Subcellular localization of hexokinase in pea leaves. Evidence for the predominance of a mitochondrially bound form

The existence of phospholipase A(2) activity in plant mitochondria and its activation by hyperosmotic stress in durum wheat (Triticum durum Desf.)

The activity of mitochondrial phospholipase A(2) (PLA(2)) was shown for the first time in plants. It was observed in etiolated seedlings from durum wheat, barley, tomato, spelt and green seedlings of maize, but not in potato and topinambur tubers and lentil etiolated seedlings. This result was achieved by a novel spectrophotometric assay based on the coupled PLA(2)/lipoxygenase reactions using 1-palmitoyl-2-linoleoyl-sn-glycero-3-phosphatidylcholine as substrate; the mitochondrial localisation was assessed by checking recovery of marker enzymes. Durum wheat mitochondrial PLA(2) (DWM-PLA(2)) showed maximal activity at pH 9.0 and 1mM Ca(2+), hyperbolic kinetics (K(m)=90±6μM, V(max)=29±1nmolmin(-1)mg(-1) of protein) and inhibition by methyl arachidonyl fluorophosphonate, 5-(4-benzyloxyphenyl)-4S-(7-phenylheptanoylamino)pentanoic acid and palmityl trifluoromethyl ketone. Reactive oxygen species had no effect on DWM-PLA(2), that instead was activated by about 50% and 95%, respectively, under salt (0.21M NaCl) and osmotic (0.42M mannitol) stress imposed during germination. Contrarily, a secondary Ca(2+)-independent activity, having optimum at pH 7.0, was stress-insensitive. We propose that the activation of DWM-PLA(2) is responsible for the strong increase of free fatty acids recently measured in mitochondria under the same stress conditions [Laus, et al., J. Exp. Bot. 62 (2011) 141-154] that, in turn, activate potassium channel and uncoupling protein, able to counteract hyperosmotic stress.

Putting plant hexokinases in their proper place

Hexokinases (HXKs), catalysts of the first essential step in glucose metabolism, have emerged as important enzymes that mediate sugar sensing in many organisms, including plants. The presence of several types of plant HXK isozymes, located in different intracellular locations, has been suggested. However, recent studies have indicated that most plants have only two types of HXKs, a plastidic stromal isozyme and membrane-associated isozymes located mainly adjacent to the mitochondria, but also in the nucleus. The membrane-associated isozymes are involved in sugar sensing and regulate gene expression. The central role of HXKs in plant development and the increasing interest in their role necessitate the correction of inaccuracies that have spread concerning the substrate specificity and intracellular localization of HXK isozymes, as these inaccuracies are affecting the hypothesized roles presented for these isozymes and shaping future research in this active field.

Spinach SoHXK1 is a mitochondria-associated hexokinase

Hexokinase, a hexose-phosphorylating enzyme, has emerged as a central enzyme in sugar-sensing processes. A few HXK isozymes have been identified in various plant species. These isozymes have been classified into two major groups; plastidic (type A) isozymes located in the plastid stroma and those containing a membrane anchor domain (type B) located mainly adjacent to the mitochondria, but also found in the nucleus. Of all the hexokinases that have been characterized to date, the only exception to this rule is a spinach type B HXK (SoHXK1) that, by means of subcellular fractionation, has been localized to the outer membrane of plastids. However, SoHXK1 has a membrane anchor domain that is almost identical to that of the other type B HXKs. To determine the localization of SoHXK1 enzyme by other means, we expressed SoHXK1::GFP fusion protein in tobacco and Arabidopsis protoplasts and compared its localization with that of the Arabidopsis AtHXK1::GFP fusion protein that shares a similar N-terminal membrane anchor domain. SoHXK1::GFP is localized adjacent to the mitochondria, similar to AtHXK1::GFP and all other previously examined type B HXKs. Proteomic analysis had previously identified AtHXK1 on the outside of the mitochondrial membrane. We, therefore, suggest that SoHXK1 enzyme is located adjacent to the mitochondria like the other type B HXKs that share the same N-terminal membrane anchor domain.

Partial purification of tightly bound mitochondrial hexokinase from maize (Zea mays L.) root membranes

In mammals, hexokinase (HK) is strategically located at the outer membrane of mitochondria bound to the porin protein. The mitochondrial HK is a crucial modulator of apoptosis and reactive oxygen species generation. In plants, these properties related to HK are unknown. In order to better understand the physiological role of non-cytosolic hexokinase (NC-HK) in plants, we developed a purification strategy here described. Crude extract of 400 g of maize roots (230 mg protein) contained a specific activity of 0.042 micromol G6P min(-1) mg PTN(-1). After solubilization with detergent two fractions were obtained by DEAE column chromatography, NC-HK 1 (specific activity = 3.6 micromol G6P min(-1) mg PTN(-1) and protein recovered = 0.7 mg) and NC-HK 2. A major purification (yield = 500-fold) was obtained after passage of NC-HK 1 through the hydrophobic phenyl-Sepharose column. The total amount of protein and activity recovered were 0.04 and 18%, respectively. The NC-HK 1 binds to the hydrophobic phenyl-Sepharose matrix, as observed for rat brain HK. Mild chymotrypsin digestion did not affect adsorption of NC-HK 1 to the hydrophobic column as it does for rat HK I. In contrast to mammal mitochondrial HK, glucose-6-phosphate, clotrimazole or thiopental did not dissociate NC-HK from maize (Zea mays) or rice (Oryza sativa) mitochondrial membranes. These data show that the interaction between maize or rice NC-HK to mitochondria differs from that reported in mammals, where the mitochondrial enzyme can be displaced by modulators or pharmacological agents known to interfere with the enzyme binding properties with the mitochondrial porin protein.

Two newly identified membrane-associated and plastidic tomato HXKs: characteristics, predicted structure and intracellular localization

Two new tomato hexokinase genes, LeHXK3 and LeHXK4, were cloned and characterized, placing tomato as the first plant with four characterized HXK genes. Based on their sequence, LeHXK3 is the third membrane-associated (type-B) and LeHXK4 is the first plastidic (type-A) HXK identified in tomato. Expression of HXK-GFP fusion proteins in protoplasts indicated that the LeHxk3 enzyme is associated with the mitochondria while LeHxk4 is localized in plastids. Furthermore, LeHxk4::GFP fusion protein is found within stromules, suggesting transport of LeHxk4 between plastids. Structure prediction of the various plant HXK enzymes suggests that unlike the plastidic HXKs, the predicted membrane-associated HXKs are positively charged near their putative N-terminal membrane anchor domain, which might enhance their association with the negatively charged membranes. LeHxk3 and LeHxk4 were analyzed following expression in yeast. Both enzymes have higher affinity for glucose relative to fructose and are inhibited by ADP. Yet, unlike the other HXKs, the stromal HXK has higher Vmax with glucose than with fructose. Expression analysis of the four HXK genes in tomato tissues demonstrated that LeHXK1 and LeHXK4 are the dominant HXKs in all tissues examined. Notably, the plastidic LeHXK4 is expressed in all tissues including starchless, non-photosynthetic sink tissues, such as pink and red fruits, implying phosphorylation of imported hexoses in plastids. It has been suggested that trehalose 6-phosphate (T6P) might inhibit HXK activity. However, none of the yeast-expressed tomato HXK genes was sensitive either to T6P or to trehalose, suggesting that unlike fungi HXKs, plant HXKs are not regulated by T6P.

A novel type of chloroplast stromal hexokinase is the major glucose-phosphorylating enzyme in the moss Physcomitrella patens

Hexokinase catalyzes the first step in the metabolism of glucose but has also been proposed to be involved in sugar sensing and signaling both in yeast and in plants. We have cloned a hexokinase gene, PpHXK1, in the moss Physcomitrella patens where gene function can be studied directly by gene targeting. PpHxk1 is a novel type of chloroplast stromal hexokinase that differs from previously studied membrane-bound plant hexokinases. Enzyme assays on a knock-out mutant revealed that PpHxk1 is the major glucose-phosphorylating enzyme in Physcomitrella, accounting for 80% of the total activity in protonemal tissue. The mutant is deficient in the response to glucose, which in wild type moss induces the formation of caulonemal filaments that protrude from the edge of the colony. Growth on glucose in the dark is strongly reduced in the mutant. Sequence data suggest that most plants including Physcomitrella and Arabidopsis have both chloroplast-imported hexokinases similar to PpHxk1 and traditional membrane-bound hexokinases. We propose that the two types of plant hexokinases have distinct physiological roles.