Occupancy of phosphorylation sites in pyruvate dehydrogenase phosphate complex in rat heart in vivo. Relation to proportion of inactive complex and rate of re-activation by phosphatase.

The [gamma-32P]ATP-back-titration method of estimating occupancy in vivo of the three phosphorylation sites in the pyruvate dehydrogenase complex was improved in precision by specific analysis with trypsin/formic acid, by more effective prevention of site-2 dephosphorylation during purification with NaF, and by other refinements. Disproportionation of phosphorylated complexes during purification was excluded. With this improved method it was shown that the relationship between occupancy of sites and the proportion of complex in the inactive form in rat heart in vivo is closely similar to that measured directly in heart mitochondria by incorporation of [32P]Pi. In the heart in vivo (as in mitochondria), occupancy of site 1 correlated linearly with the proportion of inactive complex. Occupancy of sites 2 and 3 only approached equivalence to that of site 1 when 99% of the complex was inactive (starved or diabetic rats). When 70% or less of the complex was inactive (resting or exercising fed normal rats), occupancy of sites 2 and 3 was minimal (3 less than 2) relative to site 1. The initial rate of re-activation by phosphatase of phosphorylated complex from hearts of resting or exercising fed normal rats was approximately three times that of complex from 48 h-starved rats.     

Conversion of inactive (phosphorylated) pyruvate dehydrogenase complex into active complex by the phosphate reaction in heart mitochondria is inhibited by alloxan-diabetes or starvation in the rat.

1. The conversion of inactive (phosphorylated) pyruvate dehydrogenase complex into active (dephosphorylated) complex by pyruvate dehydrogenase phosphate phosphatase is inhibited in heart mitochondria prepared from alloxan-diabetic or 48h-starved rats, in mitochondria prepared from acetate-perfused rat hearts and in mitochondria prepared from normal rat hearts incubated with respiratory substrates for 6 min (as compared with 1 min). 2. This conclusion is based on experiments with isolated intact mitochondria in which the pyruvate dehydrogenase kinase reaction was inhibited by pyruvate or ATP depletion (by using oligomycin and carbonyl cyanide m-chlorophenylhydrazone), and in experiments in which the rate of conversion of inactive complex into active complex by the phosphatase was measured in extracts of mitochondria. The inhibition of the phosphatase reaction was seen with constant concentrations of Ca2+ and Mg2+ (activators of the phosphatase). The phosphatase reaction in these mitochondrial extracts was not inhibited when an excess of exogenous pig heart pyruvate dehydrogenase phosphate was used as substrate. It is concluded that this inhibition is due to some factor(s) associated with the substrate (pyruvate dehydrogenase phosphate complex) and not to inhibition of the phosphatase as such. 3. This conclusion was verified by isolating pyruvate dehydrogenase phosphate complex, free of phosphatase, from hearts of control and diabetic rats an from heart mitochondria incubed for 1min (control) or 6min with respiratory substrates. The rates of re-activation of the inactive complexes were then measured with preparations of ox heart or rat heart phosphatase. The rates were lower (relative to controls) with inactive complex from hearts of diabetic rats or from heart mitochondria incubated for 6min with respiratory substrates. 4. The incorporation of 32Pi into inactive complex took 6min to complete in rat heart mitocondria. The extent of incorporation was consistent with three or four sites of phosphorylation in rat heart pyruvate dehydrogenase complex. 5. It is suggested that phosphorylation of sites additional to an inactivating site may inhibit the conversion of inactive complex into active complex by the phosphatase in heart mitochondria from alloxan-diabetic or 48h-starved rats or in mitochondria incubated for 6min with respiratory substrates.     

Inhibition of lactate glucogneogenesis in rat kidney by dichloroacetate.

1. Sodium dichloroacetate (1mM) inhibited glucose production from L-lactate in kidney-cortex slices from fed, starved or alloxan-diabetic rates. In general gluconeogenesis from other substrates was no inhibited. 2. Sodium dichloracetate inhibited glucose production from L-lactate but no from pyruvate in perfused isolated kidneys from normal or alloxan-diabetic rats. 3. Sodium dichloroacetate is an inhibitor of the pyruvate dehydrogenase kinase reaction and it effected conversion of pyruvate dehydrogenase into its its active (dephosphorylated) form in kidney in vivo. In general, pyruvate dehydrogenase was mainly in the active form in kidneys perfused or incubated with L-lactate and the inhibitory effect of dichloroacetate on glucose production was not dependent on activation of pyruvate dehydrogenase. 4. Balance data from kidney slices showed that dichloroacetate inhibits lactate uptake, glucose and pyruvate production from lactate, but no oxidation of lactate. 5. The mechanism of this effect of dichloroactetate on glucose production from lactate has not been fully defined, but evidence suggests that it may involve a fall in tissue pyruvate concentration and inhibition of pyruvate carboxylation.     

Phosphorylation state of cytosolic and mitochondrial adenine nucleotides and of pyruvate dehydrogenase in isolated rat liver cells.

1. Cytosolic and mitochondrial ATP and ADP concentrations of liver cells isolated from normal fed, starved and diabetic rats were determined. 2. The cytosolic ATP/ADP ratio was 6,9 and 10 in normal fed, starved and diabetic rats respectively. 3. The mitochondrial ATP/ADP ratio was 2 in normal and diabetic rats and 1.6 in starved rats. 4. Adenosine increased the cytosolic and lowered the mitochondrial ATP/ADP ratio, whereas atractyloside had the opposite effect. 5. Incubation of the hepatocytes with fructose, glycerol or sorbitol led to a fall in the ATP/ADP ratio in both the cytosolic and the mitochondrial compartment. 6. The interrelationship between the mitochondrial ATP/ADP ratio and the phosphorylation state of pyruvate dehydrogenase in intact cells was studied. 7. In hepatocytes isolated from fed rats an inverse correlation between the mitochondrial ATP/ADP ratio and the active form of pyruvate dehydrogenase (pyruvate dehydrogenase a) was demonstrable on loading with fructose, glycerol or sorbitol. 8. No such correlation was obtained with pyruvate or dihydroxyacetone. For pyruvate, this can be explained by inhibition of pyruvate dehydrogenase kinase. 9. Liver cells isolated from fed animals displayed pyruvate dehydrogenase a activity twice that found in vivo. Physiological values were obtained when the hepatocytes were incubated with albumin-oleate, which also yielded the highest mitochondrial ATP/ADP ratio.     

Effect of valine on the control of fatty acid synthesis in white adipose tissue of the rat.

In adipocytes from fed rats, the rate of fatty acid synthesis in the presence of glucose and insulin was inhibited 40% by valine (5 mm). tthis inhibition was largely abolished by the addition to the incubation medium of the transaminase inhibitor aminooxy acetate, and of pyruvate and agents which raise the intracellular pyruvate levels such as N,N,N1,N1-tetramethyl-p-phenylenediamine. Pyruvate output into the incubation medium from fat pads obtained from fed rats and incubated with glucose and insulin was decreased significantly by the addition of valine. When adipocytes were incubated under similar conditions, the final concentration of pyruvate in the incubation medium was 42 +/- 1.6 muM under control conditions and approximately one third of this value in the presence of 2.5 mM valine. Valine had no significant effect on pyruvate dehydrogenase (lipoate) (EC 1.2.4.1) activity when assayed in homogenates prepared from adipose tissue previously incubated for 60 min with the amino acid. Although the ketoacid analogue of valine alpha-ketoisovaleric acid, is a competitive inhibitor of pyruvate dehydrogenase (lipoate) (K1 = 1.4 mM), this cannot solely account for the valine-induced reduced rate of lipogenesis. Rather, the mechanism involves a reduction in pyruvate concentration and thereby a diminished flow through pyruvate dehydrogenase (lipoate). Details of the possible mechanism are discussed.     

Mitochondrial 2-oxoacid dehydrogenase complexes of animal tissues

The pyruvate dehydrogenase and branched-chain 2-oxoacid dehydrogenase complexes of animal mitochondria are inactivated by phosphorylation of serine residues, and reactivated by dephosphorylation. In addition, phosphorylated branched-chain complex is reactivated, apparently without dephosphorylation, by a protein or protein-associated factor present in liver and kidney mitochondria but not in heart or skeletal muscle mitochondria. Interconversion of the branched-chain complex may adjust the degradation of branched-chain amino acids in different tissues in response to supply. Phosphorylation is inhibited by branched-chain ketoacids, ADP and TPP. The pyruvate dehydrogenase complex is almost totally inactivated (99%) by starvation or diabetes, the kinase reactions being accelerated by products of fatty acid oxidation and by a protein or protein-associated factor induced by starvation or diabetes. There are three sites of phosphorylation, but only sites 1 and 2 are inactivating. Site 1 phosphorylation accounts for 98% of inactivation except during dephosphorylation when its contribution falls to 93%. Sites 2 and 3 are only fully phosphorylated when the complex is fully inactivated (starvation, diabetes). Phosphorylation of sites 2 and 3 inhibits reactivation by phosphatase. The phosphatase reaction is activated by Ca2+ (which may mediate effects of muscle work) and possibly by uncharacterized factors mediating insulin action in adipocytes.     

Differential effects of two mutations at arginine-234 in the alpha subunit of human pyruvate dehydrogenase.

The most common mutation in the alpha subunit of the pyruvate dehydrogenase (E1) component of the human pyruvate dehydrogenase complex (PDC) is arginine-234 to glycine and glutamine in 12 and 3 patients, respectively. Interestingly, these two mutations at the same amino acid position cause E1 (and hence PDC) deficiency by apparently different mechanisms. Recombinant human R234Q E1 had similar V(max) (25.7 +/- 4.4 units/mg E1) and apparent K(m) (101 +/- 4 nM) values for TPP as recombinant wild-type human E1, while R234G E1 had no significant change in V(max) (33.6 +/- 4.7 units/mg E1) but had a 7-fold increase in its apparent K(m) value for TPP (497 +/- 25 nM). Both of the R234 mutant proteins had similar apparent K(m) values for pyruvate. Both R234Q and R234G mutant proteins displayed similar phosphorylation rates of sites 1 and 2 by pyruvate dehydrogenase kinase 2 (PDK2) and site 3 by PDK1 compared to wild-type E1. Phosphorylated R234Q E1, R234G E1, and wild-type E1 also had similar dephosphorylation rates of sites 1 and 2 by phosphopyruvate dehydrogenase phosphatase 1. The rate of dephosphorylation of site 3 was about 50% for R234Q E1 and without a significant change for R234G E1 compared to the wild type. The data indicate that the patients with the R234G E1 mutation are symptomatic due to a decreased ability of this mutant protein to bind TPP, whereas the patients with the R234Q E1 mutation are symptomatic due to a decreased rate of dephosphorylation of site 3, hence keeping the enzyme in a phosphorylated/inactivated form.     

Function of phosphorylation sites on pyruvate dehydrogenase.

Evidence is presented that dephosphorylation of the three phosphorylation sites on bovine kidney pyruvate dehydrogenase by pyruvate dehydrogenase phosphatase is random. The relative rates of dephosphorylation were in the order site 2 > site 3 > site 1. Phosphorylation site 2, and possibly site 3, function, in addition to site 1, as inactivating sites. However, the presence of phosphoryl groups at sites 2 and 3 did not significantly affect the rate of dephosphorylation at site 1 or the rate of reactivation of the enzyme by the phosphatase. The rate-limiting step in the reactivation of phosphorylated pyruvate dehydrogenase is apparently the dephosphorylation at site 1.     

Effects of Ca2+ and Mg2+ on the activity of pyruvate dehydrogenase phosphate phosphatase within toluene-permeabilized mitochondria.

Mitochondria from rat epididymal white adipose tissue were made permeable to small molecules by toluene treatment and were used to investigate the effects of Mg2+ and Ca2+ on the re-activation of pyruvate dehydrogenase phosphate by endogenous phosphatase. Re-activation of fully phosphorylated enzyme after addition of 0.18 mM-Mg2+ showed a marked lag of 5-10 min before a maximum rate of reactivation was achieved. Increasing the Mg2+ concentration to 1.8 mM (near saturating) or the addition of 100 microM-Ca2+ resulted in loss of the lag phase, which was also greatly diminished if pyruvate dehydrogenase was not fully phosphorylated. It is concluded that, within intact mitochondria, phosphatase activity is highly sensitive to the degree of phosphorylation of pyruvate dehydrogenase and that the major effect of Ca2+ may be to overcome the inhibitory effects of sites 2 and 3 on the dephosphorylation of site 1. Apparent K0.5 values for Mg2+ and Ca2+ were determined from the increases in pyruvate dehydrogenase activity observed after 5 min. The K0.5 for Mg2+ was diminished from 0.60 mM at less than 1 nM-Ca2+ to 0.32 mM at 100 microM-Ca2+; at 0.18 mM-Mg2+, the K0.5 for Ca2+ was 0.40 microM. Ca2+ had little or no effect at saturating Mg2+ concentrations. Since effects of Ca2+ are readily observed in intact coupled mitochondria, it follows that Mg2+ concentrations within mitochondria are sub-saturating for pyruvate dehydrogenase phosphate phosphatase and hence less than 0.5 mM.     

Branched chain alpha-ketoacid dehydrogenase and pyruvate dehydrogenase activity in isolated rat pancreatic islets

Branched-chain alpha-ketoacid dehydrogenase and pyruvate dehydrogenase in isolated rat pancreatic islets were shown to be regulated by a phosphorylation/dephosphorylation mechanism. Broad-specificity phosphoprotein phosphatase treatment stimulated and ATP addition inhibited their activities. The kinases responsible for inactivating these complexes were shown to be sensitive to inhibition by known inhibitors, alpha-chloroisocaproate and dichloroacetate. Total activity (nmol/min/islet / 37 degrees C) of branched-chain alpha-ketoacid dehydrogenase and pyruvate dehydrogenase was 0.86 and 5.09, with a % active form (activity before phosphatase treatment divided by activity after phosphatase treatment X 100) of 36% and 94%, respectively. Incubation of intact isolated islets with alpha-chloroisocaproate affected neither insulin release nor flux through branched-chain alpha-ketoacid dehydrogenase.     

Role of individual phosphorylation sites in inactivation of pyruvate dehydrogenase complex in rat heart mitochondria

1. A method is described using trypsin/formic acid cleavage for unambiguously measuring occupancies of phosphorylation sites in rat heart pyruvate dehydrogenase [³²P]phosphate complexes. 2. In mitochondria oxidizing 2-oxoglutarate+l-malate relative initial rates of phosphorylation were site 1>site 2>site 3. 3. Dephosphorylation and reactivation of fully phosphorylated complex was initiated in mitochondria by inhibiting the kinase reaction. Using dichloroacetate relative rates of dephosphorylation were site 2>(1=3). Using sodium dithionite or sodium pyruvate or uncouplers+sodium arsenite or steady state turnover (³¹P replacing ³²P in inactive complex) relative rates were site 2>site 1>site 3. With dithionite reactivation was faster than site 3 dephosphorylation, i.e. site 3 is apparently not inactivating. 4. The steady state proportion of inactive complex was varied (92–48%) in mitochondria oxidizing 2-oxoglutarate/l-malate by increasing extramitochondrial Ca²⁺ (0–2.6μm). This action of Ca²⁺ induced dephosphorylation (site 3>site 2>site 1). These experiments enable prediction of site occupancies in vivo for given steady state proportions of inactive complexes. 5. The proportion of inactive complex was related linearly to occupancy of site 1. 6. Sodium dithionite (10mm) and Ca²⁺ (0.5μm) together resulted in faster dephosphorylations of each site than either agent alone; relative rates were site 2>(1=3). 7. Dephosphorylation and possibly phosphorylation of sites 1 and 2 was not purely sequential as shown by detection of complexes phosphorylated in site 2 but not in site 1. Estimates of the contribution of site 2 phosphorylation to inactivation ranged from 0.7 to 6.4%. 8. It is concluded that the primary function of site 1 phosphorylation is inactivation, phosphorylation of site 2 is not primarily concerned with inactivation and that phosphorylation of site 3 is non-inactivating.     

Dephosphorylation of pig heart pyruvate dehydrogenase phosphate complexes by pig heart pyruvate dehydrogenase phosphate phosphatase.

1. Pig heart pyruvate dehydrogenase phosphate complex in which all three sites of phosphorylation were completely phosphorylated was re-activated at a slower rate by phosphatase than complex predominantly phosphorylated in site 1. The ratio of initial rates of re-activation was approx. 1:5 with a comparatively crude preparation of phosphatase and with phosphatase purified by gel filtration and ion-exchange chromatography. 2. The ratio of apparent first-order rate constants during dephosphorylation of fully phosphorylated complex averaged 1/3.8/1.3 for site 1/site 2/site 3. Only site-1 dephosphorylation was linearly correlated with re-activation of the complex throughout dephosphorylation. Dephosphorylation of site 3 was linearly correlated with re-activation after an initial burst of dephosphorylation. 3. Because dephosphorylation of site 1 was always associated with dephosphorylation of site 2, it is concluded that dephosphorylation cannot be purely random. 4. The ratio of apparent first-order rate constants for dephosphorylation of site 1 (partially/fully phosphorylated complexes) averaged 1.72. This ratio is smaller than the ratio of approx. 5 for the initial rates of re-activation. Possible mechanisms involved in the diminished rate of re-activation of fully phosphorylated complex are discussed.     

The elementary reactions of the pig heart pyruvate dehydrogenase complex. A study of the inhibition by phosphorylation.

1. A method was devised for preparing pig heart pyruvate dehydrogenase free of thiamin pyrophosphate (TPP), permitting studies of the binding of [35S]TPP to pyruvate dehydrogenase and pyruvate dehydrogenase phosphate. The Kd of TPP for pyruvate dehydrogenase was in the range 6.2-8.2 muM, whereas that for pyruvate dehydrogenase phosphate was approximately 15 muM; both forms of the complex contained about the same total number of binding sites (500 pmol/unit of enzyme). EDTA completely inhibited binding of TPP; sodium pyrophosphate, adenylyl imidodiphosphate and GTP, which are inhibitors (competitive with TPP) of the overall pyruvate dehydrogenase reaction, did not appreciably affect TPP binding. 2. Initial-velocity patterns of the overall pyruvate dehydrogenase reaction obtained with varying TPP, CoA and NAD+ concentrations at a fixed pyruvate concentration were consistent with a sequential three-site Ping Pong mechanism; in the presence of oxaloacetate and citrate synthase to remove acetyl-CoA (an inhibitor of the overall reaction) the values of Km for NAD+ and CoA were 53+/- 5 muM and 1.9+/-0.2 muM respectively. Initial-velocity patterns observed with varying TPP concentrations at various fixed concentrations of pyruvate were indicative of either a compulsory order of addition of substrates to form a ternary complex (pyruvate-Enz-TPP) or a random-sequence mechanism in which interconversion of ternary intermediates is rate-limiting; values of Km for pyruvate and TPP were 25+/-4 muM and 50+/-10 nM respectively. The Kia-TPP (the dissociation constant for Enz-TPP complex calculated from kinetic plots) was close to the value of Kd-TPP (determined by direct binding studies). 3. Inhibition of the overall pyruvate dehydrogenase reaction by pyrophosphate was mixed non-competitive versus pyruvate and competitive versus TPP; however, pyrophosphate did not alter the calculated value for Kia-TPP, consistent with the lack of effect of pyrophosphate on the Kd for TPP. 4. Pyruvate dehydrogenase catalysed a TPP-dependent production of 14CO2 from [1-14C]pyruvate in the absence of NAD+ and CoA at approximately 0.35% of the overall reaction rate; this was substantially inhibited by phosphorylation of the enzyme both in the presence and absence of acetaldehyde (which stimulates the rate of 14CO2 production two- or three-fold). 5. Pyruvate dehydrogenase catalysed a partial back-reaction in the presence of TPP, acetyl-CoA and NADH. The Km for TPP was 4.1+/-0.5 muM. The partial back-reaction was stimulated by acetaldehyde, inhibited by pyrophosphate and abolished by phosphorylation. 6. Formation of enzyme-bound [14C]acetylhydrolipoate from [3-14C]pyruvate but not from [1-14C]acetyl-CoA was inhibited by phosphorylation. Phosphorylation also substantially inhibited the transfer of [14C]acetyl groups from enzyme-bound [14C]acetylhydrolipoate to TPP in the presence of NADH. 7...     

Further evidence for direct interaction of pyruvate dehydrogenase multienzyme complex with citric acid cycle based on nonlinearity of hill plots in presence of C2 and C4 substrate analogues

1. Mammalian pyruvate dehydrogenase multienzyme complex (PDC) is measured with two different optical assays: (i) formation of p-nitro-acetanilid with arylamine-acetyltransferase and (ii) NAD reduction. 2. It is found that in contrast to the NAD assay system (ii) the coupled system (i) exhibits cooperativity with a Hill coefficient n = 3 over the whole range of substrate concentration. 3. The cooperative behaviour can be modified by presence of dichloroacetate (n = 2) and acetoin (n = 1----3). From additional measurements of PDC activity with toluene permeabilized mitochondria of fed and starved rats it is concluded that PDC activity in vivo is modified by changes in enzyme enzyme aggregation and interaction beside the known phosphorylation dephosphorylation mechanism.     

Phosphorylation of additional sites on pyruvate dehydrogenase inhibits its re-activation by pyruvate dehydrogenase phosphate phosphatase.

The phosphorylation of sites additional to an inactivating site inhibits the formation of active pig heart pyruvate dehydrogenase complex from inactive pyruvate dehydrogenase phosphate complex by pig heart pyruvate dehydrogenase phosphate phosphatase.     

Binding of thiamin thiazolone pyrophosphate to mammalian pyruvate dehydrogenase and its effects of kinase and phosphatase activities.

The pyruvate dehydrogenase component of the bovine kidney pyruvate dehydrogenase complex has two thiamin-PP binding sites per α₂β₂ tetramer. Titration of these binding sites with the transition state analog, thiamin thiazolone pyrophosphate, strongly inhibits phosphorylation of pyruvate dehydrogenase by pyruvate dehydrogenase kinase and ATP. The analog has little effect, if any, on dephosphorylation of phosphorylated pyruvate dehydrogenase by pyruvate dehydrogenase phosphatase. Phosphorylation of pyruvate dehydrogenase inactivates the enzyme, but does not significantly affect the thiamin-PP binding sites. It appears that phosphorylation produces a conformational change in pyruvate dehydrogenase that displaces a catalytic group (or groups) at the active center.     

Amino acid sequences around the sites of phosphorylation in the pig heart pyruvate dehydrogenase complex.

1. When pig heart pyruvate dehydrogenase complex was phosphorylated to completion with [gamma-32P]ATP by its intrinsic kinase, three phosphorylation sites were observed. The amino acid sequences around these sites were: sequence 1, Tyr-Gly-Met-Gly-Thr-Ser(P)-Val-Glu-Arg; and sequence 2, Tyr-His-Gly-His-Ser(P)-Met-Ser-Asp-Pro-Gly-Val-Ser(P)-Tyr-Arg. 2. When phosphorylated to inactivation by repetitive additions of limiting quantities of [gamma-32P]ATP, phosphate was incorporated mainly (more than 90%) into Ser-5 of sequence 2. Phosphorylation of this site thus results in activation of pyruvate dehydrogenase. 3. If Ser-5 is phosphorylated with ATP and the enzyme then incubated with [gamma-32P]ATP, phosphorylation of the remaining sites occurred. Ser-12 of sequence 2 is phosphorylated about twice as rapidly as Ser-6 of sequence 1. 4. Incubation of pyruvate dehydrogenase with excess [gamma-32P]ATP with termination of phosphorylation at about 50% complete inactivation showed that Ser-5 of sequence 2 was phosphorylated most rapidly, but also that Ser-12 of sequence 2 was significantly (15% of total) phosphorylated. Ser-6 sequence 1 contained about 1% total P. 5. These results suggest that addition of limiting amounts of ATP produces primarily phosphorylation of Ser-5 of sequence 2 (inactivating site). This also occurs during incubation with excess ATP before complete inactivation occurs, but a greater occupancy of other sites also occurs during this treatment.     

Characterization of an Escherichia coli K12 mutant that is sensitive to chlorate when grown aerobically.

1. The ;initial activity' of the pyruvate dehydrogenase enzyme complex in whole tissue or mitochondrial extracts of lactating rat mammary glands was greatly decreased by 24 or 48h starvation of the rats. Injection of insulin and glucose into starved rats 60min before removal of the glands abolished this difference in ;initial activities'. 2. The ;total activity' of the enzyme complex in such extracts was revealed by incubation in the presence of free Mg(2+) and Ca(2+) ions (more than 10 and 0.1mm respectively) and a crude preparation of pig heart pyruvate dehydrogenase phosphatase. Starvation did not alter this ;total activity'. It is assumed that the decline in ;initial activity' of the enzyme complex derived from the glands of starved animals was due to increased phosphorylation of its alpha-subunit by intrinsic pyruvate dehydrogenase kinase. 3. Starvation led to an increase in intrinsic pyruvate dehydrogenase kinase activity in both whole tissue and mitochondrial extracts. Injection of insulin into starved animals 30min before removal of the lactating mammary glands abolished the increase in pyruvate dehydrogenase kinase activity in whole-tissue extracts. 4. Pyruvate (1mm) prevented ATP-induced inactivation of the enzyme complex in mitochondrial extracts from glands of fed animals. In similar extracts from starved animals pyruvate was ineffective. 5. Starvation led to a decline in activity of pyruvate dehydrogenase phosphatase in mitochondrial extracts, but not in whole-tissue extracts. 6. These changes in activity of the intrinsic kinase and phosphatase of the pyruvate dehydrogenase complex of lactating rat mammary gland are not explicable by current theories of regulation of the complex.     

Characterization of the isozymes of pyruvate dehydrogenase phosphatase: implications for the regulation of pyruvate dehydrogenase activity

The activity of mammalian pyruvate dehydrogenase complex (PDC) is regulated by a phosphorylation/dephosphorylation cycle. Dephosphorylation accompanied by activation is carried out by two genetically different isozymes of pyruvate dehydrogenase phosphatase, PDP1c and PDP2c. Here, we report data showing that PDP1c and PDP2c display marked biochemical differences. The activity of PDP1c strongly depends upon the simultaneous presence of calcium ions and the E2 component of PDC. In contrast, the activity of PDP2c displays little, if any, dependence upon either calcium ions or E2. Furthermore, PDP2c does not appreciably bind to PDC under the conditions when PDP1c exists predominantly in the PDC-bound state. The stimulatory effect of E2 on PDP1c can be partially mimicked by a monomeric construct consisting of the inner lipoyl-bearing domain and the E1-binding domain of E2 component. This strongly suggests that the E2-mediated activation of PDP1c largely reflects the effects of co-localization and mutual orientation of PDP1c and E1 component facilitated by their binding to E2. Both PDP1c and PDP2c can efficiently dephosphorylate all three phosphorylation sites located on the alpha chain of the E1 component. For PDC phosphorylated at a single site, the relative rates of dephosphorylation of individual sites are: 2>site 3>site 1. Phosphorylation of sites 2 or 3 in addition to site 1 does not have a significant effect on the rates of dephosphorylation of individual sites by PDP1c, suggesting a random mechanism of dephosphorylation. In contrast, there is a significant decrease in the overall rate of dephosphorylation of pyruvate dehydrogenase by PDP2c under these conditions. This indicates that the mechanism of dephosphorylation of PDC phosphorylated at multiple sites by PDP2c is not purely random. These marked differences in the site-specificity displayed by PDP1c and PDP2c should be particularly important under conditions such as starvation and diabetes, which are associated with a great increase in phosphorylation of sites 2 and 3 of pyruvate dehydrogenase.     

Glucose metabolism in perfused skeletal muscle. Pyruvate dehydrogenase activity in starvation, diabetes and exercise.

1. The interconversion of pyruvate dehydrogenase between its inactive phosphorylated and active dephosphorylated forms was studied in skeletal muscle. 2. Exercise, induced by electrical stimulation of the sciatic nerve (5/s), increased the measured activity of (active) pyruvate dehydrogenase threefold in intact anaesthetized rated within 2 min. No further increase was seen after 15 min of stimulation. 3. In the perfused rat hindquarter, (active) pyruvate dehydrogenase activity was decreased by 50% in muscle of starved and diabetic rats. Exercise produced a twofold increase in its activity in all groups; however, the relative differences between fed, starved and diabetic groups persisted. 4. Perfusion of muslce with acetoacetate (2 mM) decreased (active) pyruvate dehydrogenase activity by 50% at rest but not during exercise. 5. Whole-tissue concentrations of pyruvate and citrate, inhibitors of (active) pyruvate dehydrogenase kinase and (inactive) pyruvate dehydrogenase phosphate phosphatase respectively, were not altered by excerise. A decrease in the ATP/ADP ratio was observed, but did not appear to be sufficient to account for the increase in (active) pyruvate dehydrogenase activity. 6. The results suggest that interconversion of the phosphorylated and dephosphorylated forms of pyruvate dehydrogenase plays a major role in the regulation of pyruvate oxidation by eomparison of enzyme activity with measurements of lactate oxidation in the perfused hindquarter [see the preceding paper, Berger et al. (1976)] suggest that pyruvate oxidation is also modulated by the concentrations of substrates, cofactors and inhibitors of (active) pyruvate dehydrogenase activity.