Julia M. Dolence scite author profile

Protein farnesyltransferase catalyzes the alkylation of cysteine in C-terminal CaaX sequences of a variety of proteins, including Ras, nuclear lamins, large G proteins, and phosphodiesterases, by farnesyl diphosphate (FPP). These modifications enhance the ability of the proteins to associate with membranes and are essential for their respective functions. The enzyme-catalyzed reaction was studied by using a series of substrate analogs for FPP to distinguish between electrophilic and nucleophilic mechanisms for prenyl transfer. FPP analogs containing hydrogen, fluoromethyl, and trifluoromethyl substituents in place of the methyl at carbon 3 were evaluated as alternative substrates for alkylation ofthe sulfhydryl moiety in the peptide dansyl-GCVIA. The analogs were alternative substrates for the prenylation reaction and were competitive inhibitors against FPP. A comparison of k,.t for FPP and the analogs with ksolv, the rate constants for solvolysis of related p-methoxybenzenesulfonate derivatives, indicated that protein prenylation occurred by an electrophilic mechanism.

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[4] Continuous fluorescence assay for protein prenyltransferases

Cassidy

Dolence

Poulter³

1995

100

115

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Cathepsin K Knockout Mitigates High-Fat Diet–Induced Cardiac Hypertrophy and Contractile Dysfunction

Hua

Zhang

Dolence

et al. 2013

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The cysteine protease cathepsin K has been implicated in pathogenesis of cardiovascular disease. We hypothesized that ablation of cathepsin K protects against obesity-associated cardiac dysfunction. Wild-type mice fed a high-fat diet exhibited elevated heart weight, enlarged cardiomyocytes, increased left ventricular wall thickness, and decreased fractional shortening. All these changes were reconciled in cathepsin K knockout mice. Cathepsin K knockout partly reversed the impaired cardiomyocyte contractility and dysregulated calcium handling associated with high-fat diet. Additionally, cathepsin K knockout alleviated whole-body glucose intolerance and improved insulin-stimulated Akt phosphorylation in high-fat diet–fed mice. High-fat feeding increased the expression of cardiac hypertrophic proteins and apoptotic markers, which were inhibited by cathepsin K knockout. Furthermore, high-fat feeding resulted in cathepsin K release from lysosomes into the cytoplasm. In H9c2 myoblasts, silencing of cathepsin K inhibited palmitic acid–induced release of cytochrome c from mitochondria and expression of proapoptotic signaling molecules. Collectively, our data indicate that cathepsin K contributes to the development of obesity-associated cardiac hypertrophy and may represent a potential target for the treatment to obesity-associated cardiac anomalies.

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A Stereoselective Palladium/Copper-Catalyzed Route to Isoprenoids: Synthesis and Biological Evaluation of 13-Methylidenefarnesyl Diphosphate

et al. 1995

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The novel farnesyl diphosphate (FPP) analog 13-methylidenefarnesyl diphosphate (3-VFPP, 4) was designed as a potential mechanism-based inhibitor of the FPP-utilizing enzyme protein-farnesyl transferase (PFTase). A six-step stereoselective route to 3-VFPP is described. The key step in the synthetic sequence involved the stereoselective coupling of vinyl triflate 16 with vinyltributyltin using Pd(AsPh3)2 and CUI as catalysts to afford primarily the desired (Z)-divinyl ester 15. It was also demonstrated that other 3-substituted farnesyl analogs can be prepared in a highly stereoselective manner by this Pd(O)/CuI-catalyzed route. The presence of CUI significantly increases the stereoselectivity of the coupling reaction, and a possible mechanistic rationale for this observation is presented. Biological evaluation of 3-VFPP demonstrates that it is not a time-dependent inhibitor of recombinant yeast PFTase. Instead, 3-VFPP is an alternative substrate for this enzyme that exhibits a K, comparable to FPP but a Kcat significantly lower than the natural substrate.

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Yeast protein farnesyltransferase: steady-state kinetic studies of substrate binding

et al. 1995

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Protein farnesyltransferase (PFTase) catalyzes the alkylation of cysteine in C-terminal CaaX sequences of a variety of proteins, including Ras, nuclear lamins, large G-proteins, and phosphodiesterases, by farnesyl diphosphate (FPP). These modifications enhance the ability of the proteins to associate with membranes and are essential for their respective functions. The binding mechanism for yeast PFTase was deduced from a combination of steady-state kinetic and equilibrium studies. Rates for prenylation were measured by a continuous assay based on an enhancement in the fluorescence of the dansyl moiety in pentapeptide dansyl-GCVIA upon farnesylation by FPP. Unreactive substrate analogs for FPP and dansyl-GCVIA gave steady-state inhibition patterns for the dead-end inhibitors typical of an ordered sequential mechanism in which FPP adds to the enzyme before the peptide. The kinetic analysis was complicated by substrate inhibition for dansyl-GCVIA. The substrate inhibition was reversed at high concentrations of FPP, indicating that formation of the nonproductive enzyme--peptide complex is competitive with respect to FPP. Progress curves were fitted to an integrated form of the rate expression to determine the catalytic constant, kcat = 4.5 +/- 1.9 s-1, and the Michaelis constant for dansyl-GCVIA, KMD = 0.9 +/- 0.1 microM. The dissociation constant for FPP, KD = 75 +/- 15 nM, was measured using a membrane retention assay.

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Julia M. Dolence

A mechanism for posttranslational modifications of proteins by yeast protein farnesyltransferase.

[4] Continuous fluorescence assay for protein prenyltransferases

Cathepsin K Knockout Mitigates High-Fat Diet–Induced Cardiac Hypertrophy and Contractile Dysfunction

A Stereoselective Palladium/Copper-Catalyzed Route to Isoprenoids: Synthesis and Biological Evaluation of 13-Methylidenefarnesyl Diphosphate

Yeast protein farnesyltransferase: steady-state kinetic studies of substrate binding

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