Plants And Microbial Communities Diversity Pathogens And Biological Control

Biological balance. The biological world. Attributes of a successful parasite. Types of biological interactions. Man, the disrupter of balance. The changing scene. Factors involved in biological control. A plant pathologist's definition of biological control. Comparative approaches to biological control of plant pathogens and insects. Applying biological control. Biological control in plant pathology. The stature of biological control of plant pathogens. Resident antagonists. Managing the biological balance. Biological control by resident organisms and introduced organisms. Host resistance. Ecological manipulation to control weed molds and pathogens of mushrooms. Approaches to biological control with antagonistic microorganisms. Selecting soil as a source of antagonists. Antagonistic populations of whole soils. Presumptive tests of antagonists in agar culture. Tests in soil. Testing mixtures of antagonists. Plant of action. Role of the pathogen in biological control. Ways the pathogen can overcome antagonism. Vulnerability during dormancy and saprophytic growth. Populations of soilborne pathogenic fungi that produce disease. Stimulation of antagonists by the pathogen. Control of nematodes by altering the sex ratio. Role of the antagonist in biological control. Biological efficiency of saprophytic organisms. Kinds of antagonists. Forms of antagonism. The ideal antagonist. Inoculation with avirulent organisms related to the pathogen. Recontamination of soil. Biological buffering by resident antagonists. Role of the host in biological control. Root dynamics. Physical and chemical features of the rhizosphere. Root exudation and the rhizosphere effect. Cropping history and the microbiological balance of soil. Plant residues. The host as a reservoir of inoculum. Decoy, trap, and inhibitory plants. Role of the physical environment in biological control. environment operative through the host and during dormancy of the pathogen. Environment operative during growth of the pathogen. Using environment for prediction. Using environment to nudge the biological balance. Integration between biological and chemical control. Biological control of pathogens of aerial parts. Microorganisms on aerial parts. Pathogens on aerial parts. Exudation to external surfaces. Natural dissemination of epiphytes. Whither biological control?. Stage in pathogen cycle to apply biological control. Agroecosystems in relation to biological control. Applying, activating, or assisting antagonists. Large-scale production of antagonists. Integrated control. Why biological control?. The role of biological control in plant pathology.

The basis of biocontrol (in microbiology, ecology and plantpathology) is described and many examples of control measures in commercial use or development are given

Molecular Mechanisms of Plant and Microbe Coexistence presents studies on the complex and manifold interactions of plants and microbes at the population, genomics and proteomics level. The role of soil microbial diversity in enhancing plant health and plant microbe beneficial symbioses is discussed. Microbial communities are shown in the light of evolution. Main topics include genome coexistence and the functional genomics and proteomics of plant-associated microbes, which could form the basis for new environmentally benign strategies to combat infectious plant diseases and regulate plant growth. Further chapters focus on the role of signaling during the different stages of plant microbe coexistence, in symbiotic or pathogenic relationships, in quorum sensing and plant viral infections. Methods for studying the interactions in the root zone complement the book, which will certainly be of relevance in the practical application to agriculture, food security and for maintaining the balance of our ecosystems.

The roles of microbes in agriculture, industry and environment have been the point of interest since long time for their potential exploitation. Although only a fraction of microbial diversity was accessed by microbiologists earlier for harnessing them owing to limited techniques available. The molecular techniques have opened new vistas to access the wide field of the unexplored microbes and their exploitation for useful genes and novel metabolites. Sincere efforts have been made in biotechnology using microbes leading to improve our life with respect to agriculture and people health. This comprehensive volume covers different aspects of microbial biotechnology and its management in sustainable agriculture for food security and improved human health. The book comprises four sections: Endophytes and Mycorrhizae, Microbial Diversity and Plant Protection, Microbial Functions and Biotechnology, and Microbes and the Environment, which contain 53 chapters. The book examines the aspects on endophytes and mycorrhizae, bioactive compounds, growth promoting microorganisms, disease management with emphasis on biocontrol, genetics of disease resistance, microbial enzymes, advances in potential of microbes and their industrial as well as pharmaceutical applications. In addition, the use of botanicals, and the etiology and management of medicinal and aromatic plants in the post harvest management have been reviewed in greater depth for the benefit of teaching and research community. The biotechnological developments using microbe potential have enabled us combat the environment and human health problems worldwide in ecofriendly manner. We are sure that this volume will be highly useful to all those concerned with fungi, bacteria, viruses and their biology, including environmental and public health officers and professionals in the field of interest. The volume is an exhaustive coverage of almost all the aspects of microbial biology and biotechnology.

The book discusses the complex interactions between plants and their associated microbial communities. It also elucidates the ways in which these microbiomes are connected with the plant system, and how they affect plant health. The different chapters describe how microbiomes affect plants with regard to immunity, disease conditions, stress management and productivity. In addition, the book describes how an ‘additional plant genome’ functions as a whole organ system of the host, and how it presents both challenges and opportunities for the plant system. Moreover, the book includes a dedicated section on using omics tools to understand these interactions, and on exploiting them to their full potential.

This book shares the latest insights into the genetic basis of molecular communication between plants and their microbial consortia. Further, the book highlights the capabilities of the rhizosphere and endosphere, which help manage ecosystem responses to climate change, nutrient cycling and sequestration of carbon; and discusses their application to the development and management of renewable energy sources. In their natural environments, plants are surrounded by a tremendous number of microorganisms. Some microbes directly interact with plants in a mutually beneficial fashion, while others colonize plants solely for their own advantage. In addition, microbes can indirectly affect plants by drastically altering their environments. Understanding the complex nature of the plant-microbe interface (PMI) can pave the way for novel strategies to improve plant productivity in an eco-friendly manner. The PMI approach focuses on understanding the physical, molecular, and chemical interactions between organisms in order to determine their functional roles in biological, physical, chemical and environmental systems. Although several metabolites from plants and microbes have now been fully characterized, their roles in chemical interactions between these associates remain poorly understood, and require further investigation.