بررسي سازگاري و پايداري عملكرد دانه لاين هاي گندم دوروم تحت شرايط ديم با استفاده از GGE باي پلات و AMMI

GGE biplot and AMMI application in the study of adaptability and grain yield stability of durum lines under dryland conditions

بررسي اثر متقابل ژنوتيپ در محيط قبل از معرفي ارقام جديد پايدار و سازگار ضروري است. به منظور ارزيابي كارايي استفاده از GGE باي پلات و AMMI در مطالعه پايداري و سازگاري عملكرد دانه لاين هاي گندم دوروم در مناطق ديم معتدل و سرد، تعداد 17 ژنوتيپ پيشرفته دوروم به همراه شاهدها (ساجي، زردك و سرداري) به مدت سه سال زراعي (93-1390) در مناطق مراغه، سرارود، قاملو، اردبيل و شيروان در قالب طرح بلوك هاي كامل تصادفي در 3 تكرار تحت شرايط ديم كشت شدند. بر اساس نتايج تجزيه واريانس مركب، بين محيط ها، ژنوتيپ ها و اثر متقابل ژنوتيپ در محيط اختلاف آماري معني داري مشاهده گرديد. بزرگي اثرات اصلي براي محيط، ژنوتيپ و اثر متقابل ژنوتيپ در محيط به ترتيب 80 درصد، 4 درصد و 9 درصد مجموع مربعات كل بود. ميزان پوشش سبز، تيپ رشد زمستانه، شاخص زراعي و ارتفاع گياه همبستگي مثبت با عملكرد دانه داشته، ولي همبستگي عملكرد با صفات تعداد روز تا خوشه دهي و رسيدگي منفي بود. بر اساس نتايج GGE باي پلات، محيط ها به سه گروه و ژنوتيپ ها به چهار گروه تفكيك شدند. ارزيابي پايداري ژنوتيپ ها با استفاده از آماره پايداري امي (ASV) و GGE باي پلات نشان داد لاين هايي نظير راسكون در مناطق سردي مثل مراغه، قاملو و اردبيل مي توانند منبع ژنتيكي مطلوبي براي معرفي ارقام جديد دوروم باشند. نتايج AMMI و شاخص پايداري امي (ASV) در مقايسه با نتايج GGE باي پلات نشان داد تمامي اين شاخص ها از پتانسيل خوب براي ارزيابي پايداري عملكرد ژنوتيپ ها برخوردار بوده ولي GGE باي پلات بسيار كاربردي تر بوده و مي تواند به صورت گسترده اي در بررسي ژنوتيپ ها در مناطق و سال هاي متعدد در برنامه هاي اصلاح غلات بكار گرفته شود.

Introduction Durum wheat (Triticum turgidum var. durum) is grown for human consumption, mainly as pasta products, e.g., spaghetti and macaroni, couscous, bulgur, frike, flat breads, etc. Worldwide, the area annually planted to durum wheat is estimated to be around 17-18 million hectares, i.e., 8 percent of total wheat area, with a production averaging about 30 million tons annually, which is 5.5 percent of total wheat production. Although durum is grown in various regions of the world, the great bulk of durum area and production is concentrated in the Mediterranean basin and North America. Eight countries (Algeria, Canada, Italy, Morocco, Syria, Tunisia, Turkey, and USA) account for nearly two thirds (2/3) of world durum area and production. In Iran, the area under durum cultivation is about 400-500 thousands hectares with an annual production of 400-500 thousand tons, which covers about 60% of country demands. In spite of the importance of durum for Iranian rural economies, the country has not all succeeded in its research and development efforts to substantially improve durum productivity. The combinations of increasing demand for durum and durum products, as a result of demographic pressure, and relatively low durum productivity partly due to abiotic stresses (i.e. cold, terminal heat, moisture and nutrient deficiency stresses) made the country to an importer of durum. These are frequently exacerbated by biotic stresses, e.g., diseases and insects that may severely inhibit crop growth. Materials and methods The main purpose of this study was to achieve high yielding durum wheat genotypes with higher yield stability in different environmental condition, tolerance to environmental stresses such as cold damage, drought and end of season heat stress. Hence, 17 durum wheat lines were evaluated for grain yeild and morphlogical traits in Maragheh, Sararood, Qamloo, Ardabil and Shirvan agricultural research stations in 2011-14. In each location, the experiments were conducted in a randomized complete block design with three replications. Results and discussion Based on combined ANOVA, there was significant difference among the environments, genotypes and G×E. GGE-biplot models showed that the 5 environments were belonged to 3 mega-environments, and different genetopes had higher yield in each mega-environments. Sumplimentary irrigation, at sowing time and flowering growth stages, could increase grain yield of lines 30 and 70 percent in Maragheh and Qamloo locations, respectively. The increase of grain yield was 42 percent for line Rascon under suplimentary irrigation. The AMMI and GGE results also confirmed genotype 5 was the most high-yielding durum line with reasonable yield stability in cold areas (Maragheh, Qamloo and Ardabil). Also, genotype 13 was the most high yielding and stable line in Sararood. Hence, these line can be candiatted to release new durum varieties for cold and moderat rainfed areas. Complementary irrigation could increase grain yield up to 30 and 70 percent in Maragheh and Sararood, respectively. Conclusions It can be concluded that finding of new stable high-yielding durum lines, with better performances than that the existed varieies, is a great progress in durum breeding programs in cold rainfed areas. Both GGE biplot and AMMI analyses could be used in grain yield stability and adaptability under rainfed conditions and sumplementary irrigations, however, the results of GGE biploet were more applicable and can be use extensively in the study of grain yield adaptability and stability under rainfed and sumplementary irrigations conditions in durum wheat breeding programs.