Xyloglucan antibodies inhibit auxin-induced elongation and cell wall loosening of azuki bean epicotyls but not of oat coleoptiles

Polyclonal antibodies were raised in rabbits against isoprimeverose (Xyl₁Glc₁), xyloglucan heptasaccharides (Xyl₃Glc₄), and octasaccharides (Gal₁Xyl₃Glc₄). Antibodies specific for hepta- and octasaccharides suppressed auxin-induced elongation of epicotyl segments of azuki bean (Vigna angularis Ohwi and Ohashi cv Takara). These antibodies also inhibited auxin-induced cell wall loosening (decrease in the minimum stress-relaxation time and the relaxation rate of the cell walls) of azuki segments. However, none of the antibodies influenced auxin-induced elongation or cell wall loosening of coleoptile segments of oat (Avena sativa L. cv Victory). Auxin caused a decrease in molecular mass of xyloglucans in the cell walls of azuki epicotyls and oat coleoptiles. The antibodies inhibited such a change in molecular mass of xyloglucans in both species. Preimmune serum exhibited little or no inhibitory effect on auxin-induced elongation, cell wall loosening, or breakdown of xyloglucans. The results support the view that the breakdown of xyloglucans is associated with the cell wall loosening responsible for auxin-induced elongation in dicotyledons. The view does not appear to be applicable to poaceae, because the inhibition of xyloglucan breakdown by the antibodies did not influence auxin-induced elongation or cell wall loosening of oat coleoptiles.     

Effect of anti-wall protein antibodies on auxin-induced elongation, cell wall loosening, and β-D-glucan degradation in maize coleoptile segments

Antiserum raised against the LiCl extract of maize shoot cell walls suppresses auxin-induced elongation of maize coleoptile segments. A series of polyclonal antibodies were raised against protein fractions separated from the LiCl extract of maize ( Zea mays L. cv. B73 x Mo17) coleoptiles by SP-Sephadex and Bio-Gel P-150 chromatography. To understand the role of cell wall proteins in growth regulation, the effect of these antibodies on auxin-induced elongation and changes in the cell walls of maize coleoptiles was examined. Four of the fractions prepared reacted with the antiserum raised against the total LiCl extract and effectively suppressed its growth-inhibiting activity. Only these fractions contained the proteins responsible for eliciting growthinhibiting antibodies. The antibodies capable of growth inhibition of auxin-induced elongation of segments also inhibited auxin-induced cell wall loosening (decrease in the minimum stress-relaxation time of the cell walls) of segments. The antibodies raised against one of the protein fractions separated by SP-Sephadex inhibited the autolytic reactions of isolated cell walls and the auxin-induced decrease in (1→3), (1→4)-β-D-glucans in the cell walls. Thus, the degradation of β-D-glucans by cell wall enzymes may be associated with the cell wall loosening that is responsible for cell elongation. Because the other antibodies did not influence the auxin-induced degradation of (1→3), (1→4)-β-D-glucanses, β-D-glucanases and other cell wall enzymes may cooperate in regulation of cell elongation in maize coleoptiles.     

Differential Effect of Auxin on Molecular Weight Distributions of Xyloglucans in Cell Walls of Outer and Inner Tissues from Segments of Dark Grown Squash (Cucurbita maxima Duch.) Hypocotyls

Effects of indole-3-acetic acid (IAA) on the mechanical properties of cell walls and structures of cell wall polysaccharides in outer and inner tissues of segments of dark grown squash (Cucurbita maxima Duch.) hypocotyls were investigated. IAA induced the elongation of unpeeled, intact segments, but had no effect on the elongation of peeled segments. IAA induced the cell wall loosening in outer tissues as studied by the stress-relaxation analysis but not in inner tissues. IAA-induced changes in the net sugar content of cell wall fractions in outer and inner tissues were very small. Extracted hemicellulosic xyloglucans derived from outer tissues had a molecular weight about two times as large as in inner tissues, and the molecular weight of xyloglucans in both outer and inner tissues decreased during incubation. IAA substantially accelerated the depolymerization of xyloglucans in outer tissues, while it prevented that in inner tissues. These results suggest that IAA-induced growth in intact segments is due to the cell wall loosening in outer tissues, and that IAA-accelerated depolymerization of hemicellulosic xyloglucans in outer tissues is involved in the cell wall loosening processes.     

Concanavalin A Inhibits Auxin-Induced Elongation and Breakdown of (1 -> 3), (1 -> 4)-{beta}-D-Glucans in Segments of Rice Coleoptiles

Concanavalin A (Con A) suppresses auxin-induced elongation ofsurface-abraded segments from both dicotyledonous and poaceousplants. In coleoptile segments of rice (Oryza sativa L.), theauxin-induced decrease in the minimum stress-relaxation timeand increase in the mechanical extensibility of the cell wallswere also inhibited by Con A, indicating that the lectin suppresseselongation by inhibiting the cell wall loosening. Auxin causeda decrease in the level of (1 3), (1 4)-ß-D-glucansin the cell walls of rice coleoptile segments, and this decreasewas also inhibited by the lectin. Con A suppressed the autolytichydrolysis of the glucans, as well as their breakdown in vitroby a protein fraction that had been extracted from the cellwalls of rice coleoptiles with 1 M NaCl. Furthermore, most ofthe glucan-hydrolyzing activity of the wall proteins bound toa Con A-Sepharose column, suggesting that glycoprotein enzymesare involved in the hydrolysis. Although Con A also affectedthe hydrolysis of other wall polysaccharides, the present data,when considered in combination with the inhibitory effects ofglucan-specific or glucanasespecific antibodies, support theview that the breakdown of (1 3),(1 4)-ß-D-glucansis associated with the cell wall loosening that is responsiblefor auxin-induced elongation in Poaceae. (Received August 17, 1994; Accepted February 15, 1995)     

Regulation of polysaccharide breakdown during auxin-induced cell wall loosening

Auxin induces cell elongation by increasing the extensibility of the cell wall. Biochemical modifications of wall constituents lead to such changes in the mechanical properties of the cell wall (wall loosening). The results obtained in the studies using antibodies and lectins as specific probes indicate that the breakdown of xyloglucans in dicotyledons and (1→3), (1→4)-β-glucans in Poaceae is involved in auxin-induced wall loosening. In dicotyledons, xyloglucans are degraded by the direct hydrolysis with an endoglucanase to oligosaccharides and by the two-step reaction via a product with intermediate size. (1→3), (1→4)-β-Glucan breakdown in Poaceae coleoptiles is mediated by the two-step reaction with endo-and exoglucanases. Although auxin inducesde novo synthesis of some hydrolases involved in breakdown of these polysaccharides, the breakdown activity is also regulated by the wall environment such as pH, by the mobility of hydrolases through wall networks, by the interaction of hydrolases with wall polysaccharide complex, and by the presence and the concentrations of different types of regulatory molecules. Recipient of the Botanical Society Award of Young Scientists, 1992.     

Inhibition of the Breakdown of Xyloglucans in Azuki Bean Epicotyls by Concanavalin A

Indole-3-acetic acid at 10 µM caused a 30% decrease inthe weight-average molecular mass of xyloglucans extracted with24% KOH from the cell walls of epicotyl segments of azuki bean(Vigna angularis Ohwi et Ohashi cv. Takara). Concanavalin A(Con A) at 2 g liter^–1 completely inhibited the IAA-inducedchange in the molecular mass of the xyloglucans. Con A alsosuppressed the autolysis of pectin-depleted cell walls, as wellas the breakdown of xyloglucans by a protein fraction that hadbeen extracted with 1 M NaCl from the cell walls of azuki beanepicotyls. These results indicate that Con A is a potent inhibitorof the breakdown of xyloglucans both in vivo and in vitro. Mostof the activity responsible for the decrease in staining byiodine and the increase in reducing power of solution of xyloglucansin the protein fraction from cell walls bound to a column ofCon A-Sepharose and was eluted by the specific hapten, methyl     

Role of xyloglucan breakdown in epidermal cell walls for auxininduced elongation of azuki bean epicotyl segments

Auxin-induced elongation of epicotyl segments of azuki bean ( Vigna angularis Ohwi et Ohashi cv. Takara) was suppressed by a fucose-binding lectin from Tetragonolobus purpureas Moench and by polyclonal antibodies raised against xyloglucan heptasaccharide (Xyl₃Glc₄) when the cuticle present in the outer surface of epicotyls was abraded. In contrast, elongation of non-abraded segments was not influenced by the lectin or the antibodies. Epicotyl segments, from which the epidermal and the outer cortical cells had been removed, elongated rapidly for 2 h and than only slowly. Auxin slightly stimulated elongation of the inner tissue segments in the phase of slow growth. Neither in the presence nor in the absence of auxin did the lectin or the antibodies affect elongation of the inner tissue segments. The split portions of outer surface-abraded epicotyl segments incubated in buffer extended outward, and auxininhibited this outward bending. The lectin and the antibodies reversed the effect of auxin on bending. The fucose-binding lectin pretreated with fucose or the immunoglobulin fraction obtained from preimmune serum exhibited little or no inhibitory effect on auxin-induced elongation of abraded or split segments. These results support the view that a breakdown of xyloglucans in the epidermal cell walls plays an essential role in auxin-induced elongation in dicotyledons.     

Auxin-induced changes in the cell wall structure: Changes in the sugar compositions, intrinsic viscosity and molecular weight distributions of matrix polysaccharides of the epicotyl cell wall of Vigna angularis

Rapid effects of indole-3-acetic acid (IAA) on the mechanical properties of cell wall, and sugar compositions, intrinsic viscosity and molecular weight distribution of cell wall polysaccharides were investigated with excised epicotyl segments of Vigna angularis Ohwi et Ohashi cv. Takara.

• 1 IAA caused cell wall loosening as studied by stress-relaxation analysis within 15 min after the IAA application.
• 2 IAA stimulated the decrease in the content of arabinose and galactose in the hemicellulose 1 h after its application. The amounts of other component sugars in the cell wall polysaccharides remained constant during the IAA-induced segment growth.
• 3 The intrinsic viscocity of the pectin increased as early as 30 min after the IAA application. This effect was not prevented when elongation growth of the segment was osmotically suppressed by 0.15 M mannitol.
• 4 Gel permeation chromatography of the pectin on a Sepharose 4 B column demonstrated that IAA caused increase in the mass-average molecular weight of the pectin. Analysis of the sugar compositions of the pectin eluted from the Sepharose 4 B column indicated that IAA increased the molecular weight of the polysaccharides composed of uronic acid, galactose, rhamnose and arabinose. This effect became apparent within 30 min after the IAA application. Furthermore, IAA increased the molecular weight of the pectin when elongation growth of the epicotyl segments was osmotically suppressed by 0.15 M mannitol.
• 5 Hemicellulose of the cell wall chromatographed on a Sepharose CL-4 B column. Analysis of the neutral sugar compositions and the iodine staining property (specific for xyloglucans) of the polysaccharide solution eluted from the column indicated that the hemicellulose consisted of xyloglucans, arabinogalactans and polysaccharides composed of xylose and/or mannose. IAA caused a decrease in the arabinogalactan content and depolymerization of xyloglucans. These IAA effects became apparent within 30 min after the IAA application. These changes occurred even when elongation growth of the epicotyl segments was osmotically suppressed by 0.15 M mannitol.

Polymerization of the pectin, degradation of arabinogalactans and depolymerization of xyloglucans appear to be involved in the mechanism by which IAA induces cell wall loosening and therefore extension growth of cells.     

Xyloglucan breakdown during cotton fiber development

Cotton (Gossypium herbaceum L.) fibers elongated almost linearly up to about 20 days post anthesis. The molecular mass of xyloglucans in fiber cell walls decreased gradually during the elongation stage. When enzymatically active (native) cell wall preparations of fibers were autolyzed, the molecular mass of xyloglucans decreased. The decrease was most prominent in wall preparations obtained from the rapidly elongating fibers. The xyloglucan-degrading activity was recovered from the fiber cell walls with 3 mol/L NaCl, and the activity was high at the stages in which fibers elongated vigorously. These results suggest the possible involvement of xyloglucan metabolism in the regulation of cotton fiber elongation.     

Galactose inhibition of auxin-induced cell elongation in oat coleoptile segments

Auxin-induced cell elongation in oat coleoptile segments was inhibited by galactose; removal of galactose restored growth. Galactose did not appear to affect the following factors which modify cell elongation: auxin uptake, auxin metabolism, osmotic concentration of cell sap, uptake of tritium-labeled water, auxin-induced wall loosening as measured by a decrease in the minimum stress-relaxation time and auxininduced glucan degradation. Galactose markedly prevented incorporation of [¹⁴C]-glucose into cellulosic and non-cellulosic fractions of the cell wall. It was concluded that galactose inhibited auxin-induced long-term elongation of oat coleoptile segments by interfering with cell wall synthesis.     

Hypergravity increases the molecular mass of xyloglucans by decreasing xyloglucan-degrading activity in azuki bean epicotyls.

Elongation growth of dark-grown azuki bean (Vigna angularis Ohwi et Ohashi cv. Takara) epicotyls was suppressed by hypergravity at 30 x g and above. Acceleration at 300 x g significantly decreased the mechanical extensibility of cell walls. The amounts of cell wall polysaccharides (pectin, hemicellulose-II and cellulose) per unit length of epicotyls increased under the hypergravity condition. Hypergravity also increased the amounts and the weight-average molecular mass of xyloglucans in the hemicellulose-II fraction, while decreasing the activity of xyloglucan-degrading enzymes extracted from epicotyl cell walls. These results suggest that hypergravity increases the amounts and the molecular mass of xyloglucans by decreasing xyloglucan-degrading activity. Modification of xyloglucan metabolism as well as the thickening of cell walls under hypergravity conditions seems to be involved in making the cell wall mechanically rigid, thereby inhibiting elongation growth of azuki bean epicotyls.     

Changes in the apoplastic pH are involved in regulation of xyloglucan breakdown of azuki bean epicotyls under hypergravity conditions

Hypergravity inhibited elongation growth of azuki bean (Vigna angularis Ohwi et Ohashi) epicotyls by decreasing the mechanical extensibility of cell walls via the increase in the molecular mass of xyloglucans [Soga et al. (1999) Plant Cell Physiol. 40: 581]. Here, we report that the pH value of the apoplastic fluid in epicotyls increased from 5.8 to 6.6 by hypergravity (300 x g) treatment. When the xyloglucan-degrading enzymes extracted from cell walls of the 1 x g control epicotyls were assayed in buffer at pH 6.6 and 5.8, the activity at pH 6.6 was almost half of that at pH 5.8. In addition, when enzymically active cell wall preparations obtained from 1 x g control epicotyls were autolyzed in buffer at pH 5.8 and 6.6 and then xyloglucans were extracted from the autolyzed cell walls, the molecular mass of xyloglucans incubated at pH 5.8 decreased during the autolysis, while that at pH 6.6 did not change. Thus, the xyloglucans were not depolymerized by autolysis at the pH value (6.6) observed in the hypergravity-treated epicotyls. These findings suggest that in azuki bean epicotyls, hypergravity decreases the activities of xyloglucan-degrading enzymes by increasing the pH in the apoplastic fluid, which may be involved in the processes of the increase in the molecular mass of xyloglucans, leading to the decrease in the cell wall extensibility.     

beta-d-Glucan Antibodies Inhibit Auxin-Induced Cell Elongation and Changes in the Cell Wall of Zea Coleoptile Segments

Antiserum was raised against the Avena sativa L. caryopsis β-d-glucan fraction with an average molecular weight of 1.5 × 10⁴. Polyclonal antibodies recovered from the serum after Protein A-Sepharose column chromatography precipitated when cross-reacted with high molecular weight (1→3), (1→4)-β-d-glucans. These antibodies were effective in suppression of cell wall autohydrolytic reactions and auxin-induced decreases in noncellulosic glucose content of the cell wall of maize (Zea mays L.) coleoptiles. The results indicate antibody-mediated interference with in situ β-d-glucan degradation. The antibodies at a concentration of 200 micrograms per milliliter also suppress auxin-induced elongation by about 40% and cell wall loosening (measured by the minimum stress-relaxation time of the segments) of Zea coleoptiles. The suppression of elongation by antibodies was imposed without a lag period. Auxin-induced elongation, cell wall loosening, and chemical changes in the cell walls were near the levels of control tissues when segments were subjected to antibody preparation precipitated by a pretreatment with Avena caryopsis β-d-glucans. These results support the idea that the degradation of (1→3), (1→4)-β-d-glucans by cell wall enzymes is associated with the cell wall loosening responsible for auxin-induced elongation.     

Relationships between cell-wall β-1,3-endoglucanase activity and auxin-induced elongation in mung bean hypocotyl segments

Summary A β-1,3-endoglucanase (mol. wt. 43,000 and pI around 7) was immunolocalized in outer epidermal cell walls and pericycle walls in the elongation zone of mung bean hypocotyls. Hypocotyl segments infiltrated with anti-β-1,3-endoglucanase antibodies show a clear reduction in their auxin-induced elongation when the auxin treatment was maintained for a long period (15 h). These results suggest that, even in dicotyledons, rupture of some β-1,3-glycosyl linkages might be associated with the cell-wall loosening, which is responsible for auxin-induced elongation, or that some β-1,3-glucanases are indirectly involved in auxin-induced elongation through their auxin-binding properties.     

Auxin-regulated Wall Loosening and Sustained Growth in Elongation

It is proposed that auxin regulates and coordinates both wall loosening and the supply of wall materials in elongation. The tenets of the proposal allowed testable predictions. It was determined that, if the cell walls of Glycine max L. var. Wayne hypocotyl segments are maintained in a loosened state (by excising the segments directly into pH 4 medium), exogenous auxin induced only the second response. It was also predicted and confirmed that elongating systems, e.g. pea epicotyl, with certain early auxin-induced growth kinetics (an initial high non-steady-state rate followed immediately by a drop to a lower steady-state rate) would show a transient second response (in addition to the usual transient first response) when stimulated by pH 4 medium. Finally, it is pointed out that recent results which establish the existence of auxin-induced elongation-associated proteins support the proposition that auxin coordinates wall loosening and the supply of wall materials in elongation.     

Protein synthesis and wall extensibility in the Avena coleoptile

Summary The inhibitors cycloheximide and puromycin have been used to examine the relationship between protein synthesis and wall extensibility, as measured with an Instron, in Avena coleoptile segments. Cycloheximide at 4 g/ml almost totally inhibits both auxin-induced cell elongation and protein synthesis with only a slight lag. Wall extensibility is unaffected by the inhibitor if auxin is absent. If added prior to auxin, cycloheximide prevents auxin-induced wall loosening while if added after auxin it causes a substantial decline in the wall extensibility. With puromycin there is a 2–4 hr lag before growth and wall loosening are inhibited. These results support the conclusions that the proteins needed for wall loosening are unstable, and that continued protein synthesis is necessary to maintain the wall loosening process.     

pH-Dependent Interactions between Pea Cell Wall Polymers Possibly Involved in Wall Deposition and Growth

In an effort to detect a pH-dependent release of polymers such as xyloglucans, thought to be involved in auxin-induced cell wall expansion during growth, radioactively labeled cell walls from pea stem tissue were incubated at different pH values, and changes in water-soluble, ethanol- or trichloroacetic acid-insoluble components were determined. This revealed the occurrence, at neutral pH, of a time- and pH-dependent binding of soluble pectin, in the walls, to a heat-labile, presumably protein, wall component, yielding a trichloroacetic acid-insoluble pectin-protein complex. This reaction, which can also be observed between polymers in water extracts of cell walls, is inhibited at low pH and by Ca²⁺, and appears to be of a physical, possibly lectin-like, nature. Progressive binding of pectin or of the pectin-protein complex to the insoluble wall structure is also observed. These reactions may be involved in wall assembly during its deposition, and may participate in, or be analogous to pH-dependent physical interactions that participate in, wall extension during cell growth.     

Stimulation of elongation growth and xyloglucan breakdown in Arabidopsis hypocotyls under microgravity conditions in space

Seedlings of Arabidopsis thaliana (L.) Heynh. (ecotype Columbia and an ethylene-resistant mutant etr1-1) were cultivated for 68.5, 91.5 and 136 h on board during the Space Shuttle STS-95 mission, and changes in the elongation growth and the cell wall properties of hypocotyls were analyzed. Elongation growth of dark-grown hypocotyls of both Columbia and etr1-1 was stimulated under microgravity conditions in space. There were no clear differences in the degree of growth stimulation between Columbia and etr1-1, indicating that the ethylene level was not abnormally high in the cultural environment of this space experiment. Microgravity also increased the mechanical extensibility of cell walls in both cultivars, and such an increase was attributed to the increase in the apparent irreversible extensibility. The levels of cell wall polysaccharides per unit length of hypocotyls decreased in space. Microgravity also reduced the weight-average molecular mass of xyloglucans in the hemicellulose-II fraction. Also, the activity of xyloglucan-degrading enzymes extracted from hypocotyl cell walls increased under microgravity conditions. These results suggest that microgravity reduces the molecular mass of xyloglucans by increasing xyloglucan-degrading activity. Modifications of xyloglucan metabolism as well as the thickness of cell wall polysaccharides seem to be involved in an increase in the cell wall extensibility, leading to growth stimulation of Arabidopsis hypocotyls in space.     

Inhibition of cell wall autolysis and auxin-induced elongation of Cicer arietinum epicotyls by β-galactosidase antibodies

Polyclonal antibodies were raised in response to βIII-galactosidase purified from cell wall of Cicer arietinum epicotyls. The antibody preparation generated, bound to βIII protein giving a major protein band in the zone corresponding to M_r 45 000, the molecular mass previously estimated for βIII-galactosidase. These antibodies clearly suppress autolytic reactions in isolated walls of Cicer arietinum epicotyl segments, while the preimmune serum had no effect on autolytic reaction. The results strongly support the idea that the autolytic degradation of the cell wall is carried out by the βIII-galactosidase.
The antibodies against β-galactosidase were also able to inhibit cell wall hydrolysis mediated by both total cell wall protein extracted by LiCl and cell wall hydrolysis mediated by βIII-galactosidase.
Since autolysis is thought to be related to the process of cell wall loosening, the effects of the antibodies against the autolytic enzyme was also tested on epicotyl growth. β-galactosidase antibodies consistently inhibited IAA-induced elongation.     

UDP-Glucose level as a limiting factor for IAA-induced cell elongation in Avena coleoptile segments

The effects of galactose on IAA-induced elongation and endogenous level of UDP-glucose (UDPG) in oat ( Avena sativa L. cv. Victory) coleoptile segments were examined under various growth conditions to see if there was a correlation between the level of UDPG and auxin-induced growth. The following results were obtained:

• (1)

  Galactose (10 m M ) inhibited the auxin-induced cell elongation of oat coleoptile segments after a lag of ca 2 h. Determinations of cell wall polysaccharides and UDP-sugars indicated that galactose, when inhibiting the cell wall polysaccharide synthesis, decreased the level of UDPG but caused an increase in the levels of Gal-1-P and UDP-Gal.
• (2)

  When coleoptile segments treated with IAA and galactose were transferred to galactose-free IAA-solution, the segment elongation was restored and the amounts of cell wall polysaccharides increased. During this period, the amount of UDPG increased and the levels of Gal-1-P and UDP-Gal slightly decreased or leveled off. The UDP-pentoses changed similarly as UDPG did.
• (3)

  Addition of sucrose (30 m M ) enhanced IAA-induced cell elongation and removed growth inhibition by 1 m M galactose. Sucrose increased the amounts of the cell wall polysaccharides and the level of UDPG in the presence or absence of IAA and also counteracted the decrease in UDPG caused by galactose.

These results indicate that the level of UDPG is an important limiting factor for cell wall biosynthesis and, thus, for auxin-induced elongation.