Lysine-insensitive aspartate kinase in two threonine-overproducing mutants of maize

Aspartate kinase (AK; EC 2.7.2.A) catalyzes the first reaction in the biosynthesis pathway for aspartate-derived amino acids in plants. Aspartate kinase was purified from wildtype and two maize (Zea mays L.) genotypes carrying unlinked dominant mutations,Ask LT19 andAsk2 -LT20, that conferred overproduction of threonine, lysine, methionine and isoleucine. The objective of this investigation was to characterize the AKs from mutant and wildtype plants to determine their role in regulating the synthesis of aspartate-derived amino acids in maize. Kernels of the homozygousAsk2 mutant exhibited 174-, 10-, 13- and 2-fold increases in, in this sequence, free threonine, lysine, methionine and isoleucine, compared to wildtype. In wildtype maize, AK was allosterically feedback-inhibited by lysine with 10 μMl-lysine required for 50% inhibition. In contrast, AK purified from the isogenic heterozygousAsk and homozygousAsk2 mutants required 25 and 760 μM lysine for 50% inhibition, respectively, indicating thatAsk andAsk2 were separate structural loci for lysine-regulated AK subunits in maize. Further characterization of purified AK from the homozygous mutantAsk2 line indicated altered substrate and lysine inhibition kinetics. The apparent Hill coefficient was 0.7 for the mutantAsk2 AK compared with 1.6 for the wildtype enzyme, indicating that the mutant allele conferred the loss of a lysinebinding site to the mutant AK. Lysine appeared to be a linear noncompetitive inhibitor ofAsk2 AK with respect to MgATP and an uncompetitive inhibitor with respect to aspartate compared to S-parabolic, I parabolic noncompetitive inhibition of wildtype AK. Reduced lysine sensitivity of theAsk2 gene product appeared to reduce the lysine inhibition of all of the AK activity detected in homozygousAsk2 plants, indicating that maize AK is a heteromeric enzyme consisting of the two lysine-sensitive polypeptides derived from theAsk andAsk2 structural genes. Scientific paper No. 17419, Minnesota Agricultural Experiment Station projects No. 0302-4813-56 and No. 0302-4818-32 This research was supported in part by the U.S. Depatment of Agriculture Competitive Research Grants Office grant 86-CRCR-1-2019. The authors are grateful to Charles Grissom for providing the computer programs in an IBM-PC format.     

Tissue culture isolation of a second mutant locus for increased threonine accumulation in maize

Summary Regenerable maize (Zea mays L.) tissue cultures were selected for ability to grow in the presence of inhibitory (1.0–1.5 mM) concentrations of L-lysine plus L-threonine. Testcross kernels from one regenerated plant (LT20) segregated for wild-type and high free threonine concentration in a 11 ratio consistent with a single dominant gene for high free threonine. Free threonine concentrations (nmol/mg dry weight) increased an average of 29-fold in bulked F₂ kernel samples from heterozygous mutant plants, and the total (free plus protein-bound) threonine concentration increased 68%. Increases in protein-bound methionine, lysine and glycine concentrations were also noted, suggesting a possible effect of the mutation on protein concentration and composition. Allelism tests with a previously selected mutant line, Ltr ^*19, showed that two unlinked, codominant genes conditioned the high free threonine phenotype. Based on a separate study of aspartate kinase feedback inhibition characteristics in the two mutant lines, we propose that the mutant alleles [gene and allele designations are according to guidelines for maize genetic nomenclature (Burnham et al. 1975)] be designated Ask-LT19 and Ask2-LT20 for the Ltr ^*19 and LT20 mutants, respectively.     

Threonine accumulation in the seeds of a barley mutant with an altered aspartate kinase

Barley (Hordeum vulgare L.) mutants altered in the regulation of synthesis of aspartate-derived amino acids were sought by screening embryos for growth on a medium containing lysine plus threonine. One mutant, Rothamsted 2501, was selected with good growth. From the segregation of resistance in the following generations, it was concluded that the resistance was conferred by a dominant gene, Lt1. No homozygous Lt1/Lt1 fertile plants have been recovered. Partially purified aspartate kinase preparations from resistant and sensitive plants were separated on DEAE-cellulose chromatography into three peaks of activity (I, II, III) and the feedback regulatory properties of these peaks determined. These peaks are considered to be three isozymic forms of aspartate kinase, one predominantly sensitive to threonine and two sensitive to lysine or lysine plus S-adenosyl methionine. The feedback characteristics of one of the peaks of aspartate kinase activity from resistant plants were changed such that lysine was half-maximally inhibitory at 10 rather than 0.4mm. Increases in the concentrations of the free pools of threonine (4×) and methionine (2×) were measured in young plants grown on a basal medium. Threonine in the soluble fraction of mature seeds from resistant plants was increased from 0.8 to 9.6% of the total threonine content. The total content of both threonine and methionine of the seeds was increased by 6% compared with grain of similar nitrogen content.S.E.R. acknowledges the receipt of a Council of Europe Scholarship through The British Council. Part of this was also supported by EEC Grant 473.     

High threonine producer mutant ofNicotiana sylvestris (Spegg. and Comes)

Summary Mutagenesis and the subsequent selection of mesophyll diploid protoplasts ofNicotiana sylvestris on growth inhibitory concentrations of lysine plus threonine has led to the isolation of an LT-resistant mutant. Regeneration of this line (RLT 70) and analysis of its descendants demonstrated the dominant monogenic nuclear character of the resistance gene, further namedak-LT1. When the inhibition properties of aspartate kinase were examined in the homozygous mutant, lysine-sensitive activity could no longer be detected. In comparison, 70%–80% of the wild-type enzyme activity was usually inhibited by lysine, and the rest by threonine. Evidence for the existence of at least two AK isoenzymes was obtained by ion-exchange chromatography, where two peaks of activity could be detected: the first one to be eluted is lysine sensitive, and the second one threonine sensitive. One consequence of the altered regulation of AK in the mutant was the enhanced production of soluble threonine. Threonine accumulation was observed to occur throughout the life cycle of the mutant plant as well as in its different organs. In particular, leaves exhibited a 45-fold increment of soluble threonine, which corresponds to a 13-fold increase in total threonine: almost one-third of the total amino acids was free and proteinbound threonine. In RLT 70 seeds, 20% of the free amino acid pool was in the form of threonine (70-fold accumulation compared to the wild type), and total threonine content was increased five fold. As a general rule, the other amino acids were also more abundant in RLT 70 seeds, such that the total of amino acids present was between two to four times higher, but in contrast with the situation encountered in leaves, this was also due to a higher protein-bound amino acid content.     

Enhanced levels of free and protein-bound threonine in transgenic alfalfa (Medicago sativa L.) expressing a bacterial feedback-insensitive aspartate kinase gene

Threonine, lysine, methionine, and tryptophan are essential amino acids for humans and monogastric animals. Many of the commonly used diet formulations, particularly for pigs and poultry, contain limiting amounts of these amino acids. One approach for raising the level of essential amino acids is based on altering the regulation of their biosynthetic pathways in transgenic plants. Here we describe the first production of a transgenic forage plant, alfalfa (Medicago sativa L.) with modified regulation of the aspartate-family amino acid biosynthetic pathway. This was achieved by over-expressing the Escherichia coli feedback-insensitive aspartate kinase (AK) in transgenic plants. These plants showed enhanced levels of both free and protein-bound threonine. In many transgenic plants the rise in free threonine was accompanied by a significant reduction both in aspartate and in glutamate. Our data suggest that in alfalfa, AK might not be the only limiting factor for threonine biosynthesis, and that the free threonine pool in this plant limits its incorporation into plant proteins.     

Lysine and threonine metabolism are subject to complex patterns of regulation in Arabidopsis

To study the regulation of lysine and threonine metabolism in plants, we have transformed Arabidopsis thaliana with chimeric genes encoding the two bacterial enzymes dihydrodipicolinate synthase (DHPS) and aspartate kinase (AK). These bacterial enzymes are much less sensitive to feedback inhibition by lysine and threonine than their plant counterparts. Transgenic plants expressing the bacterial DHPS overproduced lysine, but lysine levels were quite variable within and between transgenic genotypes and there was no direct correlation between the levels of free lysine and the activity of DHPS. The most lysine-overproducing plants also exhibited abnormal phenotypes. However, these phenotypes were detected only at early stages of plant growth, while at later stages, new buds emerged that looked completely normal and set seeds. Wild-type plants exhibited relatively high levels of free threonine, suggesting that in Arabidopsis AK regulation may be more relaxed than in other plants. This was also supported by the fact that expression of the bacterial AK did not cause any dramatic elevation in this amino acid. Yet, the relaxed regulation of threonine synthesis in Arabidopsis was not simply due to a reduced sensitivity of the endogenous AK to feedback inhibition by lysine and threonine because growth of wild-type plants, but not of transgenic plants expressing the bacterial AK, was arrested in media containing these two amino acids. The present results, combined with previous studies from our laboratory, suggest that the regulation of lysine and threonine metabolism is highly variable among plant species and is subject to complex biochemical, physiological and environmental controls. The suitability of these transgenic Arabidopsis plants for molecular and genetic dissection of lysine and threonine metabolism is also discussed.     

Engineering of the aspartate family biosynthetic pathway in barley (Hordeum vulgare L.) by transformation with heterologous genes encoding feed-back-insensitive aspartate kinase and dihydrodipicolinate synthase

In prokaryotes and plants the synthesis of the essential amino acids lysine and threonine is predominantly regulated by feed-back inhibition of aspartate kinase (AK) and dihydrodipicolinate synthase (DHPS). In order to modify the flux through the aspartate family pathway in barley and enhance the accumulation of the corresponding amino acids, we have generated transgenic barley plants that constitutively express mutant Escherichia coli genes encoding lysine feed-back insensitive forms of AK and DHPS. As a result, leaves of primary transformants (T₀) exhibited a 14-fold increase of free lysine and an 8-fold increase in free methionine. In mature seeds of the DHPS transgenics, there was a 2-fold increase in free lysine, arginine and asparagine and a 50% reduction in free proline, while no changes were observed in the seeds of the two AK transgenic lines analysed. When compared to that of control seeds, no differences were observed in the composition of total amino acids. The introduced genes were inherited in the T₁ generation where enzymic activities revealed a 2.3-fold increase of AK activity and a 4.0–9.5-fold increase for DHPS. T₁ seeds of DHPS transformants showed the same changes in free amino acids as observed in T₀ seeds. It is concluded that the aspartate family pathway may be genetically engineered by the introduction of genes coding for feed-back-insensitive enzymes, preferentially giving elevated levels of lysine and methionine.     

Aspartate kinase and the synthesis of aspartate-derived amino acids in wheat

Aspartate kinase (EC 2.7.2.4.) has been purified from 7 day etiolated wheat (Triticum aestivum L. var. Maris Freeman) seedlings and from embryos imbibed for 8 h. The enzyme was 50% inhibited by 0.25 mM lysine. In this study wheat aspartate kinase was not inhibited by threonine alone or cooperatively with lysine; these results contrast with those published previously. In vivo regulation of the synthesis of aspartate-derived amino acids was examined by feeding [¹⁴C]acetate and [³⁵S]sulphate to 2–3 day germinating wheat embryos in culture in the presence of exogenous amino acids. Lysine (1 mM) inhibited lysine synthesis by 86%. Threonine (1 mM) inhibited threonine synthesis by 79%. Lysine (1 mM) plus threonine (1 mM) inhibited threonine synthesis by 97%. Methionine synthesis was relatively unaffected by these amino acids, suggesting that there are important regulatory sites other than aspartate kinase and homoserine dehydrogenase. [³⁵S]sulphate incorporation into methionine was inhibited 50% by lysine (2 mM) plus threonine (2 mM) correlating with the reported 50% inhibition of growth by these amino acids in this system. The synergistic inhibition of growth, methionine synthesis and threonine synthesis by lysine plus threonine is discussed in terms of lysine inhibition of aspartate kinase and threonine inhibition of homoserine dehydrogenase.Abbreviations AEC S-(2-aminoethyl) cysteine     

Lysine and threonine biosynthesis in sorghum seeds: characterisation of aspartate kinase and homoserine dehydrogenase isoenzymes

Aspartate kinase (AK, EC 2.7.2.4) and homoserine dehydrogenase (HSDH, EC 1.1.1.3) have been partially purified and characterised from immature sorghum seeds. Two peaks of AK activity were eluted by anion‐exchange chromatography [diethylaminoethyl (DEAE)‐Sephacel] with 183 and 262 mM KCl, and both activities were inhibited by lysine. Similarly, two peaks of HSDH activity were eluted with 145 and 183 mM KCl; the enzyme activity in the first peak in elution order was shown to be resistant to threonine inhibition, whereas the second was sensitive to threonine inhibition. However, following gel filtration chromatography (Sephacryl S‐200), one peak of AK activity co‐eluted with HSDH and both activities were sensitive to threonine inhibition, suggesting the presence of a bifunctional threonine‐sensitive AK–HSDH isoenzyme with a molecular mass estimated as 167 kDa. The activities of AK and HSDH were studied in the presence of lysine, threonine, methionine, valine, calcium, ethylene glycol bis(2‐aminoethylether)‐N,N,N′N′‐tetraacetic acid, calmodulin, S‐adenosylmethionine (SAM), S‐2‐aminoethyl‐l ‐cysteine (AEC) and increasing concentrations of KCl. AK was shown to be inhibited by threonine and lysine, confirming the existence of two isoenzymes, one sensitive to threonine and the other sensitive to lysine, the latter being predominant in sorghum seeds. Methionine, SAM plus lysine and AEC also inhibited AK activity; however, increasing KCl concentrations and calcium did not produce any significant effect on AK activity, indicating that calcium does not play a role in AK regulation in sorghum seeds. HSDH also exhibited some inhibition by threonine, but the majority of the activity was not inhibited, thus indicating the existence of a threonine‐sensitive isoenzyme and a second predominant threonine‐insensitive isoenzyme. Valine and SAM plus threonine also inhibited HSDH; however, increasing concentrations of KCl and calcium had no inhibitory effect.     

Two Feedback-Insensitive Enzymes of the Aspartate Pathway in Nicotiana sylvestris

Lysine and threonine overproducer mutants in Nicotiana sylvestris, characterized by an altered regulation of, respectively, dihydrodipicolinate synthase and aspartate kinase activities, were crossed to assess the effects of the simultaneous presence of these genes on the biosynthesis of aspartate-derived amino acids. The monogenic dominant behavior of both resistance traits was confirmed, and their loci were found to be unlinked. Study of the inhibition properties of dihydrodipicolinate synthase and aspartate kinase activities in RAEC-1 × RLT 70 confirmed the heterozygote state of both mutations, because only half of their lysine-sensitive activity could still be inhibited by this negative effector. Analysis of the free amino acid pool during the growth of the double mutant revealed a major free lysine overproduction reaching up to 50% of the total pool, whereas the other aspartate-derived amino acids remained equally or even less abundant than in the wild type. An abnormal phenotype was clearly associated with such high levels of lysine accumulation, which points out the possible role of this amino acid in the developmental features of the plant. Comparison of the amino acid content, free and total (free + protein-bound), between the wild type, the two mutants, and the double mutant obtained by crossing them brings new insights on the regulation of the aspartate pathway, and on its implications in relationship to plant nutritional value improvement.     

Metabolic engineering of a complex biochemical pathway: The lysine and threonine biosynthesis as an example

The nutritional quality of crop plants is determined by their content in essential amino acids provided in food for humans or in feed for monogastric animals. Amino acid composition of crop–based diets can be improved via manipulation of the properties of key enzymes of amino acid biosynthetic pathways by mutation and transformation. We focused on the aspartate-derived amino acid pathway producing four essential amino acids: lysine, threonine, isoleucine and methionine. Genes encoding aspartate kinase (AK) and dihydrodipicolinate synthase (DHDPS) that operate as key genes of the aspartate pathway have been cloned from Arabidopsis. Genetic and molecular studies revealed that at least five different ak genes are represented. Some of them were characterized in terms of gene and promoter structure, developmental expression and regulatory properties. In the case of dhdps, two quite identical genes have been identified and characterized at expression level. Mutated genes encoding a fully feedback-insensitive form of the DHDPS enzyme were obtained from Nicotiana sylvestris and Arabidopsis. Several chimeric constructs harbouring this mutated allele under the control of constitutive or seed-specific promoters were transferred via Agrobacterium or biolistics in various plant species. In all cases, lines with significant increase of free lysine content were obtained in vegetative organs, but the impact of the transgene in seeds is limited due to the presence of an active catabolic enzyme, lysine ketoreductase. These results show that, although dealing with a complex, highly regulated pathway, the overexpression of a single gene encoding a feedback-insensitive form of the key enzyme DHDPS exerts a significant effect on the carbon flux through the aspartate pathway towards lysine production.     

Lysine biosynthesis and nitrogen metabolism in quinoa (Chenopodium quinoa): study of enzymes and nitrogen-containing compounds.

Aspartate kinase (AK, EC 2.7.2.4), homoserine dehydrogenase (HSDH, EC 1.1.1.3) and dihydrodipicolinate synthase (DHDPS, EC 4.2.1.52) were isolated and partially purified from immature Chenopodium quinoa Willd seeds. Enzyme activities were studied in the presence of the aspartate-derived amino acids lysine, threonine and methionine and also the lysine analogue S-2-aminoethyl-l-cysteine (AEC), at 1 mM and 5 mM. The results confirmed the existence of, at least, two AK isoenzymes, one inhibited by lysine and the other inhibited by threonine, the latter being predominant in quinoa seeds. HSDH activity was also shown to be partially inhibited by threonine, whereas some of the activity was resistant to the inhibitory effect, indicating the presence of two isoenzymes, one resistant and another sensitive to threonine inhibition. Only one DHDPS isoenzyme highly sensitive to lysine inhibition was detected. The results suggest that the high concentration of lysine observed in quinoa seeds is possibly due to a combined effect of increased lysine synthesis and accumulation in the soluble form and/or as protein lysine. Nitrogen assimilation was also investigated and based on nitrate content, nitrate reductase activity, amino acid distribution and ureide content, the leaves were identified as the predominant site of nitrate reduction in this plant species. The amino acid profile analysis in leaves and roots also indicated an important role of soluble glutamine as a nitrogen transporting compound.     

Synthesis of 2-(d-Arabino-tetra-hydroxybutyl)pyrazine-5-sulfonic Acid

An efficient method for the isolation of dihydrodipicolinate synthase (DPS)-defective threonine producers from a Br evibacterium strain with feedback-sensitive aspartokinase (AK, Ak^s) was established. After mutagenesis of a strain with AK, No. 70, mutants resistant to α-amino-β- hydroxyvaleric acid were isolated and then selected as to threonine productivity in the presence of diaminopimelic acid. DPS activity in the strains in which the threonine production was inhibited by lysine was found to be absent or reduced to less than 10 % of the level in the parent. On the other hand, the strains in which the production was not inhibited by lysine were conventional threonine producers with feedback-resistant homoserine dehydrogenases (HDs and HD^Rs) and wild type DPS. The HD activities of most of the threonine mutants were also markedly reduced. However, only one mutant lacking DPS, DK330, exhibited an HD level comparable to that in the parent and produced the largest amount of threonine among the threonine producers obtained. The formation of HD and HK in strain DK330 was hardly repressed by the addition of methionine. Under the optimum conditions, strain DK330 produced 12.4 g/1 of threonine, while a typical HD type threonine producer, BK29, produced 9.9 g/1.     

Additive effects of the feed-back insensitive bacterial aspartate kinase and the Brazil nut 2S albumin on the methionine content of transgenic narbon bean (Vicia narbonensis L.)

So far two different strategies for engineering high methionine (Met) grain legumes were followed separately in several laboratories: a) The transfer of foreign genes encoding Met-rich proteins, and b) the engineering of Met biosynthesis pathways. In some cases a down regulation of the formation of endogenous sulfur-containing compounds was observed due to the expression of Met-rich foreign proteins. Since this might result from competition of the foreign protein with endogenous compounds for limited Met supply both strategies were combined in the present work. Double transformants of narbon bean (Vicia narbonensis L.) were generated which express seed-specifically the Met-rich Brazil nut 2S albumin (BNA) as well as a feed-back insensitive bacterial aspartate kinase (AK) known to stimulate Met biosynthesis in transgenic tobacco seeds. In order to produce double transformants a homozygous transgenic BNA line of narbon bean was either retransformed with the AK gene or crossed with an AK line. For the first time the influence of a deregulated AK on amino acids of the aspartate pathway was studied in seeds of a transgenic legume. Effects of expressing the foreign genes on inorganic sulphate, free and protein-bound Met and other amino acids of the aspartate pathway as well as on free sulphhydryl compounds of mature seeds were analysed. AK lines had 10 to 12 percent and the BNA line 80 percent increased Met in mature seeds. Double transformants showed additive but not synergistic effects of the expression of AK and BNA gene on seed Met. In their mature seeds protein-bound Met reached levels 2.0 to 2.4 times higher than in the wildtype. The Met level of best line corresponds approximately to the FAO standard for Met in a nutritionally balanced protein for human food or for feeding monogastric animals.     

The effect of aspartate-derived amino acids (lysine,threonine, methionine) on the growth of excised embryos of wheat and barley

Excised wheat (Triticum aestivum L. var. Maris Freeman) and barley (Hordeum vulgare L. var. Maris Mink) embryos were grown on medium containing both nitrate and ammonium ions. Addition of lysine (1 mM) plus threonine (1 mM) caused a synergistic inhibition of growth measured by length of first leaf or dry weight. The inhibition was specifically relieved by methionine, homocysteine and homoserine. Threonine at 0.2–0.3 mM caused half-maximal inhibition of growth at all lysine concentrations whereas lysine increased the synergistic inhibition up to 3 mM. The inhibition is explained by a model in which lysine acts as a feedback inhibitor of aspartate kinase and threonine of homoserine dehydrogenase. This is compatible with published studies of the enzymes involved. The implications of these findings for using lysine plus threonine as a selection system for lysine-overproducing cereals are discussed.Abbreviations Lys Lysine - Thr Threonine - Met Methionine - Hser Homoserine - Hcys Homocysteine     

Enzymes of lysine metabolism from Coix lacryma-jobi seeds

Lysine, threonine, methionine and isoleucine are synthesized through the aspartate metabolic pathway. The concentrations of soluble lysine and threonine in cereal seeds are very low. Coix lacryma-jobi (coix) is a maize-related grass and the enzymological aspects of the aspartate metabolic pathway are completely unknown. In order to obtain information on lysine metabolism in this plant species, two enzymes involved in the biosynthesis of these amino acids (aspartate kinase 〚AK, EC 2.7.2.4〛 and homoserine dehydrogenase 〚HSDH, EC 1.1.1.3〛) and two enzymes involved in lysine degradation (lysine 2-oxoglutarate reductase 〚LOR, EC 1.5.1.8〛 and saccharopine dehydrogenase 〚SDH, EC 1.5.1.9〛) were isolated and partially characterized in coix seeds. AK activity was inhibited by threonine and lysine separately, suggesting the presence of two isoenzymes, one sensitive to lysine and the other sensitive to threonine, with the latter corresponding to approximately 60% of the total AK activity. In contrast to previous results from other plant species, the threonine-sensitive AK eluted from an ion exchange chromatography column at higher KCl concentration than the lysine-sensitive form. The HSDH activity extracted from the seeds was partially inhibited by threonine, indicating the presence of threonine-sensitive and threonine-resistant isoenzymes. LOR and SDH activities were detected only in the endosperm tissue and co-purified on an anion exchange chromatography column, suggesting that the two activities may be linked on a single bifunctional polypeptide, as observed for other plant species. One single SDH activity band was observed on non-denaturing PAGE gels. The K_m for saccharopine of SDH was determined as 0.143 mM and the K_m for NAD as 0.531 mM. Although SDH activity was shown to be stable, LOR, AK and HSDH were extremely unstable, under all buffer systems tested.     

Selection and characterization of a feedback-insensitive tissue culture of maize

Tissue culture selection techniques were used to isolate a maize (Zea mays L.) variant D33, in which the aspartate family pathway was less sensitive to feedback inhibition by lysine. D33 was recovered by successively subculturing cultures originally derived from immature embryos on MS medium containing growth-inhibitory levels of lysine+threonine. The ability of D33 to grow vigorously on lysine+ threonine medium was retained after growth for 12 months on nonselection medium. New cultures initiated from shoot tissues of plants regenerated from D33 also were resistant to lysine+threonine inhibition. The K_i of aspartokinase for its feedback inhibitor, lysine, was about 9-fold higher in D33 than for the enzyme from unselected cultures. The free pools of lysine, threonine, isoleucine and methionine were increased 2–9-fold in D33 cultures. This was consistent with the observed change in feedback regulation of aspartokinase, the first enzyme common to the biosynthesis of these amino acids in the aspartate pathway. The accumulated evidence including the stability of resistance in the cultures, the resistance of cultures initiated from regenerated plants, the altered feedback regulation, and the increased free amino acids, indicates a mutational origin for these traits in line D33.Abbreviation LT lysine+threonine in equimolar concentration Paper No. 10880, Scientific Journal Series, Minnesota Agricultural Expertment Station     

Regulatory mechanisms after short‐ and long‐term perturbed lysine biosynthesis in the aspartate pathway: the need for isogenes in Arabidopsis thaliana

The aspartate‐derived amino acid pathway in plants is an intensively studied metabolic pathway, because of the biosynthesis of the four essential amino acids lysine, threonine, isoleucine and methionine. The pathway is mainly controlled by the key regulatory enzymes aspartate kinase (AK; EC 2.7.2.4), homoserine dehydrogenase (HSDH; EC 1.1.1.3) and 4‐hydroxy‐tetrahydrodipicolinate synthase (EC 4.3.3.7), formerly referred to as dihydrodipicolinate synthase (DHDPS). They are encoded by isoenzyme families and it is not known why such families are evolutionarily maintained. To gain more insight into the specific roles and regulation of the isoenzymes, we inhibited DHDPS in Arabidopsis thaliana with the chemical compound (N,N‐dimethylglycinatoboranyloxycarbonylmethyl)‐dimethylamine‐borane (DDAB) and compared the short‐term effects on the biochemical and biomolecular level to the long‐term adaptations in dhdps knockout mutants. We found that DHDPS2 plays a crucial role in controlling lysine biosynthesis, thereby stabilizing flux through the whole aspartate pathway. Moreover, DHDPS2 was also shown to influence the threonine level to a large extent. In addition, the lysine‐sensitive AKs, AKLYS1 and AKLYS3 control the short‐ and long‐term responses to perturbed lysine biosynthesis in Arabidopsis thaliana.     

Aspartate kinase involved in 4-hydroxy-3-nitrosobenzamide biosynthesis in Streptomyces murayamaensis

Streptomyces murayamensis carries two aspartate kinase (AK) genes: one for the biosynthesis of lysine, threonine, and methionine, and the other (nspJ) contained in the biosynthetic gene cluster for the secondary metabolite, 4-hydroxy-3-nitrosobenzamide, for catalyzing the first reaction. AKs involved in the biosynthesis of amino acids are often regulated allosterically by the end products. In the present study, we characterized NspJ to investigate whether AKs involved in secondary metabolism were also allosterically regulated. NspJ was in α₂β₂ and (α₂β₂)₂ heterooligomeric forms, and was insensitive to all the compounds tested including lysine, threonine, and methionine. The reduction in the activity following the removal of ammonium sulfate, which induced subunit dissociation, suggests that the β subunit may be involved in stabilizing the structure of the α subunit in order to exhibit its activity. This study has provided the first example of a feedback-insensitive α₂β₂-type AK, which is involved in the secondary metabolism.     

Arabidopsis loss-of-function mutant in the lysine pathway points out complex regulation mechanisms

In plants, the amino acids lysine, threonine, methionine and isoleucine have L-aspartate-beta-semialdehyde (ASA) as a common precursor in their biosynthesis pathways. How this ASA precursor is dispersed among the different pathways remains vague knowledge. The proportional balances of free and/or protein-bound lysine, threonine, isoleucine and methionine are a function of protein synthesis, secondary metabolism and plant physiology. Some control points determining the flux through the distinct pathways are known, but an adequate explanation of how the competing pathways share ASA in a fine-tuned amino acid biosynthesis network is yet not available. In this article we discuss the influence of lysine biosynthesis on the adjacent pathways of threonine and methionine. We report the finding of an Arabidopsis thaliana dihydrodipicolinate synthase T-DNA insertion mutant displaying lower lysine synthesis, and, as a result of this, a strongly enhanced synthesis of threonine. Consequences of these cross-pathway regulations are discussed.