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1867 
Bioscience Journal  Original Article 

Biosci. J., Uberlândia, v. 36, n. 6, p. 1867-1878, Sept./Oct. 2020 
http://dx.doi.org/10.14393/BJ-v36n6a2020-42494 

WHEAT GROWTH AND NUTRIENT UPTAKE AFTER PHOSPHORUS AND 
POTASSIUM APPLICATIONS IN SALINE-SODIC FIELD OF SEMI-ARID 

REGION 
 

CRESCIMENTO DO TRIGO E ABSORÇÃO DE NUTRIENTES APÓS APLICAÇÕES 
DE FÓSFORO E POTÁSSIO EM CAMPO SALINO-SÓDICO DO SEMI-ÁRIDO 

 
Zahid HUSSAIN1; Riaz Ahmad KHATTAK2; Ping AN3; Yang SHAO3; Muhammad IRSHAD*4 

1. Department of Development Studies, COMSATS University Islamabad, Abbottabad Campus, Pakistan 
2. The Brains Institute, Peshawar, Pakistan; 3. Arid Land Research Center, Tottori University, Hamasaka, Tottori, Japan; 4. Department 

of Environmental Sciences, COMSATS University Islamabad, Abbottabad Campus, Pakistan *Corresponding author: 
mirshad@cuiatd.edu.pk 

 
ABSTRACT: Nutrient deficiency is a limiting factor in saline-sodic soils resulting in low crop 

production. The study investigated wheat response to P and K added to soils. The K was applied at 0 (K0), 75 
(K1), 150 (K2) kg K2O ha

-1 as K2S04 and at (0 (P0), 60 (P1), 120 (P2) kg P2O5 ha
-1 as (NH4)2HPO4 in three 

replications under two-factorial randomized complete block (RCB) design. Both treatments significantly 
enhanced wheat grain (118%) and dry matter yield (60%) at P2K2 compared to control. The P treatments 
significantly affected leaf P, Mg, SO4, Ca:P, SO4:P ratios and soil P, Ca:P, Cl:P and SO4:P ratios, while K on 
leaf K, Na, Ca, SO4 concentration, K:Na, K:Ca, SO4:P,Ca:P ratios and soil pH, Na, K, Ca, SO4 concentrations, 
SAR, Na:K, Ca:K and Na:Ca ratios. Leaf Na was decreased to 85.3 mmol (+) kg-1 at K2 compared to 105.3 
mmol (+) kg-1at P2K0. Negative correlation (R2=0.906) of leaf K:Na was found with leaf Na concentration. The 
correlation of dry matter was higher (R2=0.851) with leaf K:Na ratio than grain yield (R2=0.392). It is 
concluded that the addition of K and P addition shows beneficial effects in improving crop nutrition and wheat 
yield in the saline-sodic soil environment. 
 

KEYWORDS: Arid region. P. K. Saline-sodic soil. Semi-arid region. Wheat growth. 
 
INTRODUCTION 
 

Reclamation of salt-affected soils through 
appropriate on-farm fertility management practices 
serves as a vital tool for the enhancement of crop 
production (JORDAN et al., 2004). Under salt 
stress, proper fertilizer applications to the soil can 
increase crop yields (HUSSAIN et al., 2014). 
Potassium (K) and phosphorus (P) can be important 
in minimizing the negative impacts of high salt 
stress in soils (GARG; GUPTA, 1998). The plants’ 
tolerance against salt stress may be improved by 
optimized K nutrition (RÖMHELD; KIRKBY, 
2010) as K plays important role in regulating the 
osmotic potential of crops and minimizing salt stress 
in saline environments. However, the P and salinity 
interactions in plant nutrition are complicated and 
vary with crop species, types of salts, levels of 
salinity, growth conditions, and the P concentrations 
of growing media (NISTE et al., 2014). 

Salinity compromises the agricultural 
potential as well as imparts serious implications on 
the socio-economic conditions of the farming 
community (HAIDER; HOSSAIN, 2013). There is 
an agreement that higher concentrations of salts in 
the rhizosphere create the osmotic stress which 

disturbs the nutrient balance and develops specific 
ion toxicity in salt-affected soils.  

A positive relationship between K uptake 
and the salinity tolerance in wheat and barley was 
reported (CUIN et al., 2008). The accumulation of 
compatible solutes by plant tissues is improved in 
the presence of K which helps to mitigate salinity 
induced damages. For example, the presence of 
proline minimizes the effects of high osmotic 
pressure by salts in soil and water and permits water 
uptake by plants, protects enzymes and proteins, and 
improves the cell wall structure (SUN et al., 2015). 
The application of K in the presence of Ca reversed 
the salinity induced stress in Cichorium endivia L., 
cv. Green Curled (TZORTZAKIS, 2010). The 
adverse effects of salinity on plants grown on P 
deficient soils and improved wheat growth in 
moderate and high soil salinity with P are reported. 
Also, P improved uptake of N, P, K, and Zn in 
sandy and calcareous soils (WAGDI et al., 2013). 
The physiology of the wheat plants was stabilized 
with P application which was due to supporting K 
transport in the plant (KHAN et al., 2013). Studying 
the interactive effects of K and P nutrition on wheat 
under natural field conditions of salinity is vital to 
understand the crop response and nutrient uptake. 

Received: 20/05/2019 
Accepted: 30/01/2020 



1868 
Wheat growth...  HUSSAIN, Z. et al. 

Biosci. J., Uberlândia, v. 36, n. 6, p. 1867-1878, Sept./Oct. 2020 
http://dx.doi.org/10.14393/BJ-v36n6a2020-42494 

The impacts of P and K fertilizers on soil 
reclamation and growth of maize and sugar beet 
were studied in the same area (HUSSAIN et al., 
2014; 2015). The present study aimed to further 
investigate the interactions of P and K and salinity 
on wheat growth and nutrient uptake in a saline-
sodic environment. 
 
MATERIALS AND METHODS 
 
Background and description of the study location 

Pakistan falls in arid and semi-arid climate 
region with salt-affected soils ranging from 5.73 m 
ha (RASHID, 2006) to 6.67 m ha (ALI et al., 2004). 
This poses a major threat to the sustainability of 
agriculture in Pakistan. District Kohat lies in 
southern Khyber Pakhtunkhwa province of Pakistan 
with a large area affected by salinity and sodicity 
(HUSSAIN et al., 2015). High evapotranspiration 
and low rainfall elevate salt accumulation in the soil 
profile. The use of saline groundwater for irrigation 
because of the unavailability of freshwater, low 
rainfall, and high salinity stress have aggravated the 
situation to the extent that most farmers have 
abandoned farming as their major livelihood 
resources.  

The experimental field lies in Tehsil Lachi 
of District Kohat in the north-western province of 
Pakistan. The soils are mixed hyperthermic Typic 
Halusteps (Soil Survey of Pakistan, 2007). The 
region is semi-arid to sub-humid subtropical 
continental situated in longitude 320 47’ and 340 5’ 
North and latitude 690 53’ and 720 1’ East (Soil 
Survey of Pakistan, 2007). Soil is calcareous, 
yellowish to reddish-brown with fine sandy loam to 
silty clay and clay loam textured and is poorly 
structured. Groundwater used for irrigation is of 
poor quality with an ECiw level of 2.2–3.0 dS m

-1. 
The soils of the area are classified as saline-sodic 
soils based on measured parameters (ECe= 5.0-9.0 
dS m-1, SAR>15).  
 
Experimentation 

A farmer’s field with characteristics of 
salinity and sodicity was selected for the 
experiment. The K2S04 was applied at three doses of 
0, 75, and 150 kg K2O ha

-1 while di-ammonium 
phosphate (DAP) at three doses of 0, 60, and 120 kg 
P2O5 ha

-1 in 27 plots of 5x5 m2 in three replications. 
The urea was applied as a basal dose to all the plots 
uniformly at 120 kg N ha-1. Inqilab-91 was selected 
as the experimental wheat variety which is widely 
used as a major wheat crop in the study area, while 
seed rate was kept as 120 kg ha-1. Two-factorial 
randomized complete block (RCB) design was 

applied to the experiment. The experiment was 
completed at crop maturity. 
 
Analytical procedures 

Before the sowing of the crop and the start 
of irrigation, composite soil samples, and 
groundwater samples were collected and analyzed. 
The plastic bottles were cleaned and rinsed for the 
collection of groundwater samples. The samples 
were filtered using Whatman filter paper No. 40 and 
saved for further analysis. At crop maturity, grain, 
and dry matter yield (Mg ha-1) of wheat were 
determined. Fully matured and young leaves of 
wheat plants were collected prior to harvesting of 
the crop. The leaf samples were cleaned with 
purified water and dehydrated in an oven at 70 0C 
for 2 days. After drying, the leaves were milled and 
saved for further analyses. The leaf samples were 
wet-digested as follows: A 0.5 g of oven-dried leaf 
samples were weighed and transferred to flask. A 10 
mL of concentrated HNO3 was added to the samples 
and were left overnight. The next day, 4 mL of 
HCIO4 was added to the flask and gently heated in 
block heater for complete digestion. The digested 
material was cooled and filtered. Distilled water was 
added to make the desired volume. Chemical 
analysis for cations and anions in leaf samples was 
done. 

Soil samples from each pot were collected at 
the depth of 0-30 cm after harvesting of crops. 
Samples were openly dried and then crushed and 
sieved through 2 mm sieve. The samples were then 
saved for further analyses. The texture of the soils 
was determined using the hydrometric method. A 
250 g soil was weighed, and the distilled water was 
added carefully to make the saturated soil paste 
while continuously stirring with a spatula. After 
that, the shining paste was developed, it was kept for 
a night to completely dissolve the salts, as well as 
the equilibrium, was achieved (RICHARDS, 1954). 
The samples were extracted to obtain clear extract 
using an aspirator. The saturation extract was 
refrigerated. 

The electrical conductivity (EC) of the 
saturation extracts and the groundwater samples was 
measured with digital Electrical conductivity meter, 
Wiss. Techn. Werkstatten (WTW) D12 Weilheim. 
The pH of groundwater samples as well as 
suspension of 1:5 soil: water was determined with 
105 Ion analyzer pH meter (MCLEAN, 1982; 
THOMAS, 1996). The Na and K concentrations in 
mmol (+) L-1 were determined in soil saturated 
extracts, groundwater, and plant samples using the 
Perkin-Elmer flame photometer model No. 2380. 
The [Ca] and [Mg] in saturation extract was 



1869 
Wheat growth...  HUSSAIN, Z. et al. 

Biosci. J., Uberlândia, v. 36, n. 6, p. 1867-1878, Sept./Oct. 2020 
http://dx.doi.org/10.14393/BJ-v36n6a2020-42494 

determined by titration methods (Richards, 1954). 
The SAR of saturation extract and the groundwaters 
was calculated using mmol (+) L-1 concentrations of 
Na, Ca, and Mg by the following formula. 

 
MSTATC statistical program was used for 

statistical analysis of the data. Regression analysis 
was performed for important variables such as 
yields of wheat and concentrations of ions and their 
ratios to understand important relationships. 
 
RESULTS  
 
Wheat yield  

There was a significant effect of K and P 
treatments on grain (P<0.01 and P<0.001) and dry 
matter (P<0.001) yields of wheat. Grain yield was 
significantly (P<0.05) influenced by P-K 
interactions but non-significant for dry matter yield 
(Table 1). Grain yield enhanced by 28 and 4.0 at 
P1K1and P1K2 and 40% and 16% at P2K1 and 
P2K2, respectively, comparative toK1 and K2 at P0. 
The increase on the other hand was by 50 and 88% 
at K1 and K2 without P but elevated to 93 and 95% 
at P1 and to 110 and 118% at P2 ha-1, respectively, 
when compared with P0K0 (Table 1). There seemed 
to be a progressive increase in yield at all K levels at 
P0. But with P1 and P2 addition at these K levels 
demonstrated a much higher effect of P on wheat 
grain yield. 

The significant (P<0.001) increase in dry 
matter (DM) yield was observed with P and K 
treatments. The DM yield improved by 7 and 23 % 
at K1 and K2 with P0, 18 and 26 % at P1 and 28 and 
61 % at P2, respectively, compared to P0K0 (Table 
1). The dry matter yield was highest at P2K2 as 
compared to P0K0. The increasing rates of K2O and 
P2O5 in saline-sodic soils consistently enhanced dry 
matter yield as shown by mean (n=9) data in Table 
1. The analysis of variance (ANOVA) shows the 
influence of P, K treatments on yields of wheat 
grown under salt-affected conditions. The P 
treatments improved grain yields while K promoted 
dry matter yield under salt-affected conditions. 
 
Chemical analysis of wheat leaf samples 

The ANOVA for chemical analysis of leaf 
tissues of wheat showed that the application of P 
significantly influenced leaf concentrations of P 
(P<0.001), Mg (P<0.01), SO4 (P<0.001) and ratios 
of Ca:P and SO4:P (P<0.001) but with non-
significant effect on Na, K, Ca and K:Na, K:Ca and 
Ca:Na ratios (Table 2). Similarly, the addition of K 
significantly affected concentrations of leaf K 
(P<0.05), Na, SO4, Ca (P<0.01) and K:Ca, K:Na 
(P<0.01), SO4:P (P<0.001) and Ca:P ratio (P<0.05) 
while the effect was non-significant for P and Mg 
concentrations and Ca:Na ratio. The interaction of P 
and K significantly affected Ca (P<0.05) and Mg 
(P<0.01) concentrations and Ca:P and SO4:P 
(P<0.01) ratios while non-significant on. 

 
 
Table 1. Wheat yield and the summary of ANOVA on the effect of K and P treatments in saline-sodic soils 

P2O5 K2O Grain yield % increase over 
control 

Dry matter yield % increase over 
control 

----------kg ha-1-------- Mg ha-1  Mg ha-1  
0 0 1.77 - 12.4 - 
 75 2.66 50 13.3 7 
 150 3.33 88 15.3 23 

60 0 2.65 50 12.9 4 
 75 3.41 93 14.6 18 
 150 3.45 95 15.6 26 

120 0 3.19 80 15.3 23 
 75 3.72 110 15.9 28 
 150 3.85 118 20.0 61 

Summary Analysis of Variation 
 SOV1 ------------------------F value----------------------  
 P 18.4**  108.0***  
 K 57.2***  17.2***  
 P x K 4.55*  NS  

*, **, ***= Significant at P<0.05, 0.01 and 0.001, respectively and NS= Not significant 
1 Source of Variation 



1870 
Wheat growth...  HUSSAIN, Z. et al. 

Biosci. J., Uberlândia, v. 36, n. 6, p. 1867-1878, Sept./Oct. 2020 
http://dx.doi.org/10.14393/BJ-v36n6a2020-42494 

The chemical composition of wheat leaves 
indicated that P concentration decreased from 35.2 
to 25.6 mmol (+) kg-1 with K1 and K2, respectively 
at P0, but increased to 59.3 59.3 mmol P kg-1at P2 
when compared with P0 (Table 2). The correlation 
of K concentrations [K] in leaves was positive with 
soil [K], showing increased bioavailability. The 
[Na] in leaves reduced to 83.4, and 85.3 mmol (+) 
kg-1 at K2 compared with 90.8 and 105.3 mmol (+) 
kg-1 Na at P00 and P2 at K0. These results suggested 
that P enhanced Na concentrations without K, while 
K1 and K2 at lowered [Na] in leaves at all P levels 
(Table 2). The K:Na ratios in leaves showed a 
positive correlation (R2=0.655) with leaf [K], while 
negative correlation (R2=0.90) with leaf [Na] (Fig. 
1). A higher correlation (R2=0.851) of wheat dry 
matter yield was noted with leaf K:Na ratio as 
compared to wheat grain yield (R2=0.392) (Fig. 2). 

The addition of diammonium phosphate 
might have suppressed the K uptake and K:Na ratios 
in leaves possibly due to the suppressing effect of 
NH4 on K (Table 2). However, the leaf P was more 
positively correlated with wheat gain yield 
(R2=0.53) than dry matter yield (R2=0.46) (Fig. 3). 

The [SO4] in leaves increased with the 
application of K2SO4but P addition tended to 
suppress SO4. The highest SO4 concentration of 
493.8 mmol (-) kg-1was found at K2P0 (Table 4). 
That is why a negative correlation (R2=0.57) was 
found between SO4:P and the leaf P concentration 
(Fig. 4). On the other hand, SO4:P ratios in the 
leaves were increased with K2SO4application. Table 

5 represents the analysis of variance (ANOVA) 
showing the influence of P and K on the chemical 
properties of wheat leaves. The [Mg] was not 
affected but the [Ca] and the Ca:P ratios increased at 
K2P04 but decreased at higher P levels (P2) in wheat 
leaves. 
 
Chemical composition of the pre- and post-
harvest soil 

Prior to the sowing of seed and the 
applications of the treatments, the individual soil 
samples were taken randomly from the whole 
experimental field at the depth of 0-30 cm and were 
thoroughly mixed to produce composite soil 
samples and were analyzed for the chemical 
properties (Table 3). Based on high values of pH 
(>8), EC (>4 dS m-1), and SAR (>13), the soils were 
categorized as saline-sodic. The [K] and [P] were 
found lower than the normal levels (<2 mmol K L-1 
and <7 mg P kg-1), while Ca and Mg were found in 
moderate quantities. The high Na concentrations 
produced high SAR values of soil. 

The composite soil samples were taken from 
each experimental plot after the harvesting of the 
crop and were analyzed for ionic concentrations 
(Table 4). The soil pH was highest in control plots 
as compared to plots treated with P2 and K2, while 
ECe remained unchanged in all plots. The P 
treatments significantly (P<0.001) enhanced AB-
DTPA extractable [P] but remained non-significant 
with K treatments (Table 5). 

 
Table 2. Ionic concentrations and ratios in wheat leaf tissue after P and K applications in saline-sodic soils 
 
P2O5 K2O P Na K Ca Mg SO4 K:Na K:Ca Ca:P SO4:P 
----kg ha-1----- -----------------------mmol (±) kg-1----------------------     
0 0 35.2  93.1   832.7  726.7  536.7  292.7  9.04  1.15  21.0  8.56  
 75 33.2  79.0  834.3  736.7  496.7  466.7  10.6  1.14  22.2  14.0  
 150 25.6  77.3  890.3  780.0  536.7  493.8  11.7  1.16  30.5  19.3  
60 0 33.6  90.8  787.7  1030.0  633.3  287.9  8.73  0.78  30.7  8.68  
 75 35.0   88.0  789.0  705.0  600.0  331.7  9.10  1.13  20.4  9.51  
 150 32.3  83.4  843.0  733.3  666.7  337.9  10.2  1.16  22.9  10.5  
120 0 56.9  105.3  704.7  936.7  480.0  352.4  6.76  0.75  16.6  6.29  
 75 51.4 104.4  741.0  740.0  876.7  354.1  7.12  1.01  14.3  6.90  
 150 59.3  85.3  847.3  666.7  750.0  438.6  10.1  1.28  11.5  7.56  
Summary Analysis of Variance (ANOVA) 
 SOV1 --------------------------------------------------------F-ratio-------------------------------------------------

------------- 
 P 63.4*** 2.5 NS 4.7 NS 1.0 NS 19.8** 13.0* 3.2 NS 2.4 NS 38.8** 37.5*** 
 K 1.1NS 8.0** 6.0* 10.1** 3.5 NS 7.0** 12.1** 8.8** 4.0* 15.9*** 
 P x K 2.8 NS 0.9 NS 0.6 NS 3.6* 6.1* 2.2 NS 0.6 NS 2.6 NS 9.0*** 7.0** 
*, **, ***= Significant at P<0.05, 0.01 and 0.001, respectively and NS= Not significant 
1 Source of Variation 
 



1871 
Wheat growth...  HUSSAIN, Z. et al. 

Biosci. J., Uberlândia, v. 36, n. 6, p. 1867-1878, Sept./Oct. 2020 
http://dx.doi.org/10.14393/BJ-v36n6a2020-42494 

Table 3. Chemical composition of saline-sodic soil before cultivation 
Soil Properties Units Range Mean ± SD 
pH - 8.2 – 8.8 8.6 ± 0.2 
ECe dS m

-1 4.2 – 9.4 5.5 ± 1.5 
P mg kg-1 5.9 –11.2 7.7 ± 1.5 
Na mmol (+) L-1 32.6 – 64.1 39.4 ± 9.8 
K mmol (+) L-1 0.2 – 0.6 0.3 ± 0.1 
Ca + Mg mmol (+) L-1 14.0 – 35.7 20.6 ± 6.7 
Cl mmol (-) L-1 23.6 – 58.5 31.3 ± 10.7 
SO4 mmol (+) L

-1 3.2 – 6.2 4.2 ± 1.1 
SAR - 10.4 – 15.2 12.4 ± 1.4 
CaCO3 % 15.3 – 19.4 17.5 ± 1.2 

The addition of P increased AB-DTPA 
extractable P and also the ratios of Ca:P, Cl:P and 
SO4:P, while the soil pH, concentrations of Na, K, 
Ca, SO4, SAR and ratios of Na:K, Na:Ca, and Ca:K 
were influenced by K. The interaction of P x K non-
significantly affected all parameters with the 
exception of Cl:P and SO4:P ratios (Table 5).  

The [K] remained inconsistent at P1 and P2 
alone, when averaged across (n=9) P levels but 
increased with combined P and K treatments (Table 
4).The [K] in soil enhanced from 0.41 to 0.57 at P0, 
0.36 to 0.56 at P1, and 0.42 to 0.65 mmol (+) L-1 at 
P2 with K2, respectively. It demonstrated that P 
addition did not affect soil [K] but with the addition 
of K treatments. The [Na] was found relatively 
higher at P0K0, P2K0, and P0K2, but decreased 
significantly (P<0.05) at P1K1 and P2K2 as 
compared to control (Table 4 and 5). Similarly, 
Na:K ratios were significantly (P<0.001) decreased 
from 87.8 to 43.7 at higher P and K, as compared 
with control (Table 4). A negative correlation 
(R2=0.637) was found between soil Na:K ratios and 
soil [K] (Fig. 5).  

The sodium adsorption ratio (SAR) was 
significantly (P<0.001) influenced by K application 
(Table 4) and hence a negative correlation 
(R2=0.631) was observed between SAR values and 
soil [K] in saturation extract (Fig. 5). The elevated 
[Ca] at P0K2 seemed to have decreased Na 
concentrations as well as the SAR to 9.6 as 
compared to control. The SAR values showed a 
decreasing tendency to 8.80 and 10.6 and to 9.42 
and 8.15 with P levels at K1 and K2 respectively, 
P1K2 and P2K2 as compared to control SAR values 
(12.0). Such trends indicated that P treatments at 
higher K levels substantially decreased SAR of the 
soil. 

The concentrations of Ca were not 
influenced by P, but the ratio of Ca:P in soil were 
significantly (P<0.001) reduced (Table 5). Similarly, 
SO4:P also decreased significantly (P<0.001), but P 

treatments did not influence the concentrations of 
Cl, CO3, and HCO3 (Table 5). A negative correlation 
(R2=0.89) was observed between soil SO4:P and the 
P treatments (Fig. 6). Similarly, there was a negative 
correlation (R2=0.73) between Cl:P and AB-DTPA 
extractable soil P (Fig. 6). 
 

  



1872 
Wheat growth...  HUSSAIN, Z. et al. 

Biosci. J., Uberlândia, v. 36, n. 6, p. 1867-1878, Sept./Oct. 2020 
http://dx.doi.org/10.14393/BJ-v36n6a2020-42494 

Table 4. Chemical composition of saturated extracts of post-harvest (wheat) silty clay loams saline-sodic soils after P and K application 
P2O5 K2O pH ECe  P SAR Na K Ca Mg Cl  SO4 CO3 HCO3 Na:K Na:Ca Ca:K Ca:P Cl:P Cl:SO4 SO4:P 
----kg ha-1-
- 

 dS 
m-1 

mg kg 
-1 

 ----------------------------mmol (±) L-1--------------------------        

0 0 8.6  5.4  4.6  12.0  36.5  0.4 10.0  8.4  42.0  7.3  1.5 2.6  87.8  3.66  24.1  69.1  284.4  5.6  50.4  
 75 8.6 5.2 6.1 10.2  29.6  0.5  9.83  7.2  31.4  7.9  1.4  2.9  57.9  3.11  18.8  49.7  164.0  4.0  40.4  
 150 8.4  5.8 6.2 9.6 32.3  0.6  12.2  11.0  50.2  9.1  1.6  3.2  57.2 2.71 21.3  60.4  247.9  5.4  45.3  
60 0 8.6  5.0  8.3  12.1  31.8  0.3  8.8  5.2 41.9  7.6  2.0  2.8  89.5  3.62 24.7  32.8  154.1  5.5  28.4  
 75 8.4  4.5  6.0  8.8  26.0  0.4  9.0  8.6  34.9  8.2  1.4  3.0  71.2  2.96  24.5  48.1  193.0  4.4  43.9  
 150 8.4 5.1  7.5 9.4  29.5  0.6  11.2  8.5  41.4  8.4  1.5  2.7  53.5  2.71  19.9  47.3  172.5  4.8  35.8  
120 0 8.6  5.4  9.6 11.5  35.2  0.4  10.9  7.8  37.1  8.0  1.7  3.3  84.6  3.27  26.1  35.2  121.7  4.5 26.1  
 75 8.4  5.8  9.4 10.6  34.1  0.6 10.7  9.8  46.8  9.3  1.8  2.8  58.9  3.18  18.6  35.5  155.4  4.9 31.0  
 150 8.2  5.5  11.7  8.1 28.3  0.7  15.1  9.9  34.7  9.4  1.4  3.1  43.7  2.00  23.0  40.2  92.1 3.6 25.1  
 
 
Table 5. Summary analysis of variance (ANOVA) on the effect of P and K on the ionic concentrations and ratios of saturation extracts of silty clay loam saline-sodic 

soils 
 Variables Analyzed 
SOV pH AB-DTPA P Na K Ca SO4 SAR Na:K Na:Ca Ca:K Ca:P Cl:P SO4:P 
 --------------------------------------------------------------------------------------------F-ratio----------------------------------------------------------------------------------------

--------------- 
P 0.32NS 92.4*** 5.02NS 3.85 NS 1.38 NS 1.09 NS 0.57 NS 3.47 NS 0.81 NS 0.52 NS 12.7* 10.9** 134.3*** 
K 7.12* 2.17NS 7.43** 26.2*** 4.62*  5.90* 33.2*** 38.6*** 12.8** 4.14* 0.49 NS 0.28 NS 0.81 NS 
P x K 0.61NS 2.51 NS 2.58 NS 1.45 NS 0.20 NS 0.33 NS 2.83 NS 1.01 NS 0.80 NS 1.60 NS 2.13 NS 3.03* 4.04* 
*, **, ***= Significant at P<0.05, 0.01 and 0.001, respectively and NS= Not significant 



1873 
Wheat growth...  HUSSAIN, Z. et al. 

Biosci. J., Uberlândia, v. 36, n. 6, p. 1867-1878, Sept./Oct. 2020 
http://dx.doi.org/10.14393/BJ-v36n6a2020-42494 

 

 
 

Figure 1. Leaf K:Na ratio in relation to leaf [K] (a) and leaf [Na] in relation to leaf K:Na ratio (b) in saline-
sodic soil 

 

 
 

Figure 2. Grain and dry matter yield of wheat in relation to K:Na ratio in leaf tissue of wheat grown in K2SO4 
treated (n=9) saline-sodic soil 

 

 
Figure 3. Grain and dry matter yield in relation to P concentrations in leaf tissue of wheat grown on P2O5 

treated (n=9) saline-sodic soils 
  



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Figure 4. Leaf SO4:P ratios in relation to [P] leaf tissue of wheat grown on P2O5 treated (n=9) saline-sodic soil 

 

Figure 5. Soil Na:K ratio and SAR in relation to [K] in saturated extracts in K2O treated (n=9) saline-sodic soil 

 

Figure 6. Soil SO4:P (a) and Cl:P ratios (b) in relation to AB-DTPA ext. soil P in P2O5 treated (n=9) saline-



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DISCUSSION 
 
Wheat growth as influenced by P and K 
application 

The findings of this study indicate a 
potential contribution of P and K to crop nutrition 
and growth. The salinity and sodicity are 
responsible to disturb the nutrient balance of the 
crops, resulting in stunted growth and poor yields. 
The deficiency of P and K nutrition and/or the 
competition of these nutrients with other ions 
restricts their uptake by plants under salt-affected 
soil conditions. The optimization of P and K 
fertilization can improve plant metabolism to 
tolerate salt stress resulting in higher yields of crops. 
In the present study, the grain yield of wheat 
increases consistently with increasing P and K 
levels in salt-affected soils. The combined P and K 
applications resulted in the highest grain and dry 
matter yields when compared with control. 
Phosphorus had a greater effect on grain yield as 
compared to the effect of K in saline-sodic soil. 
SINGH et al. (2006) confirmed the positive 
response of wheat to supplementary P in the 
presence of Na which resulted in higher grain yield 
at higher salt concentrations.  

Relatively lower wheat yields at control 
treatments are caused by the effect of Na-salts, 
while increases in yield are associated with high K 
uptake by wheat (MEHDI et al., 2007). 
KRISHNASAMY et al. (2014) examined four 
wheat cultivars under varying K and Na levels and 
reported that high Na concentration reduced wheat 
growth of all cultivars at low K, but adequate K 
maintained a higher number of tillers in most 
cultivars.  
 
Nutrient uptake and wheat yield 

Analysis of leaf tissues is important to 
monitor nutrient deficiencies and uptake under 
applied treatments, in saline-sodic soil conditions. 
The application of P and K treatments influenced 
the chemical composition of the leaf. Plants P 
concentrations [P] were increased with P 
application. Similar results were reported by NIAZI 
et al. (1990). Also, the leaf K concentrations were 
significantly increased with the application of 
K2SO4 which helped to alleviate crop stress. There 
was a positive correlation between leaf K and soil K 
concentrations. The addition of K reduced leaf [Na] 
while increasing trend in [Na] was observed when P 
was applied alone. The depressing effect of K 
fertilizer on leaf [Na] in wheat, sugar beet, and 
maize crops is reported by HUSSAIN et al. (2015). 

A positive correlation K:Na and leaf [K] 
and with the DM yield of wheat suggested a 
depressed Na uptake which promoted the yield of 
wheat in the present study. If the whole plant parts 
are compared, the leaves and stem contain much 
higher concentrations of K than roots or grains 
(NABIPOUR et al., 2007). Uptake and 
accumulation of K by plant roots are strongly 
inhibited by high Na concentrations (NETONDO et 
al., 2004). The K supply enhanced [K] and K:Na in 
leaves and shoot of all wheat cultivars, and high net 
photosynthesis rate in fully expanded leaves of 
wheat than at low K levels (KIRSHNASAMY et al., 
2014). 

A distinct relationship between wheat grain 
yield and the [P] in leaves was observed. The SO4 
uptake was depressed by P application but K 
treatments as K2SO4 enhanced concentrations of 
SO4 ratios in leaf tissue. The Ca uptake was 
enhanced with K at P0 but inhibited at P1 and P2. 
There was no difference in Ca:P at P0K0 and K1, 
but increased at K2, substantially with increasing P 
levels. A complex interaction process may be 
involved among Ca, K, SO4, and PO4 in the soil 
which affected uptake and inhibition of ions by 
plants. Application of K2SO4 enhanced Ca 
concentrations without P, which might have favored 
the development of soluble complexes of CaSO4

 in 
saline soils supporting Ca uptake by plants 
(SPOSITO, 1989). Results suggest that interactions 
of applied P and K fertilizers with Na, Ca, Cl and 
SO4 mitigate the influence of salts and promote crop 
growth in saline-sodic soils. 
 
Influence on soil chemical composition 

Phosphorus is rendered insoluble and 
immobilized in a saline soil solution because of the 
effect of high ionic strength (NISTE et al., 2014). In 
our study, the application of P had a significant 
effect on soil [P] as well as Ca:P, Cl:P, and SO4:P 
ratios. Application of K had a significant influence 
on pH, and concentrations of Na, K, Ca, SO4, SAR 
values and ratios of Na:K, Na:Ca, and Ca:K. 
Concentrations of K in soil remained unchanged 
with the addition of P alone but increased at K1 and 
K2. The soil P availability increased with P 
application which supported wheat yield, but it 
depressed other macronutrients like K and N, as 
reported in various studies (HAO et al., 2005). The 
P and K reduced Na:K ratios when compared with 
control. A negative correlation (R2=0.63) was found 
between soil [K] and soil Na:K ratios. Adding 
higher levels of K and P significantly lowered Na:K 
ratios as compared to control. The salt-tolerant crops 
tend to retain high [K] while excluding Na from the 



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shoots (FLOWERS; HAJIBAGHERI, 2001). 
Moderate native [K] sometimes even becomes 
unavailable to plants because of high competition 
with Na in soils. Therefore, K application to such 
soil may enhance its selectivity and bioavailability 
for the plants. Application of K to a highly saline 
soil promoted dry matter yield of barley, supported 
high accumulation of K and maintained lower Na:K 
ratio which also suggested positive role of K in 
mitigating salt stress (ENDRIS; MOHAMMAD, 
2007). 

The K treatment also promoted higher Ca 
concentrations in soil and reduced Na when 
compared with control. Similarly, the SAR values 
were decreased with P at higher K treatments. The 
application of K as K2SO4 increased SO4 in soil but 
the application of P lowered SO4:P ratios in soil. A 
negative correlation (R2 = 0.898) was found between 
soil SO4:P ratios and the P treatment. NISTE et al. 
(2014) reported that Cl inhibits more N than SO4, 
therefore the application of S as K2SO4 to salt-
affected soils improves concentrations of N, P, and 
K which supports higher wheat yield. Application of 
gypsum in combination with K fertilizers to saline-
sodic soils irrigated with saline water amended soil 
chemical properties and facilitated wheat growth. 
The correlation between soil Cl:P ratios and soil P 
was found negative (R2=0.73). The Cl toxicity of 
salt-affected soils was minimized with P treatment. 

 

CONCLUSIONS 
 

The study demonstrates that the addition of 
P and K fertilizers enhanced both grain and dry 
matter yields of wheat. Effect of P treatment on 
grain yield was more profound than K application 
but dry matter yield increased more with K when 
compared with control. Whereas the combined 
effect of high P and K dozes (120 kg P2O5 ha

-1 and 
150 kg K2O ha

-1) was more pronounced in grain 
yield showing 118% increases when compared with 
P or K alone. The P and K improved leaf K, P, Ca, 
and SO4 concentrations, increased K:Na and SO4:P 
ratios while reducing Na and Cl concentrations 
when compared with control values. The dry matter 
yield correlated more positively with K: Na ratios in 
leaf. The applied K amended soil K, Ca, SO4 
concentrations, and reduced Na levels, SAR, and 
Na:K in saline-sodic soils, while P application 
improved soil P while decreasing the Cl levels in the 
soil. This study suggested that applications of K and 
P fertilizers bring positive changes in soil-plant-
nutrients dynamics and hence plant yield in a saline 
environment. 
 
ACKNOWLEDGEMENT 
 

This study was partially funded by the Joint 
Research Program of Arid Land Research Center, 
Tottori University, Japan (Grant No. 29GR1001). 

 
 

RESUMO: A deficiência de nutrientes é um fator limitante em solos salino-sódicos, resultando em 
baixa produção agrícola. O estudo investigou a resposta do trigo ao P e K adicionados ao solo. O K foi aplicado 
em 0 (K0), 75 (K1), 150 (K2) kg K2O ha

-1 como K2S04 e em (0 (P0), 60 (P1), 120 (P2) kg P2O5 ha
-1 como 

(NH4)2HPO4 em três repetições sob delineamento de blocos completos casualizados (RCB) de dois fatores. 
Ambos os tratamentos aumentaram significativamente o rendimento de grãos de trigo (118%) e de matéria seca 
(60%) em P2K2 em comparação com o controle. Os tratamentos com P afetaram significativamente o P foliar, 
Mg, SO4, as razões Ca:P, SO4:P e o P do solo, e as razões Ca:P, Cl:P e SO4:P, enquanto K no K foliar, Na, Ca, 
concentração de SO4, razões K:Na, K:Ca, SO4:P, Ca:P e pH do solo, Na, K, Ca, concentrações de SO4, SAR, 
razões Na:K, Ca:K e Na:Ca. O Na da folha foi reduzido para 85,3 mmol (+) kg-1 em K2 em comparação com 
105,3 mmol (+) kg-1 em P2K0. Correlação negativa (R2 = 0,906) do K:Na na folha foi encontrada com a 
concentração de Na na folha. A correlação da matéria seca foi maior (R2 = 0,851) com a relação K:Na da folha 
do que rendimento de grãos (R2 = 0,392). Conclui-se que a adição de K e P apresenta efeitos benéficos na 
melhoria da nutrição da cultura e na produtividade do trigo em solo salino-sódico. 

 
PALAVRAS-CHAVE: Crescimento do trigo. P. K. Região semiárida. Região árida. Solo salino-

sódico. 
 
 
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