Hydrophobic interaction between the monomer of mitochondrial malate dehydrogenase and phospholipid membranes.

Porcine mitochondrial malate dehydrogenase (EC 1.1.1.37) dissociates into subunits on dilution. The enzyme monomer caused large increases in the surface pressure of monolayers of 1:1 phosphatidylserine/phosphatidylcholine at air/water and oil/water interfaces. The monomer increased the permeability of phospholipid vesicles to 22Na+. Both effects were significantly greater than the corresponding effects of ribonuclease A, cytochrome c and the dimeric form of malate dehydrogenase. Changes in the circular-dichroism spectra of the enzyme indicated that conformational changes may be associated with dimer formation or when monomer interacts with lysophosphatidyl-choline. Similar interactions to those described may occur in situ when mitochondrial malate dehydrogenase is transported to the mitochondrial matrix from its site of synthesis on cytosolic ribosomes.     

Resistance of tropoelastin and elastin peptides to degradation by alpha 2-macroglobulin-protease complexes

When α-ketoglutarate is the substrate, malate is a considerably more effective inhibitor of glutamate dehydrogenase than glutamate, oxalacetate, aspartate, or glutarate. Malate is a considerably poorer inhibitor when glutamate is the substrate. Malate is competitive with α-ketoglutarate, uncompetitive with TPNH, and noncompetitive with glutamate. The above, plus the fact that malate is a considerably more potent inhibitor when TPNH rather than TPN is the coenzyme, indicates that malate is predominantly bound to the α-ketoglutarate site of the enzyme-TPNH complex and has a considerably lower affinity for the enzyme-TPN complex. Ligands which decrease binding of TPNH to the enzyme such as ADP and leucine markedly decrease inhibition by malate. Conversely, GTP, which increases binding of TPNH to the enzyme also enhances inhibition by malate. Malate also decreases interaction between mitochondrial aspartate aminotransferase and glutamate dehydrogenase. This effect of malate on enzyme-enzyme interaction is enhanced by DPNH and GTP which also increase inhibition of glutamate dehydrogenase by malate and is decreased by TPN, ADP, ATP, α-ketoglutarate, and leucine which decrease inhibition of glutamate dehydrogenase by malate. These results indicate that malate could decrease α-ketoglutarate utilization by inhibiting glutamate dehydrogenase and retarding transfer of α-ketoglutarate from the aminotransferase to glutamate dehydrogenase. These effects of malate would be most pronounced when the mitochondrial level of α-ketoglutarate is low and the level of malate and reduced pyridine nucleotide is high.     

Interaction of d-β-hydroxybutyrate dehydrogenase with lecithin vesicles

Rat liver mitochondrial d-β-hydroxybutyrate dehydrogenase has an absolute requirement for lecithin. The nature of the interaction between the enzyme and phospholipid has been investigated. Single bilayer lecithin liposomes of shell-like structure bring about maximal enzyme activation, whereas the interaction with larger vesicles leads to enzyme inactivation. The strong binding of the enzyme to lecithin confers great stability to the enzyme activity as compared with the nonlipid-activated enzyme, and permits the isolation of a lipoprotein complex by chromatography on Sephadex G-200. Only 20% of the proteins solubilized with d-β-hydroxybutyrate dehydrogenase from mitochondrial membranes bind to lecithin liposomes, thus a 5-fold purification of the enzyme is achieved. The liposome-bound proteins had a significantly lower polarity than the remaining 80% of solubilized mitochondrial membrane proteins.     

Interaction between citrate synthase and mitochondrial malate dehydrogenase in the presence of polyethylene glycol

Pig heart citrate synthase and mitochondrial malate dehydrogenase interact in polyethylene glycol solutions as indicated by increased solution turbidity. A large percentage of both enzymes sediments when mixtures of the two in polyethylene glycol are centrifuged, whereas little if any of either enzyme sediments in the absence of the other. The observed interaction is highly specific in that neither cytosolic malate dehydrogenase nor nine other proteins showed evidence of specific interaction with either pig heart citrate synthase or mitochondrial malate dehydrogenase. Escherichia coli citrate synthase did not interact with pig heart citrate synthase, but did show evidence of interaction with pig heart mitochondrial malate dehydrogenase. The relation between enzyme behavior in polyethylene glycol solution and in the mitochondrion and the significance of possible in vivo interactions between citrate synthase and mitochondrial malate dehydrogenase are discussed.     

The three-dimensional structure of porcine heart mitochondrial malate dehydrogenase at 3.0-A resolution

In a previous study, we reported the apparent similarity between a low resolution electron density map of mitochondrial malate dehydrogenase and a model of cytoplasmic malate dehydrogenase (Roderick, S. L., and Banaszak, L. J. (1983) J. Biol. Chem. 258, 11636-11642). We have since determined the polypeptide chain conformation and coenzyme binding site of crystalline porcine heart mitochondrial malate dehydrogenase by x-ray diffraction methods. The crystals from which the diffraction data was obtained contain four subunits of the enzyme arranged as a "dimer of dimers," resulting in a crystalline tetramer which possesses 222 molecular symmetry. The overall polypeptide chain conformation of the enzyme, the location of the coenzyme binding site, and the preliminary location of several catalytically important residues have confirmed the structural similarity of mitochondrial malate dehydrogenase to cytoplasmic malate dehydrogenase and lactate dehydrogenase.     

Substrate channeling of NADH and binding of dehydrogenases to complex I

The binding of porcine heart mitochondrial malate dehydrogenase and beta-hydroxyacyl-CoA dehydrogenase to bovine heart NADH:ubiquinone oxidoreductase (complex I), but not that of bovine heart alpha-ketoglutarate dehydrogenase complex, is virtually abolished by 0.1 mM NADH. The malate dehydrogenase and beta-hydroxyacyl-CoA enzymes compete in part for the same binding site(s) on complex I as do the malate dehydrogenase and alpha-ketoglutarate dehydrogenase complex enzymes. Associations between mitochondrial malate dehydrogenase and bovine serum albumin were observed. Subtle convection artifacts in short-time centrifugation tests of enzyme association with the Beckman Airfuge are described. Substrate channeling of NADH from both the mitochondrial and cytoplasmic malate dehydrogenase isozymes to complex I and reduction of ubiquinone-1 were shown to occur in vitro by transient enzyme-enzyme complex formation. Excess apoenzyme causes little inhibition of the substrate channeling reaction with both malate dehydrogenase isozymes in spite of tighter equilibrium binding than the holoenzyme to complex I. This substrate channeling could, in principle, provide a dynamic microcompartmentation of mitochondrial NADH.     

Regulation of mitochondrial malate dehydrogenase: kinetic modulation independent of subunit interaction

Porcine heart mitochondrial malate dehydrogenase (EC 1.1.1.37), a dimeric enzyme of Mr = 70,000, is both allosterically activated and inhibited by citrate. Using an affinity elution procedure based upon citrate binding to malate dehydrogenase, the isolation of pure heterodimer (a dimeric species with one active subunit and one iodoacetamide-inactivated subunit) has been achieved. Investigations utilizing this heterodimer in conjunction with resin-bound monomers of malate dehydrogenase have allowed the formulation of a definite conclusion concerning the role of subunit interactions in catalysis and regulation of this enzyme. The citrate kinetic effects, oxaloacetate inhibition, malate activation, and the effects of 2-thenoyl-trifluoroacetone (TTFA) are shown to be independent of interaction between catalytically active subunits. Previous kinetic data thought to support a reciprocating catalytic mechanism for this enzyme may be reinterpreted upon closer analysis in relation to an allosteric, conformationally specific binding model for malate dehydrogenase.     

Effect of thiol reagents on the activity of NADP-dependent malate dehydrogenase isolated from bovine adrenal cortex cytoplasm

NADP-dependent malate dehydrogenase was rapidly inactivated in the presence of mercurous chloride. Titration of malate dehydrogenase by 5,5'-dithiobis (2-nitrobenzoic acid) (DTNB) in a solution of 8 M urea revealed 18 SH groups per molecule of the enzyme. Eight sulphydryl groups reacted with DTNB in native malate dehydrogenase and their modification was not accompanied by a loss of the enzyme activity. The interaction of p-chloromercury benzoate (PCMB) with malate dehydrogenase resulted in a 70% decrease in the enzyme activity. The binding of the thiol reagents by the malate dehydrogenase molecule appreciably increased the Michaelis constant value for the substrate. In the presence of magnesium ions, NADP and malate did not affect the process of malate dehydrogenase modification by DTNB and did not protect the enzyme from the inactivation by PCMB. It is suggested from the data obtained that the sulphyryl groups are involved in maintaining the active conformation of the enzyme.     

The interaction of yeast citrate synthase with yeast mitochondrial inner membranes

The specific interaction of yeast citrate synthase with yeast mitochondrial inner membranes was characterized with respect to saturability of binding, pH optimum, effect of ionic strength, temperature response, and inhibition by oxalacetate. The binding ability of the inner membranes is inhibited by proteolysis and heat treatment, which implies that the membrane component(s) responsible for binding is a protein. A protein fraction from inner membranes when added to liposomes will bind citrate synthase. In addition, the binding of yeast fumarase, mitochondrial malate dehydrogenase, and cytosolic malate dehydrogenase to yeast inner membranes was examined. For these studies the yeast mitochondrial matrix enzymes, citrate synthase (from two types of yeast), malate dehydrogenase, and fumarase, as well as cytosolic malate dehydrogenase, were purified using rapid new techniques.     

Binding of mitochondrial malate dehydrogenase to mitoplasts.

The binding of 14C-labelled bovine and porcine malate dehydrogenase (EC 1.1.1.37) to rat liver mitochondria and mitoplasts was examined. The bovine enzyme was found to associate nonspecifically with isolated mitochondria and sonicated mitoplasts. Scatchard plot analysis suggested a specific binding to mitoplasts of the order of 5 pmol malate dehydrogenase per milligram of mitoplast protein. Porcine malate dehydrogenase dimer but not monomer exhibited a similar binding. The results are discussed in relation to the mechanism of uptake of the enzyme by mitochondria after synthesis on cytosolic ribosomes.     

Regulation of aminotransferase-glutamate dehydrogenase interactions by carbamyl phosphate synthase-I, Mg2+ plus leucine versus citrate and malate

Citrate, malate, and high levels of ATP dissociate the mitochondrial aspartate aminotransferase-glutamate dehydrogenase complex and have an inhibitory effect on the latter enzyme. These effects are opposed by Mg2+, leucine, Mg2+ plus ATP, and carbamyl phosphate synthase-I. In addition, Mg2+ directly facilitates formation of a complex between glutamate dehydrogenase and the aminotransferase and displaces the aminotransferase from the inner mitochondrial membrane which could enable it to interact with glutamate dehydrogenase in the matrix. Zn2+ also favors an aminotransferase-glutamate dehydrogenase complex. It, however, is a potent inhibitor of and has a high affinity for glutamate dehydrogenase. Leucine, however, enhances binding of Mg2+ and decreases binding of and the effect of Zn2+ on the enzyme. Thus, since both metal ions enhance enzyme-enzyme interaction and Zn2+ is a more potent inhibitor, the addition of leucine in the presence of both metal ions results in activation of glutamate dehydrogenase without disruption of the enzyme-enzyme complex. Furthermore, the combination of leucine plus Mg2+ produces slightly more activation than leucine alone. These results indicate that leucine, carbamyl phosphate synthase-I, and its substrate and cofactor, ATP and Mg2+, operate synergistically to facilitate glutamate dehydrogenase activity and interaction between this enzyme and the aminotransferase. Alternatively, Krebs cycle intermediates, such as citrate and malate, have opposing effects.     

Crystal structure of Escherichia coli malate dehydrogenase. A complex of the apoenzyme and citrate at 1.87 A resolution.

The crystal structure of malate dehydrogenase from Escherichia coli has been determined with a resulting R-factor of 0.187 for X-ray data from 8.0 to 1.87 A. Molecular replacement, using the partially refined structure of porcine mitochondrial malate dehydrogenase as a probe, provided initial phases. The structure of this prokaryotic enzyme is closely homologous with the mitochondrial enzyme but somewhat less similar to cytosolic malate dehydrogenase from eukaryotes. However, all three enzymes are dimeric and form the subunit-subunit interface through similar surface regions. A citrate ion, found in the active site, helps define the residues involved in substrate binding and catalysis. Two arginine residues, R81 and R153, interacting with the citrate are believed to confer substrate specificity. The hydroxyl of the citrate is hydrogen-bonded to a histidine, H177, and similar interactions could be assigned to a bound malate or oxaloacetate. Histidine 177 is also hydrogen-bonded to an aspartate, D150, to form a classic His.Asp pair. Studies of the active site cavity indicate that the bound citrate would occupy part of the site needed for the coenzyme. In a model building study, the cofactor, NAD, was placed into the coenzyme site which exists when the citrate was converted to malate and crystallographic water molecules removed. This hypothetical model of a ternary complex was energy minimized for comparison with the structure of the binary complex of porcine cytosolic malate dehydrogenase. Many residues involved in cofactor binding in the minimized E. coli malate dehydrogenase structure are homologous to coenzyme binding residues in cytosolic malate dehydrogenase. In the energy minimized structure of the ternary complex, the C-4 atom of NAD is in van der Waals' contact with the C-3 atom of the malate. A catalytic cycle involves hydride transfer between these two atoms.     

(R)-3-hydroxybutyrate dehydrogenase: selective phosphatidylcholine binding by the C-terminal domain

(R)-3-Hydroxybutyrate dehydrogenase (BDH) is a lipid-requiring mitochondrial enzyme that has a specific requirement of phosphatidylcholine (PC) for function. The C-terminal domain (CTBDH) of human heart BDH (residues 195-297) has now been expressed in Escherichia coli as a chimera with a soluble protein, glutathione S-transferase (GST), yielding GST-CTBDH, a novel fusion protein that has been purified and shown to selectively bind to PC vesicles. Both recombinant human heart BDH (HH-Histag-BDH) and GST-CTBDH (but not GST) form well-defined protein-lipid complexes with either PC or phosphatidylethanolamine (PE)/diphosphatidylglycerol (DPG) vesicles (but not with digalactosyl diglyceride vesicles) as demonstrated by flotation in sucrose gradients. The protein-PC complexes are stable to 0.5 M NaCl, but complexes of either HH-Histag-BDH or GST-CTBDH with PE/DPG vesicles are dissociated by salt treatment. Thrombin cleavage of GST-CTBDH, either before or after reconstitution with PC vesicles, yields CTBDH (12 111 Da by MALDI mass spectrometry) which retains lipid binding without attached GST. The BDH activator, 1-palmitoyl-2-(1-pyrenyl)decanoyl-PC (pyrenyl-PC), at <2.5% of total phospholipid in vesicles, efficiently quenches a fraction (0.36 and 0.47, respectively) of the tryptophan fluorescence of both HH-Histag-BDH and GST-CTBDH with effective Stern-Volmer quenching constants, (K(Q))(eff), of 11 and 9.3 (%)(-)(1), respectively (half-maximal quenching at approximately 0.1% pyrenyl-PC). Maximal quenching by pyrenyl-PC obtains at approximately stoichiometric pyrenyl-PC to protein ratios, reflecting high-affinity interaction of pyrenyl-PC with both HH-Histag-BDH and GST-CTBDH. The analogous pyrenyl-PE effects a similar maximal quenching of tryptophan fluorescence for both proteins but with approximately 15-fold lower (K(Q))(eff) (half-maximal quenching at approximately 1.5% pyrenyl-PE) referable to nonspecific interaction of pyrenyl-PE with HH-Histag-BDH or GST-CTBDH. Thus, the 103-residue CTBDH constitutes a PC-selective lipid binding domain of the PC-requiring BDH.     

The role of the superoxide anion in the xanthine oxidase-induced autoxidation of linoleic acid.

A fluorescent analogue, palmitoyl-?CoA was shown to have a fluorescence lifetime (19.5 nsec.), polarization and absorption and emission characteristics useful for studying interactions with enzymes and with model membranes. The fluorescence lifetime was found to be wavelength dependent. The analogue was a better inhibitor (50% inhibition at ～ 0.2 μM) than palmitoyl-CoA (50% inhibition at 0.5 μM) when bound to mitochondrial malate dehydrogenase (L-malate: NAD⁺ oxido reductase E.C.l.l.137). The fluorescence depolarization when bound to this enzyme was less than that observed for binding to bovine serum albumin suggesting some mobility of the chromophore while bound. The changes in polarization upon titration with phosphatidylcholine (egg) vesicles were consistent with a partition of palmitoyl-(1,N⁶etheno)CoA between vesicles and malate dehydrogenase. Such partition may have physiological consequences.     

Interaction of the membrane-bound D-lactate dehydrogenase of Escherichia coli with phospholipid vesicles and reconstitution of activity using a spin-labeled fatty acid as an electron acceptor: a magnetic resonance and biochemical study.

The interaction with phospholipid vesicles of the membrane-bound respiratory enzyme D-lactate dehydrogenase of Escherichia coli has been studied. Proteolytic digestion studies show that D-lactate dehydrogenase is protected from trypsin digestion to a larger extent when it interacts with phosphatidylglycerol than with phosphatidylcholine vesicles. Wild-type D-lactate dehydrogenase and mutants in which an additional tryptophan is substituted in selected areas by site-specific oligonucleotide-directed mutagenesis have been labeled with 5-fluorotryptophan. 19F nuclear magnetic resonance studies of the interaction of these labeled enzymes with small unilamellar phospholipid vesicles show that Trp 243, 340, and 361 are exposed to the lipid phase, while Trp 384, 407, and 567 are accessible to the external aqueous phase. Reconstitution of enzymatic activity in phospholipid vesicles has been studied by adding enzyme and substrate to phospholipid vesicles containing a spin-labeled fatty acid as an electron acceptor. The reduction of the doxyl group of the spin-labeled fatty acid has been monitored indirectly by nuclear magnetic resonance and directly by electron paramagnetic resonance. These results indicate that an artificial electron-transfer system can be created by mixing D-lactate dehydrogenase and D-lactate together with phospholipid vesicles containing spin-labeled fatty acids.     

Coenzyme binding by 3-hydroxybutyrate dehydrogenase, a lipid-requiring enzyme: lecithin acts as an allosteric modulator to enhance the affinity for coenzyme

The role of phospholipid in the binding of coenzyme, NAD(H), to 3-hydroxybutyrate dehydrogenase, a lipid-requiring membrane enzyme, has been studied with the ultrafiltration binding method, which we optimized to quantitate weak ligand binding (KD in the range 10-100 microM). 3-Hydroxybutyrate dehydrogenase has a specific requirement of phosphatidylcholine (PC) for optimal function and is a tetramer quantitated both for the apodehydrogenase, which is devoid of phospholipid, and for the enzyme reconstituted into phospholipid vesicles in either the presence or absence of PC. We find that (i) the stoichiometry for NADH and NAD binding is 0.5 mol/mol of enzyme monomer (2 mol/mol of tetramer); (ii) the dissociation constant for NADH binding is essentially the same for the enzyme reconstituted into the mixture of mitochondrial phospholipids (MPL) (KD = 15 +/- 3 microM) or into dioleoyl-PC (KD = 12 +/- 3 microM); (iii) the binding of NAD+ to the enzyme-MPL complex is more than an order of magnitude weaker than NADH binding (KD approximately 200 microM versus 15 microM) but can be enhanced by formation of a ternary complex with either 2-methylmalonate (apparent KD = 1.1 +/- 0.2 microM) or sulfite to form the NAD-SO3- adduct (KD = 0.5 +/- 0.1 microM); (iv) the binding stoichiometry for NADH is the same (0.5 mol/mol) for binary (NADH alone) and ternary complexes (NADH plus monomethyl malonate); (v) binding of NAD+ and NADH together totals 0.5 mol of NAD(H)/mol of enzyme monomer, i.e., two nucleotide binding sites per enzyme tetramer; and (vi) the binding of nucleotide to the enzyme reconstituted with phospholipid devoid of PC is weak, being detected only for the NAD+ plus 2-methylmalonate ternary complex (apparent KD approximately 50 microM or approximately 50-fold weaker binding than that for the same complex in the presence of PC). The binding of NADH by equilibrium dialysis or of spin-labeled analogues of NAD+ by EPR spectroscopy gave complementary results, indicating that the ultrafiltration studies approximated equilibrium conditions. In addition to specific binding of NAD(H) to 3-hydroxybutyrate dehydrogenase, we find significant binding of NAD(H) to phospholipid vesicles. An important new finding is that the nucleotide binding site is present in 3-hydroxybutyrate dehydrogenase in the absence of activating phospholipid since (a) NAD+, as the ternary complex with 2-methylmalonate, binds to the enzyme reconstituted with phospholipid devoid of PC and (b) the apodehydrogenase, devoid of phospholipid, binds NADH or NAD-SO3- weakly (half-maximal binding at approximately 75 microM NAD-SO3- and somewhat weaker binding for NADH).(ABSTRACT TRUNCATED AT 400 WORDS)     

Kinetic studies of the uptake of aspartate aminotransferase and malate dehydrogenase into mitochondria in vitro.

Kinetic measurements of the uptake of native mitochondrial aspartate aminotransferase and malate dehydrogenase into mitochondria in vitro were carried out. The uptake of both the enzymes is essentially complete in 1 min and shows saturation characteristics. The rate of uptake of aspartate aminotransferase into mitochondria is decreased by malate dehydrogenase, and vice versa. The inhibition is exerted by isoenzyme remaining outside the mitochondria rather than by isoenzyme that has been imported. The thiol compound beta-mercaptoethanol decreases the rate of uptake of the tested enzymes; inhibition is a result of interaction of beta-mercaptoethanol with the mitochondria and not with the enzymes themselves. The rate of uptake of aspartate aminotransferase is inhibited non-competitively by malate dehydrogenase, but competitively by beta-mercaptoethanol. The rate of uptake of malate dehydrogenase is inhibited non-competitively by aspartate aminotransferase and by beta-mercaptoethanol. beta-Mercaptoethanol prevents the inhibition of the rate of uptake of malate dehydrogenase by aspartate aminotransferase. These results are interpreted in terms of a model system in which the two isoenzymes have separate but interacting binding sites within a receptor in the mitochondrial membrane system.     

Schistosoma mansoni: antigenic characterization of malate dehydrogenase isoenzymes and use in the defined antigen substrate spheres (DASS) system.

Immunoelectrophoresis of Schistosoma mansoni homogenates against mouse antisera resulted in only one precipitation line, which showed malate dehydrogenase activity. Immunoprecipitins against schistosomal malate dehydrogenase were also demonstrated in sera from individuals with schistosomiasis. Analysis by the double-diffusion method showed that malate dehydrogenase antigens in S. mansoni, S. haematobium, and S. bovis are immunologically indistinguishable. Immunoelectrophoresis of isolated mitochondrial and cytoplasmic malate dehydrogenase, showed that only the mitochondrial enzyme is able to form a malate dehydrogenase active precipitation line. Rabbit antisera directed against purified mitochondrial malate dehydrogenase showed a reaction with the enzyme as judge by immunoelectrophoresis. A purified mitochondrial malate dehydrogenase preparation, coupled to Sepharose 4B, was used in the defined antigen substrate spheres (DASS) test. Sera from experimentally infected mice contained considerably higher levels of antibodies against the mitochondrial malate dehydrogenase preparation than sera from infected individuals.     

Mitochondrial malate dehydrogenase and malic enzyme: Mendelian inherited electrophoretic variants in the mouse

Malate dehydrogenase and malic enzyme each possess supernatant and mitochondrial molecular forms which are structurally and genetically independent. We describe electrophoretic variants of the mitochondrial enzymes of malate dehydrogenase and malic enzyme in mice. Progeny testing from genetic crosses indicated that the genes which code for mitochondrial malate dehydrogenase and malic enzyme were not inherited maternally but as independent unlinked nuclear autosomal genes. The locus for mitochondrial malic enzyme was located on linkage group I. Linkage analysis with a third mitochondrial enzyme marker, glutamic oxaloacetic transaminase, showed that the nuclear genes which code for the three mitochondrial enzymes were not closely linked to each other. This evidence suggests that clusters of nuclear genes coding for mitochondrial function are unlikely in mice.Supported by U.S. Public Health Service grants 5F2 HD-35,531 and GM-09966.     

Biogenesis of the mitochondrial matrix enzyme, glutamate dehydrogenase, in rat liver cells. II. Significance of binding of glutamate dehydrogenase to microsomal membrane

1. Glutamate dehydrogenase and malate dehydrogenase solubilized from liver microsomes were able to rebind to microsomal vesicles while the corresponding dehydrogenases extracted from mitochondria showed no affinity for microsomes. 2. Competition was noticed between microsomal glutamate dehydrogenase and microsomal malate dehydrogenase in the binding to microsomal membranes. Mitochondrial malate dehydrogenase or bovine serum albumin did not inhibit the binding of microsomal glutamate dehydrogenase to microsomes. 3. Binding of microsomal glutamate dehydrogenase to microsomal membranes decreased when microsomes was preincubated with trypsin. 4. Rough microsomal glutamate dehydrogenase was more efficiently bound to rough microsomes than smooth microsomes. Conversely, smooth microsomal glutamate dehydrogenase had higher affinity for smooth microsomes than for rough microsomes. 5. A difference was noticed among the glutamate dehydrogenase isolated from rough and smooth microsomes, and from mitochondria, which suggested the possibility of minor post-translational modification of enzyme molecules in the transport from the site of synthesis to mitochondria.