Coffee is the largest export crop, and the backbone of the Ethiopian economy. The experiment were conducted at Metu, Gore and Chora for two consecutive years with the objective of determining the nature and magnitude of genotype x environment interaction, to classify environment based on genotype performance and identifying stable genotypes on coffee yield by using GGE biplot analysis. A total 17 advanced coffee genotypes were laid out using randomized complete block design with three replications. The analysis of variance for coffee bean yield revealed the presence of highly significant difference (P<0.01) among genotypes, environments and genotype by environment interaction. Results of GGE biplot showed that the first two principal components (PC1 and PC2) justified 65.66% of the sum of squares with PC1=49.12% and PC2=16.54% of the GGE sum of squares. The six test environments were divided into four different coffee growing mega-environments. Among the test location Metu2 and Gore2 were the most representative and most discriminating environment while Chora2 was less powerful to discriminate genotypes or less desirable as a testing location for coffee bean yield. Genotype G5 (236/71), followed by G8 (872/74) and G12 (227/71) were stable and high yielder across coffee growing environments and it recommended for mega environment production.
| Published in | American Journal of Biological and Environmental Statistics (Volume 8, Issue 1) |
| DOI | 10.11648/j.ajbes.20220801.15 |
| Page(s) | 36-42 |
| Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
| Copyright |
Copyright © The Author(s), 2022. Published by Science Publishing Group |
Bean Yield, Discriminating, Genotype x Environment Interaction, Stable
| [1] | Agwanda, C. O., Baradat, P., Cilas, C. and Charrier, A., 1997. Genotype-by-environment interaction and its implications on selection for improved quality in Arabica coffee (Coffea arabica L.). In Colloque Scientifique International sur le Café, 17. Nairobi (Kenya), Juillet 20-25, 1997. |
| [2] | Akter, A., Hasan, M. J., Kulsum, U., Rahman, M. H., Khatun, M. and Islam, M. R., 2015. GGE biplot analysis for yield stability in multi-environment trials of promising hybrid rice (Oryza sativa L.). Bangladesh Rice Journal, 19 (1), pp. 1-8. |
| [3] | Becker, H. C. and Leon, J., 1988. Stability analysis in plant breeding. Plant breeding, 101 (1), pp. 1-23. |
| [4] | Farshadfar, E., Geravandi, M. and Vaisi, Z., 2012. Chromosomal localization of QTLs controlling genotype environment interactions in barley. International Journal of Agriculture and Crop Sciences, 4 (6), pp. 317-324. |
| [5] | Farshadfar, E., Zali, H. and Mohammadi, R., 2011. Evaluation of phenotypic stability in chickpea genotypes using GGE-Biplot. Annals of Biological Research, 2 (6), pp. 282-292. |
| [6] | Fiseha Baraki, Yemane Tsehaye and Fetien Abay. 2015. AMMI analysis of Genotype x Environment interaction and stability analysis of sesame genotypes in northern Ethiopia. Asian Journal of Plant Science, 13 (4-8): 178-183. |
| [7] | Gauch, H. and Zobel, R. W., 1997. Identifying mega-environments and targeting genotypes. Crop Science, 37 (2), pp. 311-326. |
| [8] | Gauch, H. G. and Zobel, R. W., 1996. AMMI analysis of yield trials. In „Genotype by environment interaction‟. (Eds MS Kang, HG Gauch) pp. 85–122. |
| [9] | Getu Bekele, 2009. Genotype x environment interaction of arabica coffee (Coffea arabica L.) for bean biochemical composition and organoleptic quality characteristics. An M. Sc thesis submitted to school of graduate studies of Alemaya University. 115p. |
| [10] | Girma Adugna, Bayeta Belachew, Sisay Tesfaye, Endale Taye, Taye Kufa, 2008. Coffee diversity & knowledge. group discussions, synthesis and recommendations. Pp. 505-510. Proceedings on Four Decades of Coffee Research and Development in Ethiopia, A National Workshop, 14-17. Ghion Hotel, Addis Ababa, Ethiopia. |
| [11] | Kang, M. S. and Gauch, H. G., 1996. Genotype-by-environment interaction. CRC press. |
| [12] | Karimizadeh, R., Mohammadi, M., Sabaghni, N., Mahmoodi, A. A., Roustami, B., Seyyedi, F. and Akbari, F., 2013. GGE biplot analysis of yield stability in multi-environment trials of lentil genotypes under rainfed condition. Notulae Scientia Biologicae, 5 (2), pp. 256. |
| [13] | Kaya, Y., Akçura, M. and Taner, S., 2006. GGE-biplot analysis of multi-environment yield trials in bread wheat. Turkish Journal of Agriculture and Forestry, 30 (5), pp. 325-337. |
| [14] | Kufa, T., Shimber, T., Bellachew, B., Taye, E. and Adugna, G., 2008. Coffee Diversity & Knowledge. Ethiopian Institute of Agricultural Research Addis Ababa, Ethiopia. Pp. 187-194. |
| [15] | Lashermes, P., Andrzejewski, S., Bertrand, B., Combes, M. C., Dussert, S., Graziosi, G., Trouslot, P. and Anthony, F., 2000. Molecular analysis of introgressive breeding in coffee (Coffea arabica L.). TAG Theoretical and Applied Genetics, 100 (1), pp. 139-146. |
| [16] | Lemi B., Sentayew A., Ashenafi A. and Gerba D., 2018. Genotype by environment interaction and stability analysis of Arabica genotypes. African journal of agricultural research. Vol. 13 (4), pp. 210-219. |
| [17] | Lin, C. S., Binns, M. R. and Lefkovitch, L. P., 1986. Stability analysis: where do we stand? Crop science, 26 (5), pp. 894-900. |
| [18] | Meaza Demissie, Girma Taye and Mesfin Kebede, 2011. Additive Main Effects and Multiplicative Interaction Analysis of Coffee Germplasms from Southern Ethiopia. SINET: Ethiopian Journal of Science, 34 (1), pp. 63-70. |
| [19] | Mesfin Ameha and Bayetta Belachew, 1987. Genotype-environment interaction and its implication on selection for improved quality in arabica coffee (Coffea arabica L.) ASIC, Colloque, Nairobi, Kenya. |
| [20] | Mitroviã, B., Treski, S., Stojakoviã, M., Ivanoviã, M. and Bekavac, G., 2012. Evaluation of experımental maize hybrids tested in multi-location trials using AMMI and GGE biplot analyses. Turkish Journal of Field Crops, 17 (1), pp. 35-40. |
| [21] | Mohammed Abate, Firew Mekbib, Amsalu Ayana and Mandefro Nigussie, 2015. Genotype x Environment and Stability Analysis of Oil Content in Sesame (Sesamum indicum L.) Evaluated across Diverse Agro-ecologies of the Awash Valleys in Ethiopia. American Journal of Experimental Agriculture, 9 (2): 1-12. |
| [22] | Montagnon C., Christian Cilas, Thierry Leroy, Antoine Yapo, Pierre Charmetant. Genotype-location interactions for Coffea canephora yield in the Ivory Coast. Agronomie, EDP Sciences, 2000, 20 (1), pp. 101-109. |
| [23] | Naheif, E, M Mohammad, 2013. Genotype x environment interactions for grain yield in bread wheat (Triticum aestivum L.). Global Sci. Res. J. 1 (1): 045-052. |
| [24] | Pearl, H. M., C. Nagai, P. H. Moore, D. L. Steiger, R. V. Osgood and R. Ming, 2004. Construction of a genetic map for arabica coffee. Theor. And Appl. Genet. 108: 829-835. |
| [25] | SAS, 2014. Statistical analysis system (version 9.3), SAS Institute, Cary, NC. USA. |
| [26] | Van der Vossen, H., Bertrand, B. and Charrier, A., 2015. Next generation variety development for sustainable production of arabica coffee (Coffea arabica L.): a review. Euphytica, 204 (2), pp. 243-256. |
| [27] | YAN, W.; HUNT, l. A., 2001. Genetic and environmental causes of genotype by environment interaction for winter wheat yield in Ontario. Crop Science 41: 19–25. |
| [28] | VSN International, 2015. Genstat software reference manual (Release 18), Part 1 Summary. VSN International, Hemel Hempstead, UK. |
| [29] | Yan, W, S. Kang, M. S, Ma. B, Woods, S. and L. Cornelius. P. L., 2007. GGE Biplot vs. AMMI analysis of Genotype by Environment Data. Crop science, vol. 47, march–april 2007. doi: 10.2135/cropsci2006.06.0374. |
| [30] | Yan, W., and I. Rajcan, 2002. Biplot evaluation of test sites and trait relations of soybean in Ontario. Crop Sci. 42: 11-20. |
| [31] | Yan, W., and M. S. Kang., 2003. GGE biplot analysis: a graphical tool for breeders, In M. S. Kang (ed.), Geneticists, and Agronomist pp. 63-88). Boca Raton, FL: CRC Press. |
| [32] | Yan, W., L. A. Hunt, Q. Sheng and Z. Szlavnics. 2000. Cultivar evaluation and mega environment investigation based on the GGE biplot. Crop Science, 40: 597-605. |
| [33] | Yan, W., Sheng, Q. and Hu, Y., 2001. GGE Biplot: An Ideal Tool for Studying Genotype by Environment Interaction of Regional Yield Trial Data. Acta. Agron. Sin., 27 (1): 21-28. |
| [34] | Yirga Belay, 2016. Genotype x environment interaction and yield stability of white seeded sesame (sesamum indicum L.) genotypes in northern Ethiopia. M.Sc. Thesis Submitted to Graduate Studies of Haramaya University, Haramaya, Ethiopia. |
| [35] | Yonas Belete, Bayetta Belachew and Chemeda Fininsa, 2014. Performance evaluation of indigenous Arabica coffee genotypes across different environments. Greener Journal of Plant Breeding and Crop Science, vol. 6 (11), pp. 171-178. |
| [36] | Yan, W., 2001. GGEbiplot - A Windows application for graphical analysis of multienvironment trial data and other types of two-way data. Agronomy journal, 93 (5), pp. 1111-1118. |
| [37] | Endale Taye, Taye Kufa, Anteneh Netsire, Tesfaye Shimber, Alemseged and Tesfaye. 2008. Research on Arabica Coffee field Management. Coffee Diversity and Knowledge. Proceedings of a National Workshop Four Decades of Coffee Research and Development in Ethiopia, 14-17 Addis Ababa, Ethiopia. Pp. 187-194. |
APA Style
Afework Legesse, Sintayehu Alamrew, Abush Tesfaye. (2022). Stability Analysis of Coffee (Coffea arabica L.) Bean Yield Using GGE Biplot in South Western Ethiopia. American Journal of Biological and Environmental Statistics, 8(1), 36-42. https://doi.org/10.11648/j.ajbes.20220801.15
ACS Style
Afework Legesse; Sintayehu Alamrew; Abush Tesfaye. Stability Analysis of Coffee (Coffea arabica L.) Bean Yield Using GGE Biplot in South Western Ethiopia. Am. J. Biol. Environ. Stat. 2022, 8(1), 36-42. doi: 10.11648/j.ajbes.20220801.15
AMA Style
Afework Legesse, Sintayehu Alamrew, Abush Tesfaye. Stability Analysis of Coffee (Coffea arabica L.) Bean Yield Using GGE Biplot in South Western Ethiopia. Am J Biol Environ Stat. 2022;8(1):36-42. doi: 10.11648/j.ajbes.20220801.15
Share This Article
Twitter
Linked In
Facebook
Copy
Download@article{10.11648/j.ajbes.20220801.15,
author = {Afework Legesse and Sintayehu Alamrew and Abush Tesfaye},
title = {Stability Analysis of Coffee (Coffea arabica L.) Bean Yield Using GGE Biplot in South Western Ethiopia},
journal = {American Journal of Biological and Environmental Statistics},
volume = {8},
number = {1},
pages = {36-42},
doi = {10.11648/j.ajbes.20220801.15},
url = {https://doi.org/10.11648/j.ajbes.20220801.15},
eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.ajbes.20220801.15},
abstract = {Coffee is the largest export crop, and the backbone of the Ethiopian economy. The experiment were conducted at Metu, Gore and Chora for two consecutive years with the objective of determining the nature and magnitude of genotype x environment interaction, to classify environment based on genotype performance and identifying stable genotypes on coffee yield by using GGE biplot analysis. A total 17 advanced coffee genotypes were laid out using randomized complete block design with three replications. The analysis of variance for coffee bean yield revealed the presence of highly significant difference (P<0.01) among genotypes, environments and genotype by environment interaction. Results of GGE biplot showed that the first two principal components (PC1 and PC2) justified 65.66% of the sum of squares with PC1=49.12% and PC2=16.54% of the GGE sum of squares. The six test environments were divided into four different coffee growing mega-environments. Among the test location Metu2 and Gore2 were the most representative and most discriminating environment while Chora2 was less powerful to discriminate genotypes or less desirable as a testing location for coffee bean yield. Genotype G5 (236/71), followed by G8 (872/74) and G12 (227/71) were stable and high yielder across coffee growing environments and it recommended for mega environment production.},
year = {2022}
}
TY - JOUR T1 - Stability Analysis of Coffee (Coffea arabica L.) Bean Yield Using GGE Biplot in South Western Ethiopia AU - Afework Legesse AU - Sintayehu Alamrew AU - Abush Tesfaye Y1 - 2022/03/23 PY - 2022 N1 - https://doi.org/10.11648/j.ajbes.20220801.15 DO - 10.11648/j.ajbes.20220801.15 T2 - American Journal of Biological and Environmental Statistics JF - American Journal of Biological and Environmental Statistics JO - American Journal of Biological and Environmental Statistics SP - 36 EP - 42 PB - Science Publishing Group SN - 2471-979X UR - https://doi.org/10.11648/j.ajbes.20220801.15 AB - Coffee is the largest export crop, and the backbone of the Ethiopian economy. The experiment were conducted at Metu, Gore and Chora for two consecutive years with the objective of determining the nature and magnitude of genotype x environment interaction, to classify environment based on genotype performance and identifying stable genotypes on coffee yield by using GGE biplot analysis. A total 17 advanced coffee genotypes were laid out using randomized complete block design with three replications. The analysis of variance for coffee bean yield revealed the presence of highly significant difference (P<0.01) among genotypes, environments and genotype by environment interaction. Results of GGE biplot showed that the first two principal components (PC1 and PC2) justified 65.66% of the sum of squares with PC1=49.12% and PC2=16.54% of the GGE sum of squares. The six test environments were divided into four different coffee growing mega-environments. Among the test location Metu2 and Gore2 were the most representative and most discriminating environment while Chora2 was less powerful to discriminate genotypes or less desirable as a testing location for coffee bean yield. Genotype G5 (236/71), followed by G8 (872/74) and G12 (227/71) were stable and high yielder across coffee growing environments and it recommended for mega environment production. VL - 8 IS - 1 ER -
Email: