不同植物在水分胁迫条件下脯氨酸的累积与抗旱性的关系

Ca植物春小麦幼苗叶片累积脯氨酸的数量随水分胁迫时间和强度递增,累积的数量与品种的抗旱性没有相关性。C_4植物玉米和高粱累积脯氨酸的数量低于小麦,但高粱多于玉米。CAM植物落地生根脯氨酸含量略有变化。旱生植物细枝岩黄芪的同化枝累积脯氨酸的数量高于中生植物钻天杨和槐的叶片,而梭梭的同化校则低于槐而高于钻天杨。表明这些植物累积脯氨酸的数量与它们的抗旱性无夫。因此似不宜用脯氨酸数量的多少作为植物抗旱性的生理指标。     

The Requirement for Low-Intensity Light in the Accumulation of Proline as a Response to Water Deficit

The effect of light on proline accumulation has been examinedin excised segments from the first leaf of barley (cv. Prior)that were subjected to water deficit by exposure to polyethyleneglycol solutions. Illumination either of the intact plant priorto leaf excision or of the leaf segments after excision promotedproline accumulation. This promotion was not due to a changein tissue water potential and the response was saturated ata low irradiance (15–75 µE m ²s ¹ depending uponprevious illumination of the intact plant). Saturation was notdue to a finite capacity of the leaf segments to accumulateproline, but was apparently associated with a finite rate ofaccumulation. The stimulation of proline accumulation by lightwas apparent at all levels of external water potential imposedbut the magnitude of accumulation increased as water potentialwas decreased both in light and darkness. Proline. or its precursor,was readily translocated within the leaf, since leaves thatwere partially shaded whilst subjected to water deficit containedthe same proline concentration throughout. It is concluded thatproline accumulation is not evoked by light through a triggeringmechanism but rather is stimulated by the continuous presenceof light. Key words: Light intensity, Barley, Water deficit, Proline accumulation     

Proline Accumulation and Varietal Adaptability to Drought in Barley: a Potential Metabolic Measure of Drought Resistance

A reliable laboratory test for drought resistance in crops would be invaluable in breeding programmes. Experience so far has been disappointing, however, due to either a lack of differentiation between genotypes¹, or poor correlation between the results of the test and field experience^2–4.     

Proline Accumulation during Water Stress in Resurrection Plants

In leaves of resurrection plants dried intact, free prolineincreased in nine species and remained unchanged or declinedin two other tolerant species. Infiltration of proline into hydrated resurrection leaves oftwo species (a relatively high accumulator of proline, Borya,and low accumulator, Myrothamnus) prior to dehydration did notimprove the cells' survival rate, and in some cases caused adecrease in survival. These data indicate that the extreme drought tolerance of resurrectionplants is not related per se to proline levels.     

Effect of Potassium on Proline Accumulation in Maize during Wilting

Leaf discs from maize (Zea mays) grown at high as well as low level of potassium, were treated with different concentrations of KC1 for 2 h in light before exposing to wilting conditions. An enhanced accumulation of free proline effected by wilting was observed in potassium treated discs. Although proline accumulation was much less in leaf discs exposed to short-term severe wilting conditions than in those exposed to long-term mild wilting conditions, the effect of potassium was still evident. Under long-term mild wilting conditions, the enhanced effect was greater in leaf discs from plants grown at high level of potassium than in those from plants grown at low levels of potassium. Treatment with NaCl instead of KC1 did not lead to extra accumulation of proline.     

Carbohydrate, Nitrogen and Dry Matter Accumulation and Partitioning of Maize Hybrids Under Drought Stress

Maize (Zea mays L.) productivity under drought stress dependsto some extent upon a hybrid's capacity to produce and translocateassimilate to its developing kernels during the stress periodand/or after the stress is relieved. The objective of this studywas to evaluate differences in carbon and nitrogen accumulationand partitioning under drought stress among maize hybrids thatdiffer in yield potential and/or physiological metabolism duringreproductive development. The hybrids B73 x LH38, FS854, B73xMol7and US13 were subjected to drought stress from the 7th leafstage until pollination was completed, at which time the soilof the stressed plots was replenished with water. For d. wtand chemical constituent determinations, plants of each hybridwere harvested from the irrigated and drought stressed plotsat silking, mid-grain fill, and physiological maturity. Averagedover hybrids, vegetative biomass at silking was reduced 25%as a result of the drought stress treatment, with B73 x LH38and FS854 accumulating more total biomass during the later portionof grain fill than the other two hybrids under both soil moisturetreatments. At silking, the total non-structural carbohydratecontent of the hybrids' vegetative tissue was not changed asa result of drought stress, whereas their reduced nitrogen (N)contents were decreased by an average of 33%. B73 x LH38 andFS854 had greater grain carbohydrate and reduced N contentsunder irrigation and smaller decreases in those variables asa result of soil moisture deficit than did the other two hybrids.These results indicate that the greater drought tolerance ofB73 x LH38 and FS854 to stress imposed during vegetative andearly reproductive development resulted from their more activeN uptake and assimilation and sugar production during the laterportion of grain fill and from their more efficient partitioningof assimilate to the developing kernels. Zea mays L., maize, drought stress, nitrogen, carbohydrates, hybrids, partitioning     

Water Stress Induced Proline Accumulation in Contrasting Wheat Genotypes as Affected by Calcium and Abscisic Acid

Proline accumulation and mobilization in roots of 7-d-old seedlings of wheat genotypes varying in sensitivity towards water stress were compared. Water stress was induced by polyethylene glycol (PEG-6000; osmotic potential −1.5 MPa) in the presence of 0.1 mM abscisic acid (ABA), 1 mM calcium chloride, 0.5 mM verapamil (Ca²⁺ channel blocker), 0.5 mM fluridone (inhibitor of ABA biosynthesis). While both the genotypes did not differ in total proline accumulation, rate of proline accumulation and utilization was higher in tolerant genotype C 306 as compared to susceptible genotype HD 2380. The treatment with ABA and CaCl₂ caused further increase in proline accumulation during stress and reduced its mobilization during recovery. The membrane stability and elongation rate of roots was observed to be higher at ABA and calcium treatment in both the genotypes under stress. As was evident from inhibitor studies, the tolerant genotype was more responsive to ABA and the susceptible one to calcium. This revised version was published online in July 2006 with corrections to the Cover Date.     

Biochemically Triggered Heat and Drought Stress Tolerance in Rice by Proline Application

Journal of Plant Growth Regulation - Abiotic stresses are the prime coercion to sustainable crop production in changing climate scenario. Heat and drought stresses at reproductive as well as...     

Effects of Drought Stress on the Photosynthesis in Maize

To clarify how the components of the entire photosynthetic electron transport chain in response to drought stress in maize. The activities of photosystem II (PSII), photosystem I (PSI), and the electron transport chain between PSII and PSI of maize were investigated by prompt fluorescence (PF), delayed fluorescence (DF) and 820 nm modulated reflection (MR). Maize (Zea mays L.) plants were subjected to different levels of soil water availability including control, moderate and severe drought stress. A significant decrease in ?E₀, Ψ₀ and PI_ABS was found in maize treated with moderate drought stress. A significant increase in ABS/RC was observed, but there were no significant change in the fast MR phase and the amplitude of DF under moderate drought stress compared to the control. Under severe drought stress, the exchange capacity between Q_A to Q_B, reoxidation capacity of plastoquinol, and the oxidation and re-reduction rates of PC and P₇₀₀ all decreased. These results demonstrated that moderate drought stress reduced the photochemical activity of PSII from Q_A to PQH₂, while the photochemical activity of PSI was unscathed. However, severe drought stress inhibited the entire electron transport chain from the donor side of PSII to PSI-end electron acceptors. In addition, the photochemical activity of PSII is more sensitive to drought stress than PSI.     

转GmTMT2a基因玉米抗旱功能分析

生育酚具有很强的抗氧化功能,其中α-生育酚是最有效的组分。研究了α-生育酚含量提高的转GmTMT2a基因植株（TP）和野生型植株（WT）在干旱条件下的响应差异。结果表明,TP植株和WT植株中H2O2 含量均有所增加,但TP植株中累积了更少的H2O2;抗氧化酶类SOD、POD和CAT的酶活测定结果表明,CAT酶活性在TP植株中的增幅最大;抗旱相关基因表达分析结果显示,P5CS和TPS在TP植株中的表达显著上调。推测转GmTMT2a基因后,提高了CAT的酶活以及P5CS和TPS的表达量,进而增强了植株的抗旱性。     

Protein Synthesis as a Requirement for Wound Xylem Differentiation

An increasing rate of protein synthesis was observed during the first 2 days after the isolation of 2 mm thick internodal stem slices of Coleus on a sucrose-agar medium. This rise in the rate of protein synthesis preceeded the first visible signs of wound-vessel member differentiation in the cultured stem slices. Irradiation of tissue slices with 4000 R of x-rays at isolation reduced the numbers of wound-vessel members differentiated after 7 days in culture by 51 per cent, and this level of x-irradiation was observed to inhibit protein synthesis by the cultured stem slices. Treatment of the tissue slices with exogenous auxin (0.05 mg/1) after irradiation did not alter the degree of inhibition of xylem differentiation. Actinomycin D inhibited wound-vessel member differentiation, but it had no effect on the endogenous growth of the cultured stem slices. Similarly, auxin at 0.05 mg/1 was without effect on the endogenous growth rate of the stem slices. Actinomycin D treatment was highly effective in inhibiting xylem differentiation if it was supplied to the tissues within the first 48 hours after isolation; actinomycin D treatment had no significant effect on xylem differentiation when it was given after the first 2 days of culture. Chloramphenicol (10^?3M) inhibited both xylem differentiation and the endogenous growth of the cultured stem slices.     

氧化胁迫下稻苗体内积累的脯氨酸的抗氧化作用

水稻幼苗在外源·OH和1O2氧化胁迫下,体内脯氨酸明显积累,而和H2O2处理对稻苗体内脯氨酸含量无影响。强光亦能诱导稻苗体内脯氨酸积累。脯氨酸预处理则显著抑制·OH、1O2及强光所诱导的稻苗膜脂过氧化作用。在活性氧的产生／检测系统中,脯氨酸对·OH和1O2所引发反应有明显的竞争效应,但对和H2O2的作用没有形响。这些都表明,氧化胁迫下稻苗体内积累的脯氨酸具有抗氧化作用;脯氨酸对活性氧的清除有一定的专一性,即只对·OH和1O2有明显的清除活性。     

NaCl胁迫下海马齿(Sesuvium portulacastrum L.)植株内游离脯氨酸的合成积累途径

以海马齿(Sesuvium portulacastrum L.)为材料,测定了在6个NaCl胁迫水平上(0、0.2、0.4、0.6、0.8、1.0mol· L-1)的植株内游离脯氨酸的含量及其δ-OAT、PSCS、POD、SOD等酶的活性.结果表明:在NaCl胁迫下,海马齿植株内游离脯氨酸积累量比CK显著地增多了14.5％～33.5％,δ-OAT和P5CS活性分别比对照(CK)增强3.1％～10.1％和26.7％ ～46.1％,因此,在NaCl胁迫下海马齿植株内游离脯氨酸合成积累的两个途径均被启动和发生合成积累作用,并表现出以Glu→Pro途径为主,Orn→Pro途径为辅;在5个NaCl胁迫水平上,海马齿植株内游离脯氨酸有显著的积累效应,在0.6 mol·L-1处理水平时达到积累量的高峰值.同时,δ-OAT、P5CS、POD、SOD等酶的活性呈现出与游离脯氨酸积累量有大致相同的变化趋势.     

Proline Accumulation in Maize (Zea mays L.) Primary Roots at Low Water Potentials (I. Requirement for Increased Levels of Abscisic Acid)

We have characterized sulfate transport in the unicellular green alga Chlamydomonas reinhardtii during growth under sulfur-sufficient and sulfur-deficient conditions. Both the Vmax and the substrate concentration at which sulfate transport is half of the maximum velocity of the sulfate transport (K1/2) for uptake were altered in starved cells: the Vmax increased approximately 10-fold, and the K1/2 decreased approximately 7-fold. This suggests that sulfur-deprived C. reinhardtii cells synthesize a new, high-affinity sulfate transport system. This system accumulated rapidly; it was detected in cells within 1 h of sulfur deprivation and reached a maximum by 6 h. A second response to sulfur-limited growth, the production of arylsulfatase, was apparent only after 3 h of growth in sulfur-free medium. The enhancement of sulfate transport upon sulfur starvation was prevented by cycloheximide, but not by chloramphenicol, demonstrating that protein synthesis on 80S ribosomes was required for the development of the new, high-affinity system. The transport of sulfate into the cells occurred in both the light and the dark. Inhibition of ATP formation by the antibiotics carbonylcyanide m-chlorophenylhydrazone and gramicidin-S and inhibition of either F- or P-type ATPases by N,N-dicyclohexylcarbodiimide and vanadate completely abolished sulfate uptake. Furthermore, nigericin, a carboxylate ionophore that exchanges H+ for K+, inhibited transport in both the light and the dark. Finally, uptake in the dark was strongly inhibited by valinomycin. These results suggest that sulfate transport in C. reinhardtii is an energy-dependent process and that it may be driven by a proton gradient generated by a plasma membrane ATPase.     

低温胁迫下氯丙嗪和氯化镧对水稻幼苗脯氨酸积累的影响

低温胁迫下水稻幼苗质膜透性增大、相对含水量(RWC)下降、丙二醛(MDA)含量增加,同时脯氨酸(Pro)积累。以氯丙嗪(CPZ)和氯化镧(LaCl3)对水稻幼苗预处理以阻碍Ca2+·CaM(钙调素)信使传导后,加剧了低温胁迫下水稻幼苗质膜透性的增加、RWC的下降、MDA含量的增加和Pro的积累,说明水稻幼苗受伤害程度将加重。     

Callus Growth and Proline Accumulation in Response to Sorbitol and Sucrose-Induced Osmotic Stress in Rice

This study investigated the influence of osmotic stress, induced by sorbitol and sucrose combinations, on growth and proline accumulation in callus cultures of rice (Oryza sativa L.). Dehusked mature seeds, cv. Hassawi, were induced to callus on MS medium supplemented with 4.52 µM 2,4-dichlorophenoxyacetic acid (2,4-D) and 2.32 µM 6-furfurylaminopurine (kinetin). The medium also contained 29.2, 58.4, 87.6, and 116.8 mM sucrose combined with 0, 54.9, 109.8, and 164.7 mM sorbitol. Callus formation was observed in about 35 % of the cultured seeds irrespective of the sugar treatment. An increase in callus mass was observed as sucrose concentration increased reaching a maximum growth at 87.6 mM. Callus growth was enhanced in response to 54.9 mM sorbitol but at higher concentration it was inhibitory. Best callus growth was obtained on a medium containing 54.9 mM sorbitol combined with 87.6 mM sucrose. Increasing osmotic stress, as a consequence of increasing sucrose and sorbitol concentrations, induced proline accumulation and the highest concentration of proline, 5.8 µmol g^–1(f.m.), was obtained on 164.7 mM sorbitol combined with 116.8 mM sucrose.     

Over-expression of Osmotin Induces Proline Accumulation and Confers Tolerance to Osmotic Stress in Transgenic Tobacco

Osmotin has been implicated in conferring tolerance to drought and salt stress in plants. We have over-expressed the osmotin gene under the control of constitutive CaMV 35S promoter in transgenic tobacco, and studied involvement of the protein in imparting tolerance to salinity and drought stress. The transgenic plants exhibited retarded leaf senescence and improved germination on a medium containing 200mM NaCl. Further, the transgenics maintained higher leaf relative water content (RWC), leaf photosynthesis and free proline content than the wild type plants during water stress and after recovery from stress. When subjected to salt stress (200mM NaCl), the transgenic plants accumulated significantly more proline than the wild type plants. These results suggest the involvement of the osmotin-induced increase in proline in imparting tolerance to salinity and drought stress in transgenic plants over-expressing the osmotin gene.     

盐诱导脯氨酸累积过程中亚胺环己酮的抑制作用

微生物中控制脯氨酸合成的渗透调节基因(osm基因)的转移成功及其抗渗透胁迫能力的提高(Csonka 1980,1981,Le Rudulier和Valentine 1981),启发科学家们把注意力投向高等植物,特别是有经济价值的作物(Bodnar等1989,Nelson等1988,1989,Sanada等1989,Higgins等1987)。采用蛋白质合成抑制剂亚胺环     

Molecular Improvement of Tropical Maize for Drought Stress Tolerance in Sub-Saharan Africa

The C4 grass Zea mays (maize or corn) is the third most important food crop globally after wheat and rice in terms of production and the second most widespread genetically modified (GM) crop, after soybean. Its demand is predicted to increase by 45% by the year 2020. In sub-Saharan Africa, tropical maize has traditionally been the main staple of the diet, 95% of the maize grown is consumed directly as human food and as an important source of income for the resource—poor rural population. However, its growth, development and production are greatly affected by environmental stresses such as drought and salinization. In this respect, food security in tropical sub-Saharan Africa is increasingly dependent on continuous improvement of tropical maize through conventional breeding involving improved germplasm, greater input of fertilizers, irrigation, and production of two or more crops per year on the same piece of land. Integration of advances in biotechnology, genomic research, and molecular marker applications with conventional plant breeding practices opens tremendous avenues for genetic modifications and fundamental research in tropical maize. The ability to transfer genes into this agronomically important crop might enable improvement of the species with respect to enhanced characteristics, such as enriched nutritional quality, high yield, resistance to herbicides, diseases, viruses, and insects, and tolerance to drought, salt, and flooding. These improvements in tropical maize will ultimately enhance global food production and human health. Molecular approaches to modulate drought stress tolerance are discussed for sub-Saharan Africa, but widely applicable to other tropical genotypes in Central and Latin America. This review highlights abiotic constraints that affect growth, development and production of tropical maize and subsequently focuses on the mechanisms that regulate drought stress tolerance in maize. Biotechnological approaches to manage abiotic stress tolerance in maize will be discussed. The current status of tropical maize transformation using Agrobacterium as a vehicle for DNA transfer is emphasized. This review also addresses the present status of genetically modified organisms (GMOs) regulation in sub-Saharan Africa.