Sundari Ravindran scite author profile

To conserve carbohydrate reserves, the reaction of the pyruvate dehydrogenase complex (PDC) must be down-regulated when the citric acid cycle is provided sufficient acetyl-CoA. PDC activity is reduced primarily through increased phosphorylation of its pyruvate dehydrogenase (E1) component due to E1 kinase activity being markedly enhanced by elevated intramitochondrial NADH:NAD ؉ and acetyl-CoA:CoA ratios. A mechanism is evaluated in which enhanced kinase activity is facilitated by the build-up of the reduced and acetylated forms of the lipoyl moieties of the dihydrolipoyl acetyltransferase (E2) component through using NADH and acetyl-CoA in the reverse of the downstream reactions of the complex. Using a peptide substrate, kinase activity was stimulated by these products, ruling out the possibility kinase activity is increased due to changes in the reaction state of its substrate, E1 (thiamin pyrophosphate). Each E2 subunit contains two lipoyl domains, an NH 2 -terminal (L1) and the inward lipoyl domain (L2), which were individually produced in fully lipoylated forms by recombinant techniques. Although reduction and acetylation of the L1 domain or free lipoamide increased kinase activity, those modifications of the lipoate of the kinase-binding L2 domain gave much greater enhancements of kinase activity. The large stimulation of the kinase generated by acetyl-CoA only occurred upon addition of the transacetylase-catalyzing (lipoyl domain-free) inner core portion of E2 plus a reduced lipoate source, affirming that acetylation of this prosthetic group is an essential mechanistic step for acetyl-CoA enhancing kinase activity. Similarly, the lesser stimulation of kinase activity by just NADH required a lipoate source, supporting the need for lipoate reduction by E3 catalysis.Complete enzymatic delipoylation of PDC, the E2-kinase subcomplex, or recombinant L2 abolished the stimulatory effects of NADH and acetyl-CoA. Retention of a small portion of PDC lipoates lowered kinase activity but allowed stimulation of this residual kinase activity by these products. Reintroduction of lipoyl moieties, using lipoyl protein ligase, restored the capacity of the E2 core to support high kinase activity along with stimulation of that activity up to 3-fold by NADH and acetylCoA. As suggested by those results, the enhancement of kinase activity is very responsive to reductive acetylation with a half-maximal stimulation achieved with ϳ20% of free L2 acetylated and, from an analysis of previous results, with acetylation of only 3-6 of the 60 L2 domains in intact PDC. Based on these findings, we suggest that kinase stimulation results from modification of the lipoate of an L2 domain that becomes specifically engaged in binding the kinase. In conclusion, kinase activity is attenuated through a substantial range in response to modest changes in the proportion of oxidized, reduced, and acetylated lipoyl moieties of the L2 domain of E2 produced by fluctuations in the NADH: NAD ؉ and acetyl-CoA:CoA ratios as translated by the rapid and revers...

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Critical Role of a Lipoyl Cofactor of the Dihydrolipoyl Acetyltransferase in the Binding and Enhanced Function of the Pyruvate Dehydrogenase Kinase

Radke

Ôno

Ravindran

et al. 1993

Biochemical and Biophysical Research Communications

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Role of the E2 core in the dominant mechanisms of regulatory control of mammalian pyruvate dehydrogenase complex

Roche

Liu

Ravindran

et al. 1996

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Characterization of Empty Capsids from a Conditionally Replicating Adenovirus for Gene Therapy

Sutjipto¹,

Ravindran²,

Cornell³

et al. 2005

Human Gene Therapy

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As virus vectors for gene therapy approach the goal of successful clinical treatment, it is increasingly necessary for the product to be fully characterized. Empty capsids are perhaps the main extraneous component of recombinant adenovirus (rAd) products that are purified by column chromatography. Two diverse rAd products, one a replication-defective rAd and the other a conditionally replicating rAd, show different protein compositions of their empty capsids. The empty capsid type from the replication-defective rAd carrying the gene for p53 was previously determined to have approximately 1400 copies per particle of pVIII, the precursor to the hexon-associated protein VIII (Vellekamp et al., Hum. Gene Ther. 2001;12:1923-1936). Quantification of this protein is a useful measure of the amount of empty capsids in preparations of this vector. Here we purify and characterize empty capsids from the conditionally replicating rAd. This empty capsid type lacks any appreciable amount of pVIII but contains pVI and multiple forms of the L1 52/55K protein, mostly as disulfidelinked oligomers. Empty capsid from conditionally replicating rAd present new challenges in terms of its quantification, but sodium dodecyl sulfate-polyacrylamide gel electrophoresis densitometry analysis suggests that the amount of this empty capsid in a preparation, like that of rAd p53 empty capsid, declines with increased time of infection. This empty capsid demonstrates heterogeneity by anion-exchange chromatography, electron microscopy, and CsCl density gradient centrifugation.

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Reaction Mechanism for Mammalian Pyruvate Dehydrogenase Using Natural Lipoyl Domain Substrates

Liu

Gong

Yan

et al. 2001

Archives of Biochemistry and Biophysics

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