Detailed Notes – 2- Chapter 9-BIOTECHNOLOGY : PRINCIPLES AND PROCESSES

9.3 PROCESSES OF RECOMBINANT DNA TECHNOLOGY

1. Isolation of DNA:

   • Purpose: Obtain the DNA containing the gene of interest.
   • Technique: DNA extraction methods are used to isolate genomic DNA or specific DNA fragments from cells or tissues.

2. Fragmentation of DNA by Restriction Endonucleases:

   • Purpose: Cut the DNA into smaller fragments at specific recognition sequences.
   • Technique: Use of restriction endonucleases (restriction enzymes) to cleave DNA at specific sites, generating DNA fragments with sticky ends.

3. Isolation of Desired DNA Fragment:

   • Purpose: Select and isolate the specific DNA fragment containing the gene of interest.
   • Technique: Gel electrophoresis is often used to separate DNA fragments based on size, followed by extraction and purification of the desired fragment.

4. Ligation of DNA Fragment into a Vector:

   • Purpose: Insert the desired DNA fragment into a suitable vector for cloning.
   • Technique: Use of DNA ligase to join the sticky ends of the DNA fragment and vector, creating a recombinant DNA molecule.

5. Transferring Recombinant DNA into the Host:

   • Purpose: Introduce the recombinant DNA into host cells for replication and expression.
   • Techniques:
     • Transformation: Transfer of DNA into bacterial cells using methods like heat shock or electroporation.
     • Other methods such as micro-injection for animal cells or biolistics/gene gun for plant cells.

6. Culturing the Host Cells at Large Scale:

   • Purpose: Allow the host cells to multiply and produce the desired product.
   • Techniques: Cultivation of transformed cells in a suitable growth medium under controlled conditions (e.g., temperature, pH, nutrients) to support cell growth and gene expression.

7. Extraction of the Desired Product:

   • Purpose: Retrieve the product synthesized by the host cells containing the recombinant DNA.
   • Techniques: Cell lysis and purification methods to isolate and extract the desired product, such as proteins, enzymes, or pharmaceutical compounds.

9.3.1 Isolation of the Genetic Material (DNA)

1. Breaking Cell Open:

   • Purpose: Release DNA along with other macromolecules from cells.
   • Techniques:
     • Enzymatic Treatment: Use enzymes like lysozyme (for bacteria), cellulase (for plant cells), chitinase (for fungi) to break cell walls and membranes.
     • Mechanical Disruption: Physical methods like sonication or bead-beating can also be used to break open cells.

2. Removal of RNA and Proteins:

   • Purpose: Obtain pure DNA free from RNA and proteins.
   • Techniques:
     • Ribonuclease Treatment: Enzyme treatment to degrade RNA molecules.
     • Protease Treatment: Enzymatic degradation of proteins.
     • Other Treatments: Additional treatments may be needed to remove lipids, polysaccharides, and other contaminants.

3. Purification of DNA:

   • Purpose: Obtain pure DNA free from other molecules.
   • Techniques:
     • Ethanol Precipitation: Adding chilled ethanol to the DNA solution causes DNA molecules to precipitate out.
     • Centrifugation: Centrifugation is often used to collect and separate precipitated DNA from the solution.
     • DNA appears as fine threads or clumps in the suspension after precipitation.

9.3.2 Cutting of DNA at Specific Locations

1. Restriction Enzyme Digestion:

   • Purpose: Cut DNA at specific recognition sequences using restriction enzymes.
   • Procedure:
     • Incubation: Purified DNA molecules are incubated with the appropriate restriction enzyme under optimal conditions for that enzyme.
     • Optimal Conditions: Factors like temperature, pH, and buffer composition are optimized for efficient enzyme activity.

2. Agarose Gel Electrophoresis:

   • Purpose: Check the progress and verify the success of restriction enzyme digestion.
   • Technique:
     • Gel Preparation: Pouring agarose gel and creating wells for DNA samples.
     • Loading Samples: Loading digested DNA samples onto the gel.
     • Electrophoresis: Applying an electric field to the gel, causing DNA fragments to migrate based on size. Smaller fragments move faster and farther.

3. Joining DNA Fragments (Ligation):

   • Purpose: Combine the cut gene of interest with the cut vector DNA to create recombinant DNA.
   • Procedure:
     • Mixing Fragments: Mix the cut gene of interest (from source DNA) and the cut vector DNA, both treated with the same restriction enzyme.
     • Addition of Ligase: DNA ligase enzyme is added to catalyze the formation of phosphodiester bonds between the DNA fragments, creating a recombinant DNA molecule.

4. Resulting Recombinant DNA:

   • Outcome: The ligation process results in the formation of recombinant DNA, where the gene of interest is inserted into the vector DNA at specific sites.

9.3.3 Amplification of Gene of Interest using PCR

1. Primer Design:

   • Purpose: Design two sets of primers that are complementary to specific regions of the DNA sequence flanking the gene of interest.
   • Primer Characteristics: Primers are short, single-stranded oligonucleotides (typically 18-25 nucleotides long) synthesized chemically.

2. PCR Components:

   • Template DNA: Genomic DNA containing the gene of interest.
   • Primers: Two sets of primers (forward and reverse) that flank the target DNA region.
   • Nucleotides: dNTPs (deoxyribonucleotide triphosphates) serve as building blocks for DNA synthesis.
   • DNA Polymerase: Typically, a thermostable DNA polymerase such as Taq polymerase is used, derived from the bacterium Thermus aquaticus.

3. PCR Steps:

   • Denaturation: Heating the reaction to high temperature (around 95°C) to denature the double-stranded DNA, separating it into single strands.
   • Annealing: Cooling the reaction to a specific temperature (typically 50-65°C) to allow primers to anneal (bind) to complementary sequences on the template DNA.
   • Extension/Elongation: Raising the temperature (usually around 72°C) for DNA polymerase to extend the primers by adding nucleotides, synthesizing new DNA strands complementary to the template.

4. Cycling:

   • The denaturation, annealing, and extension steps are repeated in a cycle (typically 20-40 cycles).
   • Each cycle doubles the amount of target DNA, resulting in exponential amplification.

5. Amplification:

   • Outcome: After multiple cycles, billions of copies of the target DNA segment are generated.
   • Applications: The amplified DNA fragment can be used for various purposes, including cloning into a vector for further manipulation or analysis.

9.3.4 Insertion of Recombinant DNA into the Host Cell/Organism

1. Making Cells Competent:

   • Purpose: Prepare the host cells to efficiently take up foreign DNA.
   • Techniques:
     • Chemical Treatment: Cells are treated with chemicals that make their cell membranes more permeable to DNA, enhancing uptake.
     • Electroporation: Brief electrical pulses are applied to cells, creating temporary pores in the cell membrane through which DNA can enter.
     • Heat Shock: Some cells are made competent by exposing them to a brief heat shock, which increases membrane permeability.

2. DNA Uptake:

   • Purpose: Allow the competent cells to take up the recombinant DNA.
   • Techniques:
     • Transformation: Common method for bacterial cells like E. coli, where they take up DNA from their environment.
     • Transfection: Used for introducing DNA into eukaryotic cells (animal or plant cells) using methods like lipofection, electroporation, or viral vectors.

3. Selectable Marker:

   • Purpose: Identify and select cells that have successfully taken up the recombinant DNA.
   • Example: Using a selectable marker gene like an antibiotic resistance gene (e.g., ampicillin resistance gene) in the recombinant DNA.
   • Selection Process:
     • Transforming cells with the recombinant DNA.
     • Plating transformed cells on agar plates containing the antibiotic (e.g., ampicillin) to which the selectable marker provides resistance.
     • Only transformed cells (containing the selectable marker) will survive and grow, while untransformed cells will die due to antibiotic sensitivity.

4. Outcome:

   • Transformed Cells: The cells that successfully take up the recombinant DNA and express the selectable marker (e.g., antibiotic resistance) are considered transformed cells.
   • Selection: The presence of the selectable marker allows for the selection and growth of cells containing the desired recombinant DNA.

9.3.5 Obtaining the Foreign Gene Product

1. Purpose of Large-Scale Production:

   • Meet high demand for the protein or product.
   • Ensure economic efficiency by reducing production costs per unit.
   • Cater to clinical, industrial, and research needs.

2. Expression of Foreign Genes:

   • Inserting alien DNA into a cloning vector leads to multiplication in host cells.
   • Expression of foreign genes involves understanding technical details and optimizing conditions for protein production.

3. Need for Large-Scale Production:

   • Small-scale cultures in labs are insufficient for producing appreciable quantities.
   • Large-scale production is necessary for meeting market demands and economic viability.

4. Continuous Culture Systems:

   • Used to maintain cells in active growth phases for continuous production.
   • Involves draining used medium and adding fresh medium to optimize growth conditions.

5. Bioreactors and Their Role:

   • Bioreactors are vessels for converting raw materials into specific products using cells.
   • Provide optimal growth conditions such as temperature, pH, nutrients, and oxygen.
   • Most common type is stirring bioreactors due to their efficiency in maintaining uniform conditions and mixing nutrients.

6. Benefits of Large-Scale Production:

   • Enables cost-effective production.
   • Supports extensive research, testing, and optimization of processes.
   • Facilitates clinical trials and treatments for therapeutic proteins.
   • Meets demands in industrial applications like enzymes, biofuels, and chemicals.

9.3.6 Downstream Processing

1. Definition and Purpose:

   • Downstream processing refers to a series of processes post-biosynthesis that prepare a product for market.
   • Purpose: Prepare the product for use, ensure safety, efficacy, and quality.

2. Processes Involved:

   • Separation and Purification:
     • Separate the desired product from the cell culture or reaction mixture.
     • Purify the product to remove impurities and contaminants.
   • Formulation:
     • Add suitable preservatives or stabilizers to enhance shelf life and stability.
   • Clinical Trials:
     • Products like drugs must undergo thorough clinical trials to assess safety and efficacy in humans.
   • Quality Control Testing:
     • Rigorous testing to ensure the product meets quality standards and specifications.
     • Testing may include assays for potency, purity, identity, and safety.

3. Variability in Processes:

   • Downstream processing and quality control vary based on the type of product.
   • Different products (e.g., drugs, enzymes, biofuels) have specific processing and testing requirements.