Selection under salt stress conditions in F3 and F4 generations of wheat (Triticum aestivum L.)

Document Type : Original Article

Authors

Department of Agronomy, Faculty of Agriculture, Al-Azhar University, Cairo, Egypt

Abstract

This study was carried out during two winter successive seasons 2017/18 and 2018/19 to determine the effect of salinity stress on yield and yield components in F3 and F4 segregating populations of the two bread wheat crosses (Sakha 93 x Gemmaiza 9) Cross1 and (Sakha 93 x Giza 168) Cross II. The results showed highly significant differences between means of the two crosses and families for most the traits in F3, and 100 grain weight in F4 generations. The differences between salinity levels were highly significant for all traits in both F3 and F4 generations. The interaction between crosses × families was highly significant for all traits, except for number of grains/spikes in F3, while it was highly significant for number of grains per spike and weight of 100 grain in F4. The interaction between crosses × salinity levels was highly significant for all traits in F3, while it was highly significant for weight of 100 grain in F4. As for the interaction between families, salinity levels were highly significant for most traits in F3, while F4 were highly significant for weight of 100 grain. The interaction between crosses × families × salinity levels, were highly significant for most traits in F3, while in F4 were highly significant for weight of 100 grain. Highest values of H and GA were found for grain yield / plant and weight of 100 grain under salinity conditions in F4 generation. These traits would be improved by direct selection under saline soil conditions.

Keywords


Selection under salt stress conditions in F3 and F4 generations of wheat (Triticum aestivum L.)

M. N. Khamees *, H. E. Yassien, M. A. Hager, and E. I. Zaazaa

Department of Agronomy, Faculty of Agriculture, Al-Azhar University, Cairo, Egypt

*Corresponding author E-mail: Mohamed.abdeltawab@azhar.edu.eg (M. Khamees)

ABSTRACT

This study was carried out during two winter successive seasons 2017/18 and 2018/19 to determine the effect of salinity stress on yield and yield components in F3 and F4 segregating populations of the two bread wheat crosses (Sakha 93 x Gemmaiza 9) Cross1 and (Sakha 93 x Giza 168) Cross II. The results showed highly significant differences between means of the two crosses and families for most the traits in F3, and 100 grain weight in F4 generations. The differences between salinity levels were highly significant for all traits in both F3 and F4 generations. The interaction between crosses × families was highly significant for all traits, except for number of grains/spikes in F3, while it was highly significant for number of grains per spike and weight of 100 grain in F4. The interaction between crosses × salinity levels was highly significant for all traits in F3, while it was highly significant for weight of 100 grain in F4. As for the interaction between families, salinity levels were highly significant for most traits in F3, while F4 were highly significant for weight of 100 grain. The interaction between crosses × families × salinity levels, were highly significant for most traits in F3, while in F4 were highly significant for weight of 100 grain. Highest values of H and GA were found for grain yield / plant and weight of 100 grain under salinity conditions in F4 generation. These traits would be improved by direct selection under saline soil conditions.

Keywords: Genetical variability, Selection, Salinity, Wheat.

 

INTRODUCTION

Wheat (Triticum aestivum L.) is one of the most important and strategic cereal crops in Egypt and all over the world which belongs Poaceae family which is constituted by out-standing group of food plants. The wheat breeders are concentrating to improve the yield potential of wheat by developing new varieties. In Egypt, 3.00 million feddan of wheat are planted, this area produces 8.10 million tons and the consumption is about 16.768 million tons (CAPMAS2017). This indicates that wheat consumption in Egypt has exceeded domestic production, thus requiring the importation of about 8.66 million tonsannually. This constituted a high level of import, and food security becoming a serious problem. Therefore, it is necessary to increase wheat production to realize the food security.

Salinity is one of the major factors reducing plant growth and productivity worldwide, and affects about 7% of the world’s total land area (Flowers et al., 1997). Egypt is one of the countries that suffer from severe salinity problems. For example, 33% of the cultivated lands, which comprises only 3% of total land area in Egypt, is already salinized due to low precipitation (<25mM annual rainfall) and irrigation with saline water (Ghassemi et al., 1995). Wheat is the most important and widely adapted food cereal in Egypt. However, Egypt supplies only 40% of its annual domestic demand for wheat (Salam, 2002). Therefore, it is necessary to increase wheat production in Egypt by raising the wheat grain yield. Obviously, the most efficient way to increase wheat yield in Egypt is to improve the salt tolerance of wheat genotypes Epstein et al. (1980), Shannon. (1997) and Pervaiz et al., (2002).

Heritability plays a predictive role in breeding, expressing the reliability of phenotype as a guide to its breeding value. It is understood that only the phenotypical value can be measured directly, while breeding values of individuals are derived from appropriate analysis. It is the breeding value, which determines how much of the phenotype would be passed onto the next generation (Rehman and Alam 1994). High genetic advance coupled with high heritability estimates offers the most effective condition for selection (Larik, et al., 2000). Thus, genetic advance is yet another important selection parameter that aids breeder in a selection program (Shukla, et al., 2004). Phenotypic and genotypic variance, heritability and genetic advance have been used to assess the magnitude of variance in wheat breeding material (Bhutta, 2006). Kumar et al., (2003) reported high heritability coupled with high genetic advance for plant height, number of spikelets per spike, 1000 -grain weight and number of tillers per plant in wheat. The high heritability indicates that the characters were less influenced by environment. The similar results were also found by Yadav et al., (2003) and Gupta et al., (2004).

The main objectives of this study:

Studies the effects of salinity levels for two crosses populations (F3 and F4) for all the studied characters.

Estimate genetic parameters (σ2g , σ2 ph , σ2e , PCV, GCV, Hand GA %) for F3 and F4 populations.

MATERIALS AND METHODS

This experiment was conducted at the Experimental Farm of Agronomy Department, Faculty of Agriculture, Al-Azhar University Nasr City Cairo, Egypt during two successive seasons of 2017/18 and 2018/19.

The experimental materials comprised of two bread wheat crosses, (Sakha 93 × Gemmiza 9) and (Sakha 93 × Giza 168), which were installed in a previous study of three varieties of wheat. The plant materials (F1 and F2) were obtained from Khamees, (2016). Agronomy Dept., Fac.of Agric., Al-Azhar Univ. These materials were tested for salinity tolerance by grown under salinity levels (control, 6000, 9000 and 12000 ppm), which were farming in plastic pots of 30 cm diameter, 25 cm deep and the sand soil weight in each pot was 12 kg. Each plot contained of 8 plants. Salinity concentration setting throw determine (Leaching Requirement) according to the following equation:

L.R= EC (irrigation water) / (EC water drainage) ×100

In 2017/18 growing season, the seeds of tolerant and high yielding plants for the two crosses and their parents which selected under each salinity level in F2 seeds were planted as families (a family for each plant) to obtain F3 families.

In 2018/19 growing season, the selected plant seeds which were salinity tolerant for all salinity levels under study from F3 generation of the two crosses and their parents. They were planted to obtain F4 plants and evaluated as families under all salinity levels (a family for each plant). 

The crosses and their parents were evaluated in a randomized complete block design (RCBD) with three replicates for each salinity level.

Data were recorded on individual guarded plants for number of spikes/plant, number of grains/spike, 100- grain weight (g) and grain yield/plant (g).

Statistical analysis and genetical parameters:

Data were estimated analysis according to Snedecor and Cochran (1980) the means differences were tested against the least significant difference (L.S.D) at 5% level of probability according to Gomez and Gomez (1984).

Analysis variance and expectation of mean squares, for source of variation are shown in Table (1)

The variance components were estimated according to (Millar et al 1959) as follows:

Genotypes (б2g) = (M5+M2-M3-M4)/rbc

Genotypes × families (б2gb) = (M4-M2)/rc

Genotypes ×concentration (б2gc) = (M3-M2)/rb

Genotypes × families × concentration (б2gbc) = (M2-M1)/r

Error (б2e ) = M1

The importance of genotypic component of variance in relation to phenotypic variance (б2ph) is as follows:

б2ph = б2g + 2gb/b) +2gc/c)+2gbc/bc)+2e/gbr)

Heritability

The estimates of broad-sense heritability were computed as suggested by Allard (1960).

H2b = б2g / б2ph ×100

Phenotypic and genotypic coefficient of variation

Phenotypic (PCV) and genotypic (GCV) coefficient of variation were estimated using the formula suggested by Burton (1952) as follows:                                 

PCV = √ б2ph / -x ×100

GCV = √б2g / -x × 100

Genetic advance

Genetic advance (GA) (10 % selection intensity) as percent means and genetic advance as percentage of mean (GA %) by Lush (1949) and Johnson et al. (1955).

GA = K ×√ б2ph × h2b    GA % = GA / x- × 100

 

RESULTS AND DISCUSSION

Analysis of variance and average performance.

Analysis of variance and average performance. Average performance for four characters treated by salinity levels.

Analysis of variance

Analysis of variance for all the traits in F3 and F4 families are shown in Table (2) revealed high significant differences between two crosses for all traits in F3 and non-significant differences between crosses for all traits, except 100-grain weight (g) in F4. Moreover, high significant differences are shown between families, except number of grains/spikes in F3, while in F4 families were non-significant differences between them except, for 100-grain weight (g). The differences between salinity levels were highly significant for all studied traits in F3 and F4 generations. On the other hand there were high significant differences for interaction (crosses× families) for all the studied traits, except number of grains/spike in F3, and number of spikes/plant and grain yield /plant (g) in F4 generation. Highly significant differences were shown for interaction AC (crosses× salinity levels) for all the studied traits in F3, but they were non-significant differences for all the traits, except 100-grain weight (g) in F4. Highly significant differences were observed for interaction BC (families× salinity levels) for all traits, except number of grains/spikes in F3, while they were non-significant differences for all the traits, except 100-grain weight (g) in F4. The interaction between ABC (crosses× families× salinity levels) were highly significant for all the traits, except number of grains/spikes in F3, and non-significant for all the traits, except for 100-grain weight (g) in F4. This indicated that these populations are highly diversified for their performance and selection can be performed for various traits.

Average performance:

Average performance was variable according to the incidence of crosses, families, salinity levels, and interaction between them.

Number of spikes/plant:

Thistrait is presented in Table (3). Results indicated highly significant differences between two crosses in F3. while the differences between crosses in F4 were non-significant.

As for the families, results indicated high significant differences between families in Table (2). Family No. 8 gave the highest mean value (1.680),while family No. 10 gave the lowest one (1.297) in F3. The differences between families in F4, were non-significant differences.

As for salinity levels, results revealed high significant differences between salinity levels, control gave the highest value (1.968) and no significant differences between 6000 and 9000 ppm (1.303) and (1.297) respectively, while the salinity level 12000 ppm recorded the lowest value (1.199) in F3. In F4 generation the differences between salinity levels were non-significant Table (2).

Furthermore, the interaction between crosses× families were high significant differences, the family No.8 gave the highest mean value (1.802) for cross І, while, family No. 1 recorded the lowest value (1.245) for cross П in F3 generation, the interaction between crosses× families in F4 was non-significant.

The interaction between crosses × salinity levels were highly significant in F3, cross І recorded the highest mean value (2.298) under control, while cross І recorded the lowest value (1.184) under 12000 ppm. These results agreed with those reported by EL-Amin et al. (2011) and Aziza, M. Hassanein (2016). The interaction in F4 was non-significant.

The interactions between families × salinity levels in F3 were high significant. The family No. 8 gave the highest value (2.430) under control, while the family No.1 and No. 9 gave the lowest value (1.000) under salinity level 12000.

The family No. 1 for F4 gave the highest mean value (1.733) under control, while all families under 12000 ppm recorded the lowest values (1.000).

The interaction between crosses × families × salinity in F3 generation for number of spikes per plant were highly significant and recorded the highest mean values (3.260) for cross І in family No. 8 under control. The families No. 6, No. 8 and No. 9 in cross І recorded the lowest value (1.000) in F3 generation, while, the average performance for families No. 1, No. 4, No. 5 and No. 9 under the salinity level 12000 ppm in cross П recorded the same value (1.000), the interaction between crosses × families × salinity levels were non-significant in F4 generation.

Number of grains/spike:

This trait is presented in Table (4). Results indicated high significant differences between crosses in F3. Cross П gave the highest mean value (39.136), while cross І gave the lowest one (34.014) and the differences between crosses in F4 were non-significant

Concerning the families, results indicated non-significant differences between families in F3 and F4.

In F3, results revealed high significant differences between salinity levels and the control gave the highest value (52.387). On the other hand, the salinity level 12000 ppm recorded the lowest value (28.527) and there were no significant differences between 6000, 9000 ppm (32.713) and (32.672). These results are in agreement with Ahmad et al. (2013). In Fgeneration, the differences between salinity levels were high and significant. The control level gave the highest value (50.328). On the other hand, the salinity level 12000 ppm recorded the lowest value (30.889).

Moreover, the interaction between crosses and families were non-significant in F3, while, the interaction between crosses and families in F4 were highly significant. Family No. 2 gave the highest mean value (41.948) for cross П, while family 1 in cross І recorded the lowest mean value (30.122).

The interaction between crosses and salinity levels was highly significant in F3. Cross П recorded the highest mean value (52.713) under control. On the other hand, the cross І recorded the lowest value (25.710) under level 12000 ppm. These results are in agreement with EL-Amin et al. (2011) as he found that the interaction in F4 was non-significant.

The interaction between families and salinity levels in F3 were high significant.  The family No. 3 gave the highest mean value (55.267) under control, while family No. 9 recorded the lowest value (20.795) under level 12000 ppm in F3, but in F4 were non-significant.

The interaction between (crosses, families and salinity) were non-significant differences in F3 and F4.

100- grain weight:

It is presented in Table (5). Results showed, high significant differences between crosses in F3. Cross П gave the highest mean value (2.214), while cross І gave the lowest one (2.026). The differences between crosses in F4 were high significant.  Cross П gave the highest mean value (2.149), while, cross І gave the lowest mean value (1.954).

As for the families, results indicated high significant differences between families.  Families No. 2 and No. 3 gave the highest values (2.399 and 2.373), respectively, while Family No. 10 gave the lowest mean value (1.862) in F3. In F4, results indicated high significant differences between families. Family No. 2 gave the highest value (2.135), while Family No. 3 gave the lowest mean value (1.887).

As for the salinity levels, the results revealed high significant differences between salinity levels, the control gave the highest value (3.206), but the salinity level 6000 ppm recorded the lowest value (1.632) in F3. F4 generation showed high significant differences between salinity levels. The control gave the highest value (3.263), but the salinity level 12000 ppm recorded the lowest value (1.291).

The interaction between crosses and families was high and significant and the family No. 3 gave the highest mean value (2.642) for cross П in F3. The interaction between crosses and families, in F4 were highly significant. The family No. 1 gave the highest mean value for cross П.

The interactions between crosses and salinity levels were highly significant in F3, cross П recorded highest mean under control (3.209). On the other hand the cross І recorded the lowest value under levels 6000 ppm (1.589). These results are in agreement with El-Hendawy et al. (2005). In F4 generation the interaction between crosses and salinity levels was highly significant. Cross П recorded the highest mean under control (3.402). On the other hand, the cross І recorded the lowest value (1.322) under level 12000 ppm.

The interactions between families and salinity levels were highly significant. Family No. 3 gave the highest mean value (3.518) for control in F3, while family No. 6 recorded the lowest value (1.195) under level 9000 ppm in F3. Family No. 4 gave the highest mean value (3.450) under control. Family No.3 recorded the lowest value (1.063) under level 12000 ppm in F4 generation.

Furthermore, the interaction between (crosses, families and salinity) in F3 were highly significant with the highest mean value (3.840) for family No. 7 in cross І under the control, while the lowest values were (1.067) for cross І in family No. 10 under level 12000 ppm. The interaction between (crosses, families and salinity) in F4 were highly significant, with the highest mean value (3.553) for cross П in family No. 1 under the control, but the lowest value was (0.770) for cross П in family No. 3 under level 12000 ppm.

Grain yield/plant (gm.)

They are presented in Table (6). Results showed, high significant differences between crosses in F3. The cross П gave the highest mean value (1.445), while, cross І gave the lowest mean value (1.221). In F4 generation, the differences between crosses were non-significant.

As for the families, results indicated high significant differences between families. Family No. 2 gave the highest value (1.460 gm), while family No. 9 gave the lowest mean values (0.990 gm) in F3.  The differences between families in F4 were non-significant.

Additionally the salinity levels, results revealed high significant differences between salinity levels, the control gave the highest value (2.877 gm.), followed by (0.853gm) under salinity level 9000 ppm in F3, on the other hand, the salinity level 12000 ppm recorded the lowest value (0.803gm). In F4 generation, the differences between salinity levels were high significant. The control gave the highest value (2.352 gm.), but the salinity level 12000 ppm recorded the lowest value (0.443 gm.)

The interactions between crosses and families were high significant differences, the family No. 8 gave the highest mean value (1.693gm) for cross П in F3, but the interaction between crosses and families in F4 were non-significant.

The interactions between crosses and salinity levels were highly significant in F3 generation. Cross П recorded the highest mean under levels control (2.892gm). On the other hand, the cross І recorded the lowest value (0.591gm) under level 9000 ppm. These results are in agreement with, Mresheh et al. (2009), EL-Amin et al. (2011). In F4, the differences were non-significant.

The interactions between families and salinity levels in F3 were highly significant. Family No. 8 under the control gave the highest mean value (3.632gm), while family No. 9 and No. 10 recorded the lowest values under 12000 ppm. The interaction between families and salinity levels in F4 was non-significant.

In F3 generation, the interactions between (crosses, families and salinity) were high significant. The highest mean value was (4.290 gm) for cross І in family No. 8 under the control, while, family No. 9 in cross І recorded the lowest value (0.170gm.) under salinity level 12000 ppm. The interaction between crosses, families and salinity levels was non-significant in F4 generation.

These results indicated that most of investigated traits were sensitive to salinity stress. These results are in agreement with Aslam et al. (1989). The reduction in the values of the number of spikes/plant, number of grains/spike, 100- grains weight (g) and grain yield/plant (g) may be due to low uptake of water by plants as well as toxicity of Na and C1 because of their high concentration in the irrigation water. Also, salinity stress significantly reduced greatly values of the most investigated traits under study. The reduction in the value of these characters might be due to the toxic effect of salt on plant growth (Bhatti, 2004).

Genetical variability under salinity conditions

Genetic parameters i.e. σ2g2ph,PCV,GCV, h2 % and GA% for plant height    and yield and its component traits under salinity conditions are indicated in Table (7) for F3 and F4 families.

Table (7) showed that PCV values were higher than the GCV values for all the characters. These results are confirmed with those reported by (Ali et al. 2008), Ehdaiel and Waines (1987) and Moghaddam et al. (1997). The estimates of PCV and GCV gave the highest values for grain yield/ plant 69.76 and 65.26. Other traits showed low estimates ranged between 23.99 and 22.60 %, respectively for number of spikes per plant to 48.20 and 38.30 % for number of grains / spikes, respectively under salinity conditions in F3 generation. The estimates of PCV and GCV gave the highest values for number of grains / spike11.03 and 9.12 %. Other traits showed low estimates ranged between 1.005 and .083 % for number of spikes per plant to 8.28 and 7.94 % 100 grain weight in F4 generation. These results are in agreement with that reported by Pathak and Nema (1985).

The broad sense heritability (H %) estimates ranged from 79.46 to 94.21% for number of grains per spike and number of spikes per plant, respectively in F3 generation. The broad sense heritability (H %) estimates ranged from 71.42 to 95.88 % for grain yield per plant and 100 grain weight in F4 generation.Sachan and Singh (2003) found that high heritability estimates were also shown for the traits (plant height, grain yield, number of grains per spike, 100 grain weight and number of spike per plant). High heritability estimates indicate that, the selection for these traits will be effective, being less influenced by environmental effects (Maniee et al. 2009).

The estimates of the expected genetic advance (GA %), as percentage of the mean is shown in (Table 7). Genetic advance (GA %) ranged between 7.81% for number of grains per spike and 67.60 % for number of spikes per plant in F3 generation. The estimates of the expected genetic advance (GA %), as percentage of the mean is shown in (Table 12). Genetic advance (GA %) ranged between 13.38 % for number of spikes per plant and 46.31 % for 100 grain weight in F4 generation. Dwivedi et al. (2002) reported that100-grain weight recorded highest values for genetic advance %. High heritability accompanied with high genetic advance indicates predominance of additive gene action and in such cases selection will be effective Panse and Sukhatme (1967).

CONCLUSION

This result indicates the traits 100-grain weight and grain yield per plant had high estimates of heritabilityandGenetic advanceunder salinity conditions in F4 generation. These traits would be improved by direct selection under saline soil conditions.

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Table 1. The outline of analysis of variance and expectation of mean squares.

S.O.V

Df

MS

EMS

Rep ( r )

Genotype (a)

Families(b)

concentrations (c)

a× b

a×c

b×c

a×b×c

                       Error

r-1

a-1

b-1

c-1

(a-1) (b-1)

(a-1)( c-1 )

(b-1) ( c-1 )

(a-1) (b-1) ( c-1 )

a (a-1) (b-1) ( c-1 )

 

 

                    M5

M4

M3

M2

M1

 

 

 

 

σ2e +r σ2aec + re σ2ac + rc σ2ae + recσ2a

σ2e + r σ2aec+re σ2ac

σ2e + r σ2aec + re σ2ge

σ2e+ r σ2aec

σ2e

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Table 2. Mean squares for studied characters as affected by salinity levels in F3 and F4 families of wheat crosses during 2017/18 F3 and 2018/19 F4 season.

S.O.V

d. f

No.of spikes/plant

No.of grains/Spike

100-grain  weight   (g)

Grain yield/plant(g)

 

F3

F4

F3

F4

F3

F4

F3

F4

F3

F4

Rep

Crosses (A)

Families (B)

AB

Salinity  levels (C)

AC

BC

ABC

Error

2

1

9

9

3

3

27

27

158

2

1

3

3

3

3

9

9

62

0.005

0.675**

0.271**

0.125**

7.522**

2.103**

0.249**

0.324**

0.010

0.009

0.003

0.020

0.011

2.348**

0.005

0.010

0.013

0.012

203.580

1574.042**

117.439

66.533  6898.442**

237.709**

73.250

63.924

49.012

16.947

139.563

5.610

101.917**

1770.252**

47.970

10.254

25.929

22.486

0.017

2.139**

0.857**

0.619**  32.00**

0.617**

0.481**

0.556**

0.008

0.014

0.915**

0.298**

0.337**

17.710**

0.219**

0.103**

0.130**

0.015

0.012

3.002**

0.794**

0.333**

63.614**

0.775**

0.488**

0.739**

0.016

0.013

0.082

0.105

0.026

18.888**

0.014

0.029

0.018

0.047

 

 

 

 

 

 

Table 3. Average performance for number of spikes/plants as affected by salinity levels in F3 and F4 families of wheat crosses during 2017/2018 and 2018/2019 season.

 

Crosses   ( A )

Salinity  levels

( C )

Families

(  B )

Control

6000 ppm

9000 ppm

12000 ppm

Average

 

 

F3

F4

F3

F4

F3

F4

F3

F4

F3

F4

 

Sakha93×   Gemmiza  9 F3    and F4

1

2.733

1.733

1.827

1.210

1.083

1.000

1.603

1.000

1.661

1.236

2

1.700

1.533

1.150

1.127

1.300

1.000

1.040

1.000

1.438

1.165

3

1.767

1.667

1.370

1.087

1.743

1.000

1.247

1.000

1.480

1.188

4

2.067

1.667

1.360

1.087

1.227

1.087

1.287

1.000

1.475

1.210

5

2.290

 

1.280

 

1.303

 

1.120

 

1.540

 

6

2.393

 

1.043

 

1.000

 

1.000

 

1.389

 

7

2.790

 

1.000

 

1.000

 

1.380

 

1.447

 

8

3.260

 

1.570

 

1.000

 

1.000

 

1.802

 

9

2.400

 

1.333

 

1.067

 

1.000

 

1.450

 

10

1.583

 

1.043

 

1.443

 

1.168

 

1.268

 

Average

2.298

1.650

1.298

1.127

1.217

1.022

1.184

1.000

1.495

1.200

 

 

Sakha93× Giza 168 F3and F4

 

 

1

1.567

1.733

1.043

1.170

1.370

1.000

1.000

1.000

1.245

1.226

2

1.900

1.800

1.043

1.043

1.000

1.000

1.707

1.000

1.412

1.211

3

1.500

1.533

1.210

1.000

1.327

1.000

1.607

1.000

1.411

1.133

4

1.700

1.600

1.087

1.087

1.360

1.043

1.000

1.000

1.287

1.183

5

1.600

 

2.000

 

1.440

 

1.000

 

1.510

 

6

1.567

 

1.227

 

1.000

 

1.377

 

1.292

 

7

1.600

 

1.587

 

1.680

 

1.130

 

1.499

 

8

1.600

 

1.560

 

1.617

 

1.450

 

1.557

 

9

1.783

 

1.000

 

1.617

 

1.000

 

1.350

 

10

1.567

 

1.333

 

1.363

 

1.043

 

1.327

 

Average

1.638

1.667

1.309

1.075

1.377

1.011

1.231

1.000

1.389

1.188

Overall mean

1

2.150

1.733

1.435

1.190

1.227

1.000

1.000

1.000

1.453

1.231

2

1.800

1.667

1.097

1.085

1.150

1.000

1.655

1.000

1.425

1.188

3

1.633

1.600

1.290

1.043

1.535

1.000

1.323

1.000

1.445

1.161

4

1.883

1.633

1.223

1.087

1.293

1.065

1.123

1.000

1.381

1.196

5

1.945

 

1.640

 

1.372

 

1.143

 

1.525

 

6

1.980

 

1.135

 

1.000

 

1.248

 

1.341

 

7

2.195

 

1.293

 

1.340

 

1.065

 

1.473

 

8

2.430

 

1.565

 

1.308

 

1.415

 

1.680

 

9

2.092

 

1.167

 

1.342

 

1.000

 

1.400

 

10

1.575

 

1.188

 

1.403

 

1.022

 

1.297

 

Average

1.968

1.658

1.303

1.101

1.297

1.016

1.199

1.000

 

 

L. S. D at 5 %

F3       A        *         B    0.057       C   0.11       AB    0.036      AC 0.051      BC    0.081     ABC    0.162

F4      A       NS       B     NS          C   NS        AB     NS         AC     NS         BC   0.063      ABC       NS

 

 

 

 

 

Table 4. Average performance for number of grains/spikes as affected by salinity levels in F3 and F4 families of wheat crosses during 2017/2018 and 2018/2019 season.

 

Crosses   ( A )

Salinity  levels

(C)

Families

(B)

Control

6000 ppm

9000 ppm

12000 ppm

Average

 

 

F3

F4

F3

F4

F3

F4

F3

F4

F3

F4

 

Sakha93×  Gemmiza  9 F3    and F4

1

50.733

49.227

25.920

37.760

20.83

30.337

23.750

27.420

30.122

36.186

2

51.133

52.733

29.170

38.380

36.213

35.420

35.583

34.587

38.025

40.280

3

59.600

51.133

40.293

31.460

35.170

33.127

23.500

23.963

39.641

34.921

4

52.867

50.067

26.710

36.170

21.793

33.500

38.960

27.253

35.083

36.747

5

54.600

 

28.543

 

29.750

 

25.170

 

34.516

 

6

45.667

 

35.797

 

26.420

 

19.420

 

31.826

 

7

48.533

 

21.710

 

29.463

 

22.543

 

30.563

 

8

56.133

 

37.670

 

21.543

 

29.420

 

36.192

 

9

53.200

 

34.337

 

27.753

 

17.753

 

33.261

 

10

48.133

 

27.087

 

27.420

 

21.003

 

30.911

 

Average

52.060

50.790

30.724

35.943

27.561

33.096

25.710

28.306

34.014

37.034

 

 

Sakha93× Giza 168 F3 and F4

 

 

1

52.133

52.000

32.293

42.043

40.587

34.667

28.083

32.710

38.274

40.355

2

57.200

50.867

36.877

35.793

34.587

32.500

39.130

30.087

41.948

37.312

3

50.933

49.800

36.253

43.880

36.297

33.627

37.670

39.213

40.288

41.630

4

54.800

46.800

32.627

39.253

35.293

36.003

32.003

31.877

38.681

38.483

5

50.867

 

39.003

 

34.547

 

25.503

 

37.480

 

6

54.867

 

36.043

 

32.333

 

34.753

 

39.499

 

7

52.800

 

33.793

 

44.213

 

30.670

 

40.369

 

8

52.000

 

42.293

 

36.543

 

31.710

 

40.637

 

9

47.867

 

25.170

 

39.880

 

23.837

 

34.188

 

10

53.667

 

32.670

 

43.543

 

30.087

 

39.992

 

Average

52.713

49.867

34.702

40.243

37.782

34.199

31.345

33.472

39.136

39.445

Overall Average

1

51.433

50.613

29.107

39.902

30.335

32.502

25.917

30.065

34.198

38.270

2

54.167

51.800

33.023

37.087

35.400

33.960

37.357

32.337

39.987

38.796

3

55.267

50.467

38.273

37.670

35.733

33.377

30.585

31.588

39.965

38.275

4

53.833

48.433

29.668

37.712

28.543

34.752

35.482

29.565

36.882

37.615

5

52.733

 

33.773

 

32.148

 

25.337

 

35.998

 

6

50.267

 

35.920

 

29.377

 

27.087

 

35.662

 

7

50.667

 

27.752

 

36.838

 

26.607

 

35.466

 

8

54.067

 

39.982

 

29.043

 

30.565

 

38.414

 

9

50.533

 

29.753

 

33.817

 

20.795

 

33.725

 

10

50.900

 

29.878

 

35.482

 

25.545

 

35.451

 

Average

52.387

50.328

32.713

38.093

32.672

33.648

28.527

30.889

 

 

 

 

L. S. D at 5 %            

F3         A       *             B    NS       C   2.505       AB     NS        AC   3.542      BC      7.922       ABC      NS

F4         A       NS          B    NS       C   2.737       AB    3.871     AC    NS          BC      NS          ABC      NS

 

 

 

 

 

 

 

Table 5. Average performance for 100-grain weight(g) as affected by salinity levels in F3 and F4 families of wheat crosses during 2017/2018 and 2018/2019 season.

 

Crosses   ( A )

Salinity  levels

( C )

Families

(  B )

Control

6000 ppm

9000 ppm

12000 ppm

Mean

 

 

F3

F4

F3

F4

F3

F4

F3

F4

F3

F4

 

Sakha93×  Gemmiza  9 F3    and F4

1

3.430

3.327

1.310

1.830

1.737

1.180

1.597

1.120

2.018

1.864

2

3.110

3.047

1.563

1.907

1.940

1.550

2.217

1.410

2.208

1.978

3

3.210

2.767

1.900

1.867

1.830

1.413

1.477

1.357

2.104

1.851

4

3.720

3.353

1.383

2.067

1.753

1.663

1.890

1.400

2.187

2.121

5

2.570

 

1.490

 

1.930

 

1.467

 

1.864

 

6

3.677

 

1.523

 

1.147

 

1.920

 

2.067

 

7

3.840

 

2.277

 

1.200

 

1.727

 

2.261

 

8

3.170

 

1.920

 

1.557

 

1.830

 

2.119

 

9

2.937

 

1.170

 

1.760

 

1.630

 

1.874

 

10

2.373

 

1.353

 

1.427

 

1.067

 

1.555

 

Average

3.204

3.123

1.589

1.917

1.628

1.452

1.682

1.322

2.026

1.954

 

 

Sakha93× Giza 168 F3 and F4

 

 

1

2.857

3.553

1.633

2.143

3.067

2.123

1.740

1.480

2.324

2.325

2

3.837

3.387

2.000

2.380

2.303

2.020

2.220

1.383

2.590

2.293

3

3.827

3.123

1.787

2.030

2.573

1.770

2.383

0.770

2.642

1.923

4

3.083

3.547

1.730

1.827

3.010

1.437

1.460

1.407

2.321

2.054

5

3.193

 

1.610

 

1.823

 

2.087

 

2.178

 

6

3.030

 

1.170

 

1.243

 

1.690

 

1.783

 

7

1.617

 

2.130

 

1.790

 

1.977

 

1.878

 

8

3.743

 

1.827

 

1.677

 

1.847

 

2.273

 

9

3.363

 

1.100

 

1.700

 

1.780

 

1.986

 

10

3.537

 

1.773

 

1.797

 

1.567

 

2.168

 

Average

3.209

3.402

1.676

2.095

2.098

1.837

1.875

1.260

2.214

2.149

Overall Average

1

3.143

3.440

1.472

1.987

2.402

1.652

1.668

1.300

2.171

2.095

2

3.473

3.217

1.782

2.143

2.122

1.785

2.218

1.397

2.399

2.135

3

3.518

2.945

1.843

1.948

2.202

1.592

1.930

1.063

2.373

1.887

4

3.402

3.450

1.557

1.947

2.382

1.550

1.675

1.403

2.254

2.087

5

2.882

 

1.550

 

1.877

 

1.777

 

2.021

 

6

3.353

 

1.347

 

1.195

 

1.805

 

1.925

 

7

2.728

 

2.203

 

1.495

 

1.852

 

2.070

 

8

3.457

 

1.873

 

1.617

 

1.838

 

2.196

 

9

3.150

 

1.135

 

1.730

 

1.705

 

1.930

 

10

2.955

 

1.563

 

1.612

 

1.317

 

1.862

 

Average

3.206

3.263

1.632

2.006

1.863

1.645

1.779

1.291

 

 

L. S. D at 5 % 

F3        A        *       B    0.052     C   0.104      AB    0.033         AC   0.046        BC    0.073          ABC      0.147

F4      A        *       B    0.071     C   0.071      AB     0.100        AC   0.100       BC      0.142        ABC      0.201

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Crosses   ( A )

Salinity  levels

(C)

Families

(B)

Control

6000 ppm

9000 ppm

12000 ppm

Average

 

 

F3

F4

F3

F4

F3

F4

F3

F4

F3

F4

 

Sakha93×  Gemmiza  9 F3    and F4

1

2.353

2.300

0.620

0.960

0.413

0.527

0.880

0.347

1.067

1.033

2

2.467

2.273

0.613

0.730

1.280

0.680

1.203

0.503

1.391

1.047

3

2.940

2.203

1.227

0.630

1.023

0.480

0.393

0.400

1.396

0.928

4

2.573

2.373

0.580

0.677

0.273

0.587

1.010

0.457

1.109

1.023

5

2.377

 

0.487

 

0.580

 

1.493

 

1.234

 

6

2.780

 

0.767

 

0.337

 

0.333

 

1.054

 

7

3.970

 

0.540

 

0.400

 

0.343

 

1.313

 

8

4.290

 

1.157

 

0.357

 

0.910

 

1.678

 

9

2.907

 

0.623

 

0.377

 

0.170

 

1.019

 

10

2.260

 

0.463

 

0.873

 

0.213

 

0.952

 

Average

2.892

2.288

0.708

0.749

0.591

0.568

0.695

0.427

1.221

1.008

 

 

Sakha93× Giza 168 F3and F4

 

 

1

2.580

2.617

0.507

0.910

1.673

0.713

0.657

0.453

1.354

1.173

2

3.397

2.507

0.497

0.837

0.730

0.630

1.493

0.450

1.529

1.106

3

2.423

2.200

0.850

0.733

1.153

0.537

1.070

0.463

1.374

0.983

4

3.243

2.347

0.517

0.683

1.430

0.510

1.517

0.470

1.677

1.002

5

2.697

 

1.490

 

1.437

 

0.510

 

1.533

 

6

3.033

 

1.297

 

0.320

 

1.250

 

1.475

 

7

2.380

 

1.063

 

1.343

 

0.620

 

1.352

 

8

2.973

 

1.487

 

1.333

 

0.977

 

1.693

 

9

2.420

 

0.287

 

0.673

 

0.463

 

0.961

 

10

3.483

 

0.927

 

1.053

 

0.550

 

1.503

 

Average

2.863

2.417

0.892

0.791

1.115

0.598

0.911

0.459

1.445

1.066

Overall Average

1

2.467

2.458

0.563

0.935

1.043

0.620

0.768

0.400

1.210

1.103

2

2.932

2.390

0.555

0.783

1.005

0.655

1.348

0.477

1.460

1.076

3

2.682

2.202

1.038

0.682

1.088

0.508

0.732

0.432

1.385

0.956

4

2.908

2.360

0.548

0.680

0.852

0.548

1.263

0.463

1.393

1.013

5

2.537

 

0.988

 

1.008

 

1.002

 

1.384

 

6

2.907

 

1.032

 

0.328

 

0.792

 

1.265

 

7

3.175

 

0.802

 

0.872

 

0.482

 

1.332

 

8

3.632

 

1.322

 

0.845

 

0.943

 

1.685

 

9

2.663

 

0.455

 

0.525

 

0.317

 

0.990

 

10

2.872

 

0.695

 

0.963

 

0.382

 

1.228

 

Average

2.877

2.352

0.800

0.770

0.853

0.583

0.803

0.443

 

 

Table 6. Average performance for grain yield/plant (g) as affected by salinity levels in F3 and F4 families of wheat crosses during 2017/2018 and 2018/2019 season.

L. S. D at 5 %   

F3       A           *         B    0.071      C   0.100       AB      0.045       AC   0.063       BC      0.141     ABC      0.200

F4        A           NS         B    NS            C   0.125          AB      NS              AC   NS               BC        NS        ABC        NS

 

 

 

 

 

 

 

 

 

 

 

 

Table (7). Genetic parameters for studied characters in F3 and F4 families of wheat crosses during 2017/2018 and 2018/2019 season.

Parameters

No. of spikes/plant

No. of grains/spike

100-grain  weight

Grain yield/plant

F3

F4

F3

F4

F3

F4

F3

F4

PCV%

23.99

1.005

48.20

11.03

25.00

8.28

69.76

2.70

GCV %

22.60

0.83

38.30

9.12

22.92

7.94

65.26

1.92

H %

94.21

83.33

79.46

82.70

91.69

95.88

93.54

71.42

GA%

67.60

13.38

7.81

16.05

55.18

46.31

11.91

20.28

PCV, phenotypic coefficient at variation; GCV, Genetic coefficient at variation; H, Heritability in broad sense; GA%, Genetic advance as percentage of mean

 

 

الإنتخاب تحت ظروف الإجهاد الملحي في الأجيال الإنعزاليه الثالث والرابع في القمح

محمد نادي خميس * , حمزة السيد يس ,محمد أحمد هاجر , عزالدين ابراهيم زعزع

قسم المحاصيل - کلية الزراعة – جامعة الأزهر-القاهرة- مصر

* البريد الالکتروني للباحث الرئيسي: Mohamed.abdeltawab@azhar.edu.eg

الملخص العربي

أجري هذا البحث خلال موسمي 2017/18 و2018/19، في المزرعة البحثية بقسم المحاصيل- کلية الزراعة- جامعة الأزهر – القاهرة- مدينة نصر-مصر لتقدير تأثير إجهاد الملوحة لصفات المحصول ومکوناته لهجينين من قمح الخبز الهجين ( سخا93 × جميزة9  ) والهجين ( سخا93 × جيزة 168) تحت مستويات الملوحة (کنترول , 9000,6000 و12000ppm) في الجيلين الانعزالين الثالث والرابع. تمت دراسة صفات عدد السنابل/نبات، عدد الحبوب /سنبلة، وزن 100 حبة ومحصول حبوب / نبات لدراسة إمکانية استخدام هذه الصفات باعتبارها دلائل في برامج التربية بالانتخاب لتحمل الملوحة.

وتتلخص أهم النتائج في الآتي : کانت هناک إختلافات معنوية عالية بين الهجن وأيضا العائلات لمعظم الصفات في الجيل الثالث ولصفة وزن 100حبة في الجيل الرابع., کان هناک إختلافات معنوية عالية بين مستويات الملوحة لکل الصفات في الجيلين الثالث والرابع .,- کان التفاعل بين الهجن والعائلات معنويا لکل الصفات ماعدا عدد الحبوب في السنبلة في الجيل الثالث, وکان معنويا لصفتي عدد الحبوب في السنبلة ووزن 100حبه في الجيل الرابع.,- کان التفاعل بين الهجن ومستويات الملوحة معنويا لکل الصفات في الجيل الثالث، بينما کان معنويا لصفة وزن 100حبه في الجيل الرابع.,- کان التفاعل بين العائلات ومستويات الملوحه معنويا  لمعظم الصفات في الجيل الثالث ومعنويا لصفة وزن 100حبه في الجيل الرابع.,- کان اللتفاعل بين الهجن والعائلات  ومستويات الملوحه معنويا لمعظم الصفات في الجيل الثالث ومعنويا لوزن 100حبه في الجيل الرابع.,- وأظهرت النتائج وجود قيم عالية لدرجة التوريث والتحسين الوراثي لصفتي محصول الحبوب ووزن 100 حبة  في الجيل الرابع . مما يوضح أن هذه الصفات يمکن تحسينها من خلال الانتخاب المباشر تحت ظروف الملوحة.

الکلمات الاسترشادية: التباين الوراثي ،الانتخاب،الملوحة،القمح.