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.     

Regulation of Plant Glycine Decarboxylase by S-Nitrosylation and Glutathionylation

Mitochondria play an essential role in nitric oxide (NO) signal transduction in plants. Using the biotin-switch method in conjunction with nano-liquid chromatography and mass spectrometry, we identified 11 candidate proteins that were S-nitrosylated and/or glutathionylated in mitochondria of Arabidopsis (Arabidopsis thaliana) leaves. These included glycine decarboxylase complex (GDC), a key enzyme of the photorespiratory C₂ cycle in C3 plants. GDC activity was inhibited by S-nitrosoglutathione due to S-nitrosylation/S-glutathionylation of several cysteine residues. Gas-exchange measurements demonstrated that the bacterial elicitor harpin, a strong inducer of reactive oxygen species and NO, inhibits GDC activity. Furthermore, an inhibitor of GDC, aminoacetonitrile, was able to mimic mitochondrial depolarization, hydrogen peroxide production, and cell death in response to stress or harpin treatment of cultured Arabidopsis cells. These findings indicate that the mitochondrial photorespiratory system is involved in the regulation of NO signal transduction in Arabidopsis.Nitric oxide (NO) has emerged as a new chemical messenger in plant biology. It can interact with a variety of intracellular and extracellular targets, acting as either a cytotoxic or a cytoprotective agent. NO stimulates seed germination in different species, and a decrease in NO levels has been associated with fruit maturation and senescence of flowers (Beligni and Lamattina, 2001). NO production has been observed in response to several biotic and abiotic stimuli, such as pathogen infection, bacterial elicitors, high temperature, osmotic stress, and UV-B light (Durner et al., 1998; Barroso et al., 1999; Krause and Durner, 2004; Zeidler et al., 2004; Shapiro, 2005; Corpas et al., 2008; Kolbert et al., 2008; Zhao et al., 2009).Despite the proven importance of NO, little is known about signaling pathways downstream from it. During both programmed cell death and defense responses, NO requires cGMP and cADP Rib as secondary messengers (Wendehenne et al., 2001). Furthermore, NO activates mitogen-activated protein kinases in different plant species during stress signaling (Nakagami et al., 2005). However, direct biological activity of NO arises from chemical reactions between proteins and NO itself (Foster and Stamler, 2004; Dahm et al., 2006). S-Nitrosylation is a labile posttranslational modification with a half-life of seconds to a few minutes and represents a very sensitive mechanism for regulating cellular processes (Hess et al., 2005). More than 100 candidate S-nitrosylated proteins were identified from extracts of Arabidopsis (Arabidopsis thaliana) cultured cells treated with the NO donor S-nitrosoglutathione (GSNO) and from Arabidopsis leaves treated with gaseous NO (Lindermayr et al., 2005). Using the same proteomic approach, changes were characterized in S-nitrosylated proteins in Arabidopsis leaves undergoing a hypersensitive response (Romero-Puertas et al., 2008).In animals, mitochondria play a crucial role in S-nitrosylation-dependent NO signaling (Foster and Stamler, 2004). The mitochondrion is an essential organelle for normal cellular function, being an important site of ATP synthesis and an integrator for apoptotic signaling (Skulachev, 1999). Mitochondria interact with NO at several levels. One particularly well-characterized example is the inhibition of complex IV (cytochrome c oxidase) via binding of NO to its binuclear CuB/heme a₃ site (Cleeter et al., 1994). There are several reasons why S-nitrosylation may be an important mitochondrial regulatory mechanism. For example, mitochondria contain sizeable pools of thiols and transition metals, all of which are known to modulate nitrosothiol (SNO) biochemistry (Foster and Stamler, 2004). In addition, mitochondria are highly membranous and accumulate lipophilic molecules such as NO. Interesting in this respect is the fact that the formation of the S-nitrosylating intermediate N₂O₃ is enhanced within membranes (Burwell et al., 2006).The role of mitochondria in stress-related responses has been investigated in both animals and plants. Endogenous nitrosylation of the catalytic Cys site of a subset of mitochondrial caspases serves as an on/off switch regulating caspase activity during apoptosis (Mannick et al., 2001). Moreover, cytochrome c, which is modified by NO at its heme iron during apoptosis, is released from mitochondria into the cytoplasm, which plays a critical role in many forms of apoptosis by stimulating apoptosome formation and subsequent caspase activation (Schonhoff et al., 2003). We previously showed that a prime target of NO in plants is the mitochondrial apparatus, causing an inhibition of KCN-sensitive respiration and an activation of alternative respiration via alternative oxidase (AOX; Huang et al., 2002; Krause and Durner, 2004; Livaja et al., 2008).The aim of this study was to identify possible targets for S-nitrosylation in mitochondria of Arabidopsis leaves in order to gain more insight into the regulatory function of NO at the protein level. Using a proteomic approach involving the highly specific biotin-switch method for detection and purification of S-nitrosylated proteins (Jaffrey and Snyder, 2001) in conjunction with liquid chromatography and tandem mass spectrometry (nanoLC/MS/MS), we could identify 11 mitochondrial proteins as targets for S-nitrosylation. Among these identified proteins, we focused our attention on the P-subunit of the Gly decarboxylase complex (GDC), which is an integral part of the photorespiratory system. Since the release of apoptotic factors from mitochondria may be a result of inhibition of respiration, transition of mitochondrial permeability, and formation of reactive oxygen species (ROS; Saviani et al., 2002; Taylor et al., 2004; Chen and Gibson, 2008), we investigated the molecular mechanism and the function of GDC-Cys modification in Arabidopsis.     

D-GLYCERATE 3-KINASE, the last unknown enzyme in the photorespiratory cycle in Arabidopsis, belongs to a novel kinase family

D-GLYCERATE 3-KINASE (GLYK; EC 2.7.1.31) catalyzes the concluding reaction of the photorespiratory C2 cycle, an indispensable ancillary metabolic pathway to the photosynthetic C3 cycle that enables land plants to grow in an oxygen-containing atmosphere. Except for GLYK, all other enzymes that contribute to the C2 cycle are known by their primary structures, and the encoding genes have been identified. We have purified and partially sequenced this yet missing enzyme from Arabidopsis thaliana and identified it as a putative kinase-annotated single-copy gene At1g80380. The exclusive catalytic properties of the gene product were confirmed after heterologous expression in Escherichia coli. Arabidopsis T-DNA insertional knockout mutants show no GLYK activity and are not viable in normal air; however, they grow under elevated CO2, providing direct evidence of the obligatory nature of the ultimate step of the C2 cycle. The newly identified GLYK is both structurally and phylogenetically distinct from known glycerate kinases from bacteria and animals. Orthologous enzymes are present in other plants, fungi, and some cyanobacteria. The metabolic context of GLYK activity in fungi and cyanobacteria remains to be investigated.     

Glycine decarboxylase controls photosynthesis and plant growth

Photorespiration makes oxygenic photosynthesis possible by scavenging 2-phosphoglycolate. Hence, compromising photorespiration impairs photosynthesis. We examined whether facilitating photorespiratory carbon flow in turn accelerates photosynthesis and found that overexpression of the H-protein of glycine decarboxylase indeed considerably enhanced net-photosynthesis and growth of Arabidopsis thaliana. At the molecular level, lower glycine levels confirmed elevated GDC activity in vivo, and lower levels of the CO₂ acceptor ribulose 1,5-bisphosphate indicated higher drain from CO₂ fixation. Thus, the photorespiratory enzyme glycine decarboxylase appears as an important feed-back signaller that contributes to the control of the Calvin-Benson cycle and hence carbon flow through both photosynthesis and photorespiration.     

Only plant-type (GLYK) glycerate kinases produce d-glycerate 3-phosphate

d-Glycerate kinases (GK) occur in three phylogenetically distinct classes. Class II GKs produce glycerate 2-phosphate, while both class I GK and class III GK (GLYK) are thought to produce glycerate 3-phosphate. We report on the identification of a bacterial-type class I GK in the unicellular cyanobacterium Synechocystis sp. strain PCC 6803 and of a plant-type GLYK in the filamentous cyanobacterium Nostoc sp. strain PCC 7120. The comparison with other prokaryotic and eukaryotic GKs of both classes shows that glycerate 3-phosphate is produced only by the GLYKs, but, in contrast to current thinking, not by any of the examined class I enzymes.     

Antisense reduction of serine hydroxymethyltransferase results in diurnal displacement of NH4+ assimilation in leaves of Solanum tuberosum

Serine hydroxymethyltransferase (SHMT) is part of the mitochondrial enzyme complex catalysing the photorespiratory production of serine, ammonium and CO(2) from glycine. Potato plants (Solanum tuberosum cv. Solara) with antisensed SHMT were generated to investigate whether photorespiratory intermediates accumulated during light lead to nocturnal activation of the nitrogen-assimilating enzymes glutamine synthetase (GS) and glutamate synthase (GOGAT). The transformant lines contained 70-90% less SHMT protein, and exhibited a corresponding decrease in mitochondrial SHMT activity. SHMT antisense plants displayed lower photosynthetic capacity and accumulated glycine in light. Glycine was converted to serine in the second half of the light period, while serine, ammonium and glutamine showed an inverse diurnal rhythm and reached highest values in darkness. GS/GOGAT protein levels and activities in the transgenics also reached maximum levels in darkness. The diurnal displacement of NH(4)(+) assimilation was accompanied by a change in the subunit composition of GS(2), but not GS(1). It is concluded that internal accumulation of post-photorespiratory ammonium is leading to nocturnal activation of GS/GOGAT, and that the time shift in ammonia assimilation can constitute part of a strategy to survive photorespiratory impairment.     

Simultaneous stimulation of sedoheptulose 1,7‐bisphosphatase,fructose 1,6‐bisphophate aldolase and the photorespiratory glycine decarboxylase‐H protein increases CO2 assimilation,vegetative biomass and seed yield in Arabidopsis

In this article, we have altered the levels of three different enzymes involved in the Calvin–Benson cycle and photorespiratory pathway. We have generated transgenic Arabidopsis plants with altered combinations of sedoheptulose 1,7‐bisphosphatase (SBPase), fructose 1,6‐bisphophate aldolase (FBPA) and the glycine decarboxylase‐H protein (GDC‐H) gene identified as targets to improve photosynthesis based on previous studies. Here, we show that increasing the levels of the three corresponding proteins, either independently or in combination, significantly increases the quantum efficiency of PSII. Furthermore, photosynthetic measurements demonstrated an increase in the maximum efficiency of CO₂ fixation in lines over‐expressing SBPase and FBPA. Moreover, the co‐expression of GDC‐H with SBPase and FBPA resulted in a cumulative positive impact on leaf area and biomass. Finally, further analysis of transgenic lines revealed a cumulative increase of seed yield in SFH lines grown in high light. These results demonstrate the potential of multigene stacking for improving the productivity of food and energy crops.     

Lipoate-Protein Ligase and Octanoyltransferase Are Essential for Protein Lipoylation in Mitochondria of Arabidopsis

Prosthetic lipoyl groups are required for the function of several essential multienzyme complexes, such as pyruvate dehydrogenase (PDH), α-ketoglutarate dehydrogenase (KGDH), and the glycine cleavage system (glycine decarboxylase [GDC]). How these proteins are lipoylated has been extensively studied in prokaryotes and yeast (Saccharomyces cerevisiae), but little is known for plants. We earlier reported that mitochondrial fatty acid synthesis by ketoacyl-acyl carrier protein synthase is not vital for protein lipoylation in Arabidopsis (Arabidopsis thaliana) and does not play a significant role in roots. Here, we identify Arabidopsis lipoate-protein ligase (AtLPLA) as an essential mitochondrial enzyme that uses octanoyl-nucleoside monophosphate and possibly other donor substrates for the octanoylation of mitochondrial PDH-E2 and GDC H-protein; it shows no reactivity with bacterial and possibly plant KGDH-E2. The octanoate-activating enzyme is unknown, but we assume that it uses octanoyl moieties provided by mitochondrial β-oxidation. AtLPLA is essential for the octanoylation of PDH-E2, whereas GDC H-protein can optionally also be octanoylated by octanoyltransferase (LIP2) using octanoyl chains provided by mitochondrial ketoacyl-acyl carrier protein synthase to meet the high lipoate requirement of leaf mesophyll mitochondria. Similar to protein lipoylation in yeast, LIP2 likely also transfers octanoyl groups attached to the H-protein to KGDH-E2 but not to PDH-E2, which is exclusively octanoylated by LPLA. We suggest that LPLA and LIP2 together provide a basal protein lipoylation network to plants that is similar to that in other eukaryotes.Lipoic acid (LA; 6,8-dithiooctanoic acid) prosthetic groups are essential for the catalytic activity of four important multienzyme complexes in plants and other organisms: pyruvate dehydrogenase (PDH), α-ketoglutarate dehydrogenase (KGDH), branched-chain α-ketoacid dehydrogenase (BCDH), and the Gly cleavage system (glycine decarboxylase [GDC]; Perham, 2000; Douce et al., 2001; Mooney et al., 2002). In all these multienzyme complexes, LA is covalently attached to the ε-amino group of a particular lysyl residue of the respective protein subunit. Lipoylated E2 subunits of PDH, KGDH, and BCDH are dihydrolipoyl acyltransferases that interact with E1 and E3 subunits to pass acyl intermediates to CoA (Mooney et al., 2002). By contrast, the lipoylated H-protein of GDC acts as a cosubstrate of three other GDC proteins and has no enzymatic activity itself (Douce et al., 2001). In the course of their respective reaction cycles, LA becomes reduced to dihydrolipoic acid. Most of these enzymes are confined to the mitochondrion. As the only exception, PDH is also present in plastids, where it provides acetyl-CoA for fatty acid biosynthesis (Ohlrogge et al., 1979; Lernmark and Gardeström, 1994; Lin et al., 2003).Mitochondria and plastids each have their own route of de novo LA synthesis, both of which start with the synthesis of protein-bound octanoyl chains (Shimakata and Stumpf, 1982; Ohlrogge and Browse, 1995; Wada et al., 1997; Gueguen et al., 2000; Yasuno et al., 2004). These octanoyl moieties are passed on by organelle-specific octanoyltransferases (Wada et al., 2001a, 2001b) to the respective target apoproteins where lipoyl synthase (LIP1) inserts two sulfur atoms to finally produce functional lipoyl groups (Yasuno and Wada, 1998, 2002; Zhao et al., 2003). A similar pathway has been identified in mammalian mitochondria (Morikawa et al., 2001; Witkowski et al., 2007). In quantitative terms, leaf mesophyll mitochondria have an extraordinarily high requirement for lipoate, because they contain very large amounts of GDC to catalyze the photorespiratory Gly-to-Ser conversion (Bauwe et al., 2010). For this reason, leaf mesophyll mitochondria are the major site of LA synthesis in plants (Wada et al., 1997).It was thought that the octanoyl chains provided by mitochondrial β-ketoacyl-acyl carrier protein synthase (mtKAS) represent the solitary source for protein lipoylation in plant mitochondria (Yasuno et al., 2004). As we reported earlier, however, leaves of mtKAS-deficient knockout mutants show considerable lipoylation of mitochondrial PDH-E2 and KGDH-E2 subunits and some residual lipoylation of GDC H-protein; roots are not at all impaired. Accordingly, the phenotype of such mutants can be fully cured in the low-photorespiratory condition of elevated CO₂ (Ewald et al., 2007). These observations indicated that plant mitochondria, in addition to the mtKAS-LIP2-LIP1 route of protein lipoylation, can resort to an alternative pathway. This would not be uncommon. In Escherichia coli, for example, a salvage pathway utilizes free octanoate or LA in an ATP-dependent two-step reaction catalyzed by the bifunctional enzyme lipoate-protein ligase A (LPLA; Morris et al., 1995). Archaea (Christensen and Cronan, 2009; Posner et al., 2009) and vertebrates (Tsunoda and Yasunobu, 1967) require two separate enzymes to first activate octanoate or LA to lipoyl-nucleoside monophosphate (NMP) and then, in a second step, to convey the activated lipoyl group to the respective target proteins. The lipoate-activating enzyme (LAE) of mammals was identified as a refunctioned medium-chain acyl-CoA synthetase that utilizes GTP to produce lipoyl-GMP (Fujiwara et al., 2001). LIP3 from yeast (Saccharomyces cerevisiae) can use octanoyl-CoA to octanoylate apoE2 proteins (Hermes and Cronan, 2013), whereas octanoyl groups from fatty acid biosynthesis are first attached to H-protein and then passed on to apoE2 proteins (Schonauer et al., 2009).The physiological significance of lipoyl-protein ligases in plants is not exactly known. Such enzymes do not operate in plastids (Ewald et al., 2014) but could be present in mitochondria. A single-gene-encoded LPLA with predicted mitochondrial localization has been identified in rice (Oryza sativa; Kang et al., 2007). Complementation studies with the lipoylation-deficient E. coli mutant TM137 (Morris et al., 1995) suggested that OsLPLA belongs to the bifunctional type of LPLAs. We report the identification of the homologous enzyme in Arabidopsis (Arabidopsis thaliana), provide evidence for its mitochondrial location, and show that Arabidopsis LPLA requires a separate enzyme for octanoate/lipoate activation. We also examine the interplay between LPLA, LIP2, and the mtKAS route of protein lipoylation and suggest a model for protein lipoylation in plant mitochondria.