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Medical Genetics 1. Prof Duncan Shaw http://www.abdn.ac.uk/~gen155/djshome.html. Major Groups of Clinical Disorders with a Genetic Contribution. Single gene defects Chromosomal abnormalities Congenital malformations Multifactorial diseases - most common causes of illness. - PowerPoint PPT Presentation
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Medical Genetics 1
Prof Duncan Shawhttp://www.abdn.ac.uk/~gen155/djshome.html
Major Groups of Clinical Disorders with a Genetic Contribution
• Single gene defects
• Chromosomal abnormalities
• Congenital malformations
• Multifactorial diseases - most common causes of illness
Autosomal recessive inheritance
• Cystic fibrosis (1/2000)
• Recessive mental retardation (1/2000)
• Congenital deafness (1/5000)
Increased risk in autosomal recessive disease
• Consanguinity: if parents are related (consanguinity) there is an increased risk that both parents carry the same recessive allele
Degree Example % alleles shared
1st Siblings, parent/child 50
2nd Uncle/niece, grandparent/child
25
3rd 1st cousins 12.5
Ethnic associations with AR disease
• In particular populations, recessive allele frequency may have increased by selection in heterozygotes, or by genetic drift
-Thalassaemia: Cypriots, Greeks, Italians, Chinese, African-Americans
• Sickle Cell Disease: Arabs, West Indians• Tay-Sachs Disease: Ashkenazi Jews (4%
carriers)• Severe Combined Immunodeficiency Syndrome:
Apache Native Americans• Cystic Fibrosis: Caucasians
Finding the cystic fibrosis gene
• CF gene was found using positional cloning
• Linkage to markers on chromosome 7
• But that didn’t get closer than several Mb – still lots of genes
• To narrow the candidate region further, used linkage disequilibrium…..
Linkage and linkage disequilibrium
• Linkage is tested within families, LD by population study• This marker is linked to the disease, but to different
alleles (of the same marker gene) in each family
1,2 1,2
1,1 1,1 2,2 1,1
1,2 1,2
2,2 2,2 1,1 2,2
How LD arises
LD and haplotypes
• Haplotype – the set of alleles carried by an individual chromosome
• With N bi-allelic markers, expect 2N possible haplotypes in population, because recombination creates all possible combinations of alleles
• If fewer than 2N haplotypes are observed, this is evidence for LD
• Previous example: A1/A2 and CF/N gives 4 haplotypes with recombination, or 3 with LD
Testing for LD
Marker A (shows LD with disease)
Marker B (no LD, but could be linked)
Allele 1 Allele 2 Allele 1 Allele 2
Patients 150 50 120 80
Controls 100 100 120 80
2 test for significance
LD operates over short genetic distances
LD
0
1
Distance (kb) from disease gene
-5000 -100 0 +100 +5000
Use of LD for gene mapping
• A gene can be mapped by linkage in families to within a few cM ( = a few Mb in humans)
• If all or most cases of the disease are descended from a unique mutation, LD will be observed with markers about 100kb or less from the gene – much closer than you can get using linkage alone
• In CF, about 70% of mutations are the same (F508) and these show LD with markers very close to the CF gene – this helped the gene to be identified
Autosomal dominant inheritance
• An affected person usually has one affected parent
• Transmitted by either sex
• Child of an affected parent is at 50% risk of also being affected
Autosomal Dominant Diseases
Disease: Frequency/1000 births:
Otosclerosis 3
Familial hypercholesterolaemia 2
Adult polycystic kidney disease 1
Multiple exostoses 0.5
Huntington’s disease 0.4
Multiple exostoses
The ear
Comparisons between AD and AR
Dominant• Expressed in
heterozygote• Approx. 1/2 offspring
affected• Equal frequency and
severity in each sex• Paternal age effect on
rate of new mutation• Variable expressivity
Recessive• Expressed in homozygote• Low risk to offspring• Equal frequency and
severity in each sex• New mutations rare• Constant expressivity in
each family• Importance of
consanguinity
Revision of linkage and Lod scores
• Affecteds have A marker allele from Dad, unaffecteds have B
• If random, would expect 50:50 distribution• Evidence for linkage?
Revision of linkage and Lod scores (2)
• If marker and disease were unlinked, probability of this pedigree: (1/2)4 = 1/16 = 0.0625
• If they are linked with RF = 0.1 (10% recombination), probability of pedigree: (0.9)4 = 0.66 and odds ratio (relative to no linkage) = 0.66/0.0625 = 10.56
• If they are linked with RF = 0.0, probability of pedigree: (1)4 = 1 and odds ratio (relative to no linkage) = 1/0.0625 = 16
• To combine information from several families, take log10 of odds ( = LOD score) and add them up
• LOD > 3 good evidence for linkage; LOD < -2 evidence against linkage; -2 < LOD < 3 is inconclusive
