Mutations (Edexcel A (SNAB) AS Biology)

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Cara Head

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Cara Head

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Mutations

  • A gene mutation is a change in the sequence of base pairs in a DNA molecule that may result in an altered polypeptide
  • Mutations occur continuously and spontaneously
    • Errors in the DNA often occur during DNA replication
  • As the DNA base sequence determines the sequence of amino acids that make up a protein, mutations in a gene can sometimes lead to a change in the polypeptide that the gene codes for
  • Most mutations do not alter the polypeptide or only alter it slightly so that its structure or function is not changed
    • This is because the genetic code is degenerate 
  • There are different ways that a mutation in the DNA base sequence can occur:
    • Insertion
    • Deletion
    • Substitution
    • Duplication
    • Inversion

Insertion of nucleotides

  • A mutation that occurs when a nucleotide is randomly inserted into the DNA sequence is known as an insertion mutation
  • An insertion mutation changes the amino acid that would have been coded for by the original base triplet, as it creates a new, different triplet of bases
    • Remember that every group of three bases in a DNA sequence codes for an amino acid
  • An insertion mutation also has a knock-on effect on other base triplets by changing the triplets further on in the DNA sequence
    • This means that insertion mutations cause what is known as a frameshift mutation; they don't only change the triplet where the insertion has occurred, but every triplet downstream of the insertion
  • This may dramatically change the amino acid sequence produced from this gene and therefore the ability of the polypeptide to function

Insertion mutation

Insertion mutations occur when a new nucleotide is added into a base sequence

Deletion of nucleotides

  • A mutation that occurs when a nucleotide is randomly deleted from the DNA sequence
  • Like an insertion mutation, a deletion mutation changes the triplet in which the deletion has occurred, and also changes every group of three bases further on in the DNA sequence
    • This is known as a frameshift mutation
  • This may dramatically change the amino acid sequence produced from this gene and therefore the ability of the polypeptide to function

Substitution of nucleotides 

  • A mutation that occurs when a base in the DNA sequence is randomly swapped for a different base
  • Unlike an insertion or deletion mutation, a substitution mutation will only change the amino acid for the triplet in which the mutation occurs; it will not have a knock-on effect elsewhere in the DNA sequence
  • Substitution mutations can take three forms
    • Silent mutations
      • The mutation does not alter the amino acid sequence of the polypeptide; this is due to the degenerate nature of the genetic code
    • Missense mutations
      • The mutation alters a single amino acid in the polypeptide chain, e.g. sickle cell anaemia is caused by a single substitution mutation changing a single amino acid in the sequence
    • Nonsense mutations
      • The mutation creates a premature stop codon, causing the polypeptide chain produced to be incomplete and therefore affecting the final protein structure and function, e.g. cystic fibrosis can be caused by a nonsense mutation
        • Note that a stop codon provides a signal for the cell to stop translation of the mRNA molecule into an amino acid sequence

Substitution mutation

Substitution mutations involve swapping one nucleotide for another

Duplication

  • Duplication is a type of mutation that involves the production of one or more copies of a gene or a region of a chromosome
    • A whole gene or section of a gene is duplicated so that two copies of the gene/section appear on the same chromosome
    • The original version of the gene remains intact and therefore the mutation is not harmful
    • Overtime, the second copy can undergo mutations which enable it to develop new functions
  • Gene duplication is an important mechanism by which evolution occurs
  • Gene and chromosome duplications occur in all organisms, though they are more common in plants

Gene Duplication

In duplication mutations entire genes can be duplicated

Inversion

  • Inversion mutations usually occur during crossing-over in meiosis
    • The DNA of a single gene is cut in two places
    • The cut portion is inverted 180° then rejoined to the same place within the gene
    • The result is a large section of the gene that is 'backwards' and therefore multiple amino acids are affected
  • Inversion mutations frequently result in a non-functional protein
    • In some cases an entirely different protein is produced
  • The mutation is often harmful because the original gene can no longer be expressed from that chromosome
    • If the other chromosome in the pair carries a working gene the effect of the mutation may be lessened

Gene Inversion

Inversion mutations result in the reversal of sections of DNA

Cystic Fibrosis

  • Genes can affect the phenotype of an organism
    • A gene codes for a single polypeptide
    • The polypeptide can affect the phenotype, e.g. it could form part of an enzyme or a membrane transport protein
  • Genetic disorders are often caused by a mutation in a gene that results in a differently-functioning or non-functioning protein that alters the phenotype of the individual

Cystic fibrosis

  • Cystic fibrosis is a genetic disorder of cell membranes caused by a recessive allele of the CFTR (Cystic Fibrosis Transmembrane Conductance Regulator) gene located on chromosome 7
    • This gene codes for the production of chloride ion channels required for secretion of sweat, mucus and digestive juices
    • A mutation in the CFTR gene leads to production of non-functional chloride channels
    • This reduces the movement of water by osmosis into the secretions
    • The result is that the body produces large amounts of thick, sticky mucus in the air passages, the digestive tract and the reproductive system
  • There are many mutations in the CFTR gene that can lead to cystic fibrosis
    • The CFTR gene is large and a mutation in any part of the gene can cause cystic fibrosis
    • Around 1000 different mutations that can lead to cystic fibrosis have been identified, though some only occur very rarely
    • All of the mutations that cause cystic fibrosis are recessive
  • Because cystic fibrosis is determined by a recessive allele, this means
    • People who are heterozygous won’t be affected by the disorder but are carriers
    • People must be homozygous recessive in order to have the disorder
    • If both parents are carriers the chance of them producing a child with cystic fibrosis is 1 in 4, or 25 %
    • If only one of the parents is a carrier with the other parent being homozygous dominant, there is no chance of producing a child with cystic fibrosis, as the recessive allele will always be masked by the dominant allele

Inheritance of cystic fibrosis

Cystic fibrosis is a genetic disorder caused by a recessive allele

The respiratory system

  • Mucus in the respiratory system is a necessary part of keeping the lungs healthy
    • It prevents infection by trapping microorganisms
    • This mucus is moved out of the respiratory tract by cilia 
  • In people with cystic fibrosis, due to the faulty chloride ion channels, the cilia are unable to move as the mucus is so thick and sticky
  • This means microorganisms are not efficiently removed from the lungs and lung infections occur more frequently
  • Mucus builds up in the lungs and can block airways which limits gas exchange
    • The surface area for gas exchange is reduced which can cause breathing difficulties
  • Physiotherapy can support people with cystic fibrosis to loosen the mucus in the airways and improve gas exchange

The digestive system

  • Thick mucus in the digestive system can cause issues because
    • The tube to the pancreas can become blocked, preventing digestive enzymes from entering the small intestine
      • Digestion of some food may be reduced and therefore key nutrients may not be made available for absorption
    • The mucus can cause cysts to grow in the pancreas which inhibit the production of enzymes, further reducing digestion of key nutrients
    • The lining of the intestines is also coated in thick mucus, inhibiting the absorption of nutrients into the blood

The reproductive system

  • Mucus is normally secreted in the reproductive system to prevent infection and regulate the progress of sperm through the reproductive tract after sexual intercourse
  • The mucus in people with cystic fibrosis can cause issues in both men and women
    • In men the tubes of the testes can become blocked, preventing sperm from reaching the penis
    • In women thickened cervical mucus can prevent sperm reaching the oviduct to fertilise an egg

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Cara Head

Author: Cara Head

Expertise: Biology

Cara graduated from the University of Exeter in 2005 with a degree in Biological Sciences. She has fifteen years of experience teaching the Sciences at KS3 to KS5, and Psychology at A-Level. Cara has taught in a range of secondary schools across the South West of England before joining the team at SME. Cara is passionate about Biology and creating resources that bring the subject alive and deepen students' understanding