Performance Evaluation of Advanced Bread Wheat Genotypes for
Yield Stability Using the AMMI Stability Model

Solomon T; Shewaye Y; Zegeye H; Asnake D; Tadesse Z; Girma B

doi:10.23880/oajar-16000168

Open Access Journal of Agricultural Research Research Article 9 min read

Performance Evaluation of Advanced Bread Wheat Genotypes for Yield Stability Using the AMMI Stability Model

Solomon T^*, Shewaye Y, Zegeye H, Asnake D, Tadesse Z, Girma B

^* Corresponding author

ISSN: 2474-8846 10.23880/oajar-16000168 Received: May 26, 2018 Published: June 15, 2018

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Keywords

Bread Wheat AMMI YSI Stability

Abstract

Bread wheat (Triticum aestivum L.) is one of the staple foods for large proportion of the Ethiopian population. Ethiopia is the largest wheat producer in Sub-Saharan Africa, The country cultivates a total of more than 1.6 million hectares, and yet imports about 1/3 of the national requirement to make up for annual deficits. To increase wheat production in the country, adaptive breeding has been in progress to develop promising lines for broad adaptation or to develop wheat varieties that perform well over diverse agricultural environments. In this study a total of fifteen genotypes, eight advanced lines from CIMMYT/ICARDA source, five Ethiopian crosses, and two checks, were tested across six locations during 2017 and 2018 seasons. Yield stability index (YSI) was calculated by ranking the mean grain yield of genotypes (RY) across environments and by ranking the AMMI stability values (RASV). The smallest YSI value of 5 was exhibited by variety Hidass and entries ETBW8084, ETBW9037, ETBW9470 and ETBW8459 had YSI values of 6, 7, 12, and 12, respectively, and indicated stability across locations with comparatively higher yields. The highest YSI (30) was recorded by genotype ETBW8075 which is characterized as unstable and low yielder. ETBW 8084 was high yielder and with bi

Introduction

Bread wheat (Triticum aestivum L.), is the staple food for a large proportion of the Ethiopian population. The country is the largest wheat producer in sub- Saharan Africa, next to South Africa [1]. Wheat is found at altitudes ranging from 1700 to 2900 masl. Rainfall In these areas is bimodal and varies from 600 to 2000 mm. Most wheat is produced during the main rainy season, June to September, although some is produced during the light rain season, March to May. Virtually all wheat is produced under rain fed conditions. Central and south eastern highlands of the countries are major wheat producing areas. Therefore, Arsi, Bale and part of Shoa are considered wheat growing belt. Although Ethiopia is largest wheat producing country, the average productivity of the country is 2.5 t/ ha which is lower than world wheat productivity, 3.09 qt/ha (https://www.statista.com/statistics/237705/global- wheat-production/) and 6-7 t/h of potential farmers in the country (personal observation) [2]. Biotic stress, abiotic stress and conventional management practices are among major constraints for wheat production. In particular the breakout out of new races of wheat rusts, like Ug 99 and Digelu races throughout time made popular and wider adapted varieties out of production. Wheat producers in developing countries, like Ethiopia which use restricted inputs and grow wheat under harsh and unpredictable environments require stable wheat varieties. The development of varieties which can be adapted to a wide range of environments with high grain yield is the final goal of any plant breeders in a crop improvement program. High yield stability usually refers to a genotype’s ability to perform consistently across a wide range of environments [3]. In order to ensure consistent stability and high yields, new lines are A total of fifteen genotypes: eight advanced genotypes initially introduced from CIMMYT and ICARDA and then evaluated and selected for four consecutive years, five Ethiopian crosses, and two checks Hidasse and Lemu were evaluated in six location: Kulumsa, Arsi robe, Assasa, Bokoji, Holota and Ofla during 2016 and 2017 cropping season. Details of each location are shown in table. A randomized complete block design with three replication was used.

developed, and tested for their yield performances in different environments [4]. Genotype × environment interactions are of major importance, because they provide information about the effect of different environments on genotype performance and have a key role in assessment of stability of the breeding materials [5]. Quantitative trait like yield mainly dependent on G×E interaction as it obscures the interpretation of genetic experiments and makes predictions difficult. In such circumstances it is difficult to select and suggest one better genotype across various locations. A wider adapted Genotype performs consistently over a wider range of environment. To ensure valid genotype recommendation and to identify promising genotypes, a breeder should conduct multi location yield trials across different environments.

Materials and Methods

	Entry		Genotype		Pedigree		Selection history

1		Lemu		WAXWING*2/HEILO
2		ETBW8070		Line 1 Singh/ETBW4919		KU07-01-0KU-0KU-0KU-0BK2-22KU
3		ETBW8078		Line 1 Singh/(Cham6/WW1402)		KU07-04-0KU-0KU-0KU-0BK1-4KU
4		ETBW8084		Line 3 Singh/(Cham6/WW1402)		KU07-07-0KU-0KU-0KU-0BK1-3KU
5		ETBW8311		ND643/2WBLL1/3/KIRITATI//PRL/2PASTOR/4/KIRITA TI//PBW65/2*SERI.1B		CMSS07B00823T-099TOPY-099M- 099Y-099M-7WGY-0B
6		ETBW8065		Line 1 Singh/ETBW4919		KU07-01-0KU-0KU-0KU-0BK1-5KU
7		ETBW8427		SERI.1B//KAUZ/HEVO/3/AMAD/4/PYN/BAU//MILAN/5/I CARDA-SRRL-1		ICW06-50208-5AP-0AP-0AP -02 SD
8		ETBW8459		CHIL-1//VEE'S'/SAKER'S'		ICW99-0026-7AP-0AP-0AP-9AP-0AP- 0DZ/0AP-0DZ/0KUL/0SIN/0AP- 0NJ/0AP-0ALK/0AP
9		ETBW9037		SWSR22T.B./2BLOUK #1//WBLL12/KURUKU		CMSS08Y01116T-099M-099Y-099M- 099NJ-099NJ-23WGY-0B
10		ETBW9045		KINDE/4/CMH75A.66//H567.71/5*PVN/3/SERI		CMSS09Y00603S-099Y-17M-0WGY-6B- 0Y

Table 1: Pedigree and history of fifteen genotypes tested for yield performance and wheat rust resistance.

11	ETBW8075	Line 1 Singh/(Cham6/WW1402)	KU07-04-0KU-0KU-0KU-0BK1-1KU
12	ETBW9464	MARCHOUCH4/SAADA/3/2FRET2/KUKUNA//FRET2*2/4 /TRCH/SRTU//KACHU	CMSS10B00928T-099TOPY-099M- 099NJ-099NJ-13WGY-0B
13	ETBW9466	ATTILA/3BCN//BAV92/3/TILHI/5/BAV92/3/PRL/SARA/ /TSI/VEE#5/4/CROC_1/AE.SQUARROSA (224)//2OPATA2/6/HUW234+LR34/PRINIA//UP23382 /VIVITSI	CMSS10B01047T-099TOPY-099M- 099NJ-099NJ-2WGY-0B
14	ETBW9470	BAVIS #1/5/W15.92/4/PASTOR//HXL7573/2*BAU/3/WBLL1	CMSA10M00485S-099ZTM-099NJ- 099NJ-6WGY-0B
15	Hidasse	YANAC/3/PRL/SARA//TSI/VEE#5/4/CROC- 1/AE.SQUAROSA(224)//OPATTA	CMSA10M00485S-099ZTM-099NJ- 099NJ-6WGY-0B

Table 2: Pedigree and history of fifteen genotypes tested for yield performance and wheat rust resistance.

											Temp
	Location		Altitude (m)		Representing Agroecology		Soil type		Rainfall

											max		Min
Kulumsa		2200		Mid-altitude		Clay soil (luisols)		820mm		22.8		10.5
Arsi robe		2420		Water logged vertisoil		Heavy clay soil (vertisiol)		890mm		22.1		6
Assasa		2340		Terminal drought prone		Clay loam soil(gleysols)		620mm		23.6		5.8
Bokoji		2780		Highland/haigh rainfall		Clay siol(nitosols)		1020mm		18.6		7.9
Holota		2400		M2-5		Nitosols		1144		22		6
Ofla		2490		-		clay		-		22.2		7.7

Table 3: Information on Altitude, Soil, rainfall and temperature of tested location.

Statistical Analysis

Four internal rows were harvested and grain yield per plot was converted to ton per hectare. Analysis of Variance was computed to determine the effects of genotype, environment, and GE interactions on grain yield. The stability of yield performance for each genotype was calculated by regressing the mean grain yield of individual genotypes on environ-mental index and calculating the deviation from regression as suggested by Eberhart and Russell as [6]:

$$ Y _ {i j} = \mu_ {i} + \beta_ {i} I _ {j} + \delta_ {i j} $$

where: Yij is the variety mean of the ith environment, µi is the mean of ith variety over all environments, βi is the regression coefficient that measures the responseof the ith variety to varying environments, δij is the deviation from regression of the ith variety at the jth environment, and Ij is the environmental index obtained as the mean of all varieties at the jth environment minus the grand mean. regression coefficient (bi) close to unity and deviation from regression (S2di) near to zero, was defined as a stable cultivar [6].

AMMI Stability Value (ASV is the distance from the coordinate point to the origin in a two-dimensional plot of IPCA1 scores against IPCA2 scores in the AMMI model [7]. Because the IPCA1 score contributes more to the GXE interaction sum of squares, a weighted value is needed. This weighted value was calculated for each genotype and each environment according to the relative contribution of IPCA1 to IPCA2 to the interaction sum of squares as follows:

( )( ) ( ) 2

$$ \mathrm {A S V} = \sqrt {\left[ \left(S S _ {I P C A 1} \div S S _ {I P C A 2}\right) \left(I P C A 1 s c o r e\right) ^ {2} + \left(I P C A 2 s c o r e\right) ^ {2} \right]} $$

where, SSIPCA1/SSIPCA2 is the weight given to the IPCA1-

value by dividing the IPCA1 sum of squares by the IPCA2

sum of squares. Either the larger negative ASV value or

positive, the more specifically adapted a genotype is to

certain environments. Smaller ASV values indicate more

stable genotypes across environments [7].

Yield stability index (YSI), is calculated by ranking the

mean grain yield of genotypes (RY) across environments

and rank of AMMI stability value (ASV). The YSI

incorporates both mean yield and stability in a single criterion as follows: YSI = RASV + RY [8,9]. Ecovalnce
(Wi2) and stability variance (σi2) were computed as suggested by
Wricks’s and
Shukla’s
[10,11].
Result and Discussion
GEN
Mean
ASV
YSI
RASV
RYI
Wi2 σi2 si2 bij
Sd2i
Lemu
5.17
0.6834
14
5
9
17.26
3.662091 ns
1.818214 ns
0.408
0.21
ETBW8070
5.61
1.3542
20
14
6
30.56
6.731099 ns
4.355622 ns
0.286
0.008
ETBW8078
4.19
0.8852
21
8
13
14.46
3.016039 ns
3.570220 ns
0.807
0.006
ETBW8084
6.04
0.4525
6
4
2
5.68
0.991338 ns
0.892331 ns
1.236
0.434
ETBW8311
4.04
0.9258
24
10
14
22.6
4.890277 ns
5.565642 ns
1.283
0.123
ETBW8065
5.05
1.3461
23
13
10
31.39
6.923159 ns
7.167105 ns
0.559
0.491
ETBW8427
5.66
0.8858
14
9
5
12.89
2.652924 ns
2.987167 ns
0.77
0.042
ETBW8459
5.02
0.093
12
1
11
7.91
1.505092 ns
1.909821 ns
1.097
0.192
ETBW9037
5.74
0.3589
7
3
4
4.36
0.684794 ns
0.950139 ns
0.962
0.418
ETBW9045
5.41
0.7073
13
6
7
12.3
2.517762 ns
3.215418 ns
1.068
0.024
ETBW8075
2.35
1.6888
30
15
15
55.26
12.430907 **
14.024556 **
0.555
4.779
ETBW9464
4.5
1.2541
24
12
12
31.54
6.959196 ns
5.583620 ns
1.623
0.128
ETBW9466
5.24
0.7975
15
7
8
14.44
3.013000 ns
1.164301 ns
1.576
0.36
ETBW9470
7.13
1.1078
12
11
1
25.87
5.649403 ns
3.096933 ns
1.706
0.033
Hidasse
6
0.2096
5
2
3
5.06
0.847359 ns
1.133583 ns
1.062
0.368

Table 4: Results of AMMI stability values.

adapted to high yielding environments or optimum areas. A cultivar Hidase, genotypes: ETBW9045, ETBW8084 and ETBW8427 were high yielder and bi close to unity and Si2 near to zero. And therefore, they were widely adapted genotypes. ETBW 8084 was high yielder and bi<1, indicted that the genotype well perform to environmental changes and low yielding areas [14]. ETBW8075 with high deviation from regression Si2= 4.779 (table.) delivered the lowest yield and poor performance across tested location.

	Genotypes		Arsirobe		Assasa		Bokoji		Holota		Kulumsa		Ofla

Lemu		4.6		5.2875		4.8125		4.9625		6.675		4.685714
ETBW8070		4.9125		6.85		6.7		4.7625		5.625		4.785714
ETBW8078		3.8375		4.5125		2.575		3.0625		5.6375		5.514286
ETBW8084		6.8375		6.7		5.1625		3.55		7.9875		5.985714
ETBW8311		4.4375		5.9		1.4375		2.1125		5.2		5.171429
ETBW8065		3.9		6.8625		5.925		4.1125		5.8		3.685714
ETBW8427		5.725		6.975		6.1375		3.9875		6.625		4.5
ETBW8459		5.375		6.3625		4.8		2.2625		5.775		5.557143
ETBW9037		6.2375		6.575		5.2625		4		7.4125		4.942857
ETBW9045		4.8375		7.4875		5.6625		3.1875		6.475		4.828571
ETBW8075		1.5125		2.0375		0.8625		1.2		3		5.485714
ETBW9464		5.3625		6.05		1.425		2.3125		7.025		4.814286
ETBW9466		5.65		6.1125		3.775		2.5375		8.15		5.242857
ETBW9470		8.4		8.725		6.5286		3.4375		9.325		6.371429
Hidasse		6.0625		6.2		5.4		3.925		8.1		6.328571

Table 5: Mean grain yield of fifteen genotypes across six location for two years.

Conclusion and Recommendation

To develop varieties for different environments, very essential for breeders to evaluate their genotypes based on many years and several locations. Environmental variations are important in determining performance of elite materials. Genotype ranks consistently across different tested location has less response for highly unstable environment. Genotype 8084 is high yielder than the two checks and stable across tested location. Therefore this genotypes recommended as candidate variety for next year to release as a variety for wider environment. Genotype 9470 with highest mean grain yield and best performance at potential environments recommended as candidate variety for optimum areas.

Acknowledgement

This work would not have been possible without the financial support EIAR, Collaborating regional and federal research centers and wheat breeding teams of Kulumsa Agricultural Research Center (KARC). I am grateful to all of those with whom I have had the pleasure to work during this and other related projects.

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