Biotechnology
Biotechnology is an extended derivative of biochemistry & is a multidisciplinary field. It is an integrated subject of natural sciences and engineering sciences & achieves the application of organisms, cells, parts thereof and molecular analogues to produce products and services. It often refers to the production of products from raw materials with the aid of living organisms. The core principle of biotechnology involves harnessing biological systems and organisms, such as bacteria, yeast, and plants, to perform specific tasks or produce valuable substances. It has rendered a significant impact on many areas of society, from medicine to agriculture to environmental science.
One of the key techniques used in biotechnology is genetic-engineering, which allows scientists to modify the genetic makeup of organisms to achieve desired responses. This consists of inserting genes from one organism into another, creating new traits or modifying existing trait. Other important techniques used in biotechnology include tissue culture, which allows researchers to grow cells and tissues in the lab for research and medical purposes, and fermentation, which is used to produce a wide range of products such as beer, wine, and cheese.
The applications of biotechnology are very diverse and have led to the development of essential products like life-saving drugs, biofuels, genetically modified crops, and innovative materials. It has also been used to address environmental challenges, such as developing biodegradable plastics and using microorganisms to clean up contaminated sites. Therefore, biotechnology is a rapidly evolving field with significant potential to address pressing global challenges and improve the quality of life for people around the world; however, despite its numerous benefits, it also poses ethical and societal challenges, such as questions around genetic-modification and intellectual property rights.
Topics /Lesson Coverage:
FUNDAMENTALS OF MOLECULAR BIOTECHNOLOGY
I Fundamentals of Molecular Biotechnology
1 The molecular biotechnology Revolution
Recombinant DNA Technology
Emergence of Molecular Biotechnology
Commercialization of Molecular Biotechnology
Concerns and consequences
2 Molecular Biotechnology Biological Systems
Prokaryotic and Eukaryotic organisms
Escherichia coli
Saccharomyces cerevisiae
Secretion Pathways in Prokaryotic and Eukaryotic Organisms
Eukaryotic Cells in Culture
3 DNA, RNA, and Protein Synthesis
Structure of DNA
DNA Replication
Decoding Genetic Information: RNA and protein Translation
Regulation of mRNA Transcription in Bacteria
Regulation of mRNA Transcription in Eukaryotes
4 Recombinant DNA Technology
Restriction Endonucleases
Plasmid Cloning Vectors
Plasmid Cloning Vector pBR322
Transformation and Selection
Other Plasmid Cloning Vector
Creating and Screening a Library
Making a Gene Library
Screening by DNA Hybridization
Screening by Immunological Assay
Screening by Protein Activity
Cloning DNA Sequences That Encode Eukaryotic Proteins
Vectors for Cloning Large Pieces of DNA
Bacteriophage λ Vectors
Cosmids
High-Capacity Bacterial Vector Systems
Genetic Transformation of Prokaryotes
Transferring DNA into E. Coli
Electroporation
Conjugation
5. Chemical Synthesis, Sequencing, and Amplification of DNA
Chemical Synthesis of DNA
The Phosphonamidite Method
Uses of Synthesized Oligonucleotides
DNA Sequencing Techniques
Dideoxynucleotide Procedure for Sequencing DNA
Automated DNA Sequencing
Using Bacteriophage M13 as a DNA Sequencing Vector Primer
Walking
PCR
Gene Synthesis by PCR
Cycle Sequencing
6.Manipulation of Gene Expression in Prokaryotes
Gene Expression from strong and regulatable promoters
Regulatable Promoters
Increasing Protein Production
Large-Scale Systems
Expression in Other Microorganisms
Fusion Protein
Cleavages of Fusion Protein
Uses of Fusion Proteins
Surface Display
Unidirectional Tandem Gene Arrays
Translation Expression Vectors
Increasing Protein Stability
Protein Folding
Overcoming Oxygen Limitation
Use of Protease-Deficient Host Strains
Bacterial Haemoglobin
DNA Integration into the Host Chromosome
Removing Selectable Marker Genes
Increasing Secretion
L-Form Bacteria
Metabolic Load
7. Heterologous Protein Production in Eukaryotic Cells
Saccharomyces Cerevisiae Expression Systems
S. cerevisiae Vectors
Intracellular Production of Heterologous Proteins in S. Cerevisiae
Secretion of Heterologous Proteins by S. Cerevisiae
Pichia Pastoris and Other Yeast Expression Systems
Baculovirus-Insect Cell Expression Systems
Baculovirus Expression Vector System
Increasing the Yield of Recombinant Baculovirus
Construction of and E. Coil – Insect Cells Baculoviurs Shuttle Vector
Mammalian Glycosylation and Processing of Precursor Protiens in Insect Cells
Mammalian Cell Expression Systems
Selectable Marker Systems for Mammalian Expression Vectors
8.Directed Mutagenesis and Protein Engineering
Directed Mutagenesis Procedures
Oligonucleotide-Directed Mutagenesis with M13 DNA
Oligonucleotide-Directed Mutagenesis with Plasmid DNA
PCR-Amplified Oligonucleotide-Directed Mutagenesis
Random Mutagenesis with Degenerate Oligonucleotide primers
Random Mutagenesis with Nucleotide Analogues
Error-Prone PCR
DNA Shuffling
Mutant Proteins with Unusual Amino Acids
Protein Engineering
Adding Disulfide Bonds
Changing Asparagine to Other Amino Acids
Reducing the Number of Free Sulfhydryl Residues
Increasing Enzymatic Acvitity
Modifying Metal Cofactor Requirements
Decreasing Protease Sensitivity
Modifying Protein Specificity
Increasing Enzyme Stability and Specificity
Altering Multiple Properties
II Molecular biotechnology of Microbial Systems
9. Molecular Diagnostics
Immunological Diagnostic Procedures
Enzyme-Linked Immunosorbent Assay
Monoclonal Antibodies
Formation and Selection of Hybrid Cells
Identification of Specific Antibody-Producing Hybrid Cells Lines
DNA Diagnostic Systems
Hybridization Probes
Diagnosis of Malaria
Detection of Trypanosoma
Nonradioactive Hybridization Procedures
Molecular Beacons
DNA Fingerprinting
Random Amplified Polymorphic DNA
Bacterial Biosensors
Molecular Diagnosis of Genetic Disease
Screening for Cystic Fibrosis
Sickle-Cell Anemia
The PCR/OLA procedure
Padlock Probes
Genotyping with Fluorescence-Labeled PCR Primers
10. Therapeutic Agents Pharmaceuticals
Isolation of Interferon cDNAs
Human Interferons
Human Growth Hormone
Tumor Necrosis Factor Alpha
Optimizing Gene Expression
Therapeutics Produced and Delivered by Intestinal Bacteria
Enzymes
DNase I
Alginate Lyase
Phenylalanine Ammoria Lyase
α1-Antitrypsin
Monoclonal Antibodies as Therapeutic Agents
Structure and Function of Antibodies
Preventing Rejection of Transplated Organs
Treating Brain Tumors
Chemically Linked Monoclonal Antibodies
Human Monoclonal Antibodies
Hybrid Human-Mouse Monoclonal Antibobies
Production of Antibodies in E. coli
Phase Combinatorial Libraries
Shuffling CDR Sequences
Single-Chain Antibodies
Nucleic Acids as Therapeutic Agents
Antisense RNA
Antisense Oligonucleotides
Ribozymes
Chimeric RNA-DNA Molecules
Interfering RNAs
Antibody Genes
Treating Genetic Disorders
Human Gene Therapy
Prodrug Activation Therapy
11. Vaccines
Subunit Vaccines
Herpes Simplex Virus
Foot-and-Mouth Disease
Peptide Vaccines
Genetic Immunization: DNA Vaccines
Attenuated Vaccines
Cholera
Salmonella Species
Leishmania Species
Herpes Simplex Virus
Vector Vaccines
Vaccines Directed against Viruses
Vaccines Directed against Bacteria
Bacteria as Antigen Delivery Systems
12. Synthesis of Commercial Products by RecombinantMicroorganisms
Restriction Endonucleases
Small Biological Molecules
Synthesis of L-Ascorbic Acid
Microbial Syntheses of Indigo
Synthesis of Amino Acids
Removal of Lipids
Antibiotics
Cloning Antibiotic Biosynthesis Genes
Syntheses of Novel Antibiotics
Engineering Polyketide Antibiotics
Improving Antibiotic Production
Peptide Antibiotics
Biopolymers
Engineering Xanthomonas campestris for Xanthan Gum Production
Isolation of Melanin Biosynthesis Genes
Synthesis of an Animal Adhesive Biopolymers in Microbial Cells
Microbial Synthesis of Rubber
Microbial Production of Polyhydroxyalkanoates
13. Bioremediation and Biomass Utilization
Microbial Degradation of Xenobiotics
Genetic Engineering of Biodegradation Pathways
Manipulation by Transfer of Plasmids
Manipulation by Gene Alteration
Utilization of Starch and Sugars
Commercial production of Fructose and Alcohol
Improving Alcohol Productions
Improving Fructose Production
Zymomonasmobilis
Silage Fermentation
Utilization of Cellulose
Components of Lignocellulose
Isolation of Prokaryotic Cellulase Genes
Isolation of Eukaryotic Cellulase Genes
Manipulation of Cellulase Genes
14 Plant Growth-Promoting Bacteria
Nitrogen Fixation
Nitrogenase
Components of Nitrogenase
Genetic Engineering of the Nitrogenase Gene Cluster
Glycogen Synthase Mutants
Engineering Oxygen Levels
Hydrogenase
Hydrogen Metabolism
Genetic Engineering of Hydrogenase Genes
Nodulation
Competition among Nodulation Organisms
Genetic Engineering of Nodulation Genes
Growth Promotion by Free-Living Bacteria
Decreasing Plant Stress
Phytoremediation
Biocontrol of Pathogens
Siderophores
Antibiotics
Enzymes
Ice Nucleation and Antifreeze Proteins
Ethylene
Root Colonization
15. Microbial Insecticides
Insecticidal Toxin of B. Thuringiensis
Mode of Action and Use
Toxin Gene Isolation
Engineering of B. Thuringiensis Toxin Genes
Preventing the Development of Resistance
Genetic Engineering for Improve Biocontrol
Baculoviruses as Biocontrol Agents
Mode of Action
Genetic Engineering for Improved Biocontrol
16. Large-Scale Production of Protein from Recombinant Microorganisms
Principle of Microbial Growth
Batch Fermentation
Fed-Batch Fermentation
Continuous Fermentation
Maximizing the Efficiency of the Fermentation Process
High-Density Cell Cultures
Bioreactors
Typical Large-Scale Fermentation Systems
Two – Stage Fermentation in Tandem Airlift Reactors
Two-State Fermentation in a Single Stirred-Tank reactor
Batch versus Fed-Batch Fermentation
Harvesting Microbial Cells
Disrupting Microbial Cells
Downstream Processing
Protein Solubilization
Large-Scale Production of Plasmid DNA
III Eukaryotic Systems
17. Genetic Engineering of Plants
Methodology
Plant Transformation with the Ti Plasmid of Agrobacterium tumefaciens
Ti Plasmid-Derived Vector Systems
Physical Methods of Transferring Genes to Plants
Microprojectile Bombardment
Use of Reporter Genes in Transformed Plant Cells
Manipulation of Gene Expression in Plants
Isolation and Use of Different Promoters
Targeted Alteration in plant DNA
Targeting Foreign DNA to the Chloroplast Genome
Secretion of Foreign Proteins
Production of Marker-Free Transgenic Plants
Removing Marker Genes from Nuclear DNA
Removing Marker Genes from Chloroplast DNA
18. Genetic Engineering of Plants: Applications
Development of Insect-, Pathogen-, and Herbicide – Resistant plants
Insect-Resistant Plants
Virus-Resistant Plants
Herbicide-Resistant Plants
Fungus-and Bacterium-Resistant Plants
Development of Stress-and Senescence-Tolerant Plants
Oxidative Stress
Salt Stress
Fruit Ripening and Flower Wilting
Genetic Manipulation of Flower Pigmentation
Modification of Plant Nutritional Content
Amino Acids
Lipids
Vitamins
Iron
Modification of Food Plant and Appearance
Preventing Discoloration
Sweetness
Starch
Plants as Bioreactors
Antibodies
Polymers
Foreign Proteins in Plants
Edible Vaccines
Plant Yield
Increasing Iron Content
Altering Lignin Content
Increase Oxygen Content
19. Transgenic Animals
Transgenic Mice: Methodology
Retroviral Vector Method
DNA Microinjection Method
Engineered Embryonic Stem Cell Method
Genetic Modification with the Cre-loxP Recombination Systems
Transgenesis with High-Capacity Vectors
Transgenic Mice: Applications
Transgenic Models for Alzheimer Disease
Using Transgenic Mice as Test Systems
Conditional Regulation of Gene Expression
Conditional Control of Cell Death
Cloning Livestock by Nuclear Transfer
Transgenic Cattle, Sheep, Goats, and Pigs
Transgenic Birds
Transgenic Fish
20. Human Molecular Genetics
Modes of Human Inheritance
Genetic Linkage and Gene Mapping
Detection and Estimation of Genetic Linkage in Humans
Genetic Mapping of Human Chromosomes
Genetic Polymorphism
Restriction Fragment Length Polymorphism
Short Tandem Repeat Polymorphism
Comprehensive Human Linkage Maps
Mapping of a Genetic Disease Locus to a Chromosome Location
Whole-Genome Sequence
Detection of Mutations in Human Genes
Single-Strand Conformation Analysis
Denaturing Gradient Gel Electrophoresis
Heteroduplex Analysis
Chemical Mismatch Cleavage
Direct DNA Sequencing
Determining Gene Function
IV Regulating and Patenting Molecular
Biotechnology
21 Regulating the Use of Biotechnology
Regulating Recombinant DNA Technology
Regulating Food and Food Ingredients
Chymosin
Tryptophan
Bovine Somatotropin
Deliberate Release of GMOs
Ice-Minus P. syringe
Open-Field Tests of Other GMOs
Controversy about GMOs
Human Gene Therapy
Development of a Policy for Somatic Cell Gene Therapy
Accumulation of Defective Genes in Future Generations
Human Germ Line Gene Therapy
Cloning Human?
22 Patenting Biotechnology Invention
Patenting
Patenting in Different Countries
Patenting DNA Sequences
Patenting Multicellular Organisms
Patenting and Fundamental Research
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