Unravelling Plant-Microbe Synergy focuses on agriculturally important microorganisms (AIM's) that are indigenous to soil and roots of the plant. These microbes contributing to nutrient balance, growth regulators, suppressing pathogens, alleviate stress response, orchestrating immune response and improving crop performance as they are offering sustainable and alternative solutions to the use of chemicals in agriculture. As plant microbe synergy is an enthralling subject, is multidisciplinary in nature, and concerns scientists involved in applied, and environmental microbiology and plant health and plant protection, Unravelling Plant-Microbe Synergy is an ideal resource that emphasizes the current trends of, and probable future of, microbes mediated amelioration of abiotic and biotic stress, agriculture sustainability, induced systemic tolerance and plant health protection. Unravelling Plant-Microbe Synergy discloses the microbial interaction for stress management and provides a better understanding to know the recent mechanisms to cope these environmental stresses. Unravelling Plant-Microbe Synergy bridges the gap in recent advances in the microbes interaction and rhizosphere engineering.

The world population is expected to increase exponentially within the next decade, which means that the food demand will increase and so will waste production. There is a need for effective food waste management as wasted food leads to overutilization of water and fossil fuels and increasing greenhouse gas emissions from the degradation of food. Global Initiatives for Waste Reduction and Cutting Food Loss explores methods for reducing waste and cutting food loss in order to help the environment and support local communities, as well as solve issues including that of land space. Covering topics that include food degradation, enzymes, and microorganisms, this publication is designed for policymakers, environmentalists, engineers, government officials, researchers, scientists, academicians, and students.

Cover microbial enzymes with comprehensive and in-depth information Benefits students by describing recent advancements into microbial enzymology Provides updates regarding microbial enzymes for researchers and industrial scientists Includes findings on the microbial actions for better life

This volume provides a wide range of aspects related to mycoremediation, which can be applied for both basic and advanced multidisciplinary research. Chapters guide readers through screening of fungi, Polyaromatic Hydrocarbons (PAHs), textile dyes, pesticides, bioreactors, molecular methods, redictive Mycology and Proteomics approaches to select fungi, elucidating biological mechanisms, and fungal laccase enzyme-based biosensors for the detection of environmental contaminants. Authoritative and cutting-edge, Mycoremediation Protocols aims to be a practical guide on the functional properties of poorly known applications of fungi in order to find solutions for increasing environmental problems.

Smart Bioremediation Technologies: Microbial Enzymes provides insights into the complex behavior of enzymes and identifies metabolites and their degradation pathways. It will help readers work towards solutions for sustainable medicine and environmental pollution. The book highlights the microbial enzymes that have replaced many plant and animal enzymes, also presenting their applications in varying industries, including pharmaceuticals, genetic engineering, biofuels, diagnostics and therapy. In addition, new methods, including genomics andmetagenomics, are being employed for the discovery of new enzymes from microbes. This book brings all of these topics together, representing the first resource on how to solve problems in bioremediation.

This volume provides a wide range of aspects related to mycoremediation, which can be applied for both basic and advanced multidisciplinary research. Chapters guide readers through screening of fungi, Polyaromatic Hydrocarbons (PAHs), textile dyes, pesticides, bioreactors, molecular methods, redictive Mycology and Proteomics approaches to select fungi, elucidating biological mechanisms, and fungal laccase enzyme-based biosensors for the detection of environmental contaminants. Authoritative and cutting-edge, Mycoremediation Protocols aims to be a  practical guide on the functional properties of poorly known applications of fungi in order to find solutions for increasing environmental problems. 

The world population is expected to increase exponentially within the next decade, which means that the food demand will increase and so will waste production. There is a need for effective food waste management as wasted food leads to overutilization of water and fossil fuels and increasing greenhouse gas emissions from the degradation of food. Global Initiatives for Waste Reduction and Cutting Food Loss explores methods for reducing waste and cutting food loss in order to help the environment and support local communities, as well as solve issues including that of land space. Covering topics that include food degradation, enzymes, and microorganisms, this publication is designed for policymakers, environmentalists, engineers, government officials, researchers, scientists, academicians, and students.

Microorganisms are a major part of the Earth's biological diversity. Although a lot of research has been done on microbial diversity, most of it is fragmented. This book creates the need for a unified text to be published, full of information about microbial diversity from highly reputed and impactful sources. Recent Advancements in Microbial Diversity brings a comprehensive understanding of the recent advances in microbial diversity research focused on different bodily systems, such as the gut. Recent Advancements in Microbial Diversity also discusses how the application of advanced sequencing technologies is used to reveal previously unseen microbial diversity and show off its function.

Advanced Microbial Technology for Sustainable Agriculture and Environment focuses on plant-microbe interactions in respect to bioremediation and plant growth promotion, providing insights on diverse approaches such as genomics, metagenomics, proteomics, bioinformatics and other high-throughput analyses of environmentally relevant microorganisms. The impact of frequent applications of potentially toxic chemicals (pesticides and fertilizers) and increased industrialization processes on microbial diversity emphasizes the potential threat to microbial biodiversity in ecosystems. This is an ideal resource on current trends and the future of PGPR developments with bioremediation potential. Moreover, it gives a deep understanding of the genetics of microbial biodegradation and different remediation mechanisms that help to re-establish the natural environment.