Analysis of the Growth Response of Air-Grown Rice Coleoptiles to Submergence

The effect of submergence of air-grown rice seedlings (Oryza sativa L. var. Sasanishiki) on coleoptile growth and ultrastructure, extensibility and chemical composition of the cell walls was investigated. The lag-time between start of submergence and the onset of the enhancement of growth was less than 4 h. The growth response was associated with a drastic thinning of the cell walls and an increase in wall extensibility. At the outer epidermal wall of both air-grown and submerged coleoptiles electron-dense (osmiophilic) particles were detected. During submergence, the net accumulation of cellulose and hemicellulose was reduced, but the increase in pectic substances was unaffected. Submergence caused an 80% inhibition of the net accumulation of wall-bound phenolics (ferulic- and diferulic acid) compared with air-grown controls. The osmotic concentration of the tissue saps was not affected by submergence. Our results support the hypothesis that rapid coleoptile elongation under water is caused by an inhibition of the formation of phenolic cross-links between matrix polysaccharides via diferulate, which results in a mechanical stiffening of the cell walls in the air-grown coleoptile.     

Levels of {beta}-Glucan and Lignin in Elongating Internodes of Deepwater Rice

Partial submergence or treatment with either ethylene or gibberellicacid (GA₃ induces rapid growth in deepwater rice (Oryza sativaL.). We correlated the synthesis of two cell wall componentswith two phases of internodal elongation, namely (13,14)-ß-glucanformation with cell elongation and lignification with differentiationof the secondary cell wall and cessation of growth. The contentof ß-glucan was highest in the zone of cell elongationin internodes of air-grown plants and plants that were inducedto grow rapidly by submergence. In the intercalary meristemand in the differentiation zone of the internode, ß-glucanlevels were ca. 70% lower than in the zone of cell elongation.The outer cell layers, enriched in epidermis, contained moreß-glucan in submerged, rapidly growing internodesthan in air-grown, control internodes. The ß-glucancontent of the inner, parenchymal tissue was unaffected or slightlylowered by submergence. The epidermis appears to be the growth-limitingstructure of rapidly growing rice internodes. We hypothesizethat elevated levels of ß-glucan contribute to elongationgrowth by increasing the extensibility of the cell wall. Lignificationwas monitored by measuring the content of lignin and the activitiesof two enzymes of the lignin biosynthetic pathway, coniferylalcohol dehydrogenase (CAD) and phenylalanine ammonia-lyase(PAL), in growing and non-growing regions of the internode.Using submerged whole plants and GA₃-treated excised stem segments,we showed that lignin content and CAD activity were up to sixfoldlower in newly formed internodal tissue of rapidly growing ricethan in slowly growing tissue. No differences were observedin parts of the internode that had been formed prior to inductionof growth. PAL activity was reduced throughout the internodeof submerged plants. We conclude that lignification is one ofthe processes that is suppressed to permit rapid growth. ¹ This work was supported by the National Science Foundationthrough grants No. DCB-8718873 and DCB-9103747 and by the Departmentof Energy through grant No. DE-FGO2-90ER20021. M.S. was therecipient of a fellowship from the Max Kade Foundation.     

Changes in cell wall polysaccharides in the internodes of submerged floating rice

In excised stem segments of floating rice (Oryza sativa L.), as well as in intact plants, submergence greatly stimulates the elongation of internodes. The differences in the composition of cell wall polysaccharides along the highest internodes of submerged and air-grown stem segments were examined. The newly elongated parts of internodes that had been submerged for two days contained considerably less cellulosic and noncellulosic polysaccharides than air-grown internodes, an indication that the cell walls of the newly elongated parts of submerged internodes are extremely thin. In the young parts of both air-grown and submerged internodes, the relative amounts of noncellulosic polysaccharides were equal to those of -cellulose, whereas the relative amounts of -cellulose were higher than those of noncellulosic polysaccharides in the upper, old parts. In the cell-elongation zones of both air-grown and submerged internodes, glucose was predominant among the noncellulosic neutral sugars of cell wall. The relative amount of glucose in noncellulosic neutral sugars decreased toward the upper, old parts of internodes, whereas that of xylose increased.     

The biophysical basis of elongation growth in internodes of deepwater rice

Partial submergence induces rapid internodal elongation in deepwater rice (Oryza sativa L., cv Habiganj Aman II). We measured in vivo extensibility, tissue tension, hydraulic conductance and osmotic potential in the region of cell elongation in the uppermost internode. The in vivo extensibility of the internode, measured by stretching of living tissue with a custom-made constant stress extensiometer, rose rapidly following submergence of the plant. Both the elastic (E_el) and plastic (E_pl) extensibility increased when growth of the internode was induced. The submerged internode displayed tissue tension (elastic outward bending of longitudinally split internode sections); in air-grown control internodes, no such bending occurred. The hydraulic conductance, estimated from the kinetics of tissue shrinkage in 0.5 molar mannitol and subsequent swelling in distilled water, was not changed by submergence. The osmotic potential, measured with a dew-point hygrometer using frozen-thawed tissue, was only 18% less negative in the submerged internode than in the air-grown control. This indicates that osmoregulation takes place in rapidly elongating rice internodes. We suggest that the rapid expansion of the newly formed internodal cells of submerged plants is controlled by the yielding properties (E_pl) of the cell walls. Experiments with excised stem sections indicate that gibberellin is involved in increasing the E_pl of the elongating cell walls.     

Mobilization of Starch after Submergence of Air-Grown Rice Coleoptiles. Implications for Growth and Gravitropism

Submergence of air-grown rice seedlings (Oryza sativa L. var. Sasanishiki) induces elongation of the coleoptile. We investigated whether rapid underwater extension is associated with a loss of starch. After 1 d of submergence the starch content was reduced by 70%. This loss of reserve carbohydrate was accompanied by a 38% increase in the concentration of glucose in the cell sap of the coleoptiles. The submerged (starch-depleted) coleoptiles had a slower negative gravitropism than the air-grown controls, although the rate of elongation in the horizontal position was not impaired. We conclude that the submergence-induced mobilization of starch provides substrates and osmotica for the rapidly growing cells. In addition, our results indicate that a full complement of starch is necessary for normal gravitropism in the rice coleoptile.     

Characterization of Growth-related Osmiophilic Particles in Corn Coleoptiles and Deepwater Rice Internodes

Osmiophilic particles are secreted from the epidermal cellsinto the outer epidermal cell wall of deepwater rice internodesand corn coleoptiles that have been induced to elongate rapidlyby treatment with gibberellin or auxin, respectively. The diameterof the osmiophilic particles is 80 to 100 nm in deepwater riceand up to 300 nm in corn coleoptiles. Because these particlesare secreted to the outer epidermal wall only, they may containeither cell wall components that are specific for the outerepidermal wall or components of the cuticle that coats the outerepidermal wall. Monensin inhibited the appearance of these particles,indicating that they are derived from the Golgi apparatus. Anattempt was made to identify the contents of the osmiophilicparticles by enzyme-gold or antibody-gold labelling. Cutinase-goldaccumulated mostly in the region of the cell wall just belowthe cuticle. The osmiophilic particles became densely labelledafter incubation with proteinase K-gold, indicating that theyare, at least in part, proteinaceous. In excised tissue andultrathin sections treated with proteinase K, the number ofosmiophilic particles was reduced, while glucanase and cutinasetreatments were without effect. Antibodies against lipid transferprotein, an extensin-like protein, an arabinogalactan protein,a peroxidase, and expansin bound to the cell wall or plasmamembrane but not to the osmiophilic particles.Copyright 1994,1999 Academic Press Epidermal cell wall, gibberellin, indoleacetic acid, osmiophilic particles, Oryza sativa, Zea mays     

A novel cottong ovule culture: Induction, growth, and characterization of submerged cotton fibers (Gossypium hirsutum L.)

Summary The growth of submerged cotton (Gossypium hirsutum L.) fibers from cultured ovules has been investigated. The results indicate that exogenous plant hormone levels regulate the induction of submerged fiber growth. The age of ovules at induction is also important. Cell diameter, wall thickness, and cell length of submerged fibers were measured and compared with air-grown fibers and fibers grown in vivo (produced by cotton plants grown in the greenhouse). Various cellwall thickening patterns were observed among submerged fibers, while only one predominant cell-wall deposition pattern was produced in air-grown fibers and in fibers produced in vivo. The diameter of submerged fibers was about the same as that of air-grown fibers but about 22% less than that of fibers grown, in vivo. It appears that the secondary cell wall thickenings are initiated earlier in submerged fibers. The cell-wall thickness of submerged fibers, at 41 d post anthesis (DPA), was 51% greater than that of fibers grown in vivo, whereas the cell-wall thickness of air-grown fibers was 42% less than that of fibers produced in vivo. The cell length of submerged fibers was approximately half that of fibers grown in vivo. and the air-grown fiber length was about two-thirds of fibers grown in vivo. The age of ovules at induction affects the outcome of the air-grown fiber-cell length, but does not appear to affect the length of submerged fiber cells. To produce submerged fiber growth, we found that the optimal age of ovules at induction was 0 DPA, and the optimal medium (with a GA₃ of 0.5 μM and an IAA range of 5-20 μM) depends on the time of ovule induction (−2 to+2DPA). We conclude that conditions leading to submerged cotton fiber growth have great potential for (a) direct monitoring of growth and making precise, detailed measurements during fiber growth and development; (b) producing cellulose and fibers in vitro more efficiently than earlier ovule-culture methods; and (c) using these unique cultures to obtain a better understanding of signal transduction and gene expression leading to growth, development, and programmed cell death in the life history of the cotton fiber.     

Submergence Enhances Expression of a Gene Encoding 1-Aminocyclopropane-1-Carboxylate Oxidase in Deepwater Rice

Partial submergence greatly stimulates internodal growth indeepwater rice (Oryza sativa L.). Previous work has shown thatthe effect of submergence is, at least in part, mediated byethylene, which accumulates in the air spaces of submerged internodes.To investigate the expression of the genes encoding ethylenebiosynthetic enzymes during accelerated growth of deepwaterrice, we cloned a 1-aminocyclopropane- 1-carboxylate (ACC) oxidasecDNA (OSACO1) from internodes of submerged plants and measuredthe activity of the enzyme in tissue extracts with an improvedassay. We found an increase in ACC oxidase mRNA levels and enzymeactivity after 4 to 24 h of submergence. Thus, it is likelythat ethylene biosynthesis in internodes of deepwater rice iscontrolled, at least in part, at the level of ACC oxidase. (Received January 6, 1996; Accepted April 6, 1996)     

Effect of submergence on the cell wall composition of deep-water rice internodes

The cell wall composition of internodes of deep-water rice plants (Oryza sativa L. cv Habiganj Aman II) which were induced to grow rapidly by submergence in water was compared to that of nonsubmerged plants which grew slowly. No differences could be detected in cellulose, uronic acid, and lignin content expressed on a dry weight basis. Cell wall preparations of rapidly growing, submerged internodes contained more hydroxyproline and had a higher hydration capacity than those of control internodes. The silicon content of submerged rice internodes was considerably lower than that of air-grown plants. The role of silicon as a structural component of the cell wall of grasses is discussed in relation to lodging of deep-water rice plants after the flood waters have receded.     

Expansins and Internodal Growth of Deepwater Rice

The distribution and activity of the cell wall-loosening protein expansin is correlated with internodal growth in deepwater rice (Oryza sativa L.). Acid-induced extension of native cell walls and reconstituted extension of boiled cell walls were confined to the growing region of the internode, i.e. to the intercalary meristem (IM) and the elongation zone. Immunolocalization by tissue printing and immunoblot analysis, using antibody against cucumber expansin 29 as a probe, confirmed that rice expansin occurred primarily in the IM and elongation zone. Rice expansin was localized mainly around the vascular bundles at the base of the IM and along the inner epidermal cell layer surrounding the internodal cavity. Submergence greatly promoted the growth of rice internodes, and cell walls of submerged internodes extended much more in response to acidification than did the cell walls of air-grown internodes. Susceptibility of cell walls to added expansin was also increased in submerged internodes, and analysis by immunoblotting showed that cell walls of submerged internodes contained more expansin than did cell walls of air-grown internodes. Based on these data, we propose that expansin is involved in mediating rapid internodal elongation in submerged deepwater rice internodes.     

Changes in expansin activity and cell wall susceptibility to expansin action during cessation of internodal elongation in floating rice

We investigated the involvement of expansin action in determining the growth rate of internodes of floating rice (Oryza sativa L.). Floating rice stem segments in which rapid internodal elongation had been induced by submergence for 2 days were exposed to air or kept in submergence for 2 more days. Both treatments reduced the elongation rate of the internodes, and the degree of reduction was much greater in air-exposed stem segments than in continually submerged segments. These rates of internodal elongation were correlated with acid-induced cell wall extensibility and cell wall susceptibility to expansins in the cell elongation zone of the internodes, but not with extractable expansin activity. These results suggest that the reduced growth rate of internodes must be due, at least in part, to the decrease in acid-induced cell wall extensibility, which can be modulated through changes in the cell wall susceptibility to expansins rather than through expansin activity. Analysis of the cell wall composition of the internodes showed that the cellulosic and noncellulosic polysaccharide contents increased in response to exposure to air, but they remained almost constant under continued submergence although the cell wall susceptibility to expansins gradually declined even under continued submergence. The content of xylose in noncellulosic neutral sugars in the cell walls of internodes was closely and negatively correlated with changes in the susceptibility of the walls to expansins. These results suggest that the deposition of xylose-rich polysaccharides into the cell walls may be related to a decrease in acid-induced cell wall extensibility in floating rice internodes through the modulation of cell wall susceptibility to expansins.     

Injury to Rice Plants Caused by Complete Submergence; A Contribution by Ethylerie (Ethene)

Complete submergence of rice plants (Oryza sativa L. cv. ‘IR42’)in dilute nutrient solution for 3–6 d almost stopped theaccumulation of dry matter, depressed soluble carbohydrate concentrationby over 75% and promoted chlorosis in fully expanded leaves.Increase in fresh weight by the shoots was not impaired. Extensionby the youngest visible leaf was stimulated. Extension by thenext leaf to appear was retarded by submergence. These growthresponses to submergence were associated with a 1-5-fold increasein the partial pressure of endogenous ethylene (ethene). Applying ethylene (0.3–0.35 Pa) in the gas-phase to non-submergedplants reproduced some, but not all, of these effects of submergence.Thus, greater leaf extension and chlorosis of submerged plantscould be attributable to accumulated ethylene but neither theslow relative growth rate nor the decreased extension of leavesemerging after the start of submergence could be so attributed. Two cultivars (‘FR13A’ and ‘Kurkaruppan’)already known to tolerate submergence, differed little fromsubmergence-intolerant ‘IR42’ in their relativegrowth rate and soluble carbohydrate concentration during submergence.However, their underwater leaf extension was less than in ‘IR42’and chlorosis was much less prevalent, especially in ‘FR13A’.Similarly, ethylene supplied to non-submerged plants was a lesseffective promotor of leaf extension and chlorosis in the twosubmergence tolerant cultivars. Application of 1.0 kPa carbondioxide in the gas-phase prevented the chlorosis response toethylene. The results indicate that accumulated ethylene is a likely causeof fast leaf extension and chlorosis in submergence intolerantforms of rice, particularly when amounts of dissolved carbondioxide are minimal. Key words: Oryza sativa L., aeration, ethylene (ethene), stress-tolerance     

Effects of submergence on development and gravitropism in the coleoptile of Oryza sativa L.

Caryopses of rice (Oryza sativa L. cv. Sasanishiki) were germinated in air or under water. In submerged seedlings a twofold increase in coleoptile growth rate and an inhibition of root growth was observed. The amount of starch in the amyloplasts of submerged coleoptiles was substantially reduced compared to the air-grown control plants and plastids had a proplastidic character. During the rapid elongation of coleoptiles under water, the osmotic concentration of the press sap remained constant, whereas in air-grown coleoptiles a decrease was measured. Determination of curvature of gravistimulated air-grown and submerged shoots was carried out by placing the coleoptiles horizontally in air of 98% relative humidity. Air-grown coleoptiles reached a vertical orientation within 5 h after onset of gravistimulation. In coleoptiles germinated under water the first signs of consistent negative gravitropic bending occurred after 4–5 h and curvature was complete after 24 h. During the first 5 h of gravistimulation the water-grown coleoptiles grew at an average rate of 0.39 mm·h^–1, whereas in air-grown coleoptiles a rate of 0.27 mm·h^–1 was measured. Concomitant with the delayed onset of gravitropic bending of the water-grown coleoptiles, a change in plastid ultrastructure and an increase in starch content was observed. We conclude that the gravitropic responsiveness of the rice coleoptile depends on the presence of starch-filled amyloplasts.We wish to thank H.-J. Ensikat for technical assistance with the scanning electron microscopy. Supported by the Bundesminister für Forschung und Technologie and the Deutsche Forschungsgemeinschaft.     

Development of Nitrogen Assimilation Enzymes during Photoautotrophic Growth of Chenopodium rubrum Suspension Cultures

We have shown previously that ethylene, which accumulates in the air spaces of submerged stem sections of rice (Oryza sativa L. cv “Habiganj Aman II”), is involved in regulating the growth response caused by submergence. The role of gibberellins in the submergence response was studied using tetcyclacis (TCY), a new plant growth retardant, which inhibits gibberellin biosynthesis. Stem sections excised from plants that had been watered with a solution of 1 micromolar TCY for 7 to 10 days did not elongate when submerged in the same solution or when exposed to 1 microliter per liter ethylene in air. Gibberellic acid (GA₃) at 0.3 micromolar overcame the effect of TCY and restored the rapid internodal elongation in submerged and ethylene-treated sections to the levels observed in control sections that had not been treated with TCY. The effect of 0.01 to 0.2 micromolar GA₃ on internodal elongation was enhanced two- to eight-fold when 1 microliter per liter ethylene was added to the air passing through the chamber in which the sections were incubated. GA₃ and ethylene caused a similar increase in cell division and cell elongation in rice internodes. Thus, ethylene may cause internodal elongation in rice by increasing the activity of endogenous GAs. In internodes from which the leaf sheath had been peeled off, growth in response to submergence, ethylene and GA₃ was severely inhibited by light.     

Abscisic acid inhibits shoot elongation of Scirpus mucronatus

The relationships between free ABA levels and shoot elongation were investigated in shoots of Scirpus mucronatus L. Under submergence, shoot elongation increased but free ABA levels decreased. The extent of the increase in length and the decrease in free ABA in submerged shoots increased with the increase of water depth. When the shoots were transferred to air after 12 days of submergence, they ceased to elongate and the free ABA levels recovered to the values of air-grown shoots. ABA, at concentrations from 1 μ M to 1 m M , inhibited the submergence-induced shoot elongation. In ambient air, fluridone, an inhibitor of ABA biosynthesis, at 7 μ M decreased the free ABA levels in shoots but increased shoot elongation. The effects could be reversed by 10 μ M ABA. These results indicate that ABA is an internal inhibitor of shoot growth in Scirpus .     

Tissue localization of a submergence-induced 1-aminocyclopropane-1-carboxylic acid synthase in rice

At least two 1-aminocyclopropane-1-carboxylic acid synthase genes (ACS) are implicated in the submergence response of rice (Oryza sativa). Previously, the OS-ACS5 gene has been shown to be induced during short- as well as long-term complete submergence of seedlings and to be controlled by a balance of gibberellin and abscisic acid in both lowland and deepwater rice. This study demonstrates that OS-ACS5 mRNA is localized in specific tissues and cells both during normal development and in response to complete submergence. The temporal and spatial regulation of OS-ACS5 expression is presented by in situ hybridization and histochemical analysis of beta-glucuronidase (GUS) activity in transgenic rice carrying an OS-ACS5-gus fusion. Whole-mount in situ hybridization revealed that in air-grown rice seedlings, OS-ACS5 was expressed at a low level in the shoot apex, meristems, leaf, and adventitious root primordia, and in vascular tissues of nonelongated stems and leaf sheaths. In response to complete submergence, the expression in vascular bundles of young stems and leaf sheaths was strongly induced. The results of histochemical GUS assays were consistent with those found by whole-mount in situ hybridization. Our findings suggest that OS-ACS5 plays a role in vegetative growth of rice under normal conditions and is also recruited for enhanced growth upon complete submergence. The possible implication of OS-ACS5 in root-shoot communication during submergence stress and its putative role in aerenchyma formation upon low-oxygen stress are discussed.     

Genomic fingerprinting of Frankia strains by PCR-based techniques. Assessment of a primer based on the sequence of 16S rRNA gene of Escherichia coli

Submergence stimulates elongation of the leaves of Rumex palustris and under laboratory conditions the maximum final leaf length (of plants up to 7 weeks old) was obtained within a 9 day period. This elongation response, mainly determined by petiole elongation, depends on the availability of storage compounds and developmental stage of a leaf. A starch accumulating tap root and mature leaves and petioles were found to supply elongating leaves with substrates for polysaccharide synthesis in expanding cell walls. Changes in the composition of cell wall polysaccharides of elongated petioles suggest a substantial cell wall metabolism during cell extension. Reduced starch levels or removal of mature leaves caused a substantial limitation of submerged leaf growth. From the 5th leaf onward enough reserves were available to perform submerged leaf growth from early developmental stages. Very young petioles had a limited capacity to elongate. In slightly older petioles submergence resulted in the longest final leaf lengths and these values gradually decreased when submergence was started at more mature developmental stages. Submerged leaf growth is mainly a matter of petiole elongation in which cell elongation has a concurrent synthesis of xylem elements in the vascular tissue. Mature petioles still elongated (when submerged) by cell and tissue elongation only: the annular tracheary elements stretched enabling up to 70% petiole elongation.     

The beneficial effect of reduced elongation growth on submergence tolerance of rice

Adverse effects of elongation growth on tolerance to completesubmergence for up to 14 d were evaluated in rice seedlingsof cultivars which differed in submergence tolerance. Thereis a good negative correlation between per cent survival andelongation growth of genotypes during complete submergence (r= – 0.81). When elongation growth underwater is minimizedby application of a gibberellin biosynthesis inhibitor, percent survival increases by as much as 50 times for one cultivar.These effects are likely related to elongation growth since(i) addition of gibberellin had the opposite effect by reducingsurvival, and (ii) when the elongation inhibitor and gibberellinwere added together, there was no effect on elongation growthand the per cent survival did not change. A GA-deficient mutantof rice which had little elongation ability during submergenceshowed a high level of submergence tolerance when plants weresubmerged at equal initial dry weights and carbohydrate levelsrelative to a submergence-tolerant cultivar. These results areconsistent with the hypothesis that elongation growth competeswith maintenance processes for energy and hence reduces survivalduring submergence. The impact of these findings is that inenvironments where elongation ability is not required, thereis a potential to increase submergence tolerance of agriculturallyimportant cultivars by selecting for least elongation, at leastduring periods of complete submergence. Furthermore, this trade-offbetween stimulated elongation growth and submergence tolerancewill have important ecological consequences for the distributionof plant species in different flood-prone environments. Key words: Gibberellin, growth, Oryza sativa, rice, submergence     

Coleoptile Senescence in Rice (Oryza sativa L.)

We investigated the cellular events associated with cell deathin the coleoptile of rice plants (Oryza sativa L.). Seeds germinatedunder submergence produced coleoptiles that were more elongatedthan those grown under aerobic conditions. Transfer of seedlingsto aerobic conditions was associated with coleoptile opening(i.e. splitting) due to death of specific cells in the sideof the organ. Another type of cell death occurred in the formationof lysigenous aerenchyma. Senescence of the coleoptile was alsonoted, during which discolouration of the chlorophyll and tissuebrowning were apparent. DNA fragmentation was observed by deoxynucleotidyltransferase-mediateddUTP nick end labelling (TUNEL) assay, and further confirmedby the appearance of oligonucleosomal DNA ladders in senescentcoleoptile cells. Two nucleases (Nuc-a and Nuc-b) were detectedby in-gel-assay from proteins isolated from coleoptiles. Nuc-a,commonly observed in three cell death phases required eitherCa²⁺or Mg²⁺, whereas Nuc-b which appeared during senescencerequired both Ca²⁺and Mg²⁺. Both nucleases were strongly inhibitedby Zn²⁺. Copyright 2000 Annals of Botany Company Aerenchyma, rice, cell death, coleoptile, fragmentation, nuclease, Oryza sativa, senescence, split, submergence, TUNEL