Interactions between soluble enzymes and subcellular structure

Cytochalasins induce actin polymerization in human leukocytes

We studied the effect of cytochalasins (B, D, and E) on the F-actin content in human neutrophils and lymphocytes using NBD-phallacidin labeling followed by flow cytometry. All three cytochalasins induced a concentration- and time-dependent increase in the F-actin content in both cell types. The order of potency was cytochalasin D greater than E greater than B. The increase in F-actin content was accompanied by a decrease in the G-actin content as measured by DNase I inhibition assay. These observations suggest that in intact cells cytochalasins may function differently compared to purified and semipurified systems, and their effects may be modified through other actin-binding or sequestering proteins. 2-deoxyglucose (20 mM) caused a decrease in the basal F-actin content and significantly reduced the change induced by the cytochalasins. These results suggest that the state of actin in intact cells is regulated by cytosolic ATP levels, primarily by the integrity of the glycolytic pathway. Based on these observations, we conclude that the mechanism of action of cytochalasins in intact cells is more complex than current models suggest.

Human kidney hexosaminidase A and hexosaminidase B form a complex

The isolation and purification of human kidney hexosaminidases A and B was carried out. Regulation of the supramolecular organization and catalytic activity of hexosaminidases was investigated in the bis(2-ethylhexyl)sulphosuccinate reversed micellar system modeling the enzyme microenvironment in the lysosomes. It was shown that hexosaminidases A and B associate forming 280-300-kDa dimeric complexes under these conditions. At pH 4.75, the hexosaminidases A and B can be isolated from kidney tissue only in the form of this complex.

Cellular differentiation and the microcompartmentation of glycolysis

In this paper, the main features of the cellular activities of the glycolytic enzymes during growth and tissue differentiation are summarized, and correlated with the occurrence of multiple forms of these enzymes, and with their degree of interaction with subcellular structure. The substantial evidence for micro-organization of the glycolytic sequence is described, as well as its significant contribution to the diverse physiological situations encountered during development. Based on this evidence, a modular, biphasic model of glycolytic activity has been developed, with associated features of microcompartmentation and segmentation. Evidence has been provided that these phenomena play important roles in meeting the special needs of emerging cell types during early ontogeny, as well as offering the potential for increased flexibility and control of glycolysis in specialized physiological situations in the adult organism.

Actin cytoskeletal network in aging and cancer

The cytoskeleton is being recognized as an important modulator of metabolic functions of the cell. The actin cytoskeletal network, in particular, is involved in events regulating cell proliferation and differentiation. The state of actin in a variety of cell types is regulated by signals arising from the cell surface through a wide spectrum of interactions. In this review, we explore the role of actin cytoskeletal network in a series of events which are known to influence cell proliferation and differentiation. These include interaction of actin network with extracellular matrix proteins, cell surface membranes, second messengers, cytoplasmic enzymes and the nucleus. Because of the involvement of the actin network in such diverse interactions, we propose that alterations in the actin cytoskeletal function may be an important aspect of generalized decrease in cellular functions associated with aging. Preliminary data indicate that alterations in the cytoskeletal network do occur in cells obtained from older individuals. Alterations in actin state are also reported during malignant transformation of cells in culture, and in naturally occurring tumors. Taken together, the existing data seem to suggest that changes in the actin cytoskeletal network may be a part of the aging process as well as malignant transformation. Therefore, the study of the actin cytoskeletal network and its regulation has the potential to yield important information regarding cellular senescence and neoplastic transformation.

Limited proteolysis of bovine muscle and heart lactate dehydrogenase is inhibited by phospholipid liposome interaction

Limited proteolysis of phospholipid complexes of heart and muscle bovine lactate dehydrogenase by trypsin and chymotrypsin has been studied under nondenaturing condition at pH 7.5. Chymotrypsin cleaves the polypeptide chain of heart and muscle lactate dehydrogenase into two principal fragments and LDH subunits were protected by lipids towards the proteinase attack. Enzymatic activity of heart and muscle lactate dehydrogenase was abolished by limited proteolytic cleavage. In complexes, both isoenzymes were protected against proteinases attack by lipids.

Cooperative effect of fructose bisphosphate and glyceraldehyde-3-phosphate dehydrogenase on aldolase action

The combination of binding and kinetic approaches is suggested to study (i) the mechanism of substrate-modulated dynamic enzyme associations; (ii) the specificity of enzyme interactions. The effect of complex formation between aldolase and glyceraldehyde-3-phosphate dehydrogenase (D-glyceraldehyde-3-phosphate:NAD+ oxidoreductase (phosphorylating), EC 1.2.1.12) on aldolase catalysis was investigated under pseudo-first-order conditions. No change in kcat but a significant increase in KM of fructose 1,6-bisphosphate for aldolase was found when both enzymes were obtained from muscle. In contrast, kcat rather than KM changed if dehydrogenase was isolated from yeast. Next, the conversion of fructose 1-phosphate was not affected by interactions between enzyme couples isolated from muscle. The influence of fructose phosphates on the enzyme-complex formation was studied by means of covalently attached fluorescent probe. We found that the interaction ws not perturbed by the presence of fructose 1-phosphate; however, fructose 1,6-bisphosphate altered the dissociation constant of the enzyme complex. A molecular model for fructose 1,6-bisphosphate-modulated enzyme interaction has been evaluated which suggests that high levels of fructose bisphosphate would drive the formation of the 'channelling' complex between aldolase and glyceraldehyde-3-phosphate dehydrogenase.

Antigenic probes locate binding sites for the glycolytic enzymes glyceraldehyde-3-phosphate dehydrogenase, aldolase and phosphofructokinase on the actin monomer in microfilaments

The topology of the interfaces between actin monomers in microfilaments and three glycolytic enzymes (glyceraldehyde-3-phosphate dehydrogenase, aldolase and phosphofructokinase) was investigated using several specific antibodies directed against precisely located sequences in actin. A major contact area for glyceraldehyde-3-phosphate dehydrogenase was characterized in a region near residue 103. This interaction altered, by long-range conformational changes, the reactivity of antigenic epitopes in the C-terminal part of actin. The interface between actin and aldolase appeared to involve a sequence around residue 299 in the C-terminal region of actin. The interaction of phosphofructokinase, in contrast, modified the reactivity of all antibodies tested. Finally, the phosphagen kinases arginine kinase and creatine kinase showed no interaction with the microfilament.

Evidence that 1,3-bisphosphoglycerate dissociation from phosphoglycerate kinase is an intrinsically rapid reaction step

The steady-state kinetics of 1,3-bisphosphoglycerate formation through the action of phosphoglycerate kinase on 3-phosphoglycerate and ATP have been examined. The results show that initial velocities determined by the standard method of coupling bisphosphoglycerate production to NADH reduction in the presence of glyceraldehyde-3-phosphate dehydrogenase do not differ significantly from those determined in the absence of the latter enzyme. This observation invalidates the proposal that bisphosphoglycerate dissociation from phosphoglycerate kinase is much too slow to account for the high rates of phosphoglycerate turnover observed in the coupled two-enzyme system. The capacity for rapid bisphosphoglycerate production and release is an intrinsic catalytic property of phosphoglycerate kinase that does not require the presence of other enzymes or the involvement of a mechanism of channelized (non-diffusional) transfer of bisphosphoglycerate from the producing enzyme to the consuming one.

In vitro activation of bovine adrenal tyrosine hydroxylase by rabbit skeletal muscle actin: evidence for a possible role of cytoskeletal elements as an activator for cytoplasmic enzymes

Tyrosine hydroxylase prepared from the soluble fraction of bovine adrenal medulla was markedly activated by rabbit skeletal muscle G-actin, and this activation was accompanied by a decrease in the apparent Km of the enzyme for the pterin cofactor. The activating effect of G-actin on the soluble enzyme was still observed in the medium containing a high concentration of salt or excess amounts of proteinase inhibitors. Furthermore, this effect was not affected by either cytochalasin B or DNase I. These results therefore suggest that G-actin interacts with the enzyme molecule at the binding site(s) different from that involved in actin polymerization, and that it causes the activation of the soluble enzyme as a result of an allosteric alteration in the enzyme structure, thus giving rise to the possibility that cytoskeletal elements play an important role in the regulation of catecholamine synthesis as a factor modulating the activity of cytoplasmic tyrosine hydroxylase.

Phosphatidylcholine biosynthesis in cultured glioma cells: evidence for channeling of intermediates

The major pathway of choline (Cho) incorporation into phosphatidylcholine (PtdCho) in mammalian cells is sequential conversion of Cho to phosphocholine (PCho), cytidinediphosphate choline (CDP-Cho) and PtdCho. In intact cells, this sequence is usually demonstrated using radiolabeled Cho since PCho and CDP-Cho do not enter the cell intact. We have studied the incorporation of radiolabeled Cho, PCho and CDP-Cho into rat glioma (C6) cells following electropermeabilization. C6 cells were permeable as judged by [U-14C]sucrose and Erythrosin B uptake and more rapid incorporation of [1,2,3-3H]glycerol into cell lipids, and viable as assessed by uptake and incorporation of [methyl-3H]Cho, [1-14C]oleate and [1,2,3-3H]glycerol into complex lipids. Despite rapid incorporation of [methyl-3H]Cho into PtdCho in permeabilized cells, there was no incorporation of [methyl-14C]PCho or CDP-[methyl-14C]Cho into PtdCho. PCho (300 microM) and CDP-Cho (300 microM) failed to significantly reduce incorporation of 28 microM [methyl-3H]Cho into PtdCho. Radioactivity in PtdCho of cells prelabeled with [methyl-3H]Cho prior to permeabilization could be chased with 4 mM Cho but not with 4 mM PCho or 4 mM CDP-Cho. The water-soluble products of Cho metabolism--PCho, CDP-Cho and glycerophosphocholine--were retained at 37 degrees C in permeabilized cells compared with controls while there was uniform leakage from permeabilized cells at 4 degrees C. Hemicholinium-3, an inhibitor of high-affinity Cho transport, decreased [methyl-3H]Cho incorporation into PtdCho in permeabilized cells, as in controls, suggesting that even in permeabilized cells, Cho incorporation into PtdCho is linked to the transport system. We propose that individual steps of the cytidine pathway of PtdCho biosynthesis are functionally linked and that reaction intermediates are not freely diffusible within the cell but are channeled to PtdCho biosynthesis.

The visualization by affinity electrophoresis of a specific association between the consecutive citric acid cycle enzymes fumarase and malate dehydrogenase

Evidence is growing that the citric acid cycle, like many other metabolic pathways, might exist in vivo as a more or less tightly organized multi-enzyme cluster. The term 'metabolon' [Robinson, J. B. & Srere, P. A. (1985) J. Biol. Chem. 260, 10800-10805] was recently introduced to describe such a complex of sequential metabolic enzymes. We adopted the technique of affinity electrophoresis for the study of interactions between the cycle enzymes fumarase and malate dehydrogenase. This approach offers several advantages over our previously described affinity chromatographic technique [Beeckmans, S. & Kanarek, L. (1981) Eur. J. Biochem. 117, 527-535], one of which is the fact that the interaction can be directly visualized. The observed association is specific since both metabolically unrelated proteins and the cytoplasmic isoenzyme of malate dehydrogenase do not interact with fumarase. Several metabolites (citrate, isocitrate, 2-oxoglutarate, succinate, fumarate, malate, oxaloacetate, Pi, AMP, ADP, NAD+, NADH) were found not to affect the association between fumarase and mitochondrial malate dehydrogenase. Both ATP, Mg2+ -ATP and GTP disrupt the association when they are present at 1 mM concentrations. Lower non-physiological ATP concentrations do not, however, disturb the interaction. The presence of 1 mM ADP was found to abolish the disrupting effect of 1 mM ATP. The latter findings are suggestive of an interruption of the citric acid cycle at the level of fumarase under conditions of high energy load (i.e. high ATP/ADP ratios).

Remarks on the supramolecular organization of the glycolytic system in vivo

The great latent catalytic capacity, manifested at the extremely high intracellular concentrations and in large apparent kcat/Km values, of the glycolytic enzymes on the one hand and their tendency in experiments in vitro to form functionally-specific flux-enhancing (channeling) complexes on the other, is considered and discussed as an apparent discrepancy. A random association of glycolytic enzymes in vivo is probable.

A new strategy for the study of oligomeric enzymes: gamma-glutamyltransferase in reversed micelles of surfactants in organic solvents

A heterodimeric enzyme (gamma-glutamyltransferase) was studied in the reversed micellar medium of Aerosol OT (AOT) in octane. As was shown earlier, the size (radius) of inner cavity of the AOT-reversed micelles is determined by their hydration degree, i.e., [H2O]/[AOT] molar ratio, in the system. Owing to this, the dependence of hydrolytic, transpeptidation and autotranspeptidation activities of the enzyme on the hydration degree was investigated using L- and D-isomers of gamma-glutamyl(3-carboxy-4-nitro)anilide and glycylglycine as substrates. For all of the reaction types, the observed dependences are curves with three optima. The optima are found at the hydration degrees, [H2O]/[AOT] = 11, 17 and 26 when the inner cavity radii of reversed micelles are equal to the size of light (Mr 21,000) and heavy (Mr 54,000) subunits of gamma-glutamyltransferase, and to their dimer (Mr 75,000), respectively. Ultracentrifugation experiments showed that a change of the hydration degree resulted in a reversible dissociation of the enzyme to light and heavy subunits. The separation of light and heavy subunits of gamma-glutamyltransferase formed in reversed micelles was carried out and their catalytic properties were studied. The two subunits catalyze hydrolysis and transpeptidation reactions; autotranspeptidation reaction is detected only in the case of the heavy subunit. These findings imply that the reversed micelles of surfactants in organic solvents function as the matrices with adjustable size permitting to regulate the supramolecular structure and the catalytic activity of oligomeric enzymes.

The second E.C. Slater lecture. Micellar enzymology: its relation to membranology

Micellar enzymology, a new trend in molecular biology, studies catalysis by enzymes entrapped in hydrated reversed micelles composed of surfactants (phospholipids, detergents) in organic solvents. The key research problems of micellar enzymology and its relation to enzyme membranology are discussed.

Interaction of bovine skeletal muscle lactate dehydrogenase with liposomes. Comparison with the data for the heart enzyme

The effects of pH, salt concentration and the presence of oxidized and reduced forms of coenzyme on the interaction of skeletal muscle lactate dehydrogenase with the liposomes derived from the total fraction of bovine erythrocyte lipids were investigated by ultracentrifugation and were compared with those results obtained using the heart-rate isoenzyme which we have previously studied. Liposomes are good adsorptive systems for both types of isoenzyme. In the presence of erythrocyte lipid liposomes, bovine muscle and heart lactate dehydrogenases form two kinds of complex: lactate dehydrogenase adsorbed to liposomes and soluble lactate dehydrogenase-phospholipid complexes. Soluble protein-phospholipid complexes reveal different dependences of their stabilities on pH values and it seems that the nature of the binding site in either isozyme is different. In addition, absorption of the isoenzymes on the liposomes also reveals in difference in the effects of NAD and NADH. While the presence of NAD dissociates LDH-H4 from the liposomes and NADH does not influence its adsorption, NAD promotes the binding of LDH-M4, and NADH favors the dissociation.

Modulation of lactate dehydrogenase activity by enzyme-protein interaction

Some lactate dehydrogenase modulator proteins have been isolated from the lactate dehydrogenase-free crude mitochondrial fraction of rabbit muscle, beef liver and chicken liver. It was shown that beef and chicken liver mitochondrial extracts exhibited activatory capacity in contrast to the inhibitory capacity of rabbit muscle mitochondrial extracts. All modulators can be precipitated by 80% ammonium sulphate saturation and show high anodic electrophoretic mobility and heat stability. Modulators have higher affinity for alkaline pI lactate dehydrogenase isoenzymes, independent of whether the M and H subunits are predominant. The inhibitor and the activator molecules compete for lactate dehydrogenase since their modulatory capacity was nullified when similar relative amounts were used. This study shows the existence of analogous proteins with an acidic pI in the different mitochondrial fractions which modify lactate dehydrogenase activity.

Transient-time analysis of substrate-channelling in interacting enzyme systems

The kinetics of dynamically interacting enzyme systems is examined, in the light of increasing evidence attesting to the widespread occurrence of this mode of organization in vivo. The transient time, a key phenomenological parameter for the coupled reaction, is expressed as a function of the lifetime of the intermediate substrate. The relationships between the transient time and the pseudo-first-order rate constants for the coupled reaction by the complexed and uncomplexed enzyme species are indicative of the mechanism of intermediate transfer ('channelling'). In a dynamically interacting enzyme system these kinetic parameters are composite functions of those for the processes catalysed by the complex and by the separated enzymes. The mathematical paradigm can be extended to a linear sequence of N coupled reactions catalysed by dynamically (pair-wise) interacting enzymes.

Pyruvate kinase type M2 is phosphorylated at tyrosine residues in cells transformed by Rous sarcoma virus

Chicken embryo cells (CECs) contain pyruvate kinase (PK) type M2 (M2-PK). Transformation of CECs by Rous sarcoma virus (RSV) leads to a reduction in the affinity of PK for the substrate phosphoenolpyruvate. In vitro, M2-PK can be phosphorylated at tyrosine residues by pp60v-src, the transforming protein of RSV. To study tyrosine phosphorylation of M2-PK in intact RSV-transformed cells, the protein was immunoprecipitated from 32P-labeled normal and RSV-SR-A-transformed CECs. Phosphoamino acid analysis of immunoprecipitated M2-PK revealed that M2-PK of both normal and transformed CECs contained phosphoserine and small amounts of phosphothreonine. Only M2-PK of transformed CECs contained phosphotyrosine in addition. For enzyme kinetic studies M2-PK was partially purified by chromatography upon DEAE-Sephacel and hydroxyapatite. A decreased affinity for phosphoenolpyruvate was observed 3 h after the onset of transformation using the temperature-sensitive mutant of RSV, ts-NY 68. The kinetic changes were correlated with tyrosine phosphorylation of M2-PK, but there is no direct evidence that they are caused by post-translational modification of the enzyme.

The perfection of substrate-channelling in interacting enzyme systems: energetics and evolution

Some implications of substrate channelling in interacting enzyme systems are considered, with regard to the energetics and evolution of enzyme action. The transient time, a key analytical parameter relating to the phenomenon of channelling, is the basis of our kinetic study. Bounds on the kinetics of multienzyme complexes are established using (apparent) rate constants emanating from the transient-time formulation of coupled reactions. From a transition state representation of the rate process, it is shown how dynamically and statically organized enzyme systems lead to the modification of current ideas on the evolutionary optimization of the energy profile of enzyme catalysis in situ.

Organization of soluble enzymes in the cell. Relay at the surface

A model is proposed uniting two groups of facts: the adsorption of enzymes on subcellular structures and the direct ('from hand to hand') transfer of metabolites between enzymes. The basic idea is that the binding of metabolites (substrates and/or products) results in desorption of the enzymes from subcellular structures during each catalytic act. This makes the enzymes mobile and capable of directly (from hand to hand) transferring metabolites to other enzymes adsorbed on subcellular structures. The model leads to a mechanism by means of which soluble enzymes can be compartmentalized in defined regions of the cytoplasm.

Aldolase exists in both the fluid and solid phases of cytoplasm

We have prepared a functional fluorescent analogue of the glycolytic enzyme aldolase (rhodamine [Rh]-aldolase), using the succinimidyl ester of carboxytetramethyl-rhodamine. Fluorescence redistribution after photobleaching measurements of the diffusion coefficient of Rh-aldolase in aqueous solutions gave a value of 4.7 x 10(-7) cm2/S, and no immobile fraction. In the presence of filamentous actin, there was a 4.5-fold reduction in diffusion coefficient, as well as a 36% immobile fraction, demonstrating binding of Rh-aldolase to actin. However, in the presence of a 100-fold molar excess of its substrate, fructose 1,6-diphosphate, both the mobile fraction and diffusion coefficient of Rh-aldolase returned to control levels, indicating competition between substrate binding and actin cross-linking. When Rh-aldolase was microinjected into Swiss 3T3 cells, a relatively uniform intracellular distribution of fluorescence was observed. However, there were significant spatial differences in the in vivo diffusion coefficient and mobile fraction of Rh-aldolase measured with fluorescence redistribution after photobleaching. In the perinuclear region, we measured an apparent cytoplasmic diffusion coefficient of 1.1 x 10(-7) cm2/s with a 23% immobile fraction; while measurements in the cell periphery gave a value of 5.7 x 10(-8) cm2/s, with no immobile fraction. Ratio imaging of Rh-aldolase and FITC-dextran indicated that FITC-dextran was relatively excluded excluded from stress fiber domains. We interpret these data as evidence for the partitioning of aldolase between a soluble fraction in the fluid phase and a fraction associated with the solid phase of cytoplasm. The partitioning of aldolase and other glycolytic enzymes between the fluid and solid phases of cytoplasm could play a fundamental role in the control of glycolysis, the organization of cytoplasm, and cell motility. The concepts and experimental approaches described in this study can be applied to other cellular biochemical processes.

Theoretical analysis of compartmented coupling in linear enzyme systems

Exact equations which describe the kinetic patterns of enzyme/enzyme complexes, when compartmented coupling occurs between them, are presented. Compartmented coupling refers to the creation of a local environment in which the concentration of an intermediate, shared by two enzymes, is higher than its solution concentration. This results in a higher coupling enzyme activity, a condition reflected in a shorter transition time for the system. In this paper, equations are presented which allow experimenters to quantitate the effect of compartmented coupling in terms of changes in the apparent Km and Vmax values. The equations presented in this paper are more exact than those previously derived since they do not incorporate first order assumptions before derivation.

The control of cell metabolism for homogeneous vs. heterogeneous enzyme systems

Metabolic control theories, based on such parameters as "elasticity coefficients" and "flux-control coefficients", have emerged in recent years. These offer a potentially unifying, holistic paradigm for understanding the regulation of cell metabolism. Much of the foundation relies on the supposition that the system is a homogeneous bulk-phase solution of individual enzymes. We examine some of the tenets of such theories, in the light of increasing knowledge of enzyme organization in vivo. We cast the control parameters into a more general form applicable to the linear kinetic regime, using a newly defined unit--the kinetic power, which allows complete specification in terms of any and all factors which bear upon the conversion of free substrate to free product in situ. Extending the control theory to heterogeneous states of enzyme organization, we make a formal distinction between "solution connectivity" and "structural connectivity" in a multienzyme system. The use of "structural" rate expressions leads to the definition of a flux-control coefficient which specifies the interdependence of the individual rate processes in an organized system. The problems and limitations in applying the control theory to experimental analysis of real systems in situ are discussed. "We have arrived at last at a point which comes rather close to what might be defined as 'molecular control of cellular activity', only to discover that the 'controlling' molecules have themselves acquired their specific configurations, which are the key to their power of control, by virtue of their membership in the population of an organized cell, hence under 'cellular control'." (Weiss, 1963).

Interactions of actin and tubulin with human deoxyhemoglobin. Their possible occurrence within erythrocytes

Short actin filaments are an essential component of the red-cell membrane skeleton, and microtubules are also present in nucleated erythrocytes as a marginal band. Actin and tubulin share the property of possessing a very anionic terminal peptide. Since deoxyhemoglobin (Hb) is known to be a strong polyanion-binding protein, we have considered how it may interact with actin and tubulin within the intact cell. Here we demonstrate that actin and tubulin form in vitro a high-affinity complex with Hb. This is shown by measuring, by stopped-flow experiments, the decrease of the binding rate constant of CO to Hb in the presence of increasing amounts of actin and tubulin. One tetramer of Hb is bound by an actin monomer, and about two tetramers by an alpha, beta-tubulin heterodimer. Binding assays in batch experiments with immobilized tubulin give the same stoichiometry. Formation of the complexes involves the 2,3-bisphosphoglycerate-binding site of Hb and a negatively charged domain, most likely the highly acidic N and C-terminal peptides of actin and tubulin. In addition to providing new opportunities to study the structural and functional properties of actin and tubulin, these results support the idea that in the case of partial metabolic depletion of bisphosphoglycerate and ATP in erythrocytes, Hb may interact with oligomeric actin and tubulin present in the cytoskeleton.

Hemoglobin-membrane interaction at physiological ionic strength and temperature

The spin-label electron paramagnetic resonance (EPR) technique has been used to study the interaction between human hemoglobin and erythrocyte membranes as a function of temperature and ionic strength. We show, for the first time, experimental evidence for the existence of the interaction at physiological pH, ionic strength and temperature. In addition to the pH dependence that we have previously reported, the interactions are also temperature and ionic strength dependent. Using a simple two-state equilibrium model to analyze the EPR data, we obtain an equilibrium dissociation constant of about 8.1 +/- 5.6 X 10(-5) M for hemoglobin-membrane systems in 5 mM phosphate with 150 mM NaCl at pH 7.4 and 37 degrees C.

Linear relationships between mitochondrial forces and cytoplasmic flows argue for the organized energy-coupled nature of cellular metabolism

We have studied rates of formation of glucose, urea and lactate by isolated hepatocytes incubated with a variety of inhibitors of energy transduction. Linear relationships have been found between these metabolic rates and mitochondrial forces (membrane, redox and phosphorylation potentials). The findings are suggestive of extensive enzyme organization within these metabolic pathways.

Lactate and malate dehydrogenase binding to the microsomal fraction from chicken liver

Chicken liver microsomal fractions show lactate and malate dehydrogenase activities which behave differently with respect to successive extractions by sonication in 0.15 M NaCl, 0.2% Triton X-100 and 0.15 M NaCl, respectively. The Triton X-100-treated pellet did not show malate dehydrogenase activity but exhibited a 10-fold increase in lactate dehydrogenase activity with respect to the sonicated pellet. Total extracted lactate and malate dehydrogenase activities were, respectively, 7.5 and 1.7 times higher than that in the initial pellet. Different isoenzyme compositions were observed for cytosoluble and microsomal extracted lactate and malate dehydrogenases. When the ionic strength (0-500 mM) or the pH values (6.1-8.7) of the media were increased, an efficient release of lactate dehydrogenase was found at NaCl 30-70 mM and pH 6.6-7.3. Malate dehydrogenase solubilization under the same conditions was very small, even at NaCl 500 mM, but it attained a maximum in the 7.3-8.7 pH range. Cytosoluble lactate dehydrogenase bound in vitro to 0.15 M NaCl-treated (M2) and sonicated (M3) microsomal fractions but not to the crude microsomal fraction (M1). Particle saturation by lactate dehydrogenase occurred with M2 and M3, which contained binding sites with different affinities. Cytosoluble malate dehydrogenase did not bind to M1, M2 and M3 fractions, however, a little binding was found when purified basic malate dehydrogenase was incubated with M2 or M3 fractions.

Glycolysis--new concepts in an old pathway

A survey of the existing data on the interactions of glycolytic enzymes with the cellular structure in mammalian tissues has substantiated the occurrence of an extensive degree of such associations in all tissues and during all stages of development. Furthermore, a considerable specificity was evident between the individual multiple forms of the enzymes in relation to these associations. In reviewing these data, a model has been developed which proposes that the glycolytic sequence is best described as consisting of a number of segments in vivo, each segment formed by a cluster of isozymes, many of which can interact with the actin containing filaments of the cytomatrix. The novel features of this segmentation and compartmentation have been described, and evidence has been provided that these phenomena collectively play a key role in meeting the different types of energy requirement in the cytoplasm of divergent cell types, with the wide selection of isozymes in this system offering the potential for increased flexibility and control in this important area of metabolism.

A simple approach to detect active-site-directed enzyme-enzyme interactions. The aldolase/glycerol-phosphate-dehydrogenase enzyme system

A novel approach has been elaborated to identify the mechanism of intermediate transfer in interacting enzyme systems. The aldolase/glycerol-3-phosphate-dehydrogenase enzyme system was investigated since complex formation between these two enzymes had been demonstrated. The kinetics of dihydroxyacetone phosphate conversion catalyzed by the dehydrogenase in the absence and presence of aldolase was analyzed. It was found that the second-order rate constant (kcat/Km) of the enzymatic reaction decreases due to the formation of a heterologous complex. The decrease could be attributed to an increase of the Km value since kcat did not change in the presence of aldolase. In contrast, an apparent increase in the second-order rate constant of dihydroxyacetone phosphate conversion by the dehydrogenase was observed if the triose phosphate was produced by aldolase from fructose 1,6-bisphosphate (consecutive reaction). Moreover, no effect of dihydroxyacetone phosphate on the dissociation constant of the heterologous enzyme complex could be detected by physico-chemical methods. The results suggest that the endogenous dihydroxyacetone phosphate produced by aldolase complexed with dehydrogenase is more accessible for the dehydrogenase than the exogenous one, the binding of which is impeded due to steric hindrance by bound aldolase.

Correlation among endothelial cell shape, F-actin arrangement, and prostacyclin synthesis

Though many factors have been identified which modulate prostacyclin (PGI2) synthesis, there is little information on cellular mechanisms whereby endothelial cells (EC) regulate their basal eicosanoid metabolism. Using substrates of various adhesive capacities, bovine and porcine aortic EC shape and cytoskeletal F-actin arrangement could be modulated. Staining with rhodamine-phalloidin (R-P) permitted analysis of F-actin arrangement, while differences in cell shape were determined by measurement of cell perimeter surface area (CPSA). Spectrophotoflurometric measurements were used to quantitate the R-P binding capacity of the cultures. Cultures of reduced CPSA (225.2 +/- 13.5 mu2) generated the highest levels of basal PGl2 (6.14 +/- 0.51 pg/ug cell protein); had a diffuse arrangement of F-actin and an increased binding capacity for R-P (463.55 +/- 50.58 nmoles/ug cell protein). Cultures of enlarged CPSA (1399.3 +/- 148.3 mu2), with many actin cables and a significantly reduced (p less than 0.001) R-P binding capacity (74.941 +/- 11.79 nmoles/ug of cell protein) produced significantly smaller (p less than 0.001) basal quantities of PGl2 (1.33 +/- 0.14 pg/ug cell protein). Similarly, arachidonic acid stimulation of cultures of reduced CPSA resulted in an increased synthesis of PGl2 when compared to stimulated cultures of enlarged cells. These findings suggest a role for cell shape and the cytoskeleton in the mechanism controlling PGl2 production and indicate that alteration of the arrangement of F-actin may be of importance in regulation of EC eicosanoid metabolism.

Abnormal subcellular distribution of beta-glucuronidase in mice with a genetic alteration in enzyme structure

Liver beta-glucuronidase is structurally altered in inbred strain PAC so that a peptide subunit with a more basic isoelectric point, GUS-SN, is produced. This allele of beta-glucuronidase was transferred to strain C57BL/6J by 12 backcross matings to form the congenic line B6 X PAC-Gus(n). Liver beta-glucuronidase activity was halved in males of the congenic strain compared to normal males. The lowered activity was specifically accounted for by a decrease in the lysosomal component. There was no alteration in the concentration of microsomal activity. This alteration in the subcellular distribution of beta-glucuronidase in Gus(n)/Gus(n) mice was confirmed by two independent gel electrophoretic systems which separate microsomal and lysosomal components. beta-Glucuronidase activity was likewise approximately halved in mutant spleen, lung, and brain, organs which contain exclusively or predominantly lysosomal beta-glucuronidase. The loss of liver lysosomal beta-glucuronidase activity was shown by immunotitration to be due to a decrease in the number of beta-glucuronidase molecules in lysosomes of the congenic strain. The Gus(n) structural alteration likely causes the lowered lysosomal beta-glucuronidase activity since the two traits remain in congenic animals. Heterozygous Gus(n)/Gus(b) animals had intermediate levels of liver beta-glucuronidase. Also, the effect was specific, in that three other lysosomal enzymes were not reproducibly lower in Gus(n)/Gus(n) mice. Gus(n) is, therefore, an unusual example of a mutation which causes a change in the subcellular distribution of a two-site enzyme.

Localization of binding sites of F-protein (phosphofructokinase) on the myosin molecule

To determine the location of F-protein binding sites on myosin, the interaction of F-protein with myosin and its proteolytic fragments in 0.1 M KCl, 10 mM potassium phosphate, pH 6.5, has been investigated using sedimentation, electron microscopy and optical diffraction methods. Sedimentation experiments show that F-protein can bind to myosin and myosin rod rather than to light meromyosin or subfragment-1. The F-protein binding to myosin and rod is of a similar character. The calculated values of the constants of F-protein binding to myosin and rod are 2.6 X 10(5) M-1 and 2.1 X 10(5) M-1, respectively. The binding sites are probably located on the subfragment-2 portion of the myosin molecule. The number of the F-protein binding sites calculated per chain weight of 80,000 is 5 +/- 1. Electron microscopic observations confirm the sedimentation results. F-protein does not bind to light meromyosin paracrystals, but decorates myosin and rod filaments with the interval of 14.3 nm regardless of whether F-protein is added prior to or after filamentogenesis. The comparison of optical diffraction patterns obtained from myosin and rod filaments with those from decorated ones reveals the marked enhancement of meridional reflection at (14.3 nm)-1 in the latter case. Neither the increase in ionic strength from 0.1 to 0.15 and pH from 6.5 to 7.3 nor substitution of potassium phosphate buffer by imidazole-HCl buffer, or Tris-HCl influences F-protein binding to myosin and rod filaments as visualized by electron microscopy. The possible significance of F-protein location in the thick filament structure is discussed.

Regulation of glucose-6-phosphate dehydrogenase activity in sea urchin eggs by reversible association with cell structural elements

In unfertilized eggs of the sea urchin, Strongylocentrotus purpuratus, glucose-6-phosphate dehydrogenase (G6PDH) associates with the particulate elements remaining either after homogenization or extraction of eggs with non-ionic detergent in low ionic-strength media. At physiological ionic strength, the extent of G6PDH binding to these particulate elements is proportional to the total protein concentration in the extracts. In fertilized eggs this association is prevented by one or more low molecular weight solutes. The dissociation is reversible, and there are no permanent modifications of either G6PDH or its particulate binding site that affect binding. After fertilization, the time course of dissociation of G6PDH from particulate elements is too fast to be caused by a change in intracellular pH, but it could be triggered, but not maintained, by an increase in the intracellular calcium concentration. Binding of G6PDH to the particulate fraction lowers its catalytic activity at all substrate concentrations. Therefore, release of the enzyme into the cytoplasm may be an important part of the suite of events causing metabolic activation of the egg at fertilization.

On the ontogeny and interactions of glyceraldehyde-3-phosphate dehydrogenase

The interaction of GAPDH with cellular structure has been studied in the major tissues of the mouse during development. Overall the data provides a clear indication that interactions between GAPDH and cellular structure are appreciable in all major tissues, at least during early stages of development, and an analysis of the isozyme status of the enzyme in both soluble and bound compartments for all tissues at all developmental stages indicates the presence of only a single GAPDH isozyme in the mouse. Possible reasons for the lack of an extensive multiplicity of this enzyme in mammalian tissues (the only tetrameric glycolytic enzyme to display this restriction) and for the large amounts of GAPDH in many cell types are discussed in relation to the large number of proteins that GAPDH interacts with in the cell.

Catalytic facilitation by diffusion of adsorbed substrate on membrane surface

Membrane-alkaline phosphatase shows greater velocity of reaction than solubilized enzyme at low substrate concentration, whereas at saturation-concentration the opposite is true. The catalytic rate enhancement with the membrane-enzyme, when substrate availability is limiting, is attributed to non-specific adsorption of substrate to the membrane followed by its surface-diffusion to the active site resulting in an enhanced collision rate for the substrate with the enzyme. Experimental evidence for the adsorption-diffusion is provided by the dynamic quenching of 1-anilino-naphthalene-8-sulphonate, a membrane-bound probe's fluorescence by the substrate, 4-nitrophenyl-phosphate.