Preface
Page: i-ii (2)
Author: Prakash M. Halami and Aravind Sundararaman
DOI: 10.2174/9789815223798124010001
Advances in Microbial Study for Crop Improvement
Page: 1-42 (42)
Author: Vinay Sharma, Neelam Mishra, Sherin Thomas, Rahul Narasanna, Kalant Jambaladinni, Priscilla Kagolla, Ashish Gautam, Anamika Thakur, Abhaypratap Vishwakarma, Dayanand Agsar, Manish K. Pandey and Rakesh Kumar*
DOI: 10.2174/9789815223798124010003
PDF Price: $15
Abstract
Now and in the future, meeting the global demand for healthy food for the
ever-increasing population is a crucial challenge. In the last seven decades, agricultural
practices have shifted to the use of synthetic fertilizers and pesticides to achieve higher
yields. Despite the huge contribution of synthetic fertilizers in agronomy, their adverse
effects on the environment, natural microbial habitat, and human health cannot be
underrated. Besides, synthetic fertilizers are manufactured from non-renewable sources
such as earth mining or rock exploitation. In this context, understanding and exploiting
soil microbiota appears promising to enhance crop production without jeopardizing the
environment and human health. This chapter reviews the historical as well as current
research efforts made in identifying the interaction between soil microbes and root
exudates for crop improvement. First, microbial consortium viz. bacteria, algae, fungi,
and protozoa are briefly discussed. Then, the application of bio-stimulants followed by
genome editing of microbes for crop improvement is summarized. Finally, the
perspectives and opportunities to produce bioenergy and bio-fertilizers are analyzed.
Genome Editing Against Bacterial Plant Pathogens
Page: 43-67 (25)
Author: Ashish Warghane*, Neha G. Paserkar and Sumit Bhose
DOI: 10.2174/9789815223798124010004
PDF Price: $15
Abstract
Meeting the crucial demand for sustainable agriculture is an upcoming
challenge worldwide, leading to global food security concerns. Approximately 50% of
agricultural loss is caused by both biotic and abiotic stresses. As per the estimation of
Agrios, 42% of crop loss is characterized by biotic stress alone. Bacteria are the second
largest contributor in terms of economic losses caused by various plant diseases.
Hence, there is a need to develop elite cultivars in amalgamation with readily available
sequenced plant database and progressive genome editing. This has proved to be a
groundbreaking/milestone in the field of plant breeding for any desired trait. Until now,
many new plant breeding techniques (NPBTs) have been introduced for crop
improvement. These techniques include site-specific mutagenesis, cisgenesis,
intragenesis, breeding with transgenic inducer lines, etc. This book chapter provides a
comparative understanding of enrichment in plant genome editing approach about
bacterial pathogens aiming for sustainable agriculture development. This chapter also
brings a broad aspect of the application, advantages, unsighted aspects of genome
editing, and future challenges.
CRISPR-Cas for Genome Editing - Molecular Scissors for Combating Pathogens
Page: 68-105 (38)
Author: Poornima Devi C. Ramdev, Divya K. Shankar and B. Renuka*
DOI: 10.2174/9789815223798124010005
PDF Price: $15
Abstract
Clustered Regularly Interspaced Short Palindromic Repeats, abbreviated as
CRISPR, is a genome-editing technology that permits the creation of precise knock-out
mutants by aiding the modification of gene sequences devoid of the steps involving the
insertion of foreign DNA into pathogenic microorganisms. The microorganisms are
ubiquitous in nature and harbor in the complex ecosystem of the human being. Cas
(acronym for CRISPR-associated) genes are present in many microbial genomes. The
variable nature of the microbial genome has been utilized as an integral typing tool in
epidemiologic, diagnostic, and evolutionary analyses of the prokaryotic species. The
past decade has seen an accumulating growth in the development of gene-editing tools
utilizing the CRISPR-Cas system, which essentially is a part of the prokaryotic immune
system. The development of these unique gene-editing techniques has empowered
researchers to alter and investigate organisms with ease and efficiency as never before.
This editing tool can efficiently be programmed and delivered into the bacterial
populations to explicitly eliminate members of a targeted micro biome. Manipulation
of the gene expression and regulation of the synthesis of metabolites and proteins can
be achieved by utilizing an engineered CRISPR-Cas system. Put together, these tools
present with the exhilarating opportunity to explore the complex interaction between
the individual species of the microbiome and the host organism and thereby reveal
novel avenues for the generation of drugs to selectively target the microbiome.
CRISPR-Cas technology has been employed to cope with antibiotic resistance in
intracellular and extracellular pathogens. The widespread use of antibiotics and the
escalation of multidrug-resistant (MDR) bacteria boost the prospect of a post-antibiotic
era, which emphasizes the need for novel strategies to target MDR pathogens. The
development of permissive synthetic biology techniques offers favorable solutions to
carry through safe and efficient antibacterial therapies.
Genome Editing of Plant Growth-Promoting Microbes (PGPM) Towards Developing Smart Bio-Formulations for Sustainable Agriculture: Current Trends and Perspectives
Page: 106-149 (44)
Author: Sugitha Thankappan*, Asish K. Binodh, P. Ramesh Kumar, Sajan Kurien, Shobana Narayanasamy, Jeberlin. B. Prabina and Sivakumar Uthandi
DOI: 10.2174/9789815223798124010006
PDF Price: $15
Abstract
Plant-associated microbes, referred to as plant microbiomes, are an integral
part of the plant system. The multifaceted role of plant microbiota in combating both
abiotic and biotic stresses is well documented in different crop species. However,
understanding the co-evolution of plant growth- promoting microbes (PGPM) and PGP
traits at genetic and molecular levels requires robust molecular tools to unravel the
functional gene orthologues involved in plant-microbe interaction. The advent of
Clustered Regularly Interspaced Short Palindromic Repeats (CRISPR)/Cas9 (CRISPRassociated protein 9) is of paramount importance in deciphering the plant-microbe
interaction and addressing the challenges of unraveling endophytic microbes and their
benefits thereof. Our knowledge of plant microbiome composition, signaling cues,
secondary metabolites, microbial volatiles, and other driving factors in plant
microbiome has been enlightened. In recent years, scientists have focused more on
below-ground dialogue in recruiting efficient microbiome/engineered rhizosphere.
More recently, base editing techniques using endo-nucleolytic ally deactivated dCas9
protein and sgRNAs (CRISPR interference or CRISPRi) have emerged as a useful
approach to study the gene functions and have potential merits in exploring plantmicrobe interactions and the signaling cues involved. A systemic understanding of the
signaling events and the respective metabolic pathways will enable the application of genome editing tools to enhance the capacity of microbes to produce more targeted
metabolites that will enhance microbial colonization.
Further, it will be exciting to employ CRISPR technologies for editing plant-microbe
interactions to discover novel metabolic pathways and their modulation for plant
immunity and fitness against abiotic as well as biotic stresses. Such metabolites possess
tremendous scope in tailoring newer smart nano-based bio-formulations, besides
formulating beneficial microbiomes or cocktails, which is the best alternative for
climate resilient farming. The present review sheds light upon the deployment of
CRISPR/Cas techniques to comprehend plant-microbe interactions, microbe-mediated
abiotic and biotic stress resistance, genes edited for the development of fungal,
bacterial, and viral disease resistance, nodulation process, PGP activity, CRISPR
interference-based gene repression in the PGPM, metabolic pathway editing and their
future implications in sustainable agriculture.
Applications of Genome Editing in Bioremediation
Page: 150-183 (34)
Author: Vibhuti Sharma, Rutika Sehgal, Vani Angra and Reena Gupta*
DOI: 10.2174/9789815223798124010007
PDF Price: $15
Abstract
Excessive utilization of chemicals based substances such as pesticides,
pharmaceuticals, fertilizers, inappropriate dumping of industrial materials and local
wastes, etc., into the environment is leading towards deliverance of high amounts of
contaminants such as chlorinated hydrocarbons, dyes, toxins, petroleum and diesel
spills into the soil. The mingling of these materials with soil and water is becoming one
of the supreme complications associated with the environment, as these contaminants
are a potential menace to human health. Bioremediation is a process that has the ability
to destroy harmful contaminants and transform them into less toxic forms using living
organisms such as bacteria, fungi, plants, etc. It is the most up-to-date nature-friendly
approach to lower the extent of pollutants in the environment. With continuous
developments in the scientific area, researchers are focussing on improving the process
of bioremediation by using genome editing technologies. The gene editing techniques
have the potential to significantly improve bioremediation processes such as xenobiotic
removal, conversion of toxic compounds to less toxic compounds and pesticide
degradation to simple components. The main gene editing techniques, CRISPR-Cas,
ZFN and TALEN, have the potential to meet the aforementioned goals. This chapter
focuses on the various gene editing tools and different genomic strategies such as gene
editing, gene circuit, etc., for the alteration or editing of the genome so that their
potential value or applications can be seen in various areas.
Genome Editing and Genetically Engineered Bacteria for Bioremediation of Heavy Metals
Page: 184-221 (38)
Author: Nirmala Akoijam* and S. R. Joshi*
DOI: 10.2174/9789815223798124010008
PDF Price: $15
Abstract
Genetic engineering involves the manipulation of DNA to either improve,
enhance or repair a function by using recombinant DNA technology, which has
contributed greatly to the fields of medicine and agriculture. In recent times, the
CRISPR-Cas system of gene editing has come to the forefront of genome engineering,
transforming disease treatment strategies and the production of modified crops.
Industrial activities cause environmental pollution by releasing heavy metal-containing
xenobiotic compounds into the environment and affect animal health by causing organ
dysfunction and even cancer. Although plants utilize heavy metals from soil in small
quantities for their growth, excessive exposure leads to disruption of plant cell
machinery and reduces productivity. Similarly, heavy metals degrade soil health by
interfering with microbial processes that contribute to soil fertility. Apart from existing
methods available for the remediation of contaminated sites, bioremediation is
emerging as a potent technique due to its high efficacy, cost-effectiveness and ecofriendly nature. Microbes possess a number of physiological and biochemical
properties that have been exploited for the removal and detoxification of metal
pollutants. This chapter elaborates on the approaches of gene editing and the
development of genetically engineered bacteria to modify the expression of specific
genes coding for enzymes that take part in the degradative or detoxification pathway of
metals and xenobiotic compounds. It is crucial to address the scope as well as
limitations involved in the use of genetically engineered microbes to ensure a safe and
cost-effective method for the bioremediation of heavy metal contaminants.
Designing the Metabolic Capacities of Environmental Bioprocesses through Genome Editing
Page: 222-246 (25)
Author: Ashish Kumar Singh, Bhagyashri Poddar, Rakesh Kumar Gupta, Suraj Prabhakarrao Nakhate, Vijay Varghese, Anshuman A. Khardenavis* and Hemant J. Purohit
DOI: 10.2174/9789815223798124010009
PDF Price: $15
Abstract
The ubiquity of the CRISPR gene system in bacteria and archaea is
characterized by the Cas9 protein, which functions in the repression and activation of
several genes. This inherent function of the CRISPR system can find application in
bioprocess optimization in environmental and health research. Owing to the complex
and dynamic nature of microbial communities catalysing the bioremediation of urban
and industrial toxic waste effluents in wastewater treatment plant (WWTP)/common
effluent treatment plant (CETP), such sites represent a relatively untapped area for
applying the CRISPR technique. DNA editing using CRISPR can enable the sitespecific enhancement in process efficiency of bacterial remediation, which under
normal conditions is hampered by its non-selectivity and saturation of binding sites
with multiple non-targeted pollutants. Similarly, under the second generation biorefinery concept, CRISPR can serve as a powerful tool in strengthening and improving
the anaerobic bio-processes by genome editing in microbes for the heterogeneous
expression of various genes associated with anaerobic digestion. Not only has the
CRISPR system been used to insert desired genes in the host genome but also to
regulate the expression of the host-specific genes. The role of methanotrophic and
nitrogen metabolizing bacteria in shaping the atmospheric gaseous composition can
also be monitored via CRISPR aided manipulation so as to regulate the nutritional
exchange between the atmosphere and the soil. Additionally, genome editing of
targeted organisms and crops has found extensive applications in various areas ranging
from the nutrigenomics, food and pharmaceutical industry, diagnostics and
therapeutics, health and disease prevention.
Genetic Engineering of Methanotrophs: Methods and Recent Advancements
Page: 247-261 (15)
Author: Eleni N. Moutsoglou and Rajesh K. Sani*
DOI: 10.2174/9789815223798124010010
PDF Price: $15
Abstract
Methanotrophs use methane gas as their carbon and energy source, but their
industrial use has not yet fully been realized due to undiscovered genetic engineering
methods that could amend their slow growth rate and economically inefficient product
yield. This chapter informs upon genetic engineering approaches taken on
methanotrophs so far to enable their widespread use in industry, as well as the
reasoning behind these interests. Specific examples of successful engineering
performed so far, including conjugation and electroporation methods, CRISPR,
genome-scale metabolic modeling, and specific vectors reported as successful, are
presented. In addition, the reading provides insights into existing knowledge gaps in
the field of methanotrophic engineering and future prospects for optimizing growth and
product yield from methanotrophs.
Genome Editing in Cyanobacteria
Page: 262-277 (16)
Author: Bathula Srinivas and Prakash M. Halami*
DOI: 10.2174/9789815223798124010011
PDF Price: $15
Abstract
Cyanobacteria are potential organisms being exploited for a wide range of
biotechnological applications. They are photosynthetic bacteria and grow in a carbonfree medium and become attractive hosts for biotechnology industries. Cyanobacteria
can utilize solar energy and atmospheric CO2
for the growth and synthesis of
biomolecules. It is used in many large-scale preparations of various bioproducts such as
pharmaceuticals, biofuels, etc. Cyanobacteria become target organisms for the next
generation of biofactories for producing desired products with a low-cost technology.
The problem in the metabolic engineering of Cyanobacteria is due to ploidy. It has
multiple copies of chromosomes ranging from 3-218 copies. There are 12 copies of the
genome in Synechocystis PCC 6803 and 3 copies in Synechococcus PCC 7942.
Segregation analysis in the conventional genetic approaches of Cyanobacteria becomes
laborious due to its polyploidy. Modern genome editing tools such as CRISPR-Cas9
and 12 are available to perform genome editing. CRISPR-Cas9 has been used in a wide
range of Cyanobacteria such as Synechococcus elongates UTEX 2973, Synechocystis
sp. PCC 6803. To avoid toxic effects caused by Cas-9, a low-level expression system is
adopted in Cyanobacteria. Cas-9 base genome editing was applied in Synechococcus
and produced succinate 11-fold higher than the normal. Cas-9 is used to cure plasmids
in Synechocystis sp. PCC 6803 to develop a shuttle vector for heterologous expression.
Another variant of genome editing tool is CRISPR-Cas12a, which is successfully used
in Synechocystis sp.
Genome Editing in Streptomyces
Page: 278-306 (29)
Author: Johns Saji, Jibin James, Ramesh Kumar Saini and Shibin Mohanan*
DOI: 10.2174/9789815223798124010012
PDF Price: $15
Abstract
Streptomyces are Gram-positive, filamentous bacteria belonging to the group
actinomycetes. This bacterium is important to the modern industrial world because of
the presence of 20-50 biosynthetic gene clusters (BGCs). BGCs contain the genes for
the production of industrially important natural products (NP), which includes
antibiotics, anti-tumor drugs, anti-depressants, etc., naturally originated from this
microorganism. Strain improvement is required to enhance the production of these NP
in Streptomyces. Different methods have been used to enhance NP production and
strain improvement. In this chapter, we will be discussing strain improvement of
Streptomyces species by different genome editing tools. The information, which is put
together, includes the basic techniques used for genome editing to the most advanced
CRISPR/Cas system associated genome editing in Streptomyces (PCR targeting
system, Cre-loxP recombination system, I SceI meganuclease promoted recombination
system and CRISPR/Cas system). The authors have discussed about multiplex
automated genome editing (MAGE) tool associated with CRISPR/Cas system.
Subject Index
Page: 307-312 (6)
Author: Prakash M. Halami and Aravind Sundararaman
DOI: 10.2174/9789815223798124010013
Introduction
This reference is a comprehensive review of genome editing in bacteria. The multi-part book meticulously consolidates research findings and insights on the applications of bacteria across several industries, including food processing and pharmaceutical development. The book covers four overarching themes for readers: a historical perspective of genome editing, genome editing in probiotics, applications of genome editing in agricultural microbiology and genetic engineering in environmental microbiology. The editors have also compiled chapters that provide an in-depth analysis of gene regulation and metabolic engineering through genome editing tools for specific bacteria. Key topics in part 2: - Targeting pathogenic microbes for plants and animals using CRISPR-CAS - Genome editing microbes to improve crop yield plant growth for sustainable agriculture - Applications of genome editing for bioremediation - Microbial genome editing for environmental bioprocessing - Genetic engineering for methanotrophs - Genome engineering in Cyanobacteria - Genome editing in Streptomyces Genome Editing in Bacteria is a definitive reference for scholars, researchers and industry professionals navigating the forefront of bacterial genomics.