Earth and Life Science Quarter 2 Genetic Engineering PDF

Summary

These notes cover genetic engineering, specifically focusing on the processes involved and the categories of genetic engineering. The notes include an overview of the key stages, from DNA cleavage to cloning and screening for the desired transgenes.

Full Transcript

EARTH AND LIFE SCIENCE
QUARTER 2
MODULE 4
LESSON 1 – GENETIC
ENGINEERING
LEARNING COMPETENCY: DESCRIBE THE
PROCESS OF GENETIC ENGINEERING

Genetic engineering is the artificial
manipulation, modification, and
recombination of DNA or other nucleic
acid molecules in order to modify an
organism.
 Genetic engineering is the direct
manipulation of an organism’s genes using
biotechnology. It covers different kinds of
technologies used to alter the genomes
that includes the insertion of genes from
other individual either the same or from
different species that aims to produce or
improve products.
 4 MAIN CATEGORIES OF GENETIC
1. GreenENGINEERING
Genetic Engineering/ Agro-Genetic Engineering – Aims to
develop genetically modified plants in agriculture or the the food sector.
2. Red/Yellow Genetic Engineering – Utilized in medicine, aesthetics,
diagnostics (genetics test) and gene theraphy as well as development and
production of drugs (insulin, vaccines).
3. Grey/White Genetic Engineering – this is the production of enzymes or
fine chemicals for industrial use with the aid of genetically modified micro –
organisms (e.g. development of products for enhanced washing
performance.
4. Genetically Modified Animals – utilized for specific food production( e.g.
dairy cows modified to produce allergy-free milk, some are used for
entertainment and amusement.
 BASIC PROCESS OF GENETIC ENGINEERING

1.DNA Cleavage
2.Production of Recombinant DNA
3.Cloning
4.Screening
1. DNA CLEAVAGE

Process in DNA Cleavage
1.Selection of Gene of Interest (GOI) - desired
traits
Example: growth hormone, herbicide resistant,
resistant to drought, or insects.
2. Isolation of the DNA fragment or gene from the
chromosome( containing the target gene) and a
plasmid
However, in a normal cell, the DNA not only exists within the cell membrane, but is also
present along with other macromolecules such as RNA, polysaccharide (carbohydrates),
proteins and lipids. So, how we break open the cell and obtain DNA that is free from other
macromolecules? We can use the following enzymes for specific purposes:
Lysozyme- to break bacteria cell wall
Cellulase – to break plant cell wall
Chitinase – to break fungal cell wall
Ribonuclease – removes RNA
Protease – removes proteins (such as histones that are associated with DNA.
3. Cutting the chromosomes(restriction) and
plasmids with a restriction enzyme.

Restriction enzymes acts as molecular scissors that cut NDA at
specific locations. The desired DNA is cleaved from the donating
chromosome by the action of restriction enzymes, which recognize
and cut specific nucleotide segments, leaving a sticky end on both
ends. The restriction enzymes also merge the receiving
chromosome in a complementary location, again leaving “sticky
ends” to receive the desired DNA.
 2. PRODUCTION OF RECOMBINANT DNA

1. Insertion of the cut sections of the chromosomes into the plasmid
The desired DNA fragment is inserted into a vector, usually a plasmid, for transfer to the
receiving chromosomes. Plasmids are circular DNA molecules found in the cytoplasm of
bacteria that bond with the desired DNA fragment.
The vector is a carrier molecule which can carry the gene or interest (GI) into a host,
replicate there along with the GI making tis multiple copies.
The different types of vectors available for cloning are plasmids, bacteriophages,
bacterial artificial chromosomes (BACs), yeast artificial chromosomes (YACs) and
mammalian artificial chromosomes (MACs)
 3. CLONING

1. Transformation of bacterial cells i.e. getting the bacterial cells to
take up the plasmids
if the transfer is successful, the cells will contain a piece of recombinant DNA in
their genome. Every time the cell undergoes cell division, it will replicate the
recombinant DNA along with its own genome and transfer it to the daughter
cells. The result is an increase in the number of cells containing the desired
gene.
Example: if a recombinant DNA bearing a gene for ampicillin-resistance is
transferred into recipient E. coli bacterial cells, then the E. coli cells also become
ampicillin-resistant.
 4. SCREENING

1. Amplification and expression the trait of the recombinant DNA
the transformation process generates a mixed population of
transformed and non-transformed host cells. Transformed cells are then
regenerated into transgenic organisms. The transgenic organism are
grown maturity, and the inherited the transgene is collected. The
engineer’s job is now complete. He/she will hand the transgenic
organisms over to a plant or animal breeder who is responsible for the
final step.