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The global agrifood landscape is undergoing rapid transformation, driven by an urgent need to enhance food security, promote environmental sustainability, and address the challenges posed by climate change. As the world population continues to grow, there is increasing pressure on agricultural systems to produce more food with fewer resources. Grain legumes-such as beans, lentils, peas, chickpeas, and soybeans-offer a vital solution to these challenges. They are not only rich sources of protein, vitamins, and minerals but also play a crucial role in sustainable farming practices through their ability to fix atmospheric nitrogen, improve soil health, and reduce greenhouse gas emissions. The edited book entitled “Grain Legumes towards Sustainable Agrifood Systems” delves into the multifaceted roles that grain legumes play in shaping sustainable agrifood systems. This book brings together diverse perspectives from experts in the fields of agronomy, crop science, food technology, and policy-making to highlight the potential of grain legumes in achieving global food security and sustainability goals. Through a comprehensive exploration of topics such as genetic improvement, crop management, soil health, pest and disease management, value addition, and market development, it provides a holistic understanding of the current status, challenges, and future prospects of grain legumes in the context of sustainable agriculture. he chapters in this book reflect the interdisciplinary nature of the subject, drawing on expertise from plant biology, agronomy, environmental science, nutrition, economics, and social sciences. Together, they provide a comprehensive overview of the potential of grain legumes to contribute to a sustainable future, highlighting both opportunities and challenges in realizing this potential. It covers a wide range of topics, from the genetic improvement of legumes for enhanced yield and stress resistance to innovative agronomic practices, value addition, and policy interventions that can promote the cultivation and consumption of these important crops.

Abstract Grain legumes face significant biotic stresses fromvarious pests and pathogens, leading to substantial yield losses worldwide. This chapter synthesizes recent advances in molecular approaches and biotechnological tools for developing resistant varieties and managing diseases in legumebased cropping systems. Novel genomic technologies, including CRISPRCas9 gene editing, marker-assisted selection (MAS), and next-generation sequencing (NGS), have revolutionized our understanding of host-pathogen interactions and accelerated the development of resistant cultivars. RNA interference (RNAi) technology has emerged as a promising tool for targeted pest control, while transcriptomics and proteomics approaches have helped identify key resistance genes and defense-related proteins. Integration of these molecular tools with traditional breeding programs has resulted in improved varieties with enhanced resistance to major pests like pod borers and diseases such as fusarium wilt and ascochyta blight. Additionally, biotechnological applications including biopesticides and disease-forecasting systems have strengthened integrated pest management strategies. This review highlights the potential of combining multiple molecular approaches for sustainable pest and disease management in legume cultivation while identifying future research directions and challenges in their widespread adoption. Keywords: Biopesticides, Biotechnological tools, Marker-assisted selection, Legume

Abstract Biological nitrogen fixation (BNF) is a critical ecological process carried out by grain legumes, which form symbiotic associations with nitrogen-fixing bacteria, primarily Rhizobium species. This natural mechanism converts atmospheric nitrogen (N2) into ammonia, a form that plants can readily utilize, significantly enhancing soil fertility and reducing the need for synthetic nitrogen fertilizers. The process begins with the recognition and infection of the legume roots by rhizobia, leading to the formation of specialized structures called nodules, where the bacteria convert atmospheric nitrogen into ammonia through the enzymatic action of nitrogenase. The symbiosis between legumes and rhizobia is tightly regulated by various genetic and environmental factors, including plant signalling molecules, soil conditions, and nutrient availability. Grain legumes, such as soybeans, chickpeas, and lentils, play a vital role in sustainable agriculture by improving soil health, promoting biodiversity, and providing a protein-rich food source. This overview explores the molecular mechanisms underlying BNF, the factors influencing the efficiency of this process, and its potential to enhance sustainable agricultural practices. Understanding the intricacies of BNF in grain legumes can inform breeding programs and management strategies aimed at maximizing the benefits of this natural process for agricultural productivity and environmental sustainability. Keywords: Nitrogenase, Biological Nitrogen Fixation, Environmental sustainability, Soil fertility

Abstract Biotic stress in plants refers to the adverse impact of living organisms, such as pathogens, pests, and nematodes, on plant growth, development, and productivity. These biotic agents can infect, infest, or parasitize plants, triggering a range of physiological and biochemical responses that compromise plant health. Biotic stress can manifest in various forms, including fungal diseases, bacterial blights, viral infections, insect infestations, and nematode attacks, leading to reduced crop yields, lower quality produce, and significant economic losses. Understanding biotic stress is crucial for developing effective management strategies to protect plants and ensure food security, as it poses a significant threat to agricultural productivity and sustainability. To enhance the productivity of grain legumes, a critical food source for millions, mitigating biotic stress is essential. By adopting effective strategies to manage biotic stressors like diseases, pests, and nematodes, legume yields can be significantly increased. This can be achieved through the development and deployment of resistant cultivars, integrated pest management (IPM) practices, cultural methods like crop rotation and sanitation, and biological control methods. Additionally, rhizobia and mycorrhizal inoculation can enhance plant defense and nutrient uptake, while precision agriculture techniques facilitate early detection and targeted management of biotic stress. By implementing these approaches, legume productivity can be boosted, ensuring food security, improving livelihoods, and meeting the growing demand for this vital crop. Keywords: Biotic stress, Integrated pest management, Legume productivity, Sustainability

Abstract Grain legumes, members of the Fabaceae family, are essential for global nutrition and sustainable agriculture. The legumes such as soybean, chickpea, lentil, pigeon pea, black gram, green gram, faba bean and field peas are renowned for their high protein and energy content. A core aspect of their significance lies in their ability to fix atmospheric nitrogen through symbiotic relationships with Rhizobium bacteria, enhancing soil fertility and reducing the need for synthetic fertilizers. This process, coupled with their role in carbon sequestration, positions legumes as crucial components of sustainable farming systems. Grain legumes, as C3 plants, rely on efficient carbon assimilation to convert atmospheric CO2 into biomass, supported by high nitrogen content for optimal photosynthesis. Additionally, the symbiotic nitrogen fixation within root nodules enables legumes to transform atmospheric nitrogen into forms usable by plants, thereby contributing to soil nitrogen pools and reducing greenhouse gas emissions. By integrating legumes into crop rotations, farmers can enhance soil health, lower fossil energy inputs, and support ecological sustainability. This comprehensive analysis underscores the critical roles of carbon and nitrogen assimilation in maximizing the environmental and agronomic benefits of grain legumes. Keywords: Carbon assimilation, Grain legumes, Nitrogen assimilation, Nitrogen fixation, Photosynthesis

Abstract Global food production needs to double by 50% by the middle of the 21st century to ensure food and nutritional security for 9 billion people. Climate change, particularly atmospheric CO2 and temperature, has a complex impact on sustainable food security. Climate change is a significant constraint on legume production globally, which is a crucial food, feed, and fodder source. Legumes fix atmospheric nitrogen through bacteria in root nodules, reducing greenhouse gas emissions and boosting soil C-sequestration. Climate change positively impacts grain legumes by allowing them to allocate above-ground photosynthates into below-ground parts (nodules), improving rhizospheres’ activities, plant biomass and nutrient use efficacy. However, temperature can also negatively affect grain legumes, leading to flower abortion and abnormal pod filling. However, climate models predict more extreme events in the future, affecting legume growth and development. Heat stress, elevated CO2 concentration, drought, and rainfall variability impact legume crop production, requiring adaptation options. Results show that legumes with C3 fixation pathways show higher photosynthesis, reduced photorespiration, biomass production, and water use efficiency under atmospheric CO2. However, temperature increases lead to faster development, shorter life cycles, and lower yields. Legumes can cope with atmospheric CO2 up to 1000 ppm by storing sucrose and starch. Protein synthesis and water stress also help legumes adapt to changing climates. To achieve targeted yields in changing climatic conditions, agronomic and genetic interventions must be integrated. Targeted breeding programs should select high-yielding, biotic stress-resistant, and abiotic stress-tolerant genotypes adapted to atmospheric CO2 and temperature conditions. Integrating grain legumes with desirable traits can provide resilience against climate change. Keywords: Climate change, Grain legumes, Nutritional security, Resilience, Rhizosphere, Water Use Effciency

Abstract Understanding genetic diversity is essential for achieving genetic improvement and conservation of grain legumes. These crops serve as important pulses grown and consumed all over the world, especially in Africa, South East Asia and America. Legumes serve as a good source of carbohydrates, oil, fibre and proteins. Grain legumes are a major source of food and nutrition globally. However, it has not been possible to enhance gain legume production to the required level, primarily due to the narrow genetic base of most of the legume crops, coupled with changing climatic conditions. Most grain legumes are lacking in desired plant ideotypes and resistance sources for various biotic and abiotic stresses. The genetic diversity conserved in gene banks globally is a major resource for crop breeding programs, but it is utilized only marginally. Therefore, in order to broaden the genetic base of grain legume crops and enhance the genetic gains made in improvement programs, conventional approaches and modern scientific tools should be integrated in a phased and carefully judged manner. The first phase should focus on the search for desired traits and the infusion of diversity into the cultivated gene pool through use of landraces and CWRs. The second phase should focus on the utilization of advanced selection tools, such as genomics, high-throughput precision phenotyping, and artificial intelligence, to exploit the hidden potential of the available genetic diversity; and the third phase should involve technologies such as mutational breeding, genome editing, and transgenic technologies to improve, modify any novel or alien traits that are not available in the entire crop gene pool. We presume that enrichment of the genetic diversity of cultivated grain legume gene pools, along with simultaneous improvements in their yield and plant type with the aid of advanced scientific tools, will enhance grain legume crop yields to the required level. Keywords: Crop improvement, Genetic diversity, Genome editing, Legume, Phenotyping

Abstract Grain legumes, also known as pulses, are vital to sustainable agriculture due to their roles in enhancing soil fertility, providing essential nutrition, and supporting environmental sustainability. By establishing symbiotic relationships with nitrogen fixing bacteria, legumes naturally enrich soil with nitrogen, reducing reliance on synthetic fertilizers and fostering sustainable farming practices. Their inclusion in crop rotations not only boosts soil health but also supports food security, especially in developing countries where they are a key source of plant based protein and nutrients. The impact of climate change, including rising temperatures, altered precipitation patterns, and increased frequency of extreme weather events, presents significant challenges to agriculture. In this context, grain legumes demonstrate considerable climate resilience. Their drought tolerance, heat resistance, and ability to fix atmospheric nitrogen make them well-suited to withstand climate stress. Legumes exhibit mechanisms such as deep root systems, efficient water use, and adaptability to diverse environmental conditions, contributing to their robustness in the face of climate variability. To bolster the role of grain legumes in climate-resilient agriculture, climate-smart practices and technological advancements are essential. These include optimizing planting strategies, adopting water-efficient methods, and breeding for improved resilience traits. Addressing challenges such as climate variability, pest pressures, and resource limitations is crucial for maintaining the benefits of legumes. Future efforts should focus on developing robust management practices and improved varieties to ensure the continued contribution of grain legumes to food security and environmental sustainability. Keywords: Climate Resilience, Drought Tolerance, Grain Legumes, Heat Resistance, Sustainable Agriculture, Water Use Efficiency

Abstract Grain legumes, a group of crops which belong to Fabaceae family, are primarily grown for their edible seeds. Pulses contain a high amount of protein (20-25%), vitamins, and minerals. Consumption of pulses can be beneficial for cardiovascular health, weight management, for diabetics, cancer management, bone health etc. So, grain legumes can play a significant role to address future global food security, environmental sustainability, and nutritional needs. The nutritional value of grain legumes can be significantly enhanced through biofortification, agronomic intervention, processing, and value addition. So, diversification of food habit with pulses and cereals can solve the prolong problem of malnutrition in developing countries including India. Despite such great importance, global food legume production has been found to increase at a very slow pace. Keywords: Biofortification, Environmental sustainability, Food security, Grain legumes, Nutritional security Introduction Grain legumes or pulses are a group of crops which belong to family Fabaceae, are primarily grown for their edible seeds. The common examples of grain legumes include: bean (Phaseolus spp.), lentil (Lens culinaris), chickpea (Cicer arietinum), pea (Pisum sativum), soybean (Glycine max), lupin (Lupinus spp.), broad bean (Vicia faba), igeon pea (Cajanus cajan), grass pea (Lathyrus sativus), black gram (Vigna mungo), green gram (Vigna radiata). Grain legumes can play a significant role to address future global food security, environmental sustainability, and nutritional needs. Pulses are the second most important food crop after cereals and an important source of proteins, vitamins, and minerals. Pulses are popularly known as “Poor man’s meat” and “Rich man’s vegetable”. Pulses contain a high amount of protein (20-25%), which is almost double and triple of the protein content of wheat and rice, respectively and so can contribute significantly to the nutritional security of the country. Besides, they may serve the purpose of protein rich fodder and good quality green manure crop. Pulses can thrive well in low and marginal land with less external inputs. They act as erosion resisting crops because of its deep tap root system, leafy growth, and close spacing. Pulses can also be grown as paira crop or inter-crop in different growing situations. Being a leguminous crop, it can fix atmospheric nitrogen with the help of its root nodules, resulting in low requirement of external fertilizer. Keeping the importance of pulses in mind, United Nation’s Food and Agricultural Organization (FAO) also declared 2016 as the ‘International Year of Pulses’.

Abstract The rapid increase in global food demand, driven by fast population growth, has made it challenging to provide nutritionally balanced diets. Pulses offer a promising solution to these challenges by delivering significant nutritional and physiological benefits. Pulses such as chickpeas, green gram, peas, horse gram, beans, lentils, black gram, and others are excellent sources of protein (190-260 g kg−1), carbohydrates (600-630 g kg−1), dietary fibers, and bioactive compounds. The phytochemicals found in pulses, including flavonoids, phenolics, tannins, phytates, saponins, oxalates, peptides, and enzyme inhibitors, offer numerous health benefits. Pulses, essential to human diets for centuries, have seen historically low consumption levels due to underappreciation of their nutritional value. Recognizing their significance, the United Nations designated 10 February as World Pulses Day, and declared the year, 2016 as International Year of Pulses emphasizing their role in promoting healthy diets, sustainable food production, and food security. India is the largest producer of pulses in the world accounting for 25% of the global pulse production. The production and productivity of pulses have slightly decreased due to great emphasis to rice and wheat crops. To boost pulse production, India has implemented initiatives like the National Food Security Mission and policies to support farmers, including Minimum Support Prices (MSP) and welfare schemes integrating pulses. These efforts aim to enhance pulse cultivation, ensure food security, and improve farmer incomes, addressing the demand-supply gap and declining per capita availability of pulses. Keywords: legumes, sustainable, oxalates, inhibitors, phytochemicals

Abstract The cultivation of grain legumes is expanding globally because of their diverse applications as food for humans, feed for livestock, and raw materials for industrial purposes. Legumes contribute significantly to sustainable agricultural practices due to their unique ability to fix atmospheric nitrogen through symbiosis with rhizobia bacteria in their root nodules. Incorporating legumes into cropping systems in place of traditional cereal-cereal rotations can significantly enhance agricultural sustainability due to their multiple benefits. Their role in nutrient cycling, particularly nitrogen and phosphorus, ensures that subsequent crops benefit from improved soil nutrient availability, making legumes an essential component of crop rotations and intercropping systems. Additionally, legumes improve soil structure, organic matter content, and decrease the environmental impact associated with excessive fertilizer use, such as greenhouse gas emissions and water pollution. With the increasing demand for plant-based foods and the economic challenges of fertilizing cereal crops, grain legumes are anticipated to play a more prominent role in cropping systems, especially in regions where fertilizer availability and affordability are limited. It includes studies on improving nitrogen fixation efficiency, enhancing phosphorus uptake, and developing varieties that are better adapted to specific environmental conditions and cropping systems. Additionally, there is a need to identify the most suitable legume species and varieties for different regions and cropping patterns to ensure maximum productivity and sustainability. Keywords: Climate change mitigation, Grain legumes, N fixation, P availability, Soil organic carbon

Abstract The growing global population has intensified farming practices, increasing the use of fossil fuels and agrochemicals. With limited land and the need to enhance food production, balancing environmental impact, especially carbon footprints, is crucial. Climate-smart mitigation options, with a prime emphasis on crop diversification, can help agriculture adapt to anomalous weather patterns and build resilience. Legumes offer a sustainable solution by reducing greenhouse gas emissions, as they produce 5-7 times less gases per unit area compared to other crops. They aid in carbon sequestration, with soil carbon estimates of 7.21 g kg-1 of dry matter, and save fossil energy by decreasing nitrogen fertilizer use, reducing CO2 emissions by 277 kg ha-1 per year. Legumes play a key role in low-emission farming systems due to their ability to fix atmospheric nitrogen, reducing dependence on energy-intensive synthetic fertilizers. They improve soil health, enhance soil structure, and support carbon sequestration. Integrating legumes into crop rotations reduces the need for chemical pesticides and fertilizers. Additionally, legumes can be used in food, feed, and biofuels, lowering reliance on more carbon-intensive resources. Embracing legumes in farming systems promotes sustainability improves soil health, and considerably reduces the overall environmentalimpact of agriculture. Keywords: Carbon Footprint, Greenhouse Gas Emissions, Legumes Sustainability

Abstract Remote sensing and image analysis have emerged as essential tools in modern agriculture, particularly for plant protection in grain-based legume cropping systems. These technologies are increasingly valuable in addressing challenges such as climate change, pest infestations, and the demand for sustainable practices. Grain legumes, including peas, beans, lentils, and chickpeas, are vital for global food security and soil health due to their protein content and nitrogen-fixing capabilities. However, their productivity is often threatened by pests, diseases, and weeds. Remote sensing allows for early detection of crop stress through analysis of specific wavelengths of light, enabling farmers to identify issues before visible symptoms appear. Tools like the normalized difference vegetation index (NDVI) provide insights into crop health, allowing for timely and targeted interventions. Hyperspectral and multispectral imaging further enhance disease detection by identifying physiological changes in crops that are not visible to the naked eye. In addition to disease monitoring, remote sensing aids in pest management by detecting changes in plant temperature profiles and utilizing drone surveillance for real-time data collection. Image analysis complements these efforts by offering detailed insights into crop conditions, enabling precision agriculture practices that minimize environmental impact and reduce costs. By integrating remote sensing and image analysis with other technologies like GIS and IoT, farmers can achieve more efficient, sustainable farming practices, ultimately leading to higher yields and better protection for grain legume crops. Keywords: Food security, Remote sensing, GIS, Grain legumes, IoT, Pest management

Abstract The United Nations predicts that by 2050, the global population will reach 9.6 billion, leading to urgent challenges such as ensuring food security and reducing greenhouse gas emissions. Climate change, coupled with biotic and abiotic pressures, will significantly impact global food production. Despite advances in agriculture, malnutrition remains a widespread issue, affecting millions, especially in developing countries. Protein-energy malnutrition, which affects over 170 million children and women, poses a significant threat to national economic development, increasing healthcare costs and reducing productivity. One key solution to combating malnutrition lies in promoting legumes (pulses), which are nutrient-dense, protein-rich, and vital for both human and animal consumption. Pulses have been a staple in diets for centuries, providing essential nutrients like protein, fiber, vitamins, and minerals. They are not only beneficial for human health, reducing the risk of heart disease, diabetes, and cancer, but they also contribute to sustainable agriculture. Legumes can fix atmospheric nitrogen, reducing the need for synthetic fertilizers, improving soil health, and increasing agricultural productivity. However, despite their benefits, pulse production lags behind other staple crops like cereals. With proper management, legumes could play a vital role in alleviating global hunger, particularly in developing countries. Increased awareness and efforts to incorporate legumes into farming systems and daily diets could help meet the growing global demand for nutritious, sustainable food. Keywords: Climate change, Food security, Global hunger, Legumes, Proteinenergy malnutrition, Sustainable agriculture

Abstract Food insecurity and malnutrition are on the rise globally, impacting millions, especially in rural regions where extreme poverty and food insecurity are deeply rooted. Vulnerable groups, including women, youth, and indigenous peoples, are disproportionately affected. Producing foo  that meets dietary needs and ensuring its availability in the future is essential for sustainable development and food sustainability. Addressing the growing global food security concerns and supporting the increasing population requires the continual expansion of plant-based proteins’ significance. Legumes are excellent sources of proteins, carbohydrates, and both soluble and insoluble dietary fibers. Legumes, with their high dietary fiber and low-fat content, help maintain body weight and lower the risk of cardiovascular disease. They are also rich in essential minerals such as potassium, calcium, magnesium, phosphorus, and iron, and provide important vitamins like folate, thiamine (B1), riboflavin (B2), and niacin (B3). Additionally, pulses contain various phytochemicals, including phenolics, flavonoids, phytates, lectins, tannins, saponins, oxalates, enzyme inhibitors, phytosterols, and antimicrobial peptides, which offer numerous potential health benefits. These phytochemicals exhibit anti-inflammatory, anticancer, antimicrobial, and anti-ulcerative properties. Incorporating legumes into agricultural systems can foster more sustainable and climate-resilient farming practices. In developing countries, legumes are often used to supplement cereals or starchy foods to combat protein-energy malnutrition, as animal proteins tend to be expensive in these regions. Keywords: Antioxidants, Food security, Legume, Malnutrition, Healthy diet

Abstract India shares one fourth of global annual grain legume production and is also largest consumer of it. Weeds are the most severe and widespread biological constraint on agricultural production systems and cause damage to cropped and non-cropped lands. They reduce crop yield and degrade the quality of the produce, besides raising the cost of production. The grain legumesare commonly grown under rainfed/dry land conditions and hence do not receive the best management practices that are required for maximization of crop productivity. Among various production inputs, weed management was found to be the most important one contributing about 31% in pigeon pea, 110% in urdbean and 60 % in mungbean towards total productivity. Effective weed management in grain legumes is essential for optimizing crop yield and quality. This process involves a multi-faceted approach that integrates cultural, mechanical, and chemical methods to address the challenges posed by diverse weed species and varying environmental conditions. Traditional single-method approaches often fall short due to the complexity and variability of weed problems like development of resistance in weeds. Therefore, an integrated weed management approach becomes effective, combining timely interventions with adaptive strategies to manage weed competition throughout the growing season. This approach not only enhances crop competitiveness and yield but also offers economic and environmental benefits by reducing reliance on broad-spectrum herbicides and promoting sustainable practices. Continuous monitoring and adjustment of weed management strategies are crucial to effectively tackle evolving weed populations and changing conditions, ensuring long-term success in grain legume cultivation. Keywords: Broad-spectrum herbicides, Crop productivity, Crop weed competition, Grain legume, Integrated weed management

Abstract Legumes are an excellent group of fertility restorer crops which can be grown either as sole crop or as a component crop in the cropping system. As they are tolerant to drought condition, they can be grown throughout the year. The yield of legume crop is largely depending on pest, diseases and weeds. Among these weeds plays a major role as the weed seed bank inside the soil influence the weed population in the cropping season. Hence it is important to manage the weed seed bank for better productivity of legumes. Though legumes are short duration and fast growing crops, the germination percentage of weed seed bank will determine the final yield of legumes. There are many strategies to which the weed seed bank can be controlled to tolerable level before which the weed seed bank present in the soil has to estimate. Annual weed seed bank can be minimized by killing the weeds before they set seeds, harvest weeds, crop rotation, cover crops, inter cropping and ensiling. Weed seed bank depletion can be done by tillage, tricking the weed seeds, conditioning weed seeds, soil solarisation and herbicide application. Thus integrating various technologies may help in effective controlling of weed seeds to tolerable level thereby enhancing the yield of leguminous crops. Keywords: Estimation of weed seed bank, legumes, tillage, yield, weed seed bank