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Seed Priming with Thiourea Enhances the Performance of Sesame (Sesamum indicum L.) Varieties Under Salinity Stress

SJA_40_3_740-753

Research Article

Seed Priming with Thiourea Enhances the Performance of Sesame (Sesamum indicum L.) Varieties Under Salinity Stress

Bushra Irfan1, Muhammad Shahbaz1*, Asif Mukhtiar1, Muhammad Zubair Akram2, Muhammad Atif Bashir3, Sabina Asghar4, Abdul Ghaffar5 and Samreen Nazeer6*

1Department of Botany, University of Agriculture Faisalabad, Pakistan; 2School of Agricultural, Forest, Food and Environmental Sciences, University of Basilicata, Potenza, 85100, Italy; 3Department of Agronomy, University of Agriculture Faisalabad, Pakistan; 4Oil Seed Research Institute, Ayub Agricultural Research Institute, Faisalabad, Pakistan; 5Arid Zone Research Institute, Bhakkar, Punjab, Pakistan; 6Department of Food and Drug Sciences, University of Parma, Parma, 43121, Italy.

Abstract | Salinity is most significant abiotic factor limiting sesame growth, physio-chemical mechanisms and productivity. To address this issue a pot trial was conducted to check the effectiveness of hydropriming (water; control), thiourea (150 mM) seed priming under normal (10.8 mM) and saline conditions (70 mM). The seeds of two varieties (TS-05 and TH-06) was sown at Botany Garden, University of Agriculture, Faisalabad. Results showed that salinity decreases the growth (root and shoot parameters) impaired the balance between antioxidants (superoxide dismutase, catalase, peroxidase) and oxidants (hydrogen peroxide and malondialdehyde), and lessened the uptake of essential minerals (potassium and calcium) irrespective of varietal differences. However, the performance of TH-6 was better than TS-5. In addition, the seed priming of thiourea enhanced the sesame photosynthetic pigments and efficiency, secondary metabolites production, antioxidant machinery, and nutrient uptake in both varieties which increased growth and development as a result. So, thiourea seed priming is an effective strategy to counteract the negative effects of salt stress by improving tolerance mechanisms.


Received | April 17, 2024; Accepted | May 30, 2024; Published | July 10, 2024

*Correspondence | Muhammad Shahbaz and Samreen Nazeer, Department of Botany, University of Agriculture Faisalabad, Pakistan; Department of Food and Drug Sciences, University of Parma, Parma, 43121, Italy; Email: shahbazmuaf@uaf.edu.pk, samreen.nazeer@unipr.it

Citation | Irfan, B., M. Shahbaz, A. Mukhtiar, M.Z. Akram, M.A. Bashir, S. Asghar, A. Ghaffar and S. Nazeer. 2024. Seed priming with thiourea enhances the performance of sesame (Sesamum indicum L.) varieties under salinity stress. Sarhad Journal of Agriculture, 40(3): 740-753.

DOI | https://dx.doi.org/10.17582/journal.sja/2024/40.3.740.753

Keywords | Thiourea, Seed priming, Varieties, Photosynthetic pigments, Antioxidants, Oxidants

Copyright: 2024 by the authors. Licensee ResearchersLinks Ltd, England, UK.

This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).



Introduction

Sesame (Sesamum indicum L.) belonging to the Pedaliaceae family possesses the title queen of oilseeds owing to its superior oil quality along with beneficial compounds like sterols, sesamin, sesamolin, and tocopherols, which serve as nutraceuticals contributing to various physiological and nutritional advantages (Langyan et al., 2022). The growth of sesame plants is sustained by tropical, subtropical, and southern temperate regions. Leading sesame-exporting countries include China, Myanmar, India, and Sudan (Chen et al., 2020). Sesame can replace animal proteins and fats used in human food because it contains a plenty of fats and plant proteins (Rahman et al., 2020) and seeds of sesame are rich in oil contents ranging from 45% to 63% (Biswas et al., 2018). Additionally, it is a valuable source of minerals, fibers, and vitamins (Zebib et al., 2015). Furthermore, sesame possesses antioxidant properties which render it a desirable ingredient in pharmaceutical formulations (Wan et al., 2023).

Besides its significance, various climatic factors impact the productivity of sesame. Sesame cultivation is challenged by the occurrence of multiple abiotic stresses consequently leading to a reduction in yield (Wang et al., 2021). Several abiotic stresses such as drought, waterlogging, salt, and heat have an impact on sesame efficiency, yield, and seed quality (Dossa et al., 2019). The most significant abiotic factor limiting sesame growth and productivity is salinity. Salt stress influences emergence, growth and yield potential (Kanagaraj and Sathish, 2017). Salt stress has three major effects on plant growth including reduced soil water potential known as osmotic stress, ionic imbalance in cells and ion toxicity (Franzisky et al., 2023; Hualpa-Ramirez et al., 2024). Salinity affects a variety of physiological processes including transpiration, stomatal conductance, photosynthesis, water potential and ultimately declines the growth and yield production (Desingh and Kanagaraj, 2019; Taratima et al., 2023; Victoria et al., 2023). During salt stress conditions, the substantial amount of salt in the leaf reduces water potential. The presence of an elevated level of salts in the leaf caused the stomata to close which reduced transpiration and CO2 resulting in decreased photosynthesis (Rangani et al., 2016). Salt stress inhibits photosynthesis by triggering closure of stomata and averting the diffusion of CO2 (Zahra et al., 2022a). Saline stress may also influence non-stomatal properties like chlorophyll synthesis, photosystem structure, and electron transport (Pan et al., 2021).

To mitigate the negative effects of salinity in sesame various strategies were used including seed priming (Tariq and Shahbaz, 2020), plant growth-promoting rhizobacteria (Khademian et al., 2019), and effective use of nitrogen fertilizers (Waqas et al., 2023) and other fertilizers application (Mahdavi-Khorami et al., 2020; Dollison and Dollison, 2023). Thiourea (TU) which is a sulfur and nitrogen-containing compound, is an important plant growth regulator that influences plant growth, particularly under stressed conditions (Hafeez et al., 2024). Thiourea can reduce oxidative stress-induced growth impairment by increasing the activity of antioxidant enzymes involved in ROS scavenging and modulating calcium signaling, redox state, and hormonal homeostasis (Ahmad et al., 2022a). Farooq et al. (2023), reported that the application of foliar thiourea increased the activity of peroxidase (POD) and potassium (K) levels in roots under salt stress conditions. Additionally, it led to elevated levels of chlorophyll b, total chlorophyll, and carotenoids. Overall, it can be concluded that foliar application of thiourea mitigated the negative effects of salinity by enhancing potassium ion content and antioxidant activity including peroxidase. Similarly, in another study Jhanji and Dhingra (2020) the germination characteristics of unsoaked seeds, hydroprimed seeds, and thiourea-primed seeds (at 750 ppm concentration) were examined under varying conditions of water and NaCl (30 and 50 mM). However, foliar application of thiourea on sesame have been reported by Dhillon et al. (2023) under salinity, and Sonia et al. (2024) under drought. However, there is no study present on seed priming with thiourea to mitigate the adverse effects of salinity in sesame. Hypothetically, thiourea seed priming may enhance growth, physio-chemical processes under salinity stress. Therefore, the present study was proposed to assess the impact of thiourea seed priming to mitigate the salt stress effect in sesame.

Materials and Methods

Experimental detail

The pot experiment was conducted at Botany Garden, University of Agriculture, Faisalabad and the experimental design was used complete randomized design (CRD) with 3 way factorial arrangements to check the effectiveness of thiourea (150 mM) seed priming under normal (10.8 mM) and saline conditions (70 mM). The seeds of these two varieties (TS-05 and TH-06) obtained from Oil Seed Research Institute, Faisalabad) were soaked in the 150 mM solution of thiourea for 16 hours. Then, seeds of varieties were sown in soil (autoclave at 121°C for 120 minutes) with ten seeds in each pot. The size of each pot having the dimensions 14 inch width and 16 inch depth were filled with 10 kg of soil. After seed germination five plants per pot were maintained. Salinity stress was imposed after one week of germination in each pot, the salt stress (0 and 70 mM) was imposed after germination of seeds in increments of 35 mM initially and then was attained to the 70 mM and sodium chloride (NaCl) was used for salinity imposition and the harvesting was done after one month of sowing date for growth and biochemical analysis. The growth parameters including root length, shoot length, root and shoot fresh weight were determined.

Nutrient content

Root and shoot samples were digested following the procedure described by Wolf (1982). Initially, 0.1 g of dry root and shoot sample was placed in a digestion flask containing 2 mL of concentrated hydrogen sulfate and allowed to stand overnight. The subsequent day, the sample underwent heating on a hot plate at 50°C for an hour. After removing the hydrogen peroxide (2 mL) was mixed in the sample, followed by continued heating until the sample became colorless. To make a volume of 50 mL, distilled water was added. The resulting solution was then filtered, and the filtered sample was utilized to determine the concentrations of K+, Na+, and Ca2+ using a flame photometer.

Photosynthetic pigments

The method of Arnon (1949) and Takaichi et al. (1995) was used to measure photosynthetic pigments. Fresh leaf (0.1g) was mixed in 80% acetone having a volume of 5 milliliters. The absorbance was observed with the help of ultraviolet-visible spectrophotometer at a wavelength of 645, 480, and 663 nm.

Antioxidants

A pre-chilled mortar and pestle was utilized to grind fresh leaves (0.5 g) in buffer solution (10 mL) having pH 7.8. After homogenization, the liquid was centrifuged for 20 minutes at 12,000 rpm. The supernatant with enzymatic antioxidants was collected and stored at -20°C for subsequent analysis of peroxidase, catalase, and superoxide dismutase activity based on protein content. The catalase activity was determined using the method ascribed by Chance and Maehly (1955). The peroxidase estimation was conducted following the Chance and Maehly (1955) method. The activity of superoxide dismutase was determined using the technique described by Giannopolitis and Ries (1977).

Reactive oxygen species

The H2O2 was assessed using the protocol described by Velikova et al. (2000). The malondialdehyde content was assessed using the method followed by Heath and Packer (1968).

Secondary metabolites

Total phenolic were calculated following the technique used by Julkunen-Tiitto (1985). The total alkaloid content was determined using the method outlined by Singh and Sahu (2006). The flavonoid content was assessed using the method developed by Zhishen et al. (1999). Riboflavin was extracted using the technique described by Okwu and Josiah (2006).

Gas exchange attributes

Attributes related to gas exchange were assessed with the help of a transferable infrared gas analyzer (LCA – 4 ACD, Hoddesdon, UK). A fully exposed and mature third leaf from each treatment group was randomly chosen for data collection. Measurements were taken between 12:00 and 14:00 hours on the respective day.

Statistical analysis

A complete block design (CRD) under a factorial arrangement with three replications was used. The analysis and evaluation of data were done by using a statistical package (Statistics 8.1). HSD test was used to compare the treatment means.

Results and Discussion

Growth attributes

Data depicted in Table 1 showed that root length (RL), shoot length (SL), root fresh weight (RFW), root dry weight (RDW), shoot fresh weight (SFW), and shoot dry weight (SDW) varied significantly (P≤0.05) in both varieties, salinity stress and seed priming treatments but, interaction between them was non-signifcant (P>0.05) differences. Salinity stress resulted in reduced root length in both varieties but, the seed priming with 150 mM thiourea improved the RL up to 20.06% and 27.13% in TS-5 and TH-6 varieties, respectively. Salinity conditions decreased the SL of both varieties. However, seed priming with thiourea increased the SL 19.26% (TS-5) and 12.63% (TH-6) when compared with their respective controls. Salinity condition decreased the RFW of both varieties, but, the seed priming with 150 mM thiourea increased the RFW up to 49.01% and 28.47% in TS-5 and TH-6 varieties, respectively, when compared with their respective controls. Saline strress decreased the RDW of both varieties however, the seed priming with thiourea increased the RDW up to 98.59%

 

Table 1: Influence of seed priming of thiourea on growth parameters of sesame varieties under saline conditions.

Treatments

RDW

SL

RFW

RL

SDW

SFW

(cm)

(cm)

(cm)

(cm)

(g)

(g)

Salinity treatments (ST)

Normal conditions (NC)

0.79 A

65.32 A

3.94 A

14.43 A

3.96 A

23.65 A

Saline conditions (SC)

0.28 B

46.66 B

2.25 B

10.78 B

2.66 B

16.92 B

Varieties (Vr)

TS-5

0.39 B

51.91 B

2.34 B

11.39 B

3.04 B

17.9 B

TH-6

0.69 A

60.06 A

3.85 A

13.81 A

3.58 A

22.67 A

Seed Priming (SP)

Hyrdo priming (HP)

0.47 B

52.43 B

2.63 B

11.39 B

2.97 B

18.81 B

Thiourea priming (TP)

0.6106 A

59.54 A

3.55 A

13.81 A

3.65 A

21.76 A

ST×Vr

NC×TS-5

0.65 b

58.89 b

3.09 b

14.08 ab

3.69 a

22.13 ab

NC×TH-6

0.93 a

71.75 a

4.7875 a

14.77 a

4.22 a

25.17 a

SC×TS-5

0.13 d

44.95 c

1.57 c

9.71 c

2.38 b

13.75 c

SC×TH-6

0.44 c

48.37 c

2.91 b

11.84 bc

2.94 b

20.16 b

ST×SP

NC×HP

0.70 a

61.63 a

3.38 b

13.16 b

3.54 b

21.87 a

NC× TP

0.88c

69.01 a

4.50 a

15.69 a

4.36 a

25.43 a

SC×HP

0.2369 b

43.25 b

1.88 d

9.63 c

2.39 c

15.75 b

SC×TP

0.33 b

50.07 b

2.61 c

11.92 bc

2.94 bc

18.08 b

Vr×SP

TS-5×TP

0.48 bc

55.96 ab

2.76 b

12.89 ab

3.37 ab

18.93 bc

TH-6× HP

0.63 ab

57.00 a

3.36 b

11.89 b

3.23 ab

20.75 b

TS-5×HP

0.31 c

47.87 c

1.91 c

10.89 b

2.70 b

16.87 c

TH-6×TP

0.74 a

63.13 a

4.34 a

14.73 a

3.93 a

24.59 a

ST×Vr×SP

NC×TS-5×HP

0.52 ns

54.7 ns

2.55 ns

12.97 ns

3.28 ns

21.14 ns

NC×TS-5×TP

0.78 ns

63.0 ns

3.64 ns

15.19 ns

4.11 ns

23.13 ns

SC×TS-5×HP

0.08 ns

41.0 ns

1.26 ns

8.82 ns

2.12 ns

12.61 ns

SC×TS-5×TP

0.17 ns

48.9 ns

1.88 ns

10.59 ns

2.64 ns

14.72 ns

NC×TH-6×HP

0.87 ns

68.5 ns

4.21 ns

13.35 ns

3.81 ns

22.61 ns

NC×TH-6×TP

0.99 ns

75.0 ns

5.36 ns

16.2 ns

4.63 ns

27.74 ns

SC×TH-6×HP

0.38 ns

45.5 ns

2.50 ns

10.43 ns

2.65 ns

18.88 ns

SC×TH-6×TP

0.48 ns

51.2 ns

3.33 ns

13.26 ns

3.24 ns

21.44 ns

Significance

ST

0.000**

0.000**

0.000**

0.000**

0.000**

0.000**

SP

0.025*

0.002**

0.000**

0.001**

0.001**

0.003**

Vr

0.0000**

0.001**

0.000**

0.032*

0.007**

0.000**

ST× SP

0.411ns

0.89ns

0.276ns

0.854ns

0.468ns

0.506ns

ST× Vr

0.785ns

0.06ns

0.336ns

0.260ns

0.935ns

0.071ns

Vr×SP

0.564ns

0.64ns

0.713ns

0.507ns

0.943ns

0.335ns

ST× SP×Vr

0.469ns

0.96ns

0.835ns

0.863ns

0.913ns

0.467ns

ST, Salinity treatments, NC, normal conditions, SC, saline conditions, Vr, Varieties, SP, Seed Priming, HP, Hyrdo priming, TP, Thiourea priming. * depicted significant (p < 0.05), ns depicted non significant (p > 0.05).

 

and 26.94% in TS-5 and TH-6 varieties, respectively, when compared with their respective controls. Salinity stress resulted in decrease in the SFW of both varieties. But, the seed priming with 150 mM thiourea increased the SFW up to 16.70% and 13.52% in TS-5 and TH-6 varieties, respectively. Salinity decreased the SDW of both varieties, though, the seed priming with 150 mM thiourea improved the SDW up to 24.20% and 21.93% in TS-5 and TH-6 varieties, respectively, when compared with their respective controls.

 

Table 2: Influence of seed priming of thiourea on growth parameters of sesame varieties under saline conditions.

Treatments

Shoot Na+

Root Na+

Root K+

Shoot K+

Root Ca+

Shoot Ca+

(mg/g d.wt.)

(mg/g d.wt.)

(mg/g d.wt.)

(mg/g d.wt.)

(mg/g d.wt.)

(mg/g d.wt.)

Salinity treatments (ST)

Normal conditions (NC)

4.34 B

10.75 B

9.56 A

15.34 A

8.56 A

12.59 A

Saline conditions (SC)

5.65 A

14.71 A

7.13 B

10.719 B

5.7187 B

8.563 B

Varieties (Vr)

TS-5

4.84 A

11.93 B

8.06 A

13.46 A

5.78 B

9.46 B

TH-6

5.15 A

13.53 A

8.62 A

12.59 A

8.5 A

11.688 A

Seed priming (SP)

Hyrdo priming (HP)

5.46 A

13.81 A

7.59 B

11.93 B

6.41 B

9.25 B

Thiourea priming (TP)

4.53 B

11.65 B

9.09 A

14.12 A

7.87 A

11.91 A

ST×Vr

NC×TS-5

4.5 bc

10.87 c

8.37 c

15.5 a

7.43 b

12.18 ab

NC×TH-6

4.18 c

10.62 c

10.75 a

15.18 a

9.68 a

13.0 a

SC×TS-5

5.18 b

13.0 b

7.75 b

11.43 b

4.12 c

6.75 c

SC×TH-6

6.12 a

16.43 a

6.5 b

10.0 b

7.31 b

10.37 b

ST×SP

NC×HP

4.75 b

11.87 b

8.68 ab

14.43 ab

7.43 b

10.37 b

NC× TP

3.94 c

9.62 c

10.43 a

16.25 a

9.68 a

14.81 a

SC×HP

6.18 a

15.75 a

6.50 c

9.43 c

5.37 b

8.12 b

SC×TP

5.12 b

13.68 b

7.75 bc

12.0 bc

6.06 b

9.0 b

Vr×SP

TS-5×HP

5.50 a

13.12 a

6.93 b

12.00 a

5.31 c

8.62 b

TH-6× TP

4.87 ab

12.6 ab

9.0 ab

13.31 a

9.5 a

13.5 a

TS-5×TP

4.18 b

10.75 b

9.18 a

14.93 a

6.25 bc

10.31 b

TH-6×HP

5.43 a

14.5 a

8.25 ab

11.87 a

7.50 ab

9.87 b

ST×Vr×SP

NC×TS-5×HP

5.25 ns

12.3 ns

7.12 ns

14.87 ns

6.87 ns

10.75 ns

NC×TS-5×TP

3.75 ns

9.5 ns

9.62 ns

16.12 ns

8.00 ns

13.62 ns

SC×TS-5×HP

5.75 ns

14.0 ns

6.75 ns

9.12 ns

3.75 ns

6.50 ns

SC×TS-5×TP

4.62 ns

12.0 ns

8.75 ns

13.75 ns

4.5 ns

7.0 ns

NC×TH-6×HP

4.25 ns

11.5 ns

10.25 ns

14.0 ns

8.0 ns

10.0 ns

NC×TH-6×TP

4.12 ns

9.75 ns

11.25 ns

16.37 ns

11.37 ns

16.0 ns

SC×TH-6×HP

6.62 ns

17.5 ns

6.25 ns

9.75 ns

7.0 ns

9.75 ns

SC×TH-6×TP

5.62 ns

15.4 ns

6.75 ns

10.25 ns

7.62 ns

11.0 ns

Significance

ST

0.000**

0.000**

0.000**

0.000**

0.000**

0.000**

SP

0.000**

0.000**

0.009**

0.021*

0.021*

0.000**

Vr

0.02*

0.005**

0.298ns

0.313ns

0.000**

0.001**

ST× SP

0.526ns

0.85ns

0.641ns

0.662ns

0.170ns

0.09ns

ST× Vr

0.07ns

0.06ns

0.07ns

0.514ns

0.405ns

0.04ns

Vr×SP

0.065ns

0.68ns

0.169ns

0.386ns

0.346ns

0.139ns

ST× SP×Vr

0.121ns

0.59ns

1.000ns

0.135ns

0.294ns

0.358ns

ST, Salinity treatments, NC, normal conditions, SC, saline conditions, Vr, Varieties, SP, Seed Priming, HP, Hyrdo priming, TP, Thiourea priming.

 

Ions

The shoot and root Na+, K+ and Ca2+ content varied significantly (P≤0.05) in both varieties, salinity and seed priming, whereas the interaction between them was found to be non-significant (Table 2). Salinity stress enhanced the shoot Na+ of both varieties however, the seed priming with 150 mM thiourea decreased the shoot Na+ up to 19.56% and 15.09% in TS-5 and TH-6 varieties respectively when compared with their respective controls. Salinity boosted the root Na+ in both varieties. However, the seed priming with 150 mM thiourea reduced the root Na+ up to 14.28% and 12.14% in TS-5 and TH-6 varieties, respectively, when compared with their respective controls. Overall, TH-6 variety performed better when compared with TS-5 variety. Salinity stress decreased the K+ ions in root in both varieties. However, the seed priming with 150 mM thiourea increased the K+ ions in root up to 29.62% and 8% in TS-5 and TH-6 varieties, respectively, when compared with their respective controls. Overall, TH-6 variety performed better when compared with TS-5 variety. Salinity decreased the K+ ions in shoot in TS-5 (38.65%) and in TH-6 (30.35%), moreover, the seed priming with thiourea improved the shoot K+ up to 50.68% and 5.13% in TS-5 and TH-6 varieties, respectively, when compared with their respective controls. Salinity decreased the root Ca2+ in both varieties moreover the seed priming with 150 mM thiourea increased the root Ca2+ 20% (TS-5) and 8.92% (TH-6) when compared with their respective controls. Salinity stress decreased the shoot Ca2+ in both varieties; moreover, the seed priming with 150 mM thiourea increased the shoot Ca2+ by 7.69% (TS-5) and 12.82% (TH-6).

 

Photosynthetic pigments

The chlorophyll a content varied significantly (P≤0.05) in both varieties, salinity stress, and seed priming, although the interaction between them depicted non-significant (P>0.05) differences expect carotenoids (Figure 1; Table 3). Salt stress decreased the chlorophyll a content of both varieties; though, the seed priming with 150 mM thiourea increased the chl a 3.59% (TS-5) and 5.45% (TH-6) when compared with respective controls. Salinity stress reduced the contents of chlorophyll b in both varieties; however, the seed priming with 150 mM thiourea improved the chlorophyll b up to 8.33% and 34.69% in TS-5 and TH-6 varieties, respectively, when compared with their respective controls. Overall, TH-6 variety performed better when compared with TS-5 variety. Salinity stress decreased the carotenoids contents of both varieties, however, the seed priming with 150 mM thiourea increased the carotenoids 8.51% (TS-5) and 21.86% (TH-6) when compared with respective controls.

 

Table 3: Influence of Seed priming of thiourea on photosynthetic pigments of sesame varieties under saline conditions.

Significance

Chl a

Chl b

CAR

(mg/g f.wt.)

(mg/g f.wt.)

(mg/g f.wt.)

ST

0.000**

0.000**

0.000**

SP

0.02*

0.021*

0.004**

Vr

0.000**

0.150ns

0.000**

ST×SP

0.182ns

0.956ns

0.683ns

ST× Vr

0.498ns

0.08ns

0.06ns

Vr×SP

0.821ns

0.306ns

0.424ns

ST× SP×Vr

0.734ns

0.786ns

0.503ns

ST, Salinity treatments, NC, normal conditions, SC, saline conditions, Vr, Varieties, SP, Seed Priming, HP, Hyrdo priming, TP, Thiourea priming.

 

Oxidative stress

Statistical results for malondialdehyde and hydrogen peroxide revealed that salt stress and cultivars and seed priming had significant differences but the interaction among them was non-significant (P>0.05) (Figure 2A; Table 4). Salinity stress increased the MDA of both varieties; however, the thiourea seed priming decreased the MDA up to 20.68% and 14.01% in TS-5 and TH-6, respectively, when compared with their respective controls. Salinity stress increased the hydrogen peroxide of both varieties by 63.51% (TS-5) and 10.45% (TH-6) as compared to controls; however, the seed priming with 150 mM thiourea decreased the hydrogen peroxide up to 25.26% and 23.08 % in TS-5 and TH-6 varieties, respectively.

 

Table 4: Influence of Seed priming of thiourea on photosynthetic pigments of sesame varieties under saline conditions.

Significance

SOD

POD

CAT

H2O2

MDA

(units mg-1 protein)

(units mg-1 protein)

(units mg-1 protein)

(µmolg-1 f.wt.)

(mmolg-1 f.wt.)

ST

0.000**

0.000**

0.000**

0.000**

0.005**

SP

0.000**

0.025*

0.000**

0.000**

0.008**

Vr

0.761ns

0.003**

0.135ns

0.005**

0.012**

ST×SP

0.137ns

0.276ns

0.984ns

0.638ns

0.983ns

ST× Vr

0.062ns

0.929ns

0.921ns

0.063ns

0.264ns

Vr×SP

0.389ns

0.359ns

0.766ns

0.237ns

0.278ns

ST× SP×Vr

0.061ns

0.976ns

0.539ns

0.073ns

0.871ns

ST, Salinity treatments, NC, normal conditions, SC, saline conditions, Vr, Varieties, SP, Seed Priming, HP, Hyrdo priming, TP, Thiourea priming.

 

 

Antioxidants

The SOD, POD, CAT varied significantly (P≤0.05) in salinity stress, seed priming, and varieties while the interaction among them was non-significant (P>0.05) differences (Figure 3A; Table 4). Salinity stress increased the SOD of both varieties. Likewise, the seed priming 150 mM thiourea also increased the SOD up to 7.57% (TS-5) and 38.32% (TH-6) as compared to their respective controls. Salinity stress increased this attribute by 14.41 and 17.15% respectively as compared to control plants. Salinity stress increased the CAT of both varieties. Moreover, the seed priming with 150 mM thiourea also increased the CAT upto 14.14% and 17.51% in TS-5 and TH-6, respectively, as compared to their respective controls.

 

 

Secondary metabolites

Statistical data presenting total phenolics, alkaloids, flavonoids, and riboflavin, salinity stress, seed priming, and varieties displayed significant (P≤0.05) differences, however, the interaction was found to be non-significant (P>0.05) difference (Figure 4A; Table 5). Salt stress increased the total phenolics of both varieties; likewise, the seed priming also increased the total phenolics up to 11.03% and 8.53% in TS-5 and TH-6 varieties, respectively, when compared with their respective controls. Salinity stress increased the alkaloids of both varieties and the seed priming also increased alkaloids up to 10% and 3.28%, in TS-5 and TH-6 varieties, respectively, when compared with their respective controls. Salinity stress increased the flavonoids in both varieties and the seed priming also increased flavonoids upto 4.83% (TS-5) and 5.83% (TH-6), when compared with their respective controls. Salinity stress increased the riboflavin of both varieties and the seed priming with thiourea also increased riboflavin up to 14.81% and 1.45% in TS-5 and TH-6 varieties respectively, when compared with their respective controls.

 

Table 5: Influence of Seed priming of thiourea on secondary metabolites of sesame varieties under saline conditions.

Significance

Total soluble phenolics

Alkaloids

Flavonoids

Riboflavin

(mg g-1 fresh wt.)

(μg/g fwt.)

(μg/g fwt.)

(μg/g fwt.)

ST

0.000**

0.000**

0.000**

0.000**

SP

0.000**

0.003**

0.004**

0.000**

Vr

0.008**

0.0001**

0.029*

0.108ns

ST×SP

0.111ns

0.872ns

0.686ns

0.103ns

ST× Vr

0.17ns

0.827ns

0.064ns

0.085ns

Vr×SP

0.55ns

0.329ns

0.223ns

0.08ns

ST× SP×Vr

0.74ns

0.458ns

0.278ns

0.06ns

ST, Salinity treatments, NC, normal conditions, SC, saline conditions, Vr, Varieties, SP, Seed Priming, HP, Hyrdo priming, TP, Thiourea priming.

 

Gas exchange attributes

The photosynthetic rate, Ci, gs, and Tr varied significantly (P≤0.05) in varieties, salinity stress and seed priming, while the interaction among them was non-significant (P>0.05) differences (Figure 5A; Table 6). Salinity stress decreased the photosynthetic activity upto 41.8% (TS-5) and 51.14% (TH-6) of both varieties. Moreover, the seed priming with 150 mM thiourea also increased the photosynthetic activity upto 47.88% and 48.23% in TS-5 and TH-6, respectively, as compared to their respective controls. Salinity stress increased the Ci of both varieties however, the seed priming with 150 mM thiourea decreased the Ci up to 16.10% and 12.84% in TS-5 and TH-6 varieties, respectively. Salt stress reduced the Stomatal conductivity in both varieties; conversely, the seed priming increased Stomatal conductivity up to 6.10% (TS-5) and 13.73% (TH-6), when compared with their respective controls. Salinity stress decreased the transpiration rate in both varieties but the seed priming with 150 mM thiourea increased transpiration rate up to 54.74% and 34.16%, in TS-5 and TH-6 varieties, respectively, when compared with their respective controls.

 

Table 6: Influence of Seed priming of thiourea on gas exchange parameters of sesame varieties under saline conditions.

Significance

gs

PN

E

Ci

(mmol H2O m-2 g-1)

(µmol m-2 g -1)

(mmol H2O m-2 s-1)

(µmol CO2 mol -1)

ST

0.000**

0.000**

0.000**

0.000**

SP

0.026*

0.000**

0.000**

0.000**

Vr

0.000**

0.011**

0.034*

0.000**

ST×SP

0.366ns

0.349ns

0.09ns

0.08ns

ST× Vr

0.80ns

0.249ns

0.268ns

0.06ns

Vr×SP

0.178ns

0.822ns

0.182ns

0.268ns

ST× SP×Vr

0.582ns

0.591ns

0.919ns

0.869ns

ST, Salinity treatments, NC, normal conditions, SC, saline conditions, Vr, Varieties, SP, Seed Priming, HP, Hyrdo priming, TP, Thiourea priming.

 

Plants response under stress conditions is to employ their potential to advance the defense mechanism instead of productivity (Zhang et al., 2023). Likewise salinity stress also negatively affected the mechanisms in plants and ultimately reduced growth (Dabravolski and Isayenkov, 2023). It also negatively exaggerated the root and shoot lengths, root fresh and dry weight (Table 1), this research was supported by Nikfekr et al. (2023) and Dangue et al. (2022). Similar reduction was observed in various other crops such as maize (Sabagh et al., 2021; Ali et al., 2023), wheat (Hmissi et al., 2023), sorghum (Kaur et al., 2023) and coriander (Vojodi-Mehrabani and Kheirollahi, 2023; Sánchez-Navarro et al., 2024). Thiourea could effectively alleviate the adverse effects of salt stress and toxicities (Yadav et al., 2023), for example, thiourea application increased the growth and physiological attributes of mustard (Saleem et al., 2024), enhanced the antioxidant enzymes and decreased reactive oxygen species (Ahmad et al., 2023; Fiaz et al., 2024). The mechanism for stress mitigating effects of TU applications either foliar or seed priming have been investigated at physiological and molecular levels. Thiourea mainly controls the redox equilibrium mechanism in a cellular environment under stress (Patade et al., 2020).

Thiourea (TU) is increasingly being studied as a bioregulator for crop plant growth and development (Ahmad et al., 2022b). TU seed priming increased the root and shoot lengths, root fresh and dry weight of sesame varieties, however, TH-6 showed better growth indicators than TS-5 (Table 1), Exogenous administration of TU increases plant growth and productivity in both normal and stressful conditions (Zahra et al., 2022b). Previous research has demonstrated the benefits of exogenous TU application as a priming agent for seed pretreatment, foliar spray, and medium supplement for a variety of crop species. The use of TU has been shown to improve plant tolerance to a variety of environmental stresses, including salinity, heat, heavy metals, and drought (Granaz et al., 2022; Harisha et al., 2023; Zahid et al., 2024).

Salinity stress negatively impacts the photosynthetic machinery and causes irreparable damage to it at any developmental stage. Photosynthesis is essential for the survival of all organisms and is a major factor in plant productivity by creating all precursor biomolecules. Both varieties TS-5 and TH-6, photosynthetic pigments (Chl a, Chl b, and carotenoids) were decreased under salinity, however, seed priming with thiourea improved photosynthetic pigments (Figure 1). The present study outcomes corroborate with the results of Saddiq et al. (2021), Shahid et al. (2023), and Lalarukh et al. (2023). Under salinity stress, a significant decrease in photosynthetic content was observed; this could be because salinity stress negatively affects leaf anatomy, chloroplast ultrastructure and metabolism (Hameed et al., 2021; Barhoumi et al., 2022). Moreover, salinity stress decreased the gas exchange indicators like transpiration rate, photosynthetic rate and stomatal conductance while increased the sub-stomatal CO2 level (Figure 1). Lower gas exchange characteristics under salinity stress may be associated with increased ROS generation, which closes the stomata while thiourea application decreased the production of abscisic acid and controls the ROS induced stomatal closure (Sahoo et al., 2023).

Oxidative stress is one of the most promising effects on plants resulting in the reactive oxygen species production, causing the cellular compartments degradation and inhibition of their functions (Hasanuzzaman et al., 2021; Zahra et al., 2021). However, there is noteworthy inter and intraspecific variance in production of ROS and also tolerance against salinity stress. In the current study, there was a significant increase in the production of H2O2 and MDA under saline conditions while the seed priming with thiourea proved helpful to limit their production in both normal and saline conditions (Figure 4). Moreover, higher H2O2 and MDA production was noted in TH-5 than TS-6. Among various harmful ions the Na+ and Cl- were proved particularly to be more damaging in terms of plants cellular membranes (Khare et al., 2020). These ions move taken up by roots and transported to other plant bodies causing additional damage. Impairment to cellular structures results in the increase in the production of ROS, and in different reactive species H2O2 is the most damaging and longer half-life (Dumanović et al., 2021). In salinity stress, the production of antioxidants assists the plants to overcome the adverse oxidative stress (Ahmad et al., 2019). Sesame priming with thiourea under saline conditions exhibited higher activities of POD, CAT and SOD (Figure 5). Fiaz et al. (2024) noted that the application of thiourea enhanced the activity of SOD, CAT and POD and reduced the level of MDA and H2O2. The results of the current trial were similar with the outcomes of Nouman and Aziz (2022) which depicted that seed priming of thiourea the increased activity of SOD, CAT, POD, riboflavin, flavonoids, and alkaloids in Calotropis procera. Salinity stress increased total phenolics, flavonoids, riboflavin and alkaloids in both varieties. Moreover, thiourea seed priming also improved these secondary metabolites under saline and control conditions (Figure 2). Zhang et al. (2017) reported that amino acid and carbohydrate metabolic pathways significantly improved in the adaption to salinity stress. In current experiment, the total phenolics, flavonoids, riboflavin and alkaloids enhanced under salinity stress was comarable in sugar beet (El-Mageed et al., 2022), maize (Shahid et al., 2023) and sunflower (Barros et al., 2019). Salinity stress resulted in the increase of Na+ ions in both root and shoot while resulted in a decrease in the Ca2+ and K+, while the thiourea treatment decreased the accumulation of Na+ ions and increased the K+ and Ca2+ ions (Table 2). High salinity results in disturbance of K+ ions cytosolic homeostasis and plants endurance, which are deliberates the most essential salt tolerance mechanisms in plants, resulting in significant K+ efflux and Na+ buildup (Abbasi et al., 2014). In the current trial, salinity-stressed plants mount up more Na+ and less K+ than control sesame plants, this could be the consequence of potential antagonism between K+ and Na+ (Ferreira et al., 2020).

Conclusions and Recommendations

Salinity is the major threat to the growth of sesame. Salinity decreases the photosynthetic pigments and efficiency, impairs the balance between antioxidants and oxidants, and lessens the uptake of essential minerals irrespective of varietal differences. However, the performance of TH-6 was better than TS-5. In addition, the seed priming of thiourea enhanced the sesame photosynthetic pigments and efficiency, secondary metabolites production, antioxidant machinery, and nutrient uptake in both varieties which increased growth and development as a result. So, thiourea seed priming is an effective strategy to counteract the negative effects of salt stress by improving tolerance mechanisms.

Acknowledgements

We are thankful to the University of Agriculture, Faisalabad for providing research facilities.

Novelty Statement

Priming seeds with thiourea offers a promising approach to mitigate the detrimental effects of salt stress by enhancing tolerance mechanisms.

Author’s Contribution

Bushra Irfan: Conducted the experiment and data collection.

Muhammad Shahzad: Supervised the experiment as Project Head.

Asif Mukhtiar: Data collection

Muhammad Zubair Akram: Initial drafting and finalizing the MS.

Muhammad Atif Bashir: Statistical analysis.

Sabina Asghar: Helped in relevant literature.

Abdul Ghaffar and Samreen Nazeer: Reviewed final draft of the MS.

Conflict of interest

The authors have declared no conflict of interest.

References

Abbasi, G.H., J. Akhtar, M. Anwar-ul-Haq, S. Ali, Z. Chen and W. Malik. 2014. Exogenous potassium differentially mitigates salt stress in tolerant and sensitive maize hybrids. Pak. J. Bot., 46: 135-146.

Ahmad, M., E.A. Waraich, U. Zulfiqar, A. Ullah and M. Farooq. 2023. Thiourea application increases seed and oil yields in Camelina under heat stress by modulating the plant water relations and antioxidant defense system. J. Soil Sci. Plant Nutr., 23: 290-307. https://doi.org/10.1007/s42729-021-00735-2

Ahmad, M., E.A. Waraich, U. Zulfiqar, S. Hussain, M.U. Yasin and M. Farooq. 2022a. Thiourea application improves the growth and seed and oil yields in canola by modulating gas exchange, antioxidant defense, and osmoprotection under heat stress. J. Soil Sci. Plant Nutr., 22: 3655-3666. https://doi.org/10.1007/s42729-022-00917-6

Ahmad, N., A.L. Virk, S. Hussain, M.B. Hafeez, F.U. Haider, M.I.A. Rehmani, T.A. Yasir and A. Asif. 2022b. Integrated application of plant bioregulator and micronutrients improves crop physiology, productivity and grain biofortification of delayed sown wheat. Environ. Sci. Pollut. Res., 29: 52534-52543. https://doi.org/10.1007/s11356-022-19476-5

Ahmad, R., S. Hussain, M.A. Anjum, M.F. Khalid, M. Saqib, I. Zakir, A. Hassan, S. Fahad and S. Ahmad. 2019. Oxidative stress and antioxidant defense mechanisms in plants under salt stress. Plant abiotic stress tolerance: Agronomic, molecular biotechnological approaches, pp. 191-205. https://doi.org/10.1007/978-3-030-06118-0_8

Ali, Q., M. Ahmad, M. Kamran, S. Ashraf, M. Shabaan, B.H. Babar, U. Zulfiqar, F.U. Haider, M.A. Ali and M. Elshikh, 2023. Synergistic effects of Rhizobacteria and salicylic acid on maize salt-stress tolerance. Plants 12: 2519. https://doi.org/10.3390/plants12132519

Arnon, D., 1949. Copper enzymes in isolated chloroplasts. Polyphenoloxidase in Beta vulgaris. Plant Physiol. Biochem., 24: 1. https://doi.org/10.1104/pp.24.1.1

Barhoumi, Z., A. Atia, A.A. Hussain, T.H. Albinhassan and K.A. Saleh. 2022. Effects of high salinity on photosynthesis characteristics, leaf histological components and chloroplasts ultrastructure of Avicennia marina seedlings. Acta Physiol. Plant, 44: 85. https://doi.org/10.1007/s11738-022-03418-2

Barros, C.V.S.D., Y.L. Melo, M.d.F. Souza, D.V. Silva and C.E.C. de Macedo. 2019. Sensitivity and biochemical mechanisms of sunflower genotypes exposed to saline and water stress. Acta Physiol. Plant, 41: 159. https://doi.org/10.1007/s11738-019-2953-3

Biswas, S., S. Natta, D.P. Ray, P. Mondal and U. Saha. 2018. Til (Sesamum indicum L.)-An underexploited but promising Oilseed with multifarious applications: A review. Int. J. Bioresour. Sci., 5: 127-139. https://doi.org/10.30954/2347-9655.02.2018.8

Chance, B. and A. Maehly. 1955. Assay of catalases and peroxidases. Method Enzymol., 2: 764-775. https://doi.org/10.1016/S0076-6879(55)02300-8

Chen, Y., H. Lin, M. Lin, Y. Zheng and J. Chen. 2020. Effect of roasting and in vitro digestion on phenolic profiles and antioxidant activity of water-soluble extracts from sesame. Food Chem. Toxicol., 139: 111239. https://doi.org/10.1016/j.fct.2020.111239

Dabravolski, S.A. and S.V. Isayenkov, 2023. The regulation of plant cell wall organisation under salt stress. Front. Plant Sci., 14: 1118313. https://doi.org/10.3389/fpls.2023.1118313

Dangue, A., O.Y. Ali, D. Diaw, M.A.F. Ndiaye and T.A. Diop. 2022. Physiology and adaptation strategy of sesame (Sesamum indicum L.) to salinity. GSC Adv. Res. Rev., 11: 029-036. https://doi.org/10.30574/gscarr.2022.11.2.0117

Desingh, R. and Kanagaraj. 2019. Differential responses to salt stress on antioxidant enzymatic activity of two horse gram [Macrotyloma uniflorum (Lam.) Verdc] varieties. Int. J. Res. Anal. Rev., 6: 425-430.

Dhillon, S.A., N. Mujahid, M. Shahbaz and A. Debez. 2023. Response of sesame (Sesamum indicum L.) to foliar-applied thiourea under saline conditions. Int. J. Appl. Exp. Biol., 2: 167-177. https://doi.org/10.56612/ijaeb.v2i2.54

Dollison, M.D. and B.B. Dollison. 2023. Agronomic performance of sesame (Sesamum indicum) under different fertilizer management. Biosaintifika: J. Biol. Biol. Educ., 15: 378-385. https://doi.org/10.15294/biosaintifika.v15i3.47277

Dossa, K., J. You, L. Wang, Y. Zhang, D. Li, R. Zhou, J. Yu, X. Wei, X. Zhu and S. Jiang. 2019. Transcriptomic profiling of sesame during waterlogging and recovery. Sci. Data, 6: 204. https://doi.org/10.1038/s41597-019-0226-z

Dumanović, J., E. Nepovimova, M. Natić, K. Kuča and V. Jaćević, 2021. The significance of reactive oxygen species and antioxidant defense system in plants: A concise overview. Front. Plant Sci., 11: 552969. https://doi.org/10.3389/fpls.2020.552969

El-Mageed, T.A.A., A.A. Mekdad, M.O. Rady, A.S. Abdelbaky, H.S. Saudy and A. Shaaban. 2022. Physio-biochemical and agronomic changes of two sugar beet cultivars grown in saline soil as influenced by potassium fertilizer. J. Soil Sci. Plant Nutr., 22: 3636-3654. https://doi.org/10.1007/s42729-022-00916-7

Farooq, M., J. Uzma, T. Dayakar, G.A. Pizzio and P. Mamidala. 2023. Foliar spray of thiourea enhances salt tolerance and improves biochemical induced physiological responses in Gerbera jamesonii. https://doi.org/10.20944/preprints202310.1725.v1

Ferreira, J.F., J.B. da Silva Filho, X. Liu and D.J.P. Sandhu. 2020. Spinach plants favor the absorption of K+ over Na+ regardless of salinity, and may benefit from Na+ when K+ is deficient in the soil. Plants, 9: 507. https://doi.org/10.3390/plants9040507

Fiaz, K., M.F. Maqsood, M. Shahbaz, U. Zulfiqar, N. Naz, A.-R.Z. Gaafar, A. Tariq, F. Farhat, F.U. Haider and B. Shahzad. 2024. Application of thiourea ameliorates drought induced oxidative injury in Linum usitatissimum L. by regulating antioxidant defense machinery and nutrients absorption. Heliyon. https://doi.org/10.1016/j.heliyon.2024.e25510

Franzisky, B.L., J. Sölter, C. Xue, K. Harter, M. Stahl and C.M. Geilfus. 2023. In planta exploitation of leaf apoplastic compounds: A window of opportunity for spatiotemporal studies of apoplastic metabolites, hormones and physiology. Biorxiv, https://www.biorxiv.org/content/10.1101/2023.1104.1105.535553v535551.abstract, https://doi.org/10.1101/2023.04.05.535553

Giannopolitis, C.N. and S.K. Ries. 1977. Superoxide dismutases: I. Occurrence in higher plants. Plant Physiol. Biochem., 59: 309-314. https://doi.org/10.1104/pp.59.2.309

Granaz, K. Shaukat, G. Baksh, N. Zahra, M.B. Hafeez, A. Raza, A. Samad, M. Nizar and A. Wahid. 2022. Foliar application of thiourea, salicylic acid, and kinetin alleviate salinity stress in maize grown under etiolated and de-etiolated conditions. Discov. Food, 2: 27. https://doi.org/10.1007/s44187-022-00027-3

Hafeez, M.B., A. Ghaffar, N. Zahra, N. Ahmad, H. Shair, M. Farooq and J. Li. 2024. Exogenous application of plant growth regulators improves economic returns, grain yield and quality attributes of late-sown wheat under saline conditions. Int. J. Plant Prod., 18: 217–228. https://doi.org/10.1007/s42106-024-00285-4

Hameed, A., M.Z. Ahmed, T. Hussain, I. Aziz, N. Ahmad, B. Gul and B.L. Nielsen. 2021. Effects of salinity stress on chloroplast structure and function. Cells, 10: 2023. https://doi.org/10.3390/cells10082023

Harisha, C.B., V.B. Narayanpur, J. Rane, V.M. Ganiger, S.M. Prasanna, Y.C. Vishwanath, S.G. Reddi, H.M. Halli, K.M. Boraiah and P.S. Basavaraj. 2023. promising bioregulators for higher water productivity and oil quality of chia under deficit irrigation in semiarid regions. Plants, 12: 662. https://doi.org/10.3390/plants12030662

Hasanuzzaman, M., M.R.H. Raihan, A.A.C. Masud, K. Rahman, F. Nowroz, M. Rahman, K. Nahar and M. Fujita. 2021. Regulation of reactive oxygen species and antioxidant defense in plants under salinity. Int. J. Mol. Sci., 22: 9326. https://doi.org/10.3390/ijms22179326

Heath, R.L. and L. Packer. 1968. Photoperoxidation in isolated chloroplasts: I. Kinetics and stoichiometry of fatty acid peroxidation. Arch. Biochem. Biophys., 125: 189-198. https://doi.org/10.1016/0003-9861(68)90654-1

Hmissi, M., M. Chaieb and A. Krouma. 2023. Differences in the physiological indicators of seed germination and seedling establishment of durum wheat (Triticum durum Desf.) cultivars subjected to salinity stress. Agronomy, 13: 1718. https://doi.org/10.3390/agronomy13071718

Hualpa-Ramirez, E., E.C. Carrasco-Lozano, J. Madrid-Espinoza, R. Tejos, S. Ruiz-Lara, C. Stange and L. Norambuena, 2024. Stress salinity in plants: New strategies to cope with in the foreseeable scenario. Plant Physiol. Biochem., 208: 108507. https://doi.org/10.1016/j.plaphy.2024.108507

Jhanji, S. and M. Dhingra, 2020. Ameliorative effect of thiourea priming on germination characteristics of mungbean (Vigna radiata L.) under water and salinity stress. Legume Res. Int. J., 43: 353-358.

Julkunen-Tiitto, R., 1985. Phenolic constituents in the leaves of northern willows: Methods for the analysis of certain phenolics. J. Agric. Food Chem., 33: 213-217. https://doi.org/10.1021/jf00062a013

Kanagaraj, G. and C. Sathish, 2017. Salt stress induced changes in growth, pigments and protein. J. Sci. Agric., 8: 18.

Kaur, M., N. Gupta, N. Kaur, R. Sohu, A.K. Mahal and A. Choudhary. 2023. Preliminary screening of sorghum (Sorghum bicolor L.) germplasm for salinity stress tolerance at the early seedling stage. Cereal Res. Commun., 51: 603-613. https://doi.org/10.1007/s42976-022-00327-5

Khademian, R., B. Asghari, B. Sedaghati, Y. Yaghoubian and Products. 2019. Plant beneficial rhizospheric microorganisms (PBRMs) mitigate deleterious effects of salinity in sesame (Sesamum indicum L.): Physio-biochemical properties, fatty acids composition and secondary metabolites content. Indust. Crops, 136: 129-139. https://doi.org/10.1016/j.indcrop.2019.05.002

Khare, T., A.K. Srivastava, P. Suprasanna and V. Kumar. 2020. Individual and additive stress impacts of Na+ and Cl on proline metabolism and nitrosative responses in rice. Plant Physiol. Biochem., 152: 44-52. https://doi.org/10.1016/j.plaphy.2020.04.028

Lalarukh, I., N. Zahra, A. Shahzadi, M.B. Hafeez, S. Shaheen, A. Kausar and A. Raza. 2023. Role of aminolevulinic acid in mediating salinity stress tolerance in sunflower (Helianthus annuus L.). J. Soil Sci. Plant Nutr., 23: 5345-5359. https://doi.org/10.1007/s42729-023-01406-0

Langyan, S., P. Yadava, S. Sharma, N.C. Gupta, R. Bansal, R. Yadav, S. Kalia and A. Kumar. 2022. Food and nutraceutical functions of Sesame oil: An underutilized crop for nutritional and health benefits. Food Chem., 389: 132990. https://doi.org/10.1016/j.foodchem.2022.132990

Mahdavi-Khorami, A., J.M. Sinaki, M.A. Dehaghi, S. Rezvan and A. Damavandi. 2020. Sesame (Sesame indicum L.) biochemical and physiological responses as affected by applying chemical, biological, and nano-fertilizers in field water stress conditions. J. Plant Nutr., 43: 456-475. https://doi.org/10.1080/01904167.2019.1683189

Nikfekr, R., S.K. Kazemitabar, G. Ranjbar, S.H. Hashemi-Petroudi and P.M. Joubani. 2023. Study of genetic diversity and evaluation of some sesame genotypes under salinity stress. Environ. Stresses Crop Sci.,

Nouman, W. and U. Aziz. 2022. Seed priming improves salinity tolerance in Calotropis procera (Aiton) by increasing photosynthetic pigments, antioxidant activities, and phenolic acids. Biologia, 77: 609-626. https://doi.org/10.1007/s11756-021-00935-2

Okwu, D. and C. Josiah. 2006. Evaluation of the chemical composition of two Nigerian medicinal plants. Afr. J. Biotechnol., 5: 357-361.

Pan, T., M. Liu, V.D. Kreslavski, S.K. Zharmukhamedov, C. Nie, M. Yu, V.V. Kuznetsov, S.I. Allakhverdiev and S. Shabala. 2021. Non-stomatal limitation of photosynthesis by soil salinity. Crit. Rev. Environ. Sci. Technol., 51: 791-825. https://doi.org/10.1080/10643389.2020.1735231

Patade, V.Y., G.C. Nikalje and S. Srivastava. 2020. Role of thiourea in mitigating different environmental stresses in plants. Protective chemical agents in the amelioration of plant abiotic stress: Biochemical and molecular perspectives, pp. 467-482. https://doi.org/10.1002/9781119552154.ch23

Rahman, A., S. Bhattarai, D. Akbar, M. Thomson, T. Trotter, S. Timilsina and C. Australia. 2020. Market analysis of sesame seed. CQUniversity. Report.

Rangani, J., A.K. Parida, A. Panda and A. Kumari, 2016. Coordinated changes in antioxidative enzymes protect the photosynthetic machinery from salinity induced oxidative damage and confer salt tolerance in an extreme halophyte Salvadora persica L. Front. Plant Sci., 7: 50. https://doi.org/10.3389/fpls.2016.00050

Sabagh, A., F. Çiğ, S. Seydoşoğlu, M.L. Battaglia, T. Javed, M.A. Iqbal and M. Awad. 2021. Salinity stress in maize: Effects of stress and recent developments of tolerance for improvement. Cereal Grains, 1: 213. https://doi.org/10.5772/intechopen.98745

Saddiq, M.S., S. Iqbal, M.B. Hafeez, A.M. Ibrahim, A. Raza, E.M. Fatima, H. Baloch, Jahanzaib, P. Woodrow and L.F. Ciarmiello, 2021. Effect of salinity stress on physiological changes in winter and spring wheat. Agronomy, 11: 1193. https://doi.org/10.3390/agronomy11061193

Sahoo, S.A., R.D. Singh, J. Kulkarni, G.S. Kamble, M. Pandey, S.B. Verulkar and A.K. Srivastava. 2023. Thiourea mitigates potassium deficiency in soybean varieties through redox or ABA dependent mechanisms. J. Plant Growth Regul., https://doi.org/10.1007/s00344-023-10963-8

Saleem, I., S.R. Ahmed, A.H. Lahori, M. Mierzwa-Hersztek, S. Bano, A. Afzal, M.T. Muhammad, M. Afzal, V. Vambol and S. Vambol. 2024. Utilizing thiourea-modified biochars to mitigate toxic metal pollution and promote mustard (Brassica campestris) plant growth in contaminated soils. J. Geochem. Explor., 257: 107331. https://doi.org/10.1016/j.gexplo.2023.107331

Sánchez-Navarro, A., A. Girona-Ruíz and M.J. Delgado-Iniesta. 2024. Green manuring and irrigation strategies positively influence the soil characteristics and yield of coriander (Coriandrum sativum L.) crop under salinity stress. Land, 13: 265. https://doi.org/10.3390/land13030265

Shahid, S., A. Kausar, N. Zahra, M.B. Hafeez, A. Raza and M.Y. Ashraf, 2023. Methionine-induced regulation of secondary metabolites and antioxidants in maize (Zea mays L.) subjected to salinity stress. Gesunde Pflanzen, 75: 1143-1155. https://doi.org/10.1007/s10343-022-00774-4

Singh, D. and A. Sahu, 2006. Spectrophotometric determination of caffeine and theophylline in pure alkaloids and its application in pharmaceutical formulations. Anal. Biochem., 349: 176-180. https://doi.org/10.1016/j.ab.2005.03.007

Sonia, E., P. Ratnakumar, B.B. Pandey, K. Ramesh, S.N. Reddy, V. Hemalatha, A. Sravanthi, P.J. Daniel, C.L. Manikanta and K. Ramya, 2024. The Influence of plant growth modulators on physiological yield and quality traits of sesame (Sesamum indicum) cultivars under rainfed conditions. Agric. Res., https://doi.org/10.1007/s40003-024-00704-y

Takaichi, S., H. Yazawa and Y. Yamamoto, 1995. Carotenoids of the fruiting gliding myxobacterium, Myxococcus sp. MY-18, isolated from lake sediment: Accumulation of phytoene and keto-myxocoxanthin glucoside ester. Biosci. Biotechnol. Biochem., 59: 464-468. https://doi.org/10.1271/bbb.59.464

Taratima, W., N. Kunpratum and P. Maneerattanarungroj. 2023. Effect of salinity stress on physiological aspects of pumpkin (Cucurbita moschata duchesne. laikaotok) under hydroponic condition. Asian J. Agric. Biol., 2023: 202101050.

Tariq, A. and M. Shahbaz, 2020. Glycinebetaine induced modulation in oxidative defense system and mineral nutrients sesame (Sesamum indicum L.) under saline regimes. Pak. J. Bot., 52: 775-782. https://doi.org/10.30848/PJB2020-3(34)

Velikova, V., I. Yordanov and A. Edreva, 2000. Oxidative stress and some antioxidant systems in acid rain-treated bean plants: Protective role of exogenous polyamines. Plant Sci., 151: 59-66. https://doi.org/10.1016/S0168-9452(99)00197-1

Victoria, O., U. Idorenyin, M. Asana, L. Jia, L. Shuoshuo, S. Yang, I.M. Okoi, A. Ping and E.A. Egrinya. 2023. Seed treatment with 24-epibrassinolide improves wheat germination under salinity stress. Asian J. Agric. Biol., 2023,

Vojodi Mehrabani, L. and N.J. Kheirollahi. 2023. Effects of salinity stress and foliar application of mineral elements and methanol on growth and some physiological traits of Coriandrum sativum L. J. Plant Process Funct., 12: 81-90.

Wan, Y., Q. Zhou, M. Zhao and T. Hou. 2023. Byproducts of sesame oil extraction: Composition, function, and comprehensive utilization. Foods, 12: 2383. https://doi.org/10.3390/foods12122383

Wang, L., K. Dossa, J. You, Y. Zhang, D. Li, R. Zhou, J. Yu, X. Wei, X. Zhu and S. Jiang. 2021. High-resolution temporal transcriptome sequencing unravels ERF and WRKY as the master players in the regulatory networks underlying sesame responses to waterlogging and recovery. Genomics, 113: 276-290. https://doi.org/10.1016/j.ygeno.2020.11.022

Waqas, M., M.J. Hawkesford and C.M. Geilfus. 2023. Feeding the world sustainably: Efficient nitrogen use. Trends Plant Sci., 28: 505-508. https://doi.org/10.1016/j.tplants.2023.02.010

Wolf, B., 1982. An improved universal extracting solution and its use for diagnosing soil fertility. Commun. Soil Sci. Plant Anal., 13: 1005-1033. https://doi.org/10.1080/00103628209367331

Yadav, T., R. Yadav, G. Yadav, A. Kumar and G. Makarana. 2023. Salicylic acid and thiourea ameliorated adverse effects of salinity and drought-induced changes in physiological traits and yield of wheat. Cereal Res. Commun., pp. 1-14. https://doi.org/10.1007/s42976-023-00382-6

Zahid, A., K. ul din, M. Ahmad, U. Hayat, U. Zulfiqar, S.M.H. Askri, M.Z. Anjum, M.F. Maqsood, N. Aijaz and T. Chaudhary. 2024. Exogenous application of sulfur-rich thiourea (STU) to alleviate the adverse effects of cobalt stress in wheat. BMC Plant Biol., 24: 126. https://doi.org/10.1186/s12870-024-04795-1

Zahra, N., A. Wahid, K. Shaukat, M.B. Hafeez, A. Batool and M. Hasanuzzaman. 2021. Oxidative stress tolerance potential of milk thistle ecotypes after supplementation of different plant growth-promoting agents under salinity. Plant Physiol. Biochem., 166: 53-65. https://doi.org/10.1016/j.plaphy.2021.05.042

Zahra, N., M.S. Al Hinai, M.B. Hafeez, A. Rehman, A. Wahid, K.H. Siddique and M. Farooq. 2022a. Regulation of photosynthesis under salt stress and associated tolerance mechanisms. Plant Physiol. Biochem., 178: 55-69. https://doi.org/10.1016/j.plaphy.2022.03.003

Zahra, N., A. Wahid, M.B. Hafeez, K. Shaukat, S. Shahzad, T. Shah and M.N. Alyemeni. 2022b. Plant growth promoters alleviate oxidative damages and improve the growth of milk thistle (Silybum marianum L.) under salinity stress. J. Plant Growth Regul., 41: 3091–3116. https://doi.org/10.1007/s00344-021-10498-w

Zebib, H., G. Bultosa and S. Abera. 2015. Physico-chemical properties of sesame (Sesamum indicum L.) varieties grown in Northern Area, Ethiopia. Agric. Sci., 6: 238. https://doi.org/10.4236/as.2015.62024

Zhang, Y., J. Xu, R. Li, Y. Ge, Y. Li and R. Li. 2023. Plants response to abiotic stress: Mechanisms and strategies. Int. J. Mol. Sci., 24: 10915. https://doi.org/10.3390/ijms241310915

Zhang, Z., C. Mao, Z. Shi and X. Kou. 2017. The amino acid metabolic and carbohydrate metabolic pathway play important roles during salt-stress response in tomato. Front. Plant Sci., 8: 1231. https://doi.org/10.3389/fpls.2017.01231

Zhishen, J., T. Mengcheng and W. Jianming, 1999. The determination of flavonoid contents in mulberry and their scavenging effects on superoxide radicals. Food Chem., 64: 555-559. https://doi.org/10.1016/S0308-8146(98)00102-2

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Sarhad Journal of Agriculture

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Vol.40, Iss. 3, Pages 680-1101

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