and Plant Pathology, IAS Banaras Hindu University Varanasi Uttar Pradesh India
Deepa Thomas Faculty of Applied Sciences Parul University Vadodara Gujarat India
Manikant Tripathi Centre of Excellence, DST‐FIST Supported Department of Microbiology Dr. Rammanohar Lohia Avadh University Ayodhya Uttar Pradesh India
Baba Uqab Department of Environmental Science University of Kashmir Srinagar Jammu and Kashmir India
Ajit Varma Amity Institute of Microbial Technology (AIMT) Amity University Campus Noida Uttar Pradesh India
Fazila Younas Institute of Soil and Environmental Sciences University of Agriculture Faisalabad Faisalabad Pakistan
Preface
The economic growth and industrialization aimed at better living has resulted in environmental deterioration. The major contributing factors being industries, agriculture practices, and urbanizations, for example, that are a threat to the natural environment in all parts of the world. The fragile water and land ecosystems are under continuous threat due to the accumulation of toxic substances or contaminants thereby limiting the scope of sustainable development. Heavy metal pollution in soil is of particular concern, as it is accumulating further at higher trophic levels. The rigorous use of antibiotics, pesticides, herbicides, drugs, and other chemical forms with their persistence and disposal in a concentrated environment is also of great concern. The environmental self‐perpetuating process for transformation and degradation of xenobiotic substances is one of the key processes in natural systems. However, the rate of degradation may be reduced with the rise in pollutant concentrations. A major challenge in the current scenario is to improve the quality of the environment through effective utilization and conservation of natural resources, waste minimization, and adoption of the 3Rs, that is, reduce, recycle, and reuse. Besides, an increased demand for the remediation of wastes and contaminated areas has produced a new demand for improved and newer remediation methods that are appropriate at low cost and offer a broader application of waste management. Therefore, research into biological approaches for waste degradation has received great attention with bioremediation being one of the most important new innovations for the treatment of contaminated sites. Bioremediation mainly concerns the use of microbes and microbial agents to improve the quality of pollutant discharge in the environment vis a vis remediating contaminated sites. This book discusses effective and sustainable technological approaches for remediation of contaminates via ecofriendly usage of microbes and their products in all physical components of the environment. The main focus is the role of microbes, particularly bacteria and fungi, for degradation and removal of various xenobiotic substances from the environment. The book also emphasizes molecular approaches and the biosynthetic pathways of microbes and their gene and protein expression studies for biodeterioration techniques. As previously noted, increased urbanization and industrialization has a detrimental impact on a fragile environment and with this in mind some chapters focus on the role of biotechnological advances in cleaning the environment, through waste minimization and control, using new innovative and sophisticated green technologies. The book offers environmentalists and researchers new insights and directions in addition to motivations for waste management and control leading to effective conservation of natural resources. The research and their mechanisms presented here will be a major contributing factor to sustainable development. Presently, there is keen interest in environmental research particularly in pollution remediation, adoption of ecofriendly technologies, and the better use of agricultural products/residues as economical substrates for cleaning the environment. The untouched wealth of microorganisms in harsh environments are considered potential candidates for utilization in a better and sustainable future. A major part of this book highlights the potential aspects of microbes for various techniques of bioremediation, for example, biosorption, bioaugmentation, and biostimulation in cleaning a contaminated environment. This book covers established and up‐to‐date research on emerging trends in bioremediation and there are contributions from experimental and numerical researchers; reports on field trials are of special interest.
Javid A. Parray
1 In‐situ Bioremediation: An Eco‐sustainable Approach for the Decontamination of Polluted Sites
Shamsul Haq1, Asma Absar Bhatti1, Suhail Ahmad Bhat2, Shafat Ahmad Mir1, and Ansar ul Haq3
1 Division of Environmental Sciences, Sher‐e‐Kashmir University of Agricultural Science and Technology, Srinagar, Jammu and Kashmir, India
2 Department of Biochemistry, Pondicherry University, Puducherry, India
3 Department of Chemistry, University of Kashmir, Srinagar, Jammu and Kashmir, India
1.1 Introduction
The environment has been severely polluted with chemicals that are poisonous both to the environment and to human beings [1–3]. A polyphasic approach has been adapted to overcome the effect of these toxic pollutants that includes (i) stringent regulations for the production and usage of complex chemicals, (ii) the treatment and safe disposal of harmful chemicals, and (iii) the reclamation of polluted sites [4, 5]. The first two are defensive in nature and minimize damage to environment, while the latter is a restorative mechanism [6, 7]. The methods of bioremediation are used for (i) the conversion of highly toxic to less‐toxic substances, (ii) the mineralization of contaminants, and (iii) pollutant immobilization [8–12]. Microorganisms in general, and bacteria in particular, harbor enormous metabolic diversity, allowing them to utilize the complex chemicals as energy sources [11, 13]. Further, due to genetic evolution they attain a new metabolic potential to degrade newly added xenobiotic substances [13–15]. The other major focus area of bioremediation studies has been the characterization of metabolic pathways and their respective molecular regulations [16–18]. The advent of whole genome sequencing and related genomics methods has also given rise to new avenues for genome‐wide screening of degradative genetic elements and regulatory sequences among the pollutant‐degrading strains [19–22]. The main concerns for using isolated microorganisms are: (i) the portion of microorganisms may have substantial potential of degrading pollutants and (ii) true degradation of pollutants is not often a true reflection of the in‐situ bioremediation [23, 24]. The perfect bioremediation techniques need to be executed in such a manner that microorganisms counter a variety of biotic and abiotic factors [23–26]. These factors greatly affect the efficiency of bioremediation process through various mechanisms [27]. Numerous studies also suggest that these are not only the environmental factors but also the technological advances, which affect the process of bioremediation. From the above studies, a major area of environmental research has emerged that assess the eco‐sustainability of in‐situ bioremediation process. Furthermore, various programs are required to monitor and address the following uncertainties: the expected remediation of hazardous substances, the potential of microorganisms, and the adverse impact of remediation processes on various environmental factors [28]. Previously, only the kinetics of degradation was determined but, with the advancement of ecological techniques, community behavior has also been made mandatory for in‐situ bioremediation studies [29, 30].
The key target of a bioremediation technique is to improve the effectiveness of the restoration of contaminated sites in a cost‐effective and environmental‐friendly manner. There is no single technique for restoring contaminated sites but research on the basis of nature and type of pollutants has led to the development of new techniques. Autochthonous microorganisms present in polluted environments hold the key to solving most of the challenges associated with biodegradation and bioremediation of polluting substances [31] provided that environmental conditions are suitable for their growth
