Sugar metabolism in developing lupin seeds is affected by a short-term water deficit

A short-term water deficit (WD) imposed during the pre-storage phase of lupin seed development [15-22 d after anthesis (DAA)] accelerated seed maturation and led to smaller and lighter seeds. During seed development, neutral invertase (EC 3.2.1.26) and sucrose synthase (EC 2.4.1.13) have a central role in carbohydrate metabolism. Neutral invertase is predominant during early seed development (up to 40 DAA) and sucrose synthase during the growing and storage phase (40-70 DAA). The contribution of acid invertase is marginal. WD decreased sucrose synthase activity by 2-fold and neutral invertase activity by 5-6-fold. These changes were linked to a large decrease in sucrose ( approximately 60%) and an increase of the hexose:sucrose ratio. Rewatering restored sucrose synthase activity to control levels while neutral invertase activity remained depressed (30-60%). A transient accumulation of starch observed in control seeds was abolished by WD. Despite the several metabolic changes the final seed composition was largely unaltered by WD except for approximately 60% increase in stachyose and raffinose (raffinose family oligosaccharides). This increase in raffinose family oligosaccharides appears as the WD imprinting on mature seeds.     

Metabolism of carbohydrates during the development of seeds of the brazilian rubber tree [Hevea brasiliensis (Willd. Ex Adr. de Juss) Muell.-Arg.]

This work aimed at the assessment of the metabolism of carbohydrate during the development of the seeds of Brazilian rubber trees. The enzymatic activity of the acid invertase, neutral invertase and sucrose synthase (SuSy) and the levels of total soluble sugars (TSS), reducing sugars (RS) and sucrose were evaluated separately in each part of the fruit and seed—pericarp, seed coat, embryo and endosperm—on different days after the pollination (DAP). Based on the results obtained in this study, it is possible to conclude that in the beginning of the development of the rubber tree seeds, until 95 DAP, the endosperm presents high concentration of RS and low concentration of sucrose. After this period, the endosperm of the seed initiates starch accumulation and the concentration of RS decreases followed by the increase in the concentration of sucrose, presenting, after 120 DAP, an inversion of concentration of these two sugars. In the embryo, the levels of TSS, RS and sucrose show significant increase with the progress of the seed development. In the endosperm, the transition of the division phase and cell expansion for the storage of reserve material seem to occur around 120 DAP and is to be controlled mainly by the enzymes acid invertase and SuSy, while in the embryo, such transition seems to occur around 135 DAP and is to be controlled mainly by the enzymes acid and neutral invertases.     

Carbohydrate Content and Enzyme Metabolism in Developing Canola Siliques

Little biochemical information is available on carbohydrate metabolism in developing canola (Brassica napus L.) silique (pod) wall and seed tissues. This research examines the carbohydrate contents and sucrose (Suc) metabolic enzyme activities in different aged silique wall and seed tissues during oil filling. The silique wall partitioned photosynthate into Suc over starch and predominantly accumulated hexose. The silique wall hexose content and soluble acid invertase activity rapidly fell as embryos progressed from the early- to late-cotyledon developmental stages. A similar trend was not evident for alkaline invertase, Suc synthase (SuSy), and Suc-phosphate synthase. Silique wall SuSy activities were much higher than source leaves at all times and may serve to supply the substrate for secondary cell wall thickening. In young seeds starch was the predominant accumulated carbohydrate over the sampled developmental range. Seed hexose levels dropped as embryos developed from the early- to midcotyledon stage. Hexose and starch were localized to the testa or liquid endosperm, whereas Suc was evenly distributed among seed components. With the switch to oil accumulation, seed SuSy activity increased by 3.6-fold and soluble acid invertase activity decreased by 76%. These data provide valuable baseline knowledge for the genetic manipulation of canola seed carbon partitioning.     

Dynamics of carbohydrates in the embryo axes of horse chestnut seeds during their transition from dormancy to germination

It was shown that the content of carbohydrates and their composition in embryo axes of horse chestnut seeds changed as seeds acquired a capability of dormancy release and germination. Sucrose prevailed among carbohydrates, comprising to 150–160 mg/g dry wt. During the first half of the seed imbibition time, oligosaccharides, namely raffinose and stachyose, degraded, whereas the contents of glucose and fructose were very low. The second half of the imbibition period (until radicle protrusion) was characterized by a cessation of oligosaccharide breakdown and accumulation of monosaccharides. Carbohydrate balance showed that the contribution of oligosaccharide breakdown to sucrose and monosaccharide accumulation was rather small, and monosaccharides accumulated mostly at the expense of sucrose gradually coming from cotyledons during imbibition. The trend of carbohydrate metabolism in imbibing axial organs was similar during the entire period of a seed dormancy release in the course of stratification. A readiness for the commencement of these processes during the entire dormancy period implies that carbohydrate conversions in embryo axes are not a trigger for a dormancy release. Monosaccharide accumulation in embryo axes before radicle protrusion produces an increase in the osmotic pressure, as compared to that provided by sucrose, by approximately 20%. Recalcitrance of the horse chestnut seeds is discussed in relation to the role of carbohydrates and other endogenous osmotica in the establishment of osmotic properties.     

Responses to sucrose and glutamine by soybean embryos grown in vitro

Immature soybean (Glycine max [L.] Merr. cv. Ransom) embryos were grown in vitro in the presence of different concentrations of sucrose and glutamine to examine how availability of carbohydrate and nitrogen affects dry matter accumulation and embryo composition. Embryos were transferred to fresh medium every 4 days to maintain sucrose and glutamine concentrations of the culture medium. In all experiments, accumulation of dry matter and protein content increased when the sucrose concentration of the culture medium was increased from 1.5 to 150 mM: however, a relatively greater enhancement of dry matter than of protein accumulation resulted in a lower protein concentration at 150 than at 1.5 mM sucrose. Both content and concentration of protein were increased by the increases in glutamine supply to concentrations exceeding 68% protein at 120 mM glutamine. In combination with 150 mM sucrose, however, oil increased as glutamine supply was increased from 0.6 to 6 mM and then decreased as glutamine supply was increased from 6 lo 120 mM. Varying the concentration of sucrose available during seed development also affected embryo composition. Decreased availability of sucrose during either the early or late portion of the culture period resulted in lower accumulation of dry mailer as well as oil. Protein concentration was actually higher for embryos transferred from 150 to 1.5 nM sucrose than for those remaining in 150 mM throughout the culture period: however, the greater percentage of protein was due lo a decrease in accumulation of dry weight. In addition, embryo composition was affected by altering the availability of glutamine during culture, indicating that variation in the level of nitrogen assimilate delivered during seed development can change embryo composition. Decreasing the glutamine concentration of the medium lowered both protein and oil content. In contrast, increasing the glutamine concentration of the medium from 0.6 to 6 mM 8 days after initiation of culture increased the protein content and concentration of the embryo while oil content was not affected.     

wrinkled1: A Novel, Low-Seed-Oil Mutant of Arabidopsis with a Deficiency in the Seed-Specific Regulation of Carbohydrate Metabolism

During oil deposition in developing seeds of Arabidopsis, photosynthate is imported in the form of carbohydrates into the embryo and converted to triacylglycerols. To identify genes essential for this process and to investigate the molecular basis for the developmental regulation of oil accumulation, mutants producing wrinkled, incompletely filled seeds were isolated. A novel mutant locus, wrinkled1 (wri1), which maps to the bottom of chromosome 3 and causes an 80% reduction in seed oil content, was identified. Wild-type and homozygous wri1 mutant plantlets or mature plants were indistinguishable. However, developing homozygous wri1 seeds were impaired in the incorporation of sucrose and glucose into triacylglycerols, but incorporated pyruvate and acetate at an increased rate. Because the activities of several glycolytic enzymes, in particular hexokinase and pyrophosphate-dependent phosphofructokinase, are reduced in developing homozygous wri1 seeds, it is suggested that WRI1 is involved in the developmental regulation of carbohydrate metabolism during seed filling.     

Expression of lauroyl-acyl carrier protein thioesterase in brassica napus seeds induces pathways for both fatty acid oxidation and biosynthesis and implies a set point for triacylglycerol accumulation

Expression of a California bay lauroyl-acyl carrier protein thioesterase (MCTE) in developing seeds of transgenic oilseed rape alters the fatty acid composition of the mature seed, resulting in up to 60 mol% of laurate in triacylglycerols. In this study, we examined the metabolism of lauric acid and 14C-acetate in developing seeds of oilseed rape that express high levels of MCTE. Lauroyl-CoA oxidase activity but not palmitoyl-CoA oxidase activity was increased several-fold in developing seeds expressing MCTE. In addition, isocitrate lyase and malate synthase activities were six- and 30-fold higher, respectively, in high-laurate developing seeds. Control seeds incorporated 14C-acetate almost entirely into fatty acids, whereas in seeds expressing MCTE, only 50% of the label was recovered in lipids and the remainder was in a range of water-soluble components, including sucrose and malate. Together, these results indicate that the pathways for beta-oxidation and the glyoxylate cycle have been induced in seeds expressing high levels of MCTE. Although a substantial portion of the fatty acid produced in these seeds is recycled to acetyl-CoA and sucrose through the beta-oxidation and glyoxylate cycle pathways, total seed oil is not reduced. How is oil content maintained if lauric acid is inefficiently converted to triacylglycerol? The levels of acyl carrier protein and several enzymes of fatty acid synthesis were increased two- to threefold at midstage development in high-laurate seeds. These results indicate that a coordinate induction of the fatty acid synthesis pathway occurs, presumably to compensate for the lauric acid lost through beta-oxidation or for a shortage of long-chain fatty acids.     

Arabidopsis sucrose synthase 2 and 3 modulate metabolic homeostasis and direct carbon towards starch synthesis in developing seeds

Two genes encoding sucrose synthase (SUS), namely SUS2 (At5g49190) and SUS3 (At4g02280), are strongly and differentially expressed in Arabidopsis seed. Detailed biochemical analysis was carried out in developing seeds 9–21 days after flowering (DAF) of wild type and two knockouts. SUS2 and SUS3 are not redundant genes since single knockouts show a phenotype in developing seeds. The mutants had 30–50% less SUS activity and therefore accumulated 40% more sucrose and 50% less fructose at 15 DAF. This did not affect the hexose-P pool, but led to 30–70% less starch in embryo and seed coat. Lipids were 55% higher in both mutants at 9–15 DAF. It seems that sucrolysis via SUS is not required for oil or protein synthesis but rather for channeling carbon toward ADP-glucose and starch in seeds. Metabolite profiling with GC–TOF revealed specific downstream changes in primary metabolism as a consequence of signaling or regulatory fine-tuning. While sucrose increased, hexoses and specific amino acids decreased reciprocally. There was a developmental shift regarding an earlier timing of dry weight accumulation, germinative maturity, oil deposition, sugar levels, transient starch buildup, and protein storage. Nevertheless, final seed size and composition were unaltered due to an earlier cessation of growth, thus giving rise to an apparent silent phenotype of mature mutant seeds. We conclude that SUS is important for metabolite homeostasis and timing of seed development, and propose that an altered sucrose/hexose ratio can modify carbon partitioning and the pattern of storage compounds in Arabidopsis.     

Controlling seed development and seed size in Vicia faba: a role for seed coat-associated invertases and carbohydrate state

We previously provided evidence that seed coat-associated invertase is involved in controlling the carbohydrate state of developing seeds and, by this way, triggering developmental processes (Weber et al . (1995) Plant Cell , 7, 1835–1846). To verify our postulate, we compared seed development of two genotypes of Vicia faba differing in seed weight. The seed coat of the large-seeded genotype formed a higher number of parenchymatous cell layers and matured later. VfCWINV1 encoding a cell wall-bound invertase is expressed in the unloading zone of the seed coat. mRNA levels peaked later in 'large' coats and mRNA was present in more cell layers over a longer time period. Cell wall-bound invertase activity revealed a similar accumulation pattern, obviously generating the high hexose conditions present in the endospermal cavity bathing the premature cotyledons and thus controlling their carbohydrate state. High hexose conditions were correlated with an extended mitotic activity of the 'large' cotyledons. In 'large' and 'small' cotyledons, sucrose levels rose when hexoses decreased apparently terminating cell divisions and initiating differentiation and storage activities. This developmental switch was delayed in 'large' embryos. To prove the outlined relationship, sucrose was added in vitro to mitotically active cotyledons. This treatment favoured nuclear expansion and starch accumulation over cell division. In contrast, a hexose-based medium maintained cell divisions. We conclude that development of the embryo is coordinately regulated with that of the maternal seed coat which controls, by metabolic signals, the phase of cell division of the embryo and consequently also seed size.     

Enzymes involved in starch synthesis in the developing mung bean seed

The levels of free sugars, starch and enzymes involved in starch metabolism—sucrose synthetase, UDP and ADP glucose pyrophosphorylase, phosphorylase and starch synthetase—were assayed during seed development of three cultivars of mung bean (Vigna radiata). Free sugars and starch increased with increasing seed weight. Changes in levels of sucrose synthetase, UDP- and ADP-glucose pyrophosphorylases, and phosphorylase were paralleled by changes in starch accumulation. After the maximum activity levels of these enzymes had been reached, maximum activities of soluble starch synthetase and starch granule-bound starch synthetase occurred. There were high activities of sucrose synthetase and phosphorylase at maximum rates of starch accumulation. Thus, starch could be synthesized via the ADP glucose pathway in mung bean seeds. However, phosphorylase may account for the starch accumulation in the early stages of mung bean seed development.     

Carbohydrate metabolism in Nerine sarniensis bulbs developing in liquid culture

Anatomical and physiological changes accompanying enhanced Nerine sarniensis cv. Salmon Supreme bulb growth in vitro were examined. Small bulbs, 2–3 mm in diameter, grown in vitro on a semi-solid medium were subcultured to liquid medium with elevated levels of sucrose (Suc) and inorganic phosphate. Bulbs' fresh and dry weights, carbohydrate contents and the activities of enzymes related to carbohydrate metabolism were determined at different stages of bulb development. Starch was the dominant storage carbohydrate in these bulbs, and the leaf bases parenchyma cells were the principal storage tissue. During the first month of bulb growth, only small changes in starch content were detected. However, an increase in starch level was observed at later stages of development. The activity of ADP-glucose pyrophosphorylase (EC 2.7.7.27), a key enzyme of starch synthesis, increased just before the increase in starch accumulation. Sucrose was the dominant soluble sugar in the bulbs, only traces of glucose and fructose were detected. The activity of alkaline invertase (INV, EC 3.2.1.26) was higher than that of acid INV during the growth period. Sucrose synthase (EC 2.4.1.13) exhibited the highest Suc-degrading activity during bulb growth. Suc was hydrolyzed in the medium by the cell wall bound acid INV during the growing period. The results are discussed in relation to enhanced nerine bulb growth and development in vitro.     

Activity and localisation of sucrose synthase and invertase in ovules of sexual and apomicticBrachiaria decumbens

Summary Brachiaria decumbens has sexual and apomictic reproduction. Apomixis is facultative and of the aposporic type. In early stages of ovule development, differences in the pattern of callose deposition between sexual and apomictic plants were observed which points to possible differences in carbohydrate metabolism. Therefore, a comparative study on carbohydrate metabolism between a sexual diploid ecotype and an apomictic tetraploidB. decumbens was made. A histochemical determination of two enzymes responsible for sucrose degradation, sucrose synthase and invertase, was performed for all stages of ovule development. In addition, the concentrations of sucrose, glucose, and fructose were measured for each stage of ovule development, both for sexual and apomictic plants. The enzymes were localised by immunohistochemistry with heterologous antibodies. A distinct difference between sexual and apomictic plants was observed in the localisation of sucrose synthase activity as well as in the amount of activity, especially in the early stages of ovular development. Invertase activity localisation was comparable between ovules of the sexual and apomictic plants, but its activity is clearly higher in ovules of sexual plants. The localisation of the enzymes coincided with the place of activity. For both sexual and apomictic plants the amount of sucrose in the ovaries increased with the stage of ovule development. Differences in the amount of sucrose between sexual and apomictic plants in ovaries with ovules in comparable stages of development were detected. A delay in the onset of carbohydrate metabolism during early stages of ovule development characterises the apomictic plant.Abbreviations MMC megaspore mother cell - MC meiocyte - MS megaspore - AI apospore initial - CO coenocyte - MES mature embryo sac - SuSy sucrose synthase - INV invertase - BMM buthylmethyl methacrylate - DTT dithiothreitol - DAPI 4,6-diamidino-2-phenylindole - PBS phosphate-buffered saline     

Storage oil breakdown during embryo development of Brassica napus (L.)

In this study it is shown that at least 10% of the major storage product of developing embryos of Brassica napus (L.), triacylglycerol, is lost during the desiccation phase of seed development. The metabolism of this lipid was studied by measurements of the fate of label from [1-(14)C]decanoate supplied to isolated embryos, and by measurements of the activities of enzymes of fatty acid catabolism. Measurements on desiccating embryos have been compared with those made on embryos during lipid accumulation and on germinating seedlings. Enzymes of beta-oxidation and the glyoxylate cycle, and phosphoenolpyruvate carboxykinase were present in embryos during oil accumulation, and increased in activity and abundance as the seeds matured and became desiccated. Although the activities were less than those measured during germination, they were at least comparable to the in vivo rate of fatty acid synthesis in the embryo during development. The pattern of labelling, following metabolism of decanoate by isolated embryos, indicated a much greater involvement of the glyoxylate cycle during desiccation than earlier in oil accumulation, and showed that much of the (14)C-label from decanoate was released as CO(2) at both stages. Sucrose was not a product of decanoate metabolism during embryo development, and therefore lipid degradation was not associated with net gluconeogenic activity. These observations are discussed in the context of seed development, oil yield, and the synthesis of novel fatty acids in plants.     

Comparing carbohydrate status during norway spruce seed development and somatic embryo formation

Summary The carbohydrate status of developing seeds of Picea abies was examined in order to provide a frame of reference for the evaluation of changes in carbohydrate content in maturing somatic embryos of the same species. Samples were taken at weekly intervals from 12 May 1998 (estimated time of pollination) until 20 October 1998. The total non-structural carbohydrate content was high (≈150–180 μg mg⁻¹ dry weight) at the time of the first samples and the carbohydrate spectrum consisted of sucrose, glucose, fructose, and pinitol. A dramatic decrease in carbohydrate content took place from June 6 onwards, that was accompanied by changes in carbohydrate partitioning to favor sucrose over hexoses and the disappearance of pinitol. Raffinose and stachyose were first detected on July 28, and their content gradually increased thereafter. Isolated embryos and remaining megagametophytes were analyzed starting with September 1. Carbohydrate content was higher in isolated zygotic embryo than in the rest of the seed, with a slowly increasing fraction of raffinose and stachyose. Comparisons of presented data with the results of our previous study of somatic embryo carbohydrate status (Lipavská et al., 2000) revealed the following common features: (1) a decrease in total carbohydrate content and (2) an increase in sucrose:hexose ratios in developing seeds and embryonal suspensor mass. Marked differences were observed in carbohydrate spectra: (1) somatic embryo development was not accompanied by pinitol accumulation in any phase; (2) mature zygotic embryos, in contrast to mature somatic embryos, contained raffinose and stachyose. These observations will provide a solid basis for improvement of protocols for somatic embryogenesis in Picea.     

Respiration and soluble sugar metabolism in sugar pine embryos

Embroys excised from dormant seeds of sugar pine ( Pinus lambertiana Dougl.) incubated at 25°C (non-dormancy-breaking) or stratified at 5°C (dormancy-breaking) were analyzed to determine temperature effects on the relative activities of respiration and fermentative metabolism, the levels of soluble sugers and the activities of the hydrolytic enzymes, invertase and sucrose synthase, as related to the release of dormancy and germinatio. At 25°C, despite a sharp drop in embryo oxygen uptake after 48 h, a simultaneous decline in acetaldehyde and ethanol concentrations indicated that there was not a shift to fermentative metabolism. The concentrations of soluble sugars showed no treatment effects. Embryo invertase (EC 3.2.1.26) activity changed only slightly at either temperature, while stratification was accompanied by a 4-fold increase in sucrose synthase (EC 2.4.1.13) activity (cleavage direction). Upon transfer of stratified seeds to 25°C, embryo sucrose synthase activity rapidly increased almost 10-fold, with the increase beginning prior to germination, while mvertase activity increased 20-fold, concomitant with germination.     

Carbohydrates and carbohydrate enzymes in developing cotton ovules

Patterns of carbohydrates and carbohydrate enzymes were investigated in developing cotton ovules to establish which of these might be related to sink strength in developing bolls. Enzymatic analysis of extracted tissue indicated that beginning 1 week following anthesis, immature cotton seeds (Gossypium hirsutum L. cv. Coker 100A glandless) accumulated starch in the tissues which surround the embryo. Starting at 15 days post anthesis (DPA), this starch was depleted and starch simultaneously appeared in the embryo. Sucrose entering the tissues surrounding the embryo was rapidly degraded, apparently by sucrose synthase; the free hexose content of these tissues reached a peak at about 20 DPA. During the first few weeks of development these tissues contained substantial amounts of hexose but little sucrose; the reverse was true for cotton embryos. Embryo sucrose content rose sharply from the end of the first week until about 20 DPA; it then remained roughly constant during seed maturation. Galactinol synthase (EC 2.4.1.x) appeared in the embryos approximately 25 days after flowering. Subsequently, starch disappeared and the galactosides raffinose and stachyose appeared in the embryo. Except near maturity, sucrose synthase (EC 2.4.1.13) activity in the embryos predominated over that of both sucrose phosphate synthase (EC 2.4.1.14) and acid invertase (EC 3.2.1.26). Activities of the latter enzymes increased during the final stages of embryo maturation. The ratio of sucrose synthase to sucrose phosphate synthase was found to be high in young cotton embryos but the ratio reversed about 45 DPA, when developing ovules cease being assimilate sinks. Insoluble acid invertase was present in developing cotton embryos, but at very low activities; soluble acid invertase was present at significant activities only in nearly mature embryos. From these data it appears that sucrose synthase plays an important role in young cotton ovule carbohydrate partitioning and that sucrose phosphate synthase and the galactoside synthesizing enzymes assume the dominant roles in carbohydrate partitioning in nearly mature cotton seeds. Starch was found to be an important carbohydrate intermediate during the middle stages of cotton ovule development and raffinose and stachyose were found to be important carbohydrate pools in mature cotton seeds.     

Changes in the activities of carbon metabolizing enzymes with pod development in lentil (<Emphasis Type="Italic">Lens culinaris</Emphasis> L.)

Activities of some key enzymes of carbon metabolism sucrose synthase, acid and alkaline invertase, phosphoenol pyruvate carboxylase, malic enzyme and isocitrate dehydrogenase were investigated in relation to the carbohydrate status in lentil pods. Sucrose remained the dominant soluble sugar in the pod wall and seed, with hexoses (glucose and fructose) present at significantly lower levels. Sucrose synthase is the predominant sucrolytic enzyme in the developing seeds of lentil (Lens culinaris L.). Acid invertase was associated with pod elongation and showed little activity in seeds. Sucrose breakdown was dominated by alkaline invertase during the development of podwall, while both the sucrose synthase and alkaline invertase were active in the branch of inflorescence. A substantial increase of sucrolytic enzymes was observed at the time of maximum seed filling stage (10–20 DAF) in lentil seed. The pattern of activity of sucrose synthase highly paralleled the phase of rapid seed filling and therefore, can be correlated with seed sink strength. It seems likely that the fruiting structures of lentil utilize phosphoenol pyruvate carboxylase for recapturing respired carbon dioxide. Higher activities of isocitrate dehydrogenase and malic enzyme in the seed at the time of rapid seed filling could be effectively linked to the deposition of protein reserves.     

Analysis of carbohydrate metabolism enzymes and cellular contents of sugars and proteins during spruce somatic embryogenesis suggests a regulatory role of exogenous sucrose in embryo development.

Carbohydrate metabolism was investigated during spruce somatic embryogenesis. During the period of maintenance corresponding to the active phase of embryogenic tissue growth, activities of soluble acid invertase and alkaline invertase increased together with cellular glucose and fructose levels. During the same time, sucrose phosphate synthase (SPS) activity increased while sucrose synthase (SuSy) activity stayed constant together with the cellular sucrose level. Therefore, during maintenance, invertases were thought to generate the hexoses necessary for embryogenic tissue growth while SuSy and SPS would allow cellular sucrose to be kept at a constant level. During maturation on sucrose-containing medium, SuSy and SPS activities stayed constant whereas invertase activities were high during the early stage of maturation before declining markedly from the second to the fifth week. This decrease of invertase activities resulted in a decreased hexose:sucrose ratio accompanied by starch and protein deposition. Additionally, carbohydrate metabolism was strongly modified when sucrose in the maturation medium was replaced by equimolar concentrations of glucose and fructose. Essentially, during the first 2 weeks, invertase activities were low in tissues growing on hexose-containing medium while cellular glucose and fructose levels increased. During the same period, SuSy activity increased while the SPS activity stayed constant together with the cellular sucrose level. This metabolism reorganization on hexose-containing medium affected cellular protein and starch levels resulting in a decrease of embryo number and quality. These results provide new knowledge on carbohydrate metabolism during spruce somatic embryogenesis and suggest a regulatory role of exogenous sucrose in embryo development.