Unit 2 KA7 Flashcards
Mutagenesis
The creation of mutations by deliberately exposing an organism to mutagenic agents such as UV light, other types of radiation or chemicals, which alter their DNA.
Wildtype
The original strain of the micro-organism.
Mutants can revert to wildtype by repairing mutations in their DNA, so improved strains used in industry need constant monitoring.
Mutant strain
An improved strain of a micro-organism created by mutagenesis.
It may lack a key enzyme, which may stop or divert a metabolic pathway, leading to accumulation of a desired product.
Mutant strains tend to be unstable and can revert to wildtype.
Recombinant DNA technology
Genetic engineering.
A selected gene can be transferred into a host organism using a vector such as a bacterial plasmid or artificial chromosome.
The host organism is then able to copy and express the new gene, producing the desired protein.
Recombinant DNA
Host DNA and donor DNA combined together.
eg. a bacterial plasmid with a human gene inserted into it.
Restriction endonuclease.
DNA cutting enzymes, used to cut genes out of donor DNA and used to cut plasmids open.
There are many different types eg. EcoR1 (named after E.coli where it is found)
Each type recognises and cuts at a different specific DNA sequence.
Cuts may be straight or staggered, creating ‘sticky ends’
DNA ligase
An enzyme which is used to join fragments of DNA together. Seals the donor gene into the plasmid.
Vector
A bacterial plasmid or artificial chromosome.
Used to carry the donor gene into the host organism.
Artificial chromosomes.
Constructed by scientists.
Have the same features as a plasmid vector but can carry much longer DNA sequences into the host organism.
Features of vectors
Origin of replication
Marker gene
A restriction site
Restriction site
Contains target (recognition) sequences for specific restriction endonucleases.
The same restriction endonuclease must be used to cut the donor DNA and the plasmid, so that the sticky ends are complementary and the 2 pieces of DNA can be joined together.
Marker gene
Allows scientists to select only the cells that have taken up the recombinant plasmids, to avoid wasting resources.
eg. Ampicillin (antibiotic) resistance gene.
When the culture is treated with an antibiotic, only the cells containing the plasmid survive, as they have obtained the resistance gene along with the required donor gene.
Cells which don’t have the plasmid are destroyed.
Origin of replication
Essential for the replication of the recombinant plasmid in the transformed host cell.
Contains genes that control the self replication of the plasmid or artificial chromosome.
Also contains regulatory sequences that control expression of existing and inserted genes.
Limitations of prokaryotes
Prokaryote DNA does not contain introns, so bacterial cells cannot splice eukaryotic DNA (which does contain introns).
Eukaryotic polypeptides (such as insulin) may not be cut or folded correctly after they have been translated, as prokaryotes lack the machinery to do this.
Recombinant yeast
Yeast contains plasmids which can be modified using recombinant DNA technology.
Yeast is harder to grow than bacteria, but it is eukaryotic and so is able to carry out RNA splicing and modification of polypeptides.
