Assay of insulin mediator activity with soluble pyruvate dehydrogenase phosphatase.

The putative mediator of intracellular insulin action has been assayed quantitatively by its ability to increase the activity of solubilized pyruvate dehydrogenase (PDH) phosphatase. Conversion of soluble beef heart PDH b to PDH a by PDH phosphatase increased when incubation was carried out in the presence of a crude insulin mediator fraction generated from insulin-treated adipose tissue or liver plasma membranes. Increased PDH phosphatase activity was proportional to the concentration of added insulin mediator. Mediator generation was rapid, with a half-time of approximately 45 sec and was insulin dose dependent. Half-maximal mediator activity was produced at 0.3 nM added insulin, with maximal activity being generated at approximately 3 nM insulin. Mediator activity was significantly decreased at 7 nM insulin, but was increased 4-fold after ethanol extraction. Mediator behaved as an activator of PDH phosphatase, apparently by abolishing the inhibitory effects of ATP on phosphatase activity, but had no effect on PDH kinase activity. The assay of insulin mediator activity described here can be carried out under standardized conditions, in contrast to previously described methods using particulate mitochondrial preparations.

Sub-mitochondrial localization of the catalytic subunit of pyruvate dehydrogenase phosphatase.

Using a specific antibody against the PDP catalytic subunit, PDPc, precise localization of this subunit in mitochondria was performed. Sub-fractionation of purified mitochondria by controlled swelling processes led to the isolation of outer membranes, matrix space and inner membrane vesicles which were purified on a sucrose density gradient. In this study, we demonstrated that PDPc was not recovered as a soluble protein in the matrix space but was associated with the inner membrane. Moreover, Triton X-114 phase partitioning performed on inner membranes showed that PDPc behaved both as a hydrophilic and as a hydrophobic protein, thus suggesting two different forms of this enzyme.

32P labeling of protein phosphorylation and metabolite association in the mitochondria matrix.

Protein phosphorylations, as well as phosphate metabolite binding, are well characterized post-translational mechanisms that regulate enzyme activity in the cytosol, but remain poorly defined in mitochondria. Recently extensive matrix protein phosphorylation sites have been discovered but their functional significance is unclear. Herein we describe methods of using (32)P labeling of intact mitochondria to determine the dynamic pools of protein phosphorylation as well as phosphate metabolite association. This screening approach may be useful in not only characterizing the dynamics of these pools, but also provide insight into which phosphorylation sites have a functional significance. Using the mitochondrial ATP synthetic capacity under appropriate conditions, inorganic (32)P was added to energized mitochondria to generate high specific activity gamma-P(32)-ATP in the matrix. In general, SDS denaturing and gel electrophoresis was used to primarily follow protein phosphorylation, whereas native gel techniques were used to observe weaker metabolite associations since the structure of mitochondrial complexes was minimally affected. The protein phosphorylation and metabolite association within the matrix was found to be extensive using these approaches. (32)P labeling in 2D gels was detected in over 40 proteins, including most of the complexes of the cytochrome chain and proteins associated with intermediary metabolism, biosynthetic pathways, membrane transport, and reactive oxygen species metabolism. (32)P pulse-chase experiments further revealed the overall dynamics of these processes that included phosphorylation site turnover as well as phosphate-protein pool size alterations. The high sensitivity of (32)P resulted in many proteins being intensely labeled, but not identified due to the sensitivity limitations of mass spectrometry. These low concentration proteins may represent signaling proteins within the matrix. These results demonstrate that the mitochondrial matrix phosphoproteome is both extensive and dynamic. The use of this, in situ, labeling approach is extremely valuable in confirming protein phosphorylation sites as well as examining the dynamics of these processes under near physiological conditions.

The neurohormone orexin stimulates hypoxia-inducible factor-1 activity.

Orexin A and Orexin B (also known as hypocretins) are neuropeptides that bind two related G-coupled protein receptors (OXR1 and OXR2) and thus induce wakefulness, food consumption, and locomotion. Conversely, deletion of the orexin gene in mice produces a condition similar to canine and human narcolepsy. Despite the central importance of the orexin system in regulating wakefulness and feeding behavior, little is known about the downstream signaling mechanisms that achieve these effects. In this study, genomics techniques are used to probe this question and reveal that orexin activates the hypoxia-inducible factor 1 (HIF-1), a heterodimeric transcription factor whose pathogenic role in stimulating angiogenesis in hypoxic tumors has been the focus of intense investigation. Orexin-stimulated HIF-1 activity is due to both increased HIF-1alpha gene transcription and a down-regulation of von Hippel-Lindau (VHL), the E3 ubiquitin ligase that mediates the turnover of HIF-1 via the ubiquitin-proteasome pathway. Orexin-mediated activation of HIF-1 results in increased glucose uptake and higher glycolytic activity, as expected from studies of hypoxic cells. However, orexin receptor-expressing cells somehow override the HIF-1-mediated preference for funneling pyruvate into anaerobic glycolysis and instead favor ATP production through the tricarboxylic acid cycle and oxidative phosphorylation. These findings implicate HIF-1 as an important transcription factor in the hormone-mediated regulation of hunger and wakefulness.

Synthetic peptide substrates for mammalian pyruvate dehydrogenase kinase and pyruvate dehydrogenase phosphatase.

The specificities of pyruvate dehydrogenase kinase and pyruvate dehydrogenase phosphatase were probed using synthetic peptides corresponding to the sequence around phosphorylation sites 1 and 2 on pyruvate dehydrogenase [Tyr-His-Gly-His-Ser(P1)-Met-Ser-Asp-Pro-Gly-Val-Ser(P2)-Tyr-Arg]. The dephosphotetradecapeptide containing aspartic acid at position 8 was a better substrate for the kinase than was the tetradecapeptide containing asparagine at position 8. The apparent Km and V values for the two peptides were 0.43 and 6.1 mM and 2.7 and 2.4 nmol of 32P incorporated/min/mg, respectively. Methylation of the aspartic acid residue also increased the apparent Km of the tetradecapeptide about 14-fold. These results indicate that an acidic residue on the carboxyl-terminal side of phosphorylation site 1 is an important specificity determinant for the kinase. Phosphate was incorporated only into site 1 of the synthetic peptide by the kinase. The phosphatase exhibited an apparent Km of 0.28 mM and a V of 2.3 mumol of 32P released/min/mg for the phosphorylated tetradecapeptide containing aspartic acid. Methylation of the aspartic acid residue had no significant effect on dephosphorylation. The octapeptide and phosphooctapeptide produced by cleavage of the aspartyl-prolyl bond by formic acid were poorer substrates for the kinase and phosphatase than were the tetradecapeptide and phosphotetradecapeptide, respectively. Modification of the amino terminal by acetylation or lysine addition had only a slight effect on the kinase and phosphatase activities.

Rat liver insulin mediator which stimulates pyruvate dehydrogenase phosphate contains galactosamine and D-chiroinositol.

It has been established that insulin treatment of cells, isolated plasma membranes, or whole animals leads to the generation of low molecular weight mediators which serve as intermediates in the signalling pathway. At least two distinct classes of mediator have been described, based on differences in apparent molecular weight, isoelectric point and biological activity (Cheng, K., and Larner, J. (1985) Ann. Rev. Physiol. 45, 407-424). Recently, Saltiel's (Saltiel, A.R., and Cuatrecasas, P. (1986) Proc. Natl. Acad. Sci. U.S.A. 83, 5793-5797) and Mato's (Mato, J.M., Kelly, K.L., Abler, A., and Jarett, L. (1987) J. Biol. Chem. 262, 2131-2137) laboratories have described an insulin "modulator" which was apparently derived from glycosylphosphoinositol linker, similar to those known to anchor proteins to the external surface of the cell membrane (Low, M.G. (1987) Bioch. J. 244, 1-13). In this paper, we report that highly purified preparations of the insulin mediator which stimulates pyruvate dehydrogenase phosphatase contain mannose, galactosamine, and D-chiroinositol. These determinations are based upon analyses using paper chromatography and gas chromatography/mass spectroscopy. Nitrous acid deamination of the mediator resulted in release of inositol phosphate, indicating that the galactosamine and D-chiroinositol are linked. Although the presence of chiroinositol in modulator from H35 hepatoma cells has been recently reported (Mato, J.M., Kelly, K.L., Abler, A., Jarett, L., Corkey, B.E., Cashel, J.A., and Zopf, D. (1987) Bioch. Biophys. Res. Comm. 146, 764-770), the optical identity of the inositol remained unknown until the present report. Likewise, the presence of galactosamine rather than glucosamine in insulin mediator is a novel finding. These findings, coupled with those of Saltiel and Mato's groups, provide clear evidence for the existence of multiple forms of insulin mediators. Additionally, the results presented here afford further confirmation for the formation of insulin mediators from glycosyl-phosphoinositol linkers.