The subunit structure of rat liver pyruvate kinase

The amino acid composition for rat liver pyruvate kinase is reported. Thin layer peptide mapping of the tryptic digests yields 44 ninhydrin-reactive peptides, which is one-quarter the total number of lysyl and arginyl residues. No amino-terminal residue has been detected using the dansyl chloride procedure. Acid urea disc gel electrophoresis of the protein subunits yields only one protein band; yet, isoelectric focusing of the subunits in urea yields two protein bands. These results suggest that pyruvate kinase (L-type isozyme) consists of four subunits of similar primary structure, but with sufficient microheterogeniety to be able to resolve two types of subunits upon isoelectric focusing.     

Postnatal changes in canine erythrocyte pyruvate kinase isozymes

The isozyme pattern of pyruvate kinase in canine erythrocytes changes following birth. These changes have been followed by electrophoretic, immunologic, and kinetic measurements of the isozymes. At birth, a mixture of isozymes is present consisting of the M₂ isozyme and hybrid molecules containing M₂ and R subunits. With increasing animal age, the content of M₂ subunits decreases and the content of R subunits increases. At 6 months of age, the isozyme pattern is indistinguishable from that of adult erythrocytes which contain only the R tetramer. We conclude that there is a switch in erythrocyte pyruvate kinase gene expression during the first 6 months of postnatal life. The existence of hybrid molecules during the switch indicates that both M₂ and R genes are expressed within each erythroid precursor cell. The developmental changes in erythrocyte pyruvate kinase are consistent with the role of this enzyme in the regulation of the oxygen-transport function of canine hemoglobin by 2,3-diphosphoglycerate in the postnatal period.This research was supported by Public Health Service Grant HD-10595.     

Hybrid isozymes of pyruvate kinase appear during avian cardiac development

Pyruvate kinase isozyme patterns in the ventricle of developing chicks shift gradually from one dominated by type K at ten days of embryonic development to the adult pattern, which is dominated by type M. Hybrid isozymes are apparent throughout development and are most prominent from two days before hatching until at least 14 days after hatching. These hybrid isozymes indicate simultaneous synthesis of the two subunit types in the same cells.The complex isozyme patterns of the chick heart probably limit the usefulness of simple kinetic analyses on tissue extracts for determing isozymic compositions during development.     

Modification of pyruvate kinase isozymes in prolonged primary cultures of adult rat hepatocytes.

Pyruvate kinase isozymic changes were studied in the adult hepatocyte cultures, by electrophoretic, kinetic and immunological methods. We were able to maintain parenchymal cells from normal adult rat liver in non-proliferating monolayer cultures up to 10 days. Hepatocytes appeared to contain a dominant PK I type up to 4-5 days of culture. After day 5, PK III type was regularly present with PK I and after 7 days PK III type was always the only isozyme detected in culture. It must be pointed out that, by the Ouchterlony method and sometimes by electrophoresis, concentrated extracts from freshly isolated hepatocytes or starting hepatocyte cultures did also contain Pyruvate kinase PK III type. These results suggest that Pyruvate kinase III is present but partly repressed in the adult parenchymal cells and becomes derepressed in culture.     

Bovine pyruvate kinase isozymes and hybrid isozymes. Electrophoretic studies and tissue distribution.

Electrophoresis of various bovine tissue extracts revealed, in addition to the three major homotetrameric isozymes of pyruvate kinase (K₄, L₄, and M₄), numerous intermediate bands that behave electrophoretically as hybrid isozymes. Kidney, for example, contains both K-L and K-M hybrid sets. Representative hybrids from each set, tentatively identified as K₂L₂ and K₃M, were isolated from kidney by ionexchange chromatography and their subunit compositions were confirmed by dissociation and subsequent reassociation into new hybrid sets. All of the tissues examined that contain type K₄ also have substantial quantities of K-M hybrids, establishing the presence of the type M isozyme in a great many tissues other than striated muscle and brain, where it is most abundant. In addition, small quantities of K subunits apparently are produced even in striated muscle, which previously had been thought to contain only M₄. The pattern of hybrids and enzyme specific activities differ markedly within tissues from the same organ, as shown by dissection of the heart and great vessels. Aortic smooth muscle has a fairly uniform distribution of K-M hybrids, while cardiac muscle has mostly M₄ with a little KM₃. Connective tissue from heart valves, on the other hand, has a five-membered set dominated by K₃M, while Purkinje fibers have a five-membered set dominated by KM₃. The occurrence of K-M hybrids in these and many other tissues indicates that the distribution of mammalian pyruvate kinase isozymes is much more complex than previously reported.     

Ontogenesis of pyruvate kinase in the brain and liver tissues of the rat.

The ontogenetic study of pyruvate kinase in the brain and liver tissues was performed in different batches of rats, from the foetus at the 13th day of gestation to the adult subject. -- According to the kinetic study, the shape of the curve is transformed from sigmoid to hyperbolic from the 13th day of foetal life to adulthood in the brain. Hill coefficient increases with the age of animal in the liver tissue. -- According to polyacrylamide gel isoelectrofocusing, a family of four, transitory or definite bands are detected in the foetal brain : they are well defined by their pHi : M4, M3, M2, M1 ; at the adult stage, M1 predominates, M2 is minor. Threee principal bands are distinguished in the liver : two are characteristic of foetal life (Lf and M2), one of adulthood (L). -- According to the immunochemical tests, there are antigenic determinants common to M1, M2, M3 and M4. The confrontation of the first two methods prompts the conclusion that the kinetic of the enzyme (and perhaps its function) varies with the animals age and is linked to its molecular structure. With the third method, it allows to stress the precociousness of the appearance of the common antigenic determinants, simultaneously with immature enzymatic forms. The signification of the kinetic modifications as well as the succession of the isozymes of the M type in a determined order are discussed and the in vivo formation of hydbrids is suggested.     

Evolution of the functional properties of pyruvate kinase isozymes: pyruvate kinase L fromRana pipiens

Summary The regulatory properties of type L pyruvate kinase fromRana pipiens are intermediate between those of the mammalian K and L isozymes. As with mammalian type L, the levels of the frog isozyme are affected by the animal's nutritional state. The mammalian and amphibian isozymes show similar sensitivities to fructose 1,6-bisphosphate activation and amino acid inhibition. By contrast, the frog L isozyme shares several properties of the K class: ie. irreversible inactivation by oxidized glutathione and lack of response to a cyclic AMP stimulated phosphorylation. Furthermore, as for some mammalian K isozymes, frog type L shows a high PEP affinity and a low cooperativity of PEP binding.Insofar as the properties of this present day enzyme reflect those of its counterpart in the amphibian ancestor of higher vertebrates, our results suggest that at its first expression, the type L resembled the type K. Many important regulatory properties of the L isozyme, especially the sensitivity to phosphorylation, were acquired more recently perhaps in association with an increased importance of constant blood glucose.Abbreviations DTT dithiothreitol - EDTA ethylenediamine tetraacetic acid - EGTA ethyleneglycol-bis(2-aminoethylether)-N,N-tetraacetic acid - FB fructose-1,6-bisphosphate - PEP phosphoenolpyruvate - PK pyruvate kinase     

Ontogenesis of pyruvate kinase in the brain and liver tissues of the rat

The ontogenetic study of pyruvate kinase in the brain and liver tissues was performed in different batches of rats, from the fœtus at the 13th day of gestation to the adult subject.

— According to the kinetic study, the shape of the curve is transformed from sigmoid to hyperbolic from the 13th day of fœtal life to adulthood in the brain. Hill cœfficient increases with the age of animal in the liver tissue.

— According to polyacrylamide gel isoelectrofocusing, a family of four, transitory or definite bands are detected in the fœtal brain: they are well defined by their pHi: M₄, M₃, M₂, M₁; at the adult stage, M₁ predominates, M₂ is minor. Three principal bands are distinguished in the liver: two are characteristic of fœtal life (Lf and M₂), one of adulthood (L).

— According to the immunochemical tests, there are antigenic determinants common to M₁, M₂, M₃ and M₄.

The confrontation of the first two methods prompts the conclusion that the kinetic of the enzyme (and perhaps its function) varies with the animals age and is linked to its molecular structure. With the third method, it allows to stress the precociousness of the appearance of the common antigenic determinants, simultaneously with immature enzymatic forms.The signification of the kinetic modifications as well as the succession of the isozymes of the M type in a determined order are discussed and the in vivo formation of hybrids is suggested.     

Immunohistochemical analysis of rat S-adenosylmethionine synthetase isozymes in developmental liver

Mammalian S-adenosylmethionine (AdoMet) synthetase exists as two isozymes, liver-type and kidney(non-hepatic)-type enzymes. The developmental expression of these two isozyme proteins has been investigated in rat liver using immunohistochemical techniques. The liver-type AdoMet synthetase is expressed only in adult liver, but not in fetal liver. On the other hand, the kidney-type AdoMet synthetase is predominantly expressed in fetal liver and faintly detected in adult liver. It was also found that both isozymes were localized to the hepatocytes of rat liver. These results clearly show that AdoMet synthetase isozymes are developmentally regulated within hepatocytes. In addition, in rat kidney we have shown that the kidney-type AdoMet synthetase is predominantly localized to the distal tubule.     

Allosteric activation of pyruvate kinase via NAD+ in rat liver cells.

In isolated rat hepatocytes, it has previously been reported that a rise in the ATP content induces a proportional increase in cytosolic NAD+ concentration [Devin, A., Guérin, B. & Rigoulet, M. (1997) FEBS Lett. 410, 329-332]. This occurs under physiological conditions such as various substrates or different energetic states. To investigate the effect of a physiological rise in cytosolic [NAD+] per se on glycolysis and gluconeogenesis, an increase in [NAD+] induced by exogenous nicotinamide addition was obtained without a change in redox potential, ATP/ADP ratio and ATP concentration. Using dihydroxyacetone as substrate, we found that an increase in cytosolic [NAD+] decreases gluconeogenesis and enhances glycolysis without significant alteration of dihydroxyacetone consumption rate. These modifications are the consequence of an allosteric activation of pyruvate kinase via cytosolic NAD+ content. Thus, in addition to the well-known thermodynamic control of glycolysis by pyridine-nucleotide redox status, our study points to a new mechanism of glycolytic flux regulation by NAD+ concentration at the level of pyruvate kinase activity.     

Long-term effect of glucagon administration on rat liver L-type pyruvate kinase.

After 5 h of treatment with glucagon, liver L-type pyruvate kinase (ATP: pyruvate 2-0-phosphotransferase; EC 2.7.1.40) showed a significant decrease of K0.5 and the Hill coefficient (nH) in the absence of fructose 1,6-diphosphate. However, in the presence of fructose 1,6-diphosphate, liver enzymes from treated rats showed a slight decrease of K0.5 but nH remained unchanged. In both circumstances, no changes of Vmax were observed after treatment. These changes in the kinetic properties of liver L-type pyruvate kinase are consistent with the dephosphorylation of the enzyme caused by insulin release in response to treatment with glucagon.     

The immunological properties of pyruvate kinase. II. The relationship of the human erythrocyte isozyme to the human liver isozymes.

We have examined the hypothesis that the human erythrocyte isozyme of pyruvate kinase (EC 2.7.1.40) is a hybrid of the two isozymes present in liver. Rabbit antiserum against purified human erythrocyte pyruvate kinase inactivates the erythrocyte isozyme and the major liver isozyme from human tissue but does not inactivate the minor liver isozyme. The electrophoretic mobilities of the erythrocyte and major liver isozymes are altered by anti-erythrocyte enzyme antibody while the mobility of the minor liver isozyme is unaffected. Gel diffusion analysis indicates cross-reactivity between the erythrocyte and major liver isozyme but no cross-reactivity with the minor liver isozyme. The hybrid hypothesis would predict cross-reactivity including changes in activity and mobility of all isozymes and we conclude, therefore that the hypothesis is incorrect.     

Membrane-associated pyruvate kinase in developing guinea-pig liver.

During analysis of pyruvate kinase distribution in developing guinea-pig liver it was observed that a substantial proportion of the activity remained associated with the microsomal membrane fraction ('microsomes'). Although some of this could be removed by washing with sucrose, the majority required detergent treatment for liberation, and even then at least one-half remained attached to the microsomes. Estimates of the contribution of this fraction to total cell pyruvate kinase activity indicated that it was more than 50% of the total, and this is likely to be an underestimate because of the continued latency of the enzyme even in the presence of detergent. The susceptibility of the microsomal enzyme, whether released by detergent or sucrose washing, to inactivation by Triton X-100 suggested it to be different from the cytosolic enzyme, which was stable under such conditions. (The microsomal enzyme required the presence of additional protein, such as bovine serum albumin, to maintain stability.) This view was confirmed by DEAE-cellulose chromatography and particularly isoelectric focusing, where the microsomal enzyme was shown to consist of at least four forms, which were distinctly different from those in the cytosol. Those data and the kinetic properties of the four forms in the membrane fraction indicate that the microsomal pyruvate kinase could consist of four counterparts to the cytosolic isoenzyme forms. These results are discussed in relation to the two possible explanations for the phenomenon (not mutually exclusive): that the more hydrophobic membrane forms are precursors of the cytosolic enzyme and that they may be part of functional glycolytic pathway in the microsomes of developing liver.