Salinity tolerance in tomato: Implications of potassium,calcium, and phosphorus

Abstract

The effect of salinity on the growth and yield of tomato plants and mineral composition of tomato leaves was studied. Five tomato (Lycopersicon esculentum Mill) cultivars, Pearson, Strain B, Montecarlo, Tropic, and Marikit, were grown in sand nutrient culture. The nutrient solutions applied consisted of a modified half‐strength Hoagland solution with 50 mM sodium chloride (NaCl), 3 mM potassium sulphate (K₂SO₄), 1.5 mM orthophosphoric acid (H₃PO₄), and 10 mM calcium sulphate (CaSO₄). Stem height and number of leaves of tomato plants were not found to be significantly different but leaf and stem dry weight were reduced significantly in plants irrigated with saline nutrient solution in contrast with control plants. The total yield was reduced in plants that received saline treatments, but there was no significant difference in fruit number and fruit set percentage. The fruit electrical conductivity and total soluble solids were increased in plants irrigated with saline nutrient solution. Fruit pH was not found to be significantly different among salinity treatments. Mineral composition of tomato leaves were increased by addition of potassium (K), phosphorus (P), and calcium (Ca) to the saline nutrient solution. The addition of K to the solution resulted in an increase in sodium (Na) leaf content. The amounts of K and magnesium (Mg) were not significantly different among salinity treatments. Calcium content was increased when CaSO₄ was added. Application of H₃PO₄ resulted in the highest amount of P in tomato leaves under saline conditions. The present study revealed that application of K, P, and Ca under saline conditions improved fruit electrical conductivity and total soluble solids. Sufficiency levels of the mineral nutrients K and P were obtained in tomato leaves when the appropriate nutrient was used in the saline solution.     

Enhancement of salinity tolerance in tomato: Implications of potassium and calcium in flowering and yield

Abstract

Five tomato (Lycopersicon esculentum Mill) cultivars were grown in sand nutrient culture experiment in a greenhouse to investigate the effects of salinity on growth and yield. Nutrient solutions were made saline with 50 mM NaCl (EC = 5.5 mS/cm or supplemented with 2 mM KNO₃ (EC = 6.8), 20 mM Ca(NO₃)₂ (EC = 7.5), and combination of potassium (K) and calcium (Ca) (EC = 8.0). Seedlings were irrigated with saline treatments commencing two weeks after transplanting. Determination of sodium (Na) and K in tomato leaves and fruits were by flame photometry. Accumulation of Na in tomato fruits was higher than in leaves under control or saline conditions for all tomato cultivars. The amount of K in the tomato leaves was higher in control than in saline‐grown plants. Addition of K and Ca to the nutrient solution resulted in a 3 to 7 fold increase in K accumulation in all cultivars tested. Stem and leaf growth were significantly reduced with salinity but growth was enhanced following irrigation when K was added to the nutrient solution. Flowering and fruit set were adversely affected by NaCl stress. Reduction of flower number was 44% relative to the control plants. Fresh fruit yield decreased by 78% when plants received 50 mM NaCl. Growth and development of tomatoes under saline conditions was enhanced in this study following the application of K to the saline nutrient solution. Amelioration in growth was also achieved when Ca was used but to a lesser extent. Our results suggest that ion accumulation and regulation of K and Ca contribute to salt tolerance and growth enhancement.     

Fruit quality and partitioning of mineral elements in processing tomato in response to saline nutrients

A sand culture experiment was conducted to study the effect of saline water on the growth and fruit quality of processing tomato (Lycopersicon esculentum Mill.) Seedlings of five tomato cultivars were transplanted in quartz‐sand pots in a greenhouse at the Agricultural Experiment Station of Sultan Qaboos University. There were four saline nutrient solutions and a control consisting of half‐strength Hoagland solution. Salinity treatments were: 50 raM NaCl + 3 mM K₂SO₄ (EC 6.75), 50 mM NaCl + 1.5 mM orthophosphoric acid (EC = 7.18), 50 mM NaCl + 1.5 mM orthophosphoric acid + 3 mM R₂SO₄ (EC 7.29), and 50 mM NaCL (EC = 5.6). Treatments were applied daily commencing two weeks after transplanting. Data were collected on growth, and fruit yield and quality. Partitioning of mineral elements was determined in the vegetative tissue. The results obtained clearly show that concentrations of total soluble solids were increased in fruits treated with saline nutrients. Dry matter content of fruits exposed to salinity were higher than those from the control plants. Fruit acidity was increased with salinity, possibly due to a lower water content and increased organic acid accumulation. In the saline treatments, sodium (Na) content was decreased when potassium (K) was applied with NaCl but Na was higher in stems followed by root and leaf tissues. The partitioning of K followed a trend opposite to that for Na but with higher content in leaves. A similar situation was observed for calcium (Ca) and magnesium (Mg). Accumulation of phosphorus (P) was the lowest among all the ions. These results indicated that survival under saline conditions was accompanied by high ion accumulation. The study confirmed that saline nutrients are important for improving fruit quality of processing tomatoes.     

Effect of increasing potassium levels for alleviating sodium chloride stress on the growth and yield of tomato

Abstract

The efficacy of using various levels of potassium (K) (4, 8, and 16 mM) under saline conditions to alleviate the detrimental effects of salt‐stress were studied using five tomato (Lycopersicon esculentum Mill) cultivars, ‘Strain 19’, ‘Pearson’, ‘Montecarlo’, ‘Maruthuam’, and ‘Pusa Rub’. Results of the study revealed that 50 mM sodium chloride (NaCl) in a Hoagland nutrient solution significantly reduced stem height, fruit weight, and whole plant dry weights, but increased number of fruits/plant and improved fruit quality by increasing total soluble solids. It did not significantly affect leaf count, percent fruit set, or dry weight. The addition of 4, 8 and 16 mM potassium nitrate (KNO₃) to the nutrient solution containing 50 mM NaCl resulted in sodium/potassium (Na/K) ratios of 12.5, 6.3, and 3.1, respectively. The Na/K ratios of 12.5 and 6.3 produced significant improvement in stem height, percent fruit set, number of fruits/plant, fruit weight, and whole plant dry weight. The Na/K ratio of 3.1 was found to be detrimental as it resulted in sharp reduction of plant dry weight compared to the control. Percent total soluble solids was not significantly affected by the addition of any level of K to the saline nutrient solution. The performance of the tomatoplant grown under saline conditions supplemented with K in the nutrient solution indicated a higher response at the lowest K concentration used in this study.     

MYCORRHIZAL INFLUENCE ON FRUIT YIELD AND MINERAL CONTENT OF TOMATO GROWN UNDER SALT STRESS

Tomato (Lycopersicon esculentum Mill.) yields are known to decrease for plants grown in saline soils. This study was conducted to determine the effects of arbuscular mycorrhizal fungi (AMF) inoculation on fruit yield and mineral content of salt-tolerant and salt-sensitive tomato cultivars grown with varied levels of salt. NaCl and CaCl₂were added to soil in the irrigation water in equal molar ratios to give EC_e values of 1.4 (nonstressed) and 4.9 dS m^?1 (salt stressed). Plants were grown in a greenhouse using unsterilized, low phosphorus (P) (silty clay) soil-sand mix. Mycorrhizal root colonization occurred whether cultivars were salt stressed or nonstressed, but the extent of AMF root colonization was higher in AMF inoculated than uninoculated plants. The salt tolerant cultivar ‘Pello’ generally had higher AMF root colonization than the salt sensitive cultivar ‘Marriha’. Shoot dry matter (DM) yield, fruit fresh yield, and AMF colonization were higher for plants grown under nonstressed than for plants grown under salt stressed conditions. Shoot DM and fruit fresh yields were higher in AMF inoculated than uninoculated plants grown with or without salt stress. Pello generally had higher fruit fresh yield per plant and fruit weight than Marriha, but these differences were only significant for fruit weight in unioculated plants grown under salt stressed conditions. The enhancement in fruit fresh yield due to AMF inoculation was 26 and 23% under nonstressed and 28 and 46% under salt stressed treatments for Pello and Marriha, respectively. For both cultivars, fruit contents of P, potassium (K), zinc (Zn), copper (Cu), and iron (Fe) were higher in AMF inoculated compared with uninoculated plants grown under nonstressed and salt stressed conditions. Fruit Na concentrations were lower in AMF inoculated than uninoculated plants grown under salt stressed conditions. The enhancement in P, K, Zn, Cu, and Fe acquisition due to AMF inoculation was more pronounced in Marriha than in Pello cultivar under salt stressed conditions. The results of this study indicated that AMF inoculated plants had greater tolerance to salt stress than unioculated plants.     

Salinity Effects on Yield and Yield Components of Contrasting Naked Oat Genotypes

ABSTRACT

Global crop production systems are challenged by the increasing areas of saline soil in arid and semi-arid regions. Two naked oat (Avena sativa L.) lines (‘VAO-7’ and ‘VAO-24’) with distinct seedling tolerance to salinity were subjected to six levels of salt concentrations in a controlled greenhouse, and the response of yield and yield components to salinity stress was determined. The salt treatments 50, 100, 150, 200, and 250 mM sodium chloride (NaCl) (corresponding to EC: 3.42, 6.74, 9.66, 12.40, 15.04 dS m^?1) imposed through modified Hoagland solution. Plain Hoagland was used as control. Complete nutrient elements were provided during the entire growth period. At maturity, the number of tillers with emerged heads was counted; the plant was then harvested and separated into shoots, seeds, and roots. Both plant height and days to maturity were shortened with increasing salt stress. Among the yield components, spikelet, tiller number, and grain dry weight per plant were significantly reduced by increasing salt concentration. Number of spikelets and grain weight per plant were the most salt-sensitive yield components. Thousand grain weight also varied as salinity stress increased. Harvest index remained relatively unchanged until the salinity reached 150 mM and higher. Our data indicate that grain yield reduction in oat due to salinity stress is associated with reduced number of grains per plant and mean grain weight.     

Growth,mineral composition,leaf chlorophyll and water relationships of two cherry varieties under NaCl-induced salinity stress

Abstract

Growth, mineral nutrition, leaf chlorophyll and water relationships were studied in cherry plants (cv. ‘Bigarreau Burlat’[BB] and ‘Tragana Edessis’[TE]) grafted on ‘Mazzard’ rootstock and grown in modified Hoagland solutions containing 0, 25 or 50 mmol L^?1 NaCl, over a period of 55 days. Elongation of the main shoot of the plants treated with 25 or 50 mmol L^?1 NaCl was significantly reduced by approximately 29–36%, irrespective of the cultivar. However, both NaCl treatments caused a greater reduction in the dry weight of leaves and scion's stems in BB than in TE plants. Therefore, BB was more sensitive to salinity stress than TE. The reduction of leaf chlorophyll concentration was significant only when BB and TE plants were grown under 50 mmol L^?1 NaCl. Osmotic adjustment permitted the maintenance of leaf turgor in TE plants and induced an increase in leaf turgor of BB plants treated with 25 or 50 mmol L^?1 NaCl compared with 0 mmol L^?1 NaCl. Concerning the nutrient composition of various plant parts, Na concentrations in all plant parts of both cultivars were generally much lower than those of Cl. For both cultivars, leaf Cl concentrations were much higher than the concentrations in stems and roots, especially in the treatments containing NaCl. Finally, the distribution of Na within BB and TE plants treated with NaCl was relatively uniform.     

Effects of saline nutrient solutions on the growth and accumulation of mineral elements in some tomato cultivars

Abstract

Tomato cultivars were grown in a saline nutrient culture system to investigate growth and fruiting responses in relation to the application of 3 mM potassium (K), 1.5 mM phosphorus (P), and 10 mM calcium (Ca). The deleterious effects of salinity on tomato stem growth and fruit yield were ameliorated following the addition of K, P, and Ca to the nutrient solution. Potassium levels in tomato leaves were increased 4‐fold compared to control plants in the presence of applied K. The use of K resulted in an increase in Na content, however, a comparatively low level of sodium (Na) was obtained in treatments receiving K, Ca, and P. Calcium content was greater than sufficiency levels in all treatments, whereas magnesium (Mg) declined with the increase in salinity. The amount of P in tomato leaves was increased 4–5 fold when the nutrient solution was supplemented with 1.5 mM P. Correlation of vegetative parameters, such as stem height and leaf growth to salinity, revealed no significant responses, however commercial parameters such as total soluble solids and fruit weight correlated significantly with the saline nutrient treatments.     

Irrigation with salt water affects growth,yield, fruit quality,storability and marker-gene expression in cherry tomato

The use of saline water for plant production will become increasingly necessary over future decades. In some cases, fruit quality such as in tomato, can be improved by irrigation with saline water. The influence of different salt concentrations on physiological responses and the expression of some selected genes of cherry tomato (Solanum lycopersicum L), cv. West Virginia 106, was examined. Tomato plants were grown in peatmoss substrate and irrigated with 0, 25, 50, 75, 100 or 150?mM sodium chloride (NaCl) in a glasshouse. The NaCl treatments of 75, 100 and 150?mM salt resulted in shorter plants, decreased stem width, a lower plant dry weight, fewer flowers, and smaller leaf area, while yield was reduced by treatment with concentrations of 50?mM NaCl and above. Average fruit weight and fruit number were also negatively affected by treatment with 50?mM salt and above. Salinity treatment led to increased fruit total soluble solids, titratable acidity and firmness and improved the taste index. Salt-responsive marker genes identified in Moneymaker were also induced in cherry tomato but not at the highest salt concentrations. Our results indicated that cherry tomato treated with 25?mM NaCl produced fruit with improved quality in comparison with non-salinized control plants without compromising yield, while at 50 and 75?mM the improved fruit quality was accompanied by a reduction in yield.     

采用综合评价模型优化樱桃番茄的灌溉与钙镁肥组合

  【目的】  钙、镁肥效果既互相影响又受灌溉量影响。尝试用综合评价模型优化包括钙、镁和水等多因子的配施方案,为樱桃番茄高效生产提供指导。  【方法】  水、氮、钾、钙、镁五元二次正交旋转组合设计(1/2实施)微区试验在陕西杨凌大棚内进行,供试樱桃番茄品种为‘粉妹1号’,共36个处理。测定樱桃番茄生长、产量、品质、水肥利用率等共21个指标。采用Pearson相关性分析、组合评价方法对指标进行分级、综合评价,构建樱桃番茄综合评分对5个因子水平的响应模型。  【结果】  构建了包含14个指标的樱桃番茄综合评价体系;组合赋权确定了各指标最终权重,其中产量权重(0.2324)最大,净光合速率权重(0.0183)最小,这表明产量是对试验因子变化最敏感的指标。通过整体差异综合评价,发现樱桃番茄的综合评分随灌水量和氮肥水平的增加呈先增加后降低的趋势,灌水量0水平与–2和+2水平处理之间的差异显著大于氮肥水平之间的差异,随钙肥水平的增加略呈先增加后降低的趋势,而随钾和镁肥水平的增加几乎无显著变化。采用降维分析,当水、氮和钾处于0水平(适当水平)时,樱桃番茄的综合评分以钙和镁为0水平附近时最高;考虑5个因子的交互作用,基于整体差异组合的综合评分最优区间为:灌水量56.26～59.03 L/株、N 6.05～7.03 g/株、K₂O 5.97～6.50 g/株、CaO 2.92～3.30 g/株、MgO 0.58～0.64 g/株。  【结论】  采用综合评价模型可以兼顾生长、产量、品质和资源利用率,提出最优的水肥组合方案。本试验提出的樱桃番茄适宜施肥区间验证了该方法的可行性。     

缺钙对不同钙效率番茄幼苗钙吸收及幼茎解剖结构的影响

采用两个钙效率有较大差异的番茄品种(04,05)研究了缺钙胁迫对幼苗钙素吸收动力学特性、钙在体内的吸收和分配及幼茎解剖结构的影响。结果表明,正常供钙下不同钙效率番茄品种存在吸钙速率的基因型差异,钙低效品种04钙高效品种05,经过缺钙胁迫后重新吸收钙的速率仍然以0405。正常供钙下,钙低效品种04生长量、钙吸收量均显著高于钙高效品种05,而缺钙处理下植株生长量、钙吸收量、钙含量显著低于05。缺钙下两品种的根冠比增加,05增加程度高于04。正常供钙下两品种表皮细胞、薄壁细胞和形成层细胞形状大小匀称,排列紧密,04茎木质部导管数较多;缺钙使两品种幼茎形成层细胞发育受到影响,尤以04影响显著,表明缺钙胁迫对04品种结构的影响远远高于05。     

Ameliorative Effect of Calcium Nitrate on Cucumber and Melon Plants Drip Irrigated with Saline Water

Abstract

Cucumber (Cucumis sativus cv. Orlando) and melon (Cucumis melo cv. Ananas) were field grown to investigate the effects of supplementary calcium nitrate applied to irrigation water on plant growth and fruit yield of salt stressed and unstressed cucumber and melon plants. Treatments were (1) control: normal irrigation water (C); (2) normal irrigation water plus supplementary 5 mM Ca(NO₃)₂ added to the irrigation water (C + CaN); (3) salt treatment: C plus 60 mM NaCl added irrigation water (C + S); and (4) supplementary Ca(NO₃)₂: C + S plus supplementary 5 mM Ca(NO₃)₂ added to the irrigation water (C + S + CaN). Plants irrigated with water containing high NaCl produced less dry matter, fruit yield, and chlorophyll than the control treatments of both species. Supplementing irrigation water with Ca(NO₃)₂ resulted in increases in dry matter, fruit yield, and chlorophyll concentrations over plants irrigated with saline water. Membrane permeability increased with C + S treatment for both species. Supplementary Ca(NO₃)₂ restored membrane permeability. Sodium (Na) concentration in plant tissues increased in leaves and roots in the elevated NaCl treatment. Concentrations of Ca and N in leaves were decreased in the high salt treatment and fully restored by supplementary Ca(NO₃)₂. These results clearly show that supplementary Ca(NO₃)₂ can partly mitigate the adverse effects of saline water on both fruit yield and whole plant biomass in melon and cucumber plants.     

NaCl胁迫对不同砧木的嫁接黄瓜产量和品质的影响

为了筛选黄瓜的耐盐砧木,采用营养液栽培,分别以前期试验筛选的耐盐性较强的中国南瓜360-3×112-2杂交种和黑籽南瓜为砧木,以黄瓜品种津春2号为接穗,研究了成株期不同砧木嫁接黄瓜在80mmol.L-1 NaCl胁迫和没有NaCl胁迫下的产量与品质指标。结果表明:没有NaCl胁迫时,以360-3×112-2杂交种为砧木的嫁接黄瓜在产量指标上与以黑籽南瓜为砧木的嫁接黄瓜相当,在果实感官品质和营养品质上则优于以黑籽南瓜为砧木的嫁接黄瓜果实。NaCl胁迫时对嫁接黄瓜的产量和果实品质影响较大,单果重和单株产量降低,果实畸形率升高,风味变差,果实维生素C、游离氨基酸、可溶性糖和果实含水量减少,而纤维素和可滴定酸含量升高,以360-3×112-2杂交种为砧木的嫁接黄瓜受NaCl胁迫影响较以黑籽南瓜为砧木的嫁接黄瓜要小。因此,中国南瓜"360-3×112-2"杂交种具备黄瓜耐盐砧木品种的优良特性,可作为砧木品种在生产上应用。     

Ameliorative effect of selenium on tomato plants grown under salinity stress

The ability of selenium (Se) to counteract salt inhibitory effects in crop plants, especially in tomato, is still poorly documented. In order to examine the impact of Se addition on the growth, some biochemical parameters related to osmotic adjustment and antioxidant defense of salt-stressed tomato, a two-factorial experiment was conducted in a greenhouse. The plants were supplied with NaCl (0, 25, or 50 mM) and Se (0, 5, or 10 μM), individually or simultaneously. The results showed that salinity had a deleterious impact on plant biomass and physiological parameters studied. The application of Se alleviated this adverse effect by improving the integrity of cell membranes and by increasing leaf relative water content under stress conditions. Moreover, the application of 10 μM Se significantly increased the photosynthetic pigments concentration under salt stress. Salt stress also caused an inhibition of catalase activity, but its activity was restored in the presence of Se. The free radical scavenging activity significantly increased in plants subjected to 25 mM NaCl and supplied with 5 µM Se, compared to NaCl-alone treatment. Both physiological and biochemical results indicate that 10 µM Se treatment can increase plant performance under salt stress, especially under high NaCl concentration.

Abbreviations: CAT: catalase; Chl: chlorophyll; DPPH: 2,2-diphenyl-1-picrylhydrazyl; DW: dry weight; FW: fresh weight; POD: peroxidase; REL: relative electrolyte leakage; RWC: relative water content; free radical scavenging activity (FRSA); TW: turgid weight     

Effects of nitrogen form,nighttime nutrient solution strength,and cultivar on greenhouse tomato production

Higher greenhouse tomato (Lycopersicon esculentum Mill.) yield is obtained by using 25% of NH₄‐N in solution compared to using NO₃‐N as the sole nitrogen (N) source. However, blossom‐end rot (BER) may occur in tomato fruit when NH₄‐N was present in nutrient solutions. High nutrient solution strengths improve tomato fruit quality, but can also increase BER. Two NH₄‐N concentrations in solution (0 and 25%), and two nighttime solution strengths (NSS) (1X and 4X Steiner solution strength applied at 7 p.m.) were used to grow five indeterminate type greenhouse tomato cultivars: Caruso, Jumbo, Match, Max, and Trust. A significant interaction occurred between NH₄‐N concentration and NSS factors: 0% NH₄‐N and high NSS increased marketable yield and fruit:whole plant ratio, and reduced BER. In contrast, a concentration of 25% NH₄‐N and high NSS reduced marketable yield and the fruit:whole plant ratio, and increased BER incidence. Max, Match, and Trust tomato cultivars produced high marketable yield and high dry weight of stem and leaves, but were susceptible to BER. Use of NH₄‐N in solution reduced vegetative growth, and high NSS increased stem and leaf dry weight of the tomato plants. Fruit firmness was greater for the Max cultivar, and was unaffected by NH₄‐N and NSS at the mature green, breaker, and red ripe fruit development stages. However, at the fully ripe stage, fruit firmness was higher with high NSS and with 25% NH₄‐N.     

Induced Salinity and Supplementary Phosphorus on Growth and Mineral Content of Frijolillo

Abstract

A greenhouse pot experiment was carried out using pumice material to investigate the response of frijolillo [Rhynchosia minima (L.) DC] grown at high salinity to supplementary P (P). Plants were tested during a period from germination to vegetative growth stage. Four levels of sodium chloride (NaCl; 0, 25, 50, and 100 mM) combined with two levels of P (4 and 8 meq L^?1) were tested in a factorial arrangement with four replications. This cultivar was tolerant to salinity stress up to 50 mM of NaCl and its growth was not affected. However, with high salinity (100 mM of NaCl), growth of both stem and root was reduced. Concentration of potassium (K) and P was affected adversely. The increment of P in the saline solution results in a greatest accumulation of biomass and in a better response to the osmotic adjustment of this wild specie. The amount of NaCl was correlated negatively with the amount of K and calcium (Ca) and positively correlated with P and magnesium (Mg).     

Mitigation of salt stress on tomato crop by using foliar spraying or fertigation of various products

Abstract

Among major constraints to crop production, salt stress affects the morphological structure and yield in crop plants. Nano-fertilizers, have made their hierarchy to supplement the traditional fertilizers in mitigating the effect of abiotic stress due to their slow release and efficiency. Three products were tested namely lithovit®-standard(LITHO), monopotassium-phosphate(MKP:0-52-34), and aspirin(ASP) on salt-stressed tomato crop. These products were applied through foliar spraying (foliar) or fertigation (ferti) on tomato plants irrigated with 4 saline solutions (4, 6, 8 and 10dS/m). Control plants were subjected to five salinity levels (0, 4, 6, 8 and 10dS/m) without any treatments. Results showed that increasing in salinity levels adversely affected all parameters in the control plants. The ameliorating effect of MKP-ferti was prominent in plant height, stem diameter, number of fruits, fruit weight and yield/plant at 4 and 6S/m. Whereas, the effect of salinity was mitigated by LITHO-foliar regarding flowers number and total chlorophyll content at all salinity level. Leaf N, P and K contents were accumulated higher when MKP-ferti was used whereas, Ca²⁺ and Mg²⁺ contents were accumulated higher in the plants treated with LITHO-foliar. The cellular leakage of electrolyte was reduced at 4, 6 and 10dS/m with MKP-ferti and at 8dS/m with LITHO-foliar application. Among the two methods of application, foliar spraying of LITHO and ASP, and fertigation of MKP improved plant performance more than their complementary methods of application. The better performance of MKP necessitates the use of phosphorous and potassium-based nano-fertilizers. It can reduce the production cost of vegetables using conventional fertilizers.     

Effects of NaCl salinity on miniature dwarf tomato ‘Micro‐Tom’: II. Shoot and root growth responses,fruit production,and osmotic adjustment 1

The growth and production of miniature dwarf tomato selection Lycopersicon esculentum ’Micro‐Tom’ plants grown from seedling to harvest in solution batph culture’ at four different NaCl salinity levels (2.4 [control, no NaCl], 7.6, 12.8, or 18 dS‐m^‐1 solution conductivities) was monitored. Incremental reductions in canopy extent and shoot area of ‘Micro‐Tom’ were observed with increasing solution NaCl level. Root growth and shoot height were somewhat less responsive to imposed salinity. Fruit number, fruit size, and leaf tissue osmotic potential decreased as NaCl concentration increased. Fruit yield was highly correlated with total canopy and shoot area, but not with tissue osmotic or total water potential. ‘Micro‐Tom’ plants survived and continued fruit production at higher salinity levels despite reduced canopy growth. Treatment effects on vegetative growth and fruit production became more pronounced later in the growth cycle.     

Inducing salt tolerance in strawberry (Fragaria × ananassa Duch) plants by acetate application

Abstract

Acetate, can be considered as an appropriate interface for increasing tolerance to salinity stress in strawberries. Strawberry plants were exposed to different treatments including control (Hoagland solution), salinity (40?mM NaCl), acetic acid (AA) (1?mM), acetic acid (1?mM) + salinity (AAS), ammonium acetate (AA) (1?mM), ammonium acetate (AM) (1?mM) + salinity (AMS), ammonium carbonate (AC) (0.5?mM), and ammonium carbonate (0.5?mM) + salinity (ACS) and put them in hydroponic system. The results indicated that salinity reduced shoot dry weight about 80.12% when compared with untreated control plants. That in comparison to acetate treatments, this reduction was 47.13 and 48.77% in AAS and AMS, respectively. Leaf area was decrease 59% in salinity treatment but this reduction was 14% in AAS. The AAS and AMS were most effective in increasing fruit yields (35.93 and 52.16?g per plant, respectively) in comparison to salinity treatment alone (27.23?g per plant) condition. In saline conditions, the highest amount of soluble carbohydrate was observed in AMS treatment (9.67?mg g^?1 DW) that there was no significant difference with AAS treatment. Increase in Na⁺ and Cl^? accumulation in shoots and decreased in K⁺ in saline condition were observed. The highest amount of potassium was observed in acetate treatments. The present results have demonstrated that acetate could improve tolerance to the salinity, yield and plants growth in strawberry. But, in comparison to AA and AM treatments, better results were observed in AA treatment in both salinity and non-salinity conditions.     

Potassium Silicate Improves Salinity Resistant and Affects Fruit Quality in Two Strawberry Cultivars Grown Under Salt Stress

ABSTRACT

The response of ‘Kurdistan’ and ‘Paros’ strawberry cultivars to potassium silicate (K₂O₃Si) under sodium chloride (NaCl) salinity stress was studied in terms of vegetative parameters, sodium (Na) and potassium (K) content and fruit quality. K₂O₃Si could recover dry mass distribution of NaCl-stressed strawberry organs. Kurdistan cultivar tended to keep higher dry weight of leaves to maintain its photosynthetic apparatus activity. Inhibitory impact of K₂O₃Si on Na uptake of leaf was more obvious than root. Implementation of K₂O₃Si in some cases increased Total Soluble Solid (TSS) and Titratable Acidity (TA), which are the main factors determining taste of strawberry fruit. Furthermore, phenols and flavonoids were increased in Paros cultivar by effect K₂O₃Si under saline and non-saline conditions, respectively. Overall, our data suggest that silicon supply in strawberry plants not only could be used as a routine strategy to maintain growth and yield under salinity but also it could be beneficial for improvement of fruit quality attributes and health-related constituents.

Abbreviations: ANOVA: Analysis of Variance; CRD: Completely Randomized Design; DPPH: 1,1-Diphenyl-2-picryl-hydrazyl; FF: Fruit Firmness; LSD: Least Significant Difference; PAL: Phenyl Alanine Ammonia Lyase; ROS: Reactive Oxygen Species; TSS: Total Soluble Solid; TAA: Total Antioxidant Activity; TA: Titratable Acidity; TAC: Total Anthocyanin; TF: Total Flavonoids; TP: Total Phenolics;