Study of kinetics of thermal aggregation of mitochondrial aspartate aminotransferase by dynamic light scattering: protective effect of α-crystallin

Thermal aggregation of aspartate aminotransferase from pig heart mitochondria (mAAT) has been studied at various temperatures and various protein concentrations by dynamic light scattering. The character of the dependence of protein aggregate size on time indicates that aggregation of mAAT proceeds in the regime of diffusion-limited cluster–cluster aggregation. Suppression of mAAT aggregation by α-crystallin is due to transition of the aggregation process into the regime of reaction-limited cluster–cluster aggregation. Realization of this regime of aggregation means that the sticking probability for the colliding particles is less than unity.     

Effect of α-crystallin on thermostability of mitochondrial aspartate aminotransferase

Effect of α-crystallin on thermal inactivation, denaturation and aggregation of aspartate aminotransferase from pig heart mitochondria (mAAT) has been in the focus of this study. Acceleration of heat-induced inactivation of mAAT was demonstrated in the presence of α-crystallin. According to the data of differential scanning calorimetry, α-crystallin induces destabilization of the mAAT molecule. The size of protein aggregates formed at heating of mAAT at a constant rate (1 °C/min) has been defined by dynamic light scattering. The obtained data show that aggregation of mAAT in the presence of α-crystallin proceeds in the regime of reaction-limited cluster–cluster aggregation.     

The three-dimensional structure of mitochondrial aspartate aminotransferase at 4.5 A resolution

An X-ray crystallographic study at 4.5 Å resolution has been carried out with triclinic crystals of chicken mitochondrial aspartate aminotransferase.In the electron density map, the enzyme is clearly visible as an isologous α₂-dimer (105 Å × 60 Å × 50 Å) in which the subunits are associated about a molecular 2-fold axis. Each subunit of dimensions 70 Å × 50 Å × 40 Å contains at least seven helices, one of which is about 50 Å long.Difference maps have revealed the positions of the pyridoxyl and the phosphate moieties of the coenzyme as well as the general substrate binding area. The active sites are on opposite sides of the dimer, about 30 Å apart and close to the intersubunit boundary, so that probably both subunits contribute to each active site. An isolated chain segment, passing in front of the active site and ending in contact with the neighbouring subunit is interpreted as one of the chain termini.     

Glycation-induced inactivation of aspartate aminotransferase, effect of uric acid

Glycation is common posttranslational modification of proteins impairing their function, which occurs during diabetes mellitus and aging. Beside extracellular glycation of long-lived proteins, intracellular modifications of short-lived proteins by more reactive sugars like fructose are possible. The process includes free oxygen radicals (glycoxidation). In an attempt to reduce glycoxidation and formation of advanced glycation products (AGE), influence of 0.2–1.2 mM uric acid as endogenous antioxidant on glycoxidation of purified pig heart aspartate aminotransferase (AST) by 50 mM and 500 mM D-fructose in vitro was studied. Uric acid at 1.2 mM concentration reduced AST activity decrease and formation of total AGE products caused by incubation in vitro of the enzyme with sugar up to 25 days at 37 °C. The results thus support the hypothesis that uric acid has beneficial effects in controlling protein glycoxidation. The in vitro system AST-fructose proved to be a useful tool for investigation of glycation process. (Mol Cell Biochem 278: 85–92, 2005)     

Simultaneous purification by affinity chromatography of rat liver mitochondrial aspartate aminotransferase and malate dehydrogenase and electrophoretic properties

Mitochondrial aspartate aminotransferase and malate dehydrogenase were purified to homogeneity from rat liver by the use of aspartate-coupled Sepharose, ion exchange, and Blue Sepharose chromatography. This procedure permits rapid preparation of these enzymes. The pI of each enzyme was determined and anomalous electrophoretic properties of aspartate aminotransferase were described.     

Characterization of a soybean cDNA clone encoding the mitochondrial isozyme of aspartate aminotransferase,AAT4

A soybean leaf cDNA clone, pSAT2, was isolated by hybridization to a carrot aspartate aminotransferase (EC 2.6.1.1.; AAT) cDNA clone at low stringency. pSAT2 contained an open reading frame encoding a 47640 Da protein. The protein encoded by pSAT2 showed significant sequence similarity to AAT proteins from both plants and animals. It was most similar to two Panicum mitochondrial AATs, 81.5% and 82.0% identity. Alignment of the pSAT2-encoded protein with other mature AAT enzymes revealed a 25 amino acid N-terminal extension with characteristics of a mitochondrial transit peptide. A plasmid, pEXAT2, was constructed to encode the mature pSAT2 protein lacking the putative mitochondrial transit peptide. Escherichia coli containing the plasmid expressed a functional AAT isozyme which comigrated with the soybean AAT4 isozyme during agarose gel electrophoresis. Equilibrium sucrose gradient sedimentation of soybean extracts demonstrated that AAT4 specifically cofractionated with mitochondria. Antibodies raised against the pEXAT2-encoded AAT protein reacted with AAT4 of soybean and not with other AAT isozymes detected in soybean tissues, providing further evidence that clone pSAT2 encodes the soybean mitochondrial isozyme AAT4.     

Genomic structure,expression and evolution of the alfalfa aspartate aminotransferase genes

Genomic clones encoding two isozymes of aspartate aminotransferase (AAT) were isolated from an alfalfa genomic library and their DNA sequences were determined. The AAT1 gene contains 12 exons that encode a cytosolic protein expressed at similar levels in roots, stems and nodules. In nodules, the amount of AAT1 mRNA was similar at all stages of development, and was slightly reduced in nodules incapable of fixing nitrogen. The AAT1 mRNA is polyadenylated at multiple sites differing by more than 250 bp. The AAT2 gene contains 11 exons, with 5 introns located in positions identical to those found in animal AAT genes, and encodes a plastid-localized isozyme. The AAT2 mRNA is polyadenylated at a very limited range of sites. The transit peptide of AAT2 is encoded by the first two and part of the third exon. AAT2 mRNA is much more abundant in nodules than in other organs, and increases dramatically during the course of nodule development. Unlike AAT1, expression of AAT2 is significantly reduced in nodules incapable of fixing nitrogen. Phylogenetic analysis of deduced AAT proteins revealed 4 separate but related groups of AAT proteins; the animal cytosolic AATs, the plant cytosolic AATs, the plant plastid AATs, and the mitochondrial AATs.     

Role of aspartate aminotransferase and mitochondrial dicarboxylate transport for release of endogenously and exogenously supplied neurotransmitter in glutamatergic neurons

Evoked release of glutamate and aspartate from cultured cerebellar granule cells was studied after preincubation of the cells in tissue culture medium with glucose (6.5 mM), glutamine (1.0 mM),d[³H] aspartate and in some cases aminooxyacetate (5.0 mM) or phenylsuccinate (5.0 mM). The release of endogenous amino acids and ofd-[³H] aspartate was measured under physiological and depolarizing (56 mM KCl) conditions both in the presence and absence of calcium (1.0 mM), glutamine (1.0 mM), aminooxyacetate (5.0 mM) and phenylsuccinate (5.0 mM). The cellular content of glutamate and aspartate was also determined. Of the endogenous amino acids only glutamate was released in a transmitter fashion and newly synthesized glutamate was released preferentially to exogenously suppliedd-[³H] aspartate, a marker for exogenous glutamate. Evoked release of endogenous glutamate was reduced or completely abolished by respectively, aminooxyacetate and phenylsuccinate. In contrast, the release ofd-[³H] aspartate was increased reflecting an unaffected release of exogenous glutamate and an increased psuedospecific radioactivity of the glutamate transmitter pool. Since aminooxyacetate and phenylsuccinate inhibit respectively aspartate aminotransferase and mitochondrial keto-dicarboxylic acid transport it is concluded that replenishment of the glutamate transmitter pool from glutamine, formed in the mitochondrial compartment by the action of glutaminase requires the simultaneous operation of mitochondrial keto-dicarboxylic acid transport and aspartate aminotransferase which is localized both intra- and extra-mitochondrially. The purpose of the latter enzyme apparently is to catalyze both intra- and extra-mitochondrial transamination of -ketoglutarate which is formed intramitochondrially from the glutamate carbon skeleton and transferred across the mitochondrial membrane to the cytosol where transmitter glutamate is formed. This cytoplasmic origin of transmitter glutamate is in aggreement with the finding thatd-[³H] aspartate readily labels the transmitter pool even when synthesis of endogenous transmitter is impaired in the presence of AOAA or phenylsuccinate.Special issue dedicated to Dr Elling Kvamme     

pH-dependent aggregation of oligomeric Artocarpus hirsuta lectin on thermal denaturation

The pH dependence of the activity, aggregation, and secondary structure of Artocarpus hirsuta lectin was studied using intrinsic and extrinsic fluorescence, light scattering, and circular dichroism. The lectin is more stable in the neutral and acidic than in the alkaline pH range, which is also reflected in the binding constants of the lectin to methyl alpha-galactopyranoside (me alpha-gal). The aggregation of the protein due to heat denaturation is prevented at both extremes of pH. The binding of hydrophobic dye to the lectin takes place at pH 1-2, which increases with increasing temperature. The exposure of hydrophobic patches at pH 1 is reversible. The secondary structure of the lectin is intact in the pH range of 1-8 and is distorted above pH 9. Aggregation of the protein due to heat denaturation is also prevented in the presence of guanidine hydrochloride (GdnHCl).     

Crystal structure of Saccharomyces cerevisiae cytosolic aspartate aminotransferase.

The crystal structure of Saccharomyces cerevisiae cytoplasmic aspartate aminotransferase (EC 2.6.1.1) has been determined to 2.05 A resolution in the presence of the cofactor pyridoxal-5'-phosphate and the competitive inhibitor maleate. The structure was solved by the method of molecular replacement. The final value of the crystallographic R-factor after refinement was 23.1% with good geometry of the final model. The yeast cytoplasmic enzyme is a homodimer with two identical active sites containing residues from each subunit. It is found in the "closed" conformation with a bound maleate inhibitor in each active site. It shares the same three-dimensional fold and active site residues as the aspartate aminotransferases from Escherichia coli, chicken cytoplasm, and chicken mitochondria, although it shares less than 50% sequence identity with any of them. The availability of four similar enzyme structures from distant regions of the evolutionary tree provides a measure of tolerated changes that can arise during millions of years of evolution.     

Redesign of the substrate specificity of Escherichia coli aspartate aminotransferase to that of Escherichia coli tyrosine aminotransferase by homology modeling and site-directed mutagenesis.

Although several high-resolution X-ray crystallographic structures have been determined for Escherichia coli aspartate aminotransferase (eAATase), efforts to crystallize E. coli tyrosine aminotransferase (eTATase) have been unsuccessful. Sequence alignment analyses of eTATase and eAATase show 43% sequence identity and 72% sequence similarity, allowing for conservative substitutions. The high similarity of the two sequences indicates that both enzymes must have similar secondary and tertiary structures. Six active site residues of eAATase were targeted by homology modeling as being important for aromatic amino acid reactivity with eTATase. Two of these positions (Thr 109 and Asn 297) are invariant in all known aspartate aminotransferase enzymes, but differ in eTATase (Ser 109 and Ser 297). The other four positions (Val 39, Lys 41, Thr 47, and Asn 69) line the active site pocket of eAATase and are replaced by amino acids with more hydrophobic side chains in eTATase (Leu 39, Tyr 41, Ile 47, and Leu 69). These six positions in eAATase were mutated by site-directed mutagenesis to the corresponding amino acids found in eTATase in an attempt to redesign the substrate specificity of eAATase to that of eTATase. Five combinations of the individual mutations were obtained from mutagenesis reactions. The redesigned eAATase mutant containing all six mutations (Hex) displays second-order rate constants for the transamination of aspartate and phenylalanine that are within an order of magnitude of those observed for eTATase. Thus, the reactivity of eAATase with phenylalanine was increased by over three orders of magnitude without sacrificing the high transamination activity with aspartate observed for both enzymes.(ABSTRACT TRUNCATED AT 250 WORDS)     

Equilibrium kinetics of substrate-enzyme interactions in single crystals of cytoplasmic aspartate aminotransferase

Orthorhombic single crystals of cytoplasmic aspartate aminotransferase were examined alone or in the presence of substrates or inhibitors to quantitatively compare the interaction of ligands with the active-site chromophore between soluble and crystalline enzyme. As in enzyme solutions, equilibrium kinetic measurements can be made between substrates and single crystals of cytoplasmic aspartate aminotransferase. The absorption spectra of ligand-free enzyme forms and of enzyme-substrate or-inhibitor complexes are as distinctive as when the enzyme is in solution. The dissociation constants for glutamate with the pyridoxal form of the enzyme are identical to those in solution. The substrate analog erythro--hydroxyaspartate also binds with equal affinity to the active site in enzyme crystals as in solution; and the affinity of -ketoglutarate to bind in nonproductive complexes with the pyridoxal form of the enzyme is also unimpaired in the crystal (K _d =2 mM). In contrast to the affinity constants, the stoichiometry of the interactions does not appear to correlate to those in solution. In the presence of an amino acid plus keto acid substrates pair, the absorbance values of the enzyme-substrate complex(es) could be interpreted as for occupany of only half the available sites in the crystals. Yet an amino acid, cysteine sulfinate, and -keto acids such as , -difluorooxalacetate convert all active sites in the crystal to the pyridoxamine or pyridoxal form when added to the pyridoxal or pyridoxamine forms, respectively. This ability to completely undergo substrate-induced half-transamination and the apparently conflicting results in trapping half the sites in enzyme-substrate complexes are incorporated into a proposed reciprocating mechanism applicable only to the crystalline state of the enzyme and dictated by crystal packing forces rather than an intrinsic property of the enzyme. Active-site bound pyridoxal phosphate continues to behave as a pH indicator; nevertheless, the pK value of the single crystals is a pH unit (pK=7.15) higher than that in solution. This variation is interpreted as indication of a difference in the environment of the chromophore between the crystal and solution states. While the environmental difference does not significantly alter the affinity for substrates, it could account for the reduced rates in transformation of the enzyme-substrate complexes in half-transamination reactions in the crystalline state.     

Generation process of cytosolic aspartate aminotransferase molecular forms by several treatments

-, -, and -forms of chicken liver cytosolic aspartate aminotransferase generate variants on storage (4°C, 25 days). The variants developed from each isolated form appeared as evenly spaced bands with increasing anodic mobilities after polyacrylamide gel electrophoresis (PAGE), pH 8.8, and specific staining. Their mobilities coincided with those of the more negatively charged forms present in fresh tissue. Development of faster-running variants on storage was avoided by addition of thiol reagents to the freshly isolated forms. In their presence, - and -forms were partially transformed into one and two variants with lower anodic mobilities analogous to those of native - and -forms. Short pH and heat treatments did not modify the electrophoretic patterns of the -, -, and -forms, but the incubation with 5 mMl-ascorbic acid (37C, 7h) produced more anodic active bands. The formation of these variants was inhibited by the presence, in the incubation mixture, of superoxide dismutase and catalase. The kinetic parameters of the forms submitted to the different treatments were similar to those of the freshly isolated subforms. The results obtained suggest that minor subforms of the enzyme could be generatedin vivo by a mechanism in which the oxidation of particular amino acid groups is involved.     

In vitro synthesis of precursor forms of pig heart aspartate aminotransferase isozymes

Precursor forms of the isozymes of aspartate aminotransferase from pig heart were synthesized in vitro and purified by binding to specific antibodies. Analysis by sodium dodecylsulfate polyacrylamide gel electrophoresis showed that the precursor of the cytosolic enzyme has a similar molecular weight to that of the mature protein whereas the precursor of the mitochondrial isozyme has a molecular weight greater than that of the corresponding mature protein (ΔMW ? 2500). Preliminary sequence studies seem to suggest that the precursor of the mitochondrial isozyme has an extra N-terminal peptide sequence while that of the cytosolic protein has only an extra N-terminal methionine residue.     

Vinblastine inhibits the maturation of the precursor of mitochondrial aspartate aminotransferase. Vincristine and six other cytoskeleton inhibitors do not show this effect

Cytoskeleton inhibitors were tested in chicken embryo fibroblast cultures for possible effects on the import of the precursor of mitochondrial aspartate aminotransferase into mitochondria. Vinblastine (50 μM) increased the steady-state pool of the precursor 2.5-fold in pulse experiments with [³⁵S]methionine. If the precursor was accumulated during a pulse in the presence of the uncoupler carbonyl cyanide m-chlorophenylhydrazone (CCCP) and then chased under diluting CCCP, vinblastine (50 μM) prolonged the half-life of the precursor from 0.5 min in the control to 3 min. Other cytoskeleton inhibitors, i.e. vincristine (25 to 150 μM), colchicine (50 μM), nocodazole (50 μM), podophyllotoxin (50 μM), taxol (45 μM), cytochalasin D (20 μM) and phalloidin (25 μM) did not show this effect. The observed inhibition by vinblastine does not seem to relate to its action on microtubuli.     

Yeast aspartate aminotransferase: preparation of the apoenzyme and its interaction with coenzyme analogues

Affinity chromatography of yeast aspartate aminotransferase [l-aspartate: 2-oxoglutarate aminotransferase, EC 2.6.1.1] on N′(ω-aminohexyl) pyridoxamine-5-phosphate Sepharose 4B is reported. The specific activity of the enzyme obtained, fully activated with pyridoxal-5-phosphate, was higher than that of previous preparations but the yield of purified enzyme was poor. Purification using DEAE-cellulose gave a higher yield of enzyme with lower specific activity. This preparation contained an appreciable amount of the holoenzyme. Use of sodium borohydride permitted the preparation of apoenzyme containing only 1.4% of the holo-form. Four coenzyme analogues were synthesized. These were the N′-acetyl-, the N′-methyl- and the N′-benzyloxycarbonylglycyl-pyridoxamine-5-phosphate and the O-acetylpyridoxal-5-phosphate. The three N′-substituted pyridoxamine-5-phosphate derivatives were all effective inhibitors of the enzyme, while the O-acetylpyridoxal-5-phosphate bound to the apoenzyme and gave an active enzyme.     

Isolation and characterization of a soybean cDNA clone encoding the plastid form of aspartate aminotransferase

Five aspartate aminotransferase (EC 2.6.1.1; AAT) isozymes were identified in soybean seedling extracts and designated AAT1 to AAT5 based on their rate of migration on non-denaturing electrophoretic gels. AAT1 was detected only in extracts of cotyledons from dark-grown seedlings. AAT3 and AAT4 were detected in crude extracts of leaves and in cotyledons of seedlings grown in the light. AAT2 and AAT5 were detected in all tissues examined. A soybean leaf cDNA clone, pSAT17, was identified by hybridization to a carrot AAT cDNA clone at low stringency. pSAT17 had an open reading frame which could encode a 50 581 Da protein. Alignment of the deduced amino acid sequence from the pSAT17 open reading frame with mature AAT protein sequences from rat disclosed a 60 amino acid N-terminal extension in the pSAT17 protein. This extension had characteristics of a plastid transit peptide.A plasmid, pEXAT17, was constructed which encoded the mature protein lacking the putative chloroplast transit polypeptide. Transformed Escherichia coli expressed a functional soybean AAT isozyme, which comigrated with the soybean AAT5 isozyme during agarose gel electrophoresis. Differential sucrose gradient sedimentation of soybean extracts indicated that AAT5 specifically cofractionated with chloroplasts. Antibodies raised against the pEXAT17-encoded AAT protein specifically reacted with the AAT5 isozyme of soybean and not with any of the other isozymes, indicating that the soybean cDNA clone, pSAT17, encodes the chloroplast isozyme, AAT5.     

Identification and functional analysis of a prokaryotic-type aspartate aminotransferase: implications for plant amino acid metabolism

In this paper, we report the identification of genes from pine (PpAAT), Arabidopsis (AtAAT) and rice (OsAAT) encoding a novel class of aspartate aminotransferase (AAT, EC 2.6.1.1) in plants. The enzyme is unrelated to other eukaryotic AATs from plants and animals but similar to bacterial enzymes. Phylogenetic analysis indicates that this prokaryotic-type AAT is closely related to cyanobacterial enzymes, suggesting it might have an endosymbiotic origin. Interestingly, most of the essential residues involved in the interaction with the substrate and the attachment of pyridoxal phosphate cofactor in the active site of the enzyme were conserved in the deduced polypeptide. The polypeptide is processed in planta to a mature subunit of 45 kDa that is immunologically distinct from the cytosolic, mitochondrial and chloroplastic isoforms of AAT previously characterized in plants. Functional expression of PpAAT sequences in Escherichia coli showed that the processed precursor is assembled into a catalytically active homodimeric holoenzyme that is strictly specific for aspartate. These atypical genes are predominantly expressed in green tissues of pine, Arabidopsis and rice, suggesting a key role of this AAT in nitrogen metabolism associated with photosynthetic activity. Moreover, immunological analyses revealed that the plant prokaryotic-type AAT is a nuclear-encoded chloroplast protein. This implies that two plastidic AAT co-exist in plants: a eukaryotic type previously characterized and the prokaryotic type described here. The respective roles of these two enzymes in plant amino acid metabolism are discussed.