Microft C8 Recombinant DNA Technology PDF

Summary

This document describes recombinant DNA technology, including its various applications in biotechnology, medicine and industry. It explains objectives like modifying genomes, describing specific genetic tools, and highlighting significant findings in the field.

Full Transcript

MICROFT C8 Techniques of Recombinant DNA Technology 1. Polymerase Chain Reaction (PCR): The Role of Recombinant DNA Technology in In vitro multiplication o...

MICROFT C8 Techniques of Recombinant DNA Technology 1. Polymerase Chain Reaction (PCR): The Role of Recombinant DNA Technology in In vitro multiplication of specific DNA segments. Biotechnology Steps: Denaturation, priming, extension. Automation: Thermocycler using Taq DNA polymerase. ○ Biotechnology : The use of microorganisms to Variation: Real time PCR for quantifying DNA sequences. make practical products, a practice dating back thousands of years. Applications and Impact ○ Industrial Applications : Acetone, butanol, Industrial and Environmental: Enhanced production antibiotics, paper, textiles, vitamins, environmental processes, bioremediation, resource extraction. Medical: Development of pharmaceuticals, gene therapy, clean up, mining. diagnostics. ○ Modern Advances : Since the 1990s, recombinant Research: Simplified gene isolation, genetic mapping, and DNA technology (genetic engineering) has enabled sequencing. intentional genome modification for practical purposes. Important Concepts ○ Recombinant DNA Technology: A collection of tools Goals of Recombinant DNA Technology and techniques for genome manipulation. 1. Eliminate Undesirable Traits : ○ Genetically Modified Organisms (GMOs): Example: Genes inserted into plants for pest or freeze Organisms with inserted genes from other species. resistance. Example: Gene therapy for severe combined ○ Mutagens and Reverse Transcriptase: Key tools for immunodeficiency (SCID). inducing genetic changes and synthesizing cDNA. 2. Combine Beneficial Traits : ○ Restriction Enzymes and Vectors: Essential for Example: Laboratory animals mimicking human cutting and inserting DNA into host genomes. susceptibility to HIV. 3. Create Organisms for Product Synthesis : ○ PCR: A critical technique for amplifying DNA for Example: Bacteria producing human insulin. various applications. Tools of Recombinant DNA Technology 1. Mutagens : Applications of Recombinant DNA Technology Physical and chemical agents causing mutations. Recombinant DNA technology has a wide range of Example: Mutagens used to develop Penicillium strains applications across various fields, solving problems and producing more penicillin. creating products in research, medicine, and agriculture. 2. Reverse Transcriptase : Converts RNA to complementary DNA (cDNA). Genetic Mapping cDNA lacks noncoding sequences, making it expressible in ○ Genetic Mapping: Locating genes on nucleic acid prokaryotic cells. molecules. Applications: Producing human proteins like growth factor, insulin, blood clotting factors. ○ Utility: Provides insights into an organism’s 3. Synthetic Nucleic Acids : metabolism, growth characteristics, and relatedness In vitro production of DNA/RNA. to other microbes. Uses: Elucidating genetic code, creating specific genes, ○ Example: Discovery of hepatitis G virus, presumed synthesizing probes and antisense molecules, and PCR to cause hepatitis due to its genetic similarity to primers. 4. Restriction Enzymes : known hepatitis viruses. Enzymes that cut DNA at specific sites. Types: Sticky ends (e.g., EcoRI) and blunt ends (e.g., Techniques for Locating Genes HindII, SmaI). ○ Historical Methods: Before 1970, locating genes Applications: Combining DNA from different organisms, was cumbersome and labor intensive. creating recombinant DNA. 5. Vectors : ○ Restriction Fragmentation: DNA molecules used to deliver genes into cells. Uses restriction enzymes to cut DNA into fragments. Types: Viral genomes, transposons, plasmids. ○ Compares fragments to map gene locations relative Features: Small, stable, identifiable markers, enable to each other. genetic expression. ○ Example: Complete gene map of the bacterium *H. 6. Gene Libraries : influenzae* in 1995. Collections of clones containing genetic material. ○ Applications: Simplifies isolating specific genes for ○ Fluorescent In Situ Hybridization (FISH): Uses fluorescent DNA probes to hybridize with target research. genes. ○ Visualized under a fluorescent microscope to locate DNA Technology in Functional Genomics, Medicine, and specific genes and microbes. Agriculture ○ Applications: Disease diagnosis, identifying Functional Genomics microbes in environmental samples, analyzing ○ Gene Knockout: Removing a gene to observe biofilms. phenotypic changes. Genomics and Nucleotide Sequencing ○ E. coli Keio Knockout Collection: 3985 strains with single nonessential genes removed. ○ Genomics: Sequencing and analyzing the nucleotide bases of genomes. ○ Gene Overexpression: Enhancing transcription or translation to increase gene product abundance. ○ Early methods involved selective cleavage of DNA and mapping short molecules. Microbial Community Studies ○ Sanger Sequencing: Uses modified nucleotides to DNA Sequencing: Reveals genetic diversity of terminate DNA replication. uncultured microorganisms. ○ Automated sequencing with fluorescent dyes for Next Generation Sequencing: Rapid and cost effective each nucleotide. analysis of microbiomes. ○ Significant achievements include the Human Pharmaceutical and Therapeutic Applications Genome Project in 2001. ○ Recombinant DNA Technology: Synthesis of ○ Next Generation Sequencing (NGS): pharmaceuticals like insulin and interferon. Massively parallel sequencing, allowing hundreds of millions of DNA fragments to be sequenced simultaneously. ○ Vaccine Production: Safer subunit vaccines Four color reversible termination sequencing involves produced by inserting antigen genes into vectors. stopping DNA synthesis after each nucleotide addition, ○ Gene Therapy: Replacing missing or defective recording the sequence, and then removing the dye and stop genes with normal copies. group to continue. ○ Applications: Sequencing complete genomes of Agricultural Applications pathogens, developing drugs and therapies, relating ○ Transgenic Organisms: GMOs engineered for DNA sequences to protein functions. specific traits like herbicide tolerance and pest ○ Example: Studies on *Deinococcus radiodurans* for resistance. radiation resistance, psychrophiles for enzymes ○ Herbicide Tolerance: Glyphosate tolerant crops active at low temperatures. enable weed control without damaging crops. Applications and Impact ○ Pest Resistance: Crops producing insecticidal proteins from Bacillus thuringiensis. ○ Industrial and Environmental : Enhanced production processes, bioremediation, resource ○ Nutritional Improvement: Adding genes for desired traits like salt tolerance and increased extraction. nutritional value. ○ Medical : Development of pharmaceuticals, gene therapy, diagnostics. Safety and Ethical Concerns ○ Research : Simplified gene isolation, genetic ○ Debate: Controversy over long term effects and mapping, and sequencing. unforeseen problems. Summary of Tools and Techniques ○ Regulatory Measures: Implemented to prevent accidental release of altered organisms. ○ Mutagens : Induce genetic changes. ○ Reverse Transcriptase : Converts RNA to cDNA for ○ Ethical Issues: Privacy, ownership of genetically modified organisms, and forced genetic expression in prokaryotic cells. manipulations. ○ ynthetic Nucleic Acids : Created in vitro for various applications. Future Considerations ○ Restriction Enzymes : Cut DNA at specific sites for ○ Emerging Technologies: Continued advancement combining DNA fragments. in gene editing and its implications on society. ○ Vectors : Deliver genes into cells. ○ Ethical Considerations: Addressing societal ○ PCR : Amplifies specific DNA segments for analysis. concerns as genomic technologies evolve.

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