Diverse regulation by sucrose of enzymes involved in storage lipid breakdown in germinating lupin seeds

The regulatory function of sucrose in the activity of lipid-degrading enzymes was investigated in germinating seeds of yellow lupin (Lupinus luteus L.), white lupin (Lupinus albus L.) and Andean lupin (Lupinus mutabilis Sweet). The study was conducted on isolated embryo axes, excised cotyledons and seedlings cultured in vitro for 96 h on medium with 60 mM sucrose or without the sugar. The activity of lipase (lipolysis), acyl-CoA oxidase and catalase (fatty acid β-oxidation) was enhanced in all studied organs cultured on medium without sucrose. The activity of cytosolic aconitase (glyoxylate cycle) was stimulated by sucrose in seedling axes and isolated embryo axes, whereas in seedling cotyledons and excised cotyledons, it was inhibited. The regulatory function of sucrose in phosphoenolpyruvate carboxykinase (gluconeogenesis) was observed only in isolated embryo axes and the activity was lower in carbohydrate deficiency conditions. The peculiar features of storage lipid breakdown in germinating lupin seeds and its regulation by sucrose are discussed.     

Regulation by sucrose of storage compounds breakdown in germinating seeds of yellow lupine (Lupinus luteus L.), white lupine (Lupinus albus L.) and Andean lupine (Lupinus mutabilis Sweet). II. Mobilization of storage lipid

Research of the regulatory function of sucrose in storage lipid breakdown was conducted on isolated embryo axes, excised cotyledons and whole seedlings of three lupine species grown in vitro on medium with 60 mM sucrose or without the sugar. Lack of sucrose in the medium caused significant increase in total lipid content in yellow, white and Andean lupine isolated embryo axes but in Andean lupine seedling cotyledons and excised cotyledons, lipid level was clearly lower in carbohydrates deficient conditions. Sucrose caused no significant effect on fatty acids spectra. The main fatty acid in yellow lupine seeds was linoleic acid, in white lupine oleic acid and in Andean lupine both oleic and linoleic acids. The main phospholipid in organs of three lupine species was phosphatidylcholine. In sugar-deficient conditions, content of phosphatidylcholine and some others phospholipids was decreased. The peculiar features of regulation by sugars of storage lipid breakdown in germinating lupine seeds and induction of autophagy in young carbohydrate starved embryo axes is discussed.     

Comparative study of storage compound breakdown in germinating seeds of three lupine species

Storage lipid and protein breakdown in germinating seeds of yellow (Lupinus luteus L.), white (L. albus L.), and Andean lupine (L. mutabilis Sweet) and regulatory function of sucrose were investigated. Less oil bodies were detected in organs of yellow lupine seeds, whereas the highest content of oil bodies was noticed in the Andean lupine seeds. Mature, air-dried yellow, white and Andean lupine seeds do not contain starch. Starch grains appear the earliest in white lupine seeds during imbibition. Sucrose deficiency in tissues enhances breakdown of storage lipid, protein and temporary starch in cotyledons. In sucrose starved embryo axes of all investigated lupine species, an increased level of vacuolization was noted. Interconnections between catabolism of storage protein and storage lipid in germinating lupine seeds were identified by applying ¹⁴C-acetate. To assess the importance of key processes in storage lipid breakdown NaF (inhibitor of glycolysis and gluconeogenesis), KCN, NaN₃ and SHAM (inhibitors of mitochondrial electron transport chain) and MSO (inhibitor of glutamine synthetase) were used. Radioactivity coming from ¹⁴C-acetate was released as ¹⁴CO₂ but mostly was incorporated into ethanol-soluble fraction of embryo axes and cotyledons. Respiratory inhibitors caused a significant decrease in ¹⁴CO₂ and ethanol fractions in all three lupine species studied. MSO stimulated release of ¹⁴CO₂ and radioactivity of ethanol fractions in yellow lupine organs fed with sucrose, but in Andean lupine MSO enhanced the production of ¹⁴CO₂ and radioactivity of ethanol fractions both in organs fed and not fed with sucrose. Different strategies of storage compound breakdown are proposed, depending on relative proportion in storage protein and lipid content in lupine seeds.     

Regulation of storage lipid metabolism in developing and germinating lupin (<Emphasis Type="Italic">Lupinus</Emphasis> spp.) seeds

The main storage compound in lupin seeds is protein, whose content can reach up to 45–50 % of dry matter. However, seeds of some lupin species can also contain quite a large amount of storage lipid. The range of lipid content in lupin seeds is from about 6 to about 20 % of dry matter. Storage lipid in developing seeds is synthesized mainly from sugars delivered by mother plants. During seed germination, one of the main end-products of storage lipid breakdown is also sugars. Thus, the sugar level in tissues is considered an important regulatory agent, during both lipid accumulation and lipid breakdown. Generally, in developing legume seeds, there is a strong negative relation between accumulation of storage protein and storage lipid. Results obtained in developing lupin cotyledons cultured in vitro pointed to the possibility of a positive relation between protein and lipid accumulation. Such a positive effect could be caused by nitrate. During lupin seed germination and seedling development, the utilization of storage lipid is enhanced under sugar deficiency conditions in tissues and is controlled at the gene expression level. However, under sugar starvation conditions, autophagy is significantly enhanced, and it can cause disturbances in storage lipid breakdown. The hypothesis of pexophagy, i.e., autophagic degradation of peroxisomes under sugar starvation conditions during lupin seed germination, has been taken into consideration. The flow of lipid-derived carbon skeletons to amino acids was discovered in germinating lupin seeds, and this process is clearly more intense in sucrose-fed embryo axes. At least four alternative or mutually complementary pathways of carbon flow from storage lipid to amino acids in germinating lupin seeds are postulated. The different strategies of storage compound breakdown during lupin seed germination are also discussed.     

Sugar metabolism in germinating soybean seeds: evidence for the sorbitol pathway in soybean axes

Characterization of sugar content and enzyme activity in germinating soybean (Glycine max L. Merrell) seeds led to the discovery of sorbitol accumulating in the axes during germination. The identity of sorbitol was confirmed by relative retention times on high-performance liquid chromatography and gas liquid chromatography and by mass spectra identical with authentic sorbitol. Accumulation of sorbitol in the axes started on day 1 of germination as sucrose decreased and glucose and fructose increased. Sucrose also decreased in the cotyledons, but there was no accumulation of sorbitol, glucose, or fructose. Accumulation of sorbitol and hexoses was highly correlated with increased invertase activity in the axes, but not with sucrose synthase and sucrose phosphate synthase activities. Sucrose synthase activity was relatively high in the axes, whereas the activity of sucrose phosphate synthase was relatively high in the cotyledons. Ketose reductase and aldose reductase were detected in germinating soybean axes, but not in cotyledons. Fructokinase and glucokinase were present in both axes and cotyledons. The data suggest a sorbitol pathway functioning in germinating soybean axes, which allows for the interconversion of glucose and fructose with sorbitol as an intermediate.     

Asparagine metabolism-key to the nitrogen nutrition of developing legume seeds

Asparagine accounted for 50 to 70% of the nitrogen carried in translocatory channels serving fruit and seed of white lupin (Lupinus albus L.). Rates of supply of the amide always greatly exceeded its incorporation as such into protein. An asparaginase (l-asparagine amido hydrolase EC 3.5.1.1) was demonstrated in crude extracts of seeds. In vitro activity was up to 5 mumoles of aspartate formed per hour per gram fresh weight at the apparent Km(Asn) value of 10 mM, and this more than accounted for the estimated rates of asparagine utilization in vivo. Asparaginase activity per seed increased 10-fold in the period 5 to 7 weeks after anthesis, coinciding with early stages of storage protein synthesis in the cotyledons.Double labeled ((14)C (U), (15)N (amide)) asparagine was fed to fruiting shoots through the transpiration steram. Fruit phloem sap analysis indicated that virtually all of the label was translocated to seeds in the form of asparagine. In young seeds (15)N from asparagine breakdown was traced to the ammonia, glutamine, and alanine of endospermic fluid, the (14)C appearing mainly in nonamino compounds. In the cotyledon-filling stage the C and N of asparagine was contributed to a variety of amino acid residues of protein.     

Lupine embryo axes under salinity stress. I. Ultrastructural response

Embryonic root is the primary site of salinity perception in germinating seeds. To understand better the NaCl stress response of lupine embryo axes, ultrastructural approach combined with analysis of DNA degradation was used. In this study lupine embryo axes were cultured in vitro on the medium supplemented with two salt concentrations 250 and 500 mM to differ the reaction. To assess the rate of DNA damage, alkaline electrophoresis of isolated nuclei and DNA fragmentation analysis were performed. Results of these studies suggest programmed cell death induction under salinity stress. Moreover, ultrastructure observations revealed other characteristic features of programmed cell death like endoplasmic reticulum reorganization, increased level of vacuolization, chromatin condensation and starch grains degradation. Our comparative analysis of ultrastructure changes and DNA fragmentation speak in favour of programmed cell death in lupine (Lupinus luteus L. ‘Mister’) embryo axes treated for 12 h with 250 and 500 mM NaCl.     

Lysyl tRNAs of lupinus luteus seeds

Lysine accepting transfer RNA of lupin seeds and lupin embryo axes can be fractionated into at least 5 species by reversed-phase chromatography (RPC-5). One main and two minor isoacceptors were observed in wheat and barley embryos. Changes in isoaccepting species of tRNA^1ys were followed in cotyledons of germinating lupin seedlings. Ribosome binding studies revealed that one of the main lupin tRNA^1ys species recognizes the AAG codon, the second AAA and the third one AAA and AAG.     

Changes in soluble carbohydrates and related enzymes induced by low temperature during early developmental stages of quinoa (Chenopodium quinoa) seedlings

Low temperature represents one of the principal limitations in species distribution and crop productivity. Responses to chilling include the accumulation of simple carbohydrates and changes in enzymes involved in their metabolism. Soluble carbohydrate levels and invertase, sucrose synthase (SS), sucrose-6-phosphate synthase (SPS) and alpha-amylase activities were analysed in cotyledons and embryonic axes of quinoa seedlings grown at 5 degrees C and 25 degrees C in the dark. Significant differences in enzyme activities and carbohydrate levels were observed. Sucrose content in cotyledons was found to be similar in both treatments, while in embryonic axes there were differences. Invertase activity was the most sensitive to temperature in both organs; however, SS and SPS activities appear to be less stress-sensitive. Results suggest that 1) metabolism in germinating perispermic seeds would be different from endospermic seeds, 2) sucrose futile cycles would be operating in cotyledons, but not in embryonic axes of quinoa seedlings under our experimental conditions, 3) low temperature might induce different regulatory mechanisms on invertase, SS and SPS enzymes in both cotyledons and embryonic axes of quinoa seedlings, and 4) low temperature rather than water uptake would be mainly responsible for the changes observed in carbohydrate and related enzyme activities.     

Asparagine synthesis in pea leaves, and the occurrence of an asparagine synthetase inhibitor

Asparagine is present in the mature leaves of young pea (Pisum sativum cv Little Marvel) seedlings, and is synthesized in detached shoots. This accumulation and synthesis is greatly enhanced by darkening. In detached control shoots, [¹⁴C]aspartate was metabolized predominantly to organic acids and, as other workers have shown, there was little labeling of asparagine (after 5 hours, 3.1% of metabolized label). Addition of the aminotransferase inhibitor aminooxyacetate decreased the flow of aspartate carbon to organic acids and enhanced (about 3-fold) the labeling of asparagine. The same treatment applied to darkened shoots resulted in a substantial conversion of [¹⁴C]aspartate to asparagine, over 10-fold greater than in control shoots (66% of metabolized label), suggesting that aspartate is the normal precursor of asparagine.

Only traces of glutamine-dependent asparagine synthetase activity could be detected in pea leaf or root extracts; activity was not enhanced by sulfhydryl reagents, oxidizing conditions, or protease inhibitors. Asparagine synthetase is readily extracted from lupin cotyledons, but yield was greatly reduced by extraction in the presence of pea leaf tissue; pea leaf homogenates contained an inhibitor which produced over 95% inhibition of an asparagine synthetase preparation from lupin cotyledons. The inhibitor was heat stable, with a low molecular weight. Presence of an inhibitor may prevent detection of asparagine synthetase in pea extracts and in Asparagus, where a cyanide-dependent pathway has been proposed to account for asparagine synthesis: an inhibitor with similar properties was present in Asparagus shoot tissue.

     

Regulation by sucrose of storage compounds breakdown in germinating seeds of yellow lupine (Lupinus luteus L.), white lupine (Lupinus albus L.) and Andean lupine (Lupinus mutabilis Sweet): I. Mobilization of storage protein

Research of the regulatory function of sucrose in storage protein breakdown was conducted on isolated embryo axes, excised cotyledons and whole seedlings of three lupine species grown in vitro on medium with 60 mM sucrose or without the sugar. Sucrose stimulated growth of yellow, white and Andean lupine isolated embryo axes and cotyledons but growth of seedlings was inhibited. Dry matter content was higher in sucrose-fed isolated organs and in seedling organs. Ultrastructure research revealed that lack of sucrose in the medium caused enhancement in storage protein breakdown. Protein deposits in cotyledons were smaller as well as soluble portion content in all studied organs was lower when there was no sucrose in the medium. In the same conditions, the activity of glutamate dehydrogenase was significantly higher. Increase in vacuolization of cells of white lupine root meristematic zone cells was observed and induction of autophagy in young carbohydrate-starved embryo axes is discussed.     

Gibberellin-like activity in cotyledons and embryonic axes during pea seed germination

Endogenous gibberellin-like activity was determined in dry pea seeds (Pisum sativum cv. Bördi), in cotyledons and axes of germinating pea seeds and also in excised cotyledons and axes. During the first two days of pea seed germination, neither the embryonic axes nor the cotyledons show a mutual influence on gibberellin activity, but this appears after 72–96 h of germination. The gibberellin-like activity m cotyledons and axes of germinating seeds increased during the same period, but it decreased in isolated axes and excised cotyledons.     

Activation of isoflavone biosynthesis in excised cotyledons of Lupinus seedlings by jasmonoids and excess light

Exogenous jasmonic acid (JA) and methyl jasmonate (MJ) induced accumulation of isoflavone constituents in cotyledons prepared from imbibed seeds of white lupin (Lupinus albus L.). Exogenous 0.2 mM MJ enhanced the levels of 7-O-(6"-O-malonyl)glucosylgenistein and 7-O-glucosylgenistein in the cotyledons of etiolated seedlings that had been incubated in the dark for 48 h. Regarding isoflavone induced by excision and slicing in the cotyledons as background level, the effect of light was 2- to 3-fold higher than that of 0.2 mM MJ. Cotyledons exposed to MJ along with a 24-h light period displayed a higher level of isoflavone accumulation than that of light alone. Total molar amounts of isoflavone accumulated in the cotyledons treated with MJ under continuous light were approximately the sum of those induced by MJ alone and light alone, respectively. The additive-like effect of MJ and light on isoflavone accumulation in lupin tissues suggested the presence of two different signaling systems independently responsible for those two stimuli. Excised cotyledons from etiolated yellow lupin (L. luteus L. cv. Topaz) seedlings also supported this hypothesis. The cotyledons could accumulate both an isoflavone and a flavone, and MJ selectively increased some of the isoflavone constituents, whereas light enhanced the levels of both. The selective accumulation mechanism of isoflavonoids in cotyledons, in which jasmonoids are involved, clearly differed from that activated by light.     

Glutamine-dependent asparagine synthetase from Lupinus luteus

Asparagine synthetase (glutamine-hydrolyzing [l-aspartate: l-glutamine amido-ligase (AMP-forming), E.C. 6.3.5.4] was purified over 500-fold from cotyledon extracts of 1-week-old yellow lupin seedlings. The enzyme was labile and required protection by high levels of thiols; glycerol and the substrates also stabilized it. The reaction products were shown to be asparagine, AMP, PPi and glutamate. The limiting K_m values were for aspartate 1·3 mM, for MgATP 0·14 mM and for glutamine 0·16 mM. Positive homotropic cooperativity was observed for MgATP only, and gel filtration studies indicated that the substrate-free enzyme (MW 160 000) associated to a dimer (MW 320 000 in the presence of MgCl₂ and ATP. The purified enzyme, which had some glutaminase activity, catalyzed an aspartate- and glutamine-independent ATP-PPi exchange reaction at a rate 5–7-fold higher than the rate of asparagine synthesis. Initial velocity studies and exchange data indicated an overall ping-pong mechanism. Compared to similar enzymes isolated from mammalian tumor cells, the lupin enzyme appears to be unique with respect to MW, reaction mechanism and regulatory properties. The allosteric properties observed suggest an important role for this enzyme in the regulation of asparagine biosynthesis.     

Amino Acids Content in Germinating Seeds and Seedlings from Castanea sativa L

During germination the chestnut (Castanea sativa L.) var ecotype 33 accumulates a large amount of asparagine in the cotyledons. This compound also accumulates in the growing axis:shoots and roots. In the cotyledons, γ-aminobutyrate (GABA) represents a major amino compound during germination and early seedling growth. In young seedlings, 35 days old, arginine predominates over the other soluble amino acids, particularly in roots. Five enzymic activities involved in arginine and GABA have been measured in the storage organ of the seed: arginase and ornithine carbamyltransferase decrease during germination indicating the slowing down of the urea cycle. In contrast, ornithine aminotransferase increases. Glutamate decarboxylase is particularly active about 21 days after imbibition and GABA aminotransferase activity decreases during germination. These two activities are in good agreement with the likely transport of GABA from cotyledons to growing axis. Asparagine, arginine, and GABA are the three amino compounds obviously involved in the mobilization of nitrogen reserves in the germinating chestnut seeds Castanea sativa.     

Sucrose controls storage lipid breakdown on gene expression level in germinating yellow lupine (Lupinus luteus L.) seeds

This study revealed that cytosolic aconitase (ACO, EC 4.2.1.3) and isocitrate lyase (ICL, EC 4.1.3.1, marker of the glyoxylate cycle) are active in germinating protein seeds of yellow lupine. The glyoxylate cycle seems to function not only in the storage tissues of food-storage organs, but also in embryonic tissue of growing embryo axes. Sucrose (60 mM) added to the medium of in vitro culture of embryo axes and cotyledons decreased activity of lipase (LIP, EC 3.1.1.3) and activity of glutamate dehydrogenase (NADH-GDH, EC 1.4.1.2). The opposite effect was caused by sucrose on activity of cytosolic ACO, ICL as well as NADP⁺-dependent (EC 1.1.1.42) and NAD⁺-dependent (EC 1.1.1.41) isocitrate dehydrogenase (NADP-IDH and NAD-IDH, respectively); activity of these enzymes was clearly stimulated by sucrose. Changes in the activity of LIP, ACO, NADP-IDH, and NAD-IDH caused by sucrose were based on modifications in gene expression because corresponding changes in the enzyme activities and in the mRNA levels were observed. The significance of cytosolic ACO and NADP-IDH in carbon flow from storage lipid to amino acids, as well as the peculiar features of storage lipid breakdown during germination of lupine seeds are discussed.     

Metabolism of amino acids in germinating yellow lupin seeds III. Breakdown of arginine in sugar-starved organs cultivated in vitro

The pathways of arginine transformations in organs of yellow lupin (Lupinus luteus L.) cultivated in vitro in the presence and absence of sucrose were investigated. Isolated embryo axes, isolated cotyledons and seeds deprived of their coat were cultured for 96 h on Heller medium with 60 mM saccharose (the fed variant, +S), without sugar (the starved variant, −S) and for 72 h without sugar, followed by 24 h in its presence (the transferred variant, −S→+S). Activities of arginine decarboxylase [EC 4.1.1.19], arginase [EC 3.5.3.1], and urease [EC 3.5.1.5] were assessed in extracts from isolated embryo axes. They were the highest in the sugar-starved variant. Supplementation of the medium with saccharose resulted in decrease in enzyme activities. The level of urea was higher (of ca. 20 %) in starved embryos than in embryos grown in the saccharose-containing medium. Moreover, participation of transamination in arginine catabolism was evidenced.     

Inibizione Da Saccarosio Della Demolizione Delle Riserve Lipidiche in Cucurbita Maxima

Abstract

Inhibition by sucrose of utilization of storage lipids in germinating seeds of «Cucurbita maxima». – Previous work demonstrated that sugars inhibit almost completely the respiratory utilization of lipid in isolated cotyledons from germinating «Ricinus communis» seeds as well as in a yeast, «Rhodotorula gracilis». This research was carried out with the aim to further characterize this phenomenon; the material used are the cotyledons and the embryonic axes of «Cucurbita maxima» var. «mammouth», where the lipid contents markedly decrease during the first 72 hours of germination. By incubating the embrional axes, isolated from 48 hours germinating seeds in 0.1M sucrose it was observed: a) a rise of the R.Q. from 0,65 to 1 which is not due to alchoolic fermentation since no degradation of sucrose to ethanol was detected, b) a marked decrease or a complete inhibition of the utilization of fatty acids. On the contrary, no significant increase of R. Q. occurs, when the cotyledons are incubated in presence of 0.1M sucrose. The metabolic utilization of the fatty acids in «Cucurbita maxima» has been studied by using acetate-2-C¹⁴. Labelled acetate was fed after 30 and 90 minutes of incubation of the embryonic axes in water and, respectively in 0.1M sucrose. The radioactivity in the C0₂ and in total fatty acids fractions was measured 30 minutes after feeding the labelled acetate. It was found that: in the presence of sucrose: a) the incorporation of labelled acetate in fatty acids was increased by about 4396 after 30′ and by 10% after 90′. b) the dissimilation of acetate to CO₂ was decreased by about 5096. These results indicate that sucrose replaces lipids as respiratory material. Experiments with labelled acetate are in agreement with the hypotesis that the inhibition of lipid catabolism by sugars (or some derivative) is due chiefly an enhancement of lipid synthesis. At the same time there is probable an inhibition of fatty acids oxidation.     

Response of sugar interconversion, starch and protein accumulation to supplied metabolites during pod filling in chickpea

Detached chickpea inflorescences bearing pods at 20 days after flowering (DAF) were cultured for 5 days in complete liquid medium supplemented separately with asparate, myo-inositol, alpha-ketoglutarate and phytic acid. Effect of these metabolites on sugar interconvestion and starch and protein accumulation in developing pods was studied. Substituting asparate (62.5 mM) for glutamine in culture medium decreased relative proportion of sucrose in all pod tissues but increased the level of sugars, starch and protein in pod wall and cotyledons. In cotyledons, whereas myo-inositol (75 mM) reduced the accumulation of starch without affecting protein level, alpha-ketoglutarate (44 mM) increased both starch and protein accumulation. Both myo-inositol and alpha-ketoglutarate increased relative proportion of sucrose in cotyledons. Phytic acid (1 mM) decreased in cotyledons 14C incorporation from glucose into EtOH extract (principally constituted by sugars), amino acids and proteins but increased the same into starch. In cotyledons, phytic acid also increased 14C incorporation from glutamate into amino acids but this increase was negatively correlated with protein synthesis. Phytic acid decreased the relative distribution of 14C from glucose and glutamate into sucrose from pod wall but enhanced the same into EtOH extract from embryo. Based on the results, it is suggested that mode of metabolic response to exogenously supplied metabolites widely differs in pod tissues of chickpea.