guanosine-triphosphate and lauric-acid

Mutants were constructed for mitochondrial uncoupling protein UCP1, with single or multiple substitutions within or nearby the UCP-signatures located in the first alpha-helix and second matrix-segment, using the QuickChange site directed mutagenesis protocol (Stratagene), and were assayed fluorometrically for kinetics of fatty acid (FA)-induced H+ uniport and for Cl- uniport. Their ability to bind 3H-GTP was also evaluated. The wild type UCP1 was associated with the FA-induced H+ uniport proportional to the added protein with a Km for lauric acid of 43 micro M and Vmax of 18 micro molmin(-1)(mg protein)(-1). Neutralization of Arg152 (in the second matrix-segment UCP-signature) led to approximately 50% reduction of FA affinity (reciprocal Km) and of Vmax for FA-induced H+ uniport. Halved FA affinity and 70% reduction of Vmax was found for the double His substitution outside the signature (H145L and H147L mutant). Neutralization of Asp27 in the first alpha-helix UCP-signature (D27V mutant) resulted in 75% reduction of FA affinity and approximately 50% reduction of Vmax, whereas the triple C24A and D27V and T30A mutant was fully non-functional (Vmax reduced by 90%). Interestingly, the T30A mutant exhibited only the approximately 50% reduced FA affinity but not Vmax. Cl- uniport and 3H-GTP binding were preserved in all studied mutants. We conclude that amino acid residues of the first alpha-helix UCP signature may be required to hold the intact UCP1 transport conformation. This could be valid also for the positive charge of Arg152 (second matrix-segment UCP signature), which may alternatively mediate FA interaction with the native protein.

Topics: Amino Acid Substitution; Animals; Carrier Proteins; Chlorides; Fatty Acids; Guanosine Triphosphate; Hydrogen; Ion Channels; Ion Transport; Kinetics; Lauric Acids; Liposomes; Membrane Proteins; Mitochondria; Mitochondrial Proteins; Mutagenesis, Site-Directed; Rats; Saccharomyces cerevisiae; Saccharomyces cerevisiae Proteins; Structure-Activity Relationship; Uncoupling Protein 1

UCP2 (the lowest Km values: 20 and 29 microm, respectively) for omega-6 polyunsaturated FAs (PUFAs), all-cis-8,11,14-eicosatrienoic and all-cis-6,9,12-octadecatrienoic acids, which are also the most potent agonists of the nuclear PPARbeta receptor in the activation of UCP2 transcription. omega-3 PUFA, cis-5,8,11,14,17-eicosapentaenoic acid had lower affinity (Km, 50 microm), although as an omega-6 PUFA, arachidonic acid exhibited the same low affinity as lauric acid (Km, approximately 200 microm). These findings suggest a possible dual role of some PUFAs in activating both UCPn expression and uncoupling activity. UCP2 (UCP3)-dependent H+ translocation activated by all tested FAs was inhibited by purine nucleotides with apparent affinity to UCP2 (reciprocal Ki) decreasing in order: ADP > ATP approximately GTP > GDP >> AMP. Also [3H]GTP ([3H]ATP) binding to isolated Escherichia coli (Kd, approximately 5 microm) or yeast-expressed UCP2 (Kd, approximately 1.5 microm) or UCP3 exhibited high affinity, similar to UCP1. The estimated number of [3H]GTP high affinity (Kd, <0.4 microm) binding sites was (in pmol/mg of protein) 182 in lung mitochondria, 74 in kidney, 28 in skeletal muscle, and approximately 20 in liver mitochondria. We conclude that purine nucleotides must be the physiological inhibitors of UCPn-mediated uncoupling in vivo.

Topics: Adenosine Triphosphate; Biological Transport; Carrier Proteins; Coenzymes; Fatty Acids, Omega-6; Fatty Acids, Unsaturated; Guanosine Triphosphate; Humans; Ion Channels; Kinetics; Lauric Acids; Ligands; Liposomes; Membrane Transport Proteins; Mitochondria; Mitochondrial Proteins; Proteins; Protons; Tritium; Ubiquinone; Uncoupling Protein 2; Uncoupling Protein 3; Yeasts

The functional role of the four intrahelical arginines in uncoupling protein (UCP1) from brown adipose tissue were studied in mutants where they were replaced by noncharged residues. Wild-type and mutant UCP1 were expressed in Saccharomyces cerevisiae. As measured in isolated UCP1, nucleotide binding was largely lost in mutants of R83, R182, and R276 occurring in three repeated domains and common to mitochondrial carrier family, whereas mutation of the UCP typical R91 shows normal binding capacity but > 20-fold lower binding affinity and a near loss of pH dependency of binding. In reconstituted UCP1, fatty acid dependent H(+) transport is retained in all four mutants, but inhibition by nucleotide changes according to the binding ability of UCP1. Cl(-) transport is inhibited only by mutations of arginines in the first domain (R83 and R91). Also in isolated mitochondria H(+) transport and respiration with all four mutants is similar to wt, and inhibition by GDP is found only in R91T. The three "regular" arginines are suggested to influence the nucleotide binding site indirectly via a charge network and the "extra" R91 directly via an ion bond with the previously characterised pH sensor E190. The mutants were also used to assess intrahelical control of UCP1. In the yeast cells expressing UCP1, the aerobic growth could be reduced by fatty acid addition only with the nucleotide insensitive mutants. This demonstrates an intracellular control of UCP1 by nucleotides and fatty acids.

Topics: Animals; Arginine; Binding Sites; Biological Transport, Active; Carbon Radioisotopes; Carrier Proteins; Chloride Channels; Cricetinae; Genetic Vectors; Guanosine Triphosphate; Intracellular Fluid; Intracellular Membranes; Ion Channels; Lauric Acids; Membrane Proteins; Mitochondria; Mitochondrial Proteins; Mutagenesis, Site-Directed; Permeability; Protein Structure, Secondary; Protons; Saccharomyces cerevisiae; Uncoupling Agents; Uncoupling Protein 1

The transport inhibiting nucleotide binding to the uncoupling protein (UCP) has a unique pH dependence and has been postulated to be controlled by the dissociation state of a carboxyl group in UCP with pK 4.5 and, in addition only for the nucleoside triphosphate, by a group with pK 7.2. To prove this assumption and to identify the carboxyl group, Woodward reagent K (WRK) was applied to UCP. In mitochondria, WRK was found to inhibit binding of GTP in a noncompetitive manner using WRK in the millimolar range. In isolated UCP, GTP binding is inhibited by WRK at a 1 to 2 ratio to UCP, suggesting that WRK primarily reacts with only one carboxyl group. Prebound GTP protects against WRK reaction as monitored by GTP binding. The protection decreases from pH 5 to 7 due to better reactivity of WRK and less tight GTP binding. WRK does not inhibit H+ transport by UCP but prevents GTP inhibition of H+ transport. For elucidating the WRK target residue, the WRK derivatized group was labeled with [3H] by reduction with [3H]NaBH4. Both GTP and GDP largely protected against WRK-dependent [3H] labeling. CNBr fragmentation identified the region T121-M197 as the [3H] incorporation site. Combined CNBr and tryptophane cleavage by the reagent 3-bromo-3-methyl-2-((2-nitrophenyl) thio)-3H-indole (BNPS) allowed to further delimit the 2.8 kDa peptide W173-M197 as the [3H] label carrier which contains two acid residues E190 and D195. To further identify the residue, limited tryptic digestion in sarcosyl-treated UCP was performed, and a tryptic fragment enclosing E190 and D195 was isolated which carried most of the [3H] label. Edman degradation showed the major [3H] label at the eighth position corresponding to E190 and no peak at D195. Thus, the original postulate of the pH-sensing carboxyl group regulating both the nucleoside di- and triphosphate binding has been verified. It is identified as E190 situated in the fourth transmembrane helix. In total, now four residues close to the nucleotide binding sites in UCP have been determined.

Topics: Adipose Tissue, Brown; Amino Acid Sequence; Animals; Borohydrides; Carrier Proteins; Cricetinae; Cyanogen Bromide; Electrophoresis, Polyacrylamide Gel; Guanosine Triphosphate; Hydrogen-Ion Concentration; Indoles; Ion Channels; Isoxazoles; Lauric Acids; Membrane Proteins; Mitochondrial Proteins; Molecular Sequence Data; Nucleotides; Peptide Fragments; Protons; Sequence Analysis; Trypsin; Uncoupling Protein 1