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• The information in the DNA is in the form of a chemical code made up of four letters (A, T, C and G). Each 'word' in the information is made up of three of these four letters
• The information in a gene is like a recipe for a specific protein
• Genes are strings of letters arranged in a specific order. Just like in a recipe for a cake, the ingredients must be right and added together in the right order
• It is possible to 'read' the genetic code to find out the change in the information that has made a gene faulty
• There are a number of different ways in which the coded information in a gene can be changed so that the gene becomes faulty
• How the change in the genetic information affects the gene message and the gene product depends on:
  • the chromosome on which the gene is located (an autosome - numbered chromosomes 1-22 or a sex chromosome (X or Y)
  • the position of the gene on the chromosome
  • whether the cell can still work with the change present in only one copy of the gene ie. having one faulty copy and one working copy does not usually cause a problem (a recessive mutation)
  • whether the cell requires both copies of the gene to be sending the right message ie. having one faulty copy and one working copy of the gene causes a problem (dominant mutation)
• Everyone is born with several genes that are faulty due to recessive mutations but which usually do not cause a problem (the back up system is in place)

The information in a gene is not read from the beginning to the end without stopping.

Genes are actually made up of segments of lengths of coding DNA that are expressed in the form of a protein product, interspersed by segments of lengths of non-coding DNA (an intervening DNA sequence).

• There are 'stops' and 'starts' in the information in each gene determined by the sequence of the letters in the codon
• Genes are therefore read in a start stop fashion rather than continuously

This means that the whole message that results from a particular gene is made up of separated 'sentences'. In Figure 5.1, the information in the gene results in a message that is made up of three 'sentences'.

Figure 5.1. Representation of the message (the genetic code) sent to the cell from a gene, made up of 3 separate 'sentences'. The sentences are first read and then translated into a protein.

• The coding DNA sequence within a gene is called an exon (because it is expressed). Each exon results in a sentence in the message read by the cell (Figure 5.2).
• The non-coding DNA sequence within a gene that separates the sentences is called an intron (because it is an intervening sequence).

Changes to the sequence of letters in the non-coding segments of the gene (introns) can have an effect on the way the gene is read from beginning to end. If the instructions for where to start and stop reading are interrupted or changed, the gene product may be faulty or reduced in amount.

There are a number of different ways in which the coded information can be changed to make a gene faulty as shown in Figure 5.3. These changes can occur in either the exon or the intron of a gene.

If the change occurs in the exon and affects the sentence that is produced, it may cause a problem with the way the gene works.

Since the introns do not produce sentences that are contained in the message, changes in an intron can be present and cause no problem. If however, the change in the intron is to the start and stop instructions, the message produced may be affected.

Many genetic conditions can be caused by several different types of mutations that occur in the same gene in different people. In some people, a condition may be due to a point mutation; in others it may be a deletion that makes the gene faulty.

As people have two copies of each gene, they may have a point mutation in one gene copy and a deletion in their other gene copy. Nevertheless, the result is that both genes will be faulty and no working message will be produced from either gene copy.

• The same mutation will be present in the genes in all affected members of a family (family-specific mutations).

(a) Genes located on one of the chromosomes

Numbered 1-22 (autosomes)

Genes located on the autosomes (chromosomes that are numbered by scientists as 1-22), are in pairs (see Genetics Fact Sheet 1).

• Both copies of the gene pair send a message to the cell to make a particular product (a protein)
• A mutation in one copy of the gene makes that gene copy faulty
• The faulty gene's message may lead to the production of a protein that does not work properly, a reduced amount of protein or perhaps no protein at all
• The information for the gene product, however, will still be sent from the working copy of the gene to the cells

The impact in males and females of a mutation in a gene located on an autosome will usually be the same.

Autosomal recessive mutations

If the body can still work normally with less than the usual amount of the working gene product available, the person will be unaffected by having a gene in which one copy is faulty and the other working properly. The person is therefore an unaffected 'carrier' of the faulty gene copy.

• In these cases, the mutation causing the gene copy to be faulty is hidden or 'recessive' to the unchanged information in the working copy of the gene
• If both copies of a gene are faulty, there may be only an incorrect gene product, no gene product or the wrong amount produced in the cells of the body, which can result in the person being affected by a condition

A child can inherit a gene copy that is faulty due to a recessive mutation from a parent and be an unaffected carrier of the faulty gene copy just like the parent.

• If both parents carry the same faulty gene copy, there is 1 chance in 4 (25% chance), in every pregnancy, that their child will inherit both faulty copies of the gene and be affected by a genetic condition
• Genetics Fact Sheet 8 describes this pattern of inheritance in families, called autosomal recessive inheritance
• Genetics Fact Sheets 33, 34, 35 & 36 describe conditions that are directly caused by a recessive mutation in both copies of the gene that makes them faulty

When parents are close blood relatives, the chance is higher that they will share the same faulty gene (see Genetics Fact Sheet 16).

A recessive mutation can also occur in a gene for unknown reasons in the formation of a single sperm or egg cell or during or shortly after conception.

• This is referred to as a 'new' or 'spontaneous' recessive mutation
• If the faulty gene arising from that spontaneous mutation is located on autosome, that person will not be affected by having the faulty gene copy, ie. they will be an unaffected carrier of the mutation. They still have a working copy of the gene to provide the information for the cell to work normally

Autosomal dominant mutations

If the body cannot work normally with less than the usual amount of working gene product, the person will be affected by having a gene in which one copy is faulty and the other working.

• The mutation making the gene copy faulty appears to override or 'dominate' the information in the working copy of the gene
• Where a person has a dominant mutation that causes a genetic condition, they will usually be affected or predisposed to develop the condition

The 'dominant' mutation can be passed to a child from the parent (inherited).

• If a parent has the condition, or is predisposed to develop the condition, there is 1 chance in 2 (50% chance), in every pregnancy, that their child will inherit the faulty gene copy containing the dominant mutation from the affected or predisposed parent
• Genetics Fact Sheet 9 describes this pattern of inheritance in families, called autosomal dominant inheritance
• Genetics Fact Sheets 38 & 44 describe conditions that are directly caused by a dominant mutation in one of the copies of a gene that that makes the gene faulty (achondroplasia and huntington disease)
• Genetics Fact Sheets 48 & 50 describe an inherited predisposition to breast and ovarian cancer, and melanoma where an inherited dominant mutation in one of the gene copies makes the person predisposed or susceptible to develop the condition. In these conditions, the expression of the condition requires interaction with certain environmental factors (see Genetics Fact Sheet 11)

A 'dominant' mutation can also occur in a gene for unknown reasons in the formation of a single sperm or egg cell or during or shortly after conception.

• This is referred to as a 'new' or 'spontaneous' dominant faulty gene
• If the faulty gene results in a genetic condition in that person arising from the fertilised egg, the affected person will be the first in the family to have the condition
• There will be no history of the condition in the family: the condition is described as 'sporadic'
• He or she, however, may then pass the faulty gene causing the condition on to future generations

(b) Genes located on the X chromosome

The effects of mutations in genes carried on the X chromosome are different in males and females.

• Males have one Y chromosome and one X chromosome; they therefore only have one copy of the genes that make up most of the X chromosome
• Females have two copies of these X chromosome genes
• Shortly after conception, most of one of the X chromosome copies in each female cell is `switched off' or inactivated. This means that both males and females have only one active X chromosome copy in each cell, ie. only one copy of each gene on the X chromosome in each cell is active in both males and females
• The process by which the X chromosome is 'switched off' is random. Therefore, some cells will have the X chromosome coding for the working product, while other cells will have cells producing the wrong or reduced amount of product, or no product at all, due to the faulty gene
• This system of inactivating one copy of the X chromosome in females is discussed in Genetics Fact Sheet 14 and is an example of epigenetics

Genes that are not switched off in this process are located at the end of the short arms of both the X and Y chromosome. These regions are called the pseudo-autosomal regions. The genes located in these regions behave just like the genes on the autosomes. Changes in these genes will be autosomal recessive or autosomal dominant mutations despite their location on the X and Y chromosomes.

Some gene products must be present in all the cells of the woman for the body to work normally.

A mutation in a gene on the X chromosome that impairs the cell's ability to make a product will therefore show an effect and so the mutation is described as 'dominant'.

A woman who is an X-linked carrier of a dominant mutation will have 1 chance in 2, or 50% chance, in every pregnancy, of passing the recessive X-linked mutation on to both her sons and daughters who may be affected by a condition due to the faulty X-linked gene. Conditions due to an X-linked dominant mutation are rare.

Genetics Fact Sheet 10 describes this pattern of inheritance in families, called X-linked dominant inheritance.

Harper P. (2004). Practical Genetic Counselling. London: Arnold

Online Mendelian Inheritance in Man, OMIM. McKusick-Nathans Institute for Genetic Medicine, Johns Hopkins University (Baltimore, MD) and National Center for Biotechnology Information, National Library of Medicine (Bethesda, MD)[online]. Available from: http://www.ncbi.nlm.nih.gov/omim/ [Accessed June 2007]

Read A and Donnai D. (2007). New clinical genetics. Bloxham, Oxfordshire. Scion Publishing Ltd.

Trent R. (1997). Molecular medicine. 2nd ed. New York: Churchill Livingstone Ltd.

June 2007 (4th Ed)

Author/s: A/Prof Kristine Barlow-Stewart

Acknowledgements this edition: Gayathri Parasivam

Previous editions: 2004, 2002, 2000

Acknowledgements previous editions: Mona Saleh; Bronwyn Butler; Prof Eric Haan; Dr Meredith Wilson; Prof Ron Trent