Authors: Zia Amjad, Salem S. Alghamdi

Abstract:

The study was conducted at the student educational farm at the College of Food and Agriculture in the Kingdom of Saudi Arabia. The aim of study was to characterize 154 Vicia faba L. accessions using agro-morphological traits based on The International Union for the Protection of New Varieties of Plants (UPOV) and The International Board for Plant Genetic Resources (IBPGR) descriptors. This research is significant as it contributes to the understanding of the genetic diversity and potential yield of V. faba in Saudi Arabia. In the study, 24 agro-morphological characters including 11 quantitative and 13 qualitative were observed for genetic variation. All the results were analyzed using multivariate analysis i.e., principal component analysis (PCA). First, six principal components (PC) had eigenvalues greater than one; accounted for 72% of available V. faba genetic diversity. However, first three components revealed more than 10% of genetic diversity each i.e., 22.36%, 15.86% and 10.89% respectively. PCA distributed the V. faba accessions into different groups based on their performance for the characters under observation. PC-1, which represented 22.36% of the genetic diversity, was positively associated with stipule spot pigmentation, intensity of streaks, pod degree of curvature and to some extent with 100 seed weight. PC-2 covered 15.86 of the genetic diversity and showed positive association for average seed weight per plant, pod length, number of seeds per plant, 100 seed weight, stipule spot pigmentation, intensity of streaks (same as in PC-1) and to some extent for pod degree of curvature and number of pods per plant. PC-3 revealed 10.89% of genetic diversity and expressed positive association for number of pods per plant and number of leaflets per plant. This study contributes to the understanding of the genetic diversity and potential yield of V. faba in the Kingdom of Saudi Arabia. By establishing a core collection of V. faba, the research provides a valuable resource for future conservation and utilization of this crop worldwide.

Keywords: Agro-morphological characterization, genetic diversity, core collection, PCA, Vicia faba L.

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References:

[1] Akibode, S. & Maredia, M. (2011). Global and regional trends in production, trade and consumption of food legume crops. Draft Report, March, 27, 2011.
[2] Duc, G. (1997). Faba bean (Vicia faba L.). Field Crops Research, 53(1), 99-109.
[3] FAO. (2007). Food and agriculture organization of the United Nations. FAOSTAT. Available http://faostat.fao.org.
[4] FAO. (2008). Food and agriculture organization of the United Nations. FAOSTAT. Available www.fao.org/ag/statist.asp. Assessed at October 28, 2011.
[5] Gresta, F., Avola, G., Albertini, E., Raggi, L. & Abbate, V. (2010). A study of variability in the Sicilian faba bean landrace ‘Larga di Leonforte’. Genetic Resources and Crop Evolution, 57(4), 523-531.
[6] De Giorgio, D. & Polignano, G. (2001). Evaluating the biodiversity of almond cultivars from a germplasm collection field in Southern Italy. Sustaining the Global Farm, 56, 305-311.
[7] Nadal, S., Suso, M. & Moreno, M. (2003). Management of Vicia faba genetic resources: changes associated to the selfing process in the major, equina and minor groups. Genetic Resources and Crop Evolution, 50(2), 183-192.
[8] Terzopoulos, P. & Bebeli, P. (2008). Genetic diversity analysis of Mediterranean faba bean (Vicia faba L) with ISSR markers. Field Crops Research, 108(1), 39-44.
[9] Metayer, N. (2004). Vicia faba breeding for sustainable agriculture in Europe-identification of regional priorities and definition of target genotypes. GIE Févérole, Paris, 5.
[10] Gass, T. (1996). Report of a Working Group on Grain Legumes: First Meeting, 14-16 July 1995, Copenhagen, Denmark: International Board for Plant Genetic Resources.
[11] Alghamdi, S. S. (2007). Genetic behavior of some selected faba bean genotypes. In African Crop Science Conference Proceedings, vol. 8, pp. 709-714.
[12] Kumar, J., Choudhary, A. K., Solanki, R. K. & Pratap, A. (2011). Towards marker assisted selection in pulses: a review. Plant Breeding, 130(3), 297-313.
[13] Monti, L., Pace, C. D. & Scarascia Mugnozza, G. (1991). Faba bean (Vicia faba L.) cultivation and research in Italy. Options Mediterraneennes. Serie A: Seminaires Mediterraneens.
[14] Lawrie, A. C. & Wheeler, C. (1975). Nitrogen fixation in the root nodules of Vicia faba L. in relation to the assimilation of carbon. New Phytologist, 74(3), 437-445.
[15] Robertson, L. (1983). Faba bean germplasm collection, maintenance, evaluation, and use. In Faba Beans, Kabuli Chickpeas, and Lentils in the 1980s, Proceedings of an International Workshop, pp. 16-21.
[16] IBPGR, I. (1985). Faba bean descriptors. International Board for Plant Genetic Resources, Rome.
[17] UPOV. (2003). International union for the protection of new varieties of plants. TG/206/1, Broad bean.
[18] Abdi, H. & Williams, L. J. (2010). Principal component analysis. Wiley Interdisciplinary Reviews: Computational Statistics, 2(4), 433-459.
[19] Kumar, V., Tan, P.-N. & Steinbach, M. (2006). Cluster analysis: basic concepts and algorithms. Introduction to data mining, 487-586.
[20] Kwon, S. & Torrie, J. (1964). Heritability and interrelationship among traits of two soybean populations. Crop Sci, 4(2), 196-198.
[21] Pearson, K. (1901). On Lines and Planes of Closest Fit to Systems of Points in Spac. Philosophical Magazine. Journal of sound and vibration, 2, 559–572.
[22] Wold, S., Esbensen, K. & Geladi, P. (1987). Principal component analysis. Chemometrics and intelligent laboratory systems, 2(1), 37-52.
[23] Stoilova, T. Z. 2007. The collection of dry beans as initial materials for breeding. International scientific conference “Plant genetic stocks-the basis of agriculture of today, 13-14 June, 2007, Sadovo, pp. 53-58.
[24] Weatherspark. (2014). Average monthly meteorological data. Available http://weatherspark.com/averages/32777/Riyadh-Saudi-Arabia