باسیلوس سابتیلیس و نقش آن در کنترل بیولوژیکی پاتوژن‌های گیاهی

نوع مقاله : مقاله پژوهشی

نویسندگان

دانشکده فنی المسیب، دانشگاه فنی الفرات الاوسط، 51009 بابل، عراق.

10.22103/jab.2025.25589.1736

چکیده

هدف: افزایش تقاضا برای کشاورزی پایدار و کاهش استفاده از سموم شیمیایی، علاقه به جایگزین‌های سازگار با محیط‌زیست برای کنترل پاتوژن‌های گیاهی را افزایش داده است. در میان عوامل بیولوژیکی، باسیلوس سابتیلیس به دلیل مکانیسم‌های متنوع عمل، از جمله تولید آنتی‌بیوتیک، تحریک مقاومت سیستمیک در گیاهان و تقویت رشد گیاه، به‌عنوان یک عامل کنترل بیولوژیکی نویدبخش ظاهر شده است. این مقاله مروری با هدف بررسی ویژگی‌های بیولوژیکی و اکولوژیکی باسیلوس سابتیلیس، مکانیسم‌های آن در سرکوب پاتوژن‌های گیاهی و خلاصه‌سازی تحقیقات اخیر در مورد اثربخشی آن به‌عنوان یک عامل کنترل بیولوژیکی انجام شد.
مواد و روش‌ها: این مطالعه یافته‌های حاصل از طیف گسترده‌ای از مطالعات داوری و چاپ شده، آزمایش‌های میدانی و آزمایش‌های آزمایشگاهی متمرکز بر استفاده از باسیلوس سابتیلیس علیه پاتوژن‌های قارچی، باکتریایی و ویروسی گیاهان را ترکیب کرده است. مکانیسم‌های کلیدی عمل، از جمله کلونیزاسیون ریزوسفر، تولید آنتی‌بیوتیک، تحریک مقاومت سیستمیک القایی (ISR) و ویژگی‌های تقویت‌کننده رشد، تحلیل شدند. مطالعات موردی خاص و کاربردهای تجاری بررسی شدند تا دیدگاهی جامع درباره پتانسیل و محدودیت‌های این موجود زنده در برنامه‌های مدیریت یکپارچه آفات ارائه شود.
نتایج: باسیلوس سابتیلیس کارایی بالایی در سرکوب پاتوژن‌های مهم گیاهی مانند فوزاریوم spp.، ریزوکتونیا سولانی، فیتوفتورا اینفستانس و رالستونیا سولاناسئاروم از طریق مکانیسم‌های هم‌افزای متعدد نشان داد. این باکتری بیش از 66 آنتی‌بیوتیک شناخته‌شده (مانند سورفاکتین، فنگیسین، سابتیلین)، آنزیم‌های هیدرولیتیک مانند کیتیناز و β-1,3-گلوکاناز تولید می‌کند و بیوفیلم‌های مقاومی در ریزوسفر تشکیل می‌دهد که توانایی کلونیزاسیون آن را افزایش می‌دهد. مقاومت سیستمیک القایی ناشی از ب. سابتیلیس شامل افزایش بیان آنزیم‌های مرتبط با دفاع و مسیرهای هورمونی، به‌ویژه اسید جاسمونیک و اتیلن است. علاوه بر این، باسیلوس سابتیلیس جذب مواد مغذی، تثبیت نیتروژن و مقاومت در برابر استرس را در گیاهان تقویت می‌کند. مطالعات میدانی و فرمولاسیون‌های تجاری (مانند Kodiak، Serenade، وSubtilex ) اثربخشی آن را در شرایط محیطی متنوع تأیید می‌کنند. شواهد بررسی‌شده از اثرات ضدقارچی گسترده و تقویت‌کننده رشد گیاه پشتیبانی می‌کند.
نتیجه‌گیری: باسیلوس سابتیلیس ابزاری قدرتمند و ایمن برای محیط‌زیست، برای کنترل بیولوژیکی پاتوژن‌های گیاهی و افزایش بهره‌وری محصولات کشاورزی ارائه می‌دهد. نقش چندوجهی آن در سرکوب بیماری‌ها، فعال‌سازی دفاع گیاهی و بهبود سلامت خاک، آن را به‌عنوان یک جزء کلیدی در کشاورزی پایدار قرار می‌دهد. پذیرش محصولات کنترل بیولوژیکی مبتنی بر باسیلوس سابتیلیس با اهداف جهانی برای کاهش وابستگی به سموم شیمیایی، ترویج کشاورزی ارگانیک و دستیابی به پایداری بلندمدت کشاورزی بدون اثرات منفی اکولوژیکی یا بهداشتی هم‌راستا است.

کلیدواژه‌ها

عنوان مقاله [English]

Bacillus subtilis and its role in biological control of plant pathogens

نویسندگان [English]

  • Iqbal Harbi Kadhim
  • Ahed. A. H. Matloob
Al-Mussaib Technical College, Al-Furat Al-Awsat Technical University, 51009 Babylon, Iraq.
چکیده [English]

Objective
The increasing request for sustainable agriculture and reduced chemical pesticide apply has driven interest in eco-friendly alternatives to control plant pathogens. Among biological agents, Bacillus subtilis has emerged as a hopeful biocontrol agent due to its diverse mechanisms of action, containing antibiotic production, induction of systemic resistance in plants, and plant growth promotion. This review aims to examine the biological and ecological characteristics of B. subtilis, its mechanisms in suppressing plant pathogens, and summarize recent research on its effectiveness as a biocontrol agent.
Materials and Methods
This review synthesized results from a broad range of peer-reviewed investigations, field experiments, and laboratory trials centralized on the applying of B. subtilis against fungal, bacterial, and viral plant pathogens. Key mechanisms of action were analyzed, containing rhizosphere colonization, antibiotic production, induction of systemic resistance (ISR), and growth-promoting traits. Specific case investigations and commercial applications were reviewed to prepare a comprehensive perspective on the organism’s potential and limitations in integrated pest management programs.
Results
Bacillus subtilis demonstrated high effectiveness in suppressing major plant pathogens like Fusarium spp., Rhizoctonia solani, Phytophthora infestans, and Ralstonia solanacearum through multiple synergistic mechanisms. The bacterium generates over 66 known antibiotics (e.g., surfactin, fengycin, subtilin), hydrolytic enzymes like chitinase and β-1,3-glucanase, and forms robust biofilms in the rhizosphere, enhancing its colonization capability. ISR triggered by B. subtilis involves improved expression of defense-related enzymes and hormone pathways, notably jasmonic acid and ethylene. Furthermore, B. subtilis enhances nutrient uptake, nitrogen fixation, and stress resilience in plants. Field investigations and commercial formulations (e.g., Kodiak, Serenade, Subtilex) affirm its effectiveness under varied environmental conditions. The reviewed evidence supports its broad-spectrum antifungal and plant growth-promoting effects.
Conclusions
Bacillus subtilis shows a powerful, environmentally safe tool for the biological control of plant pathogens and the enhancement of crop productivity. Its multifaceted role in disease suppression, plant defense activation, and soil health improvement positions it as a key component of sustainable agriculture. Adoption of B. subtilis-based biocontrol products aligns with global goals for reducing chemical pesticide reliance, promoting organic farming, and achieving long-term agricultural sustainability without adverse ecological or health effects.

کلیدواژه‌ها [English]

  • antibiotics
  • Bacillus subtilis
  • biological control
  • pathogens
  • plant diseases

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مجله بیوتکنولوژی کشاورزی
دوره 17، شماره 3
شهریور 1404
صفحه 293-312

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