Discoverbiomolecular engineering technologies for the production of biofuels, pharmaceuticals, organic and amino acids, vitamins, biopolymers, surfactants, detergents, and enzymes

In Biomolecular Engineering Solutions for Renewable Specialty Chemicals, distinguished researchers andeditorsDrs.R. Navanietha KrishnarajandRajesh K. Sanidelivera collection of insightful resources on advanced technologies in the synthesis and purification of value-added compounds.Readers will discover new technologies that assist in the commercialization of the production of value-added products.

The editors also include resources that offer strategies for overcoming current limitations in biochemical synthesis, including purification.The articles within cover topics like the rewiring of anaerobic microbial processes for methane and hythane production, the extremophilic bioprocessing of wastes to biofuels, reverse methanogenesis of methane to biopolymers and value-added products, and more.

The book presents advanced concepts and biomolecular engineering technologies for the production of high-value, low-volume products, like therapeutic molecules, and describes methods for improving microbes and enzymes using protein engineering, metabolic engineering, and systems biology approaches for converting wastes.

Readers will also discover:

A thorough introduction to engineered microorganisms for the production of biocommodities and microbial production of vanillin from ferulic acid
Explorations of antibiotic trends in microbial therapy, including current approaches andfuture prospects, as well as fermentation strategies in the food and beverage industry
Practical discussions of bioactive oligosaccharides, including their production, characterization, and applications
In-depth treatments of biopolymers, including a retrospective analysis in the facets of biomedical engineering

Perfect for researchers and practicing professionals in the areas of environmental and industrial biotechnology, biomedicine, and the biological sciences, Biomolecular Engineering Solutions for Renewable Specialty Chemicals is also an invaluable resource forstudents taking courses involving biorefineries, biovalorization, industrial biotechnology, and environmental biotechnology.

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Yes, you can access Biomolecular Engineering Solutions for Renewable Specialty Chemicals by R. Navanietha Krishnaraj, Rajesh K. Sani, R. Navanietha Krishnaraj,Rajesh K. Sani in PDF and/or ePUB format, as well as other popular books in Technology & Engineering & Environmental Management. We have over one million books available in our catalogue for you to explore.

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Year

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eBook ISBN

Edition

Topic

Technology & Engineering

Subtopic

Environmental Management

Index

Technology & Engineering

1
Engineered Microorganisms for Production of Biocommodities

Akhil Rautela and Sanjay Kumar

School of Biochemical Engineering, IIT (BHU) Varanasi, Varanasi, UP, India

1.1 Introduction

As we are going toward becoming more developed, we tend to see our transition toward more sustainable resources and knowing and understanding the life form more. This leads to the use of the living system and engineer them to produce biocommodities such as fuels, polymers, hormones, therapeutic proteins and peptides, and neurotransmitters, which is termed as biocommodity engineering. It basically deals with the need of society. Biotechnology, genetic engineering, and biocommodity engineering can be combined to meet these needs. The foundation of biocommodity engineering lies in molecular biology, which is also the foundation of genetic engineering or recombinant DNA technology (rDT). Therefore, it can be said that these terms are interrelated to each other. The majority of the biocommodities consumed by humans were earlier isolated from plants and animals, posing the threat of activation of immune reactions in humans. So, the machinery of the synthesis of these biocommodities can be engineered in microorganisms.

Its main aim is to engineer microorganisms to get a high yield of the product, use cheap raw material as a substrate so that cost of the product can be minimized, easy downstream processing, increasing robustness of the microorganism, etc. All this can be achieved by genetically modifying the organisms using genetic toolkits. This chapter deals with the basics of genetic engineering, giving details about the enzymes used, transformation techniques, and how to select a transformant from non‐transformants. Further sections compile the comprehensive data of the problems in the production of biopolymers, organic acids, and therapeutic proteins from conventional methods and development of mutant strains for the synthesis of these biocommodities. The last section of the chapter gives an insight about the biofuel production from photoautotrophic organisms such as cyanobacteria and microalgae, which utilizes sunlight and carbon dioxide as energy and carbon source, respectively.

1.2 Fundamentals of Genetic Engineering

The advent of genetic engineering, also called rDT, started in 1952 with the discovery of Hershey and Chase, stating DNA as the genetic material (Hershey and Chase, 1952). Cohen and Boyer in the early 1970s were the first to show that the genetic material of one organism can be easily expressed in the other. Genetic engineering (Figure 1.1), in general, is the process in which the DNA is extracted, modified, transformed into a host cell, and a new organism is formed. The DNA from the desired organism is extracted and purified. It is then cleaved using restriction enzymes to get the gene of interest from it. The DNA fragment is then ligated into a vector, which acts as a driving vehicle for the DNA molecule to the host cells. This chimeric DNA molecule is then transformed into the host cells, and selection procedure under suitable stress conditions takes place. Finally, after numerous generations, the organism growing in the stress conditions is said to be recombinant or genetically modified. Genetic engineering has emerged as a crucial step in the development of industrial bioprocesses.

Each and every organism has a different genetic (DNA) makeup, which in turn makes the whole organism different with respect to their carbohydrates, lipids, and proteins. This is due to the fact that DNA transcribes and translates to mRNA and proteins, respectively (central dogma). This makes DNA the choice for manipulation in genetic engineering as manipulating it leads to the generation of a whole new organism. This postulation gives rise to many other disciplines of genetic engineering like recombinant protein production, protein engineering, metabolic engineering, etc.

Every organism being different makes it difficult to use proteins and other biomolecules of one organism to the other. This was the main reason why proteins/enzymes from animals cannot be used by humans. Earlier, insulin was extracted from the pancreas of slaughtered pigs, posing a threat to human health. This leads to the discovery of the first recombinant product, Insulin, approved by the US Food and Drug Administration (FDA) in 1982 (Goeddel et al., 1979). Now synthetic insulin is easily being produced by yeast worldwide as Escherichia coli does not perform post‐translational modifications required to form functional insulin.

Similarly, genetic engineering is now used to produce several other biocommodities. Modifying DNA and getting it expressed inside the host organism requires several steps, as shown in Figure 1.1 and the number of enzymes. These enzymes are explained in further sections with other requirements for genetic engineering.

1.2.1 DNA‐altering Enzymes

The basis of rDT is the manipulation of DNA molecules with the help of molecular biology tools and biocatalysts. The available purified enzymes that can manipulate DNA molecules with specific changes can be categorized in four broad classes: (i) DNA polymerases, (ii) nucleases, (iii) DNA ligases, and (iv) end‐modification enzymes.

Schematic illustration of the basic steps of gene cloning. — **Figure 1.1** Basic steps of gene cloning.

1.2.1.1 DNA Polymerases

DNA polymerases is the key enzyme in DNA replication driving the synthesis of new DNA strand from the parent DNA or RNA strand acting as a template. DNA polymerases require an oligo nucleotide (primer) for the initiation of DNA strand synthesis. DNA polymerase‐I (DNA‐dependent DNA polymerase) is widely studied polymerase and has both polymerization and exonuclease activity that can help in synthesizing new strand as well as the degradation for proof reading or repair and primer removal. DNA polymerase I (or Pol I) takes part in the process of pro...

Cover
Table of Contents
Title Page
Copyright Page
Preface
List of Contributors
1 Engineered Microorganisms for Production of Biocommodities
2 Microbial Cell Factories for the Biosynthesis of Vanillin and Its Applications
3 Antimicrobials
4 Trends in Antimicrobial Therapy
5 Fermentation Strategies in the Food and Beverage Industry
6 Bioactive Oligosaccharides
7 Biopolymers
8 Metabolic Engineering Strategies to Enhance Microbial Production of Biopolymers
9 Bioplastics Production
10 Conversion of Lignocellulosic Biomass to Ethanol
11 Advancement in Biogas Technology for Sustainable Energy Production
12 Biofertilizers
13 Biofertilizers from Food and Agricultural By‐Products and Wastes
Index
End User License Agreement

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