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. Emphasizes the plant microbes interactions, induced systemic tolerance, stress responsive genes and diversity of microorganisms Illustrates the current impact of climate change on plant productivity along with mitigation strategies Provides a two-way interactive approach to both plants and microbes, and includes multi-omics approaches

Secretomics describes the global study of proteins that are secreted by a cell, a tissue or an organism, and has recently emerged as a field for which interest is rapidly growing. The term secretome was first coined at the turn of the millennium and was defined to comprise not only the native secreted proteins released into the extracellular space but also the components of machineries for protein secretion. Two secretory pathways have been described in fungi: i) the canonical pathway through which proteins bearing a N-terminal peptide signal can traverse the endoplasmic reticulum and Golgi apparatus, and ii) the unconventional pathway for proteins lacking a peptide signal. Protein secretion systems are more diverse in bacteria, in which types I to VII pathways as well as Sec or two-arginine (Tat) pathways have been described. In oomycete species, effectors are mostly small proteins containing an N-terminal signal peptide for secretion and additional C-terminal motifs such as RXLRs and CRNs for host targeting. It has recently been shown that oomycetes exploit non-conventional secretion mechanisms to transfer certain proteins to the extracellular environment. Other non-classical secretion systems involved in plant-fugal interaction include extracellular vesicles (EVs, Figure 1 from Samuel et al 2016 Front. Plant Sci. 6:766.). The versatility of oomycetes, fungi and bacteria allows them to associate with plants in many ways depending on whether they are biotroph, hemibiotroph, necrotroph, or saprotroph. When interacting with a live organism, a microbe will invade its plant host and manipulate its metabolisms either detrimentally if it is a pathogen or beneficially if it is a symbiote. Deciphering secretomes became a crucial biological question when an increasing body of evidence indicated that secreted proteins were the main effectors initiating interactions, whether of pathogenic or symbiotic nature, between microbes and their plant hosts. Secretomics may help to contribute to the global food security and to the ecosystem sustainability by addressing issues in i) plant biosecurity, with the design of crops resistant to pathogens, ii) crop yield enhancement, for example driven by arbuscular mycorrhizal fungi helping plant hosts utilise phosphate from the soil hence increase biomass, and iii) renewable energy, through the identification of microbial enzymes able to augment the bio-conversion of plant lignocellulosic materials for the production of second generation biofuels that do not compete with food production. To this day, more than a hundred secretomics studies have been published on all taxa and the number of publications is increasing steadily. Secretory pathways have been described in various species of microbes and/or their plant hosts, yet the functions of proteins secreted outside the cell remain to be fully grasped. This Research Topic aims at discussing how secretomics can assist the scientists in gaining knowledge about the mechanisms underpinning plant-microbe interactions.

Advances in Botanical Research publishes in-depth and up-to-date reviews on a wide range of topics in plant sciences. Currently in its 75th volume, the series features several reviews by recognized experts on all aspects of plant genetics, biochemistry, cell biology, molecular biology, physiology, and ecology. Publishes in-depth and up-to-date reviews on a wide range of topics in plant sciences Contains commentary by recognized experts on all aspects of plant genetics, biochemistry, cell biology, molecular biology, physiology, and ecology This volume features reviews of the fast moving field of plant microbe interactions

This book delves into microbial production and its implications for various industries and presents the latest advancements in the field of bioactive compound production by microorganisms. Divided into 16 chapters, the book covers a wide range of topics, starting with the emerging trends in microbial production techniques, followed by the potential of fungi and algae in producing bioactive compounds, and the applications of bioactive compounds in medicine, agriculture, and industry. Contributions from expert scientists emphasize the significance of metabolic engineering and modern analytical techniques for the extraction, purification, and structural characterization of microbial bioactive compounds. The authors also present alternative technologies and methodologies for the recovery and extraction of these compounds from microbial sources and highlight the health-promoting benefits of natural plant-derived bioactive compounds. Particular attention is given to nanocarriers and their potential for managing the delivery of bioactive compounds in therapeutic applications. The importance of actinomycetes and their bioactive potential in the agricultural sector is also discussed. In this book, readers will also find out about the importance of microbial community dynamics in Antarctica, their ecological potential, and their industrial application. The last chapter of the book offers an industrial perspective of microbial pigments and their applications. This book is a valuable resource for researchers, academics, and industry professionals seeking to understand and harness the potential of microbial bioactive compounds for sustainable development, industrial applications, and improved human well-being.