Mitochondrial cysteine synthase complex regulates o-acetylserine biosynthesis in plants

Cysteine synthesis is catalyzed by serine acetyltransferase (SAT) and O-acetylserine (thiol) lyase (OAS-TL) in the cytosol, plastids, and mitochondria of plants. Biochemical analyses of recombinant plant SAT and OAS-TL indicate that the reversible association of the proteins in the cysteine synthase complex (CSC) controls cellular sulfur homeostasis. However, the relevance of CSC formation in each compartment for flux control of cysteine synthesis remains controversial. Here, we demonstrate the interaction between mitochondrial SAT3 and OAS-TL C in planta by FRET and establish the role of the mitochondrial CSC in the regulation of cysteine synthesis. NMR spectroscopy of isolated mitochondria from WT, serat2;2, and oastl-C plants showed the SAT-dependent export of OAS. The presence of cysteine resulted in reduced OAS export in mitochondria of oastl-C mutants but not in WT mitochondria. This is in agreement with the stronger in vitro feedback inhibition of free SAT by cysteine compared with CSC-bound SAT and explains the high OAS export rate of WT mitochondria in the presence of cysteine. The predominant role of mitochondrial OAS synthesis was validated in planta by feeding [(3)H]serine to the WT and loss-of-function mutants for OAS-TLs in the cytosol, plastids, and mitochondria. On the basis of these results, we propose a new model in which the mitochondrial CSC acts as a sensor that regulates the level of SAT activity in response to sulfur supply and cysteine demand.     

Dominant-negative modification reveals the regulatory function of the multimeric cysteine synthase protein complex in transgenic tobacco

Cys synthesis in plants constitutes the entry of reduced sulfur from assimilatory sulfate reduction into metabolism. The catalyzing enzymes serine acetyltransferase (SAT) and O-acetylserine (OAS) thiol lyase (OAS-TL) reversibly form the heterooligomeric Cys synthase complex (CSC). Dominant-negative mutation of the CSC showed the crucial function for the regulation of Cys biosynthesis in vivo. An Arabidopsis thaliana SAT was overexpressed in the cytosol of transgenic tobacco (Nicotiana tabacum) plants in either enzymatically active or inactive forms that were both shown to interact efficiently with endogenous tobacco OAS-TL proteins. Active SAT expression resulted in a 40-fold increase in SAT activity and strong increases in the reaction intermediate OAS as well as Cys, glutathione, Met, and total sulfur contents. However, inactive SAT expression produced much greater enhancing effects, including 30-fold increased Cys levels, attributable, apparently, to the competition of inactive transgenic SAT with endogenous tobacco SAT for binding to OAS-TL. Expression levels of tobacco SAT and OAS-TL remained unaffected. Flux control coefficients suggested that the accumulation of OAS and Cys in both types of transgenic plants was accomplished by different mechanisms. These data provide evidence that the CSC and its subcellular compartmentation play a crucial role in the control of Cys biosynthesis, a unique function for a plant metabolic protein complex.     

Plant serine acetyltransferase: new insights for regulation of sulphur metabolism in plant cells

Plant serine acetyltransferase (SAT, E.C. 2.3.1.30) catalyses the first connecting reaction between nitrogen/carbon and sulphate metabolism. SAT is associated with the second committed enzyme, O-acetylserine(thiol)lyase (OASTL, E.C. 4.2.99.8), in a bi-enzyme complex called cysteine synthase (CS). Metabolic regulation of SAT-bound OASTL in the presence of cysteine (Cys) is analysed with the extracts from the leaf cell compartments of Pisum sativum. To this end, a high performance liquid chromatography (HPLC) technique is developed to measure the rate of O-acetylserine (OAS) formation by SAT. Under physiological experimental conditions, L-Cys specifically inhibits chloroplast-SAT activity, which is linked to the sulphate assimilation network. This metabolic feedback control does not apply to the SAT activity located in the cytosol. The non-physiological range of L-Cys inhibits the mitochondrial isoform. L-Cys in a non-competitive manner in presence of L-serine or acetyl-CoA (K_i of 12–20 μM) inhibits partially purified chloroplast SAT, free of bound OASTL. The K_i values are in the range of Cys concentrations estimated in this compartment. Furthermore, we report for the first time that the multi-enzyme complex, CS dissociates in the presence of Cys as previously described with OAS. From this study, and with the integration of data previously reported in the literature, we hypothesize a new model for the regulation of Cys synthesis in plant cells containing a chloroplastic Cys-sensitive SAT.     

Analysis of cytosolic and plastidic serine acetyltransferase mutants and subcellular metabolite distributions suggests interplay of the cellular compartments for cysteine biosynthesis in Arabidopsis

In plants, the enzymes for cysteine synthesis serine acetyltransferase (SAT) and O-acetylserine-(thiol)-lyase (OASTL) are present in the cytosol, plastids and mitochondria. However, it is still not clearly resolved to what extent the different compartments are involved in cysteine biosynthesis and how compartmentation influences the regulation of this biosynthetic pathway. To address these questions, we analysed Arabidopsis thaliana T-DNA insertion mutants for cytosolic and plastidic SAT isoforms. In addition, the subcellular distribution of enzyme activities and metabolite concentrations implicated in cysteine and glutathione biosynthesis were revealed by non-aqueous fractionation (NAF). We demonstrate that cytosolic SERAT1.1 and plastidic SERAT2.1 do not contribute to cysteine biosynthesis to a major extent, but may function to overcome transport limitations of O-acetylserine (OAS) from mitochondria. Substantiated by predominantly cytosolic cysteine pools, considerable amounts of sulphide and presence of OAS in the cytosol, our results suggest that the cytosol is the principal site for cysteine biosynthesis. Subcellular metabolite analysis further indicated efficient transport of cysteine, γ -glutamylcysteine and glutathione between the compartments. With respect to regulation of cysteine biosynthesis, estimation of subcellular OAS and sulphide concentrations established that OAS is limiting for cysteine biosynthesis and that SAT is mainly present bound in the cysteine–synthase complex.     

Signaling in the plant cytosol: cysteine or sulfide?

Cysteine (Cys) is the first organic compound containing reduced sulfur that is synthesized in the last stage of plant photosynthetic assimilation of sulfate. It is a very important metabolite not only because it is crucial for the structure, function and regulation of proteins but also because it is the precursor molecule of an enormous number of sulfur-containing metabolites essential for plant health and development. The biosynthesis of Cys is accomplished by the sequential reaction of serine acetyltransferase (SAT) and O-acetylserine(thiol)synthase (OASTL). In Arabidopsis thaliana, the analysis of specific mutants of members of the SAT and OASTL families has demonstrated that the cytosol is the compartment where the bulk of Cys synthesis takes place and that the cytosolic OASTL enzyme OAS-A1 is the responsible enzyme. Another member of the OASTL family is DES1, a novel l-cysteine desulfhydrase that catalyzes the desulfuration of Cys to produce sulfide, thus acting in a manner opposite to that of OAS-A1. Detailed studies of the oas-a1 and des1 null mutants have revealed the involvement of the DES1 and OAS-A1 proteins in coordinate regulation of Cys homeostasis and the generation of sulfide in the cytosol for signaling purposes. Thus, the levels of Cys in the cytosol strongly affect plant responses to both abiotic and biotic stress conditions, while sulfide specifically generated from the degradation of Cys negatively regulates autophagy induced in different situations. In conclusion, modulation of the levels of Cys and sulfide is likely critical for plant performance.     

Analysis of the Arabidopsis O-acetylserine(thiol)lyase gene family demonstrates compartment-specific differences in the regulation of cysteine synthesis

Cys synthesis in plants takes place in plastids, cytosol, and mitochondria. Why Cys synthesis is required in all compartments with autonomous protein biosynthesis and whether Cys is exchanged between them has remained enigmatic. This question was addressed using Arabidopsis thaliana T-DNA insertion lines deficient in the final step of Cys biosynthesis catalyzed by the enzyme O-acetylserine(thiol)lyase (OAS-TL). Null alleles of oastlA or oastlB alone showed that cytosolic OAS-TL A and plastid OAS-TL B were completely dispensable, although together they contributed 95% of total OAS-TL activity. An oastlAB double mutant, relying solely on mitochondrial OAS-TL C for Cys synthesis, showed 25% growth retardation. Although OAS-TL C alone was sufficient for full development, oastlC plants also showed retarded growth. Targeted affinity purification identified the major OAS-TL-like proteins. Two-dimensional gel electrophoresis and mass spectrometry showed no compensatory changes of OAS-TL isoforms in the four mutants. Steady state concentrations of Cys and glutathione and pulse-chase labeling with [35S]sulfate indicated strong perturbation of primary sulfur metabolism. These data demonstrate that Cys and also sulfide must be sufficiently exchangeable between cytosol and organelles. Despite partial redundancy, the mitochondria and not the plastids play the most important role for Cys synthesis in Arabidopsis.     

The relevance of compartmentation for cysteine synthesis in phototrophic organisms

In the vascular plant Arabidopsis thaliana, synthesis of cysteine and its precursors O-acetylserine and sulfide is distributed between the cytosol, chloroplasts, and mitochondria. This compartmentation contributes to regulation of cysteine synthesis. In contrast to Arabidopsis, cysteine synthesis is exclusively restricted to chloroplasts in the unicellular green alga Chlamydomonas reinhardtii. Thus, the question arises, whether specification of compartmentation was driven by multicellularity and specified organs and tissues. The moss Physcomitrella patens colonizes land but is still characterized by a simple morphology compared to vascular plants. It was therefore used as model organism to study evolution of compartmented cysteine synthesis. The presence of O-acetylserine(thiol)lyase (OAS-TL) proteins, which catalyze the final step of cysteine synthesis, in different compartments was applied as criterion. Purification and characterization of native OAS-TL proteins demonstrated the presence of five OAS-TL protein species encoded by two genes in Physcomitrella. At least one of the gene products is dual targeted to plastids and cytosol, as shown by combination of GFP fusion localization studies, purification of chloroplasts, and identification of N termini from native proteins. The bulk of OAS-TL protein is targeted to plastids, whereas there is no evidence for a mitochondrial OAS-TL isoform and only a minor part of OAS-TL protein is localized in the cytosol. This demonstrates that subcellular diversification of cysteine synthesis is already initialized in Physcomitrella but appears to gain relevance later during evolution of vascular plants.     

Molecular and biochemical analysis of the enzymes of cysteine biosynthesis in the plant <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis>

Summary. Among the amino acids produced by plants cysteine plays a special role as a mediator between assimilatory sulfate reduction and provision of reduced sulfur for cell metabolism. Part of this characteristic feature is the presence of cysteine synthesis in plastids, mitochondria and cytosol. Plants are the major source of reduced sulfur for human and animal nutrition. Cysteine biosynthesis deserves special attention, since reduced sulfur is channelled from cysteine into many sulfur-containing compounds in food and feed. Recent investigations are reviewed that focus on structure and regulation of cysteine synthesis in the model plant Arabidopsis thaliana. These data indicate that cysteine synthesis is not just an intermediate reaction step but that it is part of a regulatory network that mediates between inorganic sulfur supply and the demand for reduced sulfur during plant growth and in response to environmental changes. Received December 3, 2001 Accepted December 21, 2001     

Comparative genomics and reverse genetics analysis reveal indispensable functions of the serine acetyltransferase gene family in Arabidopsis

Ser acetyltransferase (SERAT), which catalyzes O-acetyl-Ser (OAS) formation, plays a key role in sulfur assimilation and Cys synthesis. Despite several studies on SERATs from various plant species, the in vivo function of multiple SERAT genes in plant cells remains unaddressed. Comparative genomics studies with the five genes of the SERAT gene family in Arabidopsis thaliana indicated that all three Arabidopsis SERAT subfamilies are conserved across five plant species with available genome sequences. Single and multiple knockout mutants of all Arabidopsis SERAT gene family members were analyzed. All five quadruple mutants with a single gene survived, with three mutants showing dwarfism. However, the quintuple mutant lacking all SERAT genes was embryo-lethal. Thus, all five isoforms show functional redundancy in vivo. The developmental and compartment-specific roles of each SERAT isoform were also demonstrated. Mitochondrial SERAT2;2 plays a predominant role in cellular OAS formation, while plastidic SERAT2;1 contributes less to OAS formation and subsequent Cys synthesis. Three cytosolic isoforms, SERAT1;1, SERAT3;1, and SERAT3;2, may play a major role during seed development. Thus, the evolutionally conserved SERAT gene family is essential in cellular processes, and the substrates and products of SERAT must be exchangeable between the cytosol and organelles.     

Increased glutathione biosynthesis plays a role in nickel tolerance in thlaspi nickel hyperaccumulators

Worldwide more than 400 plant species are now known that hyperaccumulate various trace metals (Cd, Co, Cu, Mn, Ni, and Zn), metalloids (As) and nonmetals (Se) in their shoots. Of these, almost one-quarter are Brassicaceae family members, including numerous Thlaspi species that hyperaccumulate Ni up to 3% of there shoot dry weight. We observed that concentrations of glutathione, Cys, and O-acetyl-l-serine (OAS), in shoot tissue, are strongly correlated with the ability to hyperaccumulate Ni in various Thlaspi hyperaccumulators collected from serpentine soils, including Thlaspi goesingense, T. oxyceras, and T. rosulare, and nonaccumulator relatives, including T. perfoliatum, T. arvense, and Arabidopsis thaliana. Further analysis of the Austrian Ni hyperaccumulator T. goesingense revealed that the high concentrations of OAS, Cys, and GSH observed in this hyperaccumulator coincide with constitutively high activity of both serine acetyltransferase (SAT) and glutathione reductase. SAT catalyzes the acetylation of l-Ser to produce OAS, which acts as both a key positive regulator of sulfur assimilation and forms the carbon skeleton for Cys biosynthesis. These changes in Cys and GSH metabolism also coincide with the ability of T. goesingense to both hyperaccumulate Ni and resist its damaging oxidative effects. Overproduction of T. goesingense SAT in the nonaccumulator Brassicaceae family member Arabidopsis was found to cause accumulation of OAS, Cys, and glutathione, mimicking the biochemical changes observed in the Ni hyperaccumulators. In these transgenic Arabidopsis, glutathione concentrations strongly correlate with increased resistance to both the growth inhibitory and oxidative stress induced effects of Ni. Taken together, such evidence supports our conclusion that elevated GSH concentrations, driven by constitutively elevated SAT activity, are involved in conferring tolerance to Ni-induced oxidative stress in Thlaspi Ni hyperaccumulators.     

Overproduction of SAT and/or OASTL in transgenic plants: a survey of effects

The last steps of cysteine biosynthesis are catalysed by a bi-enzyme complex composed of serine acetyltransferase (SAT) and cysteine synthase, also called O-acetyl-serine (thiol) lyase (OASTL). SAT is responsible for the production of O-acetyl-serine (OAS) from serine and acetyl-coenzyme A, while OASTL catalyses the formation of cysteine from OAS and hydrogen sulphide. Several distinct nuclear genes for SAT and OASTL enzymes exist in plants. Products of these genes are targeted into at least three cellular compartments: cytosol, chloroplasts, and mitochondria. The SAT and OASTL enzymes are strongly evolutionary conserved, both structurally and functionally. Therefore, isoenzymes from various cellular compartments can be substituted, not only by their plant counterparts from the other cellular compartments but also by their bacterial homologues. During the last decade transgenic plants overproducing SAT, OASTL or both enzymes simultaneously were obtained independently by several research groups. These manipulations led not only to the elevated levels of the respective products, namely OAS and cysteine, but also to increased amounts of glutathione and changes in the levels of other metabolites and enzymatic activities. In several cases, the transgenic plants were also shown to be less susceptible to applied abiotic stresses. In this review, all published and some unpublished results from this laboratory related to heterologous overproduction of SAT and OASTL in transgenic plants are discussed and summarized.     

Structure and Function of the Hetero-oligomeric Cysteine Synthase Complex in Plants

Cysteine synthesis in bacteria and plants is catalyzed by serine acetyltransferase (SAT) and O-acetylserine (thiol)-lyase (OAS-TL), which form the hetero-oligomeric cysteine synthase complex (CSC). In plants, but not in bacteria, the CSC is assumed to control cellular sulfur homeostasis by reversible association of the subunits. Application of size exclusion chromatography, analytical ultracentrifugation, and isothermal titration calorimetry revealed a hexameric structure of mitochondrial SAT from Arabidopsis thaliana (AtSATm) and a 2:1 ratio of the OAS-TL dimer to the SAT hexamer in the CSC. Comparable results were obtained for the composition of the cytosolic SAT from A. thaliana (AtSATc) and the cytosolic SAT from Glycine max (Glyma16g03080, GmSATc) and their corresponding CSCs. The hexameric SAT structure is also supported by the calculated binding energies between SAT trimers. The interaction sites of dimers of AtSATm trimers are identified using peptide arrays. A negative Gibbs free energy (ΔG = −33 kcal mol⁻¹) explains the spontaneous formation of the AtCSCs, whereas the measured SAT:OAS-TL affinity (K_D = 30 nm) is 10 times weaker than that of bacterial CSCs. Free SAT from bacteria is >100-fold more sensitive to feedback inhibition by cysteine than AtSATm/c. The sensitivity of plant SATs to cysteine is further decreased by CSC formation, whereas the feedback inhibition of bacterial SAT by cysteine is not affected by CSC formation. The data demonstrate highly similar quaternary structures of the CSCs from bacteria and plants but emphasize differences with respect to the affinity of CSC formation (K_D) and the regulation of cysteine sensitivity of SAT within the CSC.     

Successful Fertilization Requires the Presence of at Least One Major O-Acetylserine(thiol)lyase for Cysteine Synthesis in Pollen of Arabidopsis

The synthesis of cysteine (Cys) is a master control switch of plant primary metabolism that coordinates the flux of sulfur with carbon and nitrogen metabolism. In Arabidopsis (Arabidopsis thaliana), nine genes encode for O-acetylserine(thiol)lyase (OAS-TL)-like proteins, of which the major isoforms, OAS-TL A, OAS-TL B, and OAS-TL C, catalyze the formation of Cys by combining O-acetylserine and sulfide in the cytosol, the plastids, and the mitochondria, respectively. So far, the significance of individual OAS-TL-like enzymes is unresolved. Generation of all major OAS-TL double loss-of-function mutants in combination with radiolabeled tracer studies revealed that subcellular localization of OAS-TL proteins is more important for efficient Cys synthesis than total cellular OAS-TL activity in leaves. The absence of oastl triple embryos after targeted crosses indicated the exclusiveness of Cys synthesis by the three major OAS-TLs and ruled out alternative sulfur fixation by other OAS-TL-like proteins. Analyses of oastlABC pollen demonstrated that the presence of at least one functional OAS-TL isoform is essential for the proper function of the male gametophyte, although the synthesis of histidine, lysine, and tryptophan is dispensable in pollen. Comparisons of oastlABC pollen derived from genetically different parent plant combinations allowed us to separate distinct functions of Cys and glutathione in pollen and revealed an additional role of glutathione for pollen germination. In contrast, female gametogenesis was not affected by the absence of major OAS-TLs, indicating significant transport of Cys into the developing ovule from the mother plant.Sulfur assimilation in plants is hallmarked by two reaction sequences, namely sulfate reduction and Cys synthesis. The sulfate reduction pathway consists of three steps and produces sulfide from sulfate, which is available in the soil and transported into the roots by specific transporters (Takahashi et al., 2011). Sulfide is subsequently incorporated into the amino acid O-acetylserine (OAS) by O-acetylserine(thiol)lyase (OAS-TL; EC 2.5.1.47) to produce Cys (Hell and Wirtz, 2011). Cys then serves as the sulfur source for all organic metabolites containing reduced sulfur in plants, including proteins, cofactors, and secondary metabolites. The tripeptide glutathione (GSH) is one of the most important Cys-derived metabolites, since it has an important function in redox homeostasis and the control of development (Meyer and Rausch, 2008). Impaired GSH synthesis negatively affects growth of the shoot and root system of Arabidopsis (Arabidopsis thaliana; Vernoux et al., 2000; Xiang et al., 2001), and loss-of-function mutants for the first enzyme (GSH1, Glu-Cys ligase; EC 6.3.2.2) or the second enzyme (GSH2, glutathione synthase; EC 6.3.2.3) of the two-step pathway leading to GSH formation show an embryo- and seedling-lethal phenotype, respectively (Cairns et al., 2006; Pasternak et al., 2008).Cys synthesis by OAS-TL constitutes the direct link between carbon and nitrogen (OAS) as well as sulfur (sulfide) metabolism and, therefore, can be designated as one of the central reactions in plant primary metabolism. The genome of the model plant Arabidopsis encodes nine OAS-TL-like enzymes: OAS-TL A1 (At4g14880), OAS-TL B (At2g43750), and OAS-TL C (At3g59760) are the major isoforms and are localized in the cytosol, plastids, and mitochondria, respectively (Jost et al., 2000). OAS-TL A2 (At3g22460) encodes a truncated and nonfunctional protein (Jost et al., 2000). In the following, therefore, OAS-TL A1 is referred to as OAS-TL A. CYS D1 (At3g04940) and CYS D2 (At5g28020) show OAS-TL activity in vitro (Yamaguchi et al., 2000). Whether they contribute to net Cys synthesis in vivo is unknown (Heeg et al., 2008). CS26 (At3g03630) encodes a plastidic S-sulfocysteine synthase, which prefers thiosulfate instead of sulfide as substrate and produces S-sulfocysteine (Bermúdez et al., 2010). Whether thiosulfate is taken up from the soil or formed within the plant is unclear, but its presence in Arabidopsis was demonstrated (Tsakraklides et al., 2002). However, the synthesis of S-sulfocysteine from thiosulfate potentially constitutes an alternative sulfur fixation pathway. So far, CS26 was shown to be important for the regulation of redox homeostasis in plastids under certain stress conditions (Bermúdez et al., 2010). DES1 (At5g28030; formerly known as CS-LIKE) is a Cys desulfhydrase (EC 4.4.1.15) that releases sulfide in the cytosol (Alvarez et al., 2010). As a Cys-consuming enzyme, it contributes to Cys homeostasis, especially in late vegetative development and under certain stress conditions (Alvarez et al., 2010, 2012). CYS C1 (At3g61440), finally, encodes a mitochondrial β-cyanoalanine synthase (EC 4.4.1.9), which detoxifies cyanide by incorporation into Cys (Yamaguchi et al., 2000; Watanabe et al., 2008a; García et al., 2010). The major isoforms OAS-TL A, OAS-TL B, and OAS-TL C as well as CYS D1 and CYS D2 can interact with serine acetyltransferase (SAT; EC 2.3.1.30) in the cysteine synthase complex (CSC; Heeg et al., 2008). Although SAT acetylates Ser at the hydroxyl group to form OAS, the direct substrate of OAS-TL, formation of the CSC has no substrate-channeling function but contributes to the demand-driven regulation of Cys synthesis (Hell and Wirtz, 2011).The subcellular compartmentation of Cys precursor formation is a remarkable feature of Cys synthesis in higher plants that implies a high degree of regulation between the participating compartments: while sulfate is exclusively reduced to sulfide in plastids (Takahashi et al., 2011), the synthesis of OAS and the incorporation of sulfide take place in all three compartments where SAT and OAS-TL are present, namely in the cytosol, plastids, and mitochondria. Reverse genetics approaches proved a certain redundancy between the different SAT and OAS-TL isoforms, which demonstrates that sulfide, OAS, and Cys can be exchanged between these compartments (Haas et al., 2008; Heeg et al., 2008; Watanabe et al., 2008a, 2008b). Indeed, sulfide can easily diffuse through membranes (Mathai et al., 2009), but OAS and Cys need to be actively transported. However, the identity of these transporters is unknown. Although sulfide, OAS, and Cys can pass the mitochondrial membrane (Wirtz et al., 2012), the loss-of-function mutant for mitochondrial OAS-TL C is the only single oastl knockout mutant that displays a significant growth phenotype (Heeg et al., 2008). This result was astonishing, since OAS-TL C contributes only 5% to extractable foliar OAS-TL activity (Heeg et al., 2008). The retarded growth of the oastlC mutant, however, cannot be explained by the lack of sulfide detoxification in mitochondria by OAS-TL C, due to an alternative detoxification mechanism for sulfide in mitochondria (Birke et al., 2012). These data question the total redundancy between the different OAS-TL isoforms and suggest specific functions in the different subcellular compartments.Despite its central position in the primary metabolism of higher plants, fundamental questions about Cys synthesis are still unanswered. First, the contribution of OAS-TL-like proteins, especially CYS D1, CYS D2, and CS26, to the fixation of sulfur in planta is unknown. Second, the significance of Cys synthesis by the major OAS-TL proteins in the different subcellular compartments during sporophyte and gametophyte development is unclear. In this study, we addressed these questions using a reverse genetics approach. We were able to prove that fixation of sulfur is carried out exclusively by the major OAS-TL isoforms OAS-TL A, OAS-TL B, and OAS-TL C and elucidated specific functions for OAS-TL A in the cytosol and OAS-TL C in mitochondria of leaf cells. Furthermore, we demonstrate that Cys can be supplied by the mother plant for the development of female gametophytes lacking OAS-TL activity. In contrast, the presence of at least one functional OAS-TL isoform is essential in the male gametophyte.     

Localization of ATP Sulfurylase and O-Acetylserine(thiol)lyase in Spinach Leaves

The intracellular compartmentation of ATP sulfurylase and O-acetylserine(thiol)lyase in spinach (Spinacia oleracea L.) leaves has been investigated by isolation of organelles and fractionation of protoplasts. ATP sulfurylase is located predominantly in the chloroplasts, but is also present in the cytosol. No evidence was found for ATP sulfurylase activity in the mitochondria. Two forms of ATP sulfurylase were separated by anion-exchange chromatography. The more abundant form is present in the chloroplasts, the second is cytosolic. O-Acetylserine(thiol)lyase activity is located primarily in the chloroplasts and cytosol, but is also present in the mitochondria. Three forms of O-acetylserine(thiol)lyase were separated by anion-exchange chromatography, and each was found to be specific to one intracellular compartment. The cytosolic ATP sulfurylase may not be active in vivo due to the unfavorable equilibrium constant of the reaction, and the presence of micromolar concentrations of inorganic pyrophosphate in the cytosol, therefore its role remains unknown. It is suggested that the plant cell may be unable to transport cysteine between the different compartments, so that the cysteine required for protein synthesis must be synthesized in situ, hence the presence of O-acetylserine(thiol)lyase in the three compartments where proteins are synthesized.     

Impact of reduced O-acetylserine(thiol)lyase isoform contents on potato plant metabolism

Plant cysteine (Cys) synthesis can occur in three cellular compartments: the chloroplast, cytoplasm, and mitochondrion. Cys formation is catalyzed by the enzyme O-acetylserine(thiol)lyase (OASTL) using O-acetylserine (OAS) and sulfide as substrates. To unravel the function of different isoforms of OASTL in cellular metabolism, a transgenic approach was used to down-regulate specifically the plastidial and cytosolic isoforms in potato (Solanum tuberosum). This approach resulted in decreased RNA, protein, and enzymatic activity levels. Intriguingly, H(2)S-releasing capacity was also reduced in these lines. Unexpectedly, the thiol levels in the transgenic lines were, regardless of the selected OASTL isoform, significantly elevated. Furthermore, levels of metabolites such as serine, OAS, methionine, threonine, isoleucine, and lysine also increased in the investigated transgenic lines. This indicates that higher Cys levels might influence methionine synthesis and subsequently pathway-related amino acids. The increase of serine and OAS points to suboptimal Cys synthesis in transgenic plants. Taking these findings together, it can be assumed that excess OASTL activity regulates not only Cys de novo synthesis but also its homeostasis. A model for the regulation of Cys levels in plants is proposed.