Book Volume 2
Preface
Page: ii-ii (1)
Author: Shampi Jain, Ashutosh Gupta and Neeraj Verma
DOI: 10.2174/9789815050264123020002
PDF Price: $15
Microorganisms and their Industrial Uses
Page: 1-11 (11)
Author: Meenakhi Prusty*, Ashish Kumar Dash, Suman G. Sahu and Neeraj Verma
DOI: 10.2174/9789815050264123020004
PDF Price: $15
Abstract
For human beings, the diversity of microorganisms is still an undiscovered
aspect. For the well-being of society, the huge microbial population performs many
vital activities. Microorganisms play an important role in sustainable agriculture,
environmental protection, and human and animal health. Microorganisms have a major
contribution to agricultural issues like crop productivity, plant health protection, soil
health maintenance, and environmental issues like bioremediation of soil and water
from many pollutants. In addition to these activities, microorganisms also produce
many products, either directly or through industrial processes, which are essential for
human survival. In this chapter, we deal with various industrial products that are
produced by microorganisms through different reactions, like antibiotics, enzymes,
natural food preservatives, vitamins, fermentation products, amino acids, and
agricultural products.
Soil Inhabitant Bacteria: Morphology, Life Cycle and Importance in Agriculture and Other Industries
Page: 12-25 (14)
Author: Safi Ur Rehman Qamar* and Mayer L. Calma
DOI: 10.2174/9789815050264123020005
PDF Price: $15
Abstract
There are many bacteria in the soil, but they have less biomass because of
their small size. Soil-inhabitant bacteria are an essential source of nutrients for plants.
Some studies highlighted their industrial importance, like in the pharmaceutical
industry, perfume manufacturing, and agriculture product scale-up production,
including biofertilizers. Most of the studies have been carried out on Actinobacteria
and Nitrobacter because of their potential to produce biofertilizers and chemical
constituents on a large scale. This chapter discussed their taxonomic and morphological
characteristics and gathered details about their practical applications from limited
studies carried out in this field.
Role of Soil Microbes in the Sustainable Development: Agriculture, Recovery of Metals and Biofuel Production
Page: 26-55 (30)
Author: Anurag Singh, Priya Bhatia, Shreya Kapoor, Simran Preet Kaur, Sanjay Gupta, Nidhi S. Chandra and Vandana Gupta*
DOI: 10.2174/9789815050264123020006
PDF Price: $15
Abstract
Indiscriminate use of agrochemicals to ramp up production capabilities has
caused a considerable decline in soil health status. The growing awareness of their ill
effects on the environment and human health has called for a reversion to old organic
agricultural practices blended with modern-day science and technology. Soil
microorganisms with an identified ability to support plant growth are now being
deployed in the form of biofertilizers and microbial biocontrol agents. Other than
augmenting nutrition supply, these bio-inoculums can synthesize phytohormones and
can also enhance the micronutrient and organic content of the soil. They can further
induce resistance in plants against phytopathogens and compete against them by
secreting secondary metabolites to keep the pathogenic population in check. Soil
microorganisms, due to their omnipresence and survivability on varied substrates and
in different environmental conditions, also find their use in other applications such as
in the mining and energy industries. Unlike conventional metallurgical practices that
deplete high-grade mineral ore reserves and cause wide-scale destruction of habitats,
bioleaching provides a safe and cheap prospect for the recovery of metals. Other than
the extraction of precious metals from low-grade ores, they also find their use in metal
recovery from e-waste and can even remove heavy metals from soil. Moreover, the
rapidly developing mining and the agrochemical industry count upon fossil fuels to
meet their energy needs. In the final section of this chapter, we discuss a yet fascinating
aspect of how non-conventional sources of energy are produced by the action of soil
microorganisms to minimize strains on fossil fuel reserves. These biofuels, produced
by the transformation of organic biomass, have an edge over fossil fuels as they emit
low levels of particulate matter, sulphur dioxide, and carbon monoxide.
Industrial Applications of Soil Microbes: Production of Enzymes, Organic Acids and Biopigments
Page: 56-84 (29)
Author: Simran Preet Kaur, Tanya Srivastava, Anushka Sharma, Sanjay Gupta, Nidhi S. Chandra and Vandana Gupta*
DOI: 10.2174/9789815050264123020007
PDF Price: $15
Abstract
Commodity chemicals are the intermediates that are generally involved in
the synthesis of other high-end products. The increasing demand for various industrial
products has upscaled the requirement for commodity chemicals. Originally, the
industrial sector was dependent upon conventional and toxic chemicals to sustain its
processes. However, the advent of biotechnology led to the development of numerous
microbial processes producing enzymes, extremozymes, organic acids, organic
solvents, etc., Moreover, the soil environment has diverse forms of microbial
communities performing assorted functions. As a result, a thorough understanding of
the soil microbiota involved in providing regulatory ecosystem services can aid in the
development of exceptional microbial strains capable of meeting the high demand for
these commodity chemicals. In addition, the exploitation of these excellent
manipulative microbial systems can improve and customize the synthesis of
commodity chemicals and thereby reduce the reliance on synthetic and petroleumbased products. This chapter will inform the readers about the applications of soil
microbes in industry and their involvement in enzymes, extremozymes, organic acids,
and biopigments production.
Applications of Microbial Biopesticides
Page: 85-101 (17)
Author: Poonam Meena, Neelam Poonar, Sampat Nehra* and P.C. Trivedi
DOI: 10.2174/9789815050264123020008
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Abstract
Microbial biopesticides involve various microorganisms such as bacteria,
fungi, viruses, nematode-associated bacteria, protozoans, and endophytes working
against invertebrate pathogens in agro-ecosystems. Such novel biopesticidal products,
after extensive research work, have been explored in the global market to combat
synthetic pesticide application adverse problems. Recent academic and industrial
efforts are involved in the discovery of toxins and virulence factors from microbial
species for the synthesis of commercial formulations. The current review is the
expansion of the application of various bacteria, fungi, viruses, nematodes, protozoans,
and endophytes for biopesticide formulations and their role in pest management.
Soil Microflora - A Potential Source of Antibiotics
Page: 102-112 (11)
Author: S. Bharathi* and Prajeesh P. Nair
DOI: 10.2174/9789815050264123020009
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Abstract
Soil is one of the principal ingredients of the universe, which supports all
forms of life directly or indirectly. Soil consists of a mixture of various organic and
inorganic matter, fluids, gases, and micro and macro-living systems and acts as a major
living medium for a wide group of living organisms. One of the important soil
inhabitants are microorganisms. Soil microorganisms can be categorized as bacteria,
fungi, actinomycetes, protozoa, algae, and viruses. These microbes have varied features
and functions. Most importantly, these microorganisms do not exist in isolation but
interact with each other and contribute significantly to overall soil fertility. Many of
these organisms have the capacity to produce antimicrobial substances as a defense
mechanism to compete with other organisms for their survival and existence. Most of
these antimicrobial substances, which are released as metabolites produced during
trophophase as well as in idiophase, are medically significant in the treatment of many
life-threatening infections in plants and animals. This chapter describes various soil
microflora and their roles in the production of different kinds of antimicrobials. The
primary goal is to familiarise readers with the various microflora found in soil and their
ability to produce anti-microbial components.
Role of Nonpathogenic Strains in Rhizosphere
Page: 113-128 (16)
Author: Rana Muhammad Sabir Tariq*, Maheen Tariq, Sarah Ali, Shahan Aziz and Jam Ghulam Mustafa
DOI: 10.2174/9789815050264123020010
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Abstract
As the world’s population is increasing rapidly, there is an urgent need to
increase crop production. To achieve this goal, an eco-friendly alternative to chemical
fertilizers and pesticides is required. Several types of microbes have been identified
inhabiting the plant rhizosphere, such as nitrogen-fixing bacteria, plant growthpromoting rhizobacteria, fungi, proteobacteria, mycoparasitic and mycorrhizal fungi.
These microorganisms not only influence the growth and development of plants but
also suppress pathogenic microbes near plant roots through several different
mechanisms. Non-symbiotic microbes play a crucial role in the biogeochemical cycling
of organic and inorganic phosphorus (P) near the root zone via solubilization and
mineralization of P from total soil phosphorus. Additionally, some non-pathogenic
microbes have also been reported to induce systemic resistance in plants, which is
phenotypically similar to pathogen-induced systemic acquired resistance (SAR). The
present review summarizes the latest knowledge on the role of non-pathogenic strains
of microbiomes residing in the rhizosphere and their commercial applications.
Bioremediation Industry: A Microbial Perspective
Page: 129-144 (16)
Author: Pooja Singh*
DOI: 10.2174/9789815050264123020011
PDF Price: $15
Abstract
Bioremediation of environmental pollutants and contaminants in soil is an
emerging technology, which will gain relevance and importance in the near future.
Microbiological bioremediation is not only cost-effective but also environmentally
sustainable, as it does not cause undesirable effects like toxic byproducts or residues,
requires heavy infrastructure, has on-site application, and is the least hazardous to
human health. With new biotechnological tools, the microbes can be designed to have
desirable effects for the bioremediation of more toxic wastes. However, the free release
of genetically modified microbes for this purpose is still under risk assessment. This is
an effective method to use indigenous microflora and harness their biodegradation
properties to remove unwanted contaminants from soil, water bodies, underground
water aquifers, ocean spills, etc. Currently, they are mostly used for cleaning oil spills
and removing petroleum products and heavy metals from soil. Both in situ and ex situ
methods are employed, where microbes can be used in varied ways. Much work is
going on to explore and enhance the properties of microbes, especially bacteria, to be
used as agents for contaminant removal from our environment. Global bioremediation
is an emerging market that is slowly growing and will become a multibillion-dollar
market worldwide in days to come. The current review tries to view the subject with
microbes in perspective; their role in bioremediation; mode of action; technologies
used; and their use for sustainable cleanup of the environment.
Alleviation of Salinity Stress by Microbes
Page: 145-174 (30)
Author: Sampat Nehra*, Raj Kumar Gothwal, Alok Kumar Varshney, Pooran Singh Solanki, Poonam Meena, P.C. Trivedi and P. Ghosh
DOI: 10.2174/9789815050264123020012
PDF Price: $15
Abstract
Agricultural production is majorly hampered by the negative impact of both
biotic and abiotic stress in most developing countries. Among abiotic stresses, soil
salinity is a major problem, affecting crop production and responsible for limiting the
growth and productivity of plants in different areas of the world due to increasing use
of poor quality of water, flooding, over-irrigation, seepage, silting, and a rising water
table. In agriculture, salt-tolerant rhizospheric/endophytic microorganisms play an
important role in helping alleviate abiotic stresses in plants. Under plant-microbe
interactions, plant root-associated microbes, including endophytes, closely interact and
cooperate with plants, and mediate important physiological and metabolic processes,
thereby enhancing the plant’s tolerance to salinity stress. Several mechanisms have
been developed for microbial alleviation of salinity stress in plants, including the
production of phytohormones, improving plant nutrient status, production of ACC
deaminase, salt exclusion, and enhancing resistance to drought in plant cells. A wide
range of micro-organisms are available that have diverse mechanisms for salt stress
alleviation in plants. Future research needs to be directed towards field evaluation for
the validation of the potential microbes.
Lignocellulose Degrading Bacteria in Soil
Page: 175-192 (18)
Author: Archana Rawat, Parul Bhatt Kotiyal*, Soni Singh and Neeraj Verma
DOI: 10.2174/9789815050264123020013
PDF Price: $15
Abstract
The degradation of wood is a highly complex process involving the
activities of several different microbes. It has been explored through research that
microorganisms have developed various strategies (enzymatic and nonenzymatic) to
utilize wood. In the present article, we are presenting the enzymes that originated from
fungi and bacteria and their reactions to decomposing wood. Analysis of enzymes
involved in wood degradation will not only be helpful in the study of the wood
degradation process but also provide information about various ecological niches of the
microorganisms. Genomic and secretome data have revealed the importance of the
enzymes secreted by microorganisms such as fungi and bacteria in wood degradation in
ecological niches.
An Overview of Diverse Yeast Species Performing the Biocontrol Function in Agriculture
Page: 193-202 (10)
Author: Abhishek Sinha*
DOI: 10.2174/9789815050264123020014
PDF Price: $15
Abstract
The agricultural economy has been suffering from various pathogenic
diseases of crops, fruits, grains, and vegetables for a long time. Controlling these
diseases is pivotal to the growth of agricultural production and the availability of
harvests. Compared with relatively harmful chemical agents, biocontrol agents are now
being used as safer and less toxic alternatives to control crop losses. Yeasts survive in
all environmental conditions and have been described as potent antagonists to various
plant pathogens. Due to their antagonistic activity towards pathogens, relatively simple
cultivation requirements, and very limited biosafety concerns, many of these
unicellular fungi are being considered for biocontrol applications. In this chapter, we
have discussed the pros and cons of yeasts as biocontrol agents, various yeast species,
and their modes of antagonistic action. To survive in the environment, yeasts need to
tolerate various biotic and abiotic stresses. Those stresses have been discussed here,
and how different yeast strains overcome these harsh conditions and carry out
antagonistic activities have also been highlighted. Yeast biocontrol activities to date
represent a largely unexplored field of research and plenty of opportunities remain for
the development of commercial, yeast-based applications for plant protection.
Macrophomina Phaseolina: An Agriculturally Destructive Soil Microbe
Page: 203-218 (16)
Author: Ramesh Nath Gupta*, Kishor Chand Kumhar and J.N. Srivastava
DOI: 10.2174/9789815050264123020015
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Abstract
Macrophomina phaseolina (Tassi) Goid. is a destructive fungal soil
microbe, a cause of charcoal rot disease and causes heavy losses in agricultural
production. It is non-specific and appears in moderate to severe form every year
worldwide. Due to the seriousness and economic importance of the pathogen as well as
disease, it requires multiple approaches like epidemiological study, induction of
systemic resistance through non-conventional chemicals, host-pathogen resistance and
chemical as well as phytoextract application for its management. Epidemiological
studies reveal that the onset of charcoal rot varied in different varieties during different
dates of sowing. Timely sowing of crops is an important tool for reducing disease
incidence. The intensity of disease in a timely sown crop is less, with higher production
and productivity. The non-conventional chemicals like salicylic acid, acetylsalicylic
acid, indole acetic acid, indole butyric acid, riboflavin, and thiamine induce systemic
acquired resistance (SAR) and effectively inhibit mycelial growth of the pathogen.
These non-conventional chemicals showed a reduction of charcoal rot disease under
field conditions. It also enhances the yield-attributing traits and yield. It induces total
phenol content, peroxidase, polyphenol oxidase, phenylalanine ammonia lyase, and
catalase activity by the treatment of these chemicals. These activities showed a
differential reaction after inoculation of the pathogen on different varieties. However,
resistant varieties showed higher induction of biochemical activities than susceptible
ones. Different phytoextracts showed inhibition of mycelial growth and a reduction of
disease incidence in different crops. Seed treatment with fungicides is an effective
method for controlling the pathogen and ultimately enhances the production of the
crop. Genotype evaluation for host resistance is an effective, economical, and
continuous way of managing the pathogen and disease.
Beauveria Bassiana: An Ecofriendly Entomopathogenic Fungi for Agriculture and Environmental Sustainability
Page: 219-233 (15)
Author: Purnima Singh Sikarwar and Balaji Vikram*
DOI: 10.2174/9789815050264123020016
PDF Price: $15
Abstract
In the present day perspective, with the increasing cost of chemical
pesticides along with increasing incidences of pesticide toxicity, the application of
microbial pesticides holds good promise for crop protection around the world.
Beauveria bassiana is a common soil fungus, having a broad host range and therefore
is used for biological control of soil-dwelling insect pests. As this fungus is epizootic, it
is being used worldwide as a biopesticide to control several pests, such as termites,
whiteflies, and malaria-transmitting mosquitoes. The use of this fungus in different
crop protection systems significantly controls the Colorado potato beetle, codling moth,
and several genera of termites and bollworms. As insecticides, the spores are sprayed
on affected crops as an emulsified suspension or wettable powder. Generally, B.
bassiana is considered a nonselective pesticide because it parasitizes a very high range
of arthropod hosts. This entomopathogenic fungus is also applied against the European
and Indian corn borer, pine caterpillar, and green leafhoppers. The ability of B.
bassiana to antagonize, parasitize, and kill insects endorses it as an efficient biocontrol
agent. Although B. bassiana has a good share in the total biopesticide market, there is
still ample scope for further development of this superior strain through advertisement
among the farming community.
Ergot, Ergotism and its Pharmaceutical Use
Page: 234-247 (14)
Author: Doomar Singh*
DOI: 10.2174/9789815050264123020017
PDF Price: $15
Abstract
Many fungi are directly or indirectly toxic to humans and animals. Ergot, a
fruiting body of the Claviceps purpurea fungus, contaminates grain after harvest and is
toxic to humans and animals who consume contaminated grains. The lysergic acid
diethylamide (LSD) that was widely used as a hallucinogen is best known as the ergot
alkaloids. The main symptoms of the disease caused by consuming ergot-contaminated
grain flour in humans and animals are blistering and reddening of the skin with a
burning sensation. Ergot alkaloids such as agroclavine, ergovaline, ergotamine,
ergonovine, lysergic acid, dopamine, etc., are the natural alkaloids produced by
Claviceps spp. in many cereal crops (mainly wheat, barley, rye, bajra, jowar, and
dallisgrass), but rye (triticale) is the most common host of this fungus. Contaminated
grain may cause very harmful diseases to internal organs, the circulatory and nervous
systems of animals and humans, and even they may die. Ergot alkaloids are very
important in the pharmaceutical industry. Therefore, this soil-borne fungus, which can
be used in the manufacturing of different types of medicines for human and animal
welfare, is very important.
Identification of Fungi on Rhizoplane and in Rhizosphere of Leguminous Crop by Adopting Different Techniques
Page: 248-255 (8)
Author: Deepali Chaturvedi*
DOI: 10.2174/9789815050264123020018
PDF Price: $15
Abstract
Microbial inhabitants of soil are in an active state and change in response to
modifications in environmental conditions, amendments, management, etc. Although
various methods have been developed to study the biological properties of a disturbed
soil sample or with their precincts, adoption of a method should be done keeping in
mind the objective, limitations and assumptions of the method. Reproducibility of
results is important to have broad applicability and comparisons, which in turn will
depend upon effectiveness. Soil is a diverse medium having varying physicochemical
properties, and hence, there should be modifications while standardizing the method. It
will help in getting reproductive results. Sampling, processing, and storage of samples
are equally important to have a true picture of the soil and need appropriate care. The
numbers and kinds of fungi on the root surface, i.e., rhizoplane of the leguminous crop
plant and in the rhizosphere (near the roots), have been compared with the number and
kinds in root-free soil. The crops showed a typical rhizosphere effect, and there were
more microorganisms in the rhizosphere than in root-free soil. A total of 34 different
species of fungi were identified. The majority belong to the Aspergillus genus. Roots
and the rhizosphere of moth bean (Vigna aconitifolia) yielded a higher proportion of
fungi than did root-free soil
Trichoderma: A Potential Arsenal for Industries
Page: 256-278 (23)
Author: P.B. Khaire*, S.S. Mane and S.V. Pawar
DOI: 10.2174/9789815050264123020019
PDF Price: $15
Abstract
The genus Trichoderma (fungi) is a very large group of microorganisms that
play a significant role in the environment. This is omnipresent in the climate,
particularly in soils. Trichoderma species could be easily isolated from the soil by all
traditional methods available because of their rapid growth and abundant conidiation.
These are used both as biofungicides for biological plant protection as well as for
bioremediation. In addition, the genus Trichoderma includes edible and medicinal
mushrooms but also human pathogens. Members of the Trichoderma genus are often
used primarily in the processing of enzymes, antibiotics, and other metabolites, but also
for biofuel in various branches of industry. Several researchers have confirmed, based
on phylogenetic analysis, that Trichoderma and Hypocrea form a single holomorphic
genus. In which two can be differentiated by large clades. Several Trichoderma spp.
positively affect plants by stimulating plant growth and protecting plants from fungal
and bacterial pathogens. Trichoderma has entered the genomic period at present, and
sections of the genome sequences are open to the public. For this purpose, Trichoderma
can be used to an even greater degree than before for human needs. Trichoderma
species possess diverse biotechnological applications, such as acting as biofungicides
to control various plant diseases and as biofertilizers to promote plant production.
Trichoderma secretes various volatile compounds, including alcohols, aldehydes,
ketones, ethylene, hydrogen cyanide, and monoterpenes, as well as non-volatile
compounds known to exhibit antibiotic activity, including peptaibols, and
diketopiperazine-like gliotoxins and gliovirins. Nonetheless, further studies are
required to make the application of these fungi more effective and safe.
Subject Index
Page: 279-284 (6)
Author: Shampi Jain, Ashutosh Gupta and Neeraj Verma
DOI: 10.2174/9789815050264123020020
PDF Price: $15
Introduction
This volume is a compilation of reviews on the industrial usage of soil microorganisms. The contents include 16 brief reviews on different soil microbe assisted industrial processes. Readers will be updated about recent applications of soil bacteria, fungi and algae in sectors such as agriculture, biotechnology, environmental management. The reviews also cover special topics like sustainable agriculture, biodiversity, ecology, and intellectual property rights of patented strains, giving a broad perspective on industrial applications of soil microbes. Volume 2 includes reviews on destructive microbes like Macrophomina Phaseolina, eco-friendly microbes like Beauveria Bassiana, the identification of fungi in the rhizosphere, the industrial application of Trichoderma, and other topics. The text is easy to understand for readers of all levels, with references provided for the benefit of advanced readers.