New 4-O-substituted xylosyl units in the xyloglucan from leaves of Hymenaea courbaril

A homogeneous fucogalactoxyloglucan, isolated from the leaves of Hymenaea courbaril, was analysed by methylation-GC–MS. These procedures involved derived partially O-methylated alditol acetates and acetylated aldononitriles, which demonstrated the presence of both 2-O- and 4-O-substituted Xylp units in the side-chains. The presence of the unusual, latter structure was confirmed by 2D NMR spectroscopy with a correlated HMQC C-4/H-4 signal at δ 77.8/3.73. A similar 4-O-substituted xylosyl structure was present in a decasaccharide Glc₄Xyl₃Gal₂Fuc obtained via endo-glucanase treatment of the polysaccharide, which gave rise to a molecular ion with m/z 1555 (ESI-MS, Na⁺ form).     

The role of the storage carbon of cotyledons in the establishment of seedlings of Hymenaea courbaril under different light conditions

BACKGROUND AND AIMS: Hymenaea courbaril (Leguminosae-Caesalpinioideae) is a tree species with wide distribution through all of the Neotropics. It has large seeds (approx. 5 g) with non-photosynthetic storage cotyledons rich (40 %) in a cell wall polysaccharide (xyloglucan) as a carbon reserve. Because it is found in the understorey of tropical forests, it has been considered as a shade-tolerant, late-secondary species. However, the physiological mechanisms involved in seedling establishment, especially regarding the interplay between storage and light intensity, are not understood. In this work, the ecophysiological role of this carbon cotyledon reserve (xyloglucan) is characterized, emphasizing its effects on seedling growth and development during the transition from heterotrophy to autotrophy under different light conditions. METHODS: Seedlings of H. courbaril were grown in environments with different light intensities, and with or without cotyledons detached before xyloglucan mobilization. Development, growth, photosynthesis and carbon partitioning (dry mass and [14C]sucrose) were analysed in each treatment. KEY RESULTS: The detachment of cotyledons was not important for seedling survival, but resulted in a strong restriction (50 % less) of shoot growth, which was the main sink for the cotyledon carbon reserves. Carbon restriction promoted an early maturation of the photosynthetic apparatus without changes in the net CO2 fixation per unit area. The reduced surface area of the first leaves in seedlings without cotyledons was evidence of limited growth and development of seedlings in low light conditions (22 micromol m(-2) s(-1) photon flux). CONCLUSIONS: There is an increase in the importance of storage xyloglucan in cotyledons for H. courbaril seedling development as light intensity decreases, confirming that this polymer plays a key role in the adaptation of this species to establish successfully in the shadowed understorey of the forest.     

Xyloglucan from the leaves of Hymenaea courbaril

A fucosylated xyloglucan was isolated from the leaves of Hymenaea courbaril by alkaline extraction, followed by ethanol precipitation and ion-exchange chromatography. The isolated polysaccharide showed Glc:Xyl:Gal:Fuc in molar ratio of 8:5:2.5:1 and (D)(25) +40.5 degrees. Composition and linkage analyses, supported by NMR spectroscopic measurements, showed that the polysaccharide has a glucan backbone which is highly substituted at O-6 with D-xylopyranose residues, about a half of which are substituted at O-2 by D-galactopyranosyl units. Some of the galactose residues are further substituted by L-fucopyranose at O-2. The M(r), as determined by HPSEC, was 49,500.     

Purification of a beta-galactosidase from cotyledons of Hymenaea courbaril L. (Leguminosae). Enzyme properties and biological function.

Beta-galactosidases are enzymes that can be found in most living beings and in the plant kingdom its activity and genes have been detected in several tissues such as ripening fruits, developing leaves and flowers and storage tissues such as cotyledons. In plants, their activities are usually associated with the secondary metabolism or with oligosaccharide or polysaccharide degradation. Polysaccharide specific beta-galactosidases include beta-galactanases, which attack pectic polymers and beta-galactosidases that attack xyloglucans (XG). In the present work we purified an XG-specific beta-galactosidase (named hcbetagal) from cotyledons of developing seedlings of Hymenaea courbaril, a legume tree from the Neotropical region of the world. The enzyme has a molecular weight of 52-62 kDa and was shown to attack specifically xyloglucan oligosaccharides (XGOs) but not the polymer. It has a pH optimum between 3 and 4 and at this pH range the enzyme increases activity linearly up to 50 degrees C. Kinetic studies showed that hcbetagal is inhibited competitively by free galactose (K(i) = 3.7). The biochemical properties of hcbetagal as a whole suggest that it is involved in storage xyloglucan mobilisation during seedling development. Its high specificity towards XGOs, the low pH optimum and the fact that it is inhibited by its product (galactose) suggest that hcbetagal might be one of the biochemical control points in xyloglucan catabolism in vivo. A possible relationship with functional stability of the wall during cell death as cotyledons undergo senescence is discussed.     

Ipomopsin and hymenain,two biscoumarins from seeds of Hymenaea courbaril

A new biscoumarin (7-hydroxy-6,6′-dimethoxy-3,7′-dicoumarinyl ether), named hymenain (1) and the known biscoumarin ipomopsin (2) were isolated from the germinated seeds of Hymenaea courbaril var. stilbocarpa. Their structures were elucidated by spectroscopic methods. Scopoletin was also detected in the extracts by TLC and GC–MS analyses. Hymenain and ipomopsin showed direct scavenging effect on a stable free radical, 2,2-diphenyl-1-picryl-hydrazyl (DPPH) with the EC₅₀ values of 100 and 300 μM, respectively.     

Isolation and characterization of microsatellite loci for Hymenaea courbaril and transferability to Hymenaea stigonocarpa, two tropical timber species

Hymenaea courbaril is a tropical timber species, intensely exploited and found in the Amazon, Atlantic Forest and Brazilian Cerrado biome. Nine highly polymorphic microsatellite loci were developed from a genomic library enriched for AG/TC repeats. In a total of 41 individuals, from two natural populations, seven to 13 alleles per locus were detected and expected heterozygosity ranged from 0.75 to 0.90. Seven loci were effectively transferred to Hymenaea stigonocarpa. High levels of polymorphism make the present primers useful for population genetic studies and are a powerful tool to investigate mating system, gene flow and spatial genetic structure.     

Clerodane-type diterpenes from the seed pods of Hymenaea courbaril var. stilbocarpa.

Three known and two new diterpenes were isolated from the ethyl acetate extract of Hymenaea courbaril var. stilbocarpa seed pods. One of the compounds was elucidated as (5R*,8S*,9S*,10R*)-cleroda-3,13E-dien-15-oic acid and the other was elucidated, after treatment with diazomethane, as methyl (5S*,8S*,9S*,10R*)-cleroda-3,13E-dien-15-oate. The known diterpenes were identified as (-)-ozic acid, (-)-isoozic acid and (-)-kovalenic acid which were characterized as their methyl ester derivatives.     

Histochemical studies on mobilization of storage components in cotyledons of germinatingPhaseolus mungo seeds

Phaseolus mungo seeds were allowed to germinate in the dark at 27 C, and time-sequence changes of mobilization of protein and starch reserves in cotyledons were observed by histochemical techniques. The distributions of amylase and protease activities in cotyledon sections were also examined during germination by use of the starch-polyacrylamide gel film and India ink-gelatin film methods, respectively. Amylolytic and proteolytic processes occurred more or less simultaneously during the germination. At the day 2 stage, low levels of hydrolytic enzyme activities were observed throughout cotyledon sections. At day 4, both amylase and protease activities appeared to increase in tissue areas farthest from vascular bundles, and the mobilization of starch and protein reserves also proceeded in these areas. At day 6, the reserves were found to remain only in the cells around vascular bundles. When cotyledons were detached from axis organs, allowed to imbibe water and incubated for 4 days at 27 C, the breakdown of reserves was markedly retarded and the patterns of enzyme localization in cotyledon sections appeared not as conspicuous as those in the sections from intact cotyledons. These histochemical results are discussed with reference to the previous results ofin vitro experiments.     

Auxin-dependent breakdown of xyloglucan in cotyledons of germinating nasturtium seeds

Rapid mobilisation of storage products, including xyloglucan, in cotyledons of germinating nasturtium (Tropaeolum majus L.) normally starts about 7–8 d after imbibition and growth of the seedling at 20–25° C. Levels of activity of endo-1,4--glucanase (EC 3.2.1.4) in cotyledons, as assayed viscometrically with xyloglucan as substrate, varied in parallel with the rate of breakdown of xyloglucan. When cotyledons were excised from the seedling axis and incubated on moist filter paper at any point before 7 d, the catabolic reactions which normally occurred in the intact seedling were suspended. If, however, cotyledons excised at 8 d were incubated in 10^–6 M 2,4-dichlorophenoxyacetic acid, a rise in endo-1,4--glucanase (xyloglucanase) activity was observed and a sharp decrease in fresh and dry weight as well as xyloglucan levels ensued at rates comparable to those observed in cotyledons attached to the seedling. Neither gibberellin nor kinetin treatments promoted xyloglucan breakdown or enhanced xyloglucanase activity. Addition of auxin to excised cotyledons before 7 d did not evoke premature breakdown, indicating that the tissue became receptive to auxin only at this time. The triggering process took place in darkness and was unaffected by various light-dark cycles. It is concluded that the sudden degradation of xyloglucan which occurs in nasturtium seeds about a week after germination begins is the result of enhanced activity of a depolymerizing xyloglucanase, this activity being evoked by auxin originating in the emerging seedling axis.Abbreviations 2,4-D 2,4-dichlorophenoxyacetic acid - 2,3-D 2,3-dichlorophenoxyacetic acid - GA₃ gibberellic acid - kDa kilodalton The authors are pleased to acknowledge the technical assistance of Alexander Marcus and valuable discussions with Dr. Vladimir Farkas. This study was supported by a scholarship to A.H. from the Deutsche Forschungsgemeinschaft (FRG) and a grant to G.M. from the Natural Sciences and Engineering Research Council of Canada.     

Phylogeographical structure of the neotropical forest tree Hymenaea courbaril (Leguminosae: Caesalpinioideae) and its relationship with the Vicariant Hymenaea stigonocarpa from Cerrado

The phylogeography of Hymenaea courbaril var. stilbocarpa from Atlantic Forest and riverine forests of the Cerrado biome in central and southeastern Brazil was investigated. The data were compared with those of its congeneric Hymenaea stigonocarpa, a typical tree from savanna. In the Cerrado, H. courbaril var. stilbocarpa is found in sites contiguous with those of H. stigonocarpa, and they share common life-history attributes. The psbC/trnS3 region of the chloroplast DNA was sequenced in 149 individuals of H. courbaril var. stilbocarpa. High genetic variation was found in this species, with the identification of 18 haplotypes, similarly to what was found in H. stigonocarpa with 23 haplotypes in the same geographic region. Populations of H. courbaril var. stilbocarpa could be structured in 3 phylogeographic groups. Spatial analysis of molecular variation indicated that 46.4% of the genetic variation was due to differences among these groups. Three haplotypes were shared by H. courbaril var. stilbocarpa and H. stigonocarpa, and only 10.5% of the total genetic variation could be attributed to between-species difference. We surmise that during the glacial times, H. courbaril var. stilbocarpa populations must have gone extinct in most parts of the southern of its present-day occurrence area. After climate amelioration, these areas were probably recolonized from northern and eastern. The relatively similar phylogeographic structure of vicariant Hymenaea species suggests that they were subjected to the same impacts during the Quaternary climatic fluctuations. The sharing of haplotypes and the genetic similarity between the 2 Hymenaea species suggest the existence of ancestral polymorphism and/or hybridization.     

Mendelian inheritance, linkage and genotypic disequilibrium in microsatellite loci isolated from Hymenaea courbaril (Leguminosae)

The Neotropical tree Hymenaea courbaril, locally known as Jatobá, is a valuable source of lumber and also produces comestible and medicinal fruit. We characterized Mendelian inheritance, linkage and genotypic disequilibrium at nine microsatellite loci isolated from H. courbaril, in order to determine if they would provide accurate estimates of population genetic parameters of this important Amazon species. The study was made on 250 open-pollinated offspring originated from 14 seed trees. Only one of nine loci presented significant deviation from the expected Mendelian segregation (1:1). Genotypic disequilibrium between pairwise loci was investigated based on samples from 55 adult and 56 juvenile trees. No genetic linkage between any paired loci was observed. After Bonferroni's corrections for multiple tests, we found no evidence of genotypic disequilibrium between pairs of loci. We conclude that this set of loci can be used for genetic diversity/ structure, mating system, gene flow, and parentage analyses in H. courbaril populations.     

Protein storage vacuole acidification as a control of storage protein mobilization in soybeans

Soybean protease C1 (EC 3.4.21.25), the subtilisin-like serine protease that initiates the proteolysis of seed storage proteins in germinating soybean [Glycine max (L.) Merrill], was localized to the protein storage vacuoles of parenchyma cells in the cotyledons by immunoelectron microscopy. This was demonstrated not only in germination and early seedling growth as expected, but also in two stages of protein storage vacuole development during seed maturation. Thus, the plant places the proteolytic enzyme in the same compartment as the storage proteins, but is still able to accumulate those protein reserves. Since soybean protease C1 activity requires acidic conditions for activity, the hypothesis that the pH condition in the protein storage vacuole would support protease C1 activity in germination, but not in seed maturation, was tested. As hypothesized, acridine orange accumulation in the protein storage vacuole of storage parenchyma cells was detected by fluorescence confocal microscopy in seedlings before the onset of mobilization of reserve proteins as noted by SDS-PAGE. Accumulation of the dye was reversed by inclusion of the weak base methylamine to dissipate the pH gradient across the vacuolar membrane. Also as hypothesized, acridine orange did not accumulate in the protein storage vacuole of those parenchyma cells during seed maturation. These results were obtained using cells separated by pectolyase treatment and also using cotyledon slices.     

Dual lipolytic control of body fat storage and mobilization in Drosophila

Energy homeostasis is a fundamental property of animal life, providing a genetically fixed balance between fat storage and mobilization. The importance of body fat regulation is emphasized by dysfunctions resulting in obesity and lipodystrophy in humans. Packaging of storage fat in intracellular lipid droplets, and the various molecules and mechanisms guiding storage-fat mobilization, are conserved between mammals and insects. We generated a Drosophila mutant lacking the receptor (AKHR) of the adipokinetic hormone signaling pathway, an insect lipolytic pathway related to ß-adrenergic signaling in mammals. Combined genetic, physiological, and biochemical analyses provide in vivo evidence that AKHR is as important for chronic accumulation and acute mobilization of storage fat as is the Brummer lipase, the homolog of mammalian adipose triglyceride lipase (ATGL). Simultaneous loss of Brummer and AKHR causes extreme obesity and blocks acute storage-fat mobilization in flies. Our data demonstrate that storage-fat mobilization in the fly is coordinated by two lipocatabolic systems, which are essential to adjust normal body fat content and ensure lifelong fat-storage homeostasis.     

The potential for predation induced somatic embryogenesis in storage cotyledons

Using seven tropical rainforest species of north Queensland, Australia, we simulated partial predation and compared the development of intact embryos and embryos from which various proportions had been removed, including in some cases the original root–shoot axis. Embryos of all species contained storage reserve cotyledons and germinate in a hypogeal manner. Species mean embryo masses ranged from 0.4–48.1 g. Partial embryo predation treatments were: ½ embryo treatment; embryos separated into component cotyledons, and ¼ embryo treatment; cotyledons separated as above and subsequently cut in half. Germination was scored as production of roots and shoots, or roots or shoots only. Embryos from all species produced seedlings in all treatments, even after the removal of up to 75 percent of the cotyledonary reserve. Moreover, the proportion germinating were not different between intact embryos and i) separated cotyledons, ii) cotyledon halves that maintained or were adjacent to the embryonic axis (except for the largest seeded species), and iii) cotyledon halves that did not include the root–shoot axis (four species). Thus, production of roots and shoots, or roots or shoots only was largely independent of the presence of the embryonic root–shoot axis – implying that somatic cells in storage cotyledons are capable of differentiating into the full range of cell types typical of shoots and roots in the absence of the root–shoot axis. The generality of this response across all seven species suggests somatic embryogenesis in storage cotyledons may be a more widespread phenomenon in tropical floras than currently considered.     

Long-pollen Movement and Deviation of Random Mating in a Low-density Continuous Population of a Tropical Tree Hymenaea courbaril in the Brazilian Amazon

Mating system and pollen flow are two key elements to understand the genetic structure of tree species. Mating and pollen-dispersal patterns of a low-density population of bat pollinated Hymanea courbaril were examined before logging in a 546-ha plot in the Brazilian Amazon. The multilocus genotypes of nine microsatellite loci were determined for 130 adult-trees and 367 seeds collected from 20 seed-trees. Mating system analysis, using mixed-mating model and paternity analysis showed that the studied population is perfectly outcrossed ( t_m = 1.002), and probably self-incompatible. However, significant deviations from random mating were detected for mating among relatives ( t_m − t_s = 0.096, P < 0.05) and correlated matings ( r_p = 0.289, P < 0.05), indicating inbreeding in the population and that part of offspring are full-sibs (28.9%). Inbreeding was reflected in the positive and significant fixation index observed in adult trees ( F = 0.137, P < 0.05), although no significant inbreeding was detected in offspring ( F = 0.074, P > 0.05). The effective number of pollen donors mating with each seed-tree was determined to be low ( N_ep ≈ 4). The average of pollen flow distance was measured inside of the plot by both paternity (827 ± 429 m) and TwoGener analysis (115–363 m). However, this underestimated pollen dispersal distance, since the detected rate of pollen immigration inside of the plot was high (55%). The observed long-pollen dispersal distance is probably related to pollination by bats and the low density of reproductive trees in the site.     

In vivo evaluation of the toxic activity and genotoxicity of the Hymenaea courbaril L.’s resin in Drosophila melanogaster

Due to the negative consequences carried by the usage of synthetic insecticides, a global interest into finding substitutes for these chemical compounds through natural products has arisen. When yielded to external attacks, plants generally produce metabolites to defend themselves. The physicochemical characteristics of this kind of compounds have allowed their usage as potential bioinsecticides. The Hymenaea courbaril L. (algarrobo) has proven to be a plant rich in metabolites with outstanding biological activity, in such a way that some of its extracts have been tested as insecticides. The goal of this study was to know the phytochemical composition of Hymenaea courbaril L.’s resin and perform evaluations in vivo of its toxic and genotoxic effects in the biological model Drosophila melanogaster. For this, two resin extracts were prepared and both a phytochemical analysis were carried out on them, having found in the ethanolic total extract the presence of terpenes, flavonoids and coumarins, while in the partial ethanolic extract only presence of terpenes and flavonoids was found. Drosophila larvae were submitted to different concentrations of the extracts and both the survival and the sexual ratio were evaluated, finding that larvae are more sensitive to the partial ethanolic extract. Subsequently, the induction of somatic mutation and mitotic recombination (SMART) was evaluated in the flies’ eyes. The most significant affectations at a genotoxic level were found when larvae were tested with the partial extract, indicating that possibly the coumarins absence makes this insect more susceptible to damages at a genetic material level.     

A storage role for albumins in pea cotyledons

Abstract It is widely held that the albumins of pea seeds are mainly enzyme proteins. In the present study of Pisum sativum cv. Greenfeast, certain major polypeptides confined to the albumin fraction from the cotyledons were shown to be degraded in vivo following germination, thus functioning as a reserve of amino nitrogen and carbon skeletons. A general definition of seed storage proteins is proposed, to encompass any protein present in major quantity in the seed which is degraded following imbibition, and for which no other function may be demonstrated.     

Identification of nucleases related to nutrient mobilization in senescing cotyledons from French bean

The knowledge about the physiological function of plant nucleases is scarce besides that they have been involved in nucleic acid degradation related with programmed cell death processes. Cotyledons provide a suitable system to investigate this process and the changes associated to nutrient mobilization. Nuclease activities have been determined in French bean seedlings. The total nuclease activity in French bean cotyledons is lower than in embryonic axes; however, several nucleases were detected by in-gel nuclease activity assays with extracts from cotyledons of French bean and ssDNA as substrate. The nuclease activities induced during cotyledon senescence showed higher activity at neutral than at acidic pH. Five different nuclease genes belonging to S1/P1 family have been identified in French bean genome database named PVN1 to PVN5. Their relative expression in cotyledons has been determined from the start of imbibition to senescence, and three genes from this family showed expression in cotyledons. PVN1 was expressed during early stages of seedlings development, whereas PVN4 and PVN5 were expressed during cotyledons senescence. The removal of epicotyl in French bean seedlings resulted in a decrease in the activity and in the expression of the genes associated with the cotyledons senescence process, i.e. PVN4 and PVN5. At the same time, the mobilization of reserves in those cotyledons was slowed down. In the same way, the deficit in phosphate and nitrate during seedlings development led to an acceleration of induction of these genes at the same time that reserves were utilized early on the time. Therefore, the induction of PVN4 and PVN5, the two S1 nuclease genes involved in the process of cotyledon senescence, is related to nutrient mobilization, supporting a possible role for nucleic acids in nutrient recycling during cotyledon senescence.     

Gluconeogenesis from storage wax in the cotyledons of jojoba seedlings

The cotyledons of jojoba (Simmondsia chinensis) seeds contained 50 to 60% of their weight as intracellular wax esters. During germination there was a gradual decrease in the wax content with a concomitant rise in soluble carbohydrates, suggesting that the wax played the role of a food reserve. Thin layer chromatography revealed that both the fatty alcohol and fatty acid were metabolized. The disappearance of wax was matched with an increase of catalase, a marker enzyme of the gluconeogenic process in other fatty seedlings. Subcellular organelles were isolated by sucrose gradient centrifugation from the cotyledons at the peak stage of germination. The enzymes of the β oxidation of fatty acid and of the glyoxylate cycle were localized in the glyoxysomes but not in the mitochondria. The glyoxysomes had specific activities of individual enzymes similar to those of the castor bean glyoxysomes. An active alkaline lipase was detected in the wax bodies at the peak stage of germination but not in the ungerminated seeds. No lipase was detected in glyoxysomes or mitochondria. After the wax in the wax bodies had been extracted with diethyl ether, the organelle membrane was isolated and it still retained the alkaline lipase. The gluconeogenesis from wax in the jojoba seedling appears to be similar, but with modification, to that from triglyceride in other fatty seedlings.