Identification of an uncoupling mutation affecting the b subunit of F1F0 ATP synthase in Escherichia coli.

A specific b subunit arginine, b(Arg-36) in Escherichia coli, displays evolutionary conservation among bacterial F1F0 ATP synthases. Site-directed mutagenesis was used to generate a collection of mutations affecting b(Arg-36). The phenotype differed depending upon the substitution, and the b(Arg-36-Glu) and b(Arg-36-Ile) substitutions virtually abolished enzyme function. Although the total amounts of F1F0 ATP synthase present in the membranes prepared from mutant strains were reduced, the primary effect of the b(Arg-36) substitutions was on the activities of the intact enzyme complexes. The most interesting result was that the b(Arg-36-Glu) substitution results in the uncoupling of a functional F0 from F1 ATP hydrolysis activity.

Molecular identification of the renal H+,K+-ATPases.

The pharmacological properties of H+,K+-ATPase activity described in the kidney were not necessarily consistent with the properties of the well-characterized gastric H+,K+-ATPase. Recent molecular biology experiments suggest that renal H+,K+-ATPase activity may be the product of several closely related P-type ATPases. At least 3 different pumps containing the HKalpha1, HKalpha2a, and HKalpha2c subunits have been detected in rabbit kidney. The current view is that these HKalpha subunits arose through gene duplication early in evolution and the proteins evolved their differing activities over time. The HKbeta protein associates with HKalpha1 in gastric tissues and is the likely mate for the HKalpha1 subunit in renal tissues. Three distinct beta subunits have been implicated as possible partners for the HKalpha2 subunits, but it remains to be determined which beta subunit predominantly associates with the HKalpha2 subunits in vivo. Sequence analysis suggests the beta subunit was constrained by size and shape of the protein rather than specific amino acid content during the course of evolution. Multiple H+,K+-ATPases in the kidney may be an important adaptation providing redundancy for the essential physiological function of maintaining ionic balance.

Deletions in the second stalk of F1F0-ATP synthase in Escherichia coli.

In Escherichia coli F1F0-ATP synthase, the two b subunits form the second stalk spanning the distance between the membrane F0 sector and the bulk of F1. Current models predict that the stator should be relatively rigid and engaged in contact with F1 at fixed points. To test this hypothesis, we constructed a series of deletion mutations in the uncF(b) gene to remove segments from the middle of the second stalk of the subunit. Mutants with deletions of 7 amino acids were essentially normal, and those with deletions of up to 11 amino acids retained considerable activity. Membranes prepared from these strains had readily detectable levels of F1-ATPase activity and proton pumping activity. Removal of 12 or more amino acids resulted in loss of oxidative phosphorylation. Levels of membrane-associated F1-ATPase dropped precipitously for the longer deletions, and immunoblot analysis indicated that reductions in activity correlated with reduced levels of b subunit in the membranes. Assuming the likely alpha-helical conformation for this area of the b subunit, the 11-amino acid deletion would result in shortening the subunit by approximately 16 A. Since these deletions did not prevent the b subunit from participating in productive interactions with F1, we suggest that the b subunit is not a rigid rodlike structure, but has an inherent flexibility compatible with a dynamic role in coupling.

Self-assembly of the brain MAP-2 microtubule-binding region into polymeric structures resembling Alzheimer filaments.

The neuronal microtubule-associated protein known as MAP-2 has not been considered to be a subunit of paired helical filaments (PHFs) in neurofibrillary tangles seen in Alzheimer's Disease. We now describe the assembly of paired helical filament-like structures from MAP-2's 203-residue microtubule-binding region (MTBR). SDS gel electrophoresis and equilibrium ultracentrifugation suggest that a dimeric form, cross-linked by an interchain disulfide, is involved in polymerization. MAP-2 MTBR polymers bind thioflavin-S, a dye used to histochemically localize Alzheimer neurofibrillary tangles. Our finding that PHF-like structures assemble from a MAP-2 fragment raises new questions about MAP-2's role in the etiology of Alzheimer's Disease.