chapter 19 p1 Flashcards
mutation
a change in the sequence of bases in DNA
Protein synthesis can be disrupted if
the mutation occurs within a gene.
The change in sequence is caused by the substitution, deletion, or insertion of one or more nucleotides (or base pairs) within a gene.
If only one nucleotide is affected it is called a point mutation.
The substitution of a single nucleotide:
changes the codon in which it occurs.
If the new codon codes for a different amino acid this will lead to a change in the primary structure of the protein.
The degenerate nature of the genetic code may mean however that the new codon still codes for the same amino acid leading to no change in the protein synthesised.
The position and involvement of the amino acid in R group interactions within the protein:
will determine the impact of the new amino acid on the function of the protein.
For example, if the protein is an enzyme and the amino acid plays an important role within the active site, then the protein may no longer act as a biological catalyst.
The insertion or deletion of a nucleotide, or nucleotides
leads to a frameshift mutation (Figure 1).
The triplet code means that sequences of bases are transcribed (or read) consecutively in non-overlapping groups of three.
This is the reading frame of a sequence of bases.
Each group of three bases corresponds to one amino acid.
The addition or deletion of a nucleotide:
moves, or shifts, the reading frame of the sequence of bases.
This will change every successive codon from the point of mutation.
The same effect is seen however many nucleotides are added or deleted, unless the number of nucleotides changed is a multiple of three.
Multiples of three correspond to full codons and therefore the reading frame will not be changed - but the protein formed will still be affected as a new amino acid is added.
effect of different point mutations diagram
Effects of different mutations:
No effect
Damaging
Beneficial
No effect
there is no effect on the phenotype of an organism because normally functioning proteins are still synthesised.
Damaging
the phenotype of an organism is affected in a negative way because proteins are no longer synthesised or proteins synthesised are non-functional.
This can interfere with one, or more, essential processes.
Beneficial
very rarely a protein is synthesised that results in a new and useful characteristic in the phenotype.
For example, a mutation in a protein present in the cell surface membranes of human cells means that the human immunodeficiency virus (HIV) cannot bind and enter these cells.
People with this mutation are immune to infection from HIV.
Causes of mutations:
- Mutations can occur spontaneously, often during DNA replication, but the rate of mutation is increased by mutagens.
- A mutagen is a chemical, physical, or biological agent which causes mutations
- The loss of a purine base (depurination) or a pyrimidine base (depyrimidination) often occurs spontaneously.
- The absence of a base can lead to the insertion of an incorrect base through complementary base pairing during DNA replication.
- Free radicals, which are oxidising agents, can affect the structures of nucleotides and also disrupt base pairing during DNA replication.
- Antioxidants, such as vitamins A, C, and E (found in fruit and vegetables), are known anticarcinogens because of their ability to negate the effects of free radicals.
main mutagens
Effects of mutation:
Silent mutations:
Nonsense mutations:
Missense mutations:
Beneficial mutations:
Silent mutations:
The vast majority of mutations are silent (or neutral) which means they do not change any proteins, or the activity of any proteins synthesised.
Therefore, they have no effect on the phenotype of an organism.
They can occur in the non-coding regions of DNA (introns) or code for the same amino acid due to the degenerate nature of the genetic code.
They may also result in changes to the primary structure but do not change the overall structure or function of the proteins synthesised.
