Rat liver L-glutamate dehydrogenase, malate dehydrogenase, D-beta-hydroxybutyrate dehydrogenase, and sulfite oxidase are each synthesized as larger precursors by cytoplasmic free polysomes

Import of a major mitochondrial enzyme depends on synergy between two distinct helices of its presequence

Mammalian glutamate dehydrogenase (GDH), a nuclear-encoded enzyme central to cellular metabolism, is among the most abundant mitochondrial proteins (constituting up to 10% of matrix proteins). To attain such high levels, GDH depends on very efficient mitochondrial targeting that, for human isoenzymes hGDH1 and hGDH2, is mediated by an unusually long cleavable presequence (N53). Here, we studied the mitochondrial transport of these proteins using isolated yeast mitochondria and human cell lines. We found that both hGDHs were very rapidly imported and processed in isolated mitochondria, with their presequences (N53) alone being capable of directing non-mitochondrial proteins into mitochondria. These presequences were predicted to form two α helices (α1: N 1–10; α2: N 16–32) separated by loops. Selective deletion of the α1 helix abolished the mitochondrial import of hGDHs. While the α1 helix alone had a very weak hGDH mitochondrial import capacity, it could direct efficiently non-mitochondrial proteins into mitochondria. In contrast, the α2 helix had no autonomous mitochondrial-targeting capacity. A peptide consisting of α1 and α2 helices without intervening sequences had GDH transport efficiency comparable with that of N53. Mutagenesis of the cleavage site blocked the intra-mitochondrial processing of hGDHs, but did not affect their mitochondrial import. Replacement of all three positively charged N-terminal residues (Arg3, Lys7 and Arg13) by Ala abolished import. We conclude that the synergistic interaction of helices α1 and α2 is crucial for the highly efficient import of hGDHs into mitochondria.

Alpha helical structures in the leader sequence of human GLUD2 glutamate dehydrogenase responsible for mitochondrial import

Human glutamate dehydrogenase (hGDH) exists in two highly homologous isoforms with a distinct regulatory and tissue expression profile: a housekeeping hGDH1 isoprotein encoded by the GLUD1 gene and an hGDH2 isoenzyme encoded by the GLUD2 gene. There is evidence that both isoenzymes are synthesized as pro-enzymes containing a 53 amino acid long N-terminal leader peptide that is cleaved upon translocation into the mitochondria. However, this GDH signal peptide is substantially larger than that of most nuclear DNA-encoded mitochondrial proteins, the leader sequence of which typically contains 17-35 amino acids and they often form a single amphipathic α-helix. To decode the structural elements that are essential for the mitochondrial targeting of human GDHs, we performed secondary structure analyses of their leader sequence. These analyses predicted, with 82% accuracy, that both leader peptides are positively charged and that they form two to three α-helices, separated by intermediate loops. The first α-helix of hGDH2 is strongly amphipathic, displaying both a positively charged surface and a hydrophobic plane. We then constructed GLUD2-EGFP deletion mutants and used them to transfect three mammalian cell lines (HEK293, COS 7 and SHSY-5Y). Confocal laser scanning microscopy, following co-transfection with pDsRed2-Mito mitochondrial targeting vector, revealed that deletion of the entire leader sequence prevented the enzyme from entering the mitochondria, resulting in its retention in the cytoplasm. Deletion of the first strongly amphipathic α-helix only was also sufficient to prevent the mitochondrial localization of the truncated protein. Moreover, truncated leader sequences, retaining the second and/or the third putative α-helix, failed to restore the mitochondrial import of hGDH2. As such, the first N-terminal alpha helical structure is crucial for the mitochondrial import of hGDH2 and these findings may have implications in understanding the evolutionary mechanisms that led to the large mitochondrial targeting signals of human GDHs.

Immunoaffinity purification and characterization of mitochondrial membrane-bound D-3-hydroxybutyrate dehydrogenase from Jaculus orientalis

BACKGROUND

The interconversion of two important energy metabolites, 3-hydroxybutyrate and acetoacetate (the major ketone bodies), is catalyzed by D-3-hydroxybutyrate dehydrogenase (BDH1: EC 1.1.1.30), a NAD+-dependent enzyme. The eukaryotic enzyme is bound to the mitochondrial inner membrane and harbors a unique lecithin-dependent activity. Here, we report an advanced purification method of the mammalian BDH applied to the liver enzyme from jerboa (Jaculus orientalis), a hibernating rodent adapted to extreme diet and environmental conditions.

RESULTS

Purifying BDH from jerboa liver overcomes its low specific activity in mitochondria for further biochemical characterization of the enzyme. This new procedure is based on the use of polyclonal antibodies raised against BDH from bacterial Pseudomonas aeruginosa. This study improves the procedure for purification of both soluble microbial and mammalian membrane-bound BDH. Even though the Jaculus orientalis genome has not yet been sequenced, for the first time a D-3-hydroxybutyrate dehydrogenase cDNA from jerboa was cloned and sequenced.

CONCLUSION

This study applies immunoaffinity chromatography to purify BDH, the membrane-bound and lipid-dependent enzyme, as a 31 kDa single polypeptide chain. In addition, bacterial BDH isolation was achieved in a two-step purification procedure, improving the knowledge of an enzyme involved in the lipid metabolism of a unique hibernating mammal. Sequence alignment revealed conserved putative amino acids for possible NAD+ interaction.

Diversity of glutamate dehydrogenase in human brain

Three forms of glutamate dehydrogenase (GDH, EC 1.4.1.3) are purified from human brain tissue. Two of them, named GDH I (consisting of 58+/-1-kDa subunit) and GDH II (consisting of 56+/-1 -kDa subunit), are readily solubilized and the third one, GDH III (consisting of 56+/-1-kDa subunit), is a membrane-associated (particulate bound) isoform. Kinetic constants were determined for GDH III. These GDH forms were found to differ in hydrophobicity as indicated by different affinity to Phenyl-Sepharose. All three GDH forms showed microheterogeneity on two-dimensional (2-D) gel electrophoresis. Specific polyclonal antibodies, which enable to determine the levels of immunoreactivities of all the GDH forms in human brain extracts by enzyme-chemiluminescent amplified (ECL)-Western immunoblotting, were obtained.

Phosphatidylcholine activation of human heart (R)-3-hydroxybutyrate dehydrogenase mutants lacking active center sulfhydryls: site-directed mutagenesis of a new recombinant fusion protein

(R)-3-Hydroxybutyrate dehydrogenase (BDH) is a lipid-requiring mitochondrial enzyme with a specific requirement of phosphatidylcholine (PC) for function. A plasmid has been constructed to express human heart (HH) BDH in Escherichia coli as a hexahistidine-tagged fusion protein (HH-Histag-BDH). A rapid two-step affinity purification yields active HH-Histag-BDH (and six mutants) with high specific activity ( approximately 130 micromol of NAD(+) reduced.min(-1).mg(-1)). HH-Histag-BDH has no activity in the absence of phospholipid and exhibits a specific requirement of PC for function. The HH-Histag-BDH-PC complex (and HH-BDH derived therefrom by enterokinase cleavage) has apparent Michaelis constants (K(m) values) for NAD(+), NADH, (R)-3-hydroxybutyrate (HOB), and acetoacetate (AcAc) similar to those for bovine heart or rat liver BDH. A computed structural model of HH-BDH predicts the two active center sulfhydryls to be C69 (near the adenosine moiety of NAD) and C242. With both sulfhydryls derivatized, BDH has minimal activity, but site-directed mutagenesis of C69 and/or C242 now shows that neither of these cysteines is required for PC activation or catalysis (the double mutant, C69A/C242A, is highly active with essentially normal kinetic parameters). Six cysteine mutants each have an increased K(m)(NADH) (2-6-fold) but an unchanged K(m)(NAD)+. The C242S and C69A/C242S enzymes (but not the analogous C242A mutants nor the C69A or C69S mutants) exhibit approximately 10-fold increases in K(m)(HOB) and K(m)(AcAc), reflecting an altered substrate binding site. Thus, although C242 (in the C-terminal lipid binding domain of BDH) is close to the active site, it appears to be in a hydrophobic environment and only indirectly defines the substrate binding site at the catalytic center of BDH.

Wild type and mutant human heart (R)-3-hydroxybutyrate dehydrogenase expressed in insect cells

(R)-3-Hydroxybutyrate dehydrogenase (BDH) is a lipid-requiring mitochondrial enzyme with a specific requirement of phosphatidylcholine (PC) for function. PC is an allosteric activator that enhances NAD(H) binding to BDH. The enzyme serves as a paradigm to study specific lipid-protein interactions in membranes. Analysis of the primary sequence of BDH, as determined by molecular cloning, predicts that lipid binding and substrate specificity are contributed by the C-terminal third of the protein [Marks, A. R., McIntyre, J. O., Duncan, T. M., Erdjument-Bromage, H., Tempst, P., & Fleischer, S. (1992) J. Biol. Chem. 267, 15459-15463]. The mature form of human heart BDH has now been expressed in catalytically active form in insect cells (Sf9, Spodoptera frugiperda) transfected with BDH-cDNA in baculovirus. Endogenous PC in the insect cells fulfills the lipid requirement for the expressed BDH since enzymatic activity is lost upon digestion with phospholipase A2 and restored selectively by reconstitution with PC vesicles. The K(m)s for NAD+ and (R)-3-hydroxybutyrate (R-HOB) of expressed BDH are similar to those for bovine heart or rat liver BDH in mitochondria. Replacing Cys242 (the only cysteine in the C-terminal domain) with serine by site-directed mutagenesis resulted in a 10-fold increase in K(m) for R-HOB with no change in the K(m) for NAD+, indicating a role for Cys242 in substrate binding. Carboxypeptidase cleavage studies had indicated a requirement of the C-terminal for catalysis and a role in lipid binding [Adami, P., Duncan, T. M., McIntyre, J. O., Carter, C. E., Fu, C., Melin, M., Latruffe, N., & Fleischer, S. (1993) Biochem J. 292, 863-872]. We now show that deletion of twelve C-terminal amino acids to form a truncated BDH mutant results in loss of enzymic function. The expression in Sf 9 cells of the constitutively active full-length mature form of human heart BDH and the first expression and characterization of BDH mutants validate this system for structure-function studies of BDH.

Reactivity of essential cysteine and lysine residues present at the catalytic domain of pig heart mitochondrial malate dehydrogenase

Pig heart mitochondrial malate dehydrogenase was inactivated very rapidly by omicron-phthalaldehyde as compared to 5,5'-dithio bis(2-nitrobenzoic acid) and pyridoxal 5'-phosphate. The omicron-phthalaldehyde reaction followed pseudo first order kinetics, and a second order rate constant of 38 M-1 S-1 was obtained. Cysteine and lysine residues participating in the omicron-phthalaldehyde reaction are located in the NADH binding region of malate dehydrogenase as shown by protection experiments. The decrease in the rate of inactivation in the presence of NADH was used to determine the dissociation constant of the enzyme-NADH complex. pH dependent studies and molar transition energy calculations of the omicron-phthalaldehyde-inactivated enzyme have indicated that cysteine and lysine residues involved in the isoindole derivative formation are located in a hydrophobic environment at the coenzyme binding site.

Malate dehydrogenase isoenzymes: cellular locations and role in the flow of metabolites between the cytoplasm and cell organelles

Malate dehydrogenases belong to the most active enzymes in glyoxysomes, mitochondria, peroxisomes, chloroplasts and the cytosol. In this review, the properties and the role of the isoenzymes in different compartments of the cell are compared, with emphasis on molecular biological aspects. Structure and function of malate dehydrogenase isoenzymes from plants, mammalian cells and ascomycetes (yeast, Neurospora) are considered. Significant information on evolutionary aspects and characterisation of functional domains of the enzymes emanates from bacterial malate and lactate dehydrogenases modified by protein engineering. The review endeavours to give up-to-date information on the biogenesis and intracellular targeting of malate dehydrogenase isoenzymes as well as enzymes cooperating with them in the flow of metabolites of a given pathway and organelle.

Mitochondrial protein import

Most mitochondrial proteins are synthesized as precursor proteins on cytosolic polysomes and are subsequently imported into mitochondria. Many precursors carry amino-terminal presequences which contain information for their targeting to mitochondria. In several cases, targeting and sorting information is also contained in non-amino-terminal portions of the precursor protein. Nucleoside triphosphates are required to keep precursors in an import-competent (unfolded) conformation. The precursors bind to specific receptor proteins on the mitochondrial surface and interact with a general insertion protein (GIP) in the outer membrane. The initial interaction of the precursor with the inner membrane requires the mitochondrial membrane potential (delta psi) and occurs at contact sites between outer and inner membranes. Completion of translocation into the inner membrane or matrix is independent of delta psi. The presequences are cleaved off by the processing peptidase in the mitochondrial matrix. In several cases, a second proteolytic processing event is performed in either the matrix or in the intermembrane space. Other modifications can occur such as the addition of prosthetic groups (e.g., heme or Fe/S clusters). Some precursors of proteins of the intermembrane space or the outer surface of the inner membrane are retranslocated from the matrix space across the inner membrane to their functional destination ('conservative sorting'). Finally, many proteins are assembled in multi-subunit complexes. Exceptions to this general import pathway are known. Precursors of outer membrane proteins are transported directly into the outer membrane in a receptor-dependent manner. The precursor of cytochrome c is directly translocated across the outer membrane and thereby reaches the intermembrane space. In addition to the general sequence of events which occurs during mitochondrial protein import, current research focuses on the molecules themselves that are involved in these processes.

Molecular cloning and nucleotide sequence of the cDNA for human liver glutamate dehydrogenase precursor

Two cDNA clones (lambda GDHh1 and lambda GDHn61) for glutamate dehydrogenase (GDH) were isolated from a human liver cDNA library in lambda gt11. The clone, lambda GDHh1, was isolated from the library using a synthetic 45mer oligodeoxy-ribonucleotide, the sequence of which was derived from the known amino acid sequence near the NH2-terminus of human liver GDH. Subsequently, lambda GDHn61 was isolated from the same library using lambda GDHh1 as a probe. The inserts of both clones contained an overlapping cDNA sequence for human liver GDH, consisting of a 5'-untranslated region of 70 bp, an open reading frame of 1677 bp, a 3'-untranslated region of 1262 bp and a 15 base poly(A) tract. The predicted amino acid sequence revealed that the human liver GDH precursor consisted of a total of 558 amino acid residues including the NH2-terminal presequence of 53 amino acids. The sequence deduced for the mature enzyme showed 94% homology to the previously reported amino acid sequence of human liver GDH.

Structural organization of the mouse mitochondrial malate dehydrogenase gene

Structural organization of the mouse mitochondrial malate dehydrogenase (EC 1.1.1.37) gene was determined by analyzing a genomic DNA fragment isolated from a cosmid library. The gene is 12,000 base-pairs long and contains nine exons interrupted by eight introns of various sizes. The 5' and 3'-flanking regions, and the exact sizes and boundaries of the exon blocks including the transcription-initiation sites were determined. In the 5'-flanking region, there is neither a TATA box nor a CAAT box. Instead of these sequences, there are six copies of the GGGCGG or CCGCCC sequence, which is a potential binding site for the transcription factor, Sp1. The 5'-flanking region up to about 600 nucleotides is G + C-rich (65%) and contains sequences compatible with the formation of a number of potentially stable stem-loop structures. S1 nuclease mapping and primer extension analysis demonstrated that transcription of the mitochondrial malate dehydrogenase gene initiates at multiple sites. Comparison of the nucleotide sequence of the promoter region of the mitochondrial malate dehydrogenase gene with that of the mitochondrial aspartate aminotransferase gene, revealed that there are several highly conserved regions between these two mitochondrial enzyme genes participating in the malate-aspartate shuttle.

Mitochondrial malate dehydrogenase and its precursor have different conformations

Antiserum prepared against the denatured form of mammalian malate dehydrogenase was found to immunoprecipitate the denatured but not the native form of the mature enzyme. In contrast, the antiserum immunoprecipitated the enzyme's precursor, synthesized in a rabbit reticulocyte lysate, either before or after denaturation. The mature form of the enzyme but not the precursor bound to an affinity column of 5'-AMP-Sepharose. These results indicate that the mature and precursor forms of malate dehydrogenase have different conformations.

Purification and characterization of a soluble and a particulate glutamate dehydrogenase from rat brain

Glutamate dehydrogenase (GDH) activity was determined in high-speed fractions (100,000 g for 60 min) obtained from whole rat brain homogenates after removal of a low-speed pellet (480 g for 10 min). Approximately 60% of the high-speed GDH activity was particulate (associated with membrane) and the remaining was soluble (probably of mitochondrial matrix origin). Most of the particulate GDH activity resisted extraction by several commonly used detergents, high concentration of salt, and sonication; however, it was largely extractable with the cationic detergent cetyltrimethylammonium bromide (CTAB) in hypotonic buffer solution. The two GDH activities were purified using a combination of hydrophobic interaction, ion exchange, and hydroxyapatite chromatography. Throughout these purification steps the two activities showed similar behavior. Kinetic studies indicated similar Km values for the two GDH fractions for the substrates alpha-ketoglutarate, ammonia, and glutamate; however, there were small but significant differences in Km values for NADH and NADPH. Although the allosteric stimulation by ADP and L-leucine and inhibition by diethylstilbestrol was comparable, the two GDH components differed significantly in their susceptibility to GTP inhibition in the presence of 1 mM ADP, with apparent Ki values of 18.5 and 9.0 microM GTP for the soluble and particulate fractions, respectively. The Hill plot coefficient, binding constant, and cooperativity index for the GTP inhibition were also significantly different, indicating that the two GDH activities differ in their allosteric sites. In addition, enzyme activities of the two purified proteins exhibited a significant difference in thermal stability when inactivated at 45 degrees C and pH 7.4 in 50 mM phosphate buffer.

Cytochrome b, the var 1 protein, and subunits I and III of cytochrome c oxidase are synthesized without transient presequences in Saccharomyces cerevisiae

The N-termini of four mitochondrial translation products, the var 1 protein, cytochrome b, and subunits I and III of cytochrome c oxidase have been characterized in Saccharomyces cerevisiae and compared with the known DNA sequences of the respective structural genes. The four mature proteins correspond to the predicted primary translation products and retain the formylated methionine residue. Thus, subunit II of cytochrome c oxidase studied previously [Pratje et al. (1983) EMBO J.2, 1049-1054] is so far the only mitochondrial translation product carrying a N-terminal-extended transient presequence in S. cerevisiae.

Purification of liver glutamate dehydrogenase by affinity precipitation and studies on its denaturation

In the presence of glutaric acid, N2,N2'-adipodihydrazido-bis(N6-carbonylmethyl-NAD+)(bis-NAD+ ) forms cross-links between molecules of glutamate dehydrogenase, resulting in precipitation. The dependence of this process on bis-NAD+ and enzyme concentration has been investigated. This procedure has been shown to be effective in the purification of glutamate dehydrogenase from rat and ox liver, and a procedure is presented in which this affinity precipitation procedure is used instead of the affinity chromatography used in an earlier method (McCarthy, A.D., Walker, J.M. and Tipton, K.F. (1980) Biochem. J. 191, 605-611). The ox liver enzyme prepared in this way had not suffered the limited proteolysis that occurs during the preparation of the enzyme by other commonly used procedures. After the purified enzyme had been denatured by treatment with urea, guanidine hydrochloride, or low pH, no recovery of activity could be demonstrated following dilution or, in the last case, dialysis.

Construction of a cDNA clone for a nuclear-coded subunit of cytochrome c oxidase from rat liver

A cDNA library for 6S-9S poly(A)-containing RNA from rat liver was constructed in E. coli. Initial screening of the clones was carried out using single stranded 32P-labeled cDNA prepared against poly(A)-containing RNA isolated from immunoadsorbed polyribosomes enriched for the nuclear-coded subunit messenger RNAs of cytochrome c oxidase. One of the clones, pCO89, was found to hybridize with the messenger RNA for subunit VIC. The DNA sequence of the insert in pCO89 was carried out and it has got extensive homology with the C-terminal 33 amino acids of subunit VIC from beef heart cytochrome c oxidase. In addition, the insert contained 146 bp, corresponding to a portion of the 3'-non-coding region. Northern blot analysis of rat liver RNA with the nick-translated insert of pCO89 revealed that the messenger RNA for subunit VI would contain around 510 bases.

Transport of proteins into mitochondria

There is still much that is obscure concerning the transport of proteins into or through the mitochondrial membrane systems. In addition, as pointed out previously, it is unlikely that the details of the process are the same for proteins destined for different compartments of the organelle. A brief summary of the process for matrix proteins might be as follows: The proteins are synthesized on free polysomes as precursors of higher molecular weight than the native forms. These precursors are liberated into the cell cytosol and subsequently translocated into the mitochondria. This timing might be different in yeast under some circumstances, synthesis being completed in association with the mitochondria. The precursors interact with a receptor in the outer mitochondrial membrane interaction being mediated by the presequences of the precursors. The presequences therefore act as addressing signals as well as possibly playing a role in one or all of (a) solubilization of precursors, (b) prevention of premature assembly into multimeric structures, or (c) maintenance of nonnative configurations required for transport. Interaction occurs with a second receptor, this time in the inner membrane of the mitochondria, interaction being with multiple sites in the polypeptide chain. Transport across the inner membrane then occurs, this transport depending on a transmembrane electrochemical gradient of which the proton component is the essential part. Transport is accompanied or followed by proteolysis of the prepiece, and formation of the native structure. While steps 1 and 2 of this sequence can be considered well established, the remaining steps are still poorly understood or purely hypothetical. Nevertheless, this sequence of events is consistent with known facts about the process and provides a framework for future investigations.

In vitro translation of canine mitochondrial creatine kinase messenger RNA

The cell-free translation products of mRNA from canine myocardium were immunoprecipitated using antiserum specific for either the MM or mitochondrial creatine kinase subunit. The two subunits were shown to be encoded by the nuclear genome and translated from separate mRNAs. The mitochondrial subunit was translated as a polypeptide with a molecular weight approximately 6,000 greater than the mature form of the enzyme. In contrast, the M-subunit was translated as a polypeptide having a molecular weight identical to that of the mature cytosolic M-subunit. It is assumed that the mitochondrial subunit precursor must be proteolytically processed during translocation from the cytoplasm into mitochondria.

ACTH-mediated induction of synthesis and activity of cytochrome P-450s and related enzymes in cultured bovine adrenocortical cells

1. Cytochromes P-450sec and P-450(11) beta, adrenodoxin and adrenodoxin reductase, mitochondrial components of the adrenocortical steroid hydroxylase pathway, are synthesized as higher molecular weight precursors; cytochrome P-450C-21, a microsomal component of this pathway, is synthesized as the mature form. 2. Synthesis of the above mitochondrial components is induced by ACTH in a co-ordinated fashion. Synthesis of cytochrome P-450C-21 and NADPH-cytochrome P-450 reductase is also induced by ACTH, however, the induction of these microsomal components is not co-ordinated with that of the mitochondrial components. 3. Following treatment of cultured cells with ACTH, the pattern of glucocorticoid output changes from approximately equal amounts of cortisol and corticosterone to predominately cortisol within 24 h. This change results from a large induction of cytochrome P-450(17) alpha activity in response to ACTH. 4. Bovine adrenocortical cells in culture become refractory to continued treatment with ACTH. This refractoriness is manifested in terms of steroid output; synthesis of cytochromes P-450scc, P-450(11) beta and P-450C-21, adrenodoxin and adrenodoxin reductase; and activities of cholesterol side-chain cleavage, 11 beta-hydroxylase and 17 alpha-hydroxylase.