Mitochondrial aspartate aminotransferase 27/32-410. Partially active enzyme derivative produced by limited proteolytic cleavage of native enzyme

The partially folded homodimeric intermediate of Escherichia coli aspartate aminotransferase contains a "molten interface" structure

The role of intersubunit side chain-side chain interactions in the stability of the Escherichia coli aspartate aminotransferase (eAATase) homodimer was investigated by directed mutagenesis at 10 different interface contacts. The urea-mediated unfolding pathway of this enzyme proceeds through the formation of a dimeric intermediate, D*, that retains only 40% of the native enzyme secondary structure as judged by circular dichroism. Disruption of any single intersubunit interaction results in a >2.6 kcal mol(-1) decrease in native state stability, independent of its location or nature. However, the stability of D* with respect to U, the unfolded monomer, is the same for all mutants. The stability of the eAATase interface cannot be ascribed to the contribution of a few hot spots, or to the accumulation of a large number of weak interactions, but only to the presence of multiple important and interconnected interactions. It is proposed that a "molten interface" structure, flexible enough to accommodate point mutations, accounts for the stability of D*. Nuclei of tertiary structure, which are not involved in native intersubunit contacts, likely provide a scaffold for the unstructured interface of D*. Such a scaffold would account for the cooperative unfolding of the intermediate.

The unfolding pathway for Apo Escherichia coli aspartate aminotransferase is dependent on the choice of denaturant

The guanidine hydrochloride (GdnHCl) mediated denaturation pathway for the apo form of homodimeric Escherichia coli aspartate aminotransferase (eAATase) (molecular mass = 43.5 kDa/monomer) includes a partially folded monomeric intermediate, M* [Herold, M., and Kirschner, K. (1990) Biochemistry 29, 1907-1913; Birolo, L., Dal Piaz, F., Pucci, P., and Marino, G. (2002) J. Biol. Chem. 277, 17428-17437]. The present investigation of the urea-mediated denaturation of eAATase finds no evidence for an M* species but uncovers a partially denatured dimeric form, D*, that is unpopulated in GdnHCl. Thus, the unfolding process is a function of the employed denaturant. D* retains less than 50% of the native secondary structure (circular dichroism), conserves significant quaternary and tertiary interactions, and unfolds cooperatively (mD*<==>U = 3.4 +/- 0.3 kcal mol-1 M-1). Therefore, the following equilibria obtain in the denaturation of apo-eAATase: D <==> 2M 2M* <==> 2U in GdnHCl and D <==> D* <==> 2U in urea (D = native dimer, M = folded monomer, and U = unfolded state). The free energy of unfolding of apo-eAATase (D <==> 2U) is 36 +/- 3 kcal mol-1, while that for the D* 2U transition is 24 +/- 2 kcal mol-1, both at 1 M standard state and pH 7.5.

Inactivation of tyrosine phenol-lyase by Pictet-Spengler reaction and alleviation by T15A mutation on intertwined N-terminal arm

Citrobacter freundiil-tyrosine phenol-lyase (TPL) was inactivated by a Pictet-Spengler reaction between the cofactor and a substrate, 3,4-dihydroxyphenyl-L-alanine (L-dopa), in proportion to an increase in the reaction temperature. Random mutagenesis of the tpl gene resulted in the generation of a Thr15 to Ala mutant (T15A), which exhibited a two-fold improved activity towards L-DOPA as the substrate. The Thr15 residue was located on the intertwined N-terminal arm of the TPL structure, and comprised an H-bond network in proximity to the hydrophobic core between the catalytic dimers. The maximum activity of the mutant and native enzymes with L-DOPA was detected at 45 and 40 degrees C, respectively, which was 15 degrees C lower than when using L-tyrosine as the substrate. The half-lives at 45 degrees C were about 16.8 and 6.4 min for the mutant and native enzymes, respectively, in 10 mM L-DOPA. On treatment with excess pyridoxal-5'-phosphate (PLP), the L-DOPA-inactivated enzymes recovered over 80% of their original activities, thereby attributing the inactivation to a loss of the cofactor through Pictet-Spengler condensation with L-DOPA. Consistent with the extended half-life, the apparent Michaelis constant of the T15A enzyme for PLP (K(m,PLP)) increased slowly when increasing the temperature, while that of the native enzyme showed a sharp increase at temperatures higher than 50 degrees C, implying that the loss of the cofactor with the Pictet-Spengler reaction was prevented by the tighter binding and smaller release of the cofactor in the mutant enzyme.

The C-terminal domain of dimeric serine hydroxymethyltransferase plays a key role in stabilization of the quaternary structure and cooperative unfolding of protein: domain swapping studies with enzymes having high sequence identity

The serine hydroxymethyltransferase from Bacillus subtilis (bsSHMT) and B. stearothermophilus (bstSHMT) are both homodimers and share approximately 77% sequence identity; however, they show very different thermal stabilities and unfolding pathways. For investigating the role of N- and C-terminal domains in stability and unfolding of dimeric SHMTs, we have swapped the structural domains between bs- and bstSHMT and generated the two novel chimeric proteins bsbstc and bstbsc, respectively. The chimeras had secondary structure, tyrosine, and pyridoxal-5'-phosphate microenvironment similar to that of the wild-type proteins. The chimeras showed enzymatic activity slightly higher than that of the wild-type proteins. Interestingly, the guanidium chloride (GdmCl)-induced unfolding showed that unlike the wild-type bsSHMT, which undergoes dissociation of native dimer into monomers at low guanidium chloride (GdmCl) concentration, resulting in a non-cooperative unfolding of enzyme, its chimera bsbstc, having the C-terminal domain of bstSHMT was resistant to low GdmCl concentration and showed a GdmCl-induced cooperative unfolding from native dimer to unfolded monomer. In contrast, the wild-type dimeric bstSHMT was resistant to low GdmCl concentration and showed a GdmCl-induced cooperative unfolding, whereas its chimera bstbsc, having the C- terminal domain of bsSHMT, showed dissociation of native dimer into monomer at low GdmCl concentration and a GdmCl-induced non-cooperative unfolding. These results clearly demonstrate that the C-terminal domain of dimeric SHMT plays a vital role in stabilization of the oligomeric structure of the native enzyme hence modulating its unfolding pathway.

The role of the conserved Lys68*:Glu265 intersubunit salt bridge in aspartate aminotransferase kinetics: multiple forced covariant amino acid substitutions in natural variants

The role of the Lys68*:Glu265 intersubunit salt bridge that is conserved (Csb) in all known aspartate aminotransferases (AATases), except those of animal cytosolic, Ac (His68*:Glu265), and plant mitochondrial, Pm (Met68*:Gln265), origins, was evaluated in the Escherichia coli AATase. Two double-mutant cycles, to K68M/E265Q and the charge reversed K68E/E265K, were characterized with the context dependence (C) and impact (I) formalism, previously defined for functional chimeric analysis. Mutations of Lys68* with Glu265 fixed are generally more deleterious than the converse mutations of Glu265 with Lys68* fixed, showing that buried negative charges have greater effects than buried positive charges in this context. Replacement of the charged Lys68*:Glu265 with the K68M/E265Q neutral pair introduces relatively small effects on the kinetic parameters. The differential sensitivity of k(cat)/K(M, L-Asp) and k(cat)/K(M, alpha-KG) to salt bridge mutagenic replacements is shown by a linear-free energy relationship, in which the logarithms of the latter second order rate constants are generally decreased by a factor of two more than are those of the former. Thus, k(cat)/K(M, L-Asp) and k(cat)/K(M, alpha-KG) are 133 and 442 mM(-1)s(-1) for the wild-type (WT) enzyme, respectively, but their relative order is reversed in the more severely compromised mutants (14.8 and 5.3 mM(-1)s(-1) for K68E). A Venn diagram illustrates apparent forced covariances of groups of amino acids that accompany the naturally occurring salt bridge replacements in the Pm and Ac classes. The more deeply rooted tree indicates that the Csb variant was the ancestral specie.

The N-terminal portion of mature aldehyde dehydrogenase affects protein folding and assembly

Human liver cytosolic (ALDH1) and mitochondrial (ALDH2) aldehyde dehydrogenases are both encoded in the nucleus and synthesized in the cytosol. ALDH1 must fold in the cytosol, but ALDH2 is first synthesized as a precursor and must remain unfolded during import into mitochondria. The two mature forms share high identity (68%) at the protein sequence level except for the first 21 residues (14%); their tertiary structures were found to be essentially identical. ALDH1 folded faster in vitro than ALDH2 and could assemble to tetramers while ALDH2 remained as monomers. Import assay was used as a tool to study the folding status of ALDH1 and ALDH2. pALDH1 was made by fusing the presequence of precursor ALDH2 to the N-terminal end of ALDH1. Its import was reduced about 10-fold compared to the precursor ALDH2. The exchange of the N-terminal 21 residues from the mature portion altered import, folding, and assembly of precursor ALDH1 and precursor ALDH2. More of chimeric ALDH1 precursor was imported into mitochondria compared to its parent precursor ALDH1. The import of chimeric ALDH2 precursor, the counterpart of chimeric ALDH1 precursor, was reduced compared to its parent precursor ALDH2. Mature ALDH1 proved to be more stable against urea denaturation than ALDH2. Urea unfolding improved the import of precursor ALDH1 and the chimeric precursors but not precursor ALDH2, consistent with ALDH1 and the chimeric ALDHs being more stable than ALDH2. The N-terminal segment of the mature protein, and not the presequence, makes a major contribution to the folding, assembly, and stability of the precursor and may play a role in folding and hence the translocation of the precursor into mitochondria.

Recombinant tyrosine aminotransferase from Trypanosoma cruzi: structural characterization and site directed mutagenesis of a broad substrate specificity enzyme

The gene encoding tyrosine aminotransferase (TAT, EC 2.6.1.5) from the parasitic protozoan Trypanosoma cruzi was amplified from genomic DNA, cloned into the pET24a expression vector and functionally expressed as a C-terminally His-tagged protein in Escherichia coli BL21(DE3)pLysS. Purified recombinant TAT exhibited identical electrophoretic and enzymatic properties as the authentic enzyme from T. cruzi. Both recombinant and authentic T. cruzi TATs were highly resistant to limited tryptic cleavage and contained no disulfide bonds. Comprehensive analysis of its substrate specificity demonstrated TAT to be a broad substrate aminotransferase, with leucine, methionine as well as tyrosine, phenylalanine, tryptophan and alanine being utilized efficiently as amino donors. Valine, isoleucine and dicarboxylic amino acids served as poor substrates while polar aliphatic amino acids could not be transaminated. TAT also accepted several 2-oxoacids, including 2-oxoisocaproate and 2-oxomethiobutyrate, in addition to pyruvate, oxaloacetate and 2-oxoglutarate. The functionality of the expression system was confirmed by constructing two variants; one (Arg389) being a completely inactive enzyme; the other (Arg283) retaining its full activity, as predicted from the recently solved three-dimensional structure of T. cruzi TAT. Thus, only one of the two strictly conserved arginines which are essential for the enzymatic activity of subfamily Ialpha aspartate and aromatic aminotransferases is critical for T. cruzi's TAT activity.

Truncated aspartate aminotransferase from alkalophilic Bacillus circulans with deletion of N-terminal 32 amino acids is a non-functional monomer in a partially structured state

Aspartate aminotransferase (AspAT) from alkalophilic Bacillus circulans contains an additional N-terminal sequence of 32 amino acid residues that are absent in all other AspATs from different sources. Modeling suggested that this sequence forms two alpha-helical segments which establish a continuous network of interactions on the surface of the molecule. In the present study, we studied the role of the N-terminal sequence in folding and stability of AspAT by applying the scanning calorimetry, and CD and fluorescence spectroscopies to the native and truncated enzymes. Truncated AspAT (Delta2alpha mutant) devoid of N-terminal residues cannot provide sufficient potential of quaternary intersubunit and subunit-cofactor interactions, which results in a monomeric non-functional conformation. However, the residual tertiary interactions in the Delta2alpha mutant are sufficient to: i) provide stability of a residual structure over a wide pH range; ii) confer moderate cooperativity of the denaturant-induced transition while only low cooperativity of the thermal transition, and iii) maintain the hydrophobic core of a part of the structure which prevents aromatic fluorophores from quenching by water. Furthermore, the present study provides evidence that AspAT from the alkalophilic bacterium follows unfolding pathway comprising a stable non-functional intermediate, in contrast to a two-state mechanism of the thermophilic AspAT from Sulfolobus solfataricus.

Selective determination of fish aspartate aminotransferase isoenzymes by their differential sensitivity to proteases

Various proteases (proteinase K, subtilisin, trypsin and chymotrypsin) were used to study the selective inactivation of the aspartate aminotransferase (EC 2.6.1.1) isoenzymes of grey mullet (Mugil auratus Risso; Osteichthyes). The cytosolic isoenzyme was significantly inactivated by proteinase K, subtilisin and chymotrypsin, while the mitochondrial isoenzyme was sensitive only to proteinase K and to high doses of trypsin. Further identification of the aspartate aminotransferase isoenzymes was based on their discrete sensitivity toward chymotrypsin. Chymotrypsin (1 mg/ml) successfully inhibited purified cytosolic aspartate aminotransferase as well as cytosolic isoenzyme from plasma, whereas the mitochondrial form persisted unaffected. Similar results were obtained when examining liver and red muscle homogenates. This method revealed that the increased total activity of aspartate aminotransferase in fish plasma with induced acute liver injury, was partially a result of the mitochondrial isoenzyme leakage from damaged tissue.

Conformation of aspartate aminotransferase isozymes folding under different conditions probed by limited proteolysis

The partially homologous mitochondrial (mAAT) and cytosolic (cAAT) aspartate aminotransferase have nearly identical three-dimensional structures but differ in their folding rates in cell-free extracts and in their affinity for binding to molecular chaperones. In its native state, each isozyme is protease-resistant. Using limited proteolysis as an index of their conformational states, we have characterized these proteins (a) during the early stages of spontaneous refolding; (b) as species trapped in stable complexes with the chaperonin GroEL; or (c) as newly translated polypeptides in cell-free extracts. Treatment of the refolding proteins with trypsin generates reproducible patterns of large proteolytic fragments that are consistent with the formation of defined folding domains soon after initiating refolding. Binding to GroEL affords considerable protection to both isozymes against proteolysis. The tryptic fragments are similar in size for both isozymes, suggesting a common distribution of compact and flexible regions in their folding intermediates. cAAT synthesized in cell-free extracts becomes protease-resistant almost instantaneously, whereas trypsin digestion of the mAAT translation product produces a pattern of fragments qualitatively akin to that observed with the protein refolding in buffer. Analysis of the large tryptic peptides obtained with the GroEL-bound proteins reveals that the cleavage sites are located in analogous regions of the N-terminal portion of each isozyme. These results suggest that (a) binding to GroEL does not cause unfolding of AAT, at least to an extent detectable by proteolysis; (b) the compact folding domains identified in AAT bound to GroEL (or in mAAT fresh translation product) are already present at the early stages of refolding of the proteins in buffer alone; and (c) the two isozymes seem to bind in a similar fashion to GroEL, with the more compact C-terminal portion completely protected and the more flexible N-terminal first 100 residues still partially accessible to proteolysis.

Kinetic properties and thermal stabilities of mutant forms of mitochondrial aspartate aminotransferase

Kinetic properties and thermal stabilities of the precursor form of mitochondrial aspartate aminotransferase, the mature form lacking 9 amino acids from the N-terminus, and forms of the mature protein in which cysteine-166 had been mutated to serine or alanine were compared with those of the mature enzyme. The precursor and the cysteine mutants showed moderately impaired catalytic properties consistent with decreased ability to undergo transition from the open to the closed conformation which is an integral part of the mechanism of action of the enzyme. The deletion mutant had a kcat only 2% of that of the mature enzyme but also much reduced Km values for both substrates. In addition it showed enhanced reactivity of cysteine-166 with 5,5'-dithiobis(2-nitrobenzoate), which is characteristic of the closed form of the enzyme, with no enhancement of reactivity in the presence of substrates. This is taken to show that the deletion mutant adopts a conformation that is significantly different from that of the mature enzyme particularly in respect of the small domain. The deletion mutant was found to be more resistant to thermal inactivation over a range of temperatures than were the other forms of the enzyme consistent with its having a more tightly packed small domain.

Crystal structure of human recombinant ornithine aminotransferase

Ornithine aminotransferase (OAT), a pyridoxal-5'-phosphate dependent enzyme, catalyses the transfer of the delta-amino group of L-ornithine to 2-oxoglutarate, producing L-glutamate-gamma-semialdehyde, which spontaneously cyclizes to pyrroline-5-carboxylate, and L-glutamate. The crystal structure determination of human recombinant OAT is described in this paper. As a first step, the structure was determined at low resolution (6 A) by molecular replacement using the refined structure of dialkylglycine decarboxylase as a search model. Crystallographic phases were then refined and extended in a step-wise fashion to 2.5 A by cyclic averaging of the electron density corresponding to the three monomers within the asymmetric unit. Interpretation of the resulting map was straightforward and refinement of the model resulted in an R-factor of 17.1% (Rfree=24.3%). The success of the procedure demonstrates the power of real-space molecular averaging even with only threefold redundancy. The alpha6-hexameric molecule is a trimer of intimate dimers with a monomer-monomer interface of 5500 A2 per subunit. The three dimers are related by an approximate 3-fold screw axis with a translational component of 18 A. The monomer fold is that of a typical representative of subgroup 2 aminotransferases and very similar to those described for dialkylglycine decarboxylase from Pseudomonas cepacia and glutamate-1-semialdehyde aminomutase from Synechococcus. It consists of a large domain that contributes most to the subunit interface, a C-terminal small domain most distant to the 2-fold axis and an N-terminal region that contains a helix, a loop and a three stranded beta-meander embracing a protrusion in the large domain of the second subunit of the dimer. The large domain contains the characteristic central seven-stranded beta-sheet (agfedbc) covered by eight helices in a typical alpha/beta fold. The cofactor pyridoxal-5'-phosphate is bound through a Schiff base to Lys292, located in the loop between strands f and g. The C-terminal domain includes a four-stranded antiparallel beta-sheet in contact with the large domain and three further helices at the far end of the subunit. The active sites of the dimer lie, about 25 A apart, at the subunit and domain interfaces. The conical entrances are on opposite sides of the dimer. In the active site, R180, E235 and R413 are probable substrate binding residues. Structure-based sequence comparisons with related transaminases in this work support that view. In patients suffering from gyrate atrophy, a recessive hereditary genetic disorder that can cause blindness in humans, ornithine aminotransferase activity is lacking. A large number of frameshift and point mutations in the ornithine aminotransferase gene have been identified in such patients. Possible effects of the various point mutations on the structural stability or the catalytic competence of the enzyme are discussed in light of the three-dimensional structure.

Insight into the conformation of protein folding intermediate(s) trapped by GroEL

Many aspects of the mechanism by which the GroEL/ES chaperonins mediate protein folding are still unclear, including the amount of structure present in the substrate bound to GroEL. To address this issue we have analyzed the susceptibility to limited proteolysis and to alkylation of cysteine residues of mitochondrial aspartate aminotransferase (mAAT) bound to GroEL. Several regions of the N-terminal portion of GroEL-bound mAAT are highly susceptible to proteolysis, whereas a large core of about 200 residues containing the C-terminal half of the polypeptide chain is protected in the complex. This protection does not extend to the mAAT sulfhydryl groups which in the GroEL-mAAT complex have similar reactivity as in fully unfolded mAAT. These results suggest that the mAAT species bound to GroEL represent folding intermediates with a conformation that is substantially more disorganized than that of the native state. The N-terminal half of the molecule is more flexible and lies exposed at the mouth of the central cavity of GroEL. The more compact C-terminal section of mAAT, which contains residues located at the subunit interface in the native dimer, appears to be hidden in the central cavity of GroEL. Thus, the bulk of the interactions in the GroEL.mAAT complex seems to involve residues from the more compact C-terminal section of the substrate.

Importance of the amino terminus in maintenance of oligomeric structure of sheep liver cytosolic serine hydroxymethyltransferase

The role of the amino and carboxyl-terminal regions of cytosolic serine hydroxymethyltransferase (SHMT) in subunit assembly and catalysis was studied using six amino-terminal (lacking the first 6, 14, 30, 49, 58, and 75 residues) and two carboxyl-terminal (lacking the last 49 and 185 residues) deletion mutants. These mutants were constructed from a full length cDNA clone using restriction enzyme/PCR-based methods and overexpressed in Escherichia coli. The overexpressed proteins, des-(A1-K6)-SHMT and des-(A1-W14)-SHMT were present in the soluble fraction and they were purified to homogeneity. The deletion clones, for des-(A1-V30)-SHMT and des-(A1-L49)-SHMT were expressed at very low levels, whereas des-(A1-R58)-SHMT, des-(A1-G75)-SHMT, des-(Q435-F483)-SHMT and des-(L299-F483)-SHMT mutant proteins were not soluble and formed inclusion bodies. Des-(A1-K6)-SHMT and des-(A1-W14)-SHMT catalyzed both the tetrahydrofolate-dependent and tetrahydrofolate-independent reactions, generating characteristic spectral intermediates with glycine and tetrahydrofolate. The two mutants had similar kinetic parameters to that of the recombinant SHMT (rSHMT). However, at 55 degrees C, the des-(A1-W14)-SHMT lost almost all the activity within 5 min, while at the same temperature rSHMT and des-(A1-K6)-SHMT retained 85% and 70% activity, respectively. Thermal denaturation studies showed that des-(A1-W14)-SHMT had a lower apparent melting temperature (52 degrees C) compared to rSHMT (56 degrees C) and des-(A1-K6)-SHMT (55 degrees C), suggesting that N-terminal deletion had resulted in a decrease in the thermal stability of the enzyme. Further, urea induced inactivation of the enzymes revealed that 50% inactivation occurred at a lower urea concentration (1.2+/-0.1 M) in the case of des-(A1-W14)-SHMT compared to rSHMT (1.8+/-0.1 M) and des-(A1-K6)-SHMT (1.7+/-0.1 M). The apoenzyme of des-(A1-W14)-SHMT was present predominantly in the dimer form, whereas the apoenzymes of rSHMT and des-(A1-K6)-SHMT were a mixture of tetramers (approximately 75% and approximately 65%, respectively) and dimers. While, rSHMT and des-(A1-K6)-SHMT apoenzymes could be reconstituted upon the addition of pyridoxal-5'-phosphate to 96% and 94% enzyme activity, respectively, des-(A1-W14)-SHMT apoenzyme could be reconstituted only up to 22%. The percentage activity regained correlated with the appearance of visible CD at 425 nm and with the amount of enzyme present in the tetrameric form upon reconstitution as monitored by gel filtration. These results demonstrate that, in addition to the cofactor, the N-terminal arm plays an important role in stabilizing the tetrameric structure of SHMT.

Crystal structures and solution studies of oxime adducts of mitochondrial aspartate aminotransferase

The interaction of mitochondrial aspartate aminotransferase with hydroxylamine and five derivatives (in which the hydroxyl hydrogen is replaced by the side chain of naturally occurring amino acids) was investigated by X-ray diffraction as well as by kinetic and spectral measurements with the enzyme in solution. The inhibitors react with pyridoxal 5'-phosphate in the enzyme active site, both in solution and in the crystalline state, in a reversible single-step reaction forming spectrally distinct oxime adducts. Dissociation constants determined in solution range from 10(-8) M to 10(-6) M depending on the nature of the side-chain group. The crystal structures of the adducts of mitochondrial aspartate aminotransferase with the monocarboxylic analogue of L-aspartate in the open and closed enzyme conformation were determined at 0.23-nm and 0.25-nm resolution, respectively. This inhibitor binds to both the open and closed crystal forms of the enzyme without disturbing the crystalline order. Small differences in the conformation of the cofactor pyridoxal phosphate were detected between the omega-carboxylate of the inhibitor and Arg292 of the neighbouring subunit is mainly responsible for the attainment of near-coplanarity of the aldimine bond with the pyridine ring in the oxime adducts. Studies with a fluorescent probe aimed to detect shifts in the open/closed conformational equilibrium of the enzyme in oxime complexes showed that the hydroxylamine-derived inhibitors, even those containing a carboxylate group, do not induce the 'domain closure' in solution. This is probably due to the absence of the alpha-carboxylate group in the monocarboxylic hydroxylamine-derived inhibitors, emphasizing that both carboxylates of the substrates L-Asp and L-Glu are essential for stabilizing the closed form of aspartate aminotransferase.

Probing conformational states of spin-labeled aspartate aminotransferase by ESR

Mitochondrial aspartate aminotransferase was selectively labeled with various maleimide-linked nitroxide spin labels at the conformationally sensitive Cys166. The mobility of the spin group was found to increase with increasing length of the spacer between the nitroxide and maleimide moiety. The label with the ethylcarbamoyl group, a spacer of intermediate length, responded sensitively to conformational changes of aspartate aminotransferase. The modification with this label decreased the enzymic activity to 30% of its initial value and increased the affinity for various substrates and inhibitors 5-10-fold. Identical ESR spectra were obtained for the pyridoxal and pyridoxamine form of the enzyme. These spectra are complex, consisting of an isotropic and at least two anisotropic components. The spectral complexity is attributed to different modes of interaction of the spin label with its local protein environment giving rise to different motional states. The same changes in the ESR spectra have been observed upon formation of the adsorption complex of the pyridoxal form with a competitive inhibitor and on formation of covalent intermediates of the transamination reaction. Essentially, the isotropic component is converted to a new anisotropic one as the local environment changes due to a conformational adaptation of aspartate aminotransferase. The ESR data are consistent with an equilibrium between two conformational states of the enzyme but inconsistent with individual protein conformations of the various intermediates of the transamination reaction. The two conformational states may be assigned to the open and closed conformations as defined by X-ray crystallography. In the adsorption complex of the pyridoxal enzyme, and in the covalent intermediates, the two-state equilibrium appears to be shifted towards the closed conformation in which the spin label is more rigidly bound, as also suggested by molecular dynamic simulations of the label modelled into aspartate aminotransferase. In contrast the formation of adsorption complexes between the pyridoxamine form and aspartate or maleate was not accompanied by the same shift of the conformational equilibrium.

Probes of ligand-induced conformational change in aspartate aminotransferase

Sodium borohydride and sodium cyanoborohydride were assessed as potential reagents for determining ligand-induced changes in accessibility to the active-site of aspartate aminotransferase. Rates of reduction of the imine formed between Lys258 and pyridoxal phosphate were determined in the presence of increasing concentrations of the dicarboxylate substrate analogues glutarate and maleate. The rate of reduction decreased to a limiting value which was about 40-fold lower than the equivalent rate in the absence of dicarboxylate. Analysis of the reaction was complicated by the increasing protonation of the imine which accompanied binding of dicarboxylates. Allowing for this increase, the true decrease in accessibility to NaBH3CN was estimated to be approximately 400-fold. Arguments are presented in support of a proposal that the ratio of closed to open conformer of the dicarboxylate-liganded enzyme is approximately 150. The effects of increasing ligand concentration on the reactivity of Cys390 were found to take place in the same range as was observed for NaBH3CN reduction. Conversely, very much higher concentrations of the dicarboxylates were required to protect against proteolysis by trypsin. It is concluded that NaBH3CN reduction and reactivity of cysteine are good determinants of the conformational status of the enzyme but that resistance to tryptic digestion is due to an additional binding mode for the dicarboxylates.

Riboflavin 5'-pyrophosphate: a contaminant of commercial FAD, a coenzyme for FAD-dependent oxidases, and an inhibitor of FAD synthetase

Commercially available preparations of flavin adenine dinucleotide (FAD) have been found to be 94% pure, the remaining 6% being composed of four or five minor contaminants which can be separated from FAD by reverse-phase high-performance liquid chromatography. FAD purified in this manner has been shown to be 100% pure. One of the contaminants has been identified as riboflavin 5'-pyrophosphate (RPP) by spectroscopic and chemical methods of analysis. This compound has been shown to exhibit biological activity as a weak cofactor for two FAD-requiring enzymes. With the apoprotein of porcine D-amino-acid oxidase, values determined for RPP were 8.4 microM for Km and 0.10 for Vmax compared to 0.47 microM and 0.28 (36 U/mg), respectively, for FAD. With fungal glucose apooxidase, values determined for RPP were 474 nM for Km and 0.02 for Vmax and 45 nM and 0.09 (105 U/mg), respectively, for FAD. RPP can also inhibit FAD biosynthesis. For bovine liver FAD synthetase, a Ki value for RPP against FMN was determined to be 9 microM where Km for FMN was 5.5 microM. These studies illustrate the value of riboflavin 5'-pyrophosphate as a flavin analog for use in the study of structure/function relationships within certain flavin-dependent enzymes.

Precursor of mitochondrial aspartate aminotransferase synthesized in Escherichia coli is complexed with heat-shock protein DnaK

On expression of the cDNA encoding the precursor of chicken mitochondrial aspartate aminotransferase (pmAspAT) in Escherichia coli, the bulk of pmAspAT was found to be associated with the 70-kDa heat-shock protein DnaK which is closely related to mitochondrial 70-kDa heat-shock protein (HSP70). Purification protocols for the DnaK/pmAspAT complex and its individual components were elaborated. The complex dissociated on treatment with MgATP or at pH 5.5. Like the mature enzyme, pmAspAT is a dimer (2 x 47 kDa) and exhibits about a third of its enzyme activity. In the DnaK/pmAspAT complex, one DnaK molecule is bound to each subunit of pmAspAT; this tetramer may further aggregate to an octamer. The complex is catalytically almost as active as free pmAspAT. It could be reconstituted from isolated DnaK and pmAspAT. No complex was formed with mAspAT. Apparently, DnaK binds to the solvent-exposed presequence of folded pmAspAT without significantly changing the structure and functional properties of its mature moiety.

X-ray structure refinement and comparison of three forms of mitochondrial aspartate aminotransferase

The X-ray crystal structures of three forms of the enzyme aspartate aminotransferase (EC 2.6.1.1) from chicken heart mitochondria have been refined by least-squares methods: holoenzyme with the co-factor pyridoxal-5'-phosphate bound at pH 7.5 (1.9 A resolution), holoenzyme with pyridoxal-5'-phosphate bound at pH 5.1 (2.3 A resolution) and holoenzyme with the co-factor pyridoxamine-5'-phosphate bound at pH 7.5 (2.2 A resolution). The crystallographic agreement factors [formula: see text] for the structures are 0.166, 0.130 and 0.131, respectively, for all data in the resolution range from 10.0 A to the limit of diffraction for each structure. The secondary, super-secondary and domain structures of the pyridoxal-phosphate holoenzyme at pH 7.5 are described in detail. The surface area of the interface between the monomer subunits of this dimeric alpha 2 protein is unusually large, indicating a very stable dimer. This is consistent with biochemical data. Both subunit and domain interfaces are relatively smooth compared with other proteins. The interactions of the protein with its co-factor are described and compared among the three structures. Observed changes in co-factor conformation may be related to spectral changes and the energetics of the catalytic reaction. Small but significant adjustments of the protein to changes in co-factor conformation are seen. These adjustments may be accommodated by small rigid-body shifts of secondary structural elements, and by packing defects in the protein core.

Limited proteolysis as a probe of conformational changes in aspartate aminotransferase from Sulfolobus solfataricus

The analysis of conformational transitions using limited proteolysis was carried out on a hyperthermophilic aspartate aminotransferase isolated from the archaebacterium Sulfolobus solfataricus, in comparison with pig cytosolic aspartate aminotransferase, a thoroughly studied mesophilic aminotransferase which shares about 15% similarity with the archaebacterial protein. Aspartate aminotransferase from S. solfataricus is cleaved at residue 28 by thermolysin and residues 32 and 33 by trypsin; analogously, pig heart cytosolic aspartate aminotransferase is cleaved at residues 19 and 25 [Iriarte, A., Hubert, E., Kraft, K. & Martinez-Carrion, M. (1984) J. Biol. Chem. 259, 723-728] by trypsin. In the case of aspartate aminotransferase from S. solfataricus, proteolytic cleavages also result in transaminase inactivation thus indicating that both enzymes, although evolutionarily distinct, possess a region involved in catalysis and well exposed to proteases which is similarly positioned in their primary structure. It has been reported that the binding of substrates induces a conformational transition in aspartate aminotransferases and protects the enzymes against proteolysis [Gehring, H. (1985) in Transaminases (Christen, P. & Metzler, D. E., eds) pp. 323-326, John Wiley & Sons, New York]. Aspartate aminotransferase from S. solfataricus is protected against proteolysis by substrates, but only at high temperatures (greater than 60 degrees C). To explain this behaviour, the kinetics of inactivation caused by thermolysin were measured in the temperature range 25-75 degrees C. The Arrhenius plot of the proteolytic kinetic constants measured in the absence of substrates is not rectilinear, while the same plot of the constants measured in the presence of substrates is a straight line. Limited proteolysis experiments suggest that aspartate aminotransferase from S. solfataricus undergoes a conformational transition induced by the binding of substrates. Another conformational transition which depends on temperature and occurs in the absence of substrates could explain the non-linear Arrhenius plot of the proteolytic kinetic constants. The latter conformational transition might also be related to the functioning of the archaebacterial aminotransferase since the Arrhenius plot of kcat is non-linear as well.

Mechanism of racemization of amino acids by aspartate aminotransferase

Aspartate aminotransferase (mitochondrial isoenzyme from chicken) has been found to racemize very slowly dicarboxylic amino acid substrates in the presence of their cognate oxo acids [Kochhar, S. & Christen, P. (1988) Eur. J. Biochem. 175, 433-438]. Tyrosine, phenylalanine and alanine are racemized at the same rate although they undergo the transamination reaction 3-5 orders of magnitude more slowly than the dicarboxylic substrates. Similarly, the truncated enzyme aspartate aminotransferase-(27/32-410) catalyzes the racemization at the same rate as the native enzyme, while its rate of transamination is decreased to 3% of that of the native enzyme. Apparently, the rate-limiting step in racemization is not immediately linked to the transamination cycle. Decreasing the water concentration in the reaction medium by adding methanol at 0 degrees C drastically reduces the rate of racemization without affecting the rate of transamination. On the basis of these and additional kinetic data and the model of the three-dimensional structure of the active site, we conclude that a water molecule is responsible for the protonation of C alpha of the coenzyme-substrate intermediate from the wrong side. The diffusion of the water molecule into the interior of the enzyme appears to be the rate-limiting step in aspartate-aminotransferase-catalyzed racemization.

Isolation and characterization of active N-terminal truncated apo- and holoenzyme of mammalian liver tyrosine aminotransferase

Limited proteolysis was used to probe the structure of the apo- and holoenzyme of rat liver tyrosine aminotransferase. Both were subjected to trypsinolysis and the major fragments were isolated and characterized. Trypsin cleaves the apoenzyme after residues Arg57, Lys64, and Lys71 and the holoenzyme after Arg37 and Lys38. The difference in the accessibility of the enzyme deprived or associated with pyridoxal 5'-phosphate reflects two distinct conformations. The activity, the affinity for the ligands and the thermostability of the purified truncated enzyme forms are similar to those of the native apo- and holoenzyme. A model for the domain structure of mammalian tyrosine aminotransferase and a mechanism for its rapid turnover are proposed.

The open/closed conformational equilibrium of aspartate aminotransferase. Studies in the crystalline state and with a fluorescent probe in solution

Aspartate aminotransferase undergoes major shifts in the conformational equilibrium of the protein matrix during transamination. The present study defines the two conformational states of the enzyme by crystallographic analysis, examines the conditions under which the enzyme crystallizes in each of these conformations, and correlates these conditions with the conformational behaviour of the enzyme in solution, as monitored by a fluorescent reporter group. Cocrystallization of chicken mitochondrial aspartate aminotransferase with inhibitors and covalent coenzymesubstrate adducts yields three different crystal forms. Unliganded enzyme forms triclinic crystals of the open conformation, the structure of which has been solved (space group P1) [Ford, G. C., Eichele, G. & Jansonius, J. N. (1980) Proc. Natl Acad. Sci. USA 77, 2559-2563; Kirsch, J. F., Eichele, G., Ford, G. C., Vincent, M. G., Jansonius, J. N., Gehring, H. & Christen, P. (1984) J. Mol. Biol. 174, 487-525]. Complexes of the enzyme with dicarboxylate ligands form monoclinic or orthorhombic crystals of the closed conformation. The results of structure determinations of the latter two crystal forms at 0.44 nm resolution are described here. In the closed conformation, the small domain has undergone a rigid-body rotation of 12-14 which closes the active-site pocket. Shifts in the conformational equilibrium of aspartate aminotransferase in solution, as induced by substrates, substrate analogues and specific dicarboxylic inhibitors, can be monitored by changes in the relative fluoresence yield of the enzyme labelled at Cys166 with monobromotrimethylammoniobimane. The pyridoxal and pyridoxamine forms of the labelled enzyme show the same fluorescence properties, whereas in the apoenzyme the fluorescence intensity is reduced by 30%. All active-site ligands, if added to the labelled pyridoxal enzyme at saturating concentrations, cause a decrease in the fluorescence intensity by 40-70% and a blue shift of maximally 5 nm. Comparison of the fluorescence properties of the enzyme in various functional states with the crystallographic data shows that both techniques probe the same conformational equilibrium. The conformational change that closes the active site seems to be ligand-induced in the reaction of the pyridoxal form of the enzyme and syncatalytic in the reverse reaction with the pyridoxamine enzyme.

Determination of human aspartate aminotransferase isoenzymes by their differential sensitivity to proteases

The effect of various proteases (trypsin, chymotrypsin, subtilisin, protease 401, and thermolysin) on the mitochondrial isoenzyme (m-AST) and cytoplasmic isoenzyme (c-AST) of human and swine aspartate aminotransferase (AST;EC 2.6.1.1) was evaluated. All procedures including the reaction with proteases and the subsequent determination of the AST activity were carried out in an automatic analyzer. The mammalian c-AST was efficiently inactivated by chymotrypsin, subtilisin and protease 401 while m-AST activity decreased very slowly with these proteases. Thermolysin and trypsin showed much less effect on c-AST activity. Especially, chymotrypsin at concentrations of 0.5-1.0 g/L inactivated human c-AST almost completely but showed no detectable inactivating effect on m-AST. Thus chymotrypsin appears to be the most suitable protease for the differential determination of AST isoenzymes in human serum. Further studies on the effects of proteases with AST from other species showed that Escherichia coli AST resembled mammalian m-AST while Pseudomonas AST resembled c-AST.

Specific proteolysis of native alanine racemases from Salmonella typhimurium: identification of the cleavage site and characterization of the clipped two-domain proteins

Native DadB and Alr alanine racemases (Mr 39,000) from Salmonella typhimurium are proteolyzed at homologous positions by alpha-chymotrypsin, trypsin, and subtilisin to generate in all cases two nonoverlapping polypeptides of Mr 28,000 and 11,000. Under nondenaturing conditions, chymotryptic digest results in an associated form of the two fragments which possesses 3% of the original catalytic activity, incorporates 0.76 equiv of the mechanism-based inactivator beta-chloro-[14C]-D-alanine [Badet, B., Roise, D., & Walsh, C. T. (1984) Biochemistry 23, 5188], and exhibits a UV circular dichroism profile identical with that of native enzyme. Protein sequence analysis of the denatured chymotryptic fragments indicates the presence of a tetrapeptide interdomain hinge (DadB, residues 254-257; Alr, residues 256-259) that is attacked at both ends during proteolysis. Under the previously employed digest conditions, NaB3H4-reduced DadB holoenzyme is resistant to alpha-chymotrypsin and trypsin and is labile only toward subtilisin. These data suggest that the hinge structure is essential for a catalytically efficient enzyme species and is sensitive to active site geometry. The sequence at the hinge region is also conserved in alanine racemases from Gram-positive bacteria.

Serine hydroxymethyltransferase. Effect of proteases on the activity and structure of the cytosolic enzyme

Homogeneous preparations of cytosolic serine hydroxymethyltransferase from rabbit liver were incubated with several different proteases. Chymotrypsin rapidly cleaves a tetradecapeptide from the NH2-terminal end of the enzyme with the enzyme retaining full catalytic activity. Trypsin digestion results in the release of several small peptides from the NH2-terminal end of the enzyme. The remaining core protein is reduced in molecular mass by about 3500 Da. With L-serine as substrate the core protein has 1.5 times the activity of the native enzyme. The difference in activity is due to a change in Vmax since the Km values for L-serine and tetrahydrofolate are unchanged. When allothreonine is used as the substrate the activity of the trypsin-treated enzyme is unchanged. Ks values for glycine and several folate compounds are also unchanged for the trypsin-digested enzyme. The relative distribution of three glycine-enzyme complexes shows only small differences between the native and trypsin-digested enzyme. Thermal denaturation studies show that the trypsin-digested enzyme has a thermal transition three degrees lower than the native enzyme but the same enthalpy of denaturation. These results suggest that the 25-30 amino acid residues from the NH2-terminal end of the enzyme are not important in determining the catalytic activity and structural stability of the purified enzyme. Several other proteases had no observable effect on the activity and size of the enzyme. All of the proteases tested inactivated the apoenzyme and digested it into small fragments. The loss of enzyme activity in frozen liver is probably the result of the enzyme slowly being converted to the apoenzyme form, which is susceptible to protease degradation.

Limited proteolysis of thermolysin by subtilisin: isolation and characterization of a partially active enzyme derivative

Incubation of the neutral metalloendopeptidase thermolysin at pH 9-10 in the presence of 10 mM CaCl2 for 2 days at room temperature with subtilisin at a 50:1 molar ratio leads to a derivative possessing lower (approximately 3%) but intrinsic catalytic activity. This derivative, called thermolysin S, was isolated by gel filtration in approximately 80% yield and then separated from some residual intact thermolysin by an affinity chromatographic step on Sepharose-Gly-D-Phe. It was found that thermolysin S results from a tight association of two polypeptide fragments of apparent Mr of 24000 and 10000. Dissociation of the complex was achieved under strong denaturing conditions, such as gel filtration on a column equilibrated and eluted with 5 M guanidine hydrochloride. The positions of the clip sites were defined by amino acid analysis, end-group determination, and amino acid sequencing of the isolated fragments and shown to lie between Thr-4 and Ser-5, between Thr-224 and Gln-225, and also between Gln-225 and Asp-226. Thermolysin S, which is therefore a stable complex of fragments 5-224(225) and 225(226)-316, shows a shift in optimum pH of about 1 unit toward the acid range with respect to intact thermolysin and a Km essentially unchanged, with furylacryloyl-Gly-Leu-NH2 as substrate. Inhibitors of thermolysin such as ethoxyformic anhydride and Zn2+ ions inactivate also the nicked enzyme.(ABSTRACT TRUNCATED AT 250 WORDS)

Partial amino-acid sequence and cysteine reactivities of cytosolic aspartate aminotransferase from horse heart

Cytosolic aspartate aminotransferase (L-aspartate:2-oxoglutarate aminotransferase, EC 2.6.1.1) from horse heart has five cysteine residues, two of which can be titrated with 5,5'-dithiobis(2-nitrobenzoid acid) in the native enzyme with no impairment of catalytic activity. The rate of modification is unaffected by the presence of substrates. Reaction with N-ethylmaleimide leads to loss of catalytic activity, the rate of inactivation being increased by the presence of substrates. Peptides containing 361 amino-acid residues (about 88% of the total number in the protein) have been isolated and aligned by comparison with the known sequence of the isotopic isoenzyme from pig heart. In the regions compared, 342 of the residues are identical. Hence, assuming that those regions are representative of the whole, then the cytosolic isoenzymes from horse and from pig have about 95% identity of structure. Uniquely among the mammalian cytosolic aspartate aminotransferases so far examined, the enzyme from horse heart is acetylated at the N-terminus.

Mechanism of action of aspartate aminotransferase proposed on the basis of its spatial structure

Aspartate aminotransferase is a pyridoxal phosphate-dependent enzyme that catalyses the transamination reaction: L-aspartate + 2-oxoglutarate----oxaloacetate + L-glutamate. The enzyme shuttles between its pyridoxal and pyridoxamine forms in a double-displacement process. This paper proposes a mechanism of action that delineates the dynamic role of the protein moiety of this enzyme. It is based on crystallographically determined spatial structures (at 2.8 A resolution) of the mitochondrial isoenzyme in its unliganded forms and in complexes with substrate analogues, as well as on model building studies. The enzyme is composed of two identical subunits, which consist of two domains. The coenzyme is bound to the larger domain and is situated in a pocket near the subunit interface. The proximal and distal carboxylate group of dicarboxylic substrates are bound to Arg386 and Arg292 , respectively, the latter residue belonging to the adjacent subunit. These interactions largely determine the substrate specificity of the enzyme. They not only position the substrate efficient catalysis but also bring about a bulk movement of the small domain that closes the active site crevice and moves Arg386 about 3 A closer to the coenzyme. The replacement of the epsilon-amino group of Lys258 by the alpha-amino group of the substrate in the aldimine bond to pyridoxal phosphate is accompanied by a tilting of the coenzyme by approximately 30 degrees. The released epsilon-amino group of Lys258 serves as a proton acceptor/donor in the 1,3- prototropic shift producing the ketimine intermediate. At this stage, or after hydrolysis of the ketimine bond, the coenzyme rotates back to an orientation between that in the "external" aldimine intermediate and that in the pyridoxal form. Throughout this process, the protonated pyridine nitrogen atom maintains a hydrogen bond to the beta-carboxylate group of Asp222 . Upon formation of the pyridoxamine form, the small domain moves back to its original position. The proposed mechanism is compatible with the known kinetic and stereochemical features of enzymic transamination.

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.