Helical growth of stage-IVb sporangiophores of <Emphasis Type="Italic">Phycomyces blakesleeanus</Emphasis>: the relationship between rotation and elongation growth rates

An understanding of the relationship between the two components of helical growth (rotation rate and elongation rate) is fundamental to understanding the biophysical and molecular mechanism(s) of cell wall extension in algal cells, fungal cells, and plant stems and roots. Helical growth occurs throughout development of the sporangiophores of Phycomyces blakesleeanus. Previous studies within the growth zone of stage-IVb sporangiophores have reported conflicting conclusions. An implicit assumption in the previous studies [E.S. Castle (1937) J Cell Comp Physiol 9:477-489; R. Cohen and M. Delbruck (1958) J Cell Comp Physiol 52:361-388; J.K.E. Ortega et al. (1974) Plant Physiol 53:485-490] was that the relationship between rotation rate and elongation rate was independent of the magnitude of the elongation rate. In the present study, for stage-IVb sporangiophores growing at a steady rate, it is shown that the ratio of rotation rate and elongation rate decreases as the elongation rate increases. Previously proposed biophysical and molecular mechanisms cannot account for the observed behavior. The previously postulated fibril-reorientation mechanism [J.K.E. Ortega and R.I. Gamow (1974) J Theor Biol 47:317-332; J.K.E. Ortega et al. (1974) Plant Physiol 53:485-490] is modified to accommodate this new finding. Other experiments were conducted to determine how the ratio of rotation rate and elongation rate behaves during a pressure response (a transient decrease in elongation rate produced by a large step-up in turgor pressure using the pressure probe). Results of these experiments indicate that this ratio increases during the pressure response.     

Pressure clamp method to measure transpiration in growing single plant cells : demonstration with sporangiophores of phycomyces

A pressure probe method (pressure clamp) was developed to measure transpiration rates of both growing and nongrowing single plant cells, and represents an improvement over the previous pressure probe method (pressure relaxation), which is restricted to nongrowing plant cells (J.K.E. Ortega, R.G. Keanini, K.J. Manica [1988] Plant Physiol 87: 11-14). The pressure clamp method was used to measure transpiration rates of Phycomyces sporangiophores in two developmental stages: stage III (nongrowing) and stage IV (growing).     

Expansins are involved in cell growth mediated by abscisic acid and indole-3-acetic acid under drought stress in wheat

Expansin protein is a component of the cell wall generally accepted to be the key regulator of cell wall extension during plant growth. Plant hormones regulate expansin gene expression as well as plant growth during drought stress. However, the relationship between expansin and plant hormone is far from clear. Here, we studied the involvement of expansin in plant cell growth mediated by the hormones indole-3-acetic acid (IAA) and abscisic acid (ABA) under osmotic stress which was induced by polyethylene glycol (PEG)-6000. Wheat coleoptiles from a drought-resistant cultivar HF9703 and a drought-sensitive cultivar 921842 were used to evaluate cell growth and expansin activity. Osmotic stress induced the accumulation of ABA. ABA induced expansin activity mainly by enhancing expansin expression, since ABA induced cell wall basification via decreasing plasma membrane H⁺-ATPase activity, which was unfavorable for expansin activity. Although ABA induced expansin activity and cell wall extension, treatment with exogenous ABA and/or fluridone (FLU, an ABA inhibitor) suggested that ABA was involved in the coleoptile growth inhibition during osmotic stress. IAA application to detached coleoptiles also enhanced coleoptile growth and increased expansin activity, but unlike ABA, IAA-induced expansin activity was mainly due to the decrease of cell wall pH by increasing plasma membrane H⁺-ATPase activity. Compared with drought-sensitive cultivar, the drought-resistant cultivar could maintain greater expansin activity and cell wall extension, which was contributive to its resultant faster growth under water stress.     

Over-expression of the cucumber expansin gene (Cs-EXPA1) in transgenic maize seed for cellulose deconstruction

Plant cell wall degradation into fermentable sugars by cellulases is one of the greatest barriers to biofuel production. Expansin protein loosens the plant cell wall by opening up the complex of cellulose microfibrils and polysaccharide matrix components thereby increasing its accessibility to cellulases. We over-expressed cucumber expansin in maize kernels to produce enough protein to assess its potential to serve as an industrial enzyme for applications particularly in biomass conversion. We used the globulin-1 embryo-preferred promoter to express the cucumber expansin gene in maize seed. Expansin protein was targeted to one of three sub-cellular locations: the cell wall, the vacuole, or the endoplasmic reticulum (ER). To assess the level of expansin accumulation in seeds of transgenic kernels, a high throughput expansin assay was developed. The highest expressing plants were chosen and enriched crude expansin extract from those plants was tested for synergistic effects with cellulase on several lignocellulosic substrates. Activity of recombinant cucumber expansin from transgenic kernels was confirmed on these pretreated substrates. The best transgenic lines (ER-targeted) can now be used for breeding to increase expansin expression for use in the biomass conversion industry. Results of these experiments show the success of expansin over-expression and accumulation in transgenic maize seed without negative impact on growth and development and confirm its synergistic effect with cellulase on deconstruction of complex cell wall substrates.     

扩展蛋白与植物抗逆性关系研究进展

扩展蛋白是一种细胞壁蛋白,可调节细胞壁的松弛和伸展。目前研究表明,扩展蛋白几乎参与调节植物生长发育的整个进程。扩展蛋白还与植物的多种抗性反应有关,在植物对干旱、高盐以及病虫害等生物胁迫和非生物胁迫响应方面起着重要的调节作用。干旱胁迫下扩展蛋白基因的表达与植物的抗旱性有一定的关系;植物的耐盐性受到扩展蛋白基因表达的影响;淹水促进植物的伸长生长与扩展蛋白的表达密切相关;扩展蛋白调节细胞壁松弛为植物抗病性研究提供了新的思路。     

The Existence of Expansin and Its Properties in the Hypocotyls of Soybean Seedlings

Expansins, a newly discovered class of cell wall proteins, were the only proteins that, to date, have been shown to have the ability to restore the "acid growth" response of the heat-inactivated cell wall in an in vitro assay. In order to characterize these proteins, an automatic extensometer had been previously constructed by modification of an equal-arm mechanical balance with a linear variable differential transformer (LVDT) and with some easily available laboratory equipment. The objective of this study was to confirm and complement the work on expansin in cucumber ( Cucumis sativus L. ) seedlings carried out in the expansin-discoverers' laboratory and in addition, to further examination of the extensometer built in the authors' laboratory. It was reported that, firstly, expansin activity was maximal in cell wall from the growing region of soybean (Glycine max L. ) hypocotyls but was negligible or lacking in that from mature, basal regions and cotyledons. Corre- spondingly, walls from the growing tissue had a strong susceptibility to the action of expansin, whereas the nongrowing tissues became insensitive to the expansin action. It was concluded that the growth of soybean hypocotyl was associated with an increase in both expansin activity and wall susceptibility to the expansin action. Secondly, the heat-inactivated wall extension could be induced by cross reconstitution with crude expansin extract between soybean and cucumber species. Thirdly, once the heat-inactivated wall has been pretreated with the exogenous expansin, the reconstituted wall required no further expansin for extension indicating that exogenous expansin could specifically bind to cell wall and be enough to repeatedly exert its action without releasing from the cell wall into the external solution, i.e., a single expansin molecule could gradually break a series of load-bearing bonds one by one while moving along the cell wall, and thereby permitting the wall to extend. Fourthly, reconstitution of the wall extension activity was evidently dependent on the expansin concentration and the pH of the bathing solution, which was consistent with the catalytic characteristics of classical enzymes. Finally, endogenous and reconstituted wall extension could be significantly induced in 50 mmoL/L sodium acetate at pH 4.5 and completely inhibited in 50 mmol/L Hepes at pH 6.8, especially these phenomena could continuously be caused by switching incubation buffer from one to the other alternately, suggesting that change in pH of bathing solution could only affect the conformation of expansin (thus leading to denaturation or renaturation of it) but not the affinity of it for cell wall. In summary, these observations lend further support to the fact that expansin could mediate the acid-induced extension of the isolated wall, probably through a biochemical or enzymatic process exerting directly to the cell wall. This protein may play an essential role in the control of plant cell growth in vivo.     

Role of Expansin in Cell Enlargement of Oat Coleoptiles (Analysis of Developmental Gradients and Photocontrol)

Expansins are wall proteins that mediate a type of acid-induced extension in isolated plant cell walls (S. McQueen-Mason, D.M. Durachko, D.J. Cosgrove [1992] Plant Cell 4: 1425-1433). To assess the role of these proteins in the process of cell enlargement in living tissues, we compared the spatial and temporal growth patterns of oat (Avena sativa L.) coleoptiles with four wall properties related to expansin action. These properties were (a) the ability of isolated walls and living segments to extend in acidic buffer, (b) the ability of heat-inactivated walls to extend upon application of expansins, (c) the amount of immunologically detectable expansin in wall protein extracts, and (d) the extractable expansin activity of walls. Growth rate was maximal in the apical half of dark-grown coleoptiles and negligible in the basal region. This growth pattern correlated with properties a and b; in contrast, the amount and activity of extractable expansin (properties c and d) were reduced only in the most basal region. Upon exposure to white light, coleoptiles abruptly ceased elongation at 8 to 10 h after start of irradiation, and this cessation correlated with reductions in properties a to c. The growth cessation at 8 to 10 h also coincided with the loss of growth response to exogenous auxin and fusicoccin in excised coleoptile segments. These results lend correlative support to the hypothesis that expansin action is important for growth responses of living oat coleoptiles (e.g. responses to acidic buffers, auxin, fusicoccin, aging, and light). Our results suggest that changes in the susceptibility of the wall to expansin action, rather than changes in expansin activity, may be a key determinant of the growth patterns in oat coleoptiles.     

Expansin-regulated cell elongation is involved in the drought tolerance in wheat

Water stress restrains plant growth. Expansin is a cell wall protein that is generally accepted to be the key regulator of cell wall extension during plant growth. In this study, we used two different wheat cultivars to study the involvement of expansin in drought tolerance. Wheat coleoptile was used as the material in experiment. Our results indicated that water stress induced an increase in acidic pH-dependant cell wall extension, which is related to expansin activity; however, water stress inhibited coleoptile elongation growth. The increased expansin activity was mainly due to increased expression of expansin protein that was upregulated by water stress, but water stress also resulted in a decrease in cell wall acidity, a negative factor for cell wall extension. Decreased plasma membrane H⁺-ATPase activity was involved in the alkalinization of the cell wall under water stress. The activity of expansin in HF9703 (a drought-tolerant wheat cultivar) was always higher than that in 921842 (a drought-sensitive wheat cultivar) under both normal and water stress conditions, which may be correlated with the higher expansin protein expression and plasma membrane H⁺-ATPase activity observed in HF9703 versus 921842. However, water stress did not change the susceptibility of the wheat cell wall to expansin, and no difference in this susceptibility was observed between the drought-tolerant and drought-sensitive wheat cultivars. These results suggest the involvement of expansin in cell elongation and the drought resistance of wheat.     

Expansin的研究进展

随着对植物生长机制的不断深入研究,发现expansin蛋白具明显而广泛的促进生长的作用。简述了expansin蛋白的生化特性及其对细胞壁的松弛机制,同时介绍了expansin在水稻中的组织定位。     

Plant Cell Growth in Tissue

Cell walls are part of the apoplasm pathway that transports water, solutes, and nutrients to cells within plant tissue. Pressures within the apoplasm (cell walls and xylem) are often different from atmospheric pressure during expansive growth of plant cells in tissue. The previously established Augmented Growth Equations are modified to evaluate the turgor pressure, water uptake, and expansive growth of plant cells in tissue when pressures within the apoplasm are lower and higher than atmospheric pressure. Analyses indicate that a step-down and step-up in pressure within the apoplasm will cause an exponential decrease and increase in turgor pressure, respectively, and the rates of water uptake and expansive growth each undergo a rapid decrease and increase, respectively, followed by an exponential return to their initial magnitude. Other analyses indicate that pressure within the apoplasm decreases exponentially to a lower value after a step-down in turgor pressure, which simulates its behavior after an increase in expansive growth rate. Also, analyses indicate that the turgor pressure decays exponentially to a constant value that is the sum of the critical turgor pressure and pressure within the apoplasm during stress relaxation experiments in which pressures within the apoplasm are not atmospheric pressure. Additional analyses indicate that when the turgor pressure is constant (clamped), a decrease in pressure within the apoplasm elicits an increase in elastic expansion followed by an increase in irreversible expansion rate. Some analytical results are supported by prior experimental research, and other analytical results can be verified with existing experimental methods.Cell walls perform many functions for plant, algal, and fungal cells. Physical and chemical protection from the environment and physical support for cells and organs are obvious functions. Cell walls also withstand the stresses imposed by turgor pressure and deform irreversibly and reversible (elastically) during expansive growth. Irreversible wall deformations during expansive growth control cell enlargement, size, and shape. Growing and mature (nongrowing) cell walls undergo elastic deformations after changes in turgor pressure caused by changes in water status and environmental conditions. Elastic wall deformations are fundamental to the water relations of plant, algal, and fungal cells. For plant cells in tissues and organs, cell walls are part of the apoplasm pathway that transports water, solutes, and nutrients to cells.Importantly, pressures within the apoplasm (cell walls and xylem) are frequently different from atmospheric pressure during expansive growth of plant cells in tissues and organs. Lower pressures (tensions) are related to transpiration rates from plant organs and to expansive growth of cells in plant organs, e.g. Boyer (1967, 2001), Molz and Boyer (1978), Nonami and Boyer (1987, 1993), Nonami and Hashimoto (1996), Passioura and Boyer (2003), Boyer and Silk (2004), Koch et al. (2004), Wiegers et al. (2009), and the references within. Higher pressures (root pressures) occur during the spring when the soil is well hydrated (e.g. Kramer, 1932). Bleeding sap from cuts and broken stems is evidence of root pressure. Also, higher pressures may occur diurnally, during the night when transpiration rates are low (e.g. Tang and Boyer, 2008). Guttation drops on leaves in the morning are evidence of these higher pressures.Prior research indicates that a significant amount of chemistry and molecular biology occur within cell walls undergoing irreversible deformation during expansive growth (e.g. Cosgrove, 2005; Boyer, 2009). Two questions arise. First, how do pressures within the wall that are different from atmospheric pressure affect the turgor pressure, water uptake, and growth rate of cells in plant organs such as roots, stems, and leaves? Second, how are relevant chemical reactions affected by lower and higher pressures within the wall? The analyses conducted in this article focus on the first question.Previously, equations derived by Lockhart (1965) for wall deformation and water uptake (Growth Equations) were augmented with terms for elastic wall deformation (Ortega, 1985) and transpiration (Ortega et al., 1988). In this article, the previously established Augmented Growth Equations (Ortega, 1985, 1990, 1994, 2004; Ortega et al., 1988; Geitmann and Ortega, 2009) are modified to evaluate the turgor pressure, water uptake, and expansive growth of plant cells in tissue when pressures within the apoplasm are lower and higher than atmospheric pressure. In addition, the pressure within the apoplasm is evaluated after turgor pressure in cells decrease, thus simulating the condition produced by an increase in expansive growth rate of cells in plant tissues and organs. Also, the modified equations are used to determine how the results of stress relaxation experiments conducted on growing plant organs are affected by pressures within the apoplasm that are not atmospheric pressure. Last, the expansive growth of a plant cell is evaluated when pressure within the apoplasm undergoes a semi-instantaneous change while the turgor pressure remains constant, i.e. clamped. Some analytical results are supported by prior experimental research, and some analytical results can be verified with existing experimental methods.     

Expansin的研究进展

随着对植物生长机制的不断深入研究,发现expansin蛋白具明显而广泛的促进生长的作用。简述了expansin蛋白的生化特性及其对细胞壁的松弛机制,同时介绍了expansin在水稻中的组织定位。     

Effect of temperature on plant elongation and cell wall extensibility

Lockhart equation was derived for explaining plant cell expansion where both cell wall extension and water uptake must occur concomitantly. Its fundamental contribution was to express turgor pressure explicitly in terms of osmosis and wall mechanics. Here we present a new equation in which pressure is determined by temperature. It also accounts for the role of osmosis and consequently the role of water uptake in growing cell. By adopting literature data, we also attempt to report theoretically the close relation between plant elongation and cell wall extensibility. This is accomplished by the modified equation of growth solved for various temperatures in case of two different species. The results enable to interpret empirical data in terms of our model and fully confirm its applicability to the investigation of the problem of plant cell extensibility in function of environmental temperature. Moreover, by separating elastic effects from growth process we specified the characteristic temperature common for both processes which corresponds to the resonance energy of biochemical reactions as well as to the rapid softening of the elastic modes toward the high temperature end where we encountered viscoelastic and/or plastic behavior as dominating. By introducing analytical formulae connected with growth and elastic properties of the cell wall, we conclude with the statement how these both processes contribute quantitatively to the resonance-like shape of the elongation curve. In addition, the tension versus temperature "phase diagram" for a living plant cell is presented.     

Plant cell enlargement and the action of expansins

Plant cells are caged within a distended polymeric network (the cell wall), which enlarges by a process of stress relaxation and slippage (creep) of the polysaccharides that make up the load-bearing network of the wall. Protein mediators of wall creep have recently been isolated and characterized. These proteins, called expansins, appear to disrupt the noncovalent adhesion of matrix polysaccharides to cellulose microfibrils, thereby permitting turgor-driven wall enlargement. Expansin activity is specifically expressed in the growing tissues of dicotyledons and monocotyledons. Sequence analysis of cDNAs indicates that expansins are novel proteins, without previously known functional motifs. Comparison of expansin cDNAs from cucumber, pea, Arabidopsis and rice shows that the proteins are highly conserved in size and amino acid sequence. Phylogenetic analysis of expansin sequences suggests that this multigene family diverged before the evolution of angiosperms. Speculation is presented about the role of this gene family in plant development and evolution.     

Variable expansin expression in Arabidopsis leads to different growth responses

Expansins have long been implicated in the control of cell wall extensibility. However, despite ample evidence supporting a role for these proteins in the endogenous mechanism of plant growth, there are also examples in the literature where the outcome of altered expansin gene expression is difficult to reconcile with a simplistic causal linkage to growth promotion. To investigate this problem, we report on the analysis of transgenic Arabidopsis plants in which a heterologous cucumber expansin can be inducibly overexpressed. Our results indicate that the effects of expansin expression on growth depend on the degree of induction of expansin expression and the developmental pattern of organ growth. They support the role of expansin in directional cell expansion. They are also consistent with the idea that excess expansin might itself impede normal activities of cell wall modifications, culminating in both growth promotion and repression depending on the degree of expression.     

An expansin gene expressed in ripening strawberry fruit

Tissue softening accompanies the ripening of many fruit and initiates the processes of irreversible deterioration. Expansins are plant cell wall proteins proposed to disrupt hydrogen bonds within the cell wall polymer matrix. Expression of specific expansin genes has been observed in tomato (Lycopersicon esculentum) meristems, expanding tissues, and ripening fruit. It has been proposed that a tomato ripening-regulated expansin might contribute to cell wall polymer disassembly and fruit softening by increasing the accessibility of specific cell wall polymers to hydrolase action. To assess whether ripening-regulated expansins are present in all ripening fruit, we examined expansin gene expression in strawberry (Fragaria x ananassa Duch.). Strawberry differs significantly from tomato in that the fruit is derived from receptacle rather than ovary tissue and strawberry is non-climacteric. A full-length cDNA encoding a ripening-regulated expansin, FaExp2, was isolated from strawberry fruit. The deduced amino acid sequence of FaExp2 is most closely related to an expansin expressed in early tomato development and to expansins expressed in apricot fruit rather than the previously identified tomato ripening-regulated expansin, LeExp1. Nearly all previously identified ripening-regulated genes in strawberry are negatively regulated by auxin. Surprisingly, FaExp2 expression was largely unaffected by auxin. Overall, our results suggest that expansins are a common component of ripening and that non-climacteric signals other than auxin may coordinate the onset of ripening in strawberry.     

Ectomycorrhizas of two species of <Emphasis Type="Italic">Tuber</Emphasis> (clade Puberulum) in the Mexican subtropical cloud forest

Expansins are non-enzymatic cell wall proteins that mediate plant growth by catalyzing loosening of cell walls without lysing the wall polymers. Advances in the field of bioinformatics have facilitated the prediction of the members of expansin gene family across several model plants. Expansins constitutes into four sub-families; α-expansin, β-expansin, expansin-like A and expansin-like B. Biological functions of expansin gene family include diverse aspects of plant growth and development, shoot and root elongation, leaf morphogenesis, flower and fruit development, embryogenesis, pollen tube growth, stress tolerance, etc. Recent studies have demonstrated the role of expansins in plant-symbiotic interactions. The present review reveals the factors that govern plant-arbuscular mycorrhizal fungi (AMF) and legume-rhizobia symbioses; and the genes that participate in these diverse symbiont interactions. Further, we focus on the expression profiles and the functions of expansins during plant-AMF and legume-rhizobia interactions. The key roles of expansin proteins during AMF invasion, arbuscule formation, rhizobial infection and nodule organogenesis were uncovered during symbioses. This review summarizes discoveries that support the key and versatile roles of various expansin members in the plant-mycorrhizal and legume-rhizobial symbioses.