Browsing by Subject "Point Mutation"
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- ItemOpen AccessA Point Mutation in the Juxtamembrane Stalk of Human Angiotensin I-converting Enzyme Invokes the Action of a Distinct Secretase(2001) Alfalah, Marwan; Parkin, Edward T; Jacob, Ralf; Sturrock, Edward D; Mentele, Reinhard; Turner, Anthony J; HOOPER, Nigel M; Naim, Hassan YAngiotensin I-converting enzyme (ACE) is one of a number of integral membrane proteins that is proteolytically shed from the cell surface by a zinc metallosecretase. Mutagenesis of Asn(631) to Gln in the juxtamembrane stalk region of ACE resulted in more efficient secretion of the mutant protein (ACE(NQ)) as determined by pulse-chase analysis. In contrast to the wild-type ACE, the cleavage of ACE(NQ) was not blocked by the metallosecretase inhibitor batimastat but by the serine protease inhibitor, 1,3-dichloroisocoumarin. Incubation of the cells at 15 degrees C revealed that ACE(NQ) was cleaved in the endoplasmic reticulum, and mass spectrometric analysis of the secreted form of the protein indicated that it had been cleaved at the Asn(635)-Ser(636) bond, three residues N-terminal to the normal secretase cleavage site at Arg(638)-Ser(639). These data clearly show that a point mutation in the juxtamembrane region of an integral membrane protein can invoke the action of a mechanistically and spatially distinct secretase. In light of this observation, previous data on the effect of mutations in the juxtamembrane stalk of shed proteins being accommodated by a single secretase having a relaxed specificity need to be re-evaluated.
- ItemOpen AccessAsparagine 706 and Glutamate 183 at the Catalytic Site of Sarcoplasmic Reticulum Ca 2+ -ATPase Play Critical but Distinct Roles in E 2 States(2006) Clausen, Johannes D; McIntosh, David B; Woolley, David G; Anthonisen, Anne Nyholm; Vilsen, Bente; Andersen, Jens PeterMutants with alteration to Asn(706) of the highly conserved (701)TGDGVND(707) motif in domain P of sarcoplasmic reticulum Ca(2+)-ATPase were analyzed for changes in transport cycle kinetics and binding of the inhibitors vanadate, BeF, AlF, and MgF. The fluorides likely mimic the phosphoryl group/P(i) in the respective ground, transition, and product states of phosphoenzyme hydrolysis (Danko, S., Yamasaki, K., Daiho, T., and Suzuki, H. (2004) J. Biol. Chem. 279, 14991-14998). Binding of BeF, AlF, and MgF was also studied for mutant Glu(183) --> Ala, where the glutamate of the (181)TGES(184) motif in domain A is replaced. Mutations of Asn(706) and Glu(183) have in common that they dramatically impede the function of the enzyme in E2 states, but have little effect in E1. Contrary to the Glu(183) mutant, in which E2P slowly accumulates (Clausen, J. D., Vilsen, B., McIntosh, D. B., Einholm, A. P., and Andersen, J. P. (2004) Proc. Natl. Acad. Sci. U. S. A. 101, 2776-2781), E2P formation was not detectable with the Asn(706) mutants. Differential sensitivities of the mutants to inhibition by AlF, MgF, and BeF made it possible to distinguish different roles of Asn(706) and Glu(183). Hence, Asn(706) is less important than Glu(183) for gaining the transition state during E2P hydrolysis but plays critical roles in stabilization of E2P ground and E2.P(i) product states and in the major conformational changes associated with the Ca(2)E1P --> E2P and E2 --> Ca(2)E1 transitions, which seem to be facilitated by interaction of Asn(706) with domain A.
- ItemOpen AccessThe functional significance of the G to A point mutation in the promoter region of the Apolipoprotein AI gene(1993) Wells, Carol Dawn; Jeenah, MohammedAG to A transition at position -76 in the promoter region of the apoAI gene was previously identified, and the A-76 has been shown to be associated with high apoAI levels. The functional significance of the point mutation was assessed by analysing the DNA-protein binding and promoter activities of the different alleles. This data would suggest that the point mutation alters the function of the apoAI promoter as gel retention assays revealed that the G fragment (-140 to +10) formed an extra DNA-protein complex compared to the A fragment (-140 to +10). Concurrent with the altered DNA-protein interaction between the G and the A fragments, the transcriptional activities of the apoAI gene were found to also be altered. CAT assays have indicated a 1.91 fold increase in promoter activity of the A fragment as compared to the G fragment (-256 to +397). The difference in promoter activity was, however, highly dependent on the particular fragment used, as no difference was observed between the alleles when a fragment {-256 to +68) was used. In this study elements were identified in the region +68 to +397 that causes a reduction in the promoter activity of the G allele by 3.6 fold, whilst reducing the A allele activity by 2 fold. This data would suggest that the point mutation functionally alters the apoAI promoter activity via its interaction with other sequences especially in the region +68 to +397.