Salinity and Low Phosphorus Differentially Affect Shoot and Root Traits in Two Wheat Cultivars with Contrasting Tolerance to Salt

Soil salinity and phosphorus (P) deficiency both have adverse effects on crop growth and productivity, but the interaction of soil salinity and P deficiency is not well known. Two P-inefficient wheat cultivars, Janz (salinity-tolerant) and Jandaroi (salinity-sensitive), grown in soil in rhizoboxes, were treated with either 100 μM P (control), 100 mM NaCl (saline stress), 10 μM P (low P stress), or both NaCl and low P (combined stress), from 10 days after sowing (DAS) until harvest at 40 DAS. Significant reductions in leaf area, shoot and root biomass, tissue water and chlorophyll contents, gas exchange, and K+ and P acquisition at harvest were observed in the three treatments. The reduction was greater for low P supply than for salinity alone, but their interaction was not additive. The detrimental effects on root growth became apparent 10 days earlier in Jandaroi compared to Janz. Root length, root number, root length densities, and root number densities were higher in the upper 10 cm soil layer than in the lower layers for both cultivars. This study demonstrated that 10 μM P is more detrimental than 100 mM NaCl for shoot and root growth of both wheat cultivars irrespective of their difference in salinity tolerance.


Introduction
More than 6% of the world's land and 20% of its irrigated areas are facing salinity threats [1,2]. Soil salinity is a major abiotic stress that limits crop growth and productivity [3,4]. Soil salinity causes osmotic stress [5] and ionic imbalance [4,6], and reduces gas exchange [7,8], tissue water, and chlorophyll contents [9], which reduce shoot and root growth [3,10,11]. The extent of the damage caused by salinity depends on the plant's developmental stage, duration of the salt stress, the amount and type of salt in the growth medium, and the crop cultivar/genotype [7,8].
Plants have developed various mechanisms to overcome both the osmotic and ionic effects of salinity [1,3]. Salt-tolerant plants have better osmotic adjustment capabilities, enabling them to uptake water under high salinity levels [5]. Ionic toxicity is mitigated by the restricted uptake of toxic ions or cellular compartmentation into vacuoles or older tissues [12]. Moreover, maintaining a higher K + /Na +

Plant Material and Growth Conditions
The Australian bread wheat (Triticum aestivum L.) cultivar Janz (released in 1989, tolerant to soil salinity) and the durum wheat (Triticum turgidum L.) cultivar Jandaroi (released in 2007, sensitive to soil salinity) were selected for the study, based on their differences in tolerance to soil salinity and their similar phenological development [31,33,34]. Both cultivars were grown in freely draining rhizoboxes (40 cm length × 5 cm width, 60 cm depth) filled with a local, coarse sandy soil. A black Polyvinyl chloride sheet was used to cover the acrylic glass wall of each rhizobox to protect the roots from direct sunlight exposure. The boxes were placed at a 30 • angle on steel stands to facilitate root growth towards the acrylic glass side [30,35]. The 30 • angle inclination is ideal for handling and mapping the root system when seeds are sown close to the acrylic glass wall [36,37]. There were two rhizoboxes on each steel stand placed on glasshouse benches.
The soil used in this experiment had the following properties: pH 6.7 (H 2 O) and 6.0 (CaCl 2 ), electrical conductivity 0.032 dS m −1 , organic carbon 2.0 g kg −1 , and nitrate-N, ammonium-N, Colwell Agronomy 2018, 8,155 3 of 16 P and Colwell K were 1.0, 1.0, 3.0, and 27 µg g −1 , respectively. The total N may be one to two orders of magnitude higher than the measured nitrate and ammonium levels. However, a high fraction of this N may be in recalcitrant forms that are not available to the plants. Each rhizobox was filled with soil to a bulk density of 1.53 g cm −3 . Three pre-germinated seeds of each cultivar were sown at a depth of 2 cm in rows very close to the acrylic glass wall of each rhizobox corresponding to the field sowing density of 150 plants m −2 . After sowing on 17 June 2016, plants were provided with 30 mL a low-concentration nutrient solution on each alternate day. The solution was the same as the one used by [16] with the P concentration modified. The solution contained (in µM): N (1000), K (1220), Ca (600), S (812), Mg (200), Zn (0.75), Cu (0.2), B (5), Mn (0.75), Mo (0.03), Co (0.2), and Fe (20). Two levels of P (10 and 100 µM) were applied as low and optimal P treatments, respectively. In the low P treatment, potassium compensation was provided by adding a supplementary amount of K 2 SO 4 , in order to maintain the same K concentrations in all treatments. For the 100 mM salinity treatment, NaCl salt was added to a nutrient solution containing an optimal P concentration. The control treatment had an optimal P concentration but without salinity.
The experiment was conducted in a temperature-controlled glasshouse at The University of Western Australia, Perth, Australia (31 • 93' S, 115 • 83' E) with a mean relative humidity of 65-70%, and a day/night temperature of 25/20 • C. The glasshouse received natural daylight (photoperiod) for 11.5 to 12.5 h during the study. The average maximum photosynthetic photon flux density (PPFD) of plants was 951 ± 21 µmol m −2 s −1 at 13:00 h. The salinity and low P treatments commenced at the two-leaf stage (10 days after sowing, DAS). Plants within each treatment were supplied with 50 mL of the relevant nutrient solutions (control, saline, low P, saline + low P) on a daily basis until harvest. The rhizoboxes were randomly rearranged each week to minimize environmental impacts. A completely randomized design comprising two wheat cultivars and four treatments (control, saline, low P, saline + low P) with three replications (rhizoboxes) was used. The experiment was assessed at 40 DAS.

Gas Exchange and Chlorophyll Content
Stomatal conductance (gs), leaf net photosynthetic rate (A), and transpiration rate (E) were measured one day before harvest (i.e., 39 DAS) between 10:00 to 14:00 h on the second fully expanded leaf from the top using a LI-6400 Portable Photosynthesis System (LI-COR, Lincoln, NE, USA). The measurement conditions were: ambient CO 2 concentration 372 mmol mol −1 , ambient pressure 99.0 kPa, average water vapour pressure in the chamber 3.45 kPa, air flow per unit leaf area 205.5 mol m −2 s −1 and maximum photosynthetically active radiations (PAR) up to 1300 mmol m −2 s −1 . The chlorophyll content index of the same leaf was measured with SPAD 502 plus chlorophyll meter (Spectrum Technologies, Aurora, IL, USA).

Shoot Traits and Nutrients
Shoot traits such as shoot length, leaf area (LA), tissue water content, and shoot biomass were measured at harvest. Shoot length was measured with a ruler, and LA was measured with a portable leaf area meter (LI-3000, LI-COR Biosciences, Lincoln, NE, USA). Tissue water content (TWC) of the same leaf was measured using the following equation described by [9]: where, FW is leaf fresh weight obtained immediately after harvest, and DW is leaf dry weight obtained after drying the leaves at 70 • C to a constant weight.
All of the plants in each rhizobox were harvested as a single replicate. The shoots were cut at the crown level, and shoot dry weights were recorded after oven drying at 70 • C for 48 h. Plant samples were digested in di-acid (nitric acid and perchloric acid) as described by [38]. The digest was used to measure the concentrations of Na + , K + , and P in the shoot and root samples.

Root Growth
From the two-leaf stage (10 DAS) until harvest (40 DAS), root growth was traced onto plastic film at 10-day intervals. On each occasion, the growth of new visible roots was traced onto transparent plastic film using a permanent water proof pen. Root growth was also marked on the glass panel each time to distinguish the new, emerging roots. The transparent films were scanned at 600 pixels with a portable scanner (Jenkins PS4100; East Bentleigh, Melbourne, Australia). The root images were analysed for root length and number using WinRHIZO (2008 Pro, Regent Instruments, Québec, QC, Canada).

Root Traits at Harvest
At harvest, the acrylic glass wall of each rhizobox was removed and the soil was divided into six 10-cm sections [36]. The soil of each section was washed through a sieve to recover the roots. Root subsamples were placed in plastic bags and stored at 4 • C until scanning. The roots were placed in a glass tray and scanned at 400 pixels per mm [39] using a desktop scanner (Epson Expression Scan 1680, Epson America Inc., Long Beach, CA, USA). The obtained images were analysed for root length and root number using WinRHIZO 2008 (model Pro, version 2, Regent Instruments, Québec, QC, Canada) computer software. Root length density (RLD) and root number density (RND) were calculated by dividing the root length and root number of each section by the volume of that section [16,30]. Root samples were then oven dried at 70 • C for 48 h and the dry weights were recorded. Root length was divided by root dry weight to obtain the specific root length.

Statistical Analysis
All the data were analysed using statistical software package "Statistix 8.1" in a completely randomized design. One-way analysis of variance (ANOVA) was performed as described by [40]. The least significant difference (LSD) test at 5% significance level and standard errors of the mean were used for further comparison of the treatments.

Plant Growth and Shoot Traits
Both wheat cultivars were at the two-leaf stage by 10 DAS and they had no emerged tillers at the end of the experiment (40 DAS), indicating similar phenology. The effects of the salinity and low P treatments significantly affected shoot length in both cultivars (Table 1, p ≤ 0.001). The three treatments (salinity, low P, salinity + low P) significantly reduced shoot length in the salt-sensitive cultivar (Jandaroi) to similar values. The salinity treatment had no effect on shoot length in the salt-tolerant cultivar (Janz), but the low P and salinity + low P treatments significantly reduced the shoot length by about one-third, compared to the control. Leaf areas of both cultivars were significantly (p ≤ 0.001) reduced in all three treatments, and more so in the low P treatments than the salinity treatment (Table 1). Table 1. Effects of salinity, low phosphorus (P) supply and their interaction on shoot length (SL, cm), leaf area (LA, cm 2 ), shoot dry weight (SDW, g plant −1 ), root dry weight (RDW, g plant −1 ), shoot:root dry weight ratio (RDW:SDW), chlorophyll content index (CCI, SPAD value) and tissue water content (TWC, mL g −1 DW) of salt-tolerant (Janz) and salt-sensitive (Jandaroi) wheat cultivars. The three treatments significantly reduced shoot dry weights in both cultivars. The effect of low P was similar in both cultivars, while salinity had a more pronounced effect in Jandaroi. The three treatments significantly (p ≤ 0.001) reduced root dry weights in both cultivars, more so in the low P and salinity + low P treatments. There was not much difference in both cultivars regarding their response to the combined treatment of salinity, and low P and reduction in dry weights was on par with low P treatments in both cultivars (Table 1). Root-to-shoot dry weight ratio (root:shoot) was higher in both low P treatments than in salinity and control treatments in Janz. In the case of Jandaroi, root:shoot in three stress treatments was on par and higher than the control treatment (Table 1).

Janz
Tissue water content (TWC) in both cultivars significantly declined in all three treatments (Table 1). In Janz, low P supply reduced TWC more than salinity. In Jandaroi, the reduction in TWC in low P treatment was on par with salinity and salinity + low P treatments. In both cultivars, the salinity + low P treatment reduced TWC to a similar level as the low P treatment. In Janz, the salinity treatment had no effect on the chlorophyll content index (Table 1), but it declined markedly in the low P and salinity + low P treatments. In Jandaroi, all three treatments reduced the chlorophyll content index to similar values, which were significantly less than the control.
The leaf gas exchange attributes were significantly (p ≤ 0.001) reduced under salinity and low P treatments. In both cultivars, leaf net photosynthetic rate (A) declined with salinity and low P supply, more so in the low P and salinity + low P treatments, which declined to similar values ( Figure 1A). A similar trend was observed for transpiration rate (E) in Janz, while in Jandaroi transpiration rate declined but to a similar extent in all treatments ( Figure 1B). In both cultivars, stomatal conductance declined more with low P supply than with soil salinity, and the reduction in the salinity + low P treatment was similar to that in the low P treatment ( Figure 1C). more so in the low P and salinity + low P treatments, which declined to similar values ( Figure 1A). A similar trend was observed for transpiration rate (E) in Janz, while in Jandaroi transpiration rate declined but to a similar extent in all treatments ( Figure 1B). In both cultivars, stomatal conductance declined more with low P supply than with soil salinity, and the reduction in the salinity + low P treatment was similar to that in the low P treatment ( Figure 1C).

Tissue Ionic Contents
Shoot and root Na + concentrations increased significantly (p ≤ 0.001) in both cultivars in the salinity treatment (Table 2) and more so than the salinity + low P treatment. The low P treatment had no effect on shoot and root Na + concentration in either cultivar. Shoot and root K + concentrations decreased significantly (p ≤ 0.001) in both cultivars in all three treatments ( Table 2). The salinity treatment reduced the shoot and root K + concentrations more than the low P treatment in both cultivars. In the salinity + low P supply treatment, these reductions were similar to those in the salinity treatment, except for shoot K + concentration in Jandaroi, where an additive effect was observed. Table 2. Effects of salinity and low P supply, and their interactions on shoot and root ionic concentrations (mmol g −1 DW) and K:Na ratios of salt-tolerant (Janz) and salt-sensitive (Jandaroi) wheat cultivars.

Tissue Ionic Contents
Shoot and root Na + concentrations increased significantly (p ≤ 0.001) in both cultivars in the salinity treatment (Table 2) and more so than the salinity + low P treatment. The low P treatment had no effect on shoot and root Na + concentration in either cultivar. Shoot and root K + concentrations decreased significantly (p ≤ 0.001) in both cultivars in all three treatments ( Table 2). The salinity treatment reduced the shoot and root K + concentrations more than the low P treatment in both cultivars. In the salinity + low P supply treatment, these reductions were similar to those in the salinity treatment, except for shoot K + concentration in Jandaroi, where an additive effect was observed. Table 2. Effects of salinity and low P supply, and their interactions on shoot and root ionic concentrations (mmol g −1 DW) and K:Na ratios of salt-tolerant (Janz) and salt-sensitive (Jandaroi) wheat cultivars. The shoot and root K + :Na + ratios decreased significantly (p ≤ 0.001) in both cultivars in the salinity and low P treatments (Table 2), more so in the salinity treatment. The K + :Na + ratios in both cultivars in the salinity + low P treatment declined to similar values as in the salinity treatment.

Janz
Shoot and root P concentrations declined (p ≤ 0.001) in both cultivars in the salinity and low P treatments ( Table 2). The shoot and root P concentrations in both cultivars declined more, and to a similar extent, in the low P and salinity + low P treatments than the salinity treatment, more so in Janz than in Jandaroi.

Root Growth
From 10 to 20 DAS, there was no significant difference in accumulated root length between treatments in Janz ( Figure 2A); differences became apparent from 30 DAS and maximal at 40 DAS, at which time the low P and salinity + low P treatments had the lowest accumulated root lengths. For Jandaroi, differences in accumulated root length between control and rest of the treatments became apparent as early as 20 DAS ( Figure 2B). The largest differences were observed at 40 DAS with accumulated root length ranked as control > salinity > low P > salinity + low P. From 10 to 20 DAS, all treatments had similar cumulative root numbers in Janz ( Figure 2C); differences became apparent at 30 DAS and maximal at 40 DAS. For Jandaroi, differences in cumulative root numbers between control and rest of the treatments became apparent at 20 DAS (10 days early than Janz) though not statistically significant, and maximal at 40 DAS, at which time all treatments had the highest cumulative root numbers ( Figure 2D).  Root length density (RLD) in both cultivars was higher in the top 10 cm layer of the soil profile than the middle (10-20 cm) and lower (20-30 cm) layers ( Figure 3A,B), with RLD in top 10 cm layer ranked as control > salinity > low P > salinity + low P. In Janz, RLD in the middle layer did not differ  Root length density (RLD) in both cultivars was higher in the top 10 cm layer of the soil profile than the middle (10-20 cm) and lower (20-30 cm) layers ( Figure 3A,B), with RLD in top 10 cm layer ranked as control > salinity > low P > salinity + low P. In Janz, RLD in the middle layer did not differ between treatments, and no root growth occurred in the lower layer in the control. In Jandaroi, the control had higher RLD in the middle layer than the low P and salinity + low P treatments; no root growth occurred in the lower layer of the soil profile in the control or salinity treatment. Root number density (RND) in both cultivars was higher in the top layer of the soil profile than the middle and lower layers ( Figure 3C,D). In both cultivars, the top layer had the highest RND (control > salinity > low P > salinity + low P). In Janz, in the lower layer, the salinity treatment had higher RND than the two low P treatments. In Jandaroi, in the lower layer, there was no difference in RND between treatments. between treatments, and no root growth occurred in the lower layer in the control. In Jandaroi, the control had higher RLD in the middle layer than the low P and salinity + low P treatments; no root growth occurred in the lower layer of the soil profile in the control or salinity treatment. Root number density (RND) in both cultivars was higher in the top layer of the soil profile than the middle and lower layers ( Figure 3C,D). In both cultivars, the top layer had the highest RND (control > salinity > low P > salinity + low P). In Janz, in the lower layer, the salinity treatment had higher RND than the two low P treatments. In Jandaroi, in the lower layer, there was no difference in RND between treatments.  At the end of the experiment (40 DAS), the three treatments had significantly (p ≤ 0.001) affected total root lengths and root numbers in both cultivars (Figures 4 and 5A,B). The controls had the highest total root lengths and root numbers, followed by the salinity treatment and, lastly, the two low P supply treatments. In both cultivars, the two low P treatments led to similar total root lengths and root numbers. Specific root length was higher in the three stress treatments as compared to control in Janz, whereas in the case of Jandaroi, control and salinity treatments had higher specific root lengths than the two low P treatments ( Figure 5C).  At the end of the experiment (40 DAS), the three treatments had significantly (p ≤ 0.001) affected total root lengths and root numbers in both cultivars (Figures 4 and 5A,B). The controls had the highest total root lengths and root numbers, followed by the salinity treatment and, lastly, the two low P supply treatments. In both cultivars, the two low P treatments led to similar total root lengths and root numbers. Specific root length was higher in the three stress treatments as compared to control in Janz, whereas in the case of Jandaroi, control and salinity treatments had higher specific root lengths than the two low P treatments ( Figure 5C).  At the end of the experiment (40 DAS), the three treatments had significantly (p ≤ 0.001) affected total root lengths and root numbers in both cultivars (Figures 4 and 5A,B). The controls had the highest total root lengths and root numbers, followed by the salinity treatment and, lastly, the two low P supply treatments. In both cultivars, the two low P treatments led to similar total root lengths and root numbers. Specific root length was higher in the three stress treatments as compared to control in Janz, whereas in the case of Jandaroi, control and salinity treatments had higher specific root lengths than the two low P treatments ( Figure 5C).

Relative Effect of P and Salt on Growth and Physiology
This study found that low P stress (10 µM) reduced the shoot and root growth of both wheat cultivars more than did salinity stress (100 mM). In line with our findings, Talbi et al. [9] found that low P supply was the most limiting factor for barley growth when it was exposed to a combination of salinity and low P supply. Phosphorus is a crucial macronutrient that is involved in

Relative Effect of P and Salt on Growth and Physiology
This study found that low P stress (10 µM) reduced the shoot and root growth of both wheat cultivars more than did salinity stress (100 mM). In line with our findings, Talbi et al. [9] found that low P supply was the most limiting factor for barley growth when it was exposed to a combination of salinity and low P supply. Phosphorus is a crucial macronutrient that is involved in photosynthesis, carbohydrate metabolism, respiration, nucleic acid synthesis, membrane synthesis and stability, and enzymes activities [14,15]. Reductions in plant growth under salinity and/or low P supply has been well documented [9][10][11]16,41]. However, under low P supply, the addition of salt to the growth medium did not further reduce growth attributes in either cultivar; that is, the interactive effects were not additive. A hydroponic experiment found that P deficiency (5 µM) significantly improved plant tolerance to salinity (100 mM NaCl) in a maize cultivar by regulating plant growth, tissue osmotic properties, and K + and Na + accumulation [42]. Other studies have suggested that the outcome of such interactions is related to plant species, cultivars, and the type of stress imposed [10,13,23]. Different levels of P in P deficiency studies have been used. For instance, Liao et al. [29] used 26 and 339 mg P/kg soil as deficient and sufficient P levels, respectively, on cereals including wheat. In another study, Osborne et al. [28] grew 53 wheat genotypes at 0 kg/ha and 30 kg/ha P under field conditions, and Fahad et al. [13] applied 5 µM P as a low P treatment, and 60 µM P and 180 µM P as sufficient P treatments to wild and cultivated barley. On the hand, screening/response of wheat genotypes to salinity has been mostly studied in the range of 50-150 mM NaCl [6,7,43]. Regarding the interaction of salinity and low P, our results are well in line with the findings of [9,13,23] who applied 5 µM P as a low P treatment, and 100 mM NaCl as salinity stress. The results clearly showed a stronger effect of low P than the applied level of salinity. So, for more conclusive studies of interaction between low P and salinity stress, gradients of stress levels of low P and NaCl should be applied.
In this study, as expected, the salinity treatment affected the salt-sensitive Jandaroi more than the salt-tolerant Janz, confirming the greater salt tolerance potential of the later cultivar [27,34]. The more severe osmotic [5] and ionic [6,44] effects of salts in Jandaroi are likely to have resulted in the greater reductions in shoot and root biomass, relative to Janz. The osmotic effect is the first response to salinity and it reduces growth, mainly due to water deficiency in the plant tissues. The ionic effect is characterized by excessive accumulation of toxic ions in the cells, which slows growth by interfering with some important biochemical processes [5]. In contrast to saline treatment, there was not much difference in both cultivars regarding their response to low P and the combined treatment of salinity with low P. Both Janz [28][29][30] and Jandaroi [31,32] are P-inefficient cultivars. Their similar sensitivities to P might be one of the factors for their similar dry weight productions under both low P treatments. The greater reduction in biomass under low P than salinity may be related to the greater reduction of various physiological attributes, such as tissue water and chlorophyll contents and gas exchange parameters. Under P-deficient conditions, the water-conducting capacity of roots declines, due to the reduced activity of water channel proteins (aquaporins), which ultimately reduces cell water contents [9,23,45]. The leaf chlorophyll content in both cultivars decreased under low P supply, which agrees with the findings from previous studies [46], and may be due to its limited biosynthesis or enhanced degradation through increased activity of the chlorophyllase enzyme [47]. It is important to note that the salinity treatment did not affect chlorophyll content in Janz, again confirming its greater salt tolerance.
Leaf gas exchange attributes (net photosynthesis rate, stomatal conductance and transpiration rate) in both cultivars were affected to different extents by soil salinity and low P supply, as observed in previous studies [9,23]. Leaf gas exchange characteristics did not significantly differ between the low P and the salinity + low P treatments in either cultivar. Reduced stomatal conductance under salinity and/or low P stress limits CO 2 influx and water vapor efflux from the leaf surface [9,48]. In our study, the limited intake of CO 2 and the reduced chlorophyll contents may have caused the apparent reduction in photosynthetic rate in both cultivars. However, Yousfi et al. [49] reported that stomatal closure is an adaptive mechanism by plants suffering from salinity-induced water deficiency, and it causes a corresponding decrease in transpiration rate. A reduction in gas exchange attributes can greatly influence biomass production [50]. In our study, the low P treatment reduced gas exchange attributes more than did the salinity treatment, thus further reducing plant biomass in both cultivars.

Relative Effects of P and Salt on Ionic Balance
We found that Na + accumulation was higher in saline treatment with optimal P supply than low P supply, which has also been observed in barley [9]. In soybean, high P supply increased Na + uptake, reducing salt tolerance [24]. It can thus be concluded that P supply affects Na + transport within plants. A recent study in maize showed that P deficit improved plant tolerance to salinity stress by reducing tissue Na + accumulation [42]. Under both salinity treatments, bread wheat cultivar Janz accumulated significantly less Na + in shoot as compared to the durum wheat cultivar Jandaroi. This differential Na + uptake may be related to the presence of HKT1; 5 transporter on the Kna1 locus on chromosome 4D, in case of the hexaploid wheat Janz, and it is absent in tetraploid wheat (Jandaroi) [51]. We found that the salinity treatment reduced shoot and root K + concentrations more than the low P treatment, in line with previous studies [9,23]. The greater reduction in K + concentration under salinity is due to competition between Na + and K + ions for the same cation channels, and the limited uptake of K + in the presence of a higher concentration of Na + ions in the growth medium [10,52] resulting in lower K + :Na + ratios. Therefore, the higher salinity tolerance of Janz compared to Jandaroi may be attributed to (a) its relatively higher shoot and root K uptake, (b) higher K + :Na + ratios, and (c) Na + exclusion from shoot via the HKT1;5 transporter [3,6,51,53].
We found that low P supply in the growth medium caused remarkable decreases in shoot and root P concentrations in both cultivars as also observed by [13,16]. Salinity also caused significant declines in shoot and root P concentrations, which contrasts with the findings of [13,23], where shoot and root P concentrations increased in barley grass and cultivated barley genotypes in response to salinity. However, in studies on lettuce [21] and spinach [22], soil salinity reduced P concentrations in all plant tissues. Information on the interaction of salinity and low P is limited and without consensus [25]. It has been suggested that the effects of salinity on P uptake vary depending on growth conditions (sand culture, soil culture, or hydroponics), the amount of salt and P in the media, the duration of the treatments, and the species or genotypes being tested [54].

Relative Effects of P and Salt on Root Growth and Morphology
Our data on accumulated root lengths and numbers revealed that the growth pattern of the two wheat cultivars differed with time. Both cultivars had similar accumulated root lengths and numbers for all the treatments at 10 DAS. The differences between the control and the rest of the treatments in Jandaroi became apparent as early as 20 DAS, whereas in case of Janz, these differences became apparent only at 30 DAS. For both cultivars, more clear differences in root lengths and root numbers between the control and the stress treatments were observed at 40 DAS than at 20 and 30 DAS. Similar root growth and proliferation patterns with time has been well documented for various wheat cultivars under different treatments [30,35,36]. Moreover [1] reported that the initial effect of salinity (osmotic effect) becomes effective with the addition of salt, and causes early growth reduction in plants due to water deficiency. Nevertheless, this osmotic effect is a temporary stress and it is followed by a more pronounced and deleterious ionic effect if plants are exposed to salinity for a few weeks.
Root length and root number densities in both cultivars were higher in the upper soil layers (0-10 cm) than the middle (10-20 cm) and lower (20-30 cm) layers. A similar pattern was observed in narrow-leafed lupin in P-deficient conditions [41]. Pfeifer et al. [36] observed similar root growth patterns in Janz and two other wheat genotypes. In the upper soil layer, the control treatment had the highest root length densities for both cultivars, followed by the salinity, low P and salinity + low P treatments. In the middle and lower soil layers, there were few differences between treatments. Root:shoot ratio was increased in both cultivars under P deficient conditions. This was mainly due to changes in biomass allocation pattern from shoot to root in response to low P supply [9,13]. Specific root length was higher in both low P treatments in Janz, whereas in Jandaroi, it was lower as compared to the control treatment. Specific root length is an indicator of root thickness [30]. Thus, it can be inferred that in response to low P supply, Jandaroi produced thicker roots and Janz produced more fine roots. While the highest total root length and root number for both cultivars were observed in the control treatment, root growth in deeper soil layers with low P supply may be due to the adaptive strategies of plants to increase P uptake [55]. For example, several authors have reported that the root morphology of plants shifts towards finer and longer roots under low P conditions to enhance P uptake from deeper soil layers [13,16,43].

Conclusions
Our study has demonstrated that low P (10 µM P) caused more reduction in shoot and root growth attributes than salinity (100 mM NaCl), both in salt-tolerant and salt-sensitive wheat cultivars. Cultivar Janz had lower tissue Na + accumulation and thus was more tolerant to salinity than Jandaroi. The detrimental effects of soil salinity and low P supply on root length and root number became apparent 10 days earlier in Jandaroi than Janz, and these effects were more pronounced in the top layer of soil profile in both cultivars.