The study of the membrane insertion of the translocation domain of diphtheria toxin deepens our insight into the interactions between proteins and membranes. During cell intoxication, this domain undergoes a change from a soluble and folded state at alkaline pH to a functional membrane-inserted state at acid pH. We found that hydrophobic and electrostatic interactions occur in a sequential manner between the domain and the membrane during the insertion. The first step involves hydrophobic interactions by the C-terminal region. This is because of the pH-induced formation of a molten globule specialized for binding to the membrane. Accumulation of this molten globule follows a precise molecular mechanism adapted to the toxin function. The second step, as the pH decreases, leads to the functional inserted state. It arises from the changes in the balance of electrostatic attractions and repulsions between the N-terminal part and the membrane. Our study shows how the structural changes and the interaction with membranes of the translocation domain are finely tuned by pH changes to take advantage of the cellular uptake system.Folding and insertion of membrane proteins (1, 2), binding of hormones to membrane receptors (3), action of antibiotic peptides (4, 5), protein translocation, and internalization of toxins (6) are examples of phenomena that require the interactions of polypeptide chains with membranes. Because of the anisotropic nature of membranes, the initial steps of the association and the final structure and localization of polypeptide chains within membranes depend on a combination of hydrophobic and electrostatic interactions (7). Hydrophobic interactions are dominant for the insertion of transmembrane polypeptides. Electrostatic interactions are important for the binding of antibiotic peptides (5,8), the association of proteins with the surface of the membrane (9 -11), and as determinants of the topology of integral membrane proteins after biosynthesis (12). In most cases, electrostatic interactions are the result of the attraction between anionic phospholipid head groups and basic amino acid side chains (13,14). However, there are examples where electrostatic repulsions are involved in the membrane association of peptides, particularly when their structure and localization within the membrane is regulated by the pH (15-19). The interplay of hydrophobicity and electrostatics and their distribution within the polypeptide sequence have only been studied in detail for small peptides (3-5, 7, 13-15, 17-20). In the case of proteins, the role of these effects on the association with and the insertion into membranes are still poorly understood (2,(21)(22)(23)(24).The study of the membrane insertion process of the translocation (T) 1 domain of diphtheria toxin (25) can provide precious insight into the interactions between proteins and membranes and the refolding mechanisms of membrane proteins. During intoxication of cells (25), the toxin reaches the early endosomes through the clathrin-coated pathway (26). Beca...
Helicobacter pylori synthesizes a heat-shock protein of the GroES class. The gene encoding this protein (heat-shock protein A, HspA) was recently cloned and it was shown to be unique in structure. H. pylori HspA consists of two domains: the N-terminal domain (domain A) homologous with other GroES proteins, and a C-terminal domain (domain B) corresponding to 27 additional residues resembling a metal-binding domain. Various recombinant proteins consisting of the entire HspA polypeptide, the A domain, or the B domain were produced independently as proteins fused to maltose-binding protein (MBP). Comparison of the divalent cation binding properties of the various MBP and MBP-fused proteins allowed us to conclude that HspA binds nickel ions by means of its C-terminal domain. HspA exhibited a high and specific affinity for nickel ions in comparison with its affinity for other divalent cations (copper, zinc, cobalt). Equilibrium dialysis experiments revealed that MBP-HspA binds nickel ions with an apparent dissociation constant (Kd) of 1.8 microM and a stoichiometry of 1.9 ions per molecule. The analysis of the deduced HspA amino acid sequences encoded by 35 independent clinical isolates demonstrated the existence of two molecular variants of HspA, i.e. a major and a minor variant present in 89% and 11% of strains, respectively. The two variants differed from each other by the simultaneous substitution of seven amino acids within the B domain, whilst the A domain was highly conserved amongst all the HspA proteins (99-100% identity). On the basis of serological studies, the highly conserved A domain of HspA was found to be the immunodominant domain. Functional complementation experiments were performed to test the properties of the two HspA variants. When co-expressed together with the H. pylori urease gene cluster in Escherichia coli cells, the two HspA variant-encoding genes led to a fourfold increase in urease activity, demonstrating that HspA in H. pylori has a specialized function with regard to the nickel metalloenzyme urease.
The mechanism of sarcoplasmic reticulum (SR) ATPase Mg2+-dependent phosphorylation from Pi was investigated in the presence of 15% v/v dimethyl sulfoxide at pH 6, 20 degrees C, and in the absence of potassium. Measurements of intrinsic fluorescence changes and of 32P-labeled phosphoprotein (*E-P) were in agreement, both at equilibrium and in transient situations. We found that the amount of phosphoenzyme present and its rate of formation depended solely on the concentration of the (Mg X Pi) complex. Up to 6 nmol of phosphate/mg of protein was covalently bound to the enzyme, implying almost complete phosphorylation. Oxygen exchange experiments were also performed in order to allow calculation of the absolute rate constant of *E-P hydrolysis to the noncovalent complex (0.8-1.0 s-1), which differs from the observed rate of enzyme dephosphorylation (0.3-0.5 s-1); in addition, they allowed calculation of the bimolecular rate constant of substrate binding (2-2.4 M-1 s-1). The results demonstrate that in the presence of dimethyl sulfoxide, phosphorylation occurs by the following simple mechanism: relatively slow binding of the neutral substrate (Mg X Pi), with poor affinity, followed by a thermodynamically favorable formation of the covalent bond between phosphate and the possibly hydrophobic active site. The interaction between magnesium and calcium-deprived SR vesicles was studied in the presence of 0-20% v/v dimethyl sulfoxide (or 0-30% v/v glycerol) at pH 7 and 20 degrees C. The presence of either solvent led to the disappearance of the two typical pH-dependent effects we previously characterized for magnesium: loss of the Mg2+-induced spectral shift of tryptophan fluorescence emission and loss of the biphasic pattern displayed by the intrinsic fluorescence rise after addition of calcium to Ca2+-deprived Mg2+-preincubated vesicles. In the absence of solvent, the interaction of magnesium with the calcium-deprived ATPase was also characterized from the point of view of phosphoenzyme formation from ATP or Pi at pH 7 in the absence of potassium: we found that calcium-independent phosphorylation was slower when phosphate was added to SR vesicles preincubated with magnesium that when magnesium was added to vesicles preincubated with phosphate, suggesting that preincubation with magnesium had depleted the phosphate-reactive conformation of the ATPase. A simple reaction scheme for phosphoenzyme formation is described: it implies that the (Mg X Pi) complex is a substrate for this reaction, whereas the Mg2+ itself acts as a pH-dependent, dimethyl sulfoxide sensitive inhibitor of full enzyme phosphorylation.(ABSTRACT TRUNCATED AT 400 WORDS)
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