Synthesis of the Arabidopsis bifunctional lysine-ketoglutarate reductase/saccharopine dehydrogenase enzyme of lysine catabolism is concertedly regulated by metabolic and stress-associated signals

In plants, excess cellular lysine (Lys) is catabolized into glutamic acid and acetyl-coenzyme A; yet, it is still not clear whether this pathway has other functions in addition to balancing Lys levels. To address this issue, we examined the effects of stress-related hormones, abscisic acid (ABA), and jasmonate, as well as various metabolic signals on the production of the mRNA and polypeptide of the bifunctional Lys-ketoglutarate reductase (LKR)/saccharopine dehydrogenase (SDH) enzyme, which contains the first two linked enzymes of Lys catabolism. The level of LKR/SDH was strongly enhanced by ABA, jasmonate, and sugar starvation, whereas excess sugars and nitrogen starvation reduced its level; thus this pathway appears to fulfill multiple functions in stress-related and carbon/nitrogen metabolism. Treatments with combination of hormones and/or metabolites, as well as use of ABA mutants in conjunction with the tester sugars mannose and 3-O-methyl-glucose further supported the idea that the hormonal and metabolic signals apparently operate through different signal transduction cascades. The stimulation of LKR/SDH protein expression by ABA is regulated by a signal transduction cascade that contains the ABI1-1 and ABI2-1 protein phosphatases. By contrast, the stimulation of LKR/SDH protein expression by sugar starvation is regulated by the hexokinase-signaling cascade in a similar manner to the repression of many photosynthetic genes by sugars. These findings suggest a metabolic and mechanistic link between Lys catabolism and photosynthesis-related metabolism in the regulation of carbon/nitrogen partitioning.     

The activity of the Arabidopsis bifunctional lysine-ketoglutarate reductase/saccharopine dehydrogenase enzyme of lysine catabolism is regulated by functional interaction between its two enzyme domains

Lysine-ketoglutarate reductase/saccharopine dehydrogenase (LKR/SDH) is a bifunctional enzyme catalyzing the first two steps of lysine catabolism in animals and plants. To elucidate the biochemical signification of the linkage between the two enzymes of LKR/SDH, namely lysine ketoglutarate and saccharopine dehydrogenase, we employed various truncated and mutated Arabidopsis LKR/SDH polypeptides expressed in yeast. Activity analyses of the different recombinant polypeptides under conditions of varying NaCl levels implied that LKR, but not SDH activity, is regulated by functional interaction between the LKR and SDH domains, which is mediated by the structural conformation of the linker region connecting them. Because LKR activity of plant LKR/SDH enzymes is also regulated by casein kinase 2 phosphorylation, we searched for such potential regulatory phosphorylation sites using matrix-assisted laser desorption/ionization time-of-flight mass spectrometry and site-directed mutagenesis. This analysis identified Ser-458 as a candidate for this function. We also tested a hypothesis suggesting that an EF-hand-like sequence at the C-terminal part of the LKR domain functions in a calcium-dependent assembly of LKR/SDH into a homodimer. We found that this region is essential for LKR activity but that it does not control a calcium-dependent assembly of LKR/SDH. The relevance of our results to the in vivo function of LKR/SDH in lysine catabolism in plants is discussed. In addition, because the linker region between LKR and SDH exists only in plants but not in animal LKR/SDH enzymes, our results suggest that the regulatory properties of LKR/SDH and, hence, the regulation of lysine catabolism are different between plants and animals.     

Purification and characterization of bifunctional lysine-ketoglutarate reductase/saccharopine dehydrogenase from developing soybean seeds

Both in mammals and plants, excess lysine (Lys) is catabolized via saccharopine into alpha-amino adipic semialdehyde and glutamate by two consecutive enzymes, Lys-ketoglutarate reductase (LKR) and saccharopine dehydrogenase (SDH), which are linked on a single bifunctional polypeptide. To study the control of metabolite flux via this bifunctional enzyme, we have purified it from developing soybean (Glycine max) seeds. LKR activity of the bifunctional LKR/SDH possessed relatively high K(m) for its substrates, Lys and alpha-ketoglutarate, suggesting that this activity may serve as a rate-limiting step in Lys catabolism. Despite their linkage, the LKR and SDH enzymes possessed significantly different pH optima, suggesting that SDH activity of the bifunctional enzyme may also be rate-limiting in vivo. We have previously shown that Arabidopsis plants contain both a bifunctional LKR/SDH and a monofunctional SDH enzymes (G. Tang, D. Miron, J.X. Zhu-Shimoni, G. Galili [1997] Plant Cell 9: 1-13). In the present study, we found no evidence for the presence of such a monofunctional SDH enzyme in soybean seeds. These results may provide a plausible regulatory explanation as to why various plant species accumulate different catabolic products of Lys.     

Inhibition of bovine liver lysine-ketoglutarate reductase by urea cycle metabolites and saccharopine

Lysine-ketoglutarate reductase was purified 675-fold from bovine liver mitochondria. Product inhibition studies gave results similar to those reported for this enzyme extracted from other sources. Inhibition studies with L-citrulline exhibited mixed inhibition patterns. No inhibition of the partially-purified enzyme by ammonium salts was detected; in contrast, marked inhibition of the enzyme by ammonium was apparently observed in crude liver homogenates. This was probably due to depletion of NADPH and/or 2-oxoglutarate in the assay mixture as a result of conversion of ammonium to glutamate by glutamate dehydrogenase. A similar explanation could account for the high levels of lysine observed in humans with urea cycle disorders.     

Characterization of the two saccharopine dehydrogenase isozymes of lysine catabolism encoded by the single composite AtLKR/SDH locus of Arabidopsis

Arabidopsis plants possess a composite AtLKR/SDH locus encoding two different polypeptides involved in lysine catabolism: a bifunctional lysine-ketoglutarate reductase/saccharopine dehydrogenase (LKR/SDH) enzyme and a monofunctional SDH enzyme. To unravel the physiological significance of these two enzymes, we analyzed their subcellular localization and detailed biochemical properties. Sucrose gradient analysis showed that the two enzymes are localized in the cytosol and therefore may operate at relatively neutral pH values in vivo. Yet while the physiological pH may provide an optimum environment for LKR activity, the pH optima for the activities of both the linked and non-linked SDH enzymes were above pH 9, suggesting that these two enzymes may operate under suboptimal conditions in vivo. The basic biochemical properties of the monofunctional SDH, including its pH optimum as well as the apparent Michaelis constant (K(m)) values for its substrates saccharopine and nicotinamide adenine dinucleotide at neutral and basic pH values, were similar to those of its SDH counterpart that is linked to LKR. Taken together, our results suggest that production of the monofunctional SDH provides Arabidopsis plants with enhanced levels of SDH activity (maximum initial velocity), rather than with an SDH isozyme with significantly altered kinetic parameters. Excess levels of this enzyme might enable efficient flux of lysine catabolism via the SDH reaction in the unfavorable physiological pH of the cytosol.     

Lysine-ketoglutarate reductase and saccharopine dehydrogenase from Arabidopsis thaliana: nucleotide sequence and characterization

We isolated the gene encoding lysine-ketoglutarate reductase (LKR, EC 1.5.1.8) and saccharopine dehydrogenase (SDH, ED 1.5.1.9) from an Arabidopsis thaliana genomic DNA library based on the homology between the yeast biosynthetic genes encoding SDH (lysine-forming) or SDH (glutamate-forming) and Arabidopsis expressed sequence tags. A corresponding cDNA was isolated from total Arabidopsis RNA using RT-PCR and 5 and 3 Race. DNA sequencing revealed that the gene encodes a bifunctional protein with an amino domain homologous to SDH (lysine-forming), thus corresponding to LKR, and a carboxy domain homologous to SDH (glutamate-forming). Sequence comparison between the plant gene product and the yeast lysine-forming and glutamate-forming SDHs showed 25% and 37% sequence identity, respectively. No intracellular targeting sequence was found at the N-terminal or C-terminal of the protein. The gene is interrupted by 24 introns ranging in size from 68 to 352 bp and is present in Arabidopsis in a single copy. 5 sequence analysis revealed several conserved promoter sequence motifs, but did not reveal sequence homologies to either an Opaque 2 binding site or a Sph box. The 3-flanking region does not contain a polyadenylation signal resembling the consensus sequence AATAAA. The plant SDH was expressed in Escherichia coli and exhibited similar biochemical characteristics to those reported for the purified enzyme from maize. This is the first report of the molecular cloning of a plant LKR-SDH genomic and cDNA sequence.     

Supply of nitrogen can reverse senescence processes and affect expression of genes coding for plastidic glutamine synthetase and lysine-ketoglutarate reductase/saccharopine dehydrogenase

Nitrogen availability has a strong influence on developmental processes in plants. We show that the time of nitrogen supply regulates the course of leaf senescence in flag leaves of Hordeum vulgare . The senescence-specific decrease in chlorophyll content and photosystem II efficiency is clearly delayed when plants are fertilised with nitrate at the onset of leaf senescence. Concurrently, the additional supply of nitrate affects expression patterns of two marker genes of nitrogen metabolism. As shown by quantitative RT-PCR analyses, senescence-specific downregulation of plastidic glutamine synthetase ( GS2 ) and senescence-specific upregulation of lysine-ketoglutarate reductase/saccharopine dehydrogenase ( LKR/SDH ) are both clearly retarded. Depletion of nitrogen in experiments using hydroponic growth systems results in premature primary leaf senescence. The already started senescence processes can be even reversed by later nitrogen addition, as proved by a further increase in photosystem II efficiency and chlorophyll content, returning to the high values of controls which had not been deprived of nitrogen. Although both addition of nitrate or ammonium effectively reversed nitrogen depletion-induced primary leaf senescence, addition of urea did not. Additionally, effects of nitrogen supply on the course of leaf senescence were analysed in the model plant Arabidopsis thaliana. Leaves of A. thaliana show the same reversion of senescence processes after receiving additional nitrogen supply, indicating that the nitrogen response of leaf development is conserved in different plant species.     

Regulation of lysine catabolism in higher plants

Lysine is an essential amino acid for mammals but its concentration in cereals, one of our main food sources, is low. Research over the past 40 years has unraveled many biochemical and molecular details of the aspartic acid pathway, which is the main route of lysine biosynthesis in plants. However, genetic manipulation of this pathway has not been successful at producing high-lysine seeds. This is because lysine, instead of being accumulated, is degraded via the saccharopine pathway. Recent work has increased our knowledge of this pathway, including both the enzymes involved and their regulation.     

Enzymatic measurement of saccharopine with saccharopine dehydrogenase

We have developed an enzymatic method for measuring saccharopine, a key intermediate in lysine metabolism. With the enzyme saccharopine dehydrogenase, saccharopine can be oxidized to lysine and alpha-ketoglutarate with the corresponding conversion of NAD to NADH. The natural equilibrium favors saccharopine formation, but using hydrazine to trap one of the products, alpha-ketoglutarate, shifts the reaction toward quantitative oxidation of saccharopine. A stable endpoint is reached in 15-20 min, and although high concentrations of alpha-ketoglutarate slow the reaction, the end product is fully recovered. Unlike previous assays this technique is specific, convenient, and capable of measuring saccharopine directly in protein-free biological fluids or extracts.     

Purification and properties of saccharopine dehydrogenase (glutamate forming) in the Saccharomyces cerevisiae lysine biosynthetic pathway.

Saccharopine dehydrogenase (glutamate forming) of the biosynthetic pathway of lysine in Saccharomyces cerevisiae was purified 1,122-fold by using acid precipitation, ammonium sulfate precipitation, DEAE-Sepharose, gel filtration, and Reactive Red-120 agarose chromatography. The enzyme exhibited a native molecular size of 69,000 daltons by gel filtration and consisted of a single 50,000-dalton polypeptide based upon sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The enzyme was readily denatured by exposures to temperatures exceeding 46 degrees C. The pH optimum for the reverse reaction was 9.5. The apparent Kms for L-saccharopine and NAD+ were 2.32 and 0.054 mM, respectively. The enzyme was inhibited by mercuric chloride but not by carbonyl or metal complexing agents.     

Conversion of saccharopine to lysine in barley

Labelled saccharopine was synthesized and showed a low conversion to lysine in barley seedlings. The results indicate a role of saccharopine in either lysine biosynthesis or catabolism.     

Supporting role of lysine 13 and glutamate 16 in the acid-base mechanism of saccharopine dehydrogenase from Saccharomyces cerevisiae

Saccharopine dehydrogenase (SDH) catalyzes the NAD+ dependent oxidative deamination of saccharopine to form lysine (Lys) and α-ketoglutarate (α-kg). The active site of SDH has a number of conserved residues that are believed important to the overall reaction. Lysine 13, positioned near the active site base (K77), forms a hydrogen bond to E78 neutralizing it, and contributing to setting the pKa of the catalytic residues to near neutral pH. Glutamate 16 is within hydrogen bond distance to the Nε atom of R18, which has strong H-bonding interactions with the α-carboxylate and α-oxo groups of α-kg. Mutation of K13 to M and E16 to Q decreased kcat by about 15-fold, and primary and solvent deuterium kinetic isotope effects measured with the mutant enzymes indicate hydride transfer is rate limiting for the overall reaction. The pH-rate profiles for K13M exhibited no pH dependence, consistent with an increase in negative charge in the active site resulting in the perturbation in the pKas of catalytic groups. Elimination of E16 affects optimal positioning of R18, which is involved in binding and holding α-kg in the correct conformation for optimum catalysis. In agreement, a ΔΔG°' of 2.60 kcal/mol is estimated from the change in Kα-kg for replacing E16 with Q.     

Purification and characterization of saccharopine dehydrogenase from baker's yeast.

Saccharopine dehydrogenase (N6-(glutar-2-yl)-L-ly-sine:NAD oxidoreductase (L-lysine-forming)) from baker's yeast was purified to homogenicity. The overall purification was about 1,200-fold over the crude extract with a yield of about 24%. The purified enzyme had a sedimentation coefficient (S20,w) of 3.0 S. The molecular weight determinations by sedimentation equilibrium, Sephadex G-100 gel filtration, and sodium dodecyl sulfate-polyacrylamide gel electrophoresis gave a value of about 39,000 and, therefore, saccharopine dehydrogenase is a single polypeptide chain enzyme. A Stokes radius of 27 A and a diffusion constant of 7.9 X 10(-7) cm2 s-1 were obtained from Sephadex gel filtration chromatography. The enzyme had a high isoelectric pH of 10.1. The NH2-terminal sequence was Ala-Ala----. The enzyme possessed 3 cysteine residues/molecule; no disulfide bond was present. Incubation of saccharopine dehydrogenase with p-chloromercuribenzoate or iodoacetate resulted in complete loss of enzyme activity. Whereas the coenzyme and substrates were ineffective in protecting from inactivation by p-chloromercuribenzoate, iodoacetate inhibition was protected by excess coenzyme.     

Inhibition of urea cycle enzymes by lysine and saccharopine

Crude and purified preparations of argininosuccinate synthetase, argininosuccinate lyase and arginase were subjected to inhibition studies with L-lysine and saccharopine. Saccharopine proved to be the more potent inhibitor of argininosuccinate synthetase and lyase, whereas lysine had more effect on arginase. Similar results were found with pure enzyme and crude preparations. Computer analysis of the results suggested that inhibition of urea cycle enzymes by saccharopine and lysine might have contributed to the high levels of citrulline found in a human patient with saccharopinuria, a defect of saccharopine metabolism, but that this was unlikely to be the sole explanation.     

Evidence in support of lysine 77 and histidine 96 as acid-base catalytic residues in saccharopine dehydrogenase from Saccharomyces cerevisiae

Saccharopine dehydrogenase (SDH) catalyzes the final reaction in the α-aminoadipate pathway, the conversion of l-saccharopine to l-lysine (Lys) and α-ketoglutarate (α-kg) using NAD? as an oxidant. The enzyme utilizes a general acid-base mechanism to conduct its reaction with a base proposed to accept a proton from the secondary amine of saccharopine in the oxidation step and a group proposed to activate water to hydrolyze the resulting imine. Crystal structures of an open apo form and a closed form of the enzyme with saccharopine and NADH bound have been determined at 2.0 and 2.2 ? resolution, respectively. In the ternary complex, a significant movement of domain I relative to domain II that closes the active site cleft between the two domains and brings H96 and K77 into the proximity of the substrate binding site is observed. The hydride transfer distance is 3.6 ?, and the side chains of H96 and K77 are properly positioned to act as acid-base catalysts. Preparation of the K77M and H96Q single-mutant and K77M/H96Q double-mutant enzymes provides data consistent with their role as the general acid-base catalysts in the SDH reaction. The side chain of K77 initially accepts a proton from the ε-amine of the substrate Lys and eventually donates it to the imino nitrogen as it is reduced to a secondary amine in the hydride transfer step, and H96 protonates the carbonyl oxygen as the carbinolamine is formed. The K77M, H976Q, and K77M/H96Q mutant enzymes give 145-, 28-, and 700-fold decreases in V/E(t) and >103-fold increases in V?/K(Lys)E(t) and V?/K(α-kg)E(t) (the double mutation gives >10?-fold decreases in the second-order rate constants). In addition, the K77M mutant enzyme exhibits a primary deuterium kinetic isotope effect of 2.0 and an inverse solvent deuterium isotope effect of 0.77 on V?/K(Lys). A value of 2.0 was also observed for (D)(V?/K(Lys))(D?O) when the primary deuterium kinetic isotope effect was repeated in D?O, consistent with a rate-limiting hydride transfer step. A viscosity effect of 0.8 was observed on V?/K(Lys), indicating the solvent deuterium isotope effect resulted from stabilization of an enzyme form prior to hydride transfer. A small normal solvent isotope effect is observed on V, which decreases slightly when repeated with NADD, consistent with a contribution from product release to rate limitation. In addition, V?/K(Lys)E(t) is pH-independent, which is consistent with the loss of an acid-base catalyst and perturbation of the pK(a) of the second catalytic group to a higher pH, likely a result of a change in the overall charge of the active site. The primary deuterium kinetic isotope effect for H96Q, measured in H?O or D?O, is within error equal to 1. A solvent deuterium isotope effect of 2.4 is observed with NADH or NADD as the dinucleotide substrate. Data suggest rate-limiting imine formation, consistent with the proposed role of H96 in protonating the leaving hydroxyl as the imine is formed. The pH-rate profile for V?/K(Lys)E(t) exhibits the pK(a) for K77, perturbed to a value of ～9, which must be unprotonated to accept a proton from the ε-amine of the substrate Lys so that it can act as a nucleophile. Overall, data are consistent with a role for K77 acting as the base that accepts a proton from the ε-amine of the substrate lysine prior to nucleophilic attack on the α-oxo group of α-ketoglutarate, and finally donating a proton to the imine nitrogen as it is reduced to give saccharopine. In addition, data indicate a role for H96 acting as a general acid-base catalyst in the formation of the imine between the ε-amine of lysine and the α-oxo group of α-ketoglutarate.     

Stereospecificity of hydrogen transfer in the saccharopine dehydrogenase reaction.

The stereospecificity of hydrogen transfer in the synthesis of saccharopine from alpha-ketoglutarate and L-lysine catalyzed by saccharopine dehydrogenase (N5-(1,3-dicarboxypropyl)-L-lysine: NAD oxidoreductase (L-lysine-forming), EC 1.5.1.7) was examined by using [4A-3H]- and [4B-3H]NADH. The enzyme showed the A-stereospecificity. The NMR analysis of the saccharopine prepared with [4"A-2H]NADH revealed that the label was incorporated into the C-2 of the glutaryl moiety.