Peter M. Ray

Extent of intracellular pH changes during H(+) extrusion by maize root-tip cells.

Abstract31P-Nuclear-magnetic-resonance spectra of maize (Zea mays L.) root tips, that had been induced to extrude large amounts of H+ in response to fusicoccin (FC) in the presence of potassium salts, indicate that the cytoplasmic pH does not become higher than that of controls. In fact, the cytoplasmic pH may become slightly (approx. 0.1 pH unit) lower in cells extruding H+. Estimations of the buffer capacity of the cells show that without active intracellular pH regulation, H+ extrusion caused by FC would cause the intracellular pH to rise by at least 0.6 pH unit h-1. Our results indicate that intracellular pH is tightly regulated even during extreme rates of acid extrusion, and that a rise in cytoplasmic pH is not the signal linking H+ extrusion with enhanced organic-acid synthesis or other intracellular responses to H+ pumping.

Polar auxin transport and auxin-induced elongation in the absence of cytoplasmic streaming

SummaryWhen cytoplasmie streaming in oat and maize coleoptile cells is completely inhibited by cytochalasin B (CB), polar transport of auxin (indole-3-acetic acid) continues at a slightly reduced rate. Therefore, cytoplasmic streaming is not required for polar transport. Auxin induces elongation in CB-inhibited coleoptile and pea stem segments, but elongation rate is reduced about 40% by CB. Therefore, stimulation of cytoplasmic streaming cannot be the means by which auxin promotes cell elongation, but streaming may be beneficial to elongation growth although not essential to it. A more severe inhibition of elongation develops after several hours in CB. With coleoptiles this could be due to inhibition of sugar uptake; in pea tissue it may be due to permeability changes and cytoplasmic degeneration. CB does not disorganize or disorient microfilament bundles when it inhibits streaming in maize, but appears instead to cause hypercondensation of microfilament material.

Plant functional types do not predict biomass responses to removal and fertilization in Alaskan tussock tundra

Plant communities in natural ecosystems are changing and species are being lost due to anthropogenic impacts including global warming and increasing nitrogen (N) deposition. We removed dominant species, combinations of species and entire functional types from Alaskan tussock tundra, in the presence and absence of fertilization, to examine the effects of non-random species loss on plant interactions and ecosystem functioning. After 6 years, growth of remaining species had compensated for biomass loss due to removal in all treatments except the combined removal of moss, Betula nana and Ledum palustre (MBL), which removed the most biomass. Total vascular plant production returned to control levels in all removal treatments, including MBL. Inorganic soil nutrient availability, as indexed by resins, returned to control levels in all unfertilized removal treatments, except MBL. Although biomass compensation occurred, the species that provided most of the compensating biomass in any given treatment were not from the same functional type (growth form) as the removed species. This provides empirical evidence that functional types based on effect traits are not the same as functional types based on response to perturbation. Calculations based on redistributing N from the removed species to the remaining species suggested that dominant species from other functional types contributed most of the compensatory biomass. Fertilization did not increase total plant community biomass, because increases in graminoid and deciduous shrub biomass were offset by decreases in evergreen shrub, moss and lichen biomass. Fertilization greatly increased inorganic soil nutrient availability. In fertilized removal treatments, deciduous shrubs and graminoids grew more than expected based on their performance in the fertilized intact community, while evergreen shrubs, mosses and lichens all grew less than expected. Deciduous shrubs performed better than graminoids when B. nana was present, but not when it had been removed. Synthesis. Terrestrial ecosystem response to warmer temperatures and greater nutrient availability in the Arctic may result in vegetative stable-states dominated by either deciduous shrubs or graminoids. The current relative abundance of these dominant growth forms may serve as a predictor for future vegetation composition.

Matrix polysaccharides of oat coleoptile cell walls

Abstract Separation of component polysaccharides in extractable fractions of the noncellulosic matrix of Avena sativa coleoptile cell walls shows that the principal classes of polymers present are glucuronoarabinoxylans (GAX) and iodine-negative hemicellulosic β-glucans. Rhamnogalacturonan is a minor component. GAX contains about 5–10% glucuronic acid and its 4- O -methyl ether, arabinose in amount almost equal to xylose, and a small amount of galactose; some subfractions contained appreciable amounts of glucose and galacturonic acid but these may derive from separate, contaminating polysaccharides. From the sedimentation and diffusion coefficients and intrinsic viscosities of one subfraction each of the GAX and of the hemicellulosic glucan that had been purified to apparent homogeneity by criteria of sedimentation and borate electrophoresis, MWs of about 200 000 were calculated by two methods. The viscosity characteristics and gel-forming ability of the hemicellulosic glucan give evidence of appreciable molecular interactions which suggest that this polymer is an important structural component of the cell wall.

Cooperative action of β-glucan synthetase and UDP-xylose xylosyl transferase of Golgi membranes in the synthesis of xyloglucan-like polysaccharide

Golgi membranes of pea seedling tissue contain a UDP xylose:polysaccharide xylosyl transferase, the action of which is stimulated by UDP glucose. In the presence of both nucleotide-sugars a heteropolysaccharide containing both xylose and glucose (xyloglucan) is produced. Transfer of xylose and glucose units is presumed to be due to separate enzymes, because their properties differ in a number of respects. Xylosyl units appear to be transferred to a glucan core polysaccharide that is produced from UDP glucose by beta-1,4-glucan synthetase. This, rather than cellulose biosynthesis, is inferred to be the in vivo role of Golgi membrane beta-1,4-glucan synthetase.

Structure of hemicellulosic polysaccharides of Avena sativa coleoptile cell walls

Abstract The glycosidic linkage compositions of intact and, in some cases, enzyme-degraded polysaccharides extracted from the cell walls of oat coleoptiles and subsequently purified have been examined. A major component is shown to be a glucuronoarabinoxylan similar in structure to those described for a variety of other monocots. The noncellulosic glucan component is a β-linked polymer containing both 1,4- and 1,3-linked glucosyl residues in a ratio of 2 to 1. Analysis of the oligosaccharide produced by ‘lichenase’ digestion of this β-glucan suggests that the the 1,3- and 1,4-glucosyl linkages repeat in regular fashion. A small amount of xyloglucan polysaccharides like those described for cell walls of dicots was also detected.

Nature of cell-to-cell transfer of auxin in polar transport

SummaryBy application of agar blocks (“side blocks”) against the inner and outer epidermis of maize (Zea mays L.) coleoptiles whose cuticle has been abraded it is found that radioactive auxin in the polar transport stream exchanges rapidly with the tissues free space and therefore does not move confined within the symplast. Polar transport of IAA is demonstrable in Avena coleoptile segments plasmolyzed in 0.5 and 0.7 M mannitol, in which most of the plasmodesmatal connections between successive cells in the polar transport pathway appear to have been broken. We conclude that during polar transport IAA probably moves from cell to cell by crossing the plasmalemmas and the free space between successive cells, rather than via plasmodesmata. Auxin in the polar transport stream exchanges rapidly with side blocks by a cyanide-and azide-insensitive, presumably passive, process. A similarly passive uptake takes place into the cells from an external donor. NPA almost completely inhibits efflux from the polar transport stream even though it does not inhibit uptake; its inhibition of efflux is completely reversed by azide or cyanide. These findings are compatible either with the traditional model of polar transport as passive uptake combined with an active basal efflux pump for IAA, or with the model of purely passive polar transport driven by pH and/or potential differences across the plasma membrane, provided certain ad hoc assumptions are made about the characteristics of the IAA anion carrier that would be operating in either model.

Expression of mung bean pectin acetyl esterase in potato tubers: effect on acetylation of cell wall polymers and tuber mechanical properties

A mung bean (Vigna radiata) pectin acetyl esterase (CAA67728) was heterologously expressed in tubers of potato (Solanum tuberosum) under the control of the granule-bound starch synthase promoter or the patatin promoter in order to probe the significance of O-acetylation on cell wall and tissue properties. The recombinant tubers showed no apparent macroscopic phenotype. The enzyme was recovered from transgenic tubers using a high ionic strength buffer and the extract was active against a range of pectic substrates. Partial in vivo de-acetylation of cell wall polysaccharides occurred in the transformants, as shown by a 39% decrease in the degree of acetylation (DA) of tuber cell wall material (CWM). Treatment of CWM using a combination of endo-polygalacturonase and pectin methyl esterase extracted more pectin polymers from the transformed tissue compared to wild type. The largest effect of the pectin acetyl esterase (68% decrease in DA) was seen in the residue from this extraction, suggesting that the enzyme is preferentially active on acetylated pectin that is tightly bound to the cell wall. The effects of acetylation on tuber mechanical properties were investigated by tests of failure under compression and by determination of viscoelastic relaxation spectra. These tests suggested that de-acetylation resulted in a stiffer tuber tissue and a stronger cell wall matrix, as a result of changes to a rapidly relaxing viscoelastic component. These results are discussed in relation to the role of pectin acetylation in primary cell walls and its implications for industrial uses of potato fibres.

A 55 kDa plasma membrane‐associated polypeptide is involved in β‐1,3‐glucan synthase activity in pea tissue

By glycerol gradient centrifugation of a detergent‐solubilized plasma membrane fraction from pea tissue, we find a polypeptide of 55 kDa that copurifies with β‐1,3‐glucan synthase activity. An antiserum against this polypeptide adsorbs glucan synthase activity and the 55 kDa polypeptide from digitonin‐solubilized plasma membrane. These results indicate that the 55 kDA polypeptide is involved in pea β‐1,3‐glucan synthase activity.

Inhibition by light of growth and Golgi-localized glucan synthetase in the maize mesocotyl

When dark-grown maize (Zea mays L.) seedlings were exposed to red light (R), Golgi-localized glucan synthetase activity in the mesocotyl began to decrease within 1 h, and fell by approx. 70% in 12 h. The response required at least 10-2 μmol m-2 R and saturated at 100 μmol m-2. Far-red light (FR) alone inhibited glucan synthetase, and FR reversed the inhibition by R back to the level caused by FR alone. Density gradient fractionation indicated that of the major membrane markers only the Golgi-localized glucan-synthetase activity was affected by R. Golgi-localized latent inosine-diphosphatase activity was unaffected. The kinetics of the response, the photon fluence dependence, and the reversibility by FR all correlated with the inhibition by light of elongation of the mesocotyl, indicating that light inhibits growth and glucan synthetase activity by a similar mechanism.