Unveiling the intricacies of allosteric regulation in aspartate kinase from the Wolbachia endosymbiont of Brugia Malayi: Mechanistic and therapeutic insights

Aspartate kinase (AK), an enzyme from the Wolbachia endosymbiont of Brugia malayi (WBm), plays a pivotal role in the bacterial cell wall and amino acid biosynthesis, rendering it an attractive candidate for therapeutic intervention. Allosteric inhibition of aspartate kinase is a prevalent mode of regulation across microorganisms and plants, often modulated by end products such as lysine, threonine, methionine, or meso-diaminopimelate. The intricate and diverse nature of microbial allosteric regulation underscores the need for rigorous investigation. This study employs a combined experimental and computational approach to decipher the allosteric regulation of WBmAK. Molecular Dynamics (MD) simulations elucidate that ATP (cofactor) and ASP (substrate) binding induce a closed conformation, promoting enzymatic activity. In contrast, the binding of lysine (allosteric inhibitor) leads to enzyme inactivation and an open conformation. The enzymatic assay demonstrates the optimal activity of WBmAK at 28 °C and a pH of 8.0. Notably, the allosteric inhibition study highlights lysine as a more potent inhibitor compared to threonine. Importantly, this investigation sheds light on the allosteric mechanism governing WBmAK and imparts novel insights into structure-based drug discovery, paving the way for the development of effective inhibitors against filarial pathogens.

Functional analysis of feedback inhibition-insensitive aspartate kinase identified in a threonine-accumulating mutant of Saccharomyces cerevisiae

Humans and mammals need to ingest essential amino acids (EAAs) for protein synthesis. In addition to their importance as nutrients, EAAs are involved in brain homeostasis. However, elderly people are unable to efficiently consume EAAs from their daily diet due to reduced appetite and variations in the contents of EAAs in foods. On the other hand, strains of the yeast Saccharomyces cerevisiae that accumulate EAAs would enable elderly people to intakegest adequate amounts of EAAs and thus might slow down the neurodegenerative process, contributing to the extension of their healthy lifespan. In this study, we isolated a mutant (strain HNV-5) that accumulates threonine, an EAA, derived from a diploid laboratory yeast by conventional mutagenesis. Strain HNV-5 carries a novel mutation in the HOM3 gene encoding the Ala462Thr variant of aspartate kinase (AK). Enzymatic analysis revealed that the Ala462Thr substitution significantly decreased the sensitivity of AK activity to threonine feedback inhibition even in the presence of 50 mM threonine. Interestingly, Ala462Thr substitution did not affect the catalytic ability of Hom3, in contrast to previously reported amino acid substitutions that resulted in reduced sensitivity to threonine feedback inhibition. Furthermore, yeast cells expressing the Ala462Thr variant showed an approximately threefold increase in intracellular threonine content compared to that of the wild-type Hom3. These findings will be useful for the development of threonine-accumulating yeast strains that may improve the quality of life in elderly people.IMPORTANCEFor humans and mammals, essential amino acids (EAAs) play an important role in maintaining brain function. Therefore, increasing the intake of EAAs by using strains of the yeast Saccharomyces cerevisiae that accumulate EAAs may inhibit neurodegeneration in elderly people and thus contribute to extending healthy lifespan and improving their quality of life. Threonine, an EAA, is synthesized from aspartate. Aspartate kinase (AK) catalyzes the first step in threonine biosynthesis and is subject to allosteric regulation by threonine. Here, we isolated a threonine-accumulating mutant of S. cerevisiae by conventional mutagenesis and identified a mutant gene encoding a novel variant of AK. In contrast to previously isolated variants, the Hom3 variant exhibited AK activity that was insensitive to feedback inhibition by threonine but retained its catalytic ability. This resulted in increased production of threonine in yeast. These findings open up the possibility for the rational design of AK to increase threonine productivity in yeast.

Mechanism of arginine sensing by CASTOR1 upstream of mTORC1

The mechanistic Target of Rapamycin Complex 1 (mTORC1) is a major regulator of eukaryotic growth that coordinates anabolic and catabolic cellular processes with inputs such as growth factors and nutrients, including amino acids. In mammals arginine is particularly important, promoting diverse physiological effects such as immune cell activation, insulin secretion, and muscle growth, largely mediated through activation of mTORC1 (refs 4, 5, 6, 7). Arginine activates mTORC1 upstream of the Rag family of GTPases, through either the lysosomal amino acid transporter SLC38A9 or the GATOR2-interacting Cellular Arginine Sensor for mTORC1 (CASTOR1). However, the mechanism by which the mTORC1 pathway detects and transmits this arginine signal has been elusive. Here, we present the 1.8 Å crystal structure of arginine-bound CASTOR1. Homodimeric CASTOR1 binds arginine at the interface of two Aspartate kinase, Chorismate mutase, TyrA (ACT) domains, enabling allosteric control of the adjacent GATOR2-binding site to trigger dissociation from GATOR2 and downstream activation of mTORC1. Our data reveal that CASTOR1 shares substantial structural homology with the lysine-binding regulatory domain of prokaryotic aspartate kinases, suggesting that the mTORC1 pathway exploited an ancient, amino-acid-dependent allosteric mechanism to acquire arginine sensitivity. Together, these results establish a structural basis for arginine sensing by the mTORC1 pathway and provide insights into the evolution of a mammalian nutrient sensor.

[Construction and characterization of R169H mutant of aspartokinase from Corynebacterium pekinense]

OBJECTIVE

Increasing the activity of aspartokinase (AK) from Corynebacterium pekinense.

METHODS

The gene of AK was constructed and mutated by site-specific mutagenesis. The mutational recombinant plasmid was heterologously expressed in Escherichia coli BL21. The mutational AK was purified by Ni(2+)-NTA column after ultrasonicating of the recombinant bacteria, and then identified by SDS-PAGE and Western blot. We compared the kinetic difference between R169H AK and WT AK by determining the enzymatic activities. Some other characteristics of R169H AK and WTAK were also studied.

RESULTS

The mutant R169H was successfully constructed. The molecular weight of AK was 48kDa. V(max) of R169H AK was 226.3 U/mg x s(-1), which was 2.3 times higher than that of WT AK. The optimum reaction temperature of R169H AK was 26 degrees C, the same as that of WT AK. The optimum reaction pH of R169H AK was 9.0, slightly higher than that of WT AK. The half-life period of R169H AK under optimum temperature and pH were 5.5h, much higher than that of WT AK. Lysine, threonine and methionine had an active effect on the activity of R169H AK when they were in low concentration.

CONCLUSION

The hydrogen bond between R169 and E92 was broken down in R169H AK, which could affect the degree of polymerization and further lowered the affinity of mutant AK with substrates and then decreased the inhibition inducing by the metabolites. Thus, the V(max) of mutant AK from R169H had increased by 2.3 times compared with that of WT AK.

Characterization of histidine-aspartate kinase HK1 and identification of histidine phosphotransfer proteins as potential partners in a Populus multistep phosphorelay

In poplar, we identified proteins homologous to yeast proteins involved in osmosensing multistep phosphorelay Sln1p-Ypd1p-Ssk1p. This finding led us to speculate that Populus cells could sense osmotic stress by a similar mechanism. This study focuses on first and second protagonists of this possible pathway: a histidine-aspartate kinase (HK1), putative osmosensor and histidine phosphotransfer proteins (HPt1 to 10), potential partners of this HK. Characterization of HK1 showed its ability to homodimerize in two-hybrid tests and to act as an osmosensor with a kinase activity in yeast, by functional complementation of sln1Δ sho1Δ strain. Moreover, in plant cells, plasma membrane localization of HK1 is shown. Further analysis on HPts allowed us to isolate seven new cDNAs, leading to a total of 10 different HPts identified in poplar. Interaction tests showed that almost all HPts can interact with HK1, but two of them exhibit stronger interactions, suggesting a preferential partnership in poplar. The importance of the phosphorylation status in these interactions has been investigated with two-hybrid tests carried out with mutated HK1 forms. Finally, in planta co-expression analysis of genes encoding these potential partners revealed that only three HPts are co-expressed with HK1 in different poplar organs. This result reinforces the hypothesis of a partnership between HK1 and these three preferential HPts in planta. Taken together, these results shed some light on proteins partnerships that could be involved in the osmosensing pathway in Populus.

Microbial metabolic engineering for L-threonine production

L-threonine, one of the three major amino acids produced throughout the world, has a wide application in industry, as an additive or as a precursor for the biosynthesis of other chemicals. It is predominantly produced through microbial fermentation the efficiency of which largely depends on the quality of strains. Metabolic engineering based on a cogent understanding of the metabolic pathways of L-threonine biosynthesis and regulation provides an effective alternative to the traditional breeding for strain development. Continuing efforts have been made in revealing the mechanisms and regulation of L-threonine producing strains, as well as in metabolic engineering of suitable organisms whereby genetically-defined, industrially competitive L-threonine producing strains have been successfully constructed. This review focuses on the global metabolic and regulatory networks responsible for L-threonine biosynthesis, the molecular mechanisms of regulation, and the strategies employed in strain engineering.

A new concept to reveal protein dynamics based on energy dissipation

Protein dynamics is essential for its function, especially for intramolecular signal transduction. In this work we propose a new concept, energy dissipation model, to systematically reveal protein dynamics upon effector binding and energy perturbation. The concept is applied to better understand the intramolecular signal transduction during allostery of enzymes. The E. coli allosteric enzyme, aspartokinase III, is used as a model system and special molecular dynamics simulations are designed and carried out. Computational results indicate that the number of residues affected by external energy perturbation (i.e. caused by a ligand binding) during the energy dissipation process shows a sigmoid pattern. Using the two-state Boltzmann equation, we define two parameters, the half response time and the dissipation rate constant, which can be used to well characterize the energy dissipation process. For the allostery of aspartokinase III, the residue response time indicates that besides the ACT2 signal transduction pathway, there is another pathway between the regulatory site and the catalytic site, which is suggested to be the β15-αK loop of ACT1. We further introduce the term “protein dynamical modules” based on the residue response time. Different from the protein structural modules which merely provide information about the structural stability of proteins, protein dynamical modules could reveal protein characteristics from the perspective of dynamics. Finally, the energy dissipation model is applied to investigate E. coli aspartokinase III mutations to better understand the desensitization of product feedback inhibition via allostery. In conclusion, the new concept proposed in this paper gives a novel holistic view of protein dynamics, a key question in biology with high impacts for both biotechnology and biomedicine.

Cloning, expression, purification, crystallization and preliminary X-ray diffraction analysis of the regulatory domain of aspartokinase (Rv3709c) from Mycobacterium tuberculosis

The regulatory domain of Mycobacterium tuberculosis aspartokinase (Mtb-AK, Mtb-Ask, Rv3709c) has been cloned, heterologously expressed in Escherichia coli and purified using standard chromatographic techniques. Screening for initial crystallization conditions using the regulatory domain (AK-β) in the presence of the potential feedback inhibitor threonine identified four conditions which yielded crystals suitable for X-ray diffraction analysis. From these four conditions five different crystal forms of Mtb-AK-β resulted, three of which belonged to the orthorhombic system, one to the tetragonal system and one to the monoclinic system. The highest resolution (1.6 Å) was observed for a crystal form belonging to space group P2(1)2(1)2(1), with unit-cell parameters a=53.70, b=63.43, c=108.85 Å and two molecules per asymmetric unit.

Metabolically engineered soybean seed with enhanced threonine levels: biochemical characterization and seed-specific expression of lysine-insensitive variants of aspartate kinases from the enteric bacterium Xenorhabdus bovienii

Threonine (Thr) is one of a few limiting essential amino acids (EAAs) in the animal feed industry, and its level in feed rations can impact production of important meat sources, such as swine and poultry. Threonine as well as EAAs lysine (Lys) and methionine (Met) are all synthesized via the aspartate family pathway. Here, we report a successful strategy to produce high free threonine soybean seed via identification of a feedback-resistant aspartate kinase (AK) enzyme that can be over-expressed in developing soybean seed. Towards this goal, we have purified and biochemically characterized AK from the enteric bacterium Xenorhabdus bovienii (Xb). Site-directed mutagenesis of XbAK identified two key regulatory residues Glu-257 and Thr-359 involved in lysine inhibition. Three feedback-resistant alleles, XbAK_T359I, XbAK_E257K and XbAK_E257K/T359I, have been generated. This study is the first to kinetically characterize the XbAK enzyme and provide biochemical and transgenic evidence that Glu-257 near the catalytic site is a critical residue for the allosteric regulation of AK. Furthermore, seed-specific expression of the feedback-resistant XbAK_T359I or XbAK_E257K allele results in increases of free Thr levels of up to 100-fold in R(1) soybean seed when compared to wild-type. Expression of feedback-sensitive wild-type AK did not substantially impact seed Thr content. In addition to high Thr, transgenic seed also showed substantial increases in other major free amino acid (FAA) levels, resulting in an up to 3.5-fold increase in the total FAA content. The transgenic seed was normal in appearance and germinated well under greenhouse conditions.

Mechanism of concerted inhibition of alpha2beta2-type hetero-oligomeric aspartate kinase from Corynebacterium glutamicum

Aspartate kinase (AK) is the first and committed enzyme of the biosynthetic pathway producing aspartate family amino acids, lysine, threonine, and methionine. AK from Corynebacterium glutamicum (CgAK), a bacterium used for industrial fermentation of amino acids, including glutamate and lysine, is inhibited by lysine and threonine in a concerted manner. To elucidate the mechanism of this unique regulation in CgAK, we determined the crystal structures in several forms: an inhibitory form complexed with both lysine and threonine, an active form complexed with only threonine, and a feedback inhibition-resistant mutant (S301F) complexed with both lysine and threonine. CgAK has a characteristic alpha(2)beta(2)-type heterotetrameric structure made up of two alpha subunits and two beta subunits. Comparison of the crystal structures between inhibitory and active forms revealed that binding inhibitors causes a conformational change to a closed inhibitory form, and the interaction between the catalytic domain in the alpha subunit and beta subunit (regulatory subunit) is a key event for stabilizing the inhibitory form. This study shows not only the first crystal structures of alpha(2)beta(2)-type AK but also the mechanism of concerted inhibition in CgAK.

Structural Insight into Concerted Inhibition of α2β2-Type Aspartate Kinase from Corynebacterium glutamicum

Aspartate kinase (AK) catalyzes the first step of the biosynthesis of the aspartic acid family amino acids, and is regulated via feedback inhibition by end-products including Thr and Lys. To elucidate the mechanism of this inhibition, we determined the crystal structure of the regulatory subunit of AK from Corynebacterium glutamicum at 1.58 A resolution in the Thr-binding form, the first crystal structure of the regulatory subunit of alpha(2)beta(2)-type AK. The regulatory subunit contains two ACT domain motifs per monomer and is arranged as a dimer. Two non-equivalent ACT domains from different chains form an effector-binding unit that binds a single Thr molecule, and the resulting two effector-binding units of the dimer associate perpendicularly in a face-to-face manner. The regulatory subunit is a monomer in the absence of Thr but becomes a dimer by adding Thr. The dimerization is eliminated in mutant AKs with changes in the Thr-binding region, suggesting that the dimerization induced by Thr binding is a key step in the inhibitory mechanism of AK from C. glutamicum. A putative Lys-binding site and the inhibitory mechanism of CgAK are discussed.

Purification, crystallization and preliminary X-ray analysis of the regulatory subunit of aspartate kinase from Thermus thermophilus

Aspartate kinase (AK) from Thermus thermophilus, which catalyzes the first step of threonine and methionine biosynthesis, is regulated via feedback inhibition by the end product threonine. To elucidate the mechanism of regulation of AK, the regulatory subunit (the beta subunit of T. thermophilus AK) was crystallized in the presence of the inhibitor threonine. Diffraction data were collected to 2.15 A at a synchrotron source. The crystal belongs to the cubic space group P4(3)32 or P4(1)32, with unit-cell parameters a = b = c = 141.8 A.

Characterization of monofunctional aspartate kinase genes in maize and their relationship with free amino acid content in the endosperm

A quantitative trait locus has previously been identified in maize (Zea mays L.) that influences the level of free amino acids in the endosperm, especially those from the aspartate pathway: lysine, threonine, methionine, leucine, and isoleucine. Because this locus occurs in a region of the genome containing ask2, a monofunctional aspartate kinase, the nature of the monofunctional aspartate kinase genes in the parental inbreds, Oh545o2 and Oh51Ao2, was investigated. Two genes, Ask1 and Ask2 were isolated, and Ask2 was mapped to the ask2 locus. Nucleotide sequence analysis of the Ask2 alleles from Oh545o2 and Oh51Ao2 showed they differ by one amino acid. Both alleles complemented a yeast aspartate kinase mutant, hom3, and based on the growth of the yeast mutant it appeared that Ask2-Oh545o2 produces an enzyme with greater total activity than that encoded by the Oh51Ao2 allele. The results suggest that the higher level of free amino acids derived from the aspartate pathway in Oh545o2 endosperm results from a single amino acid change in the ASK2 enzyme that has pleiotropic effects on its activity.

The initial step in the archaeal aspartate biosynthetic pathway catalyzed by a monofunctional aspartokinase

The activation of the beta-carboxyl group of aspartate catalyzed by aspartokinase is the commitment step to amino-acid biosynthesis in the aspartate pathway. The first structure of a microbial aspartokinase, that from Methanococcus jannaschii, has been determined in the presence of the amino-acid substrate L-aspartic acid and the nucleotide product MgADP. The enzyme assembles into a dimer of dimers, with the interfaces mediated by both the N- and C-terminal domains. The active-site functional groups responsible for substrate binding and specificity have been identified and roles have been proposed for putative catalytic functional groups.

Structures of R- and T-stateEscherichia coliAspartokinase III

Aspartokinase III (AKIII) from Escherichia coli catalyzes an initial commitment step of the aspartate pathway, giving biosynthesis of certain amino acids including lysine. We report crystal structures of AKIII in the inactive T-state with bound feedback allosteric inhibitor lysine and in the R-state with aspartate and ADP. The structures reveal an unusual configuration for the regulatory ACT domains, in which ACT2 is inserted into ACT1 rather than the expected tandem repeat. Comparison of R- and T-state AKIII indicates that binding of lysine to the regulatory ACT1 domain in R-state AKIII instigates a series of changes that release a "latch", the beta15-alphaK loop, from the catalytic domain, which in turn undergoes large rotational rearrangements, promoting tetramer formation and completion of the transition to the T-state. Lysine-induced allosteric transition in AKIII involves both destabilizing the R-state and stabilizing the T-state tetramer. Rearrangement of the catalytic domain blocks the ATP-binding site, which is therefore the structural basis for allosteric inhibition of AKIII by lysine.

A novel organization of ACT domains in allosteric enzymes revealed by the crystal structure of Arabidopsis aspartate kinase

Asp kinase catalyzes the first step of the Asp-derived essential amino acid pathway in plants and microorganisms. Depending on the source organism, this enzyme contains up to four regulatory ACT domains and exhibits several isoforms under the control of a great variety of allosteric effectors. We report here the dimeric structure of a Lys and S-adenosylmethionine-sensitive Asp kinase isoform from Arabidopsis thaliana in complex with its two inhibitors. This work reveals the structure of an Asp kinase and an enzyme containing two ACT domains cocrystallized with its effectors. Only one ACT domain (ACT1) is implicated in effector binding. A loop involved in the binding of Lys and S-adenosylmethionine provides an explanation for the synergistic inhibition by these effectors. The presence of S-adenosylmethionine in the regulatory domain indicates that ACT domains are also able to bind nucleotides. The organization of ACT domains in the present structure is different from that observed in Thr deaminase and in the regulatory subunit of acetohydroxyacid synthase III.

Identification of six novel allosteric effectors of Arabidopsis thaliana aspartate kinase-homoserine dehydrogenase isoforms. Physiological context sets the specificity

The Arabidopsis genome contains two genes predicted to code for bifunctional aspartate kinase-homoserine dehydrogenase enzymes (isoforms I and II). These two activities catalyze the first and the third steps toward the synthesis of the essential amino acids threonine, isoleucine, and methionine. We first characterized the kinetic and regulatory properties of the recombinant enzymes, showing that they mainly differ with respect to the inhibition of the homoserine dehydrogenase activity by threonine. A systematic search for other allosteric effectors allowed us to identify an additional inhibitor (leucine) and 5 activators (alanine, cysteine, isoleucine, serine, and valine) equally efficient on aspartate kinase I activity (4-fold activation). The six effectors of aspartate kinase I were all activators of aspartate kinase II activity (13-fold activation) and displayed a similar specificity for the enzyme. No synergy between different effectors could be observed. The activation, which resulted from a decrease in the Km values for the substrates, was detected using low substrates concentrations. Amino acid quantification revealed that alanine and threonine were much more abundant than the other effectors in Arabidopsis leaf chloroplasts. In vitro kinetics in the presence of physiological concentrations of the seven allosteric effectors confirmed that aspartate kinase I and II activities were highly sensitive to changes in alanine and threonine concentrations. Thus, physiological context rather than enzyme structure sets the specificity of the allosteric control. Stimulation by alanine may play the role of a feed forward activation of the aspartate-derived amino acid pathway in plant.

Characterization of the aspartate kinase from Saccharomyces cerevisiae and of its interaction with threonine

Aspartate kinase (AK) from Saccharomyces cerevisiae has been characterized to elucidate its quaternary structure and the effect of the allosteric inhibitor threonine on the enzyme conformation. The homogeneously purified enzyme was inhibited by threonine (K(i) 1.4 mM) and was found to bind this compound (K(d) 0.97 mM) in a hyperbolic manner. Gel filtration and native gel electrophoresis indicated that yeast AK is a homohexamer of 346 kDa composed by 58 kDa subunits. Threonine caused a decrease in the apparent molecular mass of AK as evidenced by size-exclusion chromatography (from 345 to 280 kDa) and blue native gel electrophoresis (from 346 to 297 kDa); no other molecular species were detected. This shift in the hydrodynamic size was threonine-specific and was reversed by rechromatography in the absence of threonine. No change in the apparent molecular mass was induced by threonine in an AK mutant insensitive to inhibition by this amino acid, which was observed to be unable to bind threonine. These results indicate that the allosteric transition elicited by binding of threonine to yeast AK involves a large conformational change of the protein that isomerizes from a relaxed active conformation to a more compact inactive one of smaller molecular dimensions.

Conversion of feedback regulation in aspartate kinase by domain exchange

To elucidate the mechanism for the regulation of aspartate kinase (AK) via feedback inhibition, we constructed several chimeric enzymes between Bacillus subtilis AK II, a lysine-sensitive mesophilic enzyme, and Thermus flavus AK, a threonine-sensitive thermostable enzyme, each having the same alpha2beta2-type tetrameric structure. A chimeric AK, named BTT, composed of the chimeric alpha subunit that comprises of the N-terminal catalytic region from B. subtilis AK II and the C-terminal region from T. flavus, and the beta subunit from T. flavus, was inhibited only by threonine. Another chimeric enzyme, BT, which has a similar structure to that of BTT but lacks the beta subunit, having alpha2-type homo-dimeric structure, was also responsive only to threonine. However, the addition of threonine enhanced the activity of BT. These results indicate the regulatory function of C-terminal region and beta subunit in AK. BTT showed extremely high thermostability comparable to that of T. flavus, suggesting that the beta subunit also contributed to the stability of the AK.

Site-directed mutagenesis of Escherichia coli acetylglutamate kinase and aspartokinase III probes the catalytic and substrate-binding mechanisms of these amino acid kinase family enzymes and allows three-dimensional modelling of aspartokinase

We test, using site-directed mutagenesis, predictions based on the X-ray structure of N-acetyl-L-glutamate kinase (NAGK), the paradigm of the amino acid kinase protein family, about the roles of specific residues on substrate binding and catalysis. The mutations K8R and D162E decreased V([sustrate]= infinity ) 100-fold and 1000-fold, respectively, in agreement with the predictions that K8 catalyzes phosphoryl transfer and D162 organizes the catalytic groups. R66K and N158Q increased selectively K(m)(Asp) three to four orders of magnitude, in agreement with the binding of R66 and N158 to the C(alpha) substituents of NAG. Mutagenesis in parallel of aspartokinase III (AKIII phosphorylates aspartate instead of acetylglutamate), another important amino acid kinase family member of unknown 3-D structure, identified in AKIII two residues, K8 and D202, that appear to play roles similar to those of K8 and D162 of NAGK, and supports the involvement of E119 and R198, similarly to R66 and N158 of NAGK, in the binding of the amino acid substrate, apparently interacting, respectively, with the alpha-NH(3)(+) and alpha-COO(-) of aspartate. These results and an improved alignment of the NAGK and AKIII sequences have guided us into 3-D modelling of the amino acid kinase domain of AKIII using NAGK as template. The model has good stereochemistry and validation parameters. It provides insight into substrate binding and catalysis, agreeing with mutagenesis results with another aspartokinase that were not considered when building the model.AKIII is homodimeric and is inhibited by lysine. Lysine may bind to a regulatory region that is C-terminal to the amino acid kinase domain. We make a C-terminally truncated AKIII (AKIIIt) and show that the C-region is involved in intersubunit interactions, since AKIIIt is found to be monomeric. Further, it is inactive, as demanded if dimer formation is essential for activity. Models for AKIII architecture are proposed that account for these findings.

Functionally important amino acids in Saccharomyces cerevisiae aspartate kinase

Saccharomyces cerevisiae aspartate kinase (AK(Sc)) phosphorylates L-Asp as the first step in the aspartate pathway responsible for the biosynthesis of L-Thr, L-Met, and L-Ile in microorganisms and plants. Using site-directed mutagenesis, we have evaluated the importance of residues in AK(Sc) that are strongly conserved among aspartate kinases or in other small molecule kinases. Steady state kinetic analysis of the purified AK(Sc) variants reveals that several of the targeted amino acids, particularly K18 and H292, have important roles in the enzymatic reaction. These results provide the first identification of amino acid residues crucial to the action of this important metabolic enzyme.

[Comparative characteristics of physico-chemical and regulating properties of aspartate kinases from three species of cyanobacteria]

Aspartokinases have been isolated from the cell-free extracts of Plectonema boryanum, Anabaena variabilis and Synechococcus cedrorum. Their physico-chemical characteristics and peculiarities of retroregulation by amino acids were studied. It has been shown that in P. boryanum cells aspartokinase reaction is catalyzed by only one enzyme, which is similar to the previously described bacterial origin enzymes. Three izoenzymes, which differ in their main properties and amino acids-effectors, have been founded in the cells of A. variabilis. One enzyme with aspartokinase activity, which differs from other cyanobacteria enzymes in some physico-chemical features has been founded in the cells of S. cedrorum.

Purification, crystallization and preliminary X-ray analysis of aspartokinase III from Escherichia coli

Aspartokinase III catalyzes the commitment step in the aspartate metabolism pathway, the phosphorylation of aspartic acid. The Escherichia coli enzyme has been crystallized in the presence of its natural substrate (aspartic acid) and Mg-ADP and diffraction data has been collected at a synchroton source. The crystals belong to the orthorhombic space group C222(1), with unit-cell parameters a = 60.44, b = 190.31, c = 99.55 A, and data 99.3% complete to 2.7 A. Solving the structure of AK III will provide the first structure of an aspartokinase from any organism.

Mutation analysis of the feedback inhibition site of aspartokinase III of Escherichia coli K-12 and its use in L-threonine production

Aspartokinase III (AKIII), one of three isozymes of Escherichia coli K-12, is inhibited allosterically by L-lysine. This enzyme is encoded by the lysC gene and has 449 amino acid residues. We analyzed the feedback inhibition site of AKIII by generating various lysC mutants in a plasmid vector. These mutants conferred resistance to L-lysine and/or an L-lysine analogue on their host. The inhibitory effects of L-lysine on and heat tolerance of 14 mutant enzymes were examined and DNA sequencing showed that the types of mutants were 12. Two hot spots, amino acid residue positions 318-325 and 345-352, were detected in the C-terminal region of AKIII and these enzyme regions may be important in L-lysine-mediated feedback inhibition of AKIII. Feedback resistant lysC relieved on L-threonine hyper-producing strain, B-3996, from reduced L-threonine productivity by addition of L-lysine, and furthermore increased L-threonine productivity even when no addition of L-lysine. It suggested that the bottleneck of L-threonine production of B-3996 was AK and feedback resistant lysC was effective because of the strict inhibition by cytoplasmic L-lysine.

The central enzymes of the aspartate family of amino acid biosynthesis

The aspartate pathway is responsible for the biosynthesis of lysine, threonine, isoleucine, and methionine in most plants and microorganisms. The absence of this pathway in humans and animals makes the central enzymes potential targets for inhibition, with the aim of developing new herbicides and biocides, and also for enhancement, to improve the nutritional value of crops. Our current state of knowledge of these enzymes is reviewed, including recently determined structural information and newly constructed bifunctional fusion enzymes.

Mutations that cause threonine sensitivity identify catalytic and regulatory regions of the aspartate kinase of Saccharomyces cerevisiae

The HOM3 gene of Saccharomyces cerevisiae encodes aspartate kinase, which catalyses the first step in the branched pathway leading to the synthesis of threonine and methionine from aspartate. Regulation of the carbon flow into this pathway takes place mainly by feedback inhibition of this enzyme by threonine. We have isolated and characterized three HOM3 mutants that show growth inhibition by threonine due to a severe, threonine-induced reduction of the carbon flow into the aspartate pathway, leading to methionine limitation. One of the mutants has an aspartate kinase which is 30-fold more strongly inhibited by threonine than the wild-type enzyme. The predicted amino acid substitution in this mutant, A406T, is located in a region associated with the modulation of the enzymatic activity. The other two mutants carry an aspartate kinase with reduced affinity for its substrates, aspartate and ATP. The corresponding amino acid substitutions, K26I and G25D, affect residues located in the vicinity of a highly conserved lysine-phenylalanine-glycine-glycine (KFGG) stretch present in the N-terminal part of the aspartate kinase, to which no function has so far been assigned. We suggest that this region is involved in substrate binding. Mutagenesis of a HOM3 region centred in the KFGG-coding triplets generated alleles that determine threonine sensitivity or auxotrophy for threonine and methionine, but not a phenotype associated with a feedback-resistant aspartate kinase, indicating that this region is not involved in the allosteric response of the enzyme.

Mutational analysis of the feedback sites of lysine-sensitive aspartokinase of Escherichia coli

In Escherichia coli, thrA, metLM, and lysC encode aspartokinase isozymes that show feedback inhibition by threonine, methionine, and lysine, respectively. In vitro chemical mutagenesis of the cloned lysC gene was used to identify residues and regions of the polypeptide essential for feedback inhibition by lysine. The isolated lysine-insensitive mutants were demonstrated to have missense mutations in amino acid residues 323-352, and at position 250 of aspartokinase III.

Subunit structure of lysine sensitive aspartate kinase from spinach leaves

The lysine-sensitive isoenzyme of aspartate kinase was purified to homogeneity from spinach leaves and its subunit composition was studied. The purified preparation had an apparent molecular mass of 280,000 and separated into two subunits- a large subunit with molecular mass of 53,000 and smaller subunit with molecular mass of 17,000 by urea treatment and SDS PAGE. The enzyme molecule has subunit composition of 4 large and 4 small subunits. The activity of the large subunit was stimulated more than two fold by the addition of small subunit and the stimulated activity was inhibited by EGTA. This inhibition could be reversed by Ca++. Further characteristics of the smaller subunit such as heat stability, behavior on ion exchange chromatography, elctrophoretic mobility on polyacrylamide gels, amino acid composition and pattern, presence of trimethyl lysine, its ability to activate other calmodulin stimulated enzymes and its calmodulin-like nature in RIA tests suggested that this subunit is identical to calmodulin.

Cloning and expression of an Arabidopsis thaliana cDNA encoding a monofunctional aspartate kinase homologous to the lysine-sensitive enzyme of Escherichia coli

As in many bacterial species, the first enzymatic reaction of the aspartate-family pathway in plants is mediated by several isozymes of aspartate kinase (AK) that are subject to feedback inhibition by the end-product amino acids lysine or threonine. So far, only cDNAs and genes encoding threonine-sensitive AKs have been cloned from plants. These were all shown to encode polypeptides containing two linked activities, namely AK and homoserine dehydrogenase (HSD), similar to the Escherichia coli thrA gene encoding a threonine-sensitive bifunctional AK/HSD isozyme. In the present report, we describe the cloning of a new Arabidopsis thaliana cDNA that is relatively highly homologous to the E. coli lysC gene encoding the lysine-sensitive AK isozyme. Moreover, similar to the bacterial lysine-sensitive AK, the polypeptide encoded by the present cDNA is monofunctional and does not contain and HSD domain. These observations imply that our cloned cDNA encodes a lysine-sensitive AK. Southern blot hybridization detected a single gene highly homologous to the present cDNA, plus an additional much less homologous gene. This was confirmed by the independent cloning of an additional Arabidopsis cDNA encoding a lysine-sensitive AK (see accompanying paper). Northern blot analysis suggested that the gene encoding this monofunctional AK cDNA is abundantly expressed in most if not all tissues of Arabidopsis.

Molecular characterization of an Arabidopsis thaliana cDNA coding for a monofunctional aspartate kinase

A cDNA clone encoding a monofunctional aspartate kinase (AK, ATP:L-aspartate 4-phosphotransferase, EC 2.7. 2.4) has been isolated from an Arabidopsis thaliana cell suspension cDNA library using a homologous PCR fragment as hybridizing probe. Amplification of the PCR fragment was done using a degenerate primer designed from a conserved region between bacterial monofunctional AK sequences and a primer identical to a region of the A. thaliana bifunctional aspartate kinase-homoserine dehydrogenase (AK-HSDH). By comparing the deduced amino acid sequence of the fragment with the bacterial and yeast corresponding gene products, the highest identity score was found with the Escherichia coli AKIII enzyme that is feedback-inhibited by lysine (encoded by lysC). The absence of HSDH-encoding sequence at the COOH end of the peptide further implies that this new cDNA is a plant lysC homologue. The presence of two homologous genes in A. thaliana is supported by PCR product sequences, Southern blot analysis and by the independent cloning of the corresponding second cDNA (see Tang et al., Plant Molecular Biology 34, pp. 287-294 [this issue]). This work is the first report of cloning a plant putative lysine-sensitive monofunctional AK cDNA. The presence of at least two genes is discussed in relation to possible different physiological roles of their respective product.

Specificity of aspartokinase III from Escherichia coli and an examination of important catalytic residues

Aspartokinase III (AK III) has been purified from a plasmid-containing strain of Escherichia coli. The enzyme shows broad specificity for the phosphoryl acceptor substrate. Structural analogs of aspartic acid with a derivatized alpha-carboxyl group are accepted as alternative substrates by the enzyme. Derivatives at the alpha-amino group are also tolerated by AK III but with diminished catalytic activity. As has been previously observed with aspartokinase I (T. S. Angeles and R. E. Viola, 1992, Biochemistry 31, 799), derivatization of the beta-carboxyl group, which serves as the phosphoryl acceptor, does not prevent catalytic activity. These beta-derivatized analogs are capable of productive binding to these enzymes through a reversal of regiospecificity, making the alpha-carboxyl group available as the phosphoryl acceptor. Chemical modification and pH profile studies have identified the functional groups of cysteine and histidine as being involved in the catalytic activity of AK III.

Effect of different levels of aspartokinase on the lysine production by Corynebacterium lactofermentum

A 2.9-kb SacI fragment containing the ask-asd operon, encoding aspartokinase and aspartatesemialdehyde dehydrogenase, was cloned from an aminoethylcysteine-resistant, lysine-producing Corynebacterium lactofermentum strain. Enzymatic analysis showed that the aspartokinase (ASK) activity was completely resistant to inhibition by mixtures of lysine and threonine. Comparison of the deduced amino acid sequence of the beta submit of the ask gene showed three amino acid residue changes with ask gene encoding wild-type, feedback-sensitive enzymes. Three C. lactofermentum strains, one being aspartokinase-negative, one carrying two ask genes on the chromosome and one having a sixfold higher specific ASK activity than the parental strain, were constructed by transconjugation and electroporation, and used to analyse the role of ASK in the lysine production by C. lactofermentum. The results indicate that, in this study, feed-back-resistant ASK is necessary for high-level lysine production, but dispensable for lysine and diaminopimelate synthesis required for cell growth.

Bacterial aspartate kinase-like activity in human platelet

One form of a group of enzymes known as aspartate kinases, primarily reported in prokaryotes and plants, might also exist in animal cells. Here we report the immunodetection of an aspartate kinase-like activity in human platelets using antibodies against the pure form of the enzyme purified from Escherichia coli. Moreover, the enrichment of platelet extracts with the bacterial kinase results in the phosphorylation of discrete forms mainly of membrane-bound endogenous polypeptides.

[Aspartate kinase complex of Anabaena variabilis during the early period of development of cyanophage A-1]

Aspartate kinase activity in cells of A. variabilis has been studied in the dynamics of development of virus infection. An early period of reproduction of cyanophage A-1 has been determined to be conjugated with the increase of biosynthesis of amino acids from aspartate family. Five isoenzymes of aspartate kinase were isolated and purified from A. variabilis cells during early development period of cyanophage A-1. Physicochemical properties and influence of amino acids of aspartate family on the activity of homogeneous isoenzymes have been studied. Retroinhibition effect was not observed in infected cyanobacteria cells, which probably enables one to increase 2-7 times the concentration of amino acids in a cell. Such an increase of the amino acids pool is apparently necessary for realization of viral genome strategy.

[Aspartate kinase activity of Cyanobacteria Anabaena variabilis]

Aspartate-kinase (ASK) activity of filamentous cyanobacteria A. variabilis and its dependence on physico-chemical factors and substrate concentration in the reaction mixture have been studied. Three isoenzymes ASK-1, ASK-2 and ASK-3 which differ in the values of pH-optima, molecular weight, isoelectric points and effector of retro-inhibition have been isolated by ion-exchange chromatography. High level of inhibition of summary ASK of the cell-free extract can be reached only in a case of simultaneous addition of all amino acids, the final products of this biosynthetic pathway into the incubation mixture.

Role of serine 352 in the allosteric response of Serratia marcescens aspartokinase I-homoserine dehydrogenase I analyzed by using site-directed mutagenesis

Aspartokinase I and homoserine dehydrogenase I (AKI-HDI) from Serratia marcescens Sr41 are encoded by the thrA gene as a single polypeptide chain. Previously, a single amino acid substitution of Ser-352 with Phe was shown to produce an AKI-HDI enzyme that is not subject to threonine-mediated feedback inhibition. To determine the role of Ser-352 in the allosteric response, the thrA gene was modified by using site-directed mutagenesis so that Ser-352 of the wild-type AKI-HDI was replaced by Ala, Arg, Asn, Gln, Glu, His, Leu, Met, Pro, Thr, Trp, Tyr, or Val. The Thr-352 and Pro-352 replacements rendered AKIs sensitive to threonine. The Tyr-352 and Asn-352 substitutions led to activation, rather than inhibition, of AKI by threonine. The other replacements conferred threonine insensitivity on AKI. The threonine sensitivity of HDI was also changed by the amino acid substitutions at Ser-352. The HDI carried by the Tyr-352 mutant AKI-HDI was activated by threonine. Single amino acid replacements at Ser-352 by Ala, Asn, Gln, His, Phe, Pro, Thr, or Tyr were introduced into truncated AKI-HDIs containing the AKI and the central regions. The AKI activity of the truncated AKI-HDI containing the first 468 amino acid residues was sensitive to threonine, and introduction of the amino acid replacements did not alter the threonine sensitivity of the AKI. Another truncated AKI-HDI containing the first 462 amino acid residues possessed threonine-resistant AKI, whereas the substitutions of Ser-352 with Ala and Pro rendered AKI sensitive to threonine. The replacement of GIn-351 with Phe activated AK1 of the truncated AKI-HDI in the presence of L-threonine. These findings suggest that Ser-352 of the central region of AKI-HDI is possibly a key residue involved with the allosteric regulation of both AKI and HDI activities.

[Isolation, purification and various properties of aspartate kinase from the cyanobacterium Plectonema boryanum]

The enzymic activity of aspartate kinase from filamentous cyanobacteria Plectonema boryanum at the logarithmic phase of growth has been studied. Aspartate kinase was purified eleven times and extracted in functionally homogeneous state from the cell-free extract by the methods of ammonium sulphate salting-out, ion-exchange chromatography and isoelectric focusing. Some physical and chemical characteristics of the enzyme have been studied: pI-7.2; optimum pH-9.0; optimum temperature-55 degrees C. The dependence of enzymatic reaction on concentration of substrates, co-enzymes, cofactors and protein has been established. Regulation of aspartate kinase activity by amino acids of the aspartate family has been investigated. L-threonine, L-homoserine and L-isoleucine (0.01-0.001 M) have a pronounced inhibitory effect. L-lysine and L-methionine are not immediate inhibitors of aspartate kinase but intensify the inhibitory effect of threonine by the cumulative mechanism.