Desiccation tolerance in developing soybean seeds: The role of stress proteins

The consistent correlation between desiccation tolerance in orthodox seed tissue and an accumulation of certain "late embryogenesis abundant" (LEA) proteins suggests that these proteins reduce desiccation-induced cellular damage. The aim of the present work was to test this hypothesis. Exogenous abscisic acid (ABA) was used to elevate the level of heal-soluble LEA-like proteins in axes from immature (30 days after flowering: mid-development) seeds of soybean ( Glycine max [L.] Merrill cv. Chippewa 64). As the LEA-like proteins accumulated in response to ABA, the leakage of all elements after desiccation and subsequent rehydration markedly declined. Both LEA-like protein accumulation and the decline in desiccation-induced electrolyte leakage were apparently dependent on the presence of ABA. Both effects of ABA were inhibited by cycloheximide. Light microscopy revealed a marked effect of the ABA on cellular integrity following desiccation. Osmotic stress also caused a decrease in desiccation-induced electrolyte leakage and stimulated the accumulation of LEA-like proteins. Our data are consistent with the hypothesis that the LEA-like proteins contribute to the increase in desiccation tolerance in response to ABA, and are consistent with a general protective role for these proteins in desiccation tolerance.     

Upregulation of antioxidant and glyoxalase systems mitigates NaCl stress in Brassica juncea by supplementation of zinc and calcium

Possible involvement of calcium (Ca) and zinc (Zn) in mitigation of salt (NaCl) stress-induced oxidative damage in Brassica juncea was investigated. Salt stress (200?mM NaCl) reduced leaf pigment synthesis and some key photosynthetic attributes including stomatal conductance and internal CO₂ concentration. Exogenous application of Ca and Zn resulted in enhanced growth possibly by induction of the antioxidant defense system, resulting in improved redox state thereby favoring growth improvement. Proline accumulation (3.39-fold) was stimulated by exogenous application of Zn and Ca causing improvement in growth through enhancement in relative water content (78.46%) and increased flavonoid accumulation (86.19%). NaCl stress enhanced the hydrogen peroxide (H₂O₂), malondialdehyde and methylglyoxal content by 3-fold, 1.51-fold, and 2.98-fold, respectively, however, supplementation of Ca and Zn individually as well as in combination reduced the accumulation to an appreciable level. Ca and Zn treatment helped Brassica juncea plants to strengthen the antioxidant system and glyoxalase system and also enzymes of ascorbate-glutathione (AsA-Glu) cycle for better protection to membranes from reactive oxygen species. Moreover, Ca and Zn supplementation reduced the salt-induced damage by maintaining Na/K ratio through improved K uptake.     

Physiological roles of nonselective cation channels in plants: from salt stress to signalling and development

Nonselective cation channels (NSCCs) catalyse passive fluxes of cations through plant membranes. NSCCs do not, or only to a small extent, select between monovalent cations, and several are also permeable to divalent cations. Although a number of NSCC genes has been identified in plant genomes, a direct correlation between gene products and in vivo observed currents is still largely absent for most NSCCs. In this review, physiological functions and molecular properties of NSCCs are critically discussed. Recent studies have demonstrated that NSCCs are directly involved in a multitude of stress responses, growth and development, uptake of nutrients and calcium signalling. NSCCs can also function in the perception of external stimuli and as signal transducers for reactive oxygen species, pathogen elicitors, cyclic nucleotides, membrane stretch, amino acids and purines.     

Effects of low temperature, high salinity and exogenous ABA on the synthesis of two chloroplastic drought-induced proteins in Solanum tuberosum

Two chloroplastic proteins of 32 and 34 kDa were previously shown to be substantially synthesized in response to a progressive water deficit in whole Solanum tuberosum plants (G. Pruvot, S. Cuiné, N. Gault, G. Peltier and P. Rey, unpublished data; G. Pruvot, S. Cuiné, G. Peltier and P. Rey. 1996. Planta 198: 471–479). These chloroplastic drought-induced stress proteins, named CDSP 32 and CDSP 34, accumulated in the stroma and in the thylakoids, respectively. In this study, we investigated the effects of low temperature and high salinity on the synthesis of the CDSP proteins. Whereas the CDSP 32 synthesis was not modified in response to a cold treatment, an increased synthesis of CDSP 32 was observed in salt-stressed plants, resulting in accumulation of the protein. The thylakoid CDSP 34 protein exhibited enhanced synthesis and substantial accumulation in response to cold and high salinity. A significant increase in the leaf abscisic acid content (at least 2.5-fold) was measured in plants subjected to water deficit, high salinity or low temperature. The contribution of ABA to the synthesis of the two proteins was investigated by spraying well-watered plants with a 100 μ M / ABA solution for 15 days. This treatment resulted in a 15-fold increase in the leaf ABA content. Whereas synthesis of the CDSP 32 protein was not affected by exogenous ABA, synthesis of the CDSP 34 protein was substantially enhanced. Based on these results, we conclude that ABA likely mediates the increased synthesis of CDSP 34 upon drought, low temperature and high salinity and suggest that another signal, likely related to high osmolarity, is involved in the induction of CDSP 32 synthesis.     

苦荞TCP转录因子全基因组鉴定及非生物胁迫分析

TCP是植物特有的一类转录因子,在植物生长发育过程中发挥着重要作用。该研究利用生物信息学方法对苦荞TCP家族进行全基因组鉴定,并通过实时荧光定量PCR(qRT-PCR)技术分析苦荞TCP基因在干旱胁迫和盐胁迫下的表达特征。结果表明:(1)在苦荞的基因组中鉴定出28个TCP家族成员,它们不均匀地分布在苦荞的8条染色体上。(2)多数的苦荞TCP基因包含1～5个外显子。(3)系统发育分析将苦荞TCP家族分为5个亚家族,种内TCP蛋白多聚集在同一分支上。(4)共线性分析表明,5个苦荞TCP基因来自全基因组复制事件。(5)顺式元件分析显示,苦荞TCP基因的启动子区域的顺式响应元件主要包含胁迫响应元件和激素响应元件两大类。(6)转录组数据分析结果显示,所有苦荞TCP基因在检测组织中均有表达。(7)qRT-PCR结果显示,FtTCP3、FtTCP6、FtTCP12和FtTCP13基因在干旱胁迫和盐胁迫下的表达量发生变化,其中FtTCP3在6 h干旱处理和盐处理时表达量均达到峰值,说明FtTCP3基因在苦荞应对干旱胁迫和盐胁迫中起正向调控作用。该研究结果为了解TCP基因家族的进化和功能提供了新的见解,为苦荞TCP基因家族的功能研究和利用奠定了基础。     

Legume nodule senescence: roles for redox and hormone signalling in the orchestration of the natural aging process

Research on legume nodule development has contributed greatly to our current understanding of plant-microbe interactions. However, the factors that orchestrate root nodule senescence have received relatively little attention. Accumulating evidence suggests that redox signals contribute to the establishment of symbiosis and senescence. Although degenerative in nature, nodule senescence is an active process programmed in development in which reactive oxygen species (ROS), antioxidants, hormones and proteinases have key roles. Nodules have high levels of the redox buffers, ascorbate and glutathione, which are important in the nodulation process and in senescence. These metabolites decline with N-fixation as the nodule ages but the resultant decrease in redox buffering capacity does not necessarily lead to enhanced ROS or oxidative stress. We propose models by which ROS and antioxidants interact with hormones such as abscisic acid in the orchestration of nodule senescence.     

ABA-based chemical signalling: the co-ordination of responses to stress in plants

There is now strong evidence that the plant hormone abscisic acid (ABA) plays an important role in the regulation of stomatal behaviour and gas exchange of droughted plants. This regulation involves both long-distance transport and modulation of ABA concentration at the guard cells, as well as differential responses of the guard cells to a given dose of the hormone. We will describe how a plant can use the ABA signalling mechanism and other chemical signals to adjust the amount of water that it loses through its stomata in response to changes in both the rhizospheric and the aerial environment. The following components of the signalling process can play an important part in regulation: (a) ABA sequestration in the root; (b) ABA synthesis versus catabolism in the root; (c) the efficiency of ABA transfer across the root and into the xylem; (d) the exchange of ABA between the xylem lumen and the xylem parenchyma in the shoot; (e) the amount of ABA in the leaf symplastic reservoir and the efficiency of ABA sequestration and release from this compartment as regulated by factors such as root and leaf-sourced changes in pH; (f) cleavage of ABA from ABA conjugates in the leaf apoplast; (g) transfer of ABA from the leaf into the phloem; (h) the sensitivity of the guard cells to the [ABA] that finally reaches them; and lastly (i) the possible interaction between nitrate stress and the ABA signal.     

Oxidant and antioxidant signalling in plants: a re-evaluation of the concept of oxidative stress in a physiological context

While the chemical nature of reactive oxygen species (ROS) dictates that they are potentially harmful to cells, recent genetic evidence suggests that in planta purely physicochemical damage may be much more limited than previously thought. The most potentially deleterious effect of ROS under most conditions is that at high concentrations they trigger genetically programmed cell suicide events. Moreover, because plants use ROS as second messengers in signal transduction cascades in processes as diverse as mitosis, tropisms and cell death, their accumulation is crucial to plant development as well as defence. Direct ROS signal transduction will ensue only if ROS escape destruction by antioxidants or are otherwise consumed in a ROS cascade. Thus, the major low molecular weight antioxidants determine the specificity of the signal. They are also themselves signal-transducing molecules that can either signal independently or further transmit ROS signals. The moment has come to re-evaluate the concept of oxidative stress. In contrast to this pejorative or negative term, implying a state to be avoided, we propose that the syndrome would be more usefully described as 'oxidative signalling', that is, an important and critical function associated with the mechanisms by which plant cells sense the environment and make appropriate adjustments to gene expression, metabolism and physiology.     

Growth rate, water relations and ion accumulation of soybean callus lines differing in salinity tolerance under salinity stress and its subsequent relief

A selected Glycine max (L.) salt-tolerant calluscell line (R100) was significantly more tolerant to salt than a salt-sensitiveline (S100) during exposure to salt stress. Growth (Fresh and Dry weights) ofthe R100 cell line declined significantly at NaCl concentrations greater than 75mM, while growth of the S100 cell line was already impaired at 25mM NaCl. Levels of Na⁺ and Cl^– inthe callus were elevated as the salt concentration increased, whileK⁺, Ca²⁺ and Mg²⁺ levels weremarkedly reduced. The lower s reduction and Na⁺accumulation found in the S100 callus corresponded with the higher callusdehydration during salinity. Calli grown on Miller's basal medium weresupplied with 100 mM NaCl for 12 days and then supplied with mediumwithout NaCl to relieve salinity stress. The Na⁺ andCl^– content decreased in both R100 and S100 cell lines duringthe first 24 h and reached normal levels four days after transferto the normal medium. This lower concentration was maintained until the end ofthe experiment. Concurrently, the K⁺ content andK⁺/Na⁺ ratio increased sharply and reached theirhighest levels within 24 h in both salt-sensitive and salt-tolerantcell lines. These data suggest that the inhibitory effects of salinization ongrowth and accumulation of potentially toxic ions (Na⁺,Cl^–) can be readily reversed when salinity is relieved.     

Growth of cotton under continuous salinity stress: influence on allocation pattern,stomatal and non-stomatal components of photosynthesis and dissipation of excess light energy

Cotton (Gossypium hirsutum L.) plants were grown in flowing-culture solutions containing 0%, 26% and 55% natural seawater under controlled and otherwise identical conditions. Leaf Na⁺ content rose to 360 mM in 55% seawater, yet the K⁺ content was maintained above 100 mM. The K⁺/Na⁺ selectivity ratio was much greater in the saline plants than in the control plants. All plants were healthy and able to complete the life cycle but relative growth rate fell by 46% in 26% seawater and by 83% in 55% seawater. Much of this reduction in growth was caused by a decreased allocation of carbon to leaf growth versus root growth. The ratio of leaf area/plant dry weight fell by 32% in 26% seawater and by 50% in 55 % seawater while the rate of carbon gain per unit leaf area fell by only 20% in 26% seawater and by as much as 66% in 55% seawater. Partial stomatal closure accounted for nearly all of the fall in the photosynthesis rate in 26% seawater but in 55% seawater much of the fall also can be attributed to non-stomatal factors. As a result of the greater effect of salinity on stomatal conductance than on CO₂-uptake rate, photosynthetic water-use efficiency was markedly improved by salinity. This was also confirmed by stablecarbon-isotope analyses of leaf sugar and of leaf cellulose and starch. — Although non-stomatal photosynthetic capacity at the growth light was reduced by as much as 42% in 55% seawater, no effects were detected on the intrinsic photon yield of photosynthesis nor on the efficiency of photosystem II photochemistry, chlorophyll a/b ratio, carotenoid composition or the operation of the xanthophyll cycle. Whereas salinity caused in increase in mesophyll thickness and content of chloroplast pigments it caused a decrease in total leaf nitrogen content. The results indicate that the salinity-induced reduction in non-stomatal photosynthetic capacity was not caused by any detrimental effect on the photosynthetic apparatus but reflects a decreased allocation to enzymes of carbon fixation. — Rates of energy dissipation via CO₂ fixation and photorespiration, calculated from gas-exchange measurements, were insufficient to balance the rate of light-energy absorption at the growth light. Salinity therefore would have been expected to cause the excess excitation energy to rise, leading to an increased nonradiative dissipation in the pigment bed and resulting increases in non-photochemical fluorescence quenching and zeaxanthin formation. However, no such changes could be detected, implying that salinity may have increased energy dissipation via a yet unidentified energy-consuming process. This lack of a response to salinity stress is in contrast to the responses elicited by short-term water stress which caused strong non-photochemical quenching and massive zeaxanthin formation.Abbreviations and Symbols A net rate of CO₂ uptake - A_c calculated rate of CO₂ uptake at constant p_i - Chl chlorophyll - E rate of transpiration - EPS epoxidation state of xanthophyll cycle components - F, F_m fluorescence emission at the actual, full reduction of PSII reaction centers - F_v variable fluorescence - g_s stomatal conductance to water vapor - g_w conductance to CO₂transfer from intercellular spaces to chloroplasts - NPQ non-photochemical fluorescence quenching - p_a, p_i, p_c atmospheric, intercellular and chloroplastic partial pressures of CO₂ - PCRO photosynthetic carbon reduction and oxygenation cycle sum of the rate of carboxylation and oxygenation - PFD photon flux density - PSII photosystem II - V+A+Z pool size of xanthophyll cycle components - ¹³C carbon-isotope composition - (_PSII) photon yield of PSII photochemistry at the actual reduction state in the light * C.I.W.-D.P.B. Publication No. 1115, CNR-RAISA paper No. XXXWe thank Connie Shih for skilful assistance in growing plants and for conducting HPLC analyses and Barbara Mortimer for conducting the nitrogen analyses. Thanks are also due to C. Barry Osmond (now, Australian National University, Research School of Biological Sciences, Canberra) and Larry Giles of the Department of Botany, Duke University, Durham, N.C., for conducting carbonisotope analysis. E.B. was partially supported by the National Research Council of Italy, Special Project RAISA, Sub-Project No. 2. A Carnegie Institution Fellowship to E.B. is also gratefully acknowledged. This work was supported by grant No. 89-37-280-4902 of the Competitive Grant Program of the U.S. Department of Agriculture to O.B.     

中国辣椒热胁迫转录因子的全基因组鉴定及热胁迫响应的初步分析

采用生物信息学方法,从中国辣椒(Capsicum chinense Jacq.)全基因组序列中鉴定得到28个热胁迫转录因子(HSF)候选基因,并对这些候选基因的染色体分布、基因结构及编码蛋白的3D结构特征进行了分析。结果显示:28个候选基因的编码蛋白长度为128~526 aa;系统发育分析结果表明,HSF可分为A、B、C 3个亚家族。进一步对热胁迫处理后的中国辣椒种质进行转录组分析,共检测到27个HSF转录本,与对照组相比,实验组中有25个基因对热胁迫有不同程度的响应。     

Interaction with ethylene: changing views on the role of abscisic acid in root and shoot growth responses to water stress

Shoot and root growth are differentially sensitive to water stress. Interest in the involvement of hormones in regulating these responses has focused on abscisic acid (ABA) because it accumulates in shoot and root tissues under water-limited conditions, and because it usually inhibits growth when applied to well-watered plants. However, the effects of ABA can differ in stressed and non-stressed plants, and it is therefore advantageous to manipulate endogenous ABA levels under water-stressed conditions. Studies utilizing ABA-deficient mutants and inhibitors of ABA synthesis to decrease endogenous ABA levels, and experimental strategies to circumvent variation in plant water status with ABA deficiency, are changing the view of the role of ABA from the traditional idea that the hormone is generally involved in growth inhibition. In particular, studies of several species indicate that an important role of endogenous ABA is to limit ethylene production, and that as a result of this interaction ABA may often function to maintain rather than inhibit shoot and root growth. Despite early speculation that interaction between these hormones may influence many of the effects of water deficit, this topic has received little attention until recently.