This book presents an overview of the latest advances and developments in plant biotechnology. The respective chapters explore emerging areas of plant biotechnology such as RNAi technology, fermentation technology, genetic engineering, nanoparticles and their applications, climate resilient crops, bio-films, bio-plastic, bio-remediation, flavonoids, antioxidants etc. All chapters were written by respected experts and address the latest developments in plant biotechnology that are of industrial importance, especially with regard to crop yields and post-harvest strategies. As such, the book offers a valuable guide for students, educators and researchers in all disciplines of the life sciences, agricultural sciences, medicine, and biotechnology at universities, research institutions and biotechnology companies.
Plant biotechnology applies to three major areas of plants and their uses: (1) control of plant growth and development; (2) protection of plants against biotic and abiotic stresses; and (3) expansion of ways by which specialty foods, biochemicals, and pharmaceuticals are produced. The topic of recent advances in plant biotechnology is ripe for consideration because of the rapid developments in this ?eld that have revolutionized our concepts of sustainable food production, cost-effective alt- native energy strategies, environmental bioremediation, and production of pla- derived medicines through plant cell biotechnology. Many of the more traditional approaches to plant biotechnology are woefully out of date and even obsolete. Fresh approaches are therefore required. To this end, we have brought together a group of contributors who address the most recent advances in plant biotechnology and what they mean for human progress, and hopefully, a more sustainable future. Achievements today in plant biotechnology have already surpassed all previous expectations. These are based on promising accomplishments in the last several decades and the fact that plant biotechnology has emerged as an exciting area of research by creating unprecedented opportunities for the manipulation of biological systems. In connection with its recent advances, plant biotechnology now allows for the transfer of a greater variety of genetic information in a more precise, controlled manner. The potential for improving plant productivity and its proper use in agric- ture relies largely on newly developed DNA biotechnology and molecular markers.
This volume, contributed to by a group of 46 research scientists and engineers, focuses on the integration of two aspects of plant biotechnology - the basic plant science and applied bioprocess engineering. Included in this book are 17 chapters, each dealing with specific topics of current interest with three coherent themes of: plant gene expression, regulation and manipulation; plant cell physiology and metabolism and their regulation; and bioprocess engineering and bioreactor performance of plant cell cultures. All of these topics are integrated into a main theme of "enabling plant biotechnology" relevant to the production of secondary metabolites. This book will be of great value to all plant cell biologists and molecular geneticists, and all those interested in the integration of plant science and bioprocess engineering for development of enabling technology relevant to the production of plant secondary metabolites.
This volume explores advances in plant biotechnology, and focuses on the use of lipids and proteins extracted from different kinds of plants tissues in potential industrial applications. In fact, lipidomics and proteomics refer to the advancement of technologies, such as chromatography and mass spectrometry, to study lipids and proteins. As such, the book discusses an important emerging field of research concerning the use of different plants to produce compounds with high value. As such, it will appeal to readers with an interest in medical, biochemical, and biotechnological disciplines.
Refinement in sequencing technologies and potential of genomic research resulted in meteoric growth of biological information such as sequences of DNA, RNA and protein requiring databases for efficient storage, management and retrieval of the biological information. Also, computational algorithms for analysis of these colossal data became a vital aspect of biological sciences. The work aims to show the process of turning bioscience innovation into companies and products, covering the basic science, the translation of science into technology. Due to rapid developments, there seems to be no basic difference between the pharmaceutical industry and the biotechnological industry. However, approved products in the pipeline and renewed public confidence make it one of the most promising areas of economic growth in the near future. India offers a huge market for the products as well as cheap manufacturing base for export. The book is a sincere work of compilation of new and recent advances in the topic of concern through various innovative researches and scientific opinion therefrom. The book is dedicated to the readers who will definitely find it interesting and knowledgeable in carrying out their respective researches in different aspects of applied microbiology and biotechnology.
In this book the potential of high technological approaches in plant genetic engineering as well as their practical applications are considered. The efficiency of plant genetic transformation remains a challenge due to limitations of intracellular transportation of genes and other biomolecules through the cell wall, damaging of cells/tissues, gene disruption, and high-cost of application of the transformation methods. From stable interest to the development of new techniques for gene delivery into plant cells, key achievements of carbon nanotubes (CNTs) and fullerene derivatives to serve as vehicles for the delivery of genetic material into plant cells and plastids are discussed. Besides CNTs and fullerenes, the mineral nanoparticles (mesoporous silica NPs, metal oxide, calcium phosphate), and cationic polymers have been proposed also for plant transformation. In the monograph, the results of practical development of efficient gene transfer techniques based on using these nanomaterials and applicable for plants are presented, too. Then the multiple strategies of site-specific recombinases application in plant genetic engineering with outlining of prospective directions of growth for this molecular tool are detailed. Currently, the CRISPR/Cas system is a powerful method for editing the genome of various organisms. The achievements and prospects of CRISPR/Cas usage for genome editing of fungi are considered in a separate chapter. Because salinity is one of major problems for modern agriculture around the world and creation of salt tolerant cultivars via conventional breeding cannot keep the pace with continuously rising food demand, one contribution to the book critically evaluates the possible roles or capacities of genes from different functional groups to improve plant salt tolerance via genetic engineering. Another chapter presents the results of systematic studies of the effects of new ecologically friendly polycomponent biostimulants of microbiological origin (developed in Ukraine on the basis of either 2,6-dimethylpyridine-N-oxide, or metabolic products of root endophyte fungus from the roots of ginseng, or metabolites of several strains of soil Streptomyces) on improving commercially useful traits in important agricultural crops, including improved growth, productivity and increased resistance to pathogenic fungi, parasitic nematodes and insects. Special attention is paid to the analysis of molecular-genetic mechanisms of the effect of microbial biostimulants at organismal, cellular, and molecular levels. The results of these studies proved that the mechanism of bioprotective effect of microbial biostimulants involves the delivery of RNA interference (RNAi) into plant cells (ie: induction of synthesis of endogenous small regulatory si/miRNAs with immuno-protective, antipathogenic and antiparasitic properties). In the final chapter, the legal approaches to the regulation of plants produced through new breeding techniques such as gene editing are considered.
The book provides an overview of current trends in biotechnology and medicinal plant sciences. The work includes detailed chapters on various advance biotechnological tools involved in production of phytoactive compounds of medicinal significance. Some recent and novel research studies on therapeutic applications of different medicinal plants from various geographical regions of the world have also been included. These studies report the antimicrobial activity of various natural plant products against various pathogenic microbial strains. Informative chapters on recent emerging applications of plant products such as source for nutraceuticals and vaccines have been integrated to cover latest advances in the field. This book also explores the conservation aspect of medicinal plants. Thus, chapters having comprehensively complied in vitro conservation protocols for various commercially important rare, threatened and endangered medicinal plants were provided in the present book.
The rapid increase in microbial resources along with the development of biotechnological methods has revolutionized the field of microbial biotechnology. Genome characterization methods and metagenomic approaches further illustrate the role of microorganisms in various fields of research. Recent Advancement in Microbial Biotechnology: Agricultural and Industrial Approach provides an overview on the recent application of the microorganisms in agricultural and industrial improvements. The purpose of this book is to integrate all these diverse areas of research in a common platform. Recent advancement in Microbial Biotechnology targets researchers from both academia and industry, professors and graduate students working in molecular biology, microbiology and biotechnology. - Gives insight in the exploration of microbial functional diversity in different systems - Highlights important microbes and their role in enhancing agricultural productivity - Provides understanding to the basics with advance information of microbial biotechnology - Explores the importance of microbial genomes studies in agricultural and industrial applications
This book is divided into five sections. The first section deals with the methodology and bioresource generation, techniques related to genetic engineering, and gene transfer to the nuclear genome and chloroplast genome. The new techniques of genome profiling and gene silencing are also presented. The second section of the book covers the classical aspect of plant biotechnology viz. tissue culture and micropropagation. Use of genetic engineering via Agrobacterium and direct transfer of DNA through particle bombardment to develop transformed plants in Artemisia, castor and orchids, and production of recombinant proteins in plant cells have been dealt with in the third section. The fourth section addresses the abiotic and biotic stress tolerance in plants. The basic biology of some of the stress responses, and designing plants for stress tolerance is discussed in this section. The fifth section examines medicinal plants and alkaloid production.
Modern Applications of Plant Biotechnology in Pharmaceutical Sciences explores advanced techniques in plant biotechnology, their applications to pharmaceutical sciences, and how these methods can lead to more effective, safe, and affordable drugs. The book covers modern approaches in a practical, step-by-step manner, and includes illustrations, examples, and case studies to enhance understanding. Key topics include plant-made pharmaceuticals, classical and non-classical techniques for secondary metabolite production in plant cell culture and their relevance to pharmaceutical science, edible vaccines, novel delivery systems for plant-based products, international industry regulatory guidelines, and more. Readers will find the book to be a comprehensive and valuable resource for the study of modern plant biotechnology approaches and their pharmaceutical applications. - Builds upon the basic concepts of cell and plant tissue culture and recombinant DNA technology to better illustrate the modern and potential applications of plant biotechnology to the pharmaceutical sciences - Provides detailed yet practical coverage of complex techniques, such as micropropogation, gene transfer, and biosynthesis - Examines critical issues of international importance and offers real-life examples and potential solutions