Possible important pair of acidic residues in vesicular acetylcholine transporter.

Invariant E309 is in contact with critical and invariant D398 in a three-dimensional homology model of vesicular acetylcholine transporter (VAChT, TC 2.A.1.2.13) [Vardy, E., et al. (2004) Protein Sci. 13, 1832-1840]. In the work reported here, E309 and D398 in human VAChT were mutated singly and together to test their functions, assign pK values to them, and determine whether the residues are close to each other in three-dimensional space. Mutants were stably expressed in the PC12(A123.7) cell line, and transport and binding properties were characterized at different pH values using radiolabeled ligands and filtration assays. Contrary to a prior conclusion, the results demonstrate that most D398 mutants do not bind the allosteric inhibitor vesamicol even weakly. Earlier work showed that most D398 mutants do not transport ACh. D398 therefore probably is the residue that must deprotonate with a pK of 6.5 for binding of vesamicol and with a pK of approximately 5.9 for transport of ACh. Because E309Q has no effect on VAChT functions at physiological pH, E309 has no apparent critical role. However, radical mutations in E309 cause decreases in ACh and vesamicol affinities and total loss of ACh transport. Unlike wild-type VAChT, which exhibits a peak of [(3)H]vesamicol binding centered at pH 7.4, mutants E309Q, E309D, E309A, and E309K all exhibit peaks of binding centered at pH >or=9. The combination of high pH and mutated E309 apparently produces a relaxed (in contrast to tense) conformation of VAChT that binds vesamicol exceptionally tightly. No compensatory interactions between E309 and D398 in double mutants were discovered. Proof of a close spatial relationship between E309 and D398 was not found. Nevertheless, the data are more consistent with the homology model than an alternative hydropathy model of VAChT that likely locates E309 far from D398 and the ACh binding site in three-dimensional space. Also, a probable network of interactions involving E309 and an unknown residue having a pK of 10 has been revealed.

Mutational and bioinformatics analysis of proline- and glycine-rich motifs in vesicular acetylcholine transporter.

The vesicular acetylcholine transporter (VAChT) contains six conserved sequence motifs that are rich in proline and glycine. Because these residues can have special roles in the conformation of polypeptide backbone, the motifs might have special roles in conformational changes during transport. Using published bioinformatics insights, the amino acid sequences of the 12 putative, helical, transmembrane segments of wild-type and mutant VAChTs were analyzed for propensity to form non-alpha-helical conformations and molecular notches. Many instances were found. In particular, high propensity for kinks and notches are robustly predicted for motifs D2, C and C'. Mutations in these motifs either increase or decrease Vmax for transport, but they rarely affect the equilibrium dissociation constants for ACh and the allosteric inhibitor, vesamicol. The near absence of equilibrium effects implies that the mutations do not alter the backbone conformation. In contrast, the Vmax effects demonstrate that the mutations alter the difficulty of a major conformational change in transport. Interestingly, mutation of an alanine to a glycine residue in motif C significantly increases the rates for reorientation across the membrane. These latter rates are deduced from the kinetics model of the transport cycle. This mutation is also predicted to produce a more flexible kink and tighter tandem notches than are present in wild-type. For the full set of mutations, faster reorientation rates correlate with greater predicted propensity for kinks and notches. The results of the study argue that conserved motifs mediate conformational changes in the VAChT backbone during transport.

Acetylcholine binding site in the vesicular acetylcholine transporter.

This study sought primarily to locate the acetylcholine (ACh) binding site in the vesicular acetylcholine transporter (VAChT). The design of the study also allowed us to locate residues linked to (a) the binding site for the allosteric inhibitor vesamicol and (b) the rates of the two transmembrane reorientation steps of a transport cycle. In more characterized proteins, ACh is known to be bound in part through cation-pi solvation by tryptophan, tyrosine, and phenylalanine residues. Each of 11 highly conserved W, Y, and F residues in putative transmembrane domains (TMDs) of rat VAChT was mutated to A and a different aromatic residue to test for loss of cation-pi solvation. Mutated VAChTs were expressed in PC12(A123.7) cells and characterized with the goal of determining whether mutations widely perturbed structure. The thermodynamic affinity for ACh was determined by displacement of trace [(3)H]-(-)-trans-2-(4-phenylpiperidino)cyclohexanol (vesamicol) with ACh, and Michaelis-Menten parameters were determined for [(3)H]ACh transport. Expression levels were determined with [(3)H]vesamicol saturation curves and Western blots, and they were used to normalize V(max) values. "Microscopic" parameters for individual binding and rate steps in the transport cycle were calculated on the basis of a published kinetics model. All mutants were expressed adequately, were properly glycosylated, and bound ACh and vesamicol. Subcellular mistargeting was shown not to be responsible for poor transport by some mutants. Mutation of residue W331, which lies in the beginning of TMD VIII proximal to the vesicular lumen, produced 5- and 9-fold decreased ACh affinities and no change in other parameters. This residue is a good candidate for cation-pi solvation of bound ACh. Mutation of four other residues decreased the ACh affinity up to 6-fold and also affected microscopic rate constants. The roles of these residues in ACh binding and transport thus are complex. Nine mutations allowed us to resolve the ACh and vesamicol binding sites from each other. Other mutations affected only the rates of the transmembrane reorientation steps, and four mutations increased the rate of one or the other. Two mutations increased the value of K(M) up to 5-fold as a result of rate effects with no ACh affinity effect. The results demonstrate that analysis of microscopic kinetics is required for the correct interpretation of mutational effects in VAChT. Results also are discussed in terms of recently determined three-dimensional structures for other transporters in the major facilitator superfamily.