Genetic and Genome-Wide Microbial Insights : Bioenergy / Javid Ahmad Parray, Niraj Singh, and Dilfuza Egamberdieva, editors.

Format:

Book

Contributor:

Parray, Javid Ahmad, editor.

Singh, Niraj, editor.

Egamberdieva, Dilfuza, editor.

Language:

English

Subjects (All):

Microbial genomics.

Physical Description:

1 online resource (386 pages)

Edition:

First edition.

Place of Publication:

London, England : Academic Press, [2025]

Summary:

Genetic and Genome-Wide Microbial Insights: Bioenergy: Microbial Genomics (Volume 3) delves into the cutting-edge developments in the field of metagenomics, encompassing both metatranscriptomics and metaproteomics.

Contents:

Front Cover

Genetic and Genome-Wide Microbial Insights: Bioenergy

Copyright Page

Contents

List of contributors

Preface

I. Microbial fuel production-advanced techniques

1 Microbe as a resource for biofuel and bioenergy production

1.1 Introduction

1.2 Microbial bioenergy and biofuel production

1.2.1 Yeast

1.2.2 Microalgae

1.2.3 Bacteria

1.2.4 High substrate utilization ability

1.3 Future perspective

1.4 Conclusion

References

2 Bioprospecting of microbial strains for biofuel production

2.1 Introduction

2.2 Biofuels from microorganisms

2.2.1 Microalgae

2.2.2 Bacteria

2.2.3 Fungi

2.3 Different biofuels from microbes

2.3.1 Biodiesel

2.3.2 Biogas

2.3.3 Bioethanol

2.3.4 Biohydrogen

2.4 Conclusion

2.5 Discussion

3 Microbial genetic resource for advanced biofuel production

3.1 Introduction

3.2 Microbial and genetic-resource diversity in bioenergy production

3.2.1 Role of different microbes in biomass breakdown

3.2.2 Interactions among microbial communities in biofuel production

3.2.3 Microbial genetic resources in biofuel production

3.2.4 Impact of environmental factors on microbial community composition

3.3 Genomics in studying microbial genetic resources

3.3.1 Application of genomics in bioenergy production

3.3.2 Omics techniques for analyzing microbial communities

3.3.3 Metagenomics for understanding functional potential and metabolic capability

3.4 Synthetic microbiology in biofuel production

3.5 Challenges in mining microbial genetic resource for bioenergy production

3.5.1 Technical challenges in mining microbial genetic resources

3.6 Metagenomic complexity

3.7 Functional characterization

3.8 Metabolic engineering

3.8.1 Inadequacy in microbial culture collections for bioenergy production.

3.8.2 Future directions for utilizing microbial genetic resource in bioenergy applications

3.8.2.1 Metabolic engineering for enhanced biofuel production

3.8.2.2 Exploration of novel microbial strains

3.8.2.3 Synthetic biology approaches

3.8.2.4 Microbiome engineering for biomass conversion

3.9 Conclusion

4 Metagenomics approach to microbial biofuel and bioenergy production

4.1 Introduction

4.2 Microbial biofuel

4.3 Prospecting novel lignocellulolytic enzymes via functional metagenomic technologies for biofuel production

4.4 Future prospects and challenges

4.5 Conclusion

II. Sustainable bioenergy: genomics and biofuel development

5 Microbes: the next-generation bioenergy producer

5.1 Introduction

5.2 Generations of biofuels

5.2.1 First-generation biofuels

5.2.2 Second-generation biofuels

5.2.2.1 Advantage

5.2.2.2 Disadvantage

5.2.3 Third-generation biofuels

5.2.3.1 Advantages

5.2.3.2 Disadvantage

5.2.4 Fourth-generation biofuels

5.2.4.1 Advantage

5.2.5 Fifth-generation biofuels

5.3 Different microorganisms as source of bioenergy

5.3.1 Bacteria

5.3.2 Fungi

5.3.3 Algae

5.3.4 Virus

5.4 Conclusion

5.5 Discussion

6 Evolution of biofuel development as a source of sustainable bioenergy

6.1 Introduction

6.2 First-generation biofuels

6.3 Second-generation biofuels

6.4 Third-generation biofuel

6.5 Fourth-generation biofuel

6.6 Fifth-generation biofuels

6.7 Conclusion

Acknowledgments

7 Microbial diversity and genomics in aid of bioenergy

7.1 Introduction

7.2 Microbial diversity

7.3 Genomics

7.4 Bioenergy production pathways

7.5 Challenges and opportunities

7.6 Opportunities for innovation and advancement

7.6.1 Integration with biorefinery processes.

7.6.2 Genomic engineering techniques

7.6.3 Metabolic engineering

7.7 Conclusion

8 Microbial system: an emerging application in bioenergy production

8.1 Introduction

8.2 Microalgae as feedstock

8.3 Effect of physiological parameters

8.3.1 Nitrogen limitation and temperature

8.3.2 Light

8.3.3 CO2

8.3.4 pH

8.4 Biomass to bioenergy

8.4.1 Thermochemical conversion

8.4.2 Biochemical conversion

8.4.2.1 Anaerobic digestion for biomethane production

8.4.2.2 Photolysis for biohydrogen production

8.4.2.3 Alcoholic fermentation for bioethanol production

8.4.2.4 Transesterification for biodiesel production

8.5 Conclusion and future prospects

9 Genome editing for better yield of bioenergy and biofuel

9.1 Introduction

9.2 Bioenergy sources

9.2.1 Types of biofuels

9.3 Biofuel generations

9.3.1 First-generation biofuels

9.3.2 Second-generation biofuels

9.3.3 Third-generation biofuels

9.3.4 Fourth-generation biofuels

9.4 Production of biofuels from raw material

9.5 Limitations of biofuel production

9.6 Genome engineering for biofuel production

9.6.1 Site-specific nucleases

9.7 Genome-editing technologies

9.7.1 Zinc finger nucleases and transcription activator-like effector nucleases system

9.7.2 Clustered regularly interspaced short palindromic repeat/CRISPR-associated nuclease 9

9.8 Conclusion

10 Microbial strategies for techno-economic biofuel production

Abbreviations

10.1 Introduction

10.2 Biofuels produced from microalgae

10.2.1 Biodiesel

10.2.2 Biobutanol

10.2.3 Biomethane

10.2.4 Biogasoline

10.2.5 Bioethanol

10.3 Potential feedstock for microbial ethanol production: paper mill effluent

10.3.1 Acid-based pretreatment

10.3.2 Alkaline-based pretreatment.

10.3.3 Solvent-based pretreatment

10.3.4 Ultrasound pretreatment

10.4 Pulping pretreatment

10.4.1 Utilization of hydrolytic enzymes in biorefinery

10.4.1.1 Cellulase

10.4.2 Hemicellulases

10.4.3 Ligninolytic enzymes

10.4.4 Lytic polysaccharide monooxygenases

10.5 Amylase

10.6 Lipases

10.7 Protease

10.8 Introduction of nanocatalyst in the improvement of microbial fuel production

10.9 Conclusions and future trends

III. Microbial engineering and other omics

11 Bioengineered microbial platform for biomass-derived biofuel production

11.1 Introduction

11.2 Overview of biomass-derived biofuels

11.3 Bioengineered microbial platforms

11.4 Design and optimization of bioengineered strain

11.5 Advances in biofuel production

11.6 Challenges

11.7 Conclusion

12 Revolutionizing biofuel production: CRISPR/Cas9-mediated genome engineering of microbial cells for upscaling and optimization

12.1 Introduction

12.2 Overview of CRISPR/Cas9-mediated genome engineering

12.3 Genome engineering in microbial cells

12.3.1 The potential of microbes as hosts for biofuel production

12.3.1.1 First-generation biofuels

12.3.1.2 Second-generation biofuels

12.3.1.3 Third-generation biofuels

12.3.1.4 Fourth-generation biofuels

12.4 Combined strategies for converting basic resources to biofuels

12.4.1 Separate hydrolysis and fermentation

12.4.2 Simultaneous saccharification and fermentation

12.4.3 Simultaneous hexose and pentose cofermentation and simultaneous saccharification and cofermentation

12.4.4 Consolidated bioprocessing

12.5 Significant role of microbes in biofuel production

12.5.1 Significance in the pretreatment

12.5.2 Significance in the hydrolysis

12.5.3 Significance in the fermentation

12.6 Recent advances in genome editing.

12.7 Genetic modification of microorganisms using CRISPR/Cas9 to improve biofuel production

12.7.1 Regulation of gene expression using CRISPR-based molecular pathways enhances the generation of biofuels

12.7.2 Genetic modification improves preventing tolerance

12.7.3 Use of native CRISPR-Cas to improve biofuel host specificity

12.7.4 Enhanced production of solvents through the redirection of biological flow

12.7.5 Enhanced capacity to use substrates

12.7.6 Genome manipulation to enhance thermal tolerance

12.8 Impact of changing microbial cell genomes on the climate and biofuel safety issues

12.9 Present situations of CRISPR-Cas9 genome engineering and its potential future directions

12.10 Conclusions

13 Advanced biofuels and bioproducts process development unit-scenarios and utility

13.1 Introduction

13.2 Overview of biomass recalcitrance

13.3 Biorefinery

13.4 Techniques for preprocessing

13.4.1 Physical method

13.4.2 Chemical method

13.4.3 Physicochemical approach

13.4.4 Biological method

13.4.5 Technique producing biofuel from lignocellulosic biomass

13.4.5.1 Genetic engineering methodology

13.4.5.2 The method of metabolic engineering

13.4.6 Current advancements in modeling research

13.5 Conclusion

14 Metagenomics: a mining enzymes from microbial cells for biofuel production

14.1 Introduction

14.2 Metagenomics

14.2.1 Metagenomics: an essential technology for creating cutting-edge biotech products

14.3 Importance of metagenomics in biotechnology

14.4 Microbial biofuel

14.5 Biofuel production upscaling assisted by metagenomics and enzyme engineering

14.6 Metagenomic implications on biotechnology

14.6.1 Access to novel biocatalysts from the metagenome

14.6.2 Pretreatment of environmental sample.

14.6.3 Extraction of nucleic acid.

Notes:

Includes bibliographical references and index.

Description based on publisher supplied metadata and other sources.

Description based on print version record.

ISBN:

9780443315572

0443315574

OCLC:

1503846249