Galactosidase of plant fibers with gelatinous cell wall: Identification and localization

Using a comprehensive approach, we have identified a tissue-specific β-galactosidase from flax (Linum usitatissimum L.) phloem fibers forming a gelatinous cell wall. It was found that when fibers started to develop gelatinous cell wall, β-galactosidase gene expression was enhanced.. Using the antibodies against β-galactosidase, we showed that the enzyme was located in flax phloem fibers where it was detected together with tissue-specific galactan in secreted Golgi vesicles and in gelatinous secondary cell wall. Similar β-galactosidase present in gelatinous cell wall of fibers was found in plants belonging to various taxa and produced by different meristems; these data presume the identical mechanisms of gelatinous cell wall formation and an important role of β-galactosidase. The role of this enzyme in developing the supramolecular structure of gelatinous cell wall is discussed.     

Specific type of secondary cell wall formed by plant fibers

The review sums data indicating that, in many plant fibers, the secondary cell wall contains so-called gelatinous layers of peculiar structure along with those of common (xylan) structure. Sometimes these gelatinous layers comprise the main bulk of the cell wall. Key characteristics of gelatinous cell wall are presented and compared with those of classic xylan-type cell wall. The process of gelatinous cell wall formation is considered in detail for flax phloem fibers; several characteristic features of this process were revealed: intense rearrangement of already deposited cell-wall layers, unusual dynamics of Golgi vesicles, the occurrence of the stage-specific polysaccharide with specific properties, high activity of β-galactosidase, and the presence of substantial amount of free galactose. Similarity and differences in the gelatinous cell wall formation in the fibers of various plant species are discussed.     

Immunolocalization of hemicelluloses in Arabidopsis thaliana stem. Part I: temporal and spatial distribution of xylans

We investigated the microdistribution of xylans in different cell types of Arabidopsis stem using immunolocalization methods with LM10 and LM11 antibodies. Xylan labeling in xylary fibers (fibers) was initially detected at the cell corner of the S(1) layer and increased gradually during fiber maturation, showing correlation between xylan labeling and general secondary cell wall formation processes in fibers. Metaxylem vessels (vessels) showed earlier development of secondary cell walls than fibers, but revealed almost identical labeling patterns to fibers during maturation. No difference in labeling patterns and intensity was detected in the cell wall of fibers, vessels and protoxylem vessels (proto-vessels) between LM10 and LM11, indicating that vascular bundle cells may be chemically composed of a highly homogeneous xylan type. Interestingly, interfascicular fibers (If-fibers) showed different labeling patterns between the two antibodies and also between different developmental stages. LM10 showed no labeling in primary cell walls and intercellular layers of If-fibers at the S(1) formation stage, but some labeling was detected in middle lamella cell corner regions at the S(2) formation stage. In contrast, LM11 revealed uniform labeling across the If-fiber cell wall during all developmental stages. These results suggest that If-fibers have different xylan deposition processes and patterns from vascular bundle cells. The presence of xylan was also confirmed in parenchyma cells following pectinase treatment. Together our results indicate that there are temporal and spatial differences in xylan labeling between cell types in Arabidopsis stem. Differences in xylan labeling between Arabidopsis stem and poplar are also discussed.     

β-Galactosidases of Lilium pollen

Lily (Lilium auratum) pollen contains very high levels of β-galactosidase. There are three forms: β-galactosidase I and II differ in M_r, while β-galactosidase III is firmly bound in the pollen wall. The two cytoplasmic forms were separated and partially purified using a combination of chromatography on DEAE-cellulose, Sephadex G-200 and Sepharose 6B. Forms I and II appear to be glycoprotein in nature as shown by binding to Con A-Sepharose. The three enzymes were optimally active near pH 4, and all were inhibited by galactose and galactonolactone. The wall-bound enzyme, β-galactosidase III effectively hydrolysed nitrophenyl β-galactosidase but not lactose, and could not be released from the wall polysaccharide matrix by high salt concentrations or detergents. The total β-galactosidase activity of lily pollen remained constant during in vitro germination. A possible role for this enzyme may be in degradation of stylar arabinogalactans providing a carbon source for pollen tube nutrition.     

β-Galactosidase activity in ripening apples

β-Galactosidase activity has been identified in soluble and cell wall preparations from apple cortex tissue. The enzyme degrades pectin galactan and has a pH optimum of 4·0 with p-nitrophenyl-β, d-galactopyranoside as substrate. Soluble polygalacturonide increased as the applies softened with ripening and these changes were preceded by loss of galactose residues from the cell wall and an increase in β-galactosidase activity.     

Glucan synthesis by intact cotton fibres fed with different precursors at the stages of primary and secondary wall formation

Seed clusters of individual locules from fruit capsules of Gossypium arboreum L. with adhering intact fibres were fed with radioactive uridinediphosphoglucose (UDPG), guanosinediphosphoglucose (GDPG), glucose and sucrose. The incorporation into high molecular weight glucans of the fibres was studied. For primary wall fibres, UDPG at 1 mM was by far the best precursor, whereas sucrose was the best precursor for secondary wall fibres. No competition was observed between the incorporation of glucose from UDPG and from sucrose when the two were fed simultaneously to secondary wall fibres, indicating that their metabolic pathways are well separated when they are fed from the apoplast. Inhibitors of respiratory ATP-formation strongly inhibited incorporation of sucrose but not that of UDPG. Sucrose incorporation was studied at five different stages of development of the cotton fibres. At the stage of most intense secondary wall formation the incorporation rate was about 300 times that during primary wall formation (24 days post anthesis (DPA)). Incorporation from 1 mM UDPG or GDPG by secondary wall fibres (35 DPA) was less than twice that of primary wall fibres (22 DPA), indicating that the two sugar nucleotides are not readily used as precursors for secondary wall cellulose when they are fed to the exterior of intact cells. The high molecular weight non-cellulosic glucans formed from UDPG and sucrose at 5 and 1,000 M were solubilized in strongly alkaline solutions or dimethyl-sulfoxide (DMSO) and were partially characterized by degradation with an exo--1,3-glucanase. After feeding for one hour, at most 1/3 of the radioactivity in high molecular weight material was found in cellulose and at least 2/3 in -1,3-glucan. The proportions varied little for fibres in the age range of 30 to 48 DPA when sucrose was the precursor although the total incorporation varied by a factor of about four. The fact that at all stages of secondary wall formation -1,3-glucan is synthesized at a very high rate, but that the total amount in the cell wall does not exceed 2% in the later stages of wall formation, can be interpreted in terms of a high turnover of this polysaccharide if it is assumed that wound effects are negligible in the system under study.Abbreviations UDPG uridinediphosphoglucose - GDPG guanosinediphosphoglucose - HEPES N-2-hydroxyethylpiperazine-N-2-ethansulphonic acid - DMSO dimethyl-sulfoxide - DNP 2,4-dinitrophenol - DPA days post anthesis     

Immunolocalization of hemicelluloses in Arabidopsis thaliana stem. Part II: Mannan deposition is regulated by phase of development and its patterns of temporal and spatial distribution differ between cell types

Microdistribution of mannans in Arabidopsis stem was examined using immunolocalization with mannan-specific monoclonal antibodies (LM21 and LM22). Mannan labeling in secondary xylem cells (except for protoxylem vessels) was initially detected in the cell wall during S₂ formation and increased gradually during development. Labeling in metaxylem vessels (vessels) was detected earlier than that in xylary fibers (fibers), but was much weaker than fibers. The S₁ layer of vessels and fibers showed much less labeling than the S₂ layer. Some strong labeling was also detected in pit membranes of vessel pits. Interfascicular fibers (If-fibers) showed more heterogeneous labeling patterns than fibers by LM21. Unlike fibers, If-fibers also revealed some strong labeling in the cell corner of the S₁ layer, indicating different mannan labeling patterns between If-fibers and fibers. Interestingly, protoxylem vessels (proto-vessels) showed strong labeling at the early stage of secondary xylem formation with more intense labeling in the outer- than inner cell wall even though fibers and vessels showed no or very low labeling at this stage. Labeling intensity of proto-vessels was also much stronger than vessels and stronger or slightly weaker than fibers by LM21 and LM22, respectively. Using pectinase and mild alkali treatment, the presence of mannans in parenchymatous cells was also confirmed. Together our observations indicate that there are temporal and spatial variations in mannan labeling between cell types in the secondary xylem of Arabidopsis stems. Some similar features of mannan labeling between Arabidopsis and poplar are also discussed.     

Action of β-galactosidase in medium on the Lemna minor (L.) callus polysaccharides

The callus culture of duckweed cultivated on medium containing different concentrations of β-galactosidase was shown to produce the following polysaccharides: pectin lemnan LMC, intracellular AG1, and extracellular AG2 arabinogalactans. The samples of lemnan with 46% galactose residue reduction and 9-46% increased galacturonic acid residue content were obtained at β-galactosidase concentrations of 10⁻³-10⁻¹ mg/mL. The most substantial alterations in the sugar composition of pectin were found to occur in the fraction with a molecular mass of 100-300 kDa. Low concentrations of enzyme failed to influence the sugar composition of intracellular arabinogalactan, whereas high concentrations were shown to decrease the amount of arabinose residues in AG1 and to cause galactan formation. Extracellular galactan was found to be produced on the medium with 10⁻¹ and 1 mg/mL β-galactosidase whereas extracellular arabinogalactan AG2 was shown to be biosynthesized without β-galactosidase or at a β-galactosidase concentration of 10⁻³ mg/mL. Alterations in the sugar composition of polysaccharides were shown to be connected with the increasing activity of α-l-arabinofuranosidase and β-galactosidase, and with the decreasing activity of intracellular polygalacturonase.     

The Relationship of Some Glycosidases to the Endogenous and IAA-induced Growth of Light-grown Cucumber Hypocotyls

Some glycosidases in light-grown cucumber (Cucumis sativus L. cv. Aonaga-jibae) hypocotyl sections were examined with respect to their localization and relation to endogenous and IAA-induced growth. Frozen-thawed sections were used directly for measurement of enzyme activities, and β-glucosidase, α- and β-galactosidases and β-xylosidase were assayed by using p- or o-nitro-phenylglycopyranosides as substrates. The order of the activity of these enzymes were β -glucosidase > β -galactosidase =α-galactosidase > β-xylosidase. No activity of α-glucosidase was detected. High glycosidase activities were found in the youngest region of the hypocotyl, where the endogenous growth rate was highest. However, there was no significant difference in the activities of this region between seedlings at different growth stages. Among the enzymes tested, β -glucosidase showed a high correlation with the endogenous growth rate. β-glucosidase was found to be mostly associated with the cell wall fraction, while β-galactosidase was rather found in the soluble fraction of the cell. Separation of the epidermis from the section showed that a very high activity of β-glucosidase was associated with the epidermis. In both whole sections and isolated cell wall fractions, IAA was shown to have no effect on the activities of β-glucosidase and β-galactosidase.     

Nitrogen-deficiency-induced loss in photosynthesis and modulation of β-galactosidase activity during senescence of <Emphasis Type="Italic">Arabidopsis</Emphasis> leaves

Senescence-induced loss in the content of chlorophyll and the rate of oxygen evolution is remarkably enhanced when the leaves of Arabidopsis thaliana experience nitrogen-deficiency stress. On the other hand, the decline in the level of total soluble sugar during senescence is very slow and nitrogen deficiency does not exhibit any further change. The relative stability in the level of the sugar in the background of severe decline of photosynthesis may suggest the contribution of sugars from other sources to sustain its homeostasis to execute and complete energy-dependent senescence process and stress response. The possible participation of cell wall polysaccharides contributing to sugar homeostasis is predicted. Senescence-induced increase in the activity of β-galactosidase (EC 3.2.1.23) and its further enhancement in senescing leaves experiencing nitrogen stress support the proposition of participation of the enzyme for breakdown of the wall polysaccharides to sugars. The loss of photosynthesis as a possible signal for enhancement in the activity of β-galactosidase has been further examined in the excised leaves incubated in Okada and Shimura (OS) nutrient medium with and without nitrogen. Nitrogen limitation experienced by excised leaves causes rapid loss in photosynthesis with concomitant increase in the activity of the enzyme extracted both from soluble and cell wall fractions. The differential activity of the enzyme from soluble and cell wall fractions during development-dependent leaf senescence and premature senescence in excised leaves induced by nitrogen deficiency appears to be complex and needs to be resolved in the future.     

Changes in biochemical composition of the cell wall of the cotton fiber during development

The composition of the cell wall of the cotton fiber (Gossypium hirsutum L. Acala SJ-1) has been studied from the early stages of elongation (5 days postanthesis) through the period of secondary wall formation, using cell walls derived both from fibers developing on the plant and from fibers obtained from excised, cultured ovules. The cell wall of the elongating cotton fiber was shown to be a dynamic structure. Expressed as a weight per cent of the total cell wall, cellulose, neutral sugars (rhamnose, fucose, arabinose, mannose, galactose, and noncellulosic glucose), uronic acids, and total protein undergo marked changes in content during the elongation period. As a way of analyzing absolute changes in the walls with time, data have also been expressed as grams component per millimeter of fiber length. Expressed in this way for plant-grown fibers, the data show that the thickness of the cell wall is relatively constant until about 12 days postanthesis; after this time it markedly increases until secondary wall cellulose deposition is completed. Between 12 and 16 days postanthesis increases in all components contribute to total wall increase per millimeter fiber length. The deposition of secondary wall cellulose begins at about 16 days postanthesis (at least 5 days prior to the cessation of elongation) and continues until about 32 days postanthesis. At the time of the onset of secondary wall cellulose deposition, a sharp decline in protein and uronic acid content occurs. The content of some of the individual neutral sugars changes during development, the most prominent change being a large increase in noncellulosic glucose which occurs just prior to the onset of secondary wall cellulose deposition. Methylation analyses indicate that this glucose, at least in part, is 3-linked. In contrast to the neutral sugars, no significant changes in cell wall amino acid composition are observed during fiber development.     

Biochemical changes associated with the ripening of hot pepper fruit

Hot pepper ( Capsicum annuum L. cv. Chooraehong) fruit underwent a respiratory climacteric during ripening. However, the rate of ethylene production was low, reaching a maximum of approximately 0.7 μl kg⁻¹ h⁻¹ at the climacteric peak when the surface color was 30 to 40% red. Ripening was accompanied by a loss of galactose and arabinose residues from the cell wall. The content of uronic acid and cellulose in the wall changed only slightly during ripening. The average molecular weight of a cell wall hemicellulosic fraction shifted progressively toward a lower molecular weight during ripening. Total β-galactosidase (EC 3.2.1.23) activity increased 50-fold from the immature green to the red ripe stage. No polygalacturonase (EC 3.2.1.15) activity was detected at any stage of ripeness. Thus, the loss of galactose and arabinose residues from the cell wall, as well as the observed modification of hemicelluloses during ripening, seem to be unrelated to active polygalacturonase. Soluble polyuronide content remained relatively constant at approximately 60 μg (g fresh weight)⁻¹ as fruit ripended.     

Permeabilized probiotic Lactobacillus plantarum as a source of β-galactosidase for the synthesis of prebiotic galactooligosaccharides

Permeabilized probiotic Lactobacillus plantarum was used as a source of β-galactosidase for the synthesis of galactooligosaccharides (GOS) from lactose. β-galactosidase activity was highest when galactose (1,724 Miller Units) was used as a carbon source compared to lactose, sucrose or glucose at 37 °C, 18 h. Permeabilized cells had the highest transgalactosylation activity resulting in 34 % (w/w) GOS synthesis from 40 % (w/v) lactose at 50 °C over 12 h. HPLC revealed that the GOS were composed of 13 % disaccharides (non-lactose), 17 % trisaccharides and 4 % tetrasaccharides that were further confirmed by ESI–MS.     

Activity of cell wall-associated enzymes in ripening olive fruit

Enzymatically active cell wall isolaled from olive (Olea europaea) fruit was employed Hi investigate some hydrolytic enzymes bound to the cell wall and the changes in these during ripening. Seven glycosidases. β-glucosidase (EC 3.2.1.21) α-galactosidase (EC 3.2.1.22). β-galactosidase (EC 3.2.1.23). α-arabinosidase (EC 3.2.1.55), α-mannosidase (EC 3.2.1,24). β-xylosidase (EC 3.2.1.37) and β-N-acetylglucosamidase (EC 3.2.1.30). as well as Cx-cellulase (EC 3.2.1.4) and endo-polygalacturonase (EC 3.2.1.15). were identified in the cell wall preparation, at four stages of ripeness (mature green. changing colour, black and black-ripe). Activities of all these cell wall-associated enzymes fionicallv and covalently linked) were determined either by cell wall incubation with artificial substrate or after extraction from the cell wall with buffers of high salt concentration (Cx-cellulase). and were compared to those of forms solubilized from acetone powders with 500 nM citrate buffer (cytoplasmic and/or apoplastic plus ionically hound to cell wall) In general, the activities of low ionic strength buffer-soluble enzymes were found to be much higher than those of the bound enzymes. The bound enzymes are present in the fruit at the green colour stage, whereas the activities of the soluble enzymes only increased from the changing colour stage onwards. The tenacity of binding of enzymes to the wall was investigated by treating the walls with high salt and measuring residual activity. The nature of the ionic and covalent binding and the changes during ripening were also established for wall-hound glycosidase During ripening there was a marked change in the percentages of covalently- and tonically linked activities of β-glucosidase and β-galaclosidase: al the changing colour stages about 75–80% of the bound active in was present in high ionic strength buffer while al the black-ripe stage it was only 15–20. A possible role for these cell wall degradative enzymes in olive softening is discussed.     

In vivo modification of the cell wall polysaccharide galactomannan of guar transformed with a α-galactosidase gene cloned from senna

Galactomannans are composed of a 1to4 mannan backbone with varying degrees of 1to6 galactose substitutions and are found in the cell walls of legume endosperm. Like other cell wall polysaccharides, many factors controlling the metabolism of galactomannans remain to be elucidated. In the endospermous legume senna (Senna occidentalis) increased -galactosidase activity has previously been observed to coincide temporarily with a decrease of the galactose content of the galactomannan. To evaluate the potential role of -galactosidase for the control of the final galactose content, a -galactosidase gene expressed in immature senna seeds was cloned and transformed into the related high-yielding species guar (Cyamopsis tetragonoloba). The isolated cDNA encoded a 406 amino acid protein with a calculated molecular mass of 44313 Da. The amino acid sequence was 75% identical to the galactomannan hydrolysing -galactosidases from germinating guar and coffee bean. The senna -galactosidase gene was inserted behind a wheat high-molecular-weight glutenin promoter in the vector employed for transformation of guar by Agrobacterium tumefaciens-mediated gene transfer. About 30% of the guar transformants produced endosperm with galactomannans where the galactose content was significantly reduced. After self-fertilization of primary transformants displaying the highest galactose reduction of the galactomannan, endosperms of R₁ plants were analysed demonstrating that this property was inherited stably to the progeny and that it was 100% coupled to the presence of the senna -galactosidase gene. This suggests that -galactosidases can be involved in the determination of the final galactose content of endosperm galactomannans, demonstrating that cell wall polysaccharide biosynthesis can be modified in vivo.     

Incorporation of galactose from UDP-galactose into microsomal and golgi membranes of rat liver

Rough and smooth microsomes and Golgi membranes were incubated with UDP[¹⁴C]galactose and the incorporation of radioactivity into the lipid extract and into endogenous protein acceptors were measured. Antagonistic pyrophosphatases were inhibited with ATP and interference from β-galactosidase activity was greatly decreased by carrying out the incubation at pH 7.8. After incubation the particles were centrifuged to remove free oligosaccharide residues. Radioactivity was found in the lipid extract from Golgi membranes but not from rough and smooth microsomes. This radioactivity, however, was not associated with dolichol or retinyl phosphates. The incorporation of radioactivity into proteins of the Golgi fraction was more than double than that of the microsomal fractions. In addition, the transferases in these two types of particles exhibited different properties. Trypsin treatment of intact rough microsomal vesicles, smooth vesicles and Golgi membranes removed about 5, 15 and 50%, respectively, of newly incorporated protein-bound galactose, indicating that the proportion of the newly galactosylated proteins, which are localized at the cytoplasmic surface of the membrane, is lowest in rough microsomes, intermediate in smooth, and highest in Golgi membranes.     

Overexpression of Poplar Xylem Sucrose Synthase in Tobacco Leads to a Thickened Cell Wall and Increased Height

Sucrose synthase (SuSy) is considered the first key enzyme for secondary growth because it is a highly regulated cytosolic enzyme that catalyzes the reversible conversion of sucrose and UDP into UDP-glucose and fructose. Although SuSy enzymes preferentially functions in the direction of sucrose cleavage at most cellular condition, they also catalyze the synthetic reaction. We isolated a gene that encodes a SuSy from Populus simonii×Populus nigra and named it PsnSuSy2 because it shares high similarity to SuSy2 in Populus trichocarpa. RT-PCR revealed that PsnSuSy2 was highly expressed in xylem, but lowly expressed in young leaves. To characterize its functions in secondary growth, multiple tobacco overexpression transgenic lines of PnsSuSy2 were generated via Agrobacterium-mediated transformation. The PsnSuSy2 expression levels and altered wood properties in stem segments from the different transgenic lines were carefully characterized. The results demonstrated that the levels of PsnSuSy2 enzyme activity, chlorophyll content, total soluble sugars, fructose and glucose increased significantly, while the sucrose level decreased significantly. Consequently, the cellulose content and fiber length increased, whereas the lignin content decreased, suggesting that PsnSuSy2 plays a significant role in cleaving sucrose into UDP-glucose and fructose to facilitate cellulose biosynthesis and that promotion of cellulose biosynthesis suppresses lignin biosynthesis. Additionally, the noticeable increase in the lodging resistance in transgenic tobacco stem suggested that the cell wall characteristics were altered by PsnSuSy2 overexpression. Scanning electron microscopy was performed to study the cell wall morphology of stem, and surprisingly, we found that the secondary cell wall was significantly thicker in transgenic tobacco. However, the thickened secondary cell wall did not negatively affect the height of the plants because the PsnSuSy2- overexpressing lines grew taller than the wildtype plants. This systematic analysis demonstrated that PsnSuSy2 plays an important role in cleaving sucrose coupled with cellulose biosynthesis in wood tissue.