Xyloglucan−pectin linkages are formed intra-protoplasmically,contribute to wall-assembly,and remain stable in the cell wall

We tested two hypotheses for the mechanism by which xyloglucan–pectin covalent bonds are formed in Arabidopsis cell cultures. Hypothesis 1 proposed hetero-transglycosylation, with xyloglucan as donor substrate and a rhamnogalacturonan-I (RG-I) side-chain as acceptor. We looked for enzyme activities that catalyse this reaction using α-(1→5)-l-[³H]arabino- or β-(1→4)-d-[³H]galacto-oligosaccharides as model acceptor substrates. The ³H-oligosaccharides were supplied (with or without added xyloglucans) to living Arabidopsis cell-cultures, permeabilised cells, cell-free extracts, or four authentic XTHs. No hetero-transglycosylation occurred. Therefore, we cannot support hypothesis 1. Hypothesis 2 proposed that some xyloglucan is manufactured de novo as a side-chain on RG-I. To test this, we pulse-labelled Arabidopsis cell-cultures with [³H]arabinose and monitored the radiolabelling of anionic (pectin-bonded) xyloglucan, which was resolved from free xyloglucan by ion-exchange chromatography. [³H]Xyloglucan–pectin complexes were detectable <4 min after [³H]arabinose feeding, which is shorter than the transit-time for polysaccharide secretion, indicating that xyloglucan–pectin bonds were formed intra-protoplasmically. Thereafter, the proportion of the wall-bound [³H]xyloglucan that was anionic remained almost constant at ∼50% for ≥6 days, showing that the xyloglucan–pectin bond was stable in vivo. Some [³H]xyloglucan was rapidly sloughed into the medium instead of becoming wall-bound. Only ∼30% of the sloughed [³H]xyloglucan was anionic, indicating that bonding to pectin promoted the integration of xyloglucan into the wall. We conclude that ∼50% of xyloglucan in cultured Arabidopsis cells is synthesised on a pectic primer, then secreted into the apoplast, where the xyloglucan–pectin bonds are stable and the pectic moiety aids wall-assembly.     

Pre-formed xyloglucans and xylans increase in molecular weight in three distinct compartments of a maize cell-suspension culture

Cultured cells of maize ( Zea mays L.) were pulse-labelled with l-[1-(3)H]arabinose (Ara) and then monitored for 7 days. The (3)H-hemicelluloses present in three compartments (protoplasm, cell wall and culture medium) were size-fractionated and the fractions assayed for [(3)H]xyloglucans and [(3)H]xylans. Protoplasmic [(3)H]xylans and [(3)H]xyloglucans initially (15 min after [(3)H]Ara-feeding) had weight-average relative molecular masses ( M(w)) approximately 0.5x10(6) and 0.3x10(6), respectively, both rising to 2x10(6) by 30 min. Thus, newly formed hemicellulose molecules were joined to other polymers, or to each other, presumably within Golgi vesicles. New (3)H-hemicelluloses very rapidly bound to the cell wall; however, after 1 day, some [(3)H]xyloglucan and [(3)H]xylan was sloughed from the wall into the medium. The wall-bound [(3)H]xyloglucans were present in the form of extremely large complexes, of M(w)>17x10(6), even as early as 15 min after [(3)H]Ara-feeding. This M(w) is >70-fold greater than that observed by similar methods in cultures of a dicotyledon ( Rosa sp.). Thus, during wall-binding, newly secreted xyloglucans greatly increased in size, possibly by transglucosylation. Some modest degradation (trimming) of wall-bound [(3)H]xyloglucan occurred later. The earliest wall-bound [(3)H]xylan had M(w) approximately 2x10(6), similar to the protoplasmic [(3)H]xylan; this increased to approximately 4x10(6) by 6 h. For the first 2 days after [(3)H]Ara-feeding, the soluble extracellular (3)H-hemicelluloses present in the culture medium had M(w) approximately 1x10(6)-2x10(6), comparable to the protoplasmic hemicelluloses. However, between 2 and 3 days after [(3)H]Ara-feeding, the M(w) of the soluble extracellular [(3)H]xylans increased abruptly to approximately 10x10(6); the soluble extracellular [(3)H]xyloglucans underwent a similar but more gradual increase in M(w). Maize (3)H-hemicelluloses thus underwent increases in M(w) in three episodes: (i) intra-protoplasmically, (ii) during wall-binding (especially xyloglucans), and (iii) after sloughing into the medium. Possible mechanisms and roles of these increases are discussed.     

Trimming and solubilization of xyloglucan after deposition in the walls of cultured rose cells

A pulse-chase technique involving the in vivo feeding of L-[1-³H]arabinoseto suspension-cultured rose (Rosa) cells at 4 d and 9 d aftersubculture (fast- and slow-growing, respectively) was used tocreate a population of [³H]xyloglucan molecules and to followtheir subsequent fate. The weight-average relative molecu larmass (M_w) of [³H]xyloglucan freshly deposited in the cell wallwas 160 000 and 240 000 in the fast- and slow-growing cells,respectively. The wall-bound [³H]xyloglucan of both culturesunderwent a decrease in M_w of 40 000 during the first 2 d afterthe pulse-labelling. At the same time, 20–30% of the initially-deposited[³H]xyloglucan disappeared from the cell wall, and a similaramount appeared in solution in the culture medium. Its failureto remain bound to the cell wall and its low M_w (39 000) indicatedthat this soluble extracellular ( was derived from partial degradationof segments of wall-bound xyloglucan that were not directlyhydrogen-bonded to microfibrils (‘loose ends’ and‘tethers’). The possible enzymic basis and biologicalroles of the degradation are discussed. Key words: Cell expansion, cell wall, hemicellulose, sloughing, xyloglucan     

Xyloglucan oligosaccharides cause cell wall loosening by enhancing xyloglucan endotransglucosylase/hydrolase activity in azuki bean epicotyls

Addition of xyloglucan-derived oligosaccharides shifted the wall-bound xyloglucans to a lower molecular mass distribution and increased the cell wall extensibility of the native epidermal tissue strips isolated from azuki bean (Vigna angularis) epicotyls. To ascertain the mechanism of oligosaccharide function, we examined the action of a xyloglucan endotransglucosylase/hydrolase (XTH) showing both endotransglucosylase and endohydrolase activities, isolated from azuki bean epicotyl cell walls, in the presence of xyloglucan oligosaccharides. The addition of xyloglucan oligosaccharides enhanced the xyloglucan-degrading activity of XTH against isolated xyloglucan substrates. When the methanol-fixed epidermal tissue strips were incubated with XTH, the molecular mass of wall-bound xyloglucans was decreased and the cell wall extensibility increased markedly in the presence of the oligosaccharides. These results suggest that xyloglucan oligosaccharides stimulate the degradation of xyloglucans by enhancing the XTH activity within the cell wall architecture, thereby increasing the cell wall extensibility in azuki bean epicotyls.     

In vitro activities of four xyloglucan endotransglycosylases from Arabidopsis

Xyloglucan endotransglycosylases (XETs) are encoded by a gene family in Arabidopsis thaliana. These enzymes modify a major structural component of the plant cell wall, xyloglucan, and therefore may influence plant growth and development. We have produced four Arabidopsis XETs (TCH4, Meri-5, EXGT and XTR9) using the baculovirus/insect cell system and compared their biochemical activities. TCH4, as previously demonstrated, and the other three proteins are capable of carrying out transglycosylation of xyloglucans. The K(m) for XLLGol acceptor oligosaccharide is in the range of 20-40 microM for all the XETs except XTR9, which has a Km of 5 microM and is significantly inhibited by high levels of XLLGol. All four enzymes are most active between pH 6.0 and 6.5. TCH4 and XTR9 have temperature optima of 18 degrees C, whereas Meri-5 and EXGT are most active at 28 and 37 degrees C, respectively. Although the activity levels of three of the XETs are not influenced by the presence of fucose on the xyloglucan polymer, XTR9 has a clear preference for non-fucosylated xyloglucan polymer. The four XETs show a marked preference for XLLGol over either XXFGol or XXXGol as acceptor oligosaccharide. All four XETs are glycosylated; however, only the activities of TCH4 and Meri-5 are affected by the removal of the N-glycan with PNGase F. These four enzymes most likely function solely as transglycosylases because xyloglucan endoglucanase activity was not apparent. Subtle differences in biochemical activities may influence the physiological functions of the distinct XETs in vivo.     

Kinetics of Integration of Xyloglucan into the Walls of Suspension-Cultured Rose Cells

To study the kinetics of synthesis, wall-binding and degradationof xyloglucan, we incubated suspension-cultured rose cells for0–5–24 h in L-[1-³H]arabinose. >95% of the [³H]arabinosewas taken up within 2 h. UDP-Pentoses were maximally labelledwithin 0–5 h and had lost most of their ³H by 2 h afterthe addition of [³H]arabinose. Therefore, the 24 h experimentresembled a pulse-chase rgime. The [³H]xyloglucan formed wasfractionated into four cellular pools [detergent-extractable(interpreted as cytoplasmic), and guanidinium thiocyanate-,06 M NaOH- and 60 M NaOH-extractable (interpreted as progressivelymore firmly wall-bound)]; soluble extracellular xyloglucan wascollected as a fifth pool. All five pools of xyloglucan hadstarted accumulating ³H at their respective maximal rates by     

The biosynthesis and wall-binding of hemicelluloses in cellulose-deficient maize cells:An example of metabolic plasticity

Cell-suspension cultures(Zea mays L.,Black Mexican sweet corn) habituated to 2,6-dichlorobenzonitrile(DCB) survive with reduced cellulose owing to hemicellulose network modification. We aimed to de fine the hemicellulose metabolism modifications in DCB-habituated maize cells showing a mild reduction in cellulose at different stages in the culture cycle. Using pulse-chase radiolabeling, we fed habituated and non-habituated cultures with [3H]arabinose,and traced the distribution of 3H-pentose residues between xylans, xyloglucans and other polymers in several cellular compartments for 5 h. Habituated cells were slower taking up exogenous [3H]arabinose. Tritium was incorporated into polysaccharide-bound arabinose and xylose residues, but habituated cells diverted a higher proportion of their new [3H]xylose residues into(hetero) xylans at the expense of xyloglucan synthesis. During logarithmic growth, habituated cells showed slower vesicular traf ficking of polymers,especially xylans. Moreover, habituated cells showed a decrease in the strong wall-binding of all pentose-containing polysaccharides studied; correspondingly, especially in log phase cultures, habituation increased the proportion of 3H-hemicelluloses([3H]xylans and [3H]xyloglucan) sloughed into the medium. These findings could be related to the cel walls' cellulose-deficiency, and consequent reduction in binding sites for hemicelluloses; the data could also re fl ect the habituated cells' reduced capacity to integrate arabinox ylans by extra-protoplasmic phenolic cross-linking, as well as xyloglucans, during wall assembly.     

Transport, degradation and cell wall-integration of XXFGol, a growth-regulating nonasaccharide of xyloglucan, in pea stems

When [glucitol-³H]XXFGol (a NaB³H₄-reduced xyloglucan nonasaccharide) was applied to excised shoots of pea (Pisum sativum L. cv. Progress) at the base of the epicotyl, it inhibited growth in the elongation zone, 4–5 cm distal. Experiments were conducted to discover whether such ³H-oligosaccharides are translocated intact over this distance, or whether an intercellular second messenger would have to be postulated. After 24 h, ³H from [glucitol-³H]XXFGol and [glucitol-³H]XXXGol showed U-shaped distributions, with most ³H at the base and apex of the stem. Radioactivity from [fucosyl-³H]XXFG and [xylosyl-³H]XXFG also moved acropetally, but did not concentrate at the apex, possibly owing to removal from the transpiration stream of fucose and xylose formed by partial hydrolysis of XXFG en route. When 10⁻⁷ M [glucitol-³H]XXFGol was supplied, about 14 fmol ·  seedling^–1 of apparently intact [³H]XXFGol was extractable from the elongation zone after 24 h. Larger amounts of degradation products were extractable (including free [³H]glucitol) and some wall-bound ³H-hemicellulose was present (presumably formed by the oligosaccharides acting as acceptor substrates for transglycosylation). We conclude that biologically active oligosaccharides of xyloglucan can move through the stem acropetally and that they are maintained at low steady-state concentrations by both hydrolysis and transglycosylation. Received: 1 April 1997 / Accepted: 28 May 1997     

Kinetic analysis using low-molecular mass xyloglucan oligosaccharides defines the catalytic mechanism of a Populus xyloglucan endotransglycosylase

Plant XETs [XG (xyloglucan) endotransglycosylases] catalyse the transglycosylation from a XG donor to a XG or low-molecular-mass XG fragment as the acceptor, and are thought to be important enzymes in the formation and remodelling of the cellulose-XG three-dimensional network in the primary plant cell wall. Current methods to assay XET activity use the XG polysaccharide as the donor substrate, and present limitations for kinetic and mechanistic studies of XET action due to the polymeric and polydisperse nature of the substrate. A novel activity assay based on HPCE (high performance capillary electrophoresis), in conjunction with a defined low-molecular-mass XGO {XG oligosaccharide; (XXXGXXXG, where G=Glcbeta1,4- and X=[Xylalpha1,6]Glcbeta1,4-)} as the glycosyl donor and a heptasaccharide derivatized with ANTS [8-aminonaphthalene-1,3,6-trisulphonic acid; (XXXG-ANTS)] as the acceptor substrate was developed and validated. The recombinant enzyme PttXET16A from Populus tremula x tremuloides (hybrid aspen) was characterized using the donor/acceptor pair indicated above, for which preparative scale syntheses have been optimized. The low-molecular-mass donor underwent a single transglycosylation reaction to the acceptor substrate under initial-rate conditions, with a pH optimum at 5.0 and maximal activity between 30 and 40 degrees C. Kinetic data are best explained by a ping-pong bi-bi mechanism with substrate inhibition by both donor and acceptor. This is the first assay for XETs using a donor substrate other than polymeric XG, enabling quantitative kinetic analysis of different XGO donors for specificity, and subsite mapping studies of XET enzymes.     

Role of transglycosylation in the integration of xyloglucan into the growing plant cell wall in vivo

Abstract

Xyloglucan endotransglycosylase (XET) activity is widespread in plant cell walls, but its action on xyloglucan in vivo has been difficult to prove because the reaction products are not expected to differ chemically from the reactants. By feeding of cultured Rosa cells with [¹³C]glucose and [³H]arabinose followed by [¹²-C]glucose, and isopyenic centrifugation of the extracted xyloglucan in caesium trifluoroacetate, we have obtained evidence for the annealing of segments of newly-secreted xyloglucan to xyloglucan chains that were already present in the cell wall. This is the first evidence for interpolymeric transglycosylation of xyloglucan in vivo.