Ozone tolerances of soybean cultivars and near‐isogenic lines in a fumigation chamber

Ozone (O₃) toxicity is a potential yield‐limiting factor for soybean (Glycine max L. Merr.) in the United States and worldwide. The most economical solution to the problem is to use O₃‐tolerant cultivars. Thirty‐four cultivars and 87 near‐isogenic lines (NILS) of soybean were screened for O₃ tolerance in a fumigation chamber (250 ppb for three hrs). Most tolerant cultivars tested were ‘Cloud’, ‘T‐276’, ‘T263’, and ‘Kindu’. Moderately tolerant cultivars included ‘Davis’, ‘T‐210’, and ‘Elton’. Most sensitive cultivars were ‘Corsoy 79’, ‘Noir’, and ‘Midwest’. The original ‘Clark’ cultivar was not tested, but ‘Clark 63’ tended to be more tolerant than ‘Harosoy’. The aluminum (Al)‐tolerant ‘Perry’ cultivar also tended toward greater O₃ tolerance than the Al‐sensitive ‘Chief’, as observed earlier. Our rankings of ‘Hark’ as moderately sensitive and ‘Davis’ as moderately tolerant are also in agreement with earlier reports. Among NILS, the order of O₃ tolerance was generally Williams>Clark>Harosoy, but differences were also observed within these parental groups. For example, L68–560 was more tolerant than some other NILS of ‘Harosoy’. ‘L76–1988’ appeared more tolerant to O₃ than other NILS of ‘Williams’, but all ‘Williams’ NILS were more tolerant than most NILS of ‘Harosoy’ and ‘Clark’. Ozone‐tolerant and ‐sensitive soybean cultivars or NILS identified in our study may be useful tools in studies on mechanisms of 03 tolerance and differential 03 tolerances in plants and in the development of ameliorative measures.     

Acid soil tolerance of soybean (Glycine Max L. Merr.) germplasm from the USSR

Nineteen soybean genotypes (ten from the former USSR, two from Brazil and seven from USA) were tested for aluminum (Al) tolerance by growing them for 21 days in greenhouse pots of acid, Al‐toxic, unlimed Tatum (Typic Hapludult) subsoil at pH 4.0 and in limed subsoil at pH 5.1. Aluminum tolerance ranking depended upon the plant traits used in the screening process. Based on absolute dry shoot weights at pH 4.0, Giessener, Brunatna, and St.‐59 (USSR), and Biloxi (USA) were most tolerant; least tolerant entries included Yantarnaya and Smena (USSR), and Davis (USA). Based on relative shoot dry weights (pH 4.0/pH 5.1 %), Giessener, Brunatna, and St.‐59 (USSR) were among the most tolerant, Bossier, Biloxi, Essex, and Perry were intermediate, and Salute 216 (USSR), Chief (USA), and Santa Rosa and IAC‐9 (Brazil) were more sensitive to the acid soil. Based on absolute root dry weights, Giessener, and St.‐59 (USSR), and Biloxi (USA) were among the most tolerant and Smena, Yantarnaya and Salute 216 (USSR), and Chief (USA) were most sensitive. Based on relative root dry weights (pH 4.0/ pH 5.1 %), Giessener was most tolerant and Smena and Salute 216 least tolerant.

Preliminary evidence indicated that soybean entries screened for Al tolerance on acid Tatum soil also differed in tolerance to naturally occurring levels of ambient ozone in greenhouses at Beltsville. The Russian entries VNIIS‐2, Giessener, and Brunatna appeared more sensitive than USA entries Perry, Biloxi, Davis, and Bossier (USA), and Santa Rosa (Brazil). Aluminum tolerance and ozone tolerance appeared to coincide in the Perry genotype. Studies on Al‐ozone‐soybean genotype relationships are being continued at Beltsville.     

Interaction Between Ozone Exposure and Iron Nutrition in Two Tobacco Cultivars

The initial objective was to confirm evidence, obtained from field grown plants, for iron (Fe) accumulation in leaves under ozone exposure. Tobacco plants were grown in pots under either open air or growth chamber conditions. The ozone-sensitive cultivar Bel W3 showed symptoms of ozone injury only when grown outside, while the cultivar Virginia never developed symptoms. In both cultivars, basal leaves of plants grown outside had higher concentration of Fe, but not of manganese (Mn) or zinc (Zn), than those from the growth chamber. Results suggest an interference of the oxidative stress with the mechanisms regulating Fe homeostasis. A second objective was to test whether differences in tolerance to ozone correspond with differences in tolerance to Fe toxicity. Iron toxicity was induced by supplying an excess of Fe-EDTA to plants, grown hydroponically in a growth chamber, upon partial root cutting. Symptoms in leaves were more severe in Bel W3 than in Virginia, which suggested that mechanisms of tolerance to ozone were also effective against Fe toxicity. In both cultivars, a good correlation was determined between Fe accumulation and ethylene production in the leaves.     

Role of water stress in differential aluminum tolerance of six sunflower cultivars grown in an acid soil

Six cultivars of sunflower (Helianthus annuus L.), were screened under controlled environmental conditions for tolerance to Al stress and water stress imposed separately and in combination with one another. Plants were grown for 4 weeks in waxed cartons containing 1 kg of acid, Al‐toxic Tatum, subsoil (clayey, mixed, thermic, Typic Hapludult) at high (pH 4.3) or low (pH 6.3) Al stress. During the final 2 weeks they were also subjected to low (‐20 to ‐40 kPa) or high (‐60 to ‐80 kPa) water stress. Plant growth responses and symptoms of Al toxicity suggested that a wide range of cultivar sensitivity existed. ‘Manchurian’, ‘S‐212’, ‘S‐254’, and ‘S‐265’ were relatively tolerant to Al toxicity while cultlvars ‘Romania HS‐52’ and ‘RM‐52’ were extremely sensitive. Under high Al stress and high water stress, chloroplasts in cells from the Al‐sensitive cultivar ‘Romania HS‐52’ were smaller and contained less starch than chloroplasts from the Al‐tolerant cultivar ‘Manchurian’. Furthermore, the smaller chloroplasts tended to have fewer grana stacks per unit area than did the chloroplasts from tolerant plants. These differences were not apparent when the Al‐sensitive cultivar was grown either in the absence of Al or water stress. In general, Al‐sensitive cultivars of sunflower were more tolerant to water stress than were Al‐tolerant cultivars. Increasing the soil moisture level reduced Al toxicity in Al‐sensitive cultivars. Similarly, decreasing Al stress partially overcame the detrimental effects of high water stress. Hence, Al stress and water stress are interrelated factors which must be considered in the characterization and breeding of plants for better adaptation to acid soils.     

Effects of excess soil manganese on stomatal function in two soybean cultivars

Manganese tolerant ‘Lee’ and Mn sensitive ‘Forrest’ soybean cultivars were grown in a potting soil with no known Mn toxicity and in Loring soil treated with excess Mn. Manganese toxicity in Loring soil was induced by the addition of Mn at 0, 100, 200 and 400 ug g^‐1 as MnSO₄.H₂O. A preliminary experiment was conducted to determine the appropriate Mn stress levels for Lee and Forrest soybean cultivars in Loring soil. Because the Loring soil produced severe Mn toxicity in both cultivars, even with an intial pH of 4.9 and no added Mn, CaCO₃ (2 g kg^‐1 ) was added to Increase the pH to 6–6.3. Soil was analysed for extractable and water soluble Mn and plants for Mn, Ca and Fe.

A second experiment was conducted to determine the effect of Mn toxicity on stomatal function. The procedure was the same as in the first experiment except that the CaCO₃ treatment was 2.5 g kg^‐1 to raise soil pH to 6.2 ‐6.5. Plants were grown in a greenhouse for 10 days and then moved to a growth chamber before making stomatal conductance measurements. A steady state porometer (LI 1600) was used. Results indicated that Mn toxicity closed stomates and decreased transpiration rates. This effect was more pronounced in Mn sensitive Forrest than in Mn tolerant Lee.     

酸性磷酸酶活性与大豆耐低磷能力的相关研究

在水培条件下研究了11个南方春大豆地方品种和育成品种对低磷胁迫反应的差异及其与酸性磷酸酶活性（APA）的相关关系。结果表明，不同大豆品种的地上部干重、根干重、植株全磷和全氮积累量差异极显著（P＜0.01），表现出品种间耐低磷的差异性。大豆品种地上部干重、根干重、植株全磷和全氮量与APA的相关性均达到显著或极显著水平。APA是大豆品种磷效率的一种机制，它可作为耐低磷品种筛选的一个生化指标。     

大豆品种耐低磷和对磷肥效应的遗传差异

大豆不同品种对低磷胁迫和磷肥效应有显著的遗传差异。低磷胁迫下,苗期植株叶片酸性磷酸酶活性（APA）和叶面积与品种的子粒产量呈极显著相关;APA、叶面积、干物质量和氮积累量与生物学产量呈显著或极显著相关。但在施磷条件下,它们之间则无相关关系。这表明APA、叶面积、干物质量和氨积累量可作为耐低磷基因型的筛选指标。试验表明,耐低磷能力弱的品种对磷肥反应更为敏感。在低磷和施磷条件下产量均较高的品种也是存在的,它们对不同的磷素营养环境有着广泛的适应性,进一步挖掘这类基因型很有意义。     

Aluminum toxicity and high bulk density: Role in limiting shoot and root growth of selected aluminum indicator plants and eastern gamagrass in an acid soil

Abstract

Shallow rooting and susceptibility to drought are believed to be caused, at least in part, by strongly acidic (pH <5.5, 1:1 soil‐water), aluminum (Al)‐toxic subsoils. However, this hypothesis has not been clearly confirmed under field conditions. The Al toxicity hypothesis was tested on a map unit of Matawan‐Hammonton loam (0–2% slope) on unlimed and limed field plots (pH range 5.1 to 5.8) at Beltsville, MD, during 1994 to 1998. Aluminum‐tolerant and sensitive pairs of barley (Hordeum vulgare L.), wheat [Triticum aestivum (L.)], snap bean (Phaseolus vulgaris L.), and soybean [Glycine max (L.) Merr.] cultivars were used as indicator plants. Eastern gamagrass [Tripsacum dactyloides (L.) L.], cultivar ‘Pete’, reported to tolerate both chemical and physical stress factors in soils, was grown for comparison. Shoots of Al‐sensitive ‘Romano’ snap beans showed a significant response to liming of the 0–15 cm surface layer, but those of Al‐tolerant ‘Dade’ did not, indicating that Al toxicity was a growth limiting factor in this acid soil at pH 5.1. Lime response of the Al‐tolerant and sensitive cultivars of barley, wheat, and soybean were in the same direction but not significant at the 5% level. Aluminum‐tolerant and sensitive cultivars did not differ in abilities to root in the 15–30 cm soil depth. Only 9 to 25% of total roots were in this layer, and 75 to 91% were in the 0–15 cm zone. No roots were found in the 30–45 cm zone which had a pH of 4.9. Soil bulk density values of 1.44 and 1.50 g cm^?3 in the 15–30 and 30–45 cm zones, respectively, indicated that mechanical impedance was a primary root barrier. Results indicated that restricted shoot growth and shallow rooting of the Al‐indicator plants studied in this acid soil were due to a combination of Al toxicity and high soil bulk density. Confounding of the two factors may have masked the expected response of indicator plants to Al. These two growth restricting factors likely occur in many, if not most acid, problem subsoils. Studies are needed to separate these factors and to develop plant genotypes that have tolerance to multiple abiotic stresses. Unlike the Al indicator cultivars, eastern gamagrass showed high tolerance to acid, compact soils in the field and did not respond to lime applications (pH 5.1–5.8).     

Magnetic resonance imaging of absorbed aluminum in alfalfa roots

An estimated 30% of the world's arable soils are acidic and aluminum (Al) toxicity is often the primary growth‐limiting factor. Excess Al is especially undesirable in sub‐soils because it reduces rooting depth and branching and predisposes plants to drought injury. Liming the plow layer does not generally neutralize subsoil phytotoxicity and Al‐tolerant cultivars offer an alternative or supplemental solution to the problem. Genetic diversity for acid soil tolerance in alfalfa (Medicago sativa L.) is limited and a better understanding of the basic tolerance mechanisms would facilitate the design of more efficacious breeding procedures. Evidence is accumulating that organic acids and proteins elicited by Al stress may complex and detoxify Al either within, or external to, the root. Because Al is a paramagnetic element that can reduce T2 relaxation times (inter‐proton interactions) markedly, the mechanism of Al tolerance in alfalfa was investigated through T2‐based Magnetic Resonance Imaging (MRI) of young lateral root sections of an Al‐sensitive and an Al‐tolerant alfalfa clone grown in nutrient solution (0 or 111 μmol Al; pH 4.5). Root sections that developed under phytotoxic levels of Al accumulated considerable Al in the epidermis and internal root tissue. Aluminum may have been complexed by low molecular weight proteins and organic acids in the tolerant clone whereas the sensitive clone appeared to have abundant free Al; however, variation among replications indicates that free Al may still have been present in tolerant roots and that other tolerance mechanisms may also be important. Root buds accumulated little Al compared to the remainder of the root, indicating that the pronounced effects of Al on lateral root development are indirect. Magnetic Resonance Imaging images evaluated in this study provided clues to the basic mechanisms of Al tolerance in alfalfa and, with further refinement, could be used as one criterion for selecting Al‐tolerant plants.     

Effects of water deficit and manganese toxicity on two cultivars of soybeans (Glycine max (L.) Merr.: Possible applications in remote sensing

The effects of water deficit and excess Mn on leaf temperatures of two soybean cultivars were tested in greenhouse experiments on Mn toxic Loring soil. Cultivars used were Mn sensitive Forrest and Mn tolerant Lee. Water stress was created by withholding known amounts of water for a period of 12–24 hours. The untreated Loring soil produced Mn toxicity in Forrest but not in Lee. Hence, Mn was added as MnSO₄‐H₂O to induce toxicity in both cultivars; Mn treatments were 0 and 200 ug g‐1 for Forrest and 0 and 600 ug g‐1 for Lee. Both Mn and water stress increased leaf temperature. The interaction of water stress and Mn stress on leaf temperature could not be distinguished because both increased leaf temperature. Hence, under field conditions the detection of Mn induced leaf temperature change requires that water stress effects be eliminated. However, the effects of water stress on leaf temperature alone would be useful in assessing drought damage to crops. Since leaf temperature differences can be detected by remote sensing techniques, the results of this experiment will assist in the interpretation of remote sensing data.     

Varietal tolerance of zinc toxicity in peanuts

Peanuts (Arachishypogaea) are more susceptible to zinc (Zn) toxicity than other crops. However, there is potential for rapid evolution of Zn tolerance in many species. The objectives of this study were to test a nutrient solution screening procedure for identifying Zn tolerant cultivars and to identify plant characteristics and cultivars which have potential for Zn tolerance. Florunner was used as the test cultivar to determine the optimum Zn and pH levels for the nutrient solution cultivar screening test. The screening test showed that VA 81B and NC 6 (both virginia‐type peanuts) were more Zn sensitive than Florunner and that N. M. Valencia C and McRan (both valencia‐type peanuts) were more tolerant than Florunner. Field tests were carried out at three locations in Tift County, Georgia: Gibbs Farm (1986–87), Richards Farm (1991), and Stephens Farm (1992). Two out of four field tests did not have adequate soil Zn levels to test Zn tolerance; soil pH between 5.0 and 5.5 and Mehlich 1 soil Zn level ranging from 15–20 mg/kg should be adequate for cultivar screening in the field. Spanish‐type cultivars (Pronto, Spanco, and Starr) had the lowest toxicity ratings and highest yields (Gibbs, 1987), but yields were not economically viable for any cultivars. Aboveground plant Zn or calcium (Ca): Zn ratio were not good indicators of cultivar tolerance. However, low hull Zn concentration, high hull Ca: Zn ratio, and high plant Zn: root Zn ratio correlated well with high yield and low toxicity rating. Minimization of Zn uptake by the hulls would evidently be beneficial in aiding peanut plants in tolerating high soil Zn levels while producing economic yields.     

黑豆种质苗期耐荫性评价及其根系对弱光胁迫的响应

玉米-大豆复合种植是西南地区重要的生态种植模式之一,而目前耐荫型专用黑豆种质十分匮乏,黑豆的耐荫机理也尚不清楚,这严重影响了该模式的进一步推广。本研究旨在建立黑豆苗期耐荫性评价数学模型,筛选出能够判断黑豆耐荫性的有效指标,并探讨不同耐荫型黑豆根系对弱光胁迫的响应差异,为耐荫型黑豆种质的选育及耐荫机理的阐释奠定基础。试验以23个黑豆种质为研究材料,采用盆栽试验方法,设置自然光和遮荫2个处理。在黑豆植株V3期测定株高、茎粗、下胚轴长度、叶片干重、茎干重、主茎节数、总根长、根表面积、总根体积等形态指标和光合参数、叶绿素荧光参数等生理指标。采用多元统计方法建立黑豆苗期耐荫性评价模型,并根据评价结果,关联分析不同耐荫型黑豆根系对弱光胁迫的响应差异。通过逐步回归分析建立了黑豆苗期耐荫性评价数学模型;并通过该模型,筛选出蒸腾速率、株高、叶干重、最大荧光强度和初始荧光强度等5个鉴定指标。在荫蔽条件下测定苗期黑豆的上述5个指标可实现对黑豆苗期耐荫性的综合评价。同时,对23份黑豆种质的耐荫性综合评价值D进行了聚类分析,结果表明,黑豆种质可划分为耐荫型、中度耐荫型和荫蔽敏感型3类。不同耐荫型黑豆种质的根系结构对弱光胁迫的响应程度不同,黑豆的总根长、根表面积、总根体积、根干重等根系强度指标均表现为耐荫型中度耐荫型荫蔽敏感型。这表明耐荫潜力大的黑豆根系更发达。     

The changes in physiological and biochemical traits of Tibetan wild and cultivated barley in response to low phosphorus stress

Low phosphorus (LP) limits crop growth and productivity in the majority of arable lands worldwide. Here, we investigated the changes in physiological and biochemical traits of Tibetan wild barleys (Hordeum vulgare L. ssp. spontaneum) XZ99 (LP tolerant), XZ100 (LP sensitive), and cultivated barley ZD9 (moderately LP tolerant) under two phosphorus (P) levels during vegetative stage. These genotypes showed considerable differences in the change of biomass accumulation, root/shoot dry weight ratio, root morphology, organic acid secretion, carbohydrate metabolism, ATPase (Adenosine triphosphatase) activity, P concentration and accumulation under LP in comparison with CK (control) condition. The higher LP tolerance of XZ99 is associated with more developed roots, enhanced sucrose biosynthesis and hydrolysis of carbohydrate metabolism pathway, higher APase (Acid phosphatase) and ATPase activity, and more secretion of citrate and succinate in roots when plants are exposed to LP stress. The results prove the potential of Tibetan wild barley in developing barley cultivars with high tolerance to LP stress and understanding the mechanisms of LP tolerance in plants.     

Zinc alleviates growth inhibition and oxidative stress caused by cadmium in rice

A hydroponic experiment with two rice cultivars differing in cadmium (Cd) tolerance was conducted to investigate the alleviating effect of zinc (Zn) on growth inhibition and oxidative stress caused by Cd. Treatments consisted of all combinations of two Zn concentrations (0.2 and 1 μM), three Cd concentrations (0, 1, and 5 μM), and two rice cultivars (Bing 97252, Cd‐tolerant; Xiushui 63, Cd‐sensitive). Cd toxicity caused a dramatic reduction in plant height and biomass, chlorophyll concentration and photosynthetic rate, and an increase in Cd concentration in both roots and shoots, malondialdehyde (MDA) concentration, and superoxide dismutase (SOD) and peroxidase (POD) activities in shoots. The response of all these parameters was much larger for Xiushui 63 than for Bing 97252. Addition of Zn to the medium solution alleviated Cd toxicity, which was reflected in a significant increase in plant height, biomass, chlorophyll concentration, and photosynthetic rate, and a marked decrease in MDA concentration and activity of anti‐oxidative enzymes. However, it was noted that Zn increased shoot Cd concentration at higher Cd supply, probably due to the enhancement of Cd translocation from roots to shoots. Therefore, further studies are necessary to determine the effect of Zn supply on Cd translocation from vegetative organs to grains or grain Cd accumulation before Zn fertilizer is applied to Cd‐contaminated soils to alleviate Cd toxicity in rice.     

Differential aluminum tolerance in some tropical rice cultivars. II. mechanism of aluminum tolerance

Ten‐day‐old seedlings of 22 rice (Oryza sativa L.) cultivars were subjected to aluminum (Al) stress in nutrient solutions with an initial pH of 4.0±0.1. The rice cultivars exhibited a wide range of response by changing the rhizosphere pH, and the uptake and efficiency ratio (ER) of utilization of nutrients both in the presence (222 μM Al) and absence of Al. In the presence of Al, the cultivars Co 37 and Basmati 370 recorded maximum uptake and highest ER's for calcium (Ca), potassium (K), magnesium (Mg), manganese (Mn), phosphorus (P), and iron (Fe). The cultivars Damodar and ADT 36 performed very poorly in terms of nutrient uptake. The tolerant cultivars (Al‐insensitive) efficiently took up and utilized Ca and P in the presence of Al. The susceptible (Al‐sensitive) and intermediate cultivars exhibited less Ca and P uptake and utilization. There was no apparent relationship between foliar Al content and the efficiency ratios. However, the Al‐tolerant cultivars, Co 37 and Basmati 370, accumulated less Al in their foliage which was the reverse in case for the Al‐susceptible cultivars. Among the 22 rice cultivars tested, Co 37 and Basmati 370 emerged as the most Al‐tolerant. Hence, they would be recommended for cultivation in acidic, infertile soils of the tropics. The results of this study are discussed in terms of identifying the mechanism of Al tolerance or sensitivity among the studied rice cultivars as related to their nutrient metabolism.     

The response of wildtype and mutant cultivars of soybean to salt stress - comparing vegetative and reproductive phases on the basis of leaf biochemical contents,RWC, and stomatal conductance

Soybean, as a major oilseed crop, is cultivated in many parts of the world including saline-affected regions. A four-replicated factorial experiment based on a completely randomized design with five salinity levels (control, 50, 100, 150, and 200 mM NaCl) and five wild-type and new mutant cultivars of soybean (Williams, Clark, M-4, M-7, and M-9) was done at two vegetative and reproductive phases to study leaf oxidants, antioxidants and osmolytes under salinity stress. The vegetative phase demonstrated higher K⁺:Na⁺ ratio, cell membrane stability, relative water content (RWC) and stomatal conductance to H₂O (gs) accompanied with lower oxidative stress, antioxidants and osmolytes contrasting to reproductive phase. At both phenological phases, saline stress stimulated antioxidative defense owing to the enhancement of oxidative stress. The results indicated that mutants possessed a better antioxidative system than their wild-types.     

Effects of Potassium Sulfate on Adaptability of Sugarcane Cultivars to Salt Stress under Hydroponic Conditions

The effect of potassium sulfate (K₂SO₄) on adaptability of sugarcane to sodium chloride (NaCl) stress was investigated under hydroponic conditions. Two sugarcane cultivars, differing in salinity tolerance, were grown in half strength Johnson's solution at 80 mM NaCl with 0, 2.5 and 5.0 mM potassium (K) as K₂SO₄. Salinity disturbed above and below-ground dry matter production in both sugarcane cultivars. However, salt sensitive cultivar showed more reduction in shoot dry matter and higher root:shoot ratio compare to the salt tolerant cultivar under. Application of K significantly (p < 0.05) improved dry matter production in both sugarcane cultivars. The concentration of Na was markedly increased with increasing salinity; however, the application of K reduced its uptake, accumulation and distribution in plant tissues. Salinity induced reduction in K concentration, K-uptake, K utilization efficiency (KUE) and K:Na ratio in both sugarcane cultivars was significantly improved with the addition of K to the saline growth medium.     

Effects of Boron on Aluminum Toxicity on Seedlings of Two Soybean Cultivars

Boron (B) is an essential micronutrient for higher plants. It has been suggested that addition of B at an optimal concentration might alleviate Al toxicity. Little information is available about B effects on soybean seedling growth under Al stress and differential alleviation of B on Al toxicity. In the present study, the seedlings of two soybean cultivars (Williams and Nanrong 73-935) were grown in a solution with factorial combinations of Al (0, 2, and 5 mM) and B (0, 5, and 50 μM) in a randomized complete block design experiment for 18 days. The results showed that high B was found to ameliorate Al toxicity by significantly increasing the growth characters including root length under 2 mM Al stress, and epicotyl length and fresh weight under 5 mM Al stress of the two cultivars. However, high B concentration did not significantly increase chlorophyll content under Al stress. Williams was more sensitive than Nanrong 73-935 on the growth characters and chlorophyll content under double stresses (B deficiency combined with Al toxicity), although they had similar sensitivity to B deficiency stress alone for growth characters. In addition, high B concentration was found to cause toxicity symptoms on root length and older leaves of both cultivars under no Al stress.     

Varietal diversity of upland rice in sensitivity to aluminium

A rapid and simple nutrient addition technique was used for evaluating Al tolerance of six local upland rice (Oryza sativa L.) cultivars (BG35, BR21, DA25, DA26, DA14, and DA22) from Bangladesh and three IRRI rice, IR46, IR97, and IR45, cultivars from the Philippines. The plants were grown for 21 days with Al (0 μM, 140 μM, 280 μM or 560 μM) at pH 4.1. The roots were more affected by Al than the shoots. In rating cultivars for Al sensitivity, relative shoot weight (RSW) was found to be the best parameter due to the severe damage of the roots, irrespective of Al sensitivity. The cultivars were rated as Al tolerant (BG35, BR21, DA25, and DA26), mid‐tolerant (DA14, DA22, and IR46) and sensitive (IR97 and IR45) . More Al was retained in the roots of tolerant cultivars than in the mid‐tolerant or sensitive cultivars. In shoots, the Al concentration of tolerant cultivars was less than in the mid‐tolerant or in the sensitive cultivars and the inhibition of growth was proportional to Al concentration irrespective of Al tolerance. Therefore, the variation among cultivars in Al sensitivity could be related to the capacity of roots to retain Al from transport to the shoots.     

拔节期干旱胁迫下冬小麦品种间产量及生理响应的差异

拔节期干旱是影响冬小麦产量的重要灾害,揭示不同品种对干旱胁迫生理响应的差异,可为鉴选与培育抗旱品种提供指导。选取黄淮海平原不同冬麦区种植面积较大的晋麦47、洛旱2号、石家庄8号、豫麦18和郑麦9023共5个品种和1个抗逆性较弱的品种偃麦20,利用防雨棚开展盆栽试验研究。从籽粒产量以及气孔特性、膜稳定性和渗透调节特性等方面,分析拔节期受水分胁迫后,各品种抗旱性和干旱胁迫响应途径的差异。结果表明:(1)灌溉条件下,晋麦47、洛旱2号和石家庄8号产量较高,豫麦18和偃麦20产量较低。拔节期受干旱胁迫后,晋麦47、洛旱2号和豫麦18产量较高,石家庄8号和偃麦20产量较低。可见,以籽粒产量为抗旱性评价的核心指标,晋麦47、洛旱2号和豫麦18抗旱性较强,石家庄8号和偃麦20抗旱性较弱,郑麦9023抗旱性居中。(2)3个抗旱品种间干旱胁迫响应途径并不一致。与抗旱性较弱的石家庄8号和偃麦20相比,拔节期干旱胁迫下,豫麦18气孔导度较低,气孔调节能力强;洛旱2号细胞渗透势较低,渗透调节能力较强;洛旱2号膜离子渗漏率较低,膜稳定性较强;晋麦47在气孔调节、渗透调节和膜稳定性调节方面与抗旱性较弱的品种无显著差异。研究结果说明,冬小麦品种间响应干旱胁迫的关键途径存在差异。因而品种的抗旱性难以通过单一生理指标科学评价,需要多指标联合鉴定。