تحقیقات علوم زراعی در مناطق خشک

تحقیقات علوم زراعی در مناطق خشک

نخود (Cicer arietinum L.): دستاوردها و فرصت‌ها در تحمل به تنش‎های غیرزنده و انعطاف‌پذیری در شرایط متغیر آب و هوایی

نوع مقاله : مقاله مروری

نویسندگان
بهمن فاضلی نسب
سعیدرضا وصال
عبدالرضا باقری
سعید ملک زاده شفارودی
گروه بیوتکنولوژی و به نژادی گیاهی، دانشکده کشاورزی، دانشگاه فردوسی مشهد، مشهد، ایران
10.22034/csrar.2024.431689.1390
چکیده
در مقاله حاضر، تلاش شده است تا مروری به شیوه تحلیل محتوا با جستجوی کلید واژه‌های نخود، تنش خشکی، تنش‌های زنده و غیره زنده، پروتئومیکس، ژنومیکس، تجزیه ترانسکریپتوم، توالی­یابی RNA، هیبریداسیون و ریزآرایه در مقاله‌های مرتبط در پایگاه­های اینترنتی Google scholar،Web of science ،PubMed  و Scopus انجام شود. مکانیسم درک تنش در گیاه نخود، شامل، گیرنده‌های خاصی است که به سیگنال‌های برون سلولی خاص (مانند اینوزیتول فسفات، قندها، گونه‌های فعال اکسیژن (Reactive Oxygen Species)، یون‌های کلسیم (Ca2+)، نوکلئوتیدهای حلقوی (cAMP و cGMP) و اکسید نیتریک (Nitric oxide)) متصل می‌شوند و از طریق انتقال این سیگنال‌ها به سایر سلول‌ها، نیز پاسخ به تنش فراگیرتر خواهد شد. فعال‌سازی آنزیم‌های آنتی اکسیدانی کلیدی توسط سالیسیلیک اسید (Salicylic acid) نقش مهمی در بهبود تنش اکسیداتیو ناشی از تنش در گیاهان نخود داشته است. به موازات آن، مدیریت اثرات تنش، به ویژه در ریشه ها با تجمع قندها و پرولین، نیز ثابت شده است که بخشی جدایی ناپذیر از توسعه تحمل به تنش توسط SA است. هشت ژن پروتئین­های شوک حرارتی (Heat Shock Proteins)، تنظیم‌کننده زمان گلدهی (efl1، FLD، GI، Myb، SFH3، bZIP، bHLH و SBP) در نخود گزارش شده اند که نقش اساسی در تحمل تنش گرمایی دارند. QTLهایی در مناطق ژنومی LG4 و LG8 به ترتیب برای عملکرد در شرایط شوری و سرما، شناسایی شده­اند که به ترتیب بین 22/6 تا 48/5 و 11/5 تا 48/4 درصد از تغییرات فنوتیپی را توجیه می­نمایند. ادغام رویکردهای مختلف بهبود ژنتیکی، درک بهتر مکانیسم‌های مولکولی، بیوشیمیایی و فیزیولوژیکی درگیر در پاسخ به تنش­های غیرزیستی، تولید گیاه نخود متحمل به شرایط محیطی تنش‌زا را ممکن می‌سازد.
کلیدواژه‌ها
اصلاح نخود
پرایمینگ بذر
پرولین
تنش خشکی
سالیسیلیک اسید

عنوان مقاله English

Chickpea (Cicer arietinum L.): Achievements and opportunities in response to abiotic stresses and its flexibility to changing weather conditions

نویسندگان English

Bahman Fazeli-Nasab
Saeedreza Vessal
Abdolreza Bagheri
Saeid Malekzadeh-Shafaroudi
Department of Biotechnology and Plant Breeding, Faculty of Agriculture, Ferdowsi University of Mashhad, Mashhad, Iran
چکیده English

Introduction: Chickpea (Cicer arietinum L.) is the second most important leguminous crop that is cultivated in 59 countries of the world with an area of 13.98 million hectares and a production of 13.73 million tons. Chickpeas are cultivated throughout the Mediterranean basin, Central Asia, East Africa, Europe, Australia and North and South America, but mainly in developing countries, where more than 90% of chickpea production is consumed locally. Annual chickpea varieties are obtained from interspecies crosses with cultivated chickpeas and are classified into three gene pools (primary, secondary and tertiary), which indicate their genetic distance from cultivated varieties. Chickpeas have two types of white and usually large Kabuli seeds and colored and usually small desi seeds. In addition to the importance of chickpeas as an important food source in human diet and animal fodder, this plant can have significant importance in soil fertility, especially in rainfed areas and in rotation with cereals. Chickpea is very valuable due to its nutritional quality and health benefits and its ability to improve soil fertility and sustainability of agricultural systems. Due to the fact that chickpeas are often cultivated in marginal lands in a dry land and completely dependent on the moisture stored in the soil and rainfall during the growing season, it is affected by various abiotic stresses during its life cycle. In most cases, such tensions have overlapped each other, resulting in a significant decrease in crop growth and productivity. Plants undergo abiotic stresses through a series of morphological, physiological, biochemical and molecular changes in an attempt to compensate for such adversities.
Materials and Methods: In this article, an attempt has been made to review the method of content analysis by searching the keywords of chickpea, drought stress, living stress, etc., proteomics, genomics, transcriptome analysis, RNA sequencing, hybridization, microarray, chain reaction. Polymerase chain reaction in related articles in Google scholar, Web of science, PubMed and Scopus websites.
Results and Discussion: The extracellular signals that pea plants respond to, such as inositol phosphate, sugars, reactive oxygen species (ROS), calcium ions (Ca2+), cyclic nucleotides (cAMP and cGMP), and nitric oxide (NO), are coupled to particular receptors in the plant's stress sensing system. As a result of these signals being sent to additional cells, the plant's reaction to stress expands. Chickpea plants have benefited greatly from the activation of crucial antioxidant enzymes by SA, which has helped to reduce oxidative damage brought on by stress. Simultaneously, the development of stress tolerance by SA has also been demonstrated to be significantly influenced by the management of stress effects, particularly in roots where proline and sugar buildup occurs. In chickpea, eight HSP genes—flowering time regulators (efl1, FLD, GI, Myb, SFH3, bZIP, bHLH, and SBP)—have been identified. These genes are critical for the plant's ability to withstand heat stress. QTLs that account for 22.6–48.5% of the phenotypic variations have been found in the genomic areas of LG4 that are related to salinity performance. A QTL responsible for 11.5 to 48.4% of the phenotypic variations in cold stress tolerance has been found in LG8. The primary detrimental impact of cold stress on pea plants is that it results in freezing during cold stress, which severely damages membranes owing to cellular dehydration.
Conclusion: To produce pea plants that can withstand harsh environmental conditions, various genetic improvement techniques must be integrated, and our understanding of the molecular, biochemical, and physiological mechanisms involved in abiotic stress response must be improved. With consideration for the effects of climate change, a more precise and efficient screening/selection of genotypes and/or genes/alleles may help boost grain yield with medium- and long-term implications on chickpea production.

کلیدواژه‌ها English

Chickpea breeding
Drought stress
Proline
Salicylic acid
Seed priming
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