Physiological and biochemical adaptations of Cynodon dactylon (L.) Pers. from the Salt Range (Pakistan) to salinity stress

Naturally adapted salt tolerant populations provide a valuable material for exploring the adaptive components of salt tolerance. Under this aspect, two populations of Cynodon dactylon (L.) Pers. were subjected to salt stress in hydroponics. One was collected from a heavily salt-affected soil in the vicinity of a natural salt lake, Uchhali Lake, in the Salt Range of the Punjab province of Pakistan, and the other from a normal non-saline habitat from the Faisalabad region. The NaCl treatments in Hoagland's nutrient solution were: Control (no salt), 50, 100, 150 and 200 mM of NaCl. After 8 weeks of growth in hydroponics produced biomass, ion relations, and photosynthetic capacity were measured in the differently adapted ecotypes. In the ecotype of C. dactylon from the Salt Range, shoot dry weight was only slightly affected by varying levels of salt. However, in contrast, its root weight was markedly increased. On the other hand, the ecotype from Faisalabad (non-saline habitat) showed a marked decrease in shoot and root dry weights under saline regimes. The ecotype from the Salt Range accumulated relatively less amount of Na⁺ in the shoot than did that from Faisalabad, particularly at higher salt levels. Shoot or root K⁺ and Ca²⁺ contents varied inconsistently in both ecotypes under salt stress. All the photosynthetic parameters, leaf water potential and osmotic potential, and chlorophyll content in both ecotypes were adversely affected by salt stress, but all these physiological attributes except turgor potential and soluble sugars were less affected at high salinities in the salt tolerant ecotype from Salt Range. This ecotype accumulated significantly higher organic osmotica (total free amino acids, proline, total soluble proteins, and total soluble sugars) under saline conditions than its intolerant counterpart. Overall, the salt tolerant ecotype of C. dactylon from the Salt Range showed high salt tolerance due to its restricted uptake of Na⁺ accompanied by an increased uptake of K⁺ and Ca²⁺ in the roots as well as shoot due to its higher photosynthetic capacity and accumulation of organic osmotica such as free amino acids and proline under saline conditions.     

Anatomical and physiological characteristics relating to ionic relations in some salt tolerant grasses from the Salt Range,Pakistan

Populations of three salt tolerant forage grasses (Cynodon dactylon, Imperata cylindrica, and Sporobolus arabicus) were collected from the salt-affected soils of the Salt Range and normal non-saline soils of the Faisalabad region to assess their mechanism of adaptation to saline stress by determining ion relations and some specific anatomical modifications. The population of S. arabicus from the Salt Range showed increased growth (root and shoot length, and root and shoot dry weights) under saline conditions. Salt tolerance in this species was related to structural modifications such as increased area of root, stem, leaf blade, and leaf sheath for toxic ion accumulation, increased vesicular hair density in leaves and aerenchyma formation in leaf sheath for ion exclusion. Uptake of toxic ions was high in the Salt Range population of C. dactylon and salt tolerance was related to ion exclusion through specific leaf structural modifications such as vesicular hairs. Salt tolerance in the Salt Range population of I. cylindrica was mainly associated with restricted uptake of toxic Na⁺ and Cl⁻ at root level, and accumulation of toxic ions via increased succulence in leaf blades and leaf sheaths in addition to some excretion of toxic ions through leaf sheath aerenchyma.     

Physiological adaptative characteristics of Imperata cylindrica for salinity tolerance

Two populations of cogongrass [Imperata cylindrica (L.) Raeuschel], one from the saline regions of the Salt Range and the other from the non-saline regions of Faisalabad were assessed for salinity tolerance on the basis of some key morphological and physiological attributes. It was hypothesized that the tolerant population from the Salt Range must have developed some specific structural modifications, which are responsible for its better survival under high salinities. These adaptive components can be effectively used in modern technologies for improving degree of tolerance of other sensitive crops. The population from the Salt Range markedly excelled the Faisalabad population in terms of growth and physiological attributes measured in this study. The Faisalabad population of I. cylindrica was unable to survive at the highest salt level (200 mM NaCl). The tolerance of the Salt Range population to salt stress was found to be related to high accumulation of organic osmotica, particularly total free amino acids and proline as well as Ca²⁺ in the shoot. The distinctive structural modifications in the Salt Range population were found to be enhanced succulence, well-developed bulliform cells in leaves and smaller stomatal area.     

Differential stress responses to NaCl salt application in early- and late-maturing diploid potato (Solanum sp.) clones

Cultivated tetraploid potatoes (Solanum tuberosum L.) are moderately salt sensitive but greater stress tolerance exists in diploid wild types. However, little work has been published on salt-tolerance in diploid potato. This study utilized sensitive and tolerant diploid potatoes as well as a commercially cultivated potato to investigate mechanisms of stress tolerance. Stem cuttings from salt-tolerant (T) and sensitive (S) clones of early-maturing (EM) and late-maturing (LM) diploid potato clones were stressed for 5 days at the tuber initiation stage with 150 mmol NaCl in a hydroponic sand culture under greenhouse conditions. The stress responses of the early- and late-maturing potato clones were distinctly different. Under stress, early-maturing clones accumulated Na⁺ in the leaf tissues while late-maturing clones generally excluded Na⁺ from the leaf tissues. Salt tolerant clones of both maturity types were able to tolerate high levels of Na⁺ in the leaf tissues. The lower leaves accumulated more Na⁺ than the upper leaves in both maturity types. The potassium to sodium ratio was significantly greater in the leaves of the late-maturing types, reflecting differences in Na⁺ accumulation rather than alterations in K⁺ levels. Proline levels increased upon salt exposure but were not clearly associated with salinity tolerance. Tolerance was manifested in maintenance of vegetative growth, tuber yield, and reduced leaf necrosis. These responses require efficient uptake of water and source–sink translocation. Maintenance of stomatal conductance under stress was not associated with these responses but tuber yield was related to lower-leaf osmotic potential (OP) in both early- and late-maturity types. Salt tolerant clones of both maturity types also had less negative tuber OP under salt stress than sensitive types. High yielding EMT and LMT clones either minimized tuber yield loss or even increased yield after exposure to salt stress. Mechanistic studies and screening experiments for salt tolerant clones should consider maturity type, leaf position and source–sink relationships enhancing tuber yield.     

Physiological homeostasis for ecological success of Typha (Typha domingensis Pers.) populations in saline soils

The natural capacity of plants to endure salt stress is largely regulated by multifaceted structural and physio-biochemical modulations. Salt toxicity endurance mechanism of six ecotypes of Typha domingensis Pers. was evaluated by analyzing photosynthesis, ionic homeostasis, and stomatal physiology under different levels of salinity (0, 100, 200 and 300 mM NaCl). Typha populations were collected across different areas of Punjab, an eastern province in Pakistan. All studied attributes among ecotypes presented differential changes as compared to control. Different salt treatments not only affected gas exchange attributes but also shown significant modifications in stomatal anatomical changes. As compared to control, net photosynthetic rate, transpiration rate, total chlorophyll contents and carotenoids were increased by 111%, 64%, 103% and 171% respectively, in Sahianwala ecotype among all other ecotypes. Similarly, maximum water use efficiency (WUE), sub stomatal CO₂ concentration, sodium (Na⁺) and chloride (Cl⁻) contents were observed in Sahianwala (191%, 93%, 168%, 158%) and Knotti (162%, 75%, 146%, 182%) respectively, as compared to the others ecotypes. Adaxial and abaxial stomatal areas remained stable in Sahianwala and Knotti. The highest abaxial stomatal density was observed in Gatwala ecotype (42 mm²) and maximum adaxial stomatal density was recorded in Sahianwala ecotype (43 mm²) at 300 mM NaCl salinity. The current study showed that Typha ecotypes responded varyingly to salinity in terms of photosynthesis attributes to avoid damages due to salinity. Overall, differential photosynthetic activity, WUE, and changes in stomatal attributes of Sahianwala and Knotti ecotypes contributed more prominently in tolerating salinity stress. Therefore, Typha domingensis is a potential species to be used to rehabilitate salt affected lands for agriculture and aquatic habitat.Supplementary InformationThe online version contains supplementary material available at 10.1007/s12298-021-00963-x.     

RESPONSES OF POPULATIONS OF SOLIDAGO SEMPERVIRENS (COMPOSITAE) TO SALT SPRAY ACROSS A BARRIER BEACH

The responses of four populations of Solidago sempervirens to salt spray at Island Beach State Park, a barrier beach in Ocean County, New Jersey, were examined under both field and greenhouse conditions. At increasing distances from the ocean, these populations were Primary Dune (PD), Dune Hollow (DH), Intermediate (INT), and Bayshore (BAY). Salt deposition on cheesecloth traps was found to drop significantly from PD to BAY. Population responses to the salt spray gradient were monitored by examining leaf stomatal and trichome densities, leaf thickness, and the salt spray tolerance of genotypes established in the greenhouse. No significant differences in either stomatal or trichome density were found among populations in the field. Leaf thickness of field plants at the PD site was significantly greater than the DH, INT, or BAY plants: however, unsprayed plants of these populations in the greenhouse did not vary significantly in leaf thickness, and for sprayed plants, leaf thickness varied only in relation to intensity of salt application. Thus, the differences in leaf thickness of field populations were not genetically based. Both nonexpanded and fully expanded leaves of BAY plants consistently showed the greatest percentage leaf damage following both low- and high-intensity artificial salt spray, indicating possible selection for population differences in salt spray tolerance.     

Analysis of salinity effects on basil leaf surface area, photosynthetic activity, and growth

Basil (Ocimum basilicum L.) seedlings were cultured on liquid medium in controlled conditions. Two varieties differing in leaf size were compared. When plants were 30?days old, the medium was supplemented with 50?mM NaCl. After 15?days of treatment, root, stem and leaf biomass, leaf number, and leaf surface area were measured. Ion accumulation was determined in roots, stems, and leaves. Photosynthetic parameters (CO₂ fixation rate, internal CO₂ concentration, stomatal conductance) as well as transpiration rate were determined on separate leaves. Electrolyte leakage and malondialdehyde content were used to estimate damage to membranes and lipid peroxidation, respectively. Several antioxidant enzymatic activities were used as proxies of oxidative stress. High Na⁺ concentration was reached in leaf tissues. Salt restricted whole plant biomass deposition rate by diminishing leaf number and leaf expansion, as well as photosynthetic activity were estimated from whole plant biomass production per unit leaf surface area. Diminished stomatal conductance restricted CO₂ fixation rate, and decrease in chlorophyll content presumably limited photosynthetic activity. Lipid peroxidation revealed damages to membranes. The magnitude of these responses differed between the two varieties, indicating that an intraspecific variability in salt response exists in basil.     

盐胁迫对平欧杂种榛幼苗生长、光合荧光特性及根系构型的影响

以平欧杂种榛3个品种(新榛1号、新榛2号、新榛3号)幼苗为材料,研究不同盐胁迫程度(对照、轻度、中度、重度)对幼苗生长性状、光合荧光特性以及根系构型的影响.结果表明: 3个品种幼苗的新稍长度、基径、叶面积,以及根、茎、叶、总生物量随着盐胁迫的增强而降低,根冠比则增加.中度、重度盐胁迫下3个品种幼苗的净光合速率较对照分别显著降低20.5%和43.2%.轻度、中度、重度盐胁迫下的蒸腾速率和气孔导度较对照分别降低2.0%、16.3%、32.0%和10.2%、35.7%、60.1%.随着盐胁迫的增强,胞间CO₂浓度缓慢上升,水分利用效率呈先上升后下降的趋势,并在轻度盐胁迫下达到最大值.3个品种幼苗的初始荧光随着盐胁迫的增强而升高.最大荧光、最大光化学效率、潜在光化学活性、实际光化学效率、电子传递速率、光化学淬灭系数随着盐胁迫的增强而下降,非光化学淬灭系数则随着盐胁迫的增强先升高后降低.根系构型分析表明,盐胁迫导致3个品种幼苗的根系生物量、长度、表面积和体积下降.同一盐胁迫下,新榛2号各径级根系构型参数的下降幅度低于其他2个品种.平欧杂种榛幼苗生长性状、光合荧光特性以及根系构型参数受品种和盐胁迫程度的双重影响.盐胁迫下新榛2号表现出较强的生长与光合生理适应性,其耐盐性优于其他2个品种.     

Enhanced drought and salt tolerance by expression of AtGSK1 gene in poplar

A GSK3/shaggy-like kinase (AtGSK1) has been implicated in the regulation of drought and salt tolerance. We transferred AtGSK1 from Arabidopsis thaliana to a hybrid poplar (Populus alba × P. tremula var. grandulosa) to determine the effect of the transgene expression in the transgenic trees. The results from northern blot and RT-PCR analyses showed that the expression level varied among the transgenic lines. During their culture on tissue culture media, the transgenic poplars formed vigorous growing roots even in the presence of 125 mM NaCl and callus in the presence of 150 mM NaCl. When the transgenic poplars were growing in pots and provided with NaCl solution, they stayed much healthier than did nontransgenic poplars, showing higher rates of photosynthetic rates, stomatal conductance, and evaporation rates under the stress. Whereas the total level of leaf Na⁺ level increased dramatically in transgenic poplars under severe saline conditions (150 mM NaCl), that of leaf K⁺ decreased in the same plants under the same conditions. Total root Na⁺ level increased in nontransgenic poplars under severe saline conditions. In contrast, total root K⁺ level decreased in the same plants under the same conditions. The chloride content and relative electrical conductivity of the transgenic poplars after salt stress treatment were lower than those of nontransgenic poplars. The transgenic poplars were also tolerant to up to 20 % PEG remaining significantly healthy when compared with nontransgenic poplars with necrosis and chlorosis symptoms. Another dramatic feature of the transgenic poplars was wilting tolerance for prolonged drought treatment up to 2 weeks. The results provide evidence that the expression of AtGSK1 gene conferred drought and salt tolerance in the transgenic poplars.     

Salt stress induced soybean <Emphasis Type="Italic">GmIFS1</Emphasis> expression and isoflavone accumulation and salt tolerance in transgenic soybean cotyledon hairy roots and tobacco

Effects of isoflavones on plant salt tolerance were investigated in soybean (Glycine max L. Merr. cultivar N23674) and tobacco (Nicotiana tabacum L.). Leaf area, fresh weight, net photosynthetic rate (Pn), and transpiration rate (Tr) of soybean N23674 plants treated with 80 mM NaCl were significantly reduced, while a gene (GmIFS1) encoding for 2-hydroxyisoflavone synthase was highly induced, and isoflavone contents significantly increased in leaves and seeds. To test the impact of isoflavones to salt tolerance, transgenic soybean cotyledon hairy roots expressing GmIFS1 (hrGmIFS1) were produced. Salt stress slightly increased isoflavone content in hairy roots of the transgenic control harboring the empty vector but substantially reduced the maximum root length, root fresh weight, and relative water content (RWC). The isoflavone content in hrGmIFS1 roots, however, was significantly higher, and the above-mentioned root growth parameters decreased much less. The GmIFS1 gene was also transformed into tobacco plants; plant height and leaf fresh weight of transgenic GmIFS1 tobacco plants were much greater than control plants after being treated with 85 mM NaCl. Leaf antioxidant capacity of transgenic tobacco was significantly higher than the control plants. Our results suggest that salt stress-induced GmIFS1 expression increased isoflavone accumulation in soybean and improved salt tolerance in transgenic soybean hairy roots and tobacco plants.     

Leaf morphological plasticity and stomatal conductance in three Populus alba L. genotypes subjected to salt stress

The effect of salt stress on leaf morphology and functionality was studied in three Populus alba genotypes differing in tolerance to salinity: 6K3 (sensitive), 2AS11 (moderately tolerant), and 14P11 (tolerant). Plants were subjected to an intense and progressive salt stress from 50 to 250 mM NaCl by 50 mM steps at 10-day intervals. The micromorphological results highlighted phenotypic variation among the three genotypes already in control plants, with the genotype 14P11 having significantly smaller epidermal cells and higher stomatal density. Salt-treated plants modulated differently the expansion of stomata compared with epidermal cells. Regression analysis showed significant correlations between decrease of stomatal area and stomatal conductance (g_s) in genotypes 14P11 and 6K3. So, the common reduction of stomatal area could be an early mechanism to save water in this species. However, only genotype 14P11 showed further significant decrease of this trait under the highest salinity level, combined with a significant reduction in leaf length. In addition, this genotype showed the lowest leaf abscission rate at the end of salt stress period. The genotype 6K3 was severely affected by leaf necrosis and showed the highest leaf abscission rate in salt stress conditions. In the moderately tolerant genotype 2AS11, an intermediate plastic behaviour in both leaf morphology and physiology was observed during the experiment. The phenotypic variation among the three genotypes in terms of micromorphology and stomatal conductance is discussed in relation to plant functionality in salt stress conditions. Overall results suggest that leaf morphological habit contributes to salt tolerance in P. alba.     

Cadmium exclusion a key factor in differential Cd-resistance in Thlaspi arvense ecotypes

Differences in Cd accumulation and Cd tolerance between Thlaspi arvense ecotype Aigues Vives (AV) from a commercial grower in South France and ecotype Jena collected in the polluted urban area of Jena (Germany) were reported here. Ecotype Jena exhibited considerable Cd-tolerance. Shoot and root masses were unaffected and root elongation was even enhanced by exposure to 50 μM Cd. In contrast, growth of ecotype AV was severely affected by this Cd treatment. Ecotype Jena was much more efficient in excluding Cd from both roots and shoots than ecotype AV. Despite the efficient restriction of Cd transport from roots to shoots in Jena, this ecotype maintained high root to shoot transport of Zn and Fe under Cd exposure. Cd supply strongly decreased the activities of antioxidant enzymes in AV, while in the Cd resistant Jena these activities either remained unaffected (SOD, APX) or were increased (CAT) by Cd supply. In conclusion, naturally selected Cd-tolerance in Thlaspi arvense is due to efficient Cd exclusion. The mechanisms underlying exclusion of Cd from the shoots seem Cd-specific yet they did not affect the homeostasis of Fe and Zn in the shoots.     

外源钙离子对东南景天生长及锌积累的影响

采用水培试验,研究了外源添加不同浓度钙离子（Ca²⁺）对两种生态型东南景天生物量、根系形态及体内锌、钙、硫含量的影响.结果表明：随着外源Ca²⁺浓度的上升,两种生态型东南景天的干物质量均增加,且超积累生态型地上部增加显著(P<0.05);超积累生态型根长和根表面积增加,而非超积累生态型降低;超积累生态型根、茎、叶锌含量随着外源Ca²⁺浓度的增加而上升,但各处理间差异不显著(P>0.05),非超积累生态型地上部锌含量显著降低(P<0.05).非超积累生态型根、茎、叶钙含量与外源Ca²⁺浓度呈显著正相关(P<0.05),超积累生态型根系硫含量与外源Ca²⁺浓度呈极显著正相关(P<0.01).外源Ca²⁺对超积累生态型东南景天锌吸收及积累有促进作用,而Ca²⁺浓度的升高抑制了非超积累生态型东南景天对锌的吸收.适当增加外源Ca²⁺可促进超积累生态型东南景天生长,改善其锌积累能力.     

Modulation in growth,photosynthetic efficiency,activity of antioxidants and mineral ions by foliar application of glycinebetaine on pea (Pisum sativum L.) under salt stress

A pot experiment was carried out to explore the role of glycinebetaine (GB) as foliar spray foliar on two pea (Pisum sativum L.) varieties (Pea 09 and Meteor Fsd) under saline and non-saline conditions. Thirty-two-day-old plants were subjected to two levels 0 and 150 mM of NaCl stress. Salt treatment was applied in full strength Hoagland’s nutrient solution. Three levels 0, 5 and 10 mM of GB were applied as foliar treatment on 34-day-old pea plants. After 2 weeks of foliar treatment with GB data for various growth and physiochemical attributes were recorded. Rooting-medium applied salt (150 mM NaCl) stress decreased growth, photosynthesis, chlorophyll, chlorophyll fluorescence and soluble protein contents, while increasing the activities of enzymatic (POD and CAT) and non-enzymatic (ascorbic acid and total phenolics) antioxidant enzymes. Foliar application of GB decreased root and shoot Na⁺ under saline conditions, while increasing shoot dry matter, root length, root fresh weight, stomatal conductance (g _s), contents of seed ascorbic acid, leaf phenolics, and root and shoot Ca²⁺ contents. Of three GB (0, 5, 10 mM) levels, 10 mM proved to be more effective in mitigating the adverse effects of salinity stress. Overall, variety Pea 09 showed better performance in comparison to those of var. Meteor Fsd under both normal and salinity stress conditions. GB-induced modulation of seed ascorbic acid, leaf phenolics, g _s, and root Ca²⁺ values might have contributed to the increased plant biomass, reduction of oxidative stress, increased osmotic adjustment and better photosynthetic performance of pea plants under salt stress.     

古老铅锌矿区生态型东南景天对锌耐性及超积累特性的研究

 植物长期生长在重金属污染的生境中,逐渐进化成不同的生态型。通过调查中国东南部古老Pb/zn矿和非矿山生境中的植物种群,发现生长在古老Pb／Zn矿的东南景天(Sedum alfredii Hance)是一种新的Zn超积累植物。在自然和控制条件下,古老Pb／Zn矿生态型比非矿山生态型植株的茎粗、叶片大、植株高。在矿山土壤Zn有效含量为105.5～325.4mg·kg-1时,矿山生态型东南景天植株地上部Zn含量为4134～5000mg·kg-1;当营养液中Zn浓度为1223.6μmol时,其Zn含量高达2％。在相同Zn浓度下,矿山生态型地上部Zn含量比非矿山生态型高30倍左右。两种生态型体内Zn分布也不同,古老铅锌矿山生态型的不同器官中Zn含量以茎>叶片>根系,而非矿山生态型则以根系>茎>叶片。古老铅锌矿山生态型地上部积累的Zn占植株总积累量的90％以上,其中叶片和茎分别占41.66％±5.46％和54.75％±5.87％;非矿山生态型各器官中积累的Zn远远低于古老铅锌矿山生态型,各器官中积累的Zn以茎>根系>叶片。本研究表明,这两种生态型东南景天的发现,为今后探讨植物耐高Zn胁迫和超积累Zn的微进化过程提供了非常有价值的材料,也为Zn污染土壤的植物修复提供了一种很有潜力的候选材料。     

Assessment of the preventive effect of vermicompost on salinity resistance in tomato (<Emphasis Type="Italic">Solanum lycopersicum</Emphasis> cv. Ailsa Craig)

To determine the effects of vermicompost leachate (VCL) on resistance to salt stress in plants, young tomato seedlings (Solanum lycopersicum, cv. Ailsa Craig) were exposed to salinity (150 mM NaCl addition to nutrient solution) for 7 days after or during 6 mL L^??1 VCL application. Salt stress significantly decreased leaf fresh and dry weights, reduced leaf water content, significantly increased root and leaf Na⁺ concentrations, and decreased K⁺ concentrations. Salt stress decreased stomatal conductance (g_s), net photosynthesis (A), instantaneous transpiration (E), maximal efficiency of PSII photochemistry in the dark-adapted state (F_v/F_m), photochemical quenching (qP), and actual PSII photochemical efficiency (ΦPSII). VCL applied during salt stress increased leaf fresh weight and g_s, but did not reduce leaf osmotic potential, despite increased proline content in salt-treated plants. VCL reduced Na⁺ concentrations in leaves (by 21.4%), but increased them in roots (by 16.9%). VCL pre-treatment followed by salt stress was more efficient than VCL concomitant to salt stress, since VCL pre-treatment provided the greatest osmotic adjustment recorded, with maintenance of net photosynthesis and K⁺/Na⁺ ratios following salt stress. VCL pre-treatment also led to the highest proline content in leaves (50 µmol g^??1 FW) and the highest sugar content in roots (9.2 µmol g^??1 FW). Fluorescence-related parameters confirmed that VCL pre-treatment of salt-stressed plants showed higher PSII stability and efficiency compared to plants under concomitant VCL and salt stress. Therefore, VCL represents an efficient protective agent for improvement of salt-stress resistance in tomato.     

NaCl胁迫对沙棘和银水牛果幼苗生长及光合特性的影响

以沙棘和银水牛果2年生幼苗为试材,设NaCl浓度分别为0、200、400和600 mmol·L^-1,研究NaCl 胁迫对其生长及光合特性的影响.结果表明: 随着NaCl浓度的增加,沙棘和银水牛果幼苗的生物量、单株总叶面积均显著下降,且NaCl浓度越高, 下降幅度越大.不同NaCl浓度处理下,沙棘和银水牛果幼苗根冠比较对照显著增加,比叶质量(LMA)略有降低.随着NaCl浓度的增加和胁迫时间的延长,沙棘和银水牛果叶片净光合速率(P_n)、蒸腾速率(T_r)和气孔导度(G_s)均明显下降, 胞间CO₂浓度(C_i)先降后升,气孔限制值(L_s)和水分利用效率(WUE)则先升后降.P_n下降的原因短期内以气孔限制为主,长期则以非气孔限制因素为主,且树种耐盐性越弱,NaCl浓度越高,由气孔限制转为非气孔限制的时间越早.试验中,沙棘幼苗在600 mmol·L^-1NaCl处理10 d时即出现盐害症状,22 d时全部死亡,而银水牛果可以忍耐600 mmol·L^-1NaCl长达30 d以上,说明银水牛果作为引进树种,其耐盐性较沙棘更强,可能更适合在我国盐碱地大面积推广种植.     

Physiological and biochemical traits involved in the genotypic variability to salt tolerance of Tunisian Cakile maritima

Cakile maritima (family: Brassicaceae) was collected from three provenances belonging to different bioclimatic stages (humid, semi arid and arid) in Tunisia to study their eco‐physiological and biochemical responses to salinity. Seedlings were cultivated on inert sand for 20 days under NaCl treatments (0, 100, 200, 400 mm NaCl). Plant response to salinity was provenance‐ and salt‐dependent. At 100 mm NaCl, growth parameters (leaf biomass, area, number per plant and relative growth rate) were improved in plants from Jerba (originating from arid bioclimatic stage) compared with the control, while growth was reduced in those from Tabarka (from humid area). High salt levels (400 mm NaCl) decreased the plant growth in the three provenances, but plants in Tabarka were the most salt sensitive. The relative salt tolerance of plants from Jerba and Bekalta provenances was associated with low levels of malondialdehyde as well as of electrolyte leakage and endoproteolytic activity. Salt reduced leaf hydration, the decrease in water content being dose‐dependent and more pronounced in Tabarka. Increase in salinity led to significant increase in leaf succulence and decrease in leaf water potential, especially in Jerba plants. The plants from the latter displayed the highest leaf levels of Na⁺ and Cl^?, proline, soluble carbohydrates, soluble proteins, and polyphenols. Overall, the higher salt tolerance of plants from Jerba provenance, and to a lower extent of those from Bekalta, may be partly related to their better capacity for osmotic adjustment and to limit oxidative damage when salt‐challenged.     

Scion and Rootstock Effects on ABA-mediated Plant Growth Regulation and Salt Tolerance of Acclimated and Unacclimated Potato Genotypes

Tolerance of salt stress in potato (Solanum tuberosum L.) increased when the plants were pre-exposed to low concentrations of salt (salt acclimation). This acclimation was accompanied by increased levels of abscisic acid (ABA) in the shoot. To further study the role of roots and shoots in this acclimation process, reciprocal grafts were made between a salt-tolerant (9506) and salt-sensitive ABA(−) mutant and its ABA(+) normal sibling potato genotype. The grafted plants were acclimated with 75 or 100 mM NaCl for 3 weeks and then exposed to 150–180 mM NaCl, depending on the salt tolerance of the rootstock. After 2 weeks of exposure to the salt stress, the acclimated and unacclimated plants were compared for physiologic and morphologic parameters. The response to the salt stress was strongly influenced by the rootstock. The salt-tolerant 9506 rootstock increased the salt tolerance of scions of both the ABA-deficient mutant and its ABA(+) sibling. This salt tolerance induced by the rootstock was primarily modulated by salt acclimation and manifested in the scion via increased plant water content, stem diameter, dry matter accumulation, stomatal conductivity, and osmotic potential, and is associated with a reduction in leaf necrosis. There was also a pronounced scion effect on the rootstock. Using 9506 as a scion significantly increased root fresh and dry weights, stem diameter, and root water content of ABA(−) mutant rootstocks. Specific evidence was found of the role of exogenous ABA in the enhancement of water status in grafted plants under salt stress beyond that of grafting alone. This was verified by more positive stomatal conductivity and upward water flow in ABA-treated grafted and nongrafted plants and the absence of upward water flow in nontreated grafted plants through NMR imaging. Grafting using either salt-tolerant scions or rootstocks with inherently high ABA levels may positively modify subsequent responses of the plant under salt stress.