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.     

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.     

Isozyme differentiation of aldolase and pyruvate kinase in fetal,regenerating, preneoplastic,and malignant rat hepatocytes during culture

Summary Aldolase and pyruvate kinase isozymes were investigated in cultured hepatocytes from fetal, regenerating, and 2-acetyl-aminofluorene-fed rat liver as well as in some epithelial liver cell lines. Our results show that: (a) cell proliferation and prolonged expression of specific isozymes were found only in cultured hepatocytes from 17-day old fetuses; (b) the fetal type of pyruvate kinase expressed in regenerating and carcinogen-treated liver was temporarily lost only in cultured hepatocytes from regenerating liver; (c) the adult type of aldolase and pyruvate kinase was absent in one epithelial cell line derived from a carcinogen-treated liver and in the hepatoma tissue cell (HTC) line but was found in the Faza clone of the Reuber H₃₅ cell line during the 50 first passages in vitro; and (d) the isozyme pattern of pyruvate kinase was always more strongly shifted than that of aldolase. The observations suggest that: (a) hepatocytes from carcinogen-treated liver exhibit the same lack of ability to proliferate in primary culture as normal adult hepatocytes; (b) adult hepatocytes can produce fetal isozymes without prior cell division; (c) pyruvate kinase is a stronger marker of dedifferentiation (retrodifferentiation) than aldolase; and (d) regulatory processes of isozyme expression are different during ontogenesis, regeneration, and hepatocarcinogenesis. This work was supported by the “Institut National de la Santé et de la Recherche Médicale” and the “Fondation pour la Recherche Medicale Fran?aise”     

Effect of dexamethasone on the isozyme pattern of adult rat liver parenchymal cells in primary cultures

Summary The influence of dexamethasone on the isozyme patterns of ATP-hexose phosphotransferases, aldolase and pyruvate kinase of adult rat hepatocytes maintained in primary cultures has been studied.A progressive loss of the typical adult liver isozymes glucokinase, pyruvate kinase L and aldolase B, with a simultaneous increase of both pyruvate kinase A and hexokinase activities, was observed in hepatocytes cultured in the absence of added glucocorticoid.When the culture medium was supplemented with 10^–7 M dexamethasone, the adult liver patterns of pyruvate kinase and aldolase were preserved for at least seven days of culture, the initial level of glucokinase was maintained for three days, and the rise of hexokinase activity was delayed and partially blocked.These results are discussed in relation to the known beneficial effect of glucocorticoids on the survival of cultured hepatocytes.     

Pyruvate kinase isozymes in adult tissues and eggs of Rana pipiens. Comparative studies on the properties of the different isozymes

The properties of the isozymes of pyruvate kinase (ATP: pyruvate phosphotransferase, EC 2.7.1.40) found in unfertilized frog egg have been compared to those found in adult tissues of Rana pipiens. Chromatographic, kinetic, and electrophoretic data indicate that, of the five electrophoretic forms found in egg, the isozyme with the least anodic mobility (isozyme I) is the same molecular species as the only isozyme found in heart, and the egg isozyme with the greatest anodic mobility (isozyme V) is identical to the major isozyme found in liver.The activity of egg isozyme I was markedly inhibited by the antibody to the skeletal muscle enzyme, which has been shown previously to cross-react with the cardiac enzyme, but was unaffected by the antibody to liver isozyme V; the opposite effects were observed with egg isozyme V. The antibody to the skeletal muscle enzyme inhibited egg isozymes II > III > IV whereas the antibody to the liver enzyme gave the reverse inhibitory pattern, e.g., isozyme IV > III > II.In vitro dissociation-reassociation of mixtures of isozyme I and V led to the formation of the other three isozymes. Similar experiments performed individually with either egg isozyme III or IV resulted in the production of predominantly isozymes III, II, and I due to the instability of isozyme V during the hybridization procedure.The above results indicate that isozymes I and V are tetramers of the respective parental subunits and that isozymes II, III, and IV are hybrid molecules with subunit assignments of (I₃V₁), I₂V₂), and (I₁V₃), respectively.     

Purification and properties of pyruvate kinase type M2 from rat lung

(1) Pyruvate kinase type M₂ from rat lung has been purified 840-fold with an overall yield of 20%. The enzyme gave a single band upon SDS-electrophoresis and isoelectrofocusing and had a specific activity of 1340 U/mg protein. The homotetramer of M_r = 224 000 and an isoelectric point of pH 5.8 had an amino acid composition closely resembling that of other pyruvate kinase isoenzymes type M₂, excepts that of the chicken liver. The enzyme was crystallized. (2) The enzyme has its pH optimum at pH 6.5. The K_0.5 value for phosphoenolpyruvate is 0.26 mM (n_H = 1.81) which decreases in the presence of 0.2 mM fructose 1,6-bisphosphate to 0.056 mM (n_H = 1.06). 1 μM fructose 1,6-bisphosphate activates the enzyme at 0.1 mM phosphoenolpyruvate half-maximally. The K_m value for ADP at 1 mM phosphoenolpyruvate is 0.4 mM. The K_m value for other nucleoside diphosphates increases in the order ADP<GDP<IDP<UDP. (3) No evidence for an interconversion of pyruvate kinase type M₂ from rat or chicken lung was found. The enzyme was neither a substrate for the cAMP-dependent protein kinase from rabbit muscle nor for the cAMP-independent protein kinase from chicken liver. Since pyruvate kinase type M₂ from chicken liver is inactivated by phosphorylation catalyzed by a cAMP-independent protein kinase (Eigenbrodt, E., Abdel-Fattah Mostafa, M. and Schoner, W. (1977) Hoppe-Seyler's Z. Physiol. Chem. 358, 1047–1055) we suggest that the interconvertible form of pyruvate kinase type M₂ may represent a separate form of the pyruvate kinase type M₂ family.     

Kinetic properties of pig pyruvate kinases type A from kidney and type M from muscle.

Kinetic properties of homogeneous preparations of pig kidney and pig muscle pyruvate kinases (EC 2.7.1.40) were studied. Both isozymes showed a hyperbolic relationship to ADP with an apparent K_m of 0.3 mm. K⁺ and Mg²⁺ were necessary for the activity of both isozymes, and their dependences on these cations were similar. The muscle isozyme expressed Michaelis-Menten type of kinetics with respect to phosphoenolpyruvate, and the apparent K_m was the same (0.03 mm) from pH 5.5 to pH 8.0. In contrast, the dependence on phosphoenolpyruvate changed with pH for the kidney isozyme. It showed similar properties to the muscle isozyme at pH 5.5–7.0 (apparent K_m of 0.08 mm), while two apparent K_m values for this substrate were present at pH 7.5–8.0, one low (0.1 mm) and one high (0.3–0.6 mm). At pH 7.5, fructose 1,6-bisphosphate converted the kidney isozyme to a kinetical form where only the lower apparent K_m for phosphoenolpyruvate was detected. On the other hand, in the presence of alanine or phenylalanine the kidney pyruvate kinase showed only the higher K_m for this substrate. At low phosphoenolpyruvate levels both isozymes were inhibited by phenylalanine, and half-maximal inhibition was found at 0.3 and 2.2 mm for the kidney and muscle isozymes, respectively. At a 5 mm concentration of the substrate only the kidney isozyme was inhibited, the apparent K_i being the same. Alanine inhibited the kidney isozyme (apparent K_i at 0.3 mm, irrespective of substrate concentration). No effect was seen on the muscle isozyme. Fructose 1,6-bisphosphate was an activator of the kidney isozyme at phosphoenolpyruvate concentrations below 1.0 mm It also counteracted the inhibition by alanine or phenylalanine of this isozyme. ATP inhibited both isozymes, and this inhibition was not counteracted by fructose 1,6-bisphosphate. The kidney isozyme showed both a high and a low apparent K_m for phosphoenolpyruvate in the presence of ATP. The influence of the effectors on the activity of both isozymes varied markedly with pH, except for the action of ATP. At low substrate concentrations, however, the inhibitor action of ATP on the muscle enzyme was diminished around pH 7.5, in contrast to higher or lower pH values. Alanine or phenylalanine were more effective as inhibitors at higher pH values, and fructose 1,6-bisphosphate stimulated the kidney isozyme only at pH levels above pH 6.5. The influence of activators and inhibitors on the regulation of the kidney and muscle pyruvate kinases is discussed.     

Characterization and kinetics of isoenzymes of pyruvate kinase from developing castor bean endosperm

Isozymes of pyruvate kinase (PK) have been isolated from developing castor bean endosperm. One isozyme, PK_c, is localized in the cytosol, and the other, PK_p, is in the plastid. Both isozymes need monovalent and divalent cations for activity, requirements which can be filled by K⁺ and Mg²⁺. Both isozymes are inhibited by citrate, pyruvate, and ATP. PK_c has a much broader pH profile than PK_p and is also more stable. Both have the same K_m (0.05 millimolar) for PEP, but PK_p has a 10-fold higher K_m (0.3 millimolar) for ADP than PK_c (0.03 millimolar). PK_c also has a higher affinity for alternate nucleotide substrates than PK_p. The two isozymes have different kinetic mechanisms. Both have an ordered sequential mechanism and bind phosphoenolpyruvate before ADP. However, the plastid isozyme releases ATP first, whereas pyruvate is the first product released from the cytosolic enzyme. The properties of the two isozymes are similar to those of their counterparts in green tissue.     

Genetic and biochemical aspects of lactate dehydrogenase isozymes in the salmonid eye

Polyacrylamide gel electrophoresis reveals similar differences between the retinal-specific lactate dehydrogenase (LDH) isozymes of the salmon (Salmo salar L.) and the sea-trout (Salmo trutta forma trutta L.) as those previously described for the salmon and the brown trout (Salmo trutta L.). F₁ salmon × sea-trout hybrids give a classic hybrid isozyme pattern, but the F₂ hybrids all possess the parental sea-trout type pattern. Loss of part of the salmon genome in these latter hybrids is the most likely explanation. It was observed that when the individual eye isozymes of the salmon, the sea-trout, and the rainbow trout (Salmo gairdneri Richardson) were eluted from preparative polyacrylamide gels and re-electrophoresed, an apparent interconversion of certain isozyme bands occurred. This phenomenon was also evident using starch gel. However, the major cathodally migrating isozyme in each case (presumably the E4 isozyme) re-electrophoresed pure. The reasons for these interconversions are, as yet, unclear. Attempts to produce in vitro hybridization between the various isolated individual isozymes were unsuccessful. K_m pyruvate values for the different salmon isozymes were of the order expected from results already published for other teleosts.     

Mammalian pyruvate kinase hybrid isozymes: tissue distribution and physiological significance

The purpose of this study was to examine the pyruvate kinase isozymic patterns of a wide variety of tissues from rats and mice, particularly regarding hybrid isozymes. For these studies, we employed longer electrophoresis times than used in most earlier studies in order to improve the resolution of closely spaced bands. The tissue distributions of types K, L, and M pyruvate kinases were found to be approximately the same as those reported earlier for rats and other mammals. In addition, K-M hybrids could be detected in most tissues examined in relative quantities which differed from one tissue to another in the same organism, in corresponding tissues from different species, and within a single tissue during development. Hybrid isozymes containing type L subunits occur in only a few tissues of either the fetus or the adult of either animal. In earlier studies utilizing L-M hybrid isozymes produced in vitro, we showed that the kinetic properties of a given subunit are profoundly affected by the nature of its neighbors within the tetramer (Dyson and Cardenas, ['73] J. Biol. Chem., 248: 8482-8488). Based on these altered kinetic properties, we suggest that there is little need for anorganism to suppress completely the gene activity for one subunit type of pyruvate kinase during the synthesis of larger quantities of a second subunit type.     

Pyruvate kinase isozymes in adult and fetal tissues of chicken.

Tissues of fetal and adult chickens were examined for pyruvate kinase activity. Two electrophoretically distinguishable and noninterconvertible isozymes were found. One of these, designated as type K (for kidney), is the sole pyruvate kinase in the early fetus and is found in appreciable quantities in all adult tissues except striated muscle. The second isozyme, type M, appears shortly before hatching in striated muscle and brain. These two isozymes correspond in their developmental pattern, tissue distribution, electrophoretic, immunological, and kinetic propertiesto similarly designated mammalian pyruvate kinases. However, no kinetic, immunological, or electrophoretic evidence could be found for a chicken isozyme corresponding to the mammalian type L pyruvate kinase. As the latter isozyme seems to be limited in its distribution mostly to highly differentiated gluconeogenic tissues (notable liver, kidney, and small intestine), our results support the proposition that the mammalian type L pyruvate kinase is a specilized isozyme that is present in mammals but not in birds.     

Pyruvate kinase isozymes in man

Anti human M2 type and anti human L type pyruvate kinase sera allowed us to distinguish two groups of pyruvate kinase in man. Erythrocyte and liver (L type) enzymes on the one hand were inhibited by anti L and not all by anti M2 serum; pyruvate kinase from all the other tissues on the other hand were inhibited by anti M2 and not at all by anti L serum. This latter group represent the M type pyruvate kinase isozymes. The M type isozymes have been studied by electrofocusing in thin layer acrylamide-ampholine gel. In adult tissues 4 types of isozymes were found, designated, from acid to alkaline pH, as M2 (predominant form in spleen, leukocytes, lung...), M3, M4 and M1 (predominant form in muscle and brain). In foetal tissues an extra band M2, called M2f, more anodic than M2, was added to the previously described isozymes. Except in brain (in which the isozymes M2, M3, M4 and M1 were found), the most anodic bands (M2f, M2 and M3) were predominant in all the foetal tissues. The isozymes M2f and M2 seem therefore to be the original M type pyruvate kinase forms from which the other isozymes issue. The rate of each isozyme seems to depend on tissue factors characterizing the state of differentiation of some tissues, as indicated by the ability of adult muscle extracts to change the isozymes M2 and M3 into more cathodic forms.     

Pancreatic islets contain the M2 isoenzyme of pyruvate kinase its phosphorylation has no effect on enzyme activity

To determine which of the major isoenzymes of pyruvate kinase pancreatic islet pyruvate kinase most resembled, it was compared to pyruvate kinase from other tissues in kinetic and immunologic studies. The pattern of activation by fructose bisphosphate and the patterns of inhibition by alanine and phenylalanine were most similar to those of the M₂ isoenzyme from kidney and were dissimilar to those of the isoenzymes from skeletal muscle (type M₁) and liver (type L). The islet pyruvate kinase was inhibited by anti-M₁ pyruvate kinase serum (which crossreacts with the M₂ isoenzyme), but not by anti-L pyruvate kinase. These results are most consistent with islets possessing predominantly, if not exclusively, the M₂ isoenzyme of pyruvate kinase. We previously showed that rat pancreatic islet cytosol contains protein kinases that can catalyze a calcium-activated phosphorylation of an endogenous peptide that has properties, such as subunit molecular weight and isoelectric pH, that are identical to those of the M₂ and M, isoenzymes of pyruvate kinase, and that islet cytosol can catalyze phosphorylation of muscle pyruvate kinase. In the present study it was shown that incubating islet cytosol with ATP under conditions known to permit phosphorylation and inhibition of liver pyruvate kinase did not affect the islet pyruvate kinase activity. It is concluded that phosphorylation of the islet pyruvate kinase has no immediate effect on enzyme activity.Abbreviations EGTA ethylene glycos his (-aminoethyl ether)-N,N,NN-tetraacetic acid - Hepes 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid     

Different Functional and Structural Properties of Lactate Dehydrogenase Isozymes at Different Stages of Danio rerioOntogenesis

We studied properties of lactate dehydrogenase isozymes expressed at different stages of Danio rerioontogenesis. H₄-LDH and a minor fraction H₃M₁are expressed during embryonic development. The muscle isozyme (₄) appears after the beginning of muscle contractions in the embryo. ₄and ₄isozymes isolated from the heart and skeletal muscle of the adult fish, respectively, show significant differences in terms of Michaelis constant (K _m) activation energy (AE), and inactivation temperature. H₄-LDH isozymes isolated from unfertilized eggs, the skeletal muscle of larvae, and the heart of the adult fish differ inK _mand activation energy, as well as in inactivation temperature. We propose that these differences may be associated with a ligand interacting with the H₄isozyme at different steps of ontogenesis.     

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.     

Properties of chicken skeletal muscle pyruvate kinase and a proposal for its evolutionary relationship to the other avian and mammalian isozymes.

Pyruvate kinase (EC 2.7.1.40) was isolated and purified from chicken and turkey breast muscle with a purification procedure very similar to that used for the bovine skeletal muscle isozyme (Cardenas, J., Dyson, R., and strandholm, J. (1973), J. Biol. Chem. 248,6931). A study of the chemical and physical properties of the chicken enzyme revealed that it is a tetramer of four apparently identical subunits, closely resembling in this and most other respects the mamalian type 7 isozyme. The properties of these two enzymes are similar enough to permit subunits of chicken type M pyruvate kinase to combine with subunits of mammalian type L (one of the three mammalian isozymes) to form interspecies tetrameric hybrid isozymes in relative quantities that do not differ makedly from those formed when both the M and L isozymes are of mammalian origin. The similarity between the mammalian and avian type M pyruvates kinases suggests a close evolutionary relationship. Further comparisons among the three mammalian and two avian isozymes of pyruvate kinase are consistent with a common evolutionary origin, perhaps from an ancestral form of the type K isozyme, which is the only pyruvate kinase identified in mammalian and avian embryos.     

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.     

Studies on the relationship between glycolysis, lipogenesis, gluconeogenesis, and pyruvate kinase activity of rat and chicken hepatocytes.

Chicken hepatocytes synthesize glucose and fatty acids at rates which are faster than rat hepatocytes. The former also consume exogenous lactate and pyruvate at a much faster rate and, in contrast to rat hepatocytes, do not accumulate large quantities of lactate and pyruvate by aerobic glycolysis. α-Cyano-4-hydroxycinnamate, an inhibitor of pyruvate transport, causes lactate and pyruvate accumulation by chicken hepatocytes. Glucagon and N⁶,O²′-dibutyryl adenosine 3′,5′-monophosphate (dibutyryl cyclic AMP) convert pyruvate kinase (EC 2.7.1.40) of rat hepatocytes to a less active form. This effect explains, in part, inhibition of glycolysis, inhibition of lipogenesis, stimulation of gluconeogenesis, and inhibition of the transfer of reducing equivalents from the mitochondrial compartment to the cytoplasmic compartment by these compounds. In contrast, pyruvate kinase of chicken hepatocytes is refractory to inhibition by glucagon or dibutyryl cyclic AMP. Rat liver is known to have predominantly the type L isozyme of pyruvate kinase and chicken liver predominantly the type K. Thus, only the type L isozyme appears subject to interconversion between active and inactive forms by a cyclic AMP-dependent, phosphorylation-dephos-phorylation mechanism. This explains why the transfer of reducing equivalents from the mitochondrial compartment to the cytoplasmic compartment of chicken hepatocytes is insensitive to cyclic AMP. However, glucagon and dibutyryl cyclic AMP inhibit net glucose utilization, inhibit fatty acid synthesis, inhibit lactate and pyruvate accumulation in the presence of α-cyano-4-hydroxycinnamate, and stimulate gluconeogenesis from lactate and dihydroxyacetone by chicken hepatocytes. Thus, a site of action of cyclic AMP distinct from pyruvate kinase must exist in the glycolytic-gluconeogenic pathway of chicken liver.     

Polymorphism of kidney pyruvate kinase in the mouse is determined by a gene,Pk-3, on chromosome 9

An electrophoretically detectable variant of pyruvate kinase (EC 2.7.1.40) has been found in the house mouse Mus musculus. The variant was seen in all tissues examined except liver and red cells. The gene (Pk-3) determining this electrophoretic variation is inherited as an autosomal codominant located on chromosome 9. Our data confirm that the genetic determination of pyruvate kinase in liver and red cells is separate from that in other tissues. In addition, our results indicate that the muscle (M₁) and kidney (M₂) pyruvate kinase isozymes share at least one genetic determinant and may in fact be determined by the same structural gene.This work was supported by the Medical Research Council and by NIH Grants GM 20919 and RR 01183. The Jackson Laboratory is fully accredited by the American Association for Accreditation of Laboratory Animal Care.