The quantity of Soybean produced and yield per given area in Ethiopia is small compared to the world average capability because of less varied soybean genotypes. The reason at the back of is due to a lack of various soybean genotype available and the genetic potential reduction of released varieties which have been in utilizing. Subsequently, genotypes that have not been characterized clustered and tested for their variability subjected for this observe. Approximately eighty-one (81) genotypes had been examined in a 9*9 easy lattice layout for his or her variability and relation of amongst trends using yield and yield related trends, qualitative, and first-class tendencies at Pawe Agricultural studies middle predominant station and Dibate substation in 2018-2019 cropping season. The analysis of variance discovered that all developments besides wide variety of nodules in line with plant, range of pods plant-1 and number of seeds pod-1 confirmed exceedingly substantial (p<0.01) differences at each tested places. Sixty three and sixty five percent of variations, from the entire, were revealed from the first 4 PCAs for Pawe and Dibate, respectively. Cluster evaluation confirmed about four specific clusters and the most inter cluster distance became determined among cluster I and cluster IV (D2=875.31) at Pawe and among cluster II and cluster IV (D2=1227.68) at Dibate. However, one season test might now not realize genotypes’ variability in response of environment; due to the fact quantitative traits are polygenic and profoundly affected by the environment. As a consequence, an addition experiment on those genotypes in changed seasons is needed for more real estimation of polygenic traits.
| Published in | World Journal of Agricultural Science and Technology (Volume 1, Issue 4) |
| DOI | 10.11648/j.wjast.20230104.11 |
| Page(s) | 76-82 |
| 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), 2023. Published by Science Publishing Group |
Cluster Distance, Genetic Divergence, Genetic Variability, Genotypes, Important Factor, Soybean
| [1] | Hymowitz T. Speciation and cytogenetic Soybeans Improvement, Production, and Uses. American Society of Agronomy, Crop Science Society of America, Soil Science Society of America, Madison, Wis. 2004; 97–136. |
| [2] | Smith KJ, Huyser W. World Distribution and Significance of Soybean. American Society of Agronomy, Inc. Madison, WI. 1987; 1-22. |
| [3] | Sharma S, Kaur M, Goyal R. Gill B. S. Physical characteristics and nutritional compositions of some new soybean (Glycine max L. Merrill) genotypes. Journal of food science and Technology. 2013; 51: 551-557. |
| [4] | Hossain Z, Komatsu S. Potentiality of soybean proteomics in untying the mechanism of Flood and Drought stresses tolerance. Proteomes. 2014; 2 (1): 10-127. |
| [5] | Ghosh J, Ghosh P. D, Choudhury P. R. An assessment of genetic relatedness between soybeans cultivars using SSR markers. American journal of plant Sciences. 2014; 05: 3089-3096. |
| [6] | Salgotra RK, Gupta BB, Bhat JA, Sharma S. Genetic diversity and population structure of basmati rice (Oryza sativa L.) germplasm collected from north western Himalayas using trait linked SSR markers. 2015; 10 (7): 1-19. |
| [7] | Otálora MA, Belinchón R, Prieto M, Aragón G, Izquierdo P, Martínez I. The Threatened Epiphytic lichen lobaria Pulmonaria in the Iberian Penisula. Genetic Diversity and Structure across a latitudinal gradient. Fungal. 2015; 119 (9): 802–811. |
| [8] | Chen YY, Wang WC, Fan XR, Sun JY, Li W, Li XL, Liu YL. Genetic discontinuities and abundant historical gene flow in wild lotus Nelumbo Nucifera Population from the Yangtze River. Aquat Bot 158: 103130. https://doi. org/10.1016/j.aquabot.2019.103130. |
| [9] | Punia, S. S, R. Baldev, N. R, Koli, B. R, Ranwah, P, Rokadia. S. R. Maloo. Genetic architecture of quantitative traits in field pea. Journal of Swollen Food. 2011; 24: 299-303. |
| [10] | Vianna VF, De Santiago S, Charnai K, Ferraudo AS, Di Mauro AO. The multivariate approach and Influence of Characters in Selecting superior Soybean genotypes. Afr. J. Agric. Res. 2013; 8 (30): 4162–4169. |
| [11] | Central Statistical Agency of Federal Democratic Republic of Ethiopia. Annual report. 2000-2012. |
| [12] | Central Statistical Authority (CSA). Agricultural sample survey. Addis Ababa, Ethiopia. 2018; 1: 14. |
| [13] | Mesfin HaileMariam and Abush Tesfaye. Progress of Soybean [Glycine max Merrill (L.)] Breeding and Genetics Research in Ethiopia. Journal of Natural Sciences Research. 2018; 8: 70. |
| [14] | Afework Hagos and Adam Bekele. Cost and returns of soybean production in Assosa Zone of Benishangul Gumuz Region of Ethiopia. Journal of Development and Agricultural Economics. 2018; 10 (11): 377-383. |
| [15] | Dudley J. W. Molecular Markers in Plant plant improvements manipulation of genes affecting quantitative traits. Crop Sci. 1993; 33: 660–668. |
| [16] | Pawe Agricultural Research Center. 2017. Laboratory and meteorology data. 2017. Assessed 16 January 2018. Available: https://en.wikipedia.org/wiki/Dibate woreda. |
| [17] | Malik M. A, Raffi M. Y, and Mondol M. A. Morphological characterization and assessment of genetic variability, character association, and divergence in soybean mutants. The Scientific World Journal. 2014; 1-12. |
| [18] | Osborne D. R, Vogt P. The Analysis of Nutrients in Foods. 6thEdn. Academic Press: London: 1978; 239-245. |
| [19] | Statistical Analysis System (SAS). System Analysis Software. Version 9.3. SAS Institute INC. Cary, North Carolina, USA. 2011. |
| [20] | Mahalanobis P. C. On the generalized distance in statistics. Proc. Natl. Sci. India B. 1936; 2: 49-55. |
| [21] | Singh R. K. and Chaudhary BD. Biometrical methods in quantitative genetic analysis. Kalyani Publishers. New Delhi. 1985. |
| [22] | Holland S. M. Principal component analysis. Department of geology, University of Georgia, Athens. Genet and Plant breed. 2016; 5 (4): 415-467. |
| [23] | Daniel Hailegiorgis, Mebrahtom Mesfin, Tsige Genet. Genetic divergence analysis on some bread wheat genotypes grown in Ethiopia. Journal of Central European Agriculture. 2011; 12: 344. |
| [24] | Gemechu Keneni, Jarsa Musa, Tezera, Getnet. Extent and pattern of genetic diversity for morph-agronomic traits in Ethiopian highland pulse landraces. Genetic Resources and Crop Evolution. 2005; 52: 539-549. |
| [25] | Tadesse Ghiday, Sintayehu Alamrew. Genetic divergence analysis on some soybean (Glycine max L. Merrill) genotypes grown in Pawe, Ethiopia. American Eurasian Journal. Agric. and Environ. Sci. 2015; 15 (10): 1927-1933. |
| [26] | Faisal AM, Afsari s, Muhammad A, Abdul G. 2011. Investigation and comparison of some morphological traits of the soybean populations using cluster analysis. Pak. J. Bot. 2011; 43 (2): 1249-1255. |
| [27] | Santosh K., Vedna K, Vinod K. Genetic variability and character association studies for seed yield and component characters in soybean under Northwestern Himalayas. Legume research an International journal. Palampur. 2018; 176: 062. |
| [28] | Amit K, Avinash P, Chubasenla A, Pattanayak. Evaluation of Genetic Diversity and Interrelationships of Agro Morphological Characters in Soybean (Glycine max) Genotypes. National Academy of Sciences. Sect. B Biol. Sci. 2014; 85 (2): 397–405. |
| [29] | Tadesse Ghiday, Asmamaw Amogne, Gezahegn Tefera, Mola Malede. Heritability, Genetic Advance and Path Coefficient Analysis for Grain Yield and its Component Characters in Soybean (Glycine max L. Merrill). International Journal of Research Studies in Agricultural Sciences. 2017; 3 (5): 1-11: ISSN 2454-6224. |
APA Style
Asmamaw Amogne Mekonen. (2023). Genetic Divergence and Principal Component Analysis of Soybean [Glycine max (L.) Merrill] Genotypes in Northwestern Ethiopia. World Journal of Agricultural Science and Technology, 1(4), 76-82. https://doi.org/10.11648/j.wjast.20230104.11
ACS Style
Asmamaw Amogne Mekonen. Genetic Divergence and Principal Component Analysis of Soybean [Glycine max (L.) Merrill] Genotypes in Northwestern Ethiopia. World J. Agric. Sci. Technol. 2023, 1(4), 76-82. doi: 10.11648/j.wjast.20230104.11
AMA Style
Asmamaw Amogne Mekonen. Genetic Divergence and Principal Component Analysis of Soybean [Glycine max (L.) Merrill] Genotypes in Northwestern Ethiopia. World J Agric Sci Technol. 2023;1(4):76-82. doi: 10.11648/j.wjast.20230104.11
Share This Article
Twitter
Linked In
Facebook
Copy
Download@article{10.11648/j.wjast.20230104.11,
author = {Asmamaw Amogne Mekonen},
title = {Genetic Divergence and Principal Component Analysis of Soybean [Glycine max (L.) Merrill] Genotypes in Northwestern Ethiopia},
journal = {World Journal of Agricultural Science and Technology},
volume = {1},
number = {4},
pages = {76-82},
doi = {10.11648/j.wjast.20230104.11},
url = {https://doi.org/10.11648/j.wjast.20230104.11},
eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.wjast.20230104.11},
abstract = {The quantity of Soybean produced and yield per given area in Ethiopia is small compared to the world average capability because of less varied soybean genotypes. The reason at the back of is due to a lack of various soybean genotype available and the genetic potential reduction of released varieties which have been in utilizing. Subsequently, genotypes that have not been characterized clustered and tested for their variability subjected for this observe. Approximately eighty-one (81) genotypes had been examined in a 9*9 easy lattice layout for his or her variability and relation of amongst trends using yield and yield related trends, qualitative, and first-class tendencies at Pawe Agricultural studies middle predominant station and Dibate substation in 2018-2019 cropping season. The analysis of variance discovered that all developments besides wide variety of nodules in line with plant, range of pods plant-1 and number of seeds pod-1 confirmed exceedingly substantial (p<0.01) differences at each tested places. Sixty three and sixty five percent of variations, from the entire, were revealed from the first 4 PCAs for Pawe and Dibate, respectively. Cluster evaluation confirmed about four specific clusters and the most inter cluster distance became determined among cluster I and cluster IV (D2=875.31) at Pawe and among cluster II and cluster IV (D2=1227.68) at Dibate. However, one season test might now not realize genotypes’ variability in response of environment; due to the fact quantitative traits are polygenic and profoundly affected by the environment. As a consequence, an addition experiment on those genotypes in changed seasons is needed for more real estimation of polygenic traits.},
year = {2023}
}
TY - JOUR T1 - Genetic Divergence and Principal Component Analysis of Soybean [Glycine max (L.) Merrill] Genotypes in Northwestern Ethiopia AU - Asmamaw Amogne Mekonen Y1 - 2023/10/14 PY - 2023 N1 - https://doi.org/10.11648/j.wjast.20230104.11 DO - 10.11648/j.wjast.20230104.11 T2 - World Journal of Agricultural Science and Technology JF - World Journal of Agricultural Science and Technology JO - World Journal of Agricultural Science and Technology SP - 76 EP - 82 PB - Science Publishing Group SN - 2994-7332 UR - https://doi.org/10.11648/j.wjast.20230104.11 AB - The quantity of Soybean produced and yield per given area in Ethiopia is small compared to the world average capability because of less varied soybean genotypes. The reason at the back of is due to a lack of various soybean genotype available and the genetic potential reduction of released varieties which have been in utilizing. Subsequently, genotypes that have not been characterized clustered and tested for their variability subjected for this observe. Approximately eighty-one (81) genotypes had been examined in a 9*9 easy lattice layout for his or her variability and relation of amongst trends using yield and yield related trends, qualitative, and first-class tendencies at Pawe Agricultural studies middle predominant station and Dibate substation in 2018-2019 cropping season. The analysis of variance discovered that all developments besides wide variety of nodules in line with plant, range of pods plant-1 and number of seeds pod-1 confirmed exceedingly substantial (p<0.01) differences at each tested places. Sixty three and sixty five percent of variations, from the entire, were revealed from the first 4 PCAs for Pawe and Dibate, respectively. Cluster evaluation confirmed about four specific clusters and the most inter cluster distance became determined among cluster I and cluster IV (D2=875.31) at Pawe and among cluster II and cluster IV (D2=1227.68) at Dibate. However, one season test might now not realize genotypes’ variability in response of environment; due to the fact quantitative traits are polygenic and profoundly affected by the environment. As a consequence, an addition experiment on those genotypes in changed seasons is needed for more real estimation of polygenic traits. VL - 1 IS - 4 ER -
Information
Email: