Effect of 2-deoxyglucose on cell wall formation in Saccharomyces cerevisiae and its relation to cell growth inhibition

The growth inhibition and the lysis of Saccharomyces cerevisiae caused by 2-deoxy-d-glucose (2-DG) were shown to be a consequence of unbalanced cellular growth and division. The lysis, but not the repression of growth and osmotic fragility of cells, could be suppressed by the addition of mannitol as an osmotic stabilizer. This result, as well as the morphological changes observed in the cells and changes in the chemical composition of the cell walls, showed that S. cerevisiae grown in the presence of 2-DG formed weakened cell walls responsible for the osmotic fragility. Evidence is presented for the first time demonstrating the incorporation of 2-DG into yeast cell wall material. Other data suggest that the inhibition of yeast growth by 2-DG results from an interference of phosphorylated metabolites of 2-DG with metabolic processes of glucose and mannose involved in the synthesis of structural cell wall polysaccharides.     

Hypocotyl growth of Pinus pinaster seedlings. Changes in α-cellulose, and in pectic and hemicellulosic polysaccharides

Lorences, E. P., Suárez, L. and Zarra, I. 1987. Hypocotyl growth of Pinus pinaster seedlings. Changes in a-cellulose, and in pectic and hemicellulosic polysaccharides.
The changes in pectic and hemicellulosic polysaccharides of hypocotyl cell walls during the growth of intact seedlings of Pinus pinaster Aiton were investigated, α -Cellulose and the water-soluble hemicellulose presented the most conspicuous changes during hypocotyl growth. The relative amount of the water-soluble hemicellulose decreased from day 7 to day 13 when hypocotyls were in the rapid growth phase, and stabilized when hypocotyl growth ceased. In this fraction, the relative amount of non-cellulosic glucose decreased dramatically during hypocotyl growth, while the relative amount of xylose increased. We suggest that these changes may be due to partial degradation of xyloglucan present in the water_:soluble hemicellulose fraction, accompanied by the synthesis of a xylan.     

Locus-specific Changes in Cell Wall Composition Characteristic of Osmotic Mutants of Neurospora crassa

The osmotic phenotype of Neurospora crassa is characterized by inhibition of growth at high osmolalities of growth medium. Mutations at six osmotic loci of linkage group I were examined to assess the biochemical and physiological effects of these mutants. Isolated cell walls from 23 osmotic strains were compared with the wild type with regard to quantitative levels of the following components: percentage of total dry weight, total glucose, alkali-soluble glucose, nonglucose carbohydrates, amino acids, glucosamine, galactosamine, and a compound tentatively identified as quinovosamine. The last component has not previously been observed in N. crassa cell walls. Although the cell wall dry weight content of osmotic mutants was not altered, walls isolated from all of the osmotic strains had less alkali-insoluble glucose than those from the wild type. In addition, all of the loci except cut exhibited other consistent differences from the wild type. The os-1, os-3, and os-5 mutants had low levels of alkali-soluble glucose. The os-3 and os-5 mutants had high levels of nonglucose carbohydrates, and flm-2 had a low level of nonglucose carbohydrates. The os-4 mutants had low levels of galactosamine and amino acids and high levels alkali-soluble glucose. An os-1 mutant, B135, produced less of the whole alkali-soluble fraction of the cell wall.     

Cell elongation in Arabidopsis hypocotyls involves dynamic changes in cell wall thickness

Field-emission scanning electron microscopy was used to measure wall thicknesses of different cell types in freeze-fractured hypocotyls of Arabidopsis thaliana. Measurements of uronic acid content, wall mass, and wall volume suggest that cell wall biosynthesis in this organ does not always keep pace with, and is not always tightly coupled to, elongation. In light-grown hypocotyls, walls thicken, maintain a constant thickness, or become thinner during elongation, depending upon the cell type and the stage of growth. In light-grown hypocotyls, exogenous gibberellic acid represses the extent of thickening and promotes cell elongation by both wall thinning and increased anisotropy during the early stages of hypocotyl elongation, and by increased wall deposition in the latter stages. Dark-grown hypocotyls, in the 48 h period between cold imbibition and seedling emergence, deposit very thick walls that subsequently thin in a narrow developmental window as the hypocotyl rapidly elongates. The rate of wall deposition is then maintained and keeps pace with cell elongation. The outer epidermal wall is always the thickest ( approximately 1 mum) whereas the thinnest walls, about 50 nm, are found in inner cell layers. It is concluded that control of wall thickness in different cell types is tightly regulated during hypocotyl development, and that wall deposition and cell elongation are not invariably coupled.     

Cell wall and cytoskeleton reorganization as the response to hyperosmotic shock in Saccharomyces cerevisiae

Transfer of exponentially growing cells of the yeast Saccharomyces cerevisiae to hyperosmotic growth medium containing 0.7-1 M KCl, 1 M mannitol, and/or 1 M glycerol caused cessation of yeast growth for about 2 h; thereafter, growth resumed at almost the original rate. During this time, formation of fluorescent patches on the inner surface of cell walls stained with Primulin or Calcofluor white was observed. The fluorescent patches also formed in solutions of KCl or when synthesis of the cell wall was blocked with cycloheximide and/or 2-deoxyglucose. The patches gradually disappeared as the cells resumed growth, and the new buds had smooth cell walls. Electron microscopy of freeze-etched replicas of osmotically stressed cells revealed deep plasma membrane invaginations filled from the periplasmic side with an amorphous cell wall material that appeared to correspond to the fluorescent patches on the cell surface. The rate of incorporation of D-[U-14C]glucose from the growth medium into the individual cell wall polysaccharides during osmotic shock followed the growth kinetics. No differences in cell wall composition between osmotically stressed yeast and control cells were found. Hyperosmotic shock caused changes in cytoskeletal elements, as demonstrated by the disappearance of microtubules and actin microfilaments. After 2-3 h in hyperosmotic medium, both microtubules and microfilaments regenerated to their original polarized forms and the actin patches resumed their positions at the apices of growing buds. The response of S. cerevisiae strains with mutations in the osmosensing pathway genes hog1 and pbs2 to hyperosmotic shock was similar to that of the wild-type strain. We conclude that, besides causing a temporary disassembling of the cytoskeleton, hyperosmotic shock induces a change in the organization of the cell wall, apparently resulting from the displacement of periplasmic and cell wall matrix material into invaginations of the plasma membrane created by the plasmolysis.     

Cell wall water content has a direct effect on extensibility in growing hypocotyls of sunflower (Helianthus annuus L.)

It has been proposed that spacing between cellulose microfibrils within plant cell walls may be an important determinant of their mechanical properties. A consequence of this hypothesis is that the water content of cell walls may alter their extensibility and that low water potentials may directly reduce growth rates by reducing cell wall spacing. This paper describes a number of experiments in which the water potential of frozen and thawed growing hypocotyls of sunflower (Helianthus annuus L.) were altered using solutions of high molecular weight polyethylene glycol (PEG) or Dextran while their extension under constant stress was monitored using a creep extensiometer (frozen and thawed tissue was used to avoid confounding effects of turgor or active responses to the treatments). Clear reductions in extensibility were observed using both PEG and Dextran, with effects observed in hypocotyl segments treated with PEG 35 000 solutions with osmotic pressures of > or =0.21 MPa suggesting that the relatively mild stresses required to reduce water potentials of plants in vivo by 0.21 MPa may be sufficient to reduce growth rates via a direct effect on wall extensibility. It is noted, therefore, that the water binding capacity of plant cell walls may be of ecophysiological importance. Measurements of cell walls of sunflower hypocotyls using scanning electron microscopy confirmed that treatment of hypocotyls with PEG solutions reduced wall thickness, supporting the hypothesis that the spatial constraint of movement of cellulose microfibrils affects the mechanical properties of the cell wall.     

Cell-wall synthesis and elongation growth in hypocotyls of Helianthus annuus L.

The relationship between growth and increase in cell-wall material (wall synthesis) was investigated in hypocotyls of sunflower seedlings (Helianthus annuus L.) that were either grown in the dark or irradiated with continuous white light (WL). The peripheral three to four cell layers comprised 30–50% of the entire wall material of the hypocotyl. The increase in wall material during growth in the dark and WL, respectively, was larger in the inner tissues than in the peripheral cell layers. The wall mass per length decreased continuously, indicating that wall thinning occurs during growth of the hypocotyl. When dark-grown seedlings were transfered to WL, a 70% inhibition of growth was observed, but the increase in wall mass was unaffected. Likewise, the composition of the cell walls (cellulose, hemicellulose, pectic substances) was not affected by WL irradiation. Upon transfer of dark-grown seedlings into WL a drastic increase in wall thickness and a concomitant decrease in cell-wall plasticity was measured. The results indicate that cell-wall synthesis and cell elongation are independent processes and that, as a result, WL irradiation of etiolated hypocotyls leads to a thickening and mechanical stiffening of the cell walls.     

Growth capacity in response to auxin of coleoptile segments of normal and dwarf rice strains

Auxin-induced growth, epidermal cell length, cellular osmotic potential, and cell wall composition of coleoptile segments excised from one normal and two dwarf rice strains were studied 2, 3, 4, and 5 days after soaking. The auxin-induced growth was higher at the early stages of coleoptile growth and decreased with age, being always higher in normal than in the two dwarf strains. A good correlation between auxin-induced growth and auxin-induced decrease in the minimum stress-relaxation time has been found, suggesting that the different growth capacity in response to auxin among the three different strains is due to differences in the structure of their cell walls. In fact, cell wall analysis revealed that (1) the relative α-cellulose content of the cell walls was higher in the two dwarf strains than in the normal one, and (2) the auxin-induced decrease in noncellulosic glucose was high, compared with dwarf strains, in the normal strain, which showed the higher auxin-induced growth, showing a highly significant correlation between the decrease in noncellulosic glucose and the growth in response to auxin. Thus, the different growth between normal and dwarf strains might be attributed to their different capacity to degrade β-glucan of their cell walls.     

Solute production and net wall synthesis in the growing and non-growing cells of gravistimulated sunflower hypocotyls

Solute generation and cell wall synthesis were examined in sunflower hypocotyl peripheral layers, the growth rate of which had been altered by gravistimulation. Measurements of both the concentrations of the major solutes and the osmotic potential showed that although upper cells stopped growing, the solute levels in these cells continued to increase at rates comparable to those in lower cells. This indicated that altered growth rates, generated during gravicurvature, are not based on solute generation but must result from cell wall changes. Gravimetric and precursor incorporation studies showed that net wall synthesis continued in upper cells despite their lack of growth. An ultrastructural study of the epidermal cells on the uppermost (non-elongating) and lowermost (elongating) surfaces of horizontal cucumber hypocotyls showed that the relative amounts of the various membrane fractions were similar in upper and lower cells despite their very different growth rates.     

Interaction between wall deposition and cell elongation in dark-grown hypocotyl cells in Arabidopsis

A central problem in plant biology is how cell expansion is coordinated with wall synthesis. We have studied growth and wall deposition in epidermal cells of dark-grown Arabidopsis hypocotyls. Cells elongated in a biphasic pattern, slowly first and rapidly thereafter. The growth acceleration was initiated at the hypocotyl base and propagated acropetally. Using transmission and scanning electron microscopy, we analyzed walls in slowly and rapidly growing cells in 4-d-old dark-grown seedlings. We observed thick walls in slowly growing cells and thin walls in rapidly growing cells, which indicates that the rate of cell wall synthesis was not coupled to the cell elongation rate. The thick walls showed a polylamellated architecture, whereas polysaccharides in thin walls were axially oriented. Interestingly, innermost cellulose microfibrils were transversely oriented in both slowly and rapidly growing cells. This suggested that transversely deposited microfibrils reoriented in deeper layers of the expanding wall. No growth acceleration, only slow growth, was observed in the cellulose synthase mutant cesA6(prc1-1) or in seedlings, which had been treated with the cellulose synthesis inhibitor isoxaben. In these seedlings, innermost microfibrils were transversely oriented and not randomized as has been reported for other cellulose-deficient mutants or following treatment with dichlorobenzonitrile. Interestingly, isoxaben treatment after the initiation of the growth acceleration in the hypocotyl did not affect subsequent cell elongation. Together, these results show that rapid cell elongation, which involves extensive remodeling of the cell wall polymer network, depends on normal cellulose deposition during the slow growth phase.     

Inhibition of Pisum sativum epicotyl elongation by white light – Different effects of light on the mechanical properties of cell walls in the epidermal and inner tissues

White fluorescent light (5 W m⁻²) inhibited subhook growth in derooted Alaska pea cuttings. In the inner tissue of the subhook, it inhibited the increase in osmotic potential during 18 h incubation. In the epidermis, on the other hand, light did not affect the osmotic potential. Light increased the minimum-stress relaxation time (T₀) of the inner tissue cell walls, but did not change T₀ of the epidermal cell wall. Light decreased tissue stress determined by the split test and the ability of the inner tissue to extend by water absorption. The short-term light effect on subhook growth. T₀, and the tissue stress almost disappeared when pea cuttings were transferred to darkness. These facts suggest that light changes the mechanical properties of the cell wall in the inner tissue of shoots, and decreases tissue stress, which is considered to be the driving force of shoot growth.     

Changes in osmotic pressure and cell wall properties during auxin- and ethylene-induced growth of intact coleoptiles of rice

Indole-3-acetic acid and 1-aminocyclopropane-1-carboxylic acid, the precursor of ethylene, stimulated elongation of coleoptiles of seedlings of intact rice ( Oryza sativa L. cv. Sasanishiki) submerged in buffer solution with constant air-bubbling. The osmotic pressure of the cell sap decreased during elongation of coleoptiles. In the presence of 30 μ M aminooxyacetic acid, an inhibitor of ethylene biosynthesis, in-dole-3-acetic acid at 30 μ M accelerated the decrease in the osmotic pressure in the early stage of growth. 1-Aminocyclopropane-1-carboxylic acid at 30 μ M did not influence the decrease in the osmotic pressure.
Both indole-3-acetic acid and 1-aminocyclopropane-1-carboxyIic acid decreased the minimum stress-relaxation time and the relaxation rate of the cell wall, suggesting that both auxin and ethylene induce elongation of rice coleoptiles by stimulating cell wall loosening. These growth regulators caused an increase in the level of glucose in hemicelluloses in the early stage of growth and a decrease in the level in the subsequent last growth phase. Indole-3-acetic acid decreased the hydroxyproline and glucosamine levels per unit dry weight of the cell wall. These changes in the level of cell wall components may be associated with the changes in the mechanical properties of the cell walls caused by auxin and ethylene.     

Viscoelastic versus plastic cell wall extensibility in growing seedling organs: a contribution to avoid some misconceptions

In a recent publication (Kutschera, 1996), it was reported thatthe cell walls of growing rye coleoptiles exhibit irreversible(plastic) extensibility in a rheological extension test. Basicallysimilar measurements with cell walls of maize coleoptiles hadpreviously shown that the apparent plastic extensibility determinedin this material is in reality due to the slowly reversible(viscoelastic) extensibility of the walls. A recent reinvestigationof this discrepancy showed that rye coleoptile walls also behaveas a perfectly viscoelastic material if precautions are takento prevent measuring artefacts. Similar results were obtainedwith cell walls from the growing zone of various other seedlingorgans (maize mesocotyl, maize root, cucumber hypocotyl). Itis concluded that plastic extensibility has not yet been convincinglydemonstrated by rheological tests that determine the intrinsicmaterial properties of cell walls. Reported changes in mechanicalmaterial properties of cell walls produced by growth-controllingfactors such as auxin or light may generally be attributed tochanges in viscoelasticity which are not directly related tothe chemo-rheological processes controlling wall extension ofgrowing cells. Key words: Cell wall extensibility, extension growth, plastic cell wall extensibility, viscoelastic cell wall extensibility     

Loss of capacity for acid-induced wall loosening as the principal cause of the cessation of cell enlargement in light-grown bean leaves

Cell enlargement in primary leaves of bean (Phaseolus vulgaris L.) can be induced, free of cell divisions, by exposure of 10-d-old, red-light-grown seedlings to white light. The absolute rate of leaf expansion increases until day 12, then decreases until the leaves reached mature size on day 18. The cause of the reduction in growth rate following day 12 has been investigated. Turgor calculated from measurements of leaf water and osmotic potential fell from 6.5 to 3.5 bar before day 12, but remained constant thereafter. The decline of growth after day 12 is not caused by a decrease in turgor. On the other hand, Instron-measured cell-wall extensibility decreased in parallel with growth rate after day 12. Two parameters influencing extensibility were examined. Light-induced acidification of cell walls, which has been shown to initiate wall extension, remained constant over the growth period (days 10–18). Furthermore, cells of any age could be stimulated to excrete H⁺ by fusicoccin. However, older tissue was not able to grow in response to fusicoccin or light. Measurements of acid-induced extension on preparations of isolated cell walls showed that as cells matured, the cell walls became less able to extend when acidified. These data indicate that it is a decline in the capacity for acid-induced wall loosening that reduces wall extensibility and thus cell enlargement in maturing leaves.Abbreviations and symbols FC fusicoccin - P turgor pressure - RL red light - WEx wall extensibility - WL white light - P _w leaf water potential - P _s osmotic potential     

Chromosaponin I increases mechanical extensibility of lettuce root cell walls

Chromosaponin I (CSI), at 3 m M , stimulates the growth of lettuce roots ( Lactuca sativa L. cv. Grand Rapids) with increasing fresh weight and decreasing root diameter compared with control. To analyze the mechanism of action of CSI, mechanical properties of lettuce root cell walls were examined with a tensiometer and the osmotic potential of the cell sap was measured with a vapor pressure osmometer. The mechanical extensibility of the cell wall was increased by CSI treatment, while the osmotic potential remained constant. Under osmotic stress, through addition of 0.225 M mannitol, the mechanical extensibility of the cell wall was increased before stimulation of growth was observed. These results suggest that cell wall-loosening is involved in the growth stimulation induced by CSI.     

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 Zeatin-Induced Growth of Cucumber Cotyledons by Sulfite Ions

The inhibitory effects of sulfite ions on zeatin-induced cellexpansion in cotyledons excised from dark-grown seedlings ofcucumber (Cucumis sativus L.) were examined. With 50 µMzeatin the growth rate in white light was about twice that ofthe control. Addition of Na₂SO₃ in the growth medium inhibitedthe zeatin-induced growth of cotyledons. Zeatin-treatment increasedthe osmotic potential in cell sap of cotyledons, while sulfitedecreased it. These treatments had no significant effect onpotassium concentration. Sulfite inhibited the zeatin-inducedincrease in contents of fructose and glucose, but did not affectsucrose content. The relative contents of non-cellulosic constituentsof cell walls fell with the advance of culture. This decreasewas repressed by sulfite, indicating that inhibition of expansiongrowth in cucumber cotyledons by sulfite ions was the resultof alterations in the cell wall structure due to changes inthe cell wall metabolism. (Received June 12, 1984; Accepted October 24, 1984)     

Changes in ascorbic acid levels in apoplastic fluid during growth of pine hypocotyls. Effect on peroxidase activities associated with cell walls

The apoplastic fluid of pine ( Pinus pinaster Aiton) hypocotyls contains ascorbic acid (AA) and dehydroascorbic acid (DHA). The amounts of ascorbic and dehydroascorbic acids were in the nmol (g fresh weight)⁻¹ range and decreased with the hypocotyl age as well as along the hypocotyl axis. The ratio AA/(AA+DHA) also decreased with the hypocotyl age and along the hypocotyl. Both ascorbic oxidase and peroxidase activity against ascorbic acid showed very low activity not only in the apoplastic fluid but also in the fractions ionically and covalently bound to the cell walls. However, the peroxidase activity in the three abovementioned fractions was strongly increased in the presence of ferulic acid. That stimulation effect increased with the hypocotyl age and from the apical towards the basal region of the hypocotyls of 10-day-old seedlings. Furthermore, the oxidation of ferulic acid by apoplastic and ionically- and covalently-bound peroxidases was inhibited by ascorbic acid as long as ascorbate was available. A regulatory role of apoplastic ascorbic acid levels in the formation of dehydrodiferulic bridges between wall polysaccharides catalysed by cell wall peroxidases and thus in the cell wall stiffening during plant growth is proposed.     

Cell wall functions in growth and development —a physical and chemical point of view

The plant cell changes its cell wall architecture during growth and development through synthesis and degradation of wall polysaccharides. Changes of chemical components in the cell wall include not only the synthesis and degradation but also the shift of molecular-weight distribution of certain species of the component polysaccharides. The changes in chemical structure, in turn lead to alteration of physical properties of the cell wall. Changes of physical parameters of cell walls obtained by a physical method accord with the biochemical degradation of polysaccharides. The changes in chemical structures of the cell wall are regulated by plant hormones, stress signals and gene expression. The physical and chemical studies of the cell wall have disclosed that degradation and/or depolymerization of wall polysaccahrides causes decrease in viscosity of the cell wall, leading further extension of the cell wall even under the unchanged osmotic relation. Furthermore, cell walls of outer and inner tissues play different regulatory roles in tissue growth and stem strength was governed by the number of cellulose molecules in the cell wall. Recipient of the Botanical Society Award for Young Scientists, 1990.     

Quantitative and qualitative changes in cell wall polysaccharides in relation to growth and cell wall loosening in Lactuca sativa hypocotyls

The correlation between hypocotyl elongation, cell wall loosening and changes in cell wall polysaccharides was studied using intact lettuce seedlings grown in the dark or in light together with gibberellic acid (GA) and/or 5-fluorodeoxyuridine (FUDR). The following results were obtained:
1) The production of pectic, hemicellulosic and cellulosic polysaccharides look place in parallel with hypocotyl elongation, which was substantially affected by different growth conditions.
2) The mole percentage sugar composition of pectic and hemicellulosic polysaccharides changed in response to dark, light, GA, or FUDR treatments.
3) The amounts of xylose and glucose in hemicellulosic polysaccharides and those of galactosc, rhumnose and uronic acid in pectic polysaccharides increased in parallel with hypocotyl elongation.
4) Statistical analysis of the quantitative relationship between sugars composing polysaccharides revealed that the uronic acid content changed in parallel with those of rhamnose and galactose in pectic polysaccharides, and the content of xylose varied in parallel with those of fucose and glucose.
5) The content of hemicellulosic polysaccharides was correlated with cell wall loosening represented by a decrease in the minimum stress-relaxation time. Changes in the stress-relaxation time value were correlated with those in the content of araltinose and galactose in hemicellulosic polysaccharides.
Based on these results, the relationship between hypocotyl elongation, changes in cell wall polysaccharides, and cell wall loosening is discussed with respect to the effect of GA and FUDR on hypocotyl elongation.