Autophagic flux analysis of Arabidopsis seedlings exposed to salt stress

In plant cells, autophagy is required for efficient recycling of cytoplasmic macromolecules in vacuoles. It was previously shown that autophagy-deficient mutants also exhibited hypersensitivity to various abiotic stresses, such as salt, osmotic changes, heat, drought, and oxidative damage. However, it has not been clearly determined whether autophagy is induced or inhibited by these environmental stressors. Using the GFP-ATG8 (green fluorescent protein fused to AUTOPHAGY-RELATED PROTEIN 8) processing assay and confocal microscopy, we assessed autophagic flux of Arabidopsis seedlings exposed to salt stress. Treatment with 150 mM NaCl resulted in an increase in the processing of GFP-ATG8. Notably, the effects of concanamycin A, an inhibitor of vacuolar proton pumps, on GFP-ATG8 processing indicated that the apparent increase in GFP-ATG8 processing by salt-induced stress was due to inefficient vacuolar degradation of the GFP moiety processed from GFP-ATG8. Salt and osmotic stresses did not increase the abundance of autophagic vesicles in the root cells. Although NaCl, KCl, and mannitol did not greatly inhibit the vacuolar trafficking of GFP-ATG8, LiCl partially inhibited autophagy. These data indicated that NaCl stress neither increases nor substantially inhibits autophagic flux. Our work illustrates the importance of autophagic flux analysis to assess the effect of abiotic stresses on plant autophagy.     

Applications of ascorbic acid or proline increase resistance to salt stress in barley seedlings

The present study was carried out to examine the effects of seed soaking in 1 mM ascorbic acid (AA) or 1 mM proline on the growth, content of photosynthetic pigments and proline, relative water content, electrolyte leakage, antioxidant enzymes and leaf anatomy of Hordeum vulgare L. Giza 124 seedlings grown in greenhouse under 100 or 200 mM NaCl. The plants exposed to the NaCl stress exhibited a significant reduction in growth, relative water content, leaf photosynthetic pigments, soluble sugars, as well as alterations in leaf anatomy. However, the treatment with AA or proline ameliorated the stress generated by NaCl and improved the above mentioned parameters. NaCl increased electrolyte leakage, proline content, and activities of antioxidant enzymes (SOD, CAT, and POX). The antioxidant enzymes and leaf anatomy exhibited considerable changes in response to AA or proline application in the absence or presence of NaCl.     

Endogenous brassinosteroids in microalgae exposed to salt and low temperature stress

Brassinosteroids are part of the hormonal network that regulates growth processes and stress responses in plants. There is evidence for a similar hormonal network in microalgae. In the present study, six microalgae (Chlorococcum ellipsoideum, Gyoerffyana humicola, Nautococcus mamillatus, Acutodesmus acuminatus, Protococcus viridis and Chlorella vulgaris) were subjected to salt and low temperature stress with the addition of 36 g l^–1 NaCl and transfer from 25°C to 15°C. There was a rapid response to salt stress with the brassinosteroid content (mainly castasterone with lower amounts of brassinolide, homocastasterone and typhasterol) increasing within 30 min of the salt treatment and remaining at these elevated levels after 7 h. The decrease in temperature had little effect on the brassinosteroid content. This was the first study to show that endogenous brassinosteroids increase in response to abiotic stress in a number of microalgae species.     

钙离子对盐胁迫小麦幼苗氮代谢的影响

为探讨增强小麦抗盐能力的调控途径,以普通小麦豫麦34为材料,研究了Ca2+对盐胁迫下小麦幼苗氮代谢及生长的影响.采用全营养液培养小麦幼苗至第一片叶完全展开,更换无钙营养液,并开始不同处理.处理分别为低盐胁迫(150 mmol · L-1 NaCl)、低盐胁迫+4 mmol · L-1 Ca2+、高盐胁迫(300 mmol · L-1 NaCl)、高盐胁迫+4mmol · L-1 Ca2+,以无NaCl胁迫的小麦为对照.5 d后取样,测定了氮同化酶活性、代谢物含量、积累量及幼苗生长状况.结果表明,Ca2+明显缓解了低盐胁迫对小麦幼苗的生长抑制,表现在鲜重、叶绿素及可溶性蛋白含量的增加,而对高盐胁迫下小麦幼苗的生长无明显改善效果;Ca2+改善了低盐胁迫下小麦幼苗的氮营养状况,表现在氮积累量的增加,这一效应主要是通过硝酸还原酶(NR)、谷氨酰胺合成酶(GS)以及异柠檬酸脱氢酶(NADP-ICDH)活性的增强而实现的.Ca2+未能改善高盐胁迫下小麦幼苗氮营养状况的主要限制因子在于NADP-ICDH活性未明显增加.     

New perspective on the mechanism of alleviating salt stress by spermidine in barley seedlings

Salt stress is considered to be a major limiting factor for plant growth and crop productivity. Salt injuries in plants are mostly due to excess Na⁺ entry. A possible survival strategy of plants under saline environments is the effective compartmentation of excess Na⁺ by sequestering Na⁺ in roots and inhibiting transport of Na⁺ from roots to shoots. Our previous study showed that exogenous application of polyamines (PAs) could attenuate salt injuries in barley plants. In order to further understand such protective roles of PAs against salt stress, the effects of spermidine (Spd) on sodium and potassium distribution in barley (Hordeum vulgare L.) seedlings under saline conditions were investigated. The results showed that exogenous application of Spd induced reductions in Na⁺ levels in roots and shoots with comparison of NaCl-treated plants, while no significant changes in K⁺ levels were observed. Correspondingly, the plants treated with Spd exogenously maintained high values of [K⁺]/[Na⁺] as compared with salt-stressed plants. Moreover, it was shown by X-ray microanalysis that K⁺ and Na⁺ accumulated mainly in the exodermal intercellular space and cortical cells of roots under salinity stress, and low accumulation was observed in endodermal cells and stelar parenchyma, indicating Casparian bands possibly act as ion transport barriers. Most importantly, Spd treatment further strengthened this barrier effects, leading to inhibition of Na⁺ transport into shoots. These results suggest that, by reinforcing barrier effects of Casparian bands, exogenous Spd inhibits Na⁺ transport from roots to shoots under conditions of high salinity which are beneficial for attenuating salt injuries in barley seedlings.     

Ionic and osmotic components of salt stress specifically modulate net ion fluxes from bean leaf mesophyll

Ionic mechanisms of salt stress perception were investigated by non‐invasive measurements of net H⁺, K⁺, Ca²⁺, Na⁺, and Cl^? fluxes from leaf mesophyll of broad bean (Vicia faba L.) plants using vibrating ion‐selective microelectrodes (the MIFE technique). Treatment with 90 m M NaCl led to a significant increase in the net K⁺ efflux and enhanced activity of the plasma membrane H⁺‐pump. Both these events were effectively prevented by high (10 m M ) Ca²⁺ concentrations in the bath. At the same time, no significant difference in the net Na⁺ flux has been found between low‐ and high‐calcium treatments. It is likely that plasma membrane K⁺ and H⁺ transporters, but not the VIC channels, play the key role in the amelioration of negative salt effects by Ca²⁺ in the bean mesophyll. Experiments with isotonic mannitol application showed that cell ionic responses to hyperosmotic treatment are highly stress‐specific. The most striking difference in response was shown by K⁺ fluxes, which varied from an increased net K⁺ efflux (NaCl treatment) to a net K⁺ influx (mannitol treatment). It is concluded that different ionic mechanisms are involved in the perception of the ‘ionic’ and ‘osmotic’ components of salt stress.     

Protective effect of exogenous polyamines on root tonoplast function against salt stress in barley seedlings

Salinity stress is one of the most serious factors limiting the productivity of agricultural crops. A possible survival strategy of plants under saline conditions is to sequester excess Na⁺ in the vacuole by vacuolar Na⁺/H⁺ antiport using a pH gradient generated by H⁺-ATPasc (EC 3.6.1.35) and H⁺-Pyrophosphatase (H⁺-PPase; EC 3.6.1.1) to maintain a higher K⁺/Na⁺ ratio in cytoplasm. The effect of exogenously applied polyamines (PAs) in stabilizing root tonoplast integrity and function against salt stress in the barley (Hordeum vulgare L.) seedlings was investigated. The NaCl-induced reductions in the contents of phospholipids and PAs in tonoplast vesicles isolated from barely seedling roots, as well as the activities of H⁺-ATPase, H⁺-PPase and vacuolar Na⁺/H⁺ antiport were all partially restored by the application of 0.5 mM putrescine and 0.5 mM spermidine, especially the former. The above results indicated that one of the mechanisms involved in attenuating salt injury in barley seedlings by exogenous PAs application was to maintain tonoplast integrity and function under saline conditions. Moreover, the possible mechanism involved in counteracting detrimental effects of salt on the barley seedlings by the application of exogenous PAs was discussed.     

Ability of leaf mesophyll to retain potassium correlates with salinity tolerance in wheat and barley

This work investigated the importance of the ability of leaf mesophyll cells to control K⁺ flux across the plasma membrane as a trait conferring tissue tolerance mechanism in plants grown under saline conditions. Four wheat (Triticum aestivum and Triticum turgidum) and four barley (Hordeum vulgare) genotypes contrasting in their salinity tolerance were grown under glasshouse conditions. Seven to 10‐day‐old leaves were excised, and net K⁺ and H⁺ fluxes were measured from either epidermal or mesophyll cells upon acute 100 mM treatment (mimicking plant failure to restrict Na⁺ delivery to the shoot) using non‐invasive microelectrode ion flux estimation (the MIFE) system. To enable net ion flux measurements from leaf epidermal cells, removal of epicuticular waxes was trialed with organic solvents. A series of methodological experiments was conducted to test the efficiency of different methods of wax removal, and the impact of experimental procedures on cell viability, in order to optimize the method. A strong positive correlation was found between plants' ability to retain K⁺ in salt‐treated leaves and their salinity tolerance, in both wheat and especially barley. The observed effects were related to the ionic but not osmotic component of salt stress. Pharmacological experiments have suggested that voltage‐gated K⁺‐permeable channels mediate K⁺ retention in leaf mesophyll upon elevated NaCl levels in the apoplast. It is concluded that MIFE measurements of NaCl‐induced K⁺ fluxes from leaf mesophyll may be used as an efficient screening tool for breeding in cereals for salinity tissue tolerance.     

Chloroplast development in low light-grown barley seedlings

Segments of 7-d low light-grown barley laminae cut at 0.5 cm intervals up from the intercalary meristem were examined ultrastructurally and biochemically. The different regions upwards showed the succession of plastid development in light-grown tissues of eoplasts, amyloplasts, amoeboid, immature and mature plastids as described by Whatley (1977). Semi-crystalline bodies were detected in all of them. The eoplast-amyloplast regions are characterised by a greater proportion of mitochondria and high levels of ATP and 3-phosphoglyceric acid, together with low levels of inorganic phosphate conducive to the activation of ADP glucose pyrophosphorylase. The amoeboid and immature plastid regions have higher levels of inhibitory phosphate and starch breakdown may be responsible for the release of metabolites and energy for development. Segments containing amoeboid and immature plastids also have reduced levels of ATP (and 3-phosphoglyceric acid) as photosynthetic components are synthesised. Using ultrastructural assessments of areas of thylakoids, first -carotene and violaxanthin, followed by chlorophyll a and lutein and, lastly, chlorophyll b are concentrated in the developing lamellar systems of the immature and mature chloroplasts. The formation of additional membraneous material which spreads these pigment systems over a greater thylakoid area within the plastids is the final stage of plastid morphogenesis in low light-grown seedlings.Abbreviations Chl chlorophyll - 3-PGA 3 phosphoglyceric acid     

Protective effects of exogenous fatty acids on root tonoplast function against salt stress in barley seedlings

Salinity stress is one of the most serous factors limiting the productivity of agricultural crops. Previous studies have shown that exogenous fatty acids (EFAs) enhanced plant performance in saline environment. However, the mechanisms remained unclear. This study aimed to investigate whether EFAs (palmitic and linoleic acids) had ameliorating effects on salt injury in NaCl-treated barley (Hordeum vulgare L.) seedlings, and to explore the possible mechanisms by determining tonoplast composition and function. The results showed that linoleic acid at 1 mmol l⁻¹ in culture solution possessed protective effects on root tonoplast function against salt stress in the barley seedlings; this was accompanied with a significant suppression of the degradation of phospholipids and PAs in tonoplast vesicles. Moreover, these salt-ameliorating effects of linoleic acid on tonoplast function were also indicated by the increase in H⁺-ATPase and H⁺-PPase activities. In response to the changes in membrane bound enzyme activities, an augmentation in the activity of a vacuolar Na⁺/H⁺ antiport was occurred by the application of linoleic acid under saline conditions. These findings suggested that the application of linoleic acid exhibited protective effects on tonoplast function in the barley seedlings under salt stress, perhaps due partly to suppress the degradation of phospholipids and PAs in tonoplast vesicles, thus leading partial restorations in the activities of vacuolar H⁺-ATPase, H⁺-PPase and Na⁺/H⁺ antiport.     

The short-term growth response to salt of the developing barley leaf

Recent results concerning the short-term growth response to salinity of the developing barley leaf are reviewed. Plants were grown hydroponically and the growth response of leaf 3 was studied between 10 min and 5 d following addition of 100 mM NaCl to the root medium. The aim of the experiments was to relate changes in variables that are likely to affect cell elongation to changes in leaf growth. Changes in hormone content (ABA, cytokinins), water and solute relationships (osmolality, turgor, water potential, solute concentrations), gene expression (water channel), cuticle deposition, membrane potential, and transpiration were followed, while leaf elongation velocity was monitored. Leaf elongation decreased close to zero within seconds following addition of NaCl. Between 20 and 30 min after exposure to salt, elongation velocity recovered rather abruptly, to about 46% of the pre-stress level, and remained at the reduced rate for the following 5 d, when it reached about 70% of the level in non-stressed plants. Biophysical and physiological analyses led to three major conclusions. (i) The immediate reduction and sudden recovery in elongation velocity is due to changes in the water potential gradient between leaf xylem and peripheral elongating cells. Changes in transpiration, ABA and cytokinin content, water channel expression, and plasma membrane potential are involved in this response. (ii) Significant solute accumulation, which aids growth recovery, is detectable from 1 h onwards; growing and non-growing leaf regions and mesophyll and epidermis differ in their solute response. (iii) Cuticular wax density is not affected by short-term exposure to salt; transpirational changes are due to stomatal control.     

Salinity stress induced tissue-specific proteins in barley seedlings

Protein changes induced by salinity stress were investigated in two barley cultivars, California Mariout, a salt-tolerant variety and Prato, a salt-sensitive variety. Rapidly growing young barley seedlings were exposed to NaCl and the newly synthesized proteins were resolved on two dimensional polyacrylamide gels following isoelectric focusing or nonequilibrium pH gradient gel electrophoresis in the first dimension. Salinity induces distinct protein changes in root and shoot tissues. In roots, the salinity effects are identical in both cultivars. First, salinity modulates the synthesis of two different sets of proteins, one of which is elevated, and the other, depressed. Second, six new proteins are induced all of which are low in molecular weight, 24 to 27 kilodaltons, with an isoelectric point range of 6.1 to 7.6. In contrast to roots, salinity induces cultivar-specific shoot proteins. Five new shoot proteins are induced whose molecular weights and isoelectric points fall within the range of 20 to 24 kilodaltons and 6.3 to 7.2, respectively. Three of the newly induced proteins are unique to Prato. In addition, salinity inhibits the synthesis of a majority of shoot proteins. The new proteins produced in roots and shoots are unique to each tissue and their induction is apparently regulated coordinately during salinity stress.     

Changes in the polypeptide patterns of barley seedlings exposed to jasmonic Acid and salinity

Soluble and thylakoid membrane proteins of jasmonic acid (JA)-treated and salt-stressed barley (Hordeum vulgare L.) seedlings were investigated using 15% sodium dodecyl sulfate-polyacrylamide slab gel electrophoresis. High JA concentrations induced marked quantitative and qualitative changes in polypeptide profiles concerning mainly the proteins with approximately equal mobility, as in NaCl-stressed plants. The most obvious increase in thylakoid polypeptide band intensity was at 55 to 57 kilodaltons (kD). The relative share of some polypeptides with apparent molecular masses above 66 kD and of polypeptides with lower molecular masses in the region of 20.5 to 15 kD was enhanced. At the same time, one new band at 31 to 31.5 kD was well expressed at 25 and 250 micromolar JA concentrations and became discernible in the 100 micromolar NaCl-treated plants. The intensity of some polypeptides of soluble proteins (molecular masses of 60, 47, 37, 30, and 23.4 kD) increased with increasing JA concentration, whereas the intensities of other polypeptide bands (55, 21.4, and 15 kD) decreased. Enhanced levels of 60-, 47-, 34-, and 30-kD polypeptides and reduced levels of 55- and 15-kD polypeptides were present in NaCl-treated plants. The appearance of one new polypeptide, of 25.1 kD, was observed only in NaCl-treated plants. At 100 millimolar NaCl, an eightfold increase in proline content was observed while at 250 micromolar JA, the proline content was threefold over the control. It is hypothesized that exogenously applied jasmonates act as stress agents. As such, they provoke alterations in the proline content and they can modulate typical stress responses by induction of stress proteins.     

Effects of nitrogen on mesophyll cell division and epidermal cell elongation in tall fescue leaf blades

Leaf elongation rate (LER) in grasses is dependent on epidermal cell supply (number) and on rate and duration of epidermal cell elongation. Nitrogen (N) fertilization increases LER. Longitudinal sections from two genotypes of tall fescue (Festuca arundinacea Schreb.), which differ by 50% in LER, were used to quantify the effects of N on the components of epidermal cell elongation and on mesophyll cell division. Rate and duration of epidermal cell elongation were determined by using a relationship between cell length and displacement velocity derived from the continuity equation. Rate of epidermal cell elongation was exponential. Relative rates of epidermal cell elongation increased by 9% with high N, even though high N increased LER by 89%. Duration of cell elongation was approximately 20 h longer in the high- than in the low-LER genotype regardless of N treatment. The percentage of mesophyll cells in division was greater in the high- than in the low-LER genotype. This increased with high N in both genotypes, indicating that LER increased with cell supply. Division of mesophyll cells adjacent to abaxial epidermal cells continued after epidermal cell division stopped, until epidermal cells had elongated to a mean length of 40 micrometers in the high-LER and a mean length of 50 micrometers in the low-LER genotype. The cell cycle length for mesophyll cells was calculated to be 12 to 13 hours. Nitrogen increased mesophyll cell number more than epidermal cell number: in both genotypes, the final number of mesophyll cells adjacent to each abaxial epidermal cell was 10 with low N and 14 with high N. A spatial model is used to describe three cell development processes relevant to leaf growth. It illustrates the overlap of mesophyll cell division and epidermal cell elongation, and the transition from epidermal cell elongation to secondary cell wall deposition.     

Calcium and phytochrome control of leaf unrolling in dark-grown barley seedlings

The red light-stimulated component of unrolling in sections from 7-d-old dark-grown barley (Hordeum vulgare L.) leaves is inhibited by ethyleneglycol-bis-(-aminoethyl ether)-N,N,N,N-tetracetic acid (EGTA). A free-Ca²⁺ activity of less than 40 M restores the ability to respond to red light, but only if supplied within 1 h of red light. Magnesium ions are an ineffective substitute. At least two processes in unrolling appear to be Ca²⁺-sensitive.Fluence-response measurements indicate that the levels of the far-red-absorbing from of phytochrome (Pfr) still present 4 h after red-light treatment should be above saturation for the unrolling response; consequently, loss of Pfr does not explain the loss in effectiveness of Ca²⁺ during prolonged EGTA treatment. However, if a further red-light treatment is given simultaneously with Ca²⁺ addition 4 h after the initial light stimulus, then full unrolling occurs in EGTA-treated sections. These data indicate that, under normal circumstances, a functional change in the properties of Pfr must occur, uncoupling it from the transduction chain.Abbreviations EGTA ethyleneglycol-bis-(-aminoethylether)-N,N,N,N,-tetracetic acid - FR far-red light - Mes 2-(N-morpholino)ethanesulphonic, acid - Pfr far-red absorbing form of phytochrome - Pr red-absorbing form of phytochrome - R red light     

Uptake of jasmonic acid and related compounds by mesophyll protoplasts of the barley leaf

Jasmonic acid (JA) permeates the plasma membrane of mesophyll cells by diffusion as the lipophilic undissociated JAH molecule probably without the participation of a saturable uptake component. The mesophyll plasma membrane is nearly impermeable to the JA anion. The permeability coefficients of JA and several JA derivatives (its methyl ester (JAMe), 7-iso-cucurbic acid (7-iso-CA), 6-epi-7-iso-cucurbic acid (6-epi-7-iso-CA), and both stereoisomers of the JA leucine conjugate ((+)-JA-Leu and (-)-JA-Leu)) were determined and used in a simplified mathematical model to predict stressdependent JA redistribution between cytosol and apoplast in comparison with ABA. The redistribution of JA takes place similar to ABA; however, its velocity is much higher because of the high JA membrane permeability. When the permeability coefficients for the mesophyll plasma membrane are plotted double-logarithmically against the ratio of the distribution coefficient and the molecular ratio to the power of 1.5 (K_DM_r ^–1.5), two straight lines result for two different classes of compounds. The permeability coefficients of JA conjugates are lower than that of the free acid by approximately one order of magnitude, but they are still significantly higher than that of ABA.     

Morphological changes in Escherichia coli cells exposed to low or high concentrations of hydrogen peroxide

Escherichia coli cells challenged with low or high concentrations of hydrogen peroxide are killed via two different mechanisms and respond with morphological changes which are also dependent on the extracellular concentration of the oxidant. Treatment with low concentrations (less than 2.5 mM) of H2O2 is followed by an extensive cell filamentation which is dependent on the level of H2O2 or the time of exposure. In particular, addition of 1.75 mM H2O2 results in a growth lag of approximately 90 min followed by partial increase in optical density, which was mainly due to the onset of the filamentous response. In fact, microscopic analysis of the samples obtained from cultures incubated with the oxidant for various time intervals has revealed that this change in morphology becomes apparent after 90 min of exposure to H2O2 and that the length of the filaments gradually increases following longer time intervals. Analysis of the ability of these cells to form colonies has indicated a loss in viability in the first 90 min of exposure followed by a gradual recovery in the number of cells capable of forming colonies. Measurement of lactate dehydrogenase in culture medium (as a marker for membrane damage) has revealed that a small amount of this enzyme was released from the cells at early times (less than 150 min) but not after longer incubation periods (300 min). Cells exposed to high concentrations of H2O2 (greater than 10 mM) do not filament and their loss of viability is associated with a marked reduction in cell volume. In fact, treatment with 17.5 mM H2O2 resulted in a time-dependent decrease of the optical density, clonogenicity, and cellular volume. In addition, these effects were paralleled by a significant release in the culture medium of lactate dehydrogenase thus suggesting that the reduced cell volume may be dependent on membrane damage followed by loss of intracellular material. This hypothesis is supported by preliminary results obtained in electron microscopy studies. In conclusion, this study further demonstrates that the response of E. coli to hydrogen peroxide is highly dependent on the concentration of H2O2 and further stresses the point that low or high concentrations of the oxidant result in the production of different species leading to cell death via two different mechanisms and/or capable of specifically affecting the cell shape.     

5-Azacytidine decreases fragmentation of nuclear DNA and pigment formation in first leaf cells of barley seedlings

Realization of programmed cell death in senescence represents an activation/inactivation of the respective gene. Enzymatic methylation of nuclear DNA with the creation of 5methylcytosine is one of the mechanisms, which can regulate gene activity in animal and plant cells. 5Azacytidine (5azaC) acts as an inhibitor of DNA methylation, and induces expression of a range of some genes including genes responsible for senescence. Fragmentation of nuclear DNA is one of the hallmarks of programmed cell death in apoptosis pathway in plant cells. The influence of 5azaC (100 microg/ml) on nuclear DNS amount and its fragmentation in the first leaf cells of barley was studied. It was shown that in the first leaf cells of barley seedlings there is an apoptosis pathway of programmed cell death. It was also observed that nuclear DNA fragmentation under the 5azaC influence is strongly inhibited, and the DNA amount in the first leaf increases. Synthesis and destruction of chlorophyll also play a significant role in programmed cell death in plants. It was shown that under the 5azaC influence, the absorption spectrum of a pigment does not change in leaves and coleoptiles in the light, whereas in the dark condition, these pigments are not created under the 5azaC influence.     

盐胁迫对黄瓜幼苗根系生长和水分利用的影响

采用营养液水培法,研究了NaCl胁迫对两个耐盐性不同的黄瓜品种幼苗根系生长、活力、质膜透性和叶片生长、蒸腾速率（T_r）、相对含水量（RWC）及水分利用率（WUE）的影响.结果表明,盐胁迫下黄瓜植株根系吸收面积下降,质膜透性升高,叶片数减少,叶片T_r和RWC在盐胁迫2 d后明显下降,根系活力和叶片WUE均先升后降,50、75和100 mmol·L^-1NaCl胁迫9 d时,耐盐性较弱的津春2号根系活力降低幅度分别比耐盐性较强的长春密刺高18.01%、12.17%和10.95%,胁迫8 d时WUE下降幅度分别比长春密刺高2.74%、5.27%和0.23%.短期盐胁迫下,黄瓜植株通过提高根系吸收能力来补偿根系吸收面积的下降,通过降低叶片T_r和提高WUE来减少水分散失,在一定程度上有利于缓解水分失衡,提高植株耐盐性;盐胁迫5 d后,根系活力和WUE的下降导致水分失衡加剧,表明根系吸收能力的下降是导致水分失衡的重要原因,叶片WUE的下降是水分失衡的反应,两者均与品种的耐盐性关系密切.