The glycine cleavage system: Composition,reaction mechanism,and physiological significance

Summary The glycine cleavage system catalyzes the following reversible reaction: Glycine + THF + NAD⁺ 5,10-methylene-THF + + CO₂ + NH₃ + NADHReversibility of the overall reaction was established through the studies with the enzymes prepared from liver mitochondria of rat and cock and from extracts ofArthrobacter globiformis grown on glycine. The glycine cleavage system is composed from four protein components. The four proteins were revealed to exist originally as an enzyme complex in the liver mitochondria. Partial reactions of glycine cleavage and glycine synthesis were studied in detail with partially purified individual protein components. Particularly a protein-bound intermediate of glycine metabolism could be isolated and its nature and role were clarified. A tentative scheme was presented to explain the whole process of the reversible glycine cleavage.The glycine cleavage system was shown to represent the major pathway of catabolism of both glycine and serine in vertebrates, including mammals, birds, reptiles, amphibians, and fishes. Serine catabolism in these animals proceeds mainly by way of the cleavage of serine to form methylene-THF and glycine rather than deamination by serine dehydratase. In ureotelic and ammonotelic animals methylene-THF formed from the -carbon of glycine as well as the-carbon of serine could be further oxidized to CO₂ in either the mitochondria or the soluble tissue fractions, while in uricotelic animals methylene-THF could hardly be oxidized to CO₂ and instead, was utilized mostly for purine synthesis. Glycine synthesis by the glycine cleavage system did not appear to have appreciable physiological significance in animals.Abbreviation THF dl,l-tetrahydrofolic acid. an invited article     

The glycine decarboxylase system: a fascinating complex

The mitochondrial glycine decarboxylase multienzyme system, connected to serine hydroxymethyltransferase through a soluble pool of tetrahydrofolate, consists of four different component enzymes, the P-, H-, T- and L-proteins. In a multi-step reaction, it catalyses the rapid destruction of glycine molecules flooding out of the peroxisomes during the course of photorespiration. In green leaves, this multienzyme system is present at tremendously high concentrations within the mitochondrial matrix. The structure, mechanism and biogenesis of glycine decarboxylase are discussed. In the catalytic cycle of glycine decarboxylase, emphasis is given to the lipoate-dependent H-protein that plays a pivotal role, acting as a mobile substrate that commutes successively between the other three proteins. Plant mitochondria possess all the necessary enzymatic equipment for de novo synthesis of tetrahydrofolate and lipoic acid, serving as cofactors for glycine decarboxylase and serine hydroxymethyltransferase functioning.     

Glycine decarboxylase is confined to the bundle-sheath cells of leaves of C3−C4 intermediate species

Immunogold labelling has been used to determine the cellular distribution of glycine decarboxylase in leaves of C₃, C₃–C₄ intermediate and C₄ species in the genera Moricandia, Panicum, Flaveria and Mollugo. In the C₃ species Moricandia foleyi and Panicum laxum, glycine decarboxylase was present in the mitochondria of both mesophyll and bundle-sheath cells. However, in all the C₃–C₄ intermediate (M. arvensis var. garamatum, M. nitens, M. sinaica, M. spinosa, M. suffruticosa, P. milioides, Flaveria floridana, F. linearis, Mollugo verticillata) and C₄ (P. prionitis, F. trinervia) species studied glycine decarboxylase was present in the mitochondria of only the bundle-sheath cells. The bundle-sheath cells of all the C₃–C₄ intermediate species have on their centripetal faces numerous mitochondria which are larger in profile area than those in mesophyll cells and are in close association with chloroplasts and peroxisomes. Confinement of glycine decarboxylase to the bundle-sheath cells is likely to improve the potential for recapture of photorespired CO₂ via the Calvin cycle and could account for the low rate of photorespiration in all C₃–C₄ intermediate species.Abbreviation and symbol kDa kilodaltons - CO₂ compensation point     

Growth and phenotype of potato plants expressing an antisense gene of P-protein of glycine decarboxylase under control of a promoter with preference for the mesophyll

A cDNA encoding P‐protein of glycine decarboxylase was expressed in antisense orientation in leaves of potato (Solanum tuberosum cv. Solara) under control of the promoter of a P‐protein gene of glycine decarboxylase from Flaveria pringlei. This promoter targets gene expression preferentially to the leaf mesophyll cells. In two of the transgenic lines, mitochondria oxidise glycine only with extremely low rates. Phenotypically, these transgenic lines were only marginally different from wild type plants under ambient carbon dioxide concentrations and indistinguishable from wild type plants when grown under 800 ppm carbon dioxide. When grown in ambient carbon dioxide, transgenic plants accumulated high amounts of glycine during the light period followed by nearly complete degradation in the following night.     

Light-induced increases in the glycine decarboxylase multienzyme complex from pea leaf mitochondria

The rates of mitochondrial glycine oxidation estimated by CO2-release and glycine-bicarbonate exchange activities in fully greened tissues are approximately 10 times greater than those of etiolated pea leaves and potato tuber mitochondria. The release of CO2 from glycine in intact mitochondria isolated from dark-grown and nonphotosynthetic tissues was sensitive to inhibitors of mitochondrial electron transport, glycine transport, and glycine decarboxylase activities. The CO2-release and glycine-bicarbonate exchange activities in crude mitochondrial protein extracts from light-grown versus dark-grown tissues exhibited light/dark ratios of 12 and 21, respectively. This suggests that the differences in capacity to oxidize glycine reside with the glycine decarboxylase enzyme complex itself. The complex is composed of four subunit enzymes, the P, H, T, and L proteins, which can be isolated individually and reconstituted into the active enzyme. The activities of P and T proteins were at least 10 times higher in fully greened pea leaves than in the etiolated tissue, while the H and L protein activities were four times higher in these same tissues. The levels of P and T proteins detected immunochemically were substantially lower in total mitochondrial extracts prepared from leaves of dark-grown pea seedlings. Labeling of whole pea seedlings and in vitro protein synthesis with isolated mitochondria indicated that the entire glycine decarboxylase enzyme complex is cytoplasmically synthesized and therefore encoded by the nucleus. Polypeptides synthesized from total leaf polyadenylated mRNA isolated from leaves of both the dark-grown and light-treated peas indicated the presence of P protein. This implies that translatable messages for this enzyme are present at some level throughout leaf development.     

Effect of light intensity on ammonia assimilation in maize leaves

The effect of light on the metabolism of ammonia was studied by subjecting detached maize leaves to 150 or 1350 mol m^–2 s^–1 PAR during incubation with the leaf base in 2 mM ¹⁵NH₄Cl. After up to 60 min, leaves were extracted. Ammonia, glutamine, glycine, serine, alanine, and aspartate were separated by isothermal distillation and ion exchange chromatography. ¹⁵N enrichments were analyzed by emission spectroscopy. The uptake of ammonium chloride did not influence CO₂ assimilation (8.3 and 17.4 mol m^–1 s^–1 at 150 and 1350 mol m^–2 s^–1 PAR, respectively). Leaves kept at high light intensity contained more serine and less alanine than leaves from low light treatments. Within 1 h of incubation the enrichment of ammonia extracted from leaves rose to approximately 20% ¹⁵N. In the high light regime the amino acids contained up to 15% ¹⁵N, whereas in low light ¹⁵N enrichments were small (up to 6%). The kinetics of ¹⁵N incorporation indicated that NH₃ was firstly assimilated into glutamine and then into glutamate. After 15 min ¹⁵N was also found in glycine, serine and alanine. At high light intensity nearly half of the ¹⁵N was incorporated in glycine. On the other hand, at low light intensity alanine was the predominant ¹⁵N sink. It is concluded that light influences ammonia assimilation at the glutamine synthetase reaction.     

Photorespiration in C3–C4 intermediate species of Alternanthera and Parthenium: Reduced ammonia production and increased capacity of CO2 refixation in the light

The pattern of photorespiratory ammonia (PR–NH₃) formation and its modulation by exogenous bicarbonate or glycine were investigated in C₃–C₄ intermediates of Alternanthera (A. ficoides and A. tenella) and Parthenium hysterophorus in comparison to those of C₃ or C₄ species. The average rates of PR–NH₃ accumulation in leaves of the intermediates were slightly less than (about 25% reduced) those in C₃ species, and were further low in C₄ plants (40% of that in C₃). The levels of PR–NH₃ in leaf discs decreased markedly when exogenous bicarbonate was present in the incubation medium. The inhibitory effect of bicarbonate on PR–NH₃ accumulation was pronounced in C₃ plants, very low in C₄ species and was moderate in the C₃–C₄ intermediates. Glycine, an intermediate of photorespiratory metabolism, raised the levels of PR–NH₃ in leaves of not only C₄ but also C₃–C₄ intermediates, bringing the rates close to those of C₃ species. The rate of mitochondrial glycine decarboxylation in darkness in C₃–C₄ intermediates was partially reduced (about 80% of that in C₃ species), corresponding to the activity-levels of glycine decarboxylase and serine hydroxymethyltransferase in leaves. The intermediates had a remarkable capacity of reassimilating photorespiratory CO₂ in vivo, as indicated by the apparent refixation of about 85% of the CO₂ released from exogenous glycine in the light. We suggest that the reduced photorespiration in the C₃–C₄ intermediate species of Alternanthera and Parthenium is due to both a limitation in the extent of glycine production/decarboxylation and an efficient refixation/recycling of internal CO₂.Abbreviations GDC glycine decarboxylase - GS glutamine synthetase - GOGAT glutamate-oxoglutarate aminotransferase - -HPMS -hydroxy-2-pyridinemethanesulfonic acid - INH isonicotinyl hydrazide - MSO L-methionine sulfoximine - PR–NH₃ photorespiratory-ammonia - SHMT serine hydroxymethyltransferase     

Characterization of harpin<Subscript>Xoo</Subscript> induced hypersensitive responses in non host plant,tobacco

Harpin proteins encoded by hrp genes are bacterial protein elicitors that can stimulate hypersensitive response (HR) in non-host plants. HR-related pathogen resistance involves a complex form of programmed cell death (PCD). It is increasingly viewed as a key component of the hypersensitive disease response of plants. Currently, the evidence of harpin proteins-induced PCD is deficient though it exhibits phenotypic parallels with HR, and the mechanism of harpin proteins-induced PCD is not well understood. In this study, we demonstrate that harpin_Xoo protein from Xanthomonas oryzae pv. oryzae of rice bacterial blight expressed and isolated from bacterial cells acted as an agent to induce PCD in infiltrated tobacco plants. Treatment of tobacco leaves with harpin_Xoo induced typical PCD-related morphological and biochemical changes including cell shrinkage and nuclear DNA degradation. We further analyzed the expression of several genes in signal transduction pathway of PCD in tobacco plants by real-time qRT-PCR analysis using EF-1α as an endogenous control. Our results showed that the expression of NtDAD1 was down-regulated and the expression of BI-1, tpa1 and aox1 was up-regulated following the infiltration of harpin_Xoo into tobacco leaves. Our data suggest that harpin_Xoo can induce PCD with the coordination of PCD-related genes in infiltrated tobacco leaves, providing evidence to further investigate the signal transduction pathways of HR and PCD.     

Mitochondria from leaf mesophyll cells of C(4) plants are deficient in the H protein of glycine decarboxylase complex

Mesophyll mitochondria from green leaves of the C(4) plants Zea mays (NADP-ME-type), Panicum miliaceum (NAD-ME-type) and Panicum maximum (PEP-CK-type) oxidized NADH, malate and succinate at relatively high rates with respiratory control, but glycine was not oxidized. Among the mitochondrial proteins involved in glycine oxidation, the L, P and T proteins of glycine decarboxylase complex (GDC) and serine hydroxymethyltransferase (SHMT) were present, while the H protein of GDC was undetectable. In contrast, mesophyll mitochondria from etiolated leaves of Z. mays oxidized glycine at a slow rate and with no respiratory control, and contained the H protein as well as the other GDC proteins and SHMT. The T and P proteins and SHMT were present in the mitochondria from etiolated leaves at significantly higher levels than in those from green leaves of Z. mays. The content of the L protein was almost identical in all three C(4) plants examined and close to the value obtained for mesophyll mitochondria from the C(3) plant Pisum sativum, whereas the other GDC proteins and SHMT were less abundant than the L protein. We discuss possible reasons for the H protein's absence in mesophyll mitochondria of C(4) plants, as well as the role(s) the other GDC components could play in its absence.     

Genetic manipulation of glycine decarboxylation

The glycine-serine interconversion, catalysed by glycine decarboxylase and serine hydroxymethyltransferase, is an important reaction of primary metabolism in all organisms including plants, by providing one-carbon units for many biosynthetic reactions. In plants, in addition, it is an integral part of the photorespiratory metabolic pathway and produces large amounts of photorespiratory CO(2) within mitochondria. Although controversial, there is significant evidence that this process, by the relocation of glycine decarboxylase within the leaves from the mesophyll to the bundle-sheath, contributed to the evolution of C(4) photosynthesis. In this review, some aspects of current knowledge about glycine decarboxylase and serine hydroxymethyltransferase and the role of these enzymes in metabolism, about the corresponding genes and their expression as well as about mutants and anti-sense plants related to these genes or processes will be summarized and discussed. From a comparison of the available information about the number and organization of GDC and SHMT genes in the genomes of Arabidopsis thaliana and Oryza sativa it appears that these and, possibly, other genes related to photorespiration, are similarly organized even in only very distantly related angiosperms.     

Enzymes of serine and glycine metabolism in leaves and non-photosynthetic tissues of Pisum sativum L.

A comparative study is presented of the activities of enzymes of glycine and serine metabolism in leaves, germinated cotyledons and root apices of pea (Pisum sativum L.). Data are given for aminotransferase activities with glyoxylate, hydroxypyruvate and pyruvate, for enzymes associated with serine synthesis from 3-phosphoglycerate and for glycine decarboxylase and serine hydroxymethyltransferase. Aminotransferase activities differ between the tissues in that, firstly, appreciable transamination of serine, hydroxypyruvate and asparagine occurs only in leaf extracts and, secondly, glyoxylate is transaminated more actively than pyruvate in leaf extracts, whereas the converse is true of extracts of cotyledons and root apices. Alanine is the most active amino-group donor to both glyoxylate and hydroxypyruvate. 3-Phosphoglycerate dehydrogenase and glutamate: O-phosphohydroxypyruvate aminotransferase have comparable activities in all three tissues, except germinated cotyledons, in which the aminotransferase appears to be undetectable. Glycollate oxidase is virtually undetectable in the non-photosynthetic tissues and in these tissues the activity of glycerate dehydrogenase is much lower than that of 3-phosphoglycerate dehydrogenase. Glycine decarboxylase activity in leaves, measured in the presence of oxaloacetate, is equal to about 30–40% of the measured rate of CO₂ fixation and is therefore adequate to account for the expected rate of photorespiration. The activity of glycine decarboxylase in the non-photosynthetic tissues is calculated to be about 2–5% of the activity in leaves and has the characteristics of a pyridoxal-and tetrahydrofolate-dependent mitochondrial reaction; it is stimulated by oxaloacetate, although not by ADP. In leaves, the measured activity of serine hydroxymethyltransferase is somewhat lower than that of glycine decarboxylase, whereas in root apices it is substantially higher. Differential centrifugation of extracts of root apices suggests that an appreciable proportion of serine hydroxymethyltransferase activity is associated with the plastids.Abbreviation GOGAT l-Glutamine:2-oxoglutarate aminotransferase     

Control of photosynthesis in barley plants with reduced activities of glycine decarboxylase

A mutant (LaPr 87/30) of barley (Hordeum vulgare L.) deficient in glycine decarboxylase (GDC; EC 2.1.2.10) was crossed with wild-type plants to generate heterozygous plants with reduced GDC activities. Plants of the F₂ generation were grown in air and analysed for reductions in GDC proteins and GDC activity. The leaves of heterozygous plants contained reduced amounts of H-protein, and when the content of H-protein was lower than 60% of the wild-type, the P-protein was also reduced. The contents of the other two proteins of the GDC complex, T-protein and L-protein were not affected. Glycine decarboxylase activities, measured as the decarboxylation of [1-¹⁴C]glycine by intact mitochondria released from protoplasts, were between 47% and 63% of the wild-type activity in heterozygous plants and between 86% and 100% in plants with normal contents of H-protein. The enzyme activity was linearly correlated with the relative content of H-protein. Plants with reduced GDC activities developed normally and did not show major pleiotropic effects. In air, the reduction in GDC activity had no effect on the leaf metabolite content or photosynthesis, but under conditions of enhanced photorespiration (low CO₂ and high light), glycine accumulated and the rates of photosynthesis decreased compared to the wild-type. The accumulation of glycine did not lead to a depletion of amino donors or to the accumulation of glyoxylate. The lower rates of photosynthesis were probably caused by an impaired recycling of carbon in the photorespiratory pathway. It is concluded that GDC has no control over CO₂ assimilation under normal growth conditions, but appreciable control by GDC becomes apparent under conditions leading to higher rates of photorespiration. Received: 24 November 1996 / Accepted: 23 January 1997     

Purification and primary amino acid sequence of the L subunit of glycine decarboxylase. Evidence for a single lipoamide dehydrogenase in plant mitochondria.

In order to purify the lipoamide dehydrogenase associated with the glycine decarboxylase complex of pea leaf mitochondria, the activity of free lipoamide dehydrogenase has been separated from those of the pyruvate and 2-oxoglutarate dehydrogenase complexes under conditions in which the glycine decarboxylase dissociates into its component subunits. This free lipoamide dehydrogenase which is normally associated with the glycine decarboxylase complex has been further purified and the N-terminal amino acid sequence determined. Positive cDNA clones isolated from both a pea leaf and embryo lambda gt11 expression library using an antibody raised against the purified lipoamide dehydrogenase proved to be the product of a single gene. The amino acid sequence deduced from the open reading frame included a sequence matching that determined directly from the N terminus of the mature protein. The deduced amino acid sequence shows good homology to the sequence of lipoamide dehydrogenase associated with the pyruvate dehydrogenase complex from Escherichia coli, yeast, and humans. The corresponding mRNA is strongly light-induced both in etiolated pea seedlings and in the leaves of mature plants following a period of darkness. The evidence suggests that the mitochondrial enzyme complexes: pyruvate dehydrogenase, 2-oxoglutarate dehydrogenase, and glycine decarboxylase all use the same lipoamide dehydrogenase subunit.     

Arabidopsis thaliana Atvsp is homologous to soybean VspA and VspB,genes encoding vegetative storage protein acid phosphatases,and is regulated similarly by methyl jasmonate,wounding, sugars,light and phosphate

The soybean vegetative storage proteins, VSP and VSP, are acid phosphatases that accumulate to very high levels in hypocotyls, young leaves and flowers and pods. The genes encoding the soybean VSP are activated by jasmonate, wounding, sugars and light and down regulated by phosphate and auxin. In this study, expression of an Arabidopsis thaliana gene (Atvsp) encoding a protein homologous to soybean Vsp and Vsp, was examined and compared to expression of the soybean Vsp genes. Atvsp mRNA was present at high levels in flowers and buds and at low levels in roots, stems, leaves and siliques. Expression of Atvsp in leaves could be induced by wounding or by treatment of illuminated plants with methyl jasmonate and sucrose. Roots of plants with wounded leaves also accumulated Atvsp mRNA indicating that this gene can be regulated by a transmissible wound signal. Phosphate partially inhibited expression of Atvsp. Arabidopsis proteins of 29 and 30 kDa crossreacted with antibodies against soybean VSP. These proteins were very abundant in flowers and the proteins accumulated in leaves and roots of plants treated with methyl jasmonate. The level of these proteins in flowers was similar to the levels of soybean VSP in young soybean leaves. Overall, these data indicate that Arabidopsis Atvsp and soybean VspA/B genes are regulated similarly and that in both plants, the gene products can accumulate to high levels. This suggests that genes homologous to VspA/B may be of greater general significance than previously recognized.     

Immunocytochemical localization of proteins P1, P2, P3 of glycine decarboxylase and of the selenoprotein PA of glycine reductase,all involved in anaerobic glycine metabolism of Eubacterium acidaminophilum

Antibodies raised against the glycine decarboxylase proteins P1, P2, P3, and the selenoprotein P_A, a component of the glycine reductase complex, were used for immunocytochemical localization experiments. Cells of Eubacterium acidaminophilum from logarithmic growth phase were fixed in the growth media with paraformaldehyde and glutaraldehyde. Fixed cells were embedded by the low-temperature procedure using Lowicryl K4M resin, and the protein A-gold technique was applied for the localization experiments. The vicinity of the cytoplasmic membrane contained about 27% of all gold particles when proteins P1 and P2 were to be localized, 50% for protein P_A, and 61% for protein P3. Double immunocytochemical labeling experiments gave evidence for the existence of a protein P1/P2 complex located predominantly in the cytoplasm, and a P3/P_A complex located at the cytoplasmic membrane. Only in very few instances the labels for proteins P3 and P1 were seen very close together in respective doublelabeling experiments. These results indicate that glycine decarboxylase does not occur in this organism as a complex consisting of all four proteins, but that protein P3, the atypical lipoamide dehydrogenase, takes part in both the glycine decarboxylase as well as in the glycine reductase reaction.