracis and is the major cause of death in infected animals (9).Although LF has been shown to cleave the NH 2 termini of select members of the mitogen-activated protein kinase kinase or MEK family (10 -12), the substrate requirements that determine LF specificity are unknown. Indirect evidence suggests that epitopes distal to the cleavage site are required for LF-MEK interaction. Yeast two-hybrid assays for binding partners of LF have isolated cDNA for MEK2, which lacks the NH 2 -terminal cleavage site (13). Moreover, although it has been demonstrated that LF-cleaved MEK1 as well as recombinant MEK1, which lacks the seven NH 2 -terminal residues that are removed by LF, has reduced kinase activity (10), it is not clear how the absence of these residues alters MEK activity. Therefore, to identify regions distal to the cleavage site that are required for proteolysis, we have constructed a series of internal and COOH-terminal deletion mutants of MEK1 and have analyzed their cleavability by LF. The results reveal that a functionally conserved COOH-terminal region located adjacent to a proli...
A variety of ion channels are regulated by cholesterol, a major lipid component of the plasma membrane whose excess is associated with multiple pathological conditions. However, the mechanism underlying cholesterol sensitivity of ion channels is unknown. We have recently shown that an increase in membrane cholesterol suppresses inwardly rectifying K ؉ (Kir2) channels that are responsible for maintaining membrane potential in a variety of cell types. Here we show that cholesterol sensitivity of Kir2 channels depends on a specific region of the C terminus of the cytosolic domain of the channel, the CD loop. Within this loop, the L222I mutation in Kir2.1 abrogates the sensitivity of the channel to cholesterol whereas a reverse mutation in the corresponding position in Kir2.3, I214L, has the opposite effect, increasing cholesterol sensitivity. Furthermore, the L222I mutation has a dominant negative effect on cholesterol sensitivity of Kir2.1 WT. Mutations of 2 additional residues in the CD loop in Kir2.1, N216D and K219Q, partially affect the sensitivity of the channel to cholesterol. Yet, whereas these mutations have been shown to affect activation of the channel by the membrane phospholipid phosphatidylinositol 4,5-bisphosphate [PI(4,5)P 2], other mutations outside the CD loop that have been previously shown to affect activation of the channel by PI(4,5)P2 had no effect on cholesterol sensitivity. Mutations of the lipid-facing residues of the outer transmembrane helix also had no effect. These findings provide insights into the structural determinants of the sensitivity of Kir2 channels to cholesterol, and introduce the critical role of the cytosolic domain in cholesterol dependent channel regulation.
PA63, a proteolytically activated 63-kDa form of anthrax protective antigen (PA), forms heptameric oligomers and has the ability to bind and translocate the catalytic moieties, lethal factor (LF), and edema factor (EF) into the cytosol of mammalian cells. Acidic pH triggers oligomerization and membrane insertion by PA63. A disordered amphipathic loop in domain II of PA (22-23 loop) is involved in membrane insertion by PA63. Because conditions required for membrane insertion coincide with those for oligomerization of PA63 in mammalian cells, residues constituting the 22-23 loop were replaced with the residues of the amphipathic membrane-inserting loop of its homologue iota-b toxin secreted by Clostridium perfringens. It was hypothesized that such a molecule might assemble into heteroheptameric structures with wild-type PA ultimately leading to the inhibition of cellular intoxication. The mutation blocked the ability of PA to mediate membrane insertion and translocation of LF into the cytosol but had no effect on proteolytic activation, oligomerization, or binding LF. Moreover, an equimolar mixture of purified mutant PA (PA-I) and wild-type PA showed complete inhibition of toxin activity both in vitro on J774A.1 cells and in vivo in Fischer 344 rats thereby exhibiting a dominant negative effect. In addition, PA-I inhibited the channel-forming ability of wild-type PA on the plasma membrane of CHO-K1 cells thereby indicating protein-protein interactions between the two proteins resulting in the formation of mixed oligomers with defective functional activity. Our findings provide a basis for understanding the mechanism of translocation and exploring the possibility of the use of this PA molecule as a therapeutic agent against anthrax toxin action in vivo.
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