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Phenological Assessments of Selected Wheat Genotypes in Different Agro-Environment

SJA_38_3_759-777

Research Article

Phenological Assessments of Selected Wheat Genotypes in Different Agro-Environment

Rabia Goher, Inamullah and Mohammad Akmal*

Department of Agronomy, The University of Agriculture Peshawar, 25130 Peshawar, Pakistan.

Abstract | Despite the genetic potential, the yield performance of a genotype is expressed in the prevailing environments. A high yielding genotype may not necessarily reflect its potential performance when subjected to a different Agro-Environment (AE). This study, therefore, aimed to assess the foremost developmental stages of the selected genotypes of wheat in three AE i.e. AEP (Peshawar), AEK (Kashmir) and AEC (Chitral). An experiment was conducted in a randomized complete block, having 3 replications. Four cultivars (i.e. Pirsabak-2005, Pakhtunkhwa-2015, Pakistan-2013 and DN-84) along with three advanced lines (i.e. P-2, P-12 and P-18) were compared for the crop growth seasons (i.e. 2017-18 and 2018-19). Averaged across genotypes, days to emergence, heading, anthesis, and maturity did differ (p<0.05) in various AE, with highest in higher altitudes and lowest in the plains area. Genotypes differed in crop developmental stages with mild to marked effects on tiller height, spike length, spike weight and unit grain weight, which has resulted in significant changes (p<0.05) for biomass and grain yield. Harvest indices did differ for AE among genotypes. Based on the experimental results, it is concluded that a genotype may not necessarily perform similar in production with changing the AE. However, with a close association of the crop developmental stages, more than one genotype can be recommended to perform good within different AE to adress future food security. Moreover, expressing suitable traits, a genotype could be used as a source of well breeding material for ensuring food security in changing climate.


Received | July 14, 2021; Accepted | December 13, 2021; Published | June 10, 2022

*Correspondence | Mohammad Akmal, Department of Agronomy, The University of Agriculture Peshawar, 25130 Peshawar, Pakistan; Email: [email protected]

Citation | Goher, R., I. Ullah and M. Akmal. 2022. Phenological assessments of selected wheat genotypes in different agro-environment. Sarhad Journal of Agriculture, 38(3): 759-777.

DOI | https://dx.doi.org/10.17582/journal.sja/2022/38.3.759.777

Keywords | Phenology parameters, Days to emergence, Anthesis, Maturity, Wheat genotypes, Agro-environment, Biomass and harvest index

Copyright: 2022 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

Wheat (Triticum aestivum L.) is an important staple food crop of the poor people in the world (Pandey et al., 2020). Its grains are rich source of energy and carbohydrates, which provides components essential for health i.e. protein, vitamins, dietary fibers (Bhutto et al., 2021). Its demand increases in developing countries due to its higher consumption with increasing population (Zandalinas et al., 2018). Climate change is an emerging challenge to crops, which may increase or decrease its production in different agro-ecological zones (Raza et al., 2019). Temperature rise boosts growth of wheat from sowing to maturity, but humidity together encourages scale of rust and smut attack (Rezaei et al., 2018). Rise in temperature tended to continue at the start of this century and is expected to increase, which makes sense to understand the wheat crop phenology in different environments. A minor change in climate, specifically at anthesis stage of the crop growth, has resulted in a complete grain failure (He et al., 2020). Unavailability of irrigation or rain at sowing time has shifted wheat sowing from normal to late in season (Akmal et al., 2018), which results in a limited reproductive stage that adversely affects the harvest index (Gobin, 2018).

Other than production factors, temperature plays a key role in crop growth and development (Awan et al., 2017a). Temperature fluctuations correspond to the plant development have shown significant effects on production of wheat (Zhao et al., 2017). It is reported that high temperature may lower downs photosynthesis by reducing metabolism and oxidation of chloroplasts, which adversely affects the yield (Wang et al., 2018a). To turn a genotype to mature faster may be due to a rapid increase in temperature, which resulted in a reduction in production (Khan et al., 2021). Increase in temperature for a while i.e. a few hours may not be harmful but adversely affects productivity (IPCC, 2012). Studies have paid attention to extreme events, such as temperature shock at grain development stages focusing on yield (Ali et al., 2017). Crop response differently to different environments either by fluctuation in temperature or drought stress events during the crop development (Cohen et al., 2021). Variations in environment are due to changes in temperature (i.e. the photoperiod and intensity at a given time), which coupled with drought stress responded accordingly for rates of the crop evapotranspiration to contribute to growth (Phan et al., 2018).

Wheat is originated in southwestern Asia. It is an important staple food crop of central Asia including Pakistan (Liu et al., 2017a). Wheat occupied the maximum area under cultivation for the protein source (FAO., 2020). It has a broad range of adaptability to a different environment (Dowla et al., 2018), But still the climatic changes govern its performance for different genotypes. This is due to both biotic and abiotic factors e.g. salinity, temperature, soil water, etc. Genotypes released with either by single plant selection or inter-breeding of selected plants for different traits. Both single plant selection and interbreeding have shown equally good performance in fields in different environments. Nontheless, genotype performed better in an AE after its release but the sustainability not ensured under mild changes permanently (Osei et al., 2018)

Keeping in view the future food security, it is important to compare the developmental stages of genotypes for good traits identification, which can be used as breeding material for changing climate of an AE. The study, therefore, aimed to compare developmental stage of the crop growth in different AE focusing on phenological differences of genotypes. We, therefore, compared growth performance of selected genotypes in different AE to recommend a genotype wider cultivation ensured food security.

Materials and Methods

Experimental sites and locations

Experiments were conducted in three agro-environment (AE) focusing on the objective to assess phenological changes during the crop growth and development for two seasons. Three AE were the University of Agriculture Peshawar (AEP), the Agriculture Research station Garhi-Dopatta Azad Kashmir (AEK), and the Agriculture Research station Bunni, Chitral (AEC). According to USDA classification, the soil type of the three AEP ranked halpic luvisol, alkaline clay-loam and contains organic matter 10.94 g kg-1 (Anonymous 2007). Whereas, AEK falls within Himalayan orogenic belt and the soil has a pH of 6.5 to 7.5, clay loam texture, adequate organic matter, available Phosphorus and Potassium (Almas and Saeed, 2000). Soil of the AEC (Chitral-Bunni) ranges from silt-loam, slightly acidic and moderate to highly calcareous with salinity indication in patches and organic matter >2% (Ahmad et al., 2018) Location and the crop growth factors of the different AE are shown in Table 1. However, diurnal temperatures (Max. and Min.) and rainfall of the crop growth seasons are shown in Figure 1.

Experimental design and treatments

Experiments were randomized complete block, in three replications at each AE with a common layout, which includes a set of seven genotypes of which 4 were high yielding cultivars (i.e. Pakhtunkhwa-2015, Pakistan-2013, Pirsabak-2005, & DN-84) and three were the advanced lines (i.e. P-2, P-12, & P-18). The pre-basic seed-class was used at the rate of 100 kg ha-1 and a hand-driven drill on November 30 (2017), and 10 (2018) in AEP, November 27 (2017), and 21(2018) in AEK, October 13 (2017), and 12 (2018) in AEC. There were six rows of 5.0m length equally spaced at 30cm width. The field was irrigated and

 

Table 1: Comparison of agro-environment for different climate and locations.

Agro-environment

Height above sea level

Temperature (OC)

Rainfall (mm)

Latitude & altitude

Irrigation with rainfall (mm)

Max.

Min.

AEP (Peshawar)

350

40.7±6.29

24±6.24

500-700

34.01°N & 71.52 °E

607* +602**

AEK (Kashmir)

819

20 to 32

04 - 07

1242

34.22 °N & 73.61 °E

576*+815**

AEC (Chitral)

1880

11.4-32.8

11.4

800

36.27 °N & 72.25 °E

606*+500**

* represents 2017-18 and **2018-19

 

 

plowed with a cultivator. On the day of sowing, fertilizers were applied at the rate of 120 (N), 80 (P-2O5) and 50 (K2O) kg ha-1 respectively from urea, SSP and MOP sources. However, N was applied in two splits one half at sowing and the other half about 50 days after the sowing (DAS) as recommended for the wheat crop.

Experiment details

All agronomic practices recommended for the wheat crop were carried out uniformly for all three AE (i.e. locations). However, the AEK was rainfed with no irrigation facility. Harvesting was done on the crop physiological maturity in each AE when a genotype was ready to harvest i.e. May 4, 2018 (cv. Pirsabak-2005, Pakhtunkhwa-2015, Pakistan-2013, DN-84 & P-12), May 10, 2018 and 13 2019 (cv. P-2 & P-18) at the AEP, May 25, 2018, and May 29, 2019 in AEK, and likewise on July 10, 2018, and July 15, 2019, in AEC. It is clear that the crop harvesting in AEK and AEC was made on same dates for all 7 genotypes.

Sampling and measurements

Days to emergence, heading, anthesis and maturity were observed by counting the number of days from sowing to the respective growth stage of the crop genotypes within an AE. A meter square sample was marked in an experimental unit and all data were manually recorded during the regular field visits. Tiller’s height was recorded by randomly measuring 10 representative samples in an experimental unit from base to tip of the tiller including spikes close to harvesting of the crop. Spike length (cm) was also recorded on the same tillers selected for the tiller’s height. Spike weight (g) was recorded on same spikes after drying (70OC) for a week in forced air circulating dryers. Thousand

 

Table 2: Days to emergence and heading of wheat cultivars planted in different agro- environments.

Agro environment (AE)

Days to emergence

Days to heading

2017-18

2018-19

Mean

2017-18

2018-19

Mean

AEP

15.3

11.2

13.3 b

107.5

112.7

110.1 c

AEK

15.4

12.1

13.8 b

117.5

119.7

118.6 b

AEC

14.9

14.7

14.8 a

155.5

158.0

156.7 a

LSD (0.05) for AE

0.25

1.51

0.68

1.1

0.7

0.59

Genotypes (G)

Pirsabak-2005

15.6

12.6

14.1

124.9

127.1

126.0 c

Pakhtunkhwa-2015

15.1

13.2

14.2

129.7

132.1

130.9 b

Pakistan-2013

14.9

12.4

13.7

123.8

127.1

125.4 c

DN-84

14.8

12.6

13.7

121.7

124.7

123.2 d

P-2

15.2

12.2

13.7

131.8

136.6

134.2 a

P-12

15.3

12.4

13.9

124.3

127.0

125.7 c

P-18

15.6

13.2

14.4

131.7

136.3

134.0 a

LSD (0.05) for G

NS

NS

NS

1.3

0.9

0.77

Year mean

15.2

12.7

**

126.8 b

130.1 a

**

Level of significance (p<0.05) for treatment interaction

Y x AE

-

-

***

-

-

-

Y x G

-

-

NS

-

-

-

AE x G

NS

NS

NS

**

**

-

Y x AE x G

-

-

NS

-

-

-

Means followed by different letters within a category are statistically different using the least significant difference test (p<0.05); * and ** represents the significance at (p<0.05) and (p<0.01); NS =Non-significant

 

grains weight (g) was taken on random selected grains samples from seed at harvest, counted 1000 on an auto-counter, dried in forced circulating air dryers for a week and weighed. Grain and biomass yield were recorded by harvesting 4 central rows in an experimental unit, bundled and initially sun-dried for two weeks in field. Each bundle was weighed and separately threshed on a mini-lab thresher. Grains after threshing were collected in paper bags and weighed. Sub samples of both biomass and grains were collected, oven dried for a constant weight and adjusted both biomass and grain yield with expressing in kg ha-1. Harvest index (HI) is expressed in percent as the ratio of the grain to total above ground biomass.

Heat use efficiency (HUE) was derived as a secondary parameter. It is the ratio of the grain yield per unit area (g m2) obtained from total thermal hours (OC) consumed by the crop in an AE from emergence to physiological maturity for completion of the life cycle. Thermal hours were estimated as the average daily temperature by use of the maximum and minimum in an AE for the crop life cycle.

Data collected during the study were statistically analyzed using the computer software (Statistics) as per procedure explained by Fishers Analysis of Variance Technique using appropriate for the Randomized Complete Block Design (RCBD). Means found significant (p<0.05) were separated using the least significant difference (LSD) (Steel et al., 1997).

Results and Discussion

Crop developmental stages

Days to emergence, heading (Table 2), anthesis, and maturity (Table 3) of the wheat crop showed significant differences for the treatments Agro-environments (AE) and selected genotypes (G). While averaged across G, significant (p<0.05) changes were observed in the crop developmental stages for three AE with no change between AEP and AEK on emergence but with statistical differences for rest of the three developmental stages (i.e. heading, anthesis and maturity) for three AE. Emergence is a short-duration stage of the crop and changes in emergence with a reduction of solar radiations expressed significant changes. The genotypes did not differ (p<0.05)

 

Table 3: Days to anthesis and maturity of wheat cultivars planted in different agro- environments.

Agro environment (AE)

Days to anthesis

Days to maturity

2017-18

2018-19

Mean

2017-18

2018-19

Mean

AEP

116.4

122.6

119.5 c

149

158.7

153.9 c

AEK

125.8

129.4

127.6 b

157.7

163

160.4 b

AEC

180

183.6

181.8 a

227.3

238.7

233.0 a

LSD (0.05) for AE

2.04

1.06

1.02

0.47

1.37

0.65

Genotypes (G)

Pirsabak-2005

137.9

141.3

139.6 c

174.1

182.4

178.3 c

Pakhtunkhwa-2015

142.2

145.4

143.8 b

179.2

187.3

183.3 b

Pakistan-2013

137.9

142.4

140.2 c

174.7

183.1

178.9 c

DN-84

135.6

140

137.8 d

173.1

180.8

176.9 d

P-2

147.3

153.3

150.3 a

185.1

196.6

190.8 a

P-12

137.4

141.7

139.6 c

174.1

182.0

178.1 c

P-18

146.9

152.2

149.6 a

185.7

195.3

190.5 a

LSD (0.05) for G

1.07

1.24

0.81

1.05

1.42

0.87

Year (Y) mean

140.7 b

145.2 a

**

178.0 b

186.8 a

**

Level of significance (p<0.05) for treatment interaction

Y x AE

-

-

*

-

-

**

Y x G

-

-

*

-

-

**

AE x G

**

**

**

**

**

**

Y x AE x G

-

-

**

-

-

*

Means followed by different letters within a category are statistically different using the least significant difference test (p<0.05); * and ** represents the significance at (p<0.05) and (p<0.01) ; NS =Non-significant

 

in days to emergence for AEP and AEK but differed (p<0.05) for AEC due to cooler climate for more days to complete. Responses of the crop developmental (i.e. emergence, heading, anthesis and maturity) confirmed climate effects for the duration within years. Overall growth and development of the crop expressed maximum days to heading, anthesis and maturity in AEC, followed by AEK, and the minimum in AEP, which have confirmed more days in a cooler climate due to higher altitude by extending crop life cycle (Shah et al., 2021). Emergence is concerned with soil temperature and moisture. Genotypes may differ but not too much. However, temperatures do play role in open fields making differences for AE (e.g. AEC). Differences in AE made seeds to take maximum days into germination in a cooler environment due to higher altitudes. Literature has also confirmed +5 days change in wheat germination for season or delay in sowing (Meleha et al., 2020). Days to heading, anthesis and maturity are developmental stages of a crop, which varied for the environment due to location and altitudes. Different days were observed for the same crop for changes in thermal hours (Ahmed et al., 2016). All developmental stages of the crop i.e. heading, anthesis and maturity expressed a common trend for an environent by an increase in the altitude (i.e. AEP, followed by AEK and AEC), which increased for the decreasing intensity of thermal units (Hatfield and Prueger, 2015). It was has been observed that wheat from emergence to stem elongation faced dormancy due to a decrease in temperature of following days. Growth slows down and stops at temperature (6OC) in winter (Saatkamp et al., 2019). The crop is dormant (Renzi et al., 2020). Climates of AE differ from mild to marked hence their effect responded accordingly (p<0.05) (Rezazadeh et al., 2018). Crop, when turns from vegetative to the reproductive stage, has to meet minimum thermal units. Chitral is relatively cool due to the higher altitude. Crop generally expressed late anthesis and maturity with a long dormant phase (Ahmed et al., 2016).

Averaged on AE, genotypes differed in day to emergence, heading, anthesis and maturity. Two advanced lines took maximum days. Line P-12 was within ranges with other 4 genotypes expressing the crop developmental phenology. All genotypes, but two lines, differed from each other with smaller variations (p<0.05) for days to heading, anthesis and maturity. The maximum days were taken by lines P-2 and P-18, which confirmed a relatively longer growth vegetative phase (Maeoka et al., 2020). Differences in days to heading of genotypes have expressed changes in the active growth period which delayed maturity by confirming the longer life cycle in AEC due to prolonged dormancy (Aslam et al., 2017). Differences in genotypes are common but for few days., The more days for an event delayed both anthesis and maturity (Hatfield and Prueger, 2015). Changes heading, anthesis and maturity enable genotypes to recommend for timely sowing where the crop faced an adverse effect e.g. heat shock at critical stages, i.e. drought stress, or other weather conditions (Ghosh et al., 2020). Two advanced lines (i.e. P-2 and P-18), were markedly late in expressing the development stages and could be recommended for cultivation to escape the adverse climate of abnormality. However, all genotypes including the one advance line (P-12) have shown an almost same trend to develop in the 3 environments (Flohr et al., 2018).

Days to emergence for interaction (year x AE) showed changes (p<0.05), showing marked changes between years for emergence in AEP and AEK, which were almost similar for AEC due to relatively cooler climates and shorter photoperiod. Emergence is time related activity within limited days’ and it differs with changes in soil temperature for one to two weeks (Dos-Santos et al., 2019). Days to heading, anthesis and maturity differed for interaction year x AE with almost same patterns between years within an AE. Differences were higher in year 2 due to early sowing of the crop. Nonetheless, AE differs markedly in expressing the crop development for AEC as compared to AEP or AEK. The AEK was relatively dry and cool from the AEP. Crop phenological development took same days in AEP and AEK due to drought AEK despite cool climate and no drought in AEP despite warmer days. Crop in AEC took more days due to cooler climate (Sattar et al., 2015). Dormancy of the crop development, therefore extended in cooler climate of AEC, which was crop remained dormant from emergence to stem elongation, which delayed both anthesis and maturity (Rademacher, 2015).

Interaction (genotypes x year) differed for days to heading, anthesis and maturity due to variations in accumulated energy in an environment (Delcour et al., 2015). Genotypes differed in the developmental stages expressed in an environment (Eller et al., 2020). Crop development is a temperature-related parameter and expressed duration accordingly. Differences in mean thermal units’ accumulation in an environment determine length of the growth phases to reach anthesis, heading and maturity. Genotypes x AE interaction was different in a similar fashion for days to heading, anthesis and maturity of the genotypes with the maximum in AEC, followed by AEK and the minimum in AEP (Figure 2). Cooler climates by higher altitudes took more days to express the developmental stage of crop, hence more days required to complete the life cycle (Lippmann et al., 2019) subject to similar sowing timings (Hyles et al., 2020). Literature has confirmed the delay in anthesis in cooler climates due to limited mean thermal units (Dong et al., 2019).

 

Treatments interaction (genotypes x year x AE) were significant for days to heading, anthesis and maturity. Wheat took maximum days to heading, anthesis and maturity in AEC followed by AEK and minimum in AEP, which were due to total thermal sunshine hours and their intensity (Yu et al., 2018). Cooler climate (AEC) took more days followed by intermediate (AEK) and the lowest by warmers (AEP). However, genotypes differed in AE and years higher readings

 

Table 4: Tiller height (cm) and spike length (cm) of wheat cultivars planted in different agro-environments.

Agro environment (AE)

Tiller height (cm)

Spike length (cm)

2017-18

2018-19

Mean

2017-18

2018-19

Mean

AEP

103.4

111.5

107.4 a

9.63

10.32

9.98

AEK

86.1

98.8

92.5 c

9.42

9.8

9.61

AEC

105.1

100.7

102.9 b

10.17

9.9

10.04

LSD (0.05) for AE

8.94

1.96

4.08

NS

NS

NS

Genotypes (G)

Pirsabak-2005

100.1

99.3

99.7 b

9.29

9.42

9.35 d

Pakhtunkhwa-2015

96.8

101.2

99.0 b

9.70

10.02

9.86 c

Pakistan-2013

97.2

99.5

98.3 b

9.70

10.09

9.89 c

DN-84

90.5

95.3

92.9 c

8.79

9.20

9.00 e

P-2

113.0

117.9

115.5 a

10.79

11.00

10.89 a

P-12

95.9

102.2

99.1 b

9.71

9.84

9.78 c

P-18

93.9

110.2

102.1 b

10.19

10.49

10.34 b

LSD (0.05) for G

10.26

2.24

5.16

0.46

0.23

0.25

Year (Y) mean

98.2 b

103.7 a

**

9.74

10.01

NS

Level of significance (p<0.05) for treatment interaction

Y x AE

-

-

**

-

-

NS

Y x G

-

-

NS

-

-

NS

AE x G

*

**

**

**

**

**

Y x AE x G

-

-

NS

-

-

NS

Means followed by different letters within a category are statistically different using the least significant difference test (p<0.05); * and ** represents the significance at (p<0.05) and (p<0.01); NS =Non-significant

 

for year 2 due to early sowing but more days in AEC due to cooler climate, followed by AEK and AEP. To change the stage of crop development from heading to anthesis and/or maturity, the temperature is a key factor of the environment (Girousse et al., 2021) AE causing dormancy between the events (Flohr et al., 2018). Nonetheless, responses of genotype in an AE govern by thermal units during growth and genotype to respond (Abdelrahman et al., 2020). We have seen almost similar trends in crop developmental stages for genotypes but environment.

Yield contributing traits

Primary yield contributing traits are tillers per unit, grain number and grain weight. Using a similar seed rate with similar tillering potential, the density per unit did not differ (Bastos et al., 2020). However, the most interesting was comparing their spike-length and -weight which caused variations in grain number and/or their weight (Arjona et al., 2018). Comparing the crop phenology, tillers height (Table 4) differed significantly (p<0.05) with the highest in AEP, followed by AEC and lowest in AEK. Tiller height is a genetic character but is strongly influenced in an environment (Duan et al., 2020). A warmer climate e.g. AEP with sufficient water enables plants to grow faster in daily thermal units’ expansion (Clarke et al., 2015). Wheat, after emergence, passes the dormancy duration depending on spring starts. Shorter the winter in an environment limited will be dormant period to start vegetative growth also making differences in tiller number and height AE. Literature has also confirmed that tiller height (cm) differed in different environments due to differences in temperatures of the growing days which promote internode length, accordingly (Bilgin et al., 2016). The mean daily temperature of the crop growth period is important but drought plays a major role to inhibit stem elongation (Breitkreuz et al., 2020). Optimum mean thermal hours of the growth period, when coordinated with drought, has strongly affected stem sizes e.g. as observed in AEK (Gleason et al., 2017). Genotypes differed in tiller’s height with the maximum for P-2, thereafter, rest of the genotypes were statistically the same to each other. However, the lowest tiller height was recorded for DN-84. Tiller height does vary within genotypes, which is mainly due to node number and internode length of the genotype (Liu et al., 2021). The more optimum or close to optimum temperatures for the days results in longer internodes and hence the tiller’s height in an environment subject to sufficient soil moisture. Besides the environmental changes, genetics of the genotypes do play a role to express the maximum height in an environment (Mishra et al., 2017). Rapid increase in temperature in the following days contributed towards growth with maximum internode length (Steinfort et al., 2017). Differences among s environment for trait i.e. height AE are obvious to classify them tall and dwarf (Munsif et al., 2016).

Interaction (AE x year) showed (p<0.05) taller tillers at AEP and AEK but otherwise in the AEC in year 2. Early sowing in year 2 yielded taller plants. However, the longe dormancy of winter with a steady increase in temperature at AEC did not show any change in tillers height. Snowfall in winter increased dormancy after emergence which showed a non-significant effect on tiller height (Bisbis et al., 2018). Crop growth from minimum to optimum temperature is static and contributes to a uniform growth in an environment during the season (Anjum et al., 2021). Contrary to the AEC, growth in AEP and AEK was subjected to a limited dormancy phase (Munsif et al., 2015). Interaction genotypes x AE showed a significant change (p<0.05) in height (Figure 3a). Genotypes showed alike trend for the tiller height and varying responses observed for lines. Tiller height of genotypes was lower in AEK due to drought when compared with AEP and AEC. Similarly, the tiller height of Pirsabak-2005 and Pakistan-2013 did not differ in AEP and AEC but was lower in AEK. Pakhtunkhwa-2015 showed taller plants in AEC. Temperature and soil moisture are governing factors of plant growth (Hatfield and Prueger, 2015) and hence the growth was higher in AEP with limited days (Klepeckas et al., 2020). Crop in AEP exposed to a relatively higher daily temperature with adequate irrigation hence showed the same height as observed in AEC. Whereas lines showed longer internode length while comparing AEP with AEC and AEK., Plants with longer internodes are the genotype better interaction with the environment (Bhutto et al., 2021).

Spike length, spike weight and unit grain weight

Grain yield showed a close association with the spike length (cm), spike weight (g) and grain weight (g) for different (p<0.05) environments and genotypes x AE interaction (Table 4 and 5). Two years’ data did not show any change (p<0.05) in spike length for different environments (Table 4) but did differ for the genotypes. Contrary to this, spike weight was higher in AEC and lower in AEK with no change (p<0.05) in AEP. Likewise, 1000 grains weight was observed highest in AEC, followed by AEP and lowest in AEK (Table 5). Spike length depends on spikelet number, which contributed to the spike length. Average over genotypes, spikelets did not differ in number hence the spike length was unchanged within environments (O’Brien et al., 2019). Grain size and number differed within spikes for the genotypes, due to the genetic characters. Temperature does play a role within an environment for grain development that makes changes within spike weight for the different environments (Asif et al., 2019). Grain assimilates production and partitioning to sink depends on prevailing temperature, which was observed lower in AEC, followed by AEK and AEP. The assimilates production is usually reported higher at cooler climate e.g. AEC, which resulted in heavier grain weight (Phung et al., 2019). Grain weight in AEK was lowest due to drought which limits grain development despite the favorable climate (Daryanto et al., 2017). The more number and weight of grains contributed to heavier spike and finally, the yield e.g. in AEC. Spike weight in AEP and AEK was the same but differed in grain weight showing that the drought effect was strong enough to reflect on the sink (Wang et al., 2019). Temperatures do play a role in spike weight but drought stress (Javadipour et al., 2019). While averaged across AE, genotypes differed significantly in spike length, spike weight and grains weight. Maximum spike length associated with line P-2, followed by P-18. All genotypes including line P-12 reflected a similar spike length except the Pirsabak-2005 and DN-84. Spike weight associated with grain weight, which differed in genotypes. Grain size depends on assimilates accumulation rate during growth which also corresponds to flag leaf area (Kajla et al., 2015). Genotypes differ in grain size, hence showed variations in spike weight including grain index (Wang et al., 2018b). The spike weight of a genotype depends on spike efficiency from the available sources i.e. leaf area and flag leaf to contribute for grains. Spikelets on spike showed grain number and their weight (Steinfort et al., 2017). Genotypes differ in sensitivity to carbohydrates supply from sources that adversely affect grain weight (Shi et al., 2016). Sensitivity of fertile florets led to increasing abortion in an environment which may lead to differences in spike weight and/or grain number (Zahra et al., 2021).

 

Table 5: Spike weight (g) spike-1 and thousand grains weight (g) of wheat cultivars planted in different Agro-environments.

Agro environment (AE)

Spike weight (g) spike-1

Thousand grains weight (g)

2017-18

2018-19

Mean

2017-18

2018-19

Mean

AEP

2.34

2.72

2.53 b

29.3

32.8

31.0 b

AEK

2.51

2.7

2.61 b

24.1

27.7

25.9 c

AEC

3.2

2.74

2.97 a

48.1

45.4

46.8 a

LSD (0.05) for AE

0.22

NS

0.11

1.4

1.3

0.9

Genotypes (G)

Pirsabak-2005

2.89

3.00

2.94 a

37.9

38.0

38.0 a

Pakhtunkhwa-2015

2.59

2.79

2.69 b

38.3

37.8

38.1 a

Pakistan-2013

2.81

3.04

2.92 a

37.4

38.5

37.9 a

DN-84

2.61

2.58

2.60 bc

31.3

33.2

32.3 c

P-2

2.71

2.38

2.54 c

28.7

29.1

28.9 e

P-12

2.52

2.63

2.57 bc

35.1

38.8

37.0 b

P-18

2.64

2.62

2.63 bc

28.0

31.6

29.8 d

LSD (0.05) for G

0.17

0.16

0.12

1.1

1.23

0.81

Year (Y) mean

2.68

2.72

NS

33.8 b

35.3 a

***

Level of significance (p<0.05) for treatment interaction

Y x AE

-

-

**

-

-

**

Y x G

-

-

**

-

-

**

AE x G

**

**

**

**

**

**

Y x AE x G

-

-

**

-

-

**

Means followed by different letters within a category are statistically different using the least significant difference test (p<0.05); * and ** represents the significance at (p<0.05) and (p<0.01); NS =Non-significant

 

 

Interaction (AE x year) reflected a higher spike weight in AEP and AEK in year 2. The crop was sown relatively early in season hence, took more days to develop and resulted in healthy spike weight (El-Nakhlawy et al., 2015). Optimum growth conditions contributed to the maximum grain potential and weight (Hazari et al., 2019). Both AEP and AEK showed higher grain weight whereas the AEC did not show the same response. In prolonged winter, the slowly rising temperature of spring (e.g. AEC) during the growing seasons supported grain development to accumulate better assimilates with heavier spike weight (El-Nakhlawy et al., 2015). Interaction (genotypes x year) exhibited marked differences in spike weight in year 2for the maximum genotypes with visible for Pakistan-2013. However, genotypes DN-84 and P-18 did not show a change in grain weight. Spike weight is grain and its biomass, which varied for genotypes (Ding et al., 2020). Differences in grain weight of genotypes related to genetic; i.e. source capacity for sinks. Smaller grain sizes usually affected less spike weight (Alonso et al., 2018). Moreover, changes in flag leaf area also affect grains weight accordingly (Aldesuquy et al., 2018). Changes in grain weight of genotypes are obvious due to grain sizes (Li et al., 2016). Moreover, anthesis timings and conditions also play their role in grain weight of genotype in an environment (Huang et al., 2020).

Treatment interaction (genotypes × AE) was significant for spike length with different trends for the genotypes in different environments (Figure 3b). Spike length was relatively higher for Pirsabak-2005 and DN-84 in AEP to AEK and AEC, whereas, remained the same in Pakistan-2013 and P-12, but a lower spike length was observed in AEK than the rest of twoAE for Pakhtunkhwa-2015 and P-18. The difference in spikes length of genotype is obvious due to arrangements of spikelets and intra-spikelets spaces (Guo et al., 2018). Temperature is a key factor of crop growth and development, which changed the photoperiod and light intensity in an environment (Rezazadeh et al., 2018). Genotypes do respond accordingly for the spike development. Genotypes with no change in spike length can be considered stable for diverse climates. A reduction in spike length with decreasing temperature in coolers climate e.g. AEC limits the genotypes’ cultivation. Contrary to the spike length, spike weight showed a different trend for treatment’s interaction (genotypes × AE) which was due to straw and grain ratio in the spike weight (Russell, 2017). Spike weight of genotypes within 3 environments i.e. AEP, AEK and AEC are shown in Figure 3c. Spike weight of Pirsabak-2005 and P-12 was almost similar in 3 AE, but was higher in AEC for Pakhtunkhuwa-2015 and DN-84, and was lower in AEK for Pakistan-2013. Spike weight is the grain weight and straw (Liu et al., 2017b). As compared to straw, both grain number and sizes are strongly influenced by temperature and hence the spike weight (Mansouri et al., 2018). Genotypes did differ in grain number but were high in their sizes which made significant changes in spike weights. Size and duration of the flag leaf area are critical to contribute in grain number and more significantly in grains weight. Climate changes of an environment did differ and hence their effect on both spike- and grains weight (Gruszka et al., 2020). Moreover, changes in moisture at a critical stage i.e. grains development, also affected grain size and weight (Escalona et al., 2015). Unit grain weight differs in AE for different genotypes (Figure 3d). As explained earlier, all genotypes showed higher grains in AEC due to a suitable climate for grain development. Grain weight in total spike weight is close to 40%. Changes in spike weight in an environment did not match with the grain weight of genotypes. Both water and temperature played a significant role in grain development. Grain growth in cooler climate was more appropriate and hence all genotypes showed better grain weight in the AEC. Contrary to temperature, drought was the most limiting factor (Velu et al., 2016). In the most appropriate temperatures in AEK, drought effect was stronger than AEP (Barlow et al., 2015). Any of the tested genotypes including lines could not perform better in AEK due to drought (Yadav et al., 2020). Genotypes, therefore, showed a decrease in grain weight in the AEK. All factors interaction (genotypes × AE × year) are interesting part of the spike weight and grain weight and have reflected on genotypes accordingly in different environments which were almost the same for both years of the experiments.

Biomass and harvest index

Biomass and harvest indices (HI) showed variations (p<0.05) within genotypes and AE (Table 6). Maximum biomass and HI were obtained in AEC, followed by AEP, and minimum in AEK. According to the literature of Campoy et al. (2020), delay in sowing from optimum time caused a significant loss in biomass and harvest index, which is mainly due to limited sources for the sink. A rapid increase in the temperatures of the reproductive phase of the crop growth limits growth with smaller grains and hence decreases the harvest index (Mukhtarullah and Akmal, 2016). A decrease in biomass is highly associated with drought than rising temperature caused more reduction in grain and thus the harvest index (Zhang et al., 2018). Despite the lower temperature in AEK, lowest biomass from AEP was due to drought stress. Trends of biomass and harvest index were similar but greater in AEC, followed by AEP and lowest in AEK. While average over AE, genotypes’ responses were different in biomass and harvest index. Both lines (P-2 and P-18) were tall and hence showed higher biomass., Pakistan-2013 and Pakhtunkhwa-2015 were similar (p<0.05) in biomasses due to optimum heights (Awan et al., 2017b). Harvest index was high for Pakistan-2013, followed by P-12 and DN-84. The lowest HI was noted for P-2. Changes in biomass are common among genotypes but changes in grain size and weight affect harvest index (Porker et al., 2020). Drought and temperatures affected grain size and number which made differences in harvest index (Pradhan et al., 2019).

 

Table 6: Biomass yield (kg ha-1) and harvest index (%) and of wheat cultivars planted in different Agro-environments.

Agro environment (AE)

Biomass yield (kg ha-1)

Harvest index (%)

2017-18

2018-19

Mean

2017-18

2018-19

Mean

AEP

9823

11683

10753 b

29.93

28.67

29.30 b

AEK

7052

7762

7406 c

25.45

27.97

26.71 c

AEC

13507

12480

12993 a

42.24

40.9

41.57 a

LSD (0.05) for AE

543.9

804.4

432.3

1.53

1.9

1.09

Genotypes (G)

 

 

Pirsabak-2005

9684

10295

9990 de

35.76

34.59

35.17 b

Pakhtunkhwa-2015

10501

10579

10540 bc

31.59

31.62

31.61 d

Pakistan-2013

10291

10740

10515 bc

37.02

36.28

36.65 a

DN-84

9275

9942

9609 e

33.5

32.76

33.13 c

P-2

10580

11249

10915 ab

27.02

27.25

27.13 f

P-12

9698

10545

10121cd

34.71

35.58

35.15 b

P-18

10860

11142

11001a

28.2

29.53

28.86 e

LSD (0.05) for G

612.7

665.6

444.6

2.2

1.93

1.44

Year (Y) mean

10127 b

10642 a

**

32.5

32.5

NS

Level of significance (p<0.05) for treatment interaction

Y x AE

-

-

**

-

-

**

Y x G

-

-

NS

-

-

NS

AE x G

**

**

**

**

**

**

Y x AE x G

-

-

NS

-

-

NS

Means followed by different letters within a category are statistically different using the least significant difference test (p<0.05); * and ** represents the significance at (p<0.05) and (p<0.01); NS =Non-significant

 

 

Interactive effect of treatments (AE x year) showed an increase in biomass in year 2 for AEP and AEK but AEC. The AEC did not differ in sowing dates as well as the crop faced a longer dormancy in winter. Both AEP and AEK biomasses were decreased by delay sowing for a week. The HI in AEP did not differ Temperature, undoubtedly, is the main factor but the drought stress effect cannot be neutralized with temperature (Fahad et al., 2017). The wheat harvest index is around 35% Mild temperatures growth in AEC showed a higher harvest index, whereas, growth in high temperature (AEP) and/or drought with low temperature (AEK) the almost same harvest index. Growth is an outcome of climate. Climate of the AEC was stable with slow rise. Whereas, the climate of AEK was mild but faced drought and the climate of AEP was warm but no drought. Effect of low temperature without stress favors growth with better yield (Chen et al., 2015). Interaction (genotypes x AE) also expressed variation in biomass and harvest index (Figure 4). Some genotypes express better biomass in an environment. Biomass accumulation per unit area and time expressed yield, which correlated for the growth (Zhang and Flottmann, 2016). Longer days resulted in better growth subject to a stable increase in temperature (Magney et al., 2016). It is due to plant accumulate more matter with slow down senescence (Porker et al., 2020). A rapid increase in temperature promoted stem elongation and limited leaf area which also adversely affected leaf number and sizes to change biomass and harvest indices accordingly (Schreel et al., 2019). Early senescence at high temperature or drought decreased biomass, which also limits grain size and weight and hence harvest index (Pradhan et al., 2019). Drought (AEK) as compared to higher temperature (AEP) was observed the same for P-12, P-2, but different for P-18 due to differences in total life cycles and late anthesis. Whereas, rest of the genotypes did not show such a response in harvest index (Akmal et al., 2014). Changes in AE for different genotypes are common, but significant variations due to crop morphology and genotypes’ interaction with environments is obvious.

 

Table 7: Grain heat index (OC) of wheat cultivars planted in different agro-environments.

Agro environment (AE)

Grain heat index (OC)

Mean

2017-18

2018-19

AEP

1.30

1.35

1.33 b

AEK

0.67

0.81

0.74 c

AEC

1.60

1.56

1.58 a

LSD (0.05) for AE

0.08

0.10

0.06

Genotypes (G)

Pirsabak-2005

1.26

1.29

1.27 bc

Pakhtunkhwa-2015

1.21

1.22

1.22 c

Pakistan-2013

1.40

1.40

1.40 a

DN-84

1.13

1.17

1.15 d

P-2

1.05

1.09

1.07 e

P-12

1.22

1.34

1.28 b

P-18

1.09

1.16

1.12 de

LSD (0.05) for G

0.09

0.08

0.06

Year (Y) mean

1.19

1.24

Level of significance (p<0.05) for treatment interaction

Y x AE

*

Y x G

NS

AE x G

**

Y x AE x G

NS

Means followed by different letters within a category are statistically different using the least significant difference test (p<0.05); * and ** represents the significant at (p<0.05) and (p<0.01); NS =Non-significant

 

Grain heat index (OC)

Grain heat index (GHI), the ratio of grain yield (kg ha-1) to accumulated heat units (OC) in an environment, differed for AE with highest in AEC, followed by AEP and lowest in AEK (Table 7). This pattern was found common for two years. Sunshine duration differed for the environment with location and altitude, which affects both photoperiod and its intensity hence affected days to emergence. Thereafter, the dormancy in winter duration. Total growth durations were reported highest in AEC, followed by AEK and lowest in AEP. The AEK was mild in temperature but drought could not compensate for the growth and hence the yield. Plant biomasses due to climate differs and hence reflected a pattern of highest GHI at AEC, followed by AEP and the lowest at AEK. It is obvious that cooler climates with higher altitudes have lower heat intensity, but drought effects were stronger (Arshad et al., 2017) which cannot be compensated with mild days for the crop growth. The GHI was noted lowest in AEK than AEP (Vazquez-Ramirez and Venn, 2021). Altitude is decreased heat intensity, which delays maturity but not under drought (Arshad et al., 2017). Right after sowing, a decreasing temperature in the following days and/or winter snow may extend the crop dormancy but thereafter the rising temperature plays a major role in biomass and yield that affects the harvest index (Hoyle et al., 2015). Our results also confirmed the lowest GHI in AEK with greater effects on yield by drought besides the relatively low temperature as compared to AEP. The GHI in AEC was the highest due to better yield despite the crop remained dormant for the maximum days (Li et al., 2015). Nonetheless, days taken by the crop in AEK were relatively more than AEP but drought effects were not compensated for the crop. Genotypes differ in maturity and for their responses to the climates. The GHI was highest for Pakistan-2013, followed by P-12 and Pirsabak-2005 with the lowest for P-2 due to their life cycles. The GHI of genotypes varied which showed changes in grain yield. The higher GHI of a genotype expressed its suitability for a wider environment. The genotype, with higher GHI, could be ranked suitable for general cultivation in diverse environments. Among treatment interactions (year × AE) and (genotypes × AE), GHI also differed (Figure 4). Crop planted early in year 2 reflected higher yield and hence the GHI Literature has confirmed drought effect stronger than any other factor of production (Daryanto et al., 2016). Interaction (AE × genotypes) revealed diversified trends with stability for Pakistan-2013 but in AEK due to drought. Rest of the genotype did not show a comparable response for GHI for environments. Changes in GHI of genotypes limit their wider cultivation when compared with Pakistan-2013.

Conclusions and Recommendations

The study concludes that genotype x environment interaction is an important parameter to identify the scope of the genotype for future food security. The most appropriate genotype has the potential to perform in diversified environments and should be recommended for a profitable crop to ensure the future food security of the growing population. Contrary to this, a genotype with better performance in an environment should be defined with its limitation for the environment and expression of the growth traits not to risk the food security of the growing population and abrupt climate changes in the environment.

Novelty Statement

Focused on the interactive effects of selected high yielding varieties response for changes in different climates.

Author’s Contribution

Rabia Goher: Conducted the research, prepared and drafted the manuscript.

Inamullah: Proofread and improving the manuscript.

Mohammad Akmal: Supervised the researcha and proofread the manuscript.

Conflict of interest

The authors have declared no conflict of interest.

References

Abdelrahman, M., D.J. Burritt, A. Gupta, H. Tsujimoto and L.S.P. Tran. 2020. Heat stress effects on source sink relationships and metabolome dynamics in wheat. J. Exp. Bot., 71: 543-554. https://doi.org/10.1093/jxb/erz296

Ahmed, M., M.N. Akram, M. Asim, M. Aslam, F. Hassan, S. Higgins, C.O. Stöckle and G. Hoogenboom. 2016. Calibration and validation of APSIM-Wheat and CERES-Wheat for spring wheat under rainfed conditions: Models evaluation and application. Comput. Electron. Agric., 123: 384-401. https://doi.org/10.1016/j.compag.2016.03.015

Ahmad, M., D. Muhammad, M. Mussarat, M. Naseer and M.İ. Shafi. 2018. Spatial variability pattern and mapping of selected soil properties in hilly areas of Hindukush range northern, Pakistan. Eurasian J. Soil Sci. 7: 355-364.

Akmal, M., N. Ahmad, A. Khan, F. Bibi and J. Ali. 2014. Climate change and adaptation–farmer’s experiences from rainfed areas of Pakistan. Climate Change Centre. The Agricultural University, Peshawar: 40.

Akmal, M., A. Shah and J. Ali. 2018. Growth, radiation use efficiency and grain yield of wheat as influenced by nitrogen, tillage, and crop residue management. J. Plant Nutr., 41: 2032-2047. https://doi.org/10.1080/01904167.2018.1485161

Aldesuquy, H., F. Ibraheem and H. Ghanem. 2018. Exogenously supplied salicylic acid and trehalose protect growth vigor, chlorophylls and thylakoid membranes of wheat flag leaf from drought-induced damage. J. Agric. Forest Meteorol. Res., 1: 13-20.

Ali, S., Y. Liu, M. Ishaq, T. Shah, A. Ilyas and I.U. Din. 2017. Climate change and its impact on the yield of major food crops: Evidence from Pakistan. Foods, 6: 39. https://doi.org/10.3390/foods6060039

Almas, M. and R. Saeed. 2000. Fertility status of cultivated land in Azad Kashmir (Pakistan). Pak. J. Biol. Sci. 3: 1851-1852.

Alonso, M.P., P.E. Abbate, N.E. Mirabella, F.A. Merlos, J.S. Panelo and A.C. Pontaroli. 2018. Analysis of sink/source relations in bread wheat recombinant inbred lines and commercial cultivars under a high yield potential environment. Eur. J. Agron., 93: 82-87. https://doi.org/10.1016/j.eja.2017.11.007

Anjum, M.M., M. Arif, M. Riaz, K. Akhtar, S.Q. Zhang and C.P. Zhao. 2021. Performance of Hybrid Wheat Cultivars Facing Deficit Irrigation under Semi-Arid Climate in Pakistan. Agronomy, 11: 1976. https://doi.org/10.3390/agronomy11101976

Anonymous. 2007. Soil Survey of Pakistan. Land resources inventory and agricultural land use plan of Peshawar district. p 102.

Arjona, J.M., C. Royo, S. Dreisigacker, K. Ammar and D. Villegas. 2018. Effect of Ppd-A1 and Ppd-B1 allelic variants on grain number and thousand kernel weight of durum wheat and their impact on final grain yield. Front. Plant Sci., 9: 888. https://doi.org/10.3389/fpls.2018.00888

Arshad, M.S., M. Farooq, F. Asch, J.S. Krishna, P.V. Prasad and K.H. Siddique. 2017. Thermal stress impacts reproductive development and grain yield in rice. Plant Physiol. Biochem., 115: 57-72. https://doi.org/10.1016/j.plaphy.2017.03.011

Asif, M., C.E. Tunc, M.A. Yazici, Y. Tutus, R. Rehman, A. Rehman and L. Ozturk. 2019. Effect of predicted climate change on growth and yield performance of wheat under varied nitrogen and zinc supply. Plant Soil., 434: 231-244. https://doi.org/10.1007/s11104-018-3808-1

Aslam, M.A., M. Ahmed, C.O. Stockle, S.S. Higgins and R. Hayat. 2017. Can growing degree days and photoperiod predict spring wheat phenology? Front. Environ. Sci., 5: 57. https://doi.org/10.3389/fenvs.2017.00057

Awan, K.A., J. Ali and M. Akmal. 2017a. Yield comparison of potential wheat varieties by delay sowing as rainfed crop for Peshawar climate. Sarhad J. Agric., 33: 480-488. https://doi.org/10.17582/journal.sja/2017/33.3.480.488

Awan, K.A., J. Ali and M. Akmal. 2017b. Yield comparison of potential wheat varieties by delay sowing as rainfed crop for peshawar climate. Sarhad J. Agric., 33: 480-488. https://doi.org/10.17582/journal.sja/2017/33.3.480.488

Barlow, K., B. Christy, G. O’leary, P. Riffkin and J. Nuttall. 2015. Simulating the impact of extreme heat and frost events on wheat crop production: A review. Field Crops Res., 171: 109-119. https://doi.org/10.1016/j.fcr.2014.11.010

Bastos, L.M., W. Carciochi, R.P. Lollato, B.R. Jaenisch, C.R. Rezende, R. Schwalbert, P. Vara Prasad, G. Zhang, A.K. Fritz and C. Foster. 2020. Winter wheat yield response to plant density as a function of yield environment and tillering potential: A review and field studies. Front. Plant Sci., 11: 54. https://doi.org/10.3389/fpls.2020.00054

Bhutto, T.A., M. Buriro, N.A. Wahocho, S.A. Wahocho, M.I. Jakhro, Z.A. Abbasi, R. Vistro, F. Abbasi, S. Kumbhar and F.M. Shawani. 2021. Evaluation of wheat cultivars for growth and yield traits under agro-ecological condition of Tandojam. Pak. J. Agric. Sci., 34: 136. https://doi.org/10.17582/journal.pjar/2021/34.1.136.143

Bilgin, O., C. Guzman, İ. Baser, J. Crossa and K.Z. Korkut. 2016. Evaluation of grain yield and quality traits of bread wheat genotypes cultivated in Northwest Turkey. Crop Sci., 56: 73-84. https://doi.org/10.2135/cropsci2015.03.0148

Bisbis, M.B., N. Gruda and M. Blanke. 2018. Potential impacts of climate change on vegetable production and product quality–A review. J. Clean. Prod., 170: 1602-1620. https://doi.org/10.1016/j.jclepro.2017.09.224

Breitkreuz, C., F. Buscot, M. Tarkka and T. Reitz. 2020. Shifts between and among populations of wheat rhizosphere Pseudomonas, Streptomyces and Phyllobacterium suggest consistent phosphate mobilization at different wheat growth stages under abiotic stress. Front. microbiol., 10: 3109. https://doi.org/10.3389/fmicb.2019.03109

Campoy, J., I. Campos, C. Plaza, M. Calera, V. Bodas and A. Calera. 2020. Estimation of harvest index in wheat crops using a remote sensing-based approach. Field Crops Res., 256: 107910. https://doi.org/10.1016/j.fcr.2020.107910

Chen, Y., T. Liu, X. Tian, X. Wang, M. Li, S. Wang and Z. Wang. 2015. Effects of plastic film combined with straw mulch on grain yield and water use efficiency of winter wheat in Loess Plateau. Field Crops Res., 172: 53-58. https://doi.org/10.1016/j.fcr.2014.11.016

Clarke, S.J., K. Lamont, H. Pan, L. Barry, A. Hall and S.Y. Rogiers. 2015. Spring root-zone temperature regulates root growth, nutrient uptake and shoot growth dynamics in grapevines. Aust. J. Grape Wine Res., 21: 479-489. https://doi.org/10.1111/ajgw.12160

Cohen, I., S.I. Zandalinas, C. Huck, F.B. Fritschi and R. Mittler. 2021. Meta-analysis of drought and heat stress combination impact on crop yield and yield components. Physiol. Plant., 171: 66-76. https://doi.org/10.1111/ppl.13203

Daryanto, S., L. Wang and P.A. Jacinthe. 2016. Global synthesis of drought effects on maize and wheat production. PLoS One, 11: e0156362. https://doi.org/10.1371/journal.pone.0156362

Daryanto, S., L. Wang and P.A. Jacinthe. 2017. Global synthesis of drought effects on cereal, legume, tuber and root crops production: A review. Agric. Water Manage., 179: 18-33. https://doi.org/10.1016/j.agwat.2016.04.022

Delcour, I., P. Spanoghe and M. Uyttendaele. 2015. Literature review: Impact of climate change on pesticide use. Int. Food Res. J., 68: 7-15. https://doi.org/10.1016/j.foodres.2014.09.030

Ding, J., P. Liang, P. Wu, M. Zhu, C. Li, X. Zhu, D. Gao, Y. Chen and W. Guo. 2020. Effects of waterlogging on grain yield and associated traits of historic wheat cultivars in the middle and lower reaches of the Yangtze River, China. Field Crops Res., 246: 107695. https://doi.org/10.1016/j.fcr.2019.107695

Dong, B., H. Yang, H. Liu, Y. Qiao, M. Zhang, Y. Wang, Z. Xie and M. Liu. 2019. Effects of shading stress on grain number, yield, and photosynthesis during early reproductive growth in wheat. Crop Sci., 59: 363-378. https://doi.org/10.2135/cropsci2018.06.0396

Dos-Santos, H.O., R.C. Vasconcellos, B. de Pauli, R.M. Pires, E.M. Pereira, G.V. Tirelli and É. Pinho. 2019. Effect of Soil Temperature in the Emergence of Maize Seeds. J. Agric. Sci., 11: 479-484. https://doi.org/10.5539/jas.v11n1p479

Dowla, M.N.U., I. Edwards, G. O’Hara, S. Islam and W. Ma. 2018. Developing wheat for improved yield and adaptation under a changing climate: optimization of a few key genes. Engineering, 4: 514-522. https://doi.org/10.1016/j.eng.2018.06.005

Duan, S., Z. Zhao, Y. Qiao, C. Cui, A. Morgunov, A.G. Condon, L. Chen and Y.-G. Hu. 2020. GAR dwarf gene Rht14 reduced plant height and affected agronomic traits in durum wheat (Triticum durum L). Field Crops Res., 248: 107721. https://doi.org/10.1016/j.fcr.2020.107721

El-Nakhlawy, F.S., F. Alghabari and M.Z. Ihsan. 2015. Response of wheat genotypes to planting dates in the arid region. Sci. Agric., 10: 59-63. https://doi.org/10.15192/PSCP.SA.2015.10.2.5963

Eller, F., B. Hyldgaard, S.M. Driever and C.O. Ottosen. 2020. Inherent trait differences explain wheat cultivar responses to climate factor interactions: New insights for more robust crop modelling. Glob. Change Biol., 26: 5965-5978. https://doi.org/10.1111/gcb.15278

Escalona, J., J. Bota and H. Medrano. 2015. Distribution of leaf photosynthesis and transpiration within grapevine canopies under different drought conditions. Vitis - J. Grapevine Res., 42: 57.

Fahad, S., A.A. Bajwa, U. Nazir, S.A. Anjum, A. Farooq, A. Zohaib, S. Sadia, W. Nasim, S. Adkins and S. Saud. 2017. Crop production under drought and heat stress: plant responses and management options. Front. Plant Sci., 8: 1147. https://doi.org/10.3389/fpls.2017.01147

FAO. 2020. Food outlook–biannual report on global food markets: June 2020. Food Outlook, Rome, Italy.

Flohr, B., J. Hunt, J. Kirkegaard, J. Evans, B. Trevaskis, A. Zwart, A. Swan, A. Fletcher and B. Rheinheimer. 2018. Fast winter wheat phenology can stabilise flowering date and maximise grain yield in semi-arid Mediterranean and temperate environments. Field Crops Res., 223: 12-25. https://doi.org/10.1016/j.fcr.2018.03.021

Ghosh, A., A.K. Pandey, M. Agrawal and S.B. Agrawal. 2020. Assessment of growth, physiological, and yield attributes of wheat cultivar HD 2967 under elevated ozone exposure adopting timely and delayed sowing conditions. Environ. Sci. Pollut. Res. Int., 27: 17205-17220. https://doi.org/10.1007/s11356-020-08325-y

Girousse, C., L. Inchboard, J.-C. Deswarte and K. Chenu. 2021. How does post-flowering heat impact grain growth and its determining processes in wheat. J. Exp. Bot., 72: 6596-6610. https://doi.org/10.1093/jxb/erab282

Gleason, S.M., D.R. Wiggans, C.A. Bliss, L.H. Comas, M. Cooper, K.C. DeJonge, J.S. Young and H. Zhang. 2017. Coordinated decline in photosynthesis and hydraulic conductance during drought stress in Zea mays. Flora, 227: 1-9. https://doi.org/10.1016/j.flora.2016.11.017

Gobin, A. 2018. Weather related risks in Belgian arable agriculture. Agric. Syst., 159: 225-236. https://doi.org/10.1016/j.agsy.2017.06.009

Gruszka, D., A. Janeczko, J. Puła, A. Lepiarczyk and E. Pociecha. 2020. Impact of Drought Exerted during Spike Development on Tillering, Yield Parameters and Grain Chemical Composition in Semi-Dwarf Barley Mutants Deficient in the Brassinosteroid Metabolism. Agronomy, 10: 1595. https://doi.org/10.3390/agronomy10101595

Guo, Z., Y. Zhao, M.S. Röder, J.C. Reif, M.W. Ganal, D. Chen and T. Schnurbusch. 2018. Manipulation and prediction of spike morphology traits for the improvement of grain yield in wheat. Sci. Rep., 8: 1-10. https://doi.org/10.1038/s41598-018-31977-3

Hatfield, J.L. and J.H. Prueger. 2015. Temperature extremes: Effect on plant growth and development. Weather. Clim. Extremes., 10: 4-10. https://doi.org/10.1016/j.wace.2015.08.001

Hazari, S., R. Mondal and S. Das. 2019. Performance of wheat genotypes under different irrigational approaches in the Terai agro ecological condition. J. Pharm. Innov., 8: 01-04.

He, L., N. Jin and Q. Yu. 2020. Impacts of climate change and crop management practices on soybean phenology changes in China. Sci.Total Environ., 707: 135638. https://doi.org/10.1016/j.scitotenv.2019.135638

Hoyle, G.L., K.J. Steadman, R.B. Good, E.J. McIntosh, L.M. Galea and A.B. Nicotra. 2015. Seed germination strategies: an evolutionary trajectory independent of vegetative functional traits. Front. Plant Sci., 6: 731. https://doi.org/10.3389/fpls.2015.00731

Huang, M., S. Fang, F. Cao, J. Chen, S. Shan, Y. Liu, T. Lei, A. Tian, Z. Tao and Y. Zou. 2020. Early sowing increases grain yield of machine-transplanted late-season rice under single-seed sowing. Field Crops Res., 253: 107832. https://doi.org/10.1016/j.fcr.2020.107832

Hyles, J., M.T. Bloomfield, J.R. Hunt, R.M. Trethowan and B. Trevaskis. 2020. Phenology and related traits for wheat adaptation. Heredity, 125: 417-430. https://doi.org/10.1038/s41437-020-0320-1

IPCC. 2012. Managing the risks of extreme events and disasters to advance climate change adaptation: A special report of working groups I and II of the Intergovernmental Panel on Climate Change. C.B. Field, V. Barros, T.F. Stocker and Q. Dahe (eds). Cambridge University Press, New York, USA.

Javadipour, Z., H. Balouchi, M.M. Dehnavi and A. Yadavi. 2019. Roles of methyl jasmonate in improving growth and yield of two varieties of bread wheat (Triticum aestivum L.) under different irrigation regimes. Agric. Water Manag., 222: 336-345. https://doi.org/10.1016/j.agwat.2019.06.011

Kajla, M., V. Yadav, R. Chhokar and R. Sharma. 2015. Management practices to mitigate the impact of high temperature on wheat. J. Wheat Res., 7: 1-12. https://doi.org/10.31018/jans.v7i2.733

Khan, A., M. Ahmad, M. Ahmed and M. Iftikhar Hussain. 2021. Rising atmospheric temperature impact on wheat and thermotolerance strategies. Plants, 10: 43. https://doi.org/10.3390/plants10010043

Klepeckas, M., I. Januskaitienė, I. Vagusevicienė and R. Juknys. 2020. Effects of different sowing time to phenology and yield of winter wheat. Agric. Food Sci., 29: 346-358. https://doi.org/10.23986/afsci.90013

Li, X., H.B. Topbjerg, D. Jiang and F. Liu. 2015. Drought priming at vegetative stage improves the antioxidant capacity and photosynthesis performance of wheat exposed to a short-term low temperature stress at jointing stage. Plant Soil., 393: 307-318. https://doi.org/10.1007/s11104-015-2499-0

Li, Y., Z. Cui, Y. Ni, M. Zheng, D. Yang, M. Jin, J. Chen, Z. Wang and Y. Yin. 2016. Plant density effect on grain number and weight of two winter wheat cultivars at different spikelet and grain positions. PLoS One. 11: e0155351. https://doi.org/10.1371/journal.pone.0155351

Lippmann, R., S. Babben, A. Menger, C. Delker and M. Quint. 2019. Development of wild and cultivated plants under global warming conditions. Curr. Biol., 29: R1326-R1338. https://doi.org/10.1016/j.cub.2019.10.016

Liu, W., G. Liu, Y. Yang, X. Guo, B. Ming, R. Xie, Y. Liu, K. Wang, P. Hou and S. Li. 2021. Spatial variation of maize height morphological traits for the same cultivars at a large agroecological scale. Eur. J. Agron., 130: 126349. https://doi.org/10.1016/j.eja.2021.126349

Liu, X., D.L. Lister, Z. Zhao, C.A. Petrie, X. Zeng, P.J. Jones, R.A. Staff, A.K. Pokharia, J. Bates and R.N. Singh. 2017a. Journey to the east: Diverse routes and variable flowering times for wheat and barley en route to prehistoric China. PLoS One. 12: e0187405. https://doi.org/10.1371/journal.pone.0187405

Liu, X., Y. Ren, C. Gao, Z. Yan and Q. Li. 2017b. Compensation effect of winter wheat grain yield reduction under straw mulching in wide-precision planting in the North China Plain. Sci. Rep., 7: 1-9. https://doi.org/10.1038/s41598-017-00391-6

Maeoka, R.E., V.O. Sadras, I.A. Ciampitti, D.R. Diaz, A.K. Fritz and R.P. Lollato. 2020. Changes in the phenotype of winter wheat varieties released between 1920 and 2016 in response to in-furrow fertilizer: Biomass allocation, yield, and grain protein concentration. Front. Plant Sci., 10: 1786. https://doi.org/10.3389/fpls.2019.01786

Magney, T.S., J.U. Eitel, D.R. Huggins and L.A. Vierling. 2016. Proximal NDVI derived phenology improves in-season predictions of wheat quantity and quality. Agric. For. Meteorol., 217: 46-60. https://doi.org/10.1016/j.agrformet.2015.11.009

Mansouri, A., B. Oudjehih, A. Benbelkacem, Z.E.A. Fellahi and H. Bouzerzour. 2018. Variation and relationships among agronomic traits in durum wheat (Triticum turgidum L.) Thell. Ssp. Turgidum conv. Durum (Desf.) Mackey] under south Mediterranean growth conditions: Stepwise and path analyses. Int. J. Agron., 2018. https://doi.org/10.1155/2018/8191749

Meleha, A.M., A. Hassan, M.A. El-Bialy and M.A. El-Mansoury. 2020. Effect of planting dates and planting methods on water relations of wheat. Int. J. Agron., 2020. https://doi.org/10.1155/2020/8864143

Miersch, S., A. Gertz, F. Breuer, A. Schierholt and H.C. Becker. 2016. Influence of the semi-dwarf growth type on seed yield and agronomic parameters at low and high nitrogen fertilization in winter oilseed rape. Crop Sci., 56: 1573-1585. https://doi.org/10.2135/cropsci2015.09.0554

Mishra, D., S. Shekhar, L. Agrawal, S. Chakraborty and N. Chakraborty. 2017. Cultivar-specific high temperature stress responses in bread wheat (Triticum aestivum L.) associated with physicochemical traits and defense pathways. Food Chem., 221: 1077-1087. https://doi.org/10.1016/j.foodchem.2016.11.053

Mukhtarullah, J.A. and M. Akmal. 2016. Yield comparison of some improved wheat varieties under different sowings dates as rainfed crop. Sarhad J. Agric., 32: 89-95. https://doi.org/10.17582/journal.sja/2016/32.2.89.95

Munsif, F., M. Arif, K. Ali, M. Khan, S. Munir and F. Rasul. 2016. Evaluation of various morpho-physiological and growth traits of dual purpose wheat under early sowing dates. Pak. J. Bot., 48: 81-88.

Munsif, F., M. Arif, M. Jan, K. Ali and M. Khan. 2015. Influence of sowing dates on phenological development and yield of dual purpose wheat cultivars. Pak. J. Bot., 47: 83-88.

O’Brien, T., M. Sammut, J. Lee and M. Smart. 2019. The Vascular System of the Wheat Spikelet. Paper presented at the Fourth International Symposium on Pre-Harvest Sprouting in Cereals. https://doi.org/10.1201/9780429038471-33

Osei, M.K., B. Annor, J. Adjebeng-Danquah, A. Danquah, E. Danquah, E. Blay and H. Adu-Dapaah 2018. Genotype× Environment interaction: a prerequisite for tomato variety development. In: Recent Advances in Tomato Breeding and Production. T.N. Seloame and D. Agyemang (eds), pp: 71-93. IntechOpen, London UK.

Pandey, M., J. Shrestha, S. Subedi and K.K. Shah. 2020. Role of nutrients in wheat: a review. TRAB, 1: 18-23. https://doi.org/10.26480/trab.01.2020.18.23

Phan, T.N., M. Kappas and T.P. Tran. 2018. Land surface temperature variation due to changes in elevation in northwest Vietnam. Climate, 6: 28. https://doi.org/10.3390/cli6020028

Phung, H.D., D. Sugiura, H. Sunohara, D. Makihara, M. Kondo, S. Nishiuchi and K. Doi. 2019. QTL analysis for carbon assimilate translocation-related traits during maturity in rice (Oryza sativa L.). Breed. Sci., 18203. https://doi.org/10.1270/jsbbs.18203

Porker, K., M. Straight and J.R. Hunt. 2020. Evaluation of G× E× M Interactions to increase harvest index and yield of early sown wheat. Front. Plant Sci., 11: 994. https://doi.org/10.3389/fpls.2020.00994

Pradhan, S., M.A. Babar, K. Robbins, G. Bai, R.E. Mason, J. Khan, D. Shahi, M. Avci, J. Guo and M. Maksud Hossain. 2019. Understanding the genetic basis of spike fertility to improve grain number, harvest index, and grain yield in wheat under high temperature stress environments. Front. Plant Sci., 10: 1481. https://doi.org/10.3389/fpls.2019.01481

Rademacher, W. 2015. Plant growth regulators: backgrounds and uses in plant production. J. Plant Growth Regul., 34: 845-872. https://doi.org/10.1007/s00344-015-9541-6

Raza, A., A. Razzaq, S.S. Mehmood, X. Zou, X. Zhang, Y. Lv and J. Xu. 2019. Impact of climate change on crops adaptation and strategies to tackle its outcome: A review. Plants, 8: 34. https://doi.org/10.3390/plants8020034

Renzi, J.P., M. Duchoslav, J. Brus, I. Hradilova, V. Pechanec, T. Václavek, J. Machalova, K. Hron, J. Verdier and P. Smykal. 2020. Physical dormancy release in Medicago truncatula seeds is related to environmental variations. Plants, 9: 503. https://doi.org/10.3390/plants9040503

Rezaei, E.E., S. Siebert, H. Hüging and F. Ewert. 2018. Climate change effect on wheat phenology depends on cultivar change. Sci. Rep., 8: 1-10. https://doi.org/10.1038/s41598-018-23101-2

Rezazadeh, A., R.L. Harkess and T. Telmadarrehei. 2018. The effect of light intensity and temperature on flowering and morphology of potted red firespike. Horticulturae, 4: 36. https://doi.org/10.3390/horticulturae4040036

Russell, K. 2017. Genotype× Environment× Management: Implications for selection to heat stress tolerance and nitrogen use efficiency in Soft Red Winter Wheat. College of Agriculture, Food, and EnvironmenT, University of Kentucky.

Saatkamp, A., A. Cochrane, L. Commander, L.K. Guja, B. Jimenez-Alfaro, J. Larson, A. Nicotra, P. Poschlod, F.A. Silveira and A.T. Cross. 2019. A research agenda for seed-trait functional ecology. New Phytol., 221: 1764-1775. https://doi.org/10.1111/nph.15502

Sattar, A., M.M. Iqbal, A. Areeb, Z. Ahmed, M. Irfan, R.N. Shabbir, G. Aishia and S. Hussain. 2015. Genotypic variations in wheat for phenology and accumulative heat unit under different sowing times. J. Environ. Agric. Sci., 2: 1-8.

Schreel, J.D., B.A. Van de Wal, P. Hervé-Fernandez, P. Boeckx and K. Steppe. 2019. Hydraulic redistribution of foliar absorbed water causes turgor-driven growth in mangrove seedlings. Plant Cell Environ., 42: 2437-2447. https://doi.org/10.1111/pce.13556

Shah, H., C. Siderius and P. Hellegers. 2021. Limitations to adjusting growing periods in different agroecological zones of Pakistan. Agric. Syst., 192: 103184. https://doi.org/10.1016/j.agsy.2021.103184

Shi, H., B. Wang, P. Yang, Y. Li and F. Miao. 2016. Differences in sugar accumulation and mobilization between sequential and non-sequential senescence wheat cultivars under natural and drought conditions. PLoS One. 11: e0166155. https://doi.org/10.1371/journal.pone.0166155

Steel, R.G.D., J.H. Torrie and D.A. Dickey. 1997. Principles and procedures of statistics: a biometrical approach. 352-358. McGraw-Hill, New York, USA.

Steinfort, U., S. Fukai, B. Trevaskis, D. Glassop, A. Chan and M.F. Dreccer. 2017. Vernalisation and photoperiod sensitivity in wheat: the response of floret fertility and grain number is affected by vernalisation status. Field Crops Res., 203: 243-255. https://doi.org/10.1016/j.fcr.2016.10.013

Vazquez-Ramirez, J. and S.E. Venn. 2021. Seeds and Seedlings in a Changing World: A Systematic Review and Meta-Analysis from High Altitude and High Latitude Ecosystems. Plants, 10: 768. https://doi.org/10.3390/plants10040768

Velu, G., C. Guzman, S. Mondal, J.E. Autrique, J. Huerta and R.P. Singh. 2016. Effect of drought and elevated temperature on grain zinc and iron concentrations in CIMMYT spring wheat. J. Cereal Sci., 69: 182-186. https://doi.org/10.1016/j.jcs.2016.03.006

Wang, B., C. Liu, D. Zhang, C. He, J. Zhang and Z. Li. 2019. Effects of maize organ-specific drought stress response on yields from transcriptome analysis. BMC Plant Biol., 19: 1-19. https://doi.org/10.1186/s12870-019-1941-5

Wang, Q.-L., J.-H. Chen, N.-Y. He and F.-Q. Guo. 2018a. Metabolic reprogramming in chloroplasts under heat stress in plants. Int. J. Mol. Sci., 19: 849. https://doi.org/10.3390/ijms19030849

Wang, W., J. Simmonds, Q. Pan, D. Davidson, F. He, A. Battal, A. Akhunova, H.N. Trick, C. Uauy and E. Akhunov. 2018b. Gene editing and mutagenesis reveal inter-cultivar differences and additivity in the contribution of TaGW2 homoeologues to grain size and weight in wheat. Theor. Appl. Genet., 131: 2463-2475. https://doi.org/10.1007/s00122-018-3166-7

Yadav, S., P. Modi, A. Dave, A. Vijapura, D. Patel and M. Patel 2020. Effect of abiotic stress on crops. In: Sustainable Crop Production. H. Mirza, F. Masayuki, C.M.T.F. Marcelo and A.R.N. Thiago (eds), Pp: 3-24. IntechOpen, London, UK. https://doi.org/10.5772/intechopen.88434

Yu, H., Q. Zhang, P. Sun and C. Song. 2018. Impact of droughts on winter wheat yield in different growth stages during 2001–2016 in Eastern China. nt. J. Disaster Risk Sci., 9: 376-391. https://doi.org/10.1007/s13753-018-0187-4

Zahra, N., A. Wahid, M.B. Hafeez, A. Ullah, K.H. Siddique and M. Farooq. 2021. Grain development in wheat under combined heat and drought stress: plant responses and management. Environ. Exp. Bot., 104517. https://doi.org/10.1016/j.envexpbot.2021.104517

Zandalinas, S.I., R. Mittler, D. Balfagón, V. Arbona and A. Gómez-Cadenas. 2018. Plant adaptations to the combination of drought and high temperatures. Physiol. Plant., 162: 2-12. https://doi.org/10.1111/ppl.12540

Zhang, H. and S. Flottmann. 2016. Seed yield of canola (Brassica napus L.) is determined primarily by biomass in a high-yielding environment. Crop Pasture Sci., 67: 369-380. https://doi.org/10.1071/CP15236

Zhang, J., S. Zhang, M. Cheng, H. Jiang, X. Zhang, C. Peng, X. Lu, M. Zhang and J. Jin. 2018. Effect of drought on agronomic traits of rice and wheat: A meta-analysis. Int. J. Environ. Res. Public Health, 15: 839. https://doi.org/10.3390/ijerph15050839

Zhao, C., B. Liu, S. Piao, X. Wang, D.B. Lobell, Y. Huang, M. Huang, Y. Yao, S. Bassu and P. Ciais. 2017. Temperature increase reduces global yields of major crops in four independent estimates. Proc. Natl. Acad. Sci., USA. 114: 9326-9331. https://doi.org/10.1073/pnas.1701762114

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Pakistan J. Zool., Vol. 56, Iss. 6, pp. 2501-3000

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