Lecture 42: Mapping QTLs and Disease genes
(version 17 Sept 2001)
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| You are visitor number | since 17 Sept 2001 |
(version 17 Sept 2001)
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| You are visitor number | since 17 Sept 2001 |
Most traits have a complex genetic basis
No single gene shows perfect segregation with the trait
Generally, Multiple loci contribute
Environmental effects are also important
Even with a single underlying gene, can have:
incomplete penetrance, variable expressivity.
Phenocopies -- individuals showing the trait for strictly environmental reasons.
These are any trait we can measure:
Height, weight, Blood pressure, Facial features, IQ or other quantifiable behaviors
Quantitative Genetics (Chapter 25 in the book) is the branch of genetics that deals with the analysis of such complex traits. There is a very heavy use of statistics, not for the faint-of-heart! ( More info )
Can score individuals as affected / unaffected
Alternatively, if known, the appropriate underlying physiological variable can be used as a quantitative character
e.g., Blood pressure vs. hypertension (affected / normal)
In most cases, don't know underlying biochemical variables.
QTLs (Quantitative Trait loci) -- those underlying quantitative traits
DS (Disease susceptibility) genes -- those influencing an individual's susceptibility to a particular disease (e.g., heart disease, Alzheimer's). Note that DS genes are simply QTLs that influence a disease.
One looks for associations between the trait and the average values for particular alleles at the candidate locus
Each copy of allele e4 found to increases cholesterol level by 5-10
Each copy of allele e2 decreases cholesterol level by 15-20
e4 e4 -- mean age of onset 68.4 years
e4 e- (heterozygote) mean age of onset 75.5 years
No e4 alleles -- mean age of onset 84.3 years
Individuals with long alleles higher in Novelty seeking
More exploratory, thrill-seeking, excitable
Individuals with no long alleles lower in Novelty seeking
More deliberate, rigid, and orderly
D4DR accounts for about 10% of all genetic variance in the trait novelty seeking
High amounts of polymorphism at the DNA level
Two random humans differ by on average 20 million base pairs
These differences provide genetic (molecular) markers for mapping genes
KEY : QTLs, DS genes can be detected by looking for marker-trait associations using these markers.
Can either examine an entire family ( Family analysis ) or pairs of affected individuals ( affected sib pairs )
Here, a number of highly polymorphic marker loci are examined
Suppose a marker locus M is linked to a QTL influences the trait of interest, where
If the father has (say) genotype M1Q / M2q , then he generates the following gametes
| Gamete | frequency | trait value |
| M1Q | (1/2)(1-c) | a |
| M1q | (1/2)c | 0 |
| M2Q | (1/2)c | a |
| M2 q | (1/2)(1-c) | 0 |
A significant difference between offspring carrying alternative parental marker alleles implies a linked QTL.
Suppose we observe the following data in a family. The father has marker genotype M1 M2 while the mother has marker genotype M2 M3
The following trait values are seen in the offspring:
| Offspring marker type | Mean trait value |
| M1 M3 | 30 |
| M1 M2 | 20 |
| M2 M3 | 10 |
| M2 M2 | 20 |
Paternal allele means
M1 = (20 + 30)/2 = 25
M2 = (10 + 20)/2 = 15
Maternal allele means
M2 = (20 + 20)/2 = 20
M3 = (30 + 10)/2 = 20
Hence, the marker appears linked to a QTL that is heterozygous in the father (e.g., Qq), but homozygous in the mother (QQ or qq).
Here the idea is to compare the number of shared maternal and paternal marker alleles in pairs of affected sibs.
Affected sibs 1 & 3 share (1/2) their marker alleles
Both share paternal marker, but have different maternal marker
If the marker is unlinked to disease, we expect, on average, 50% of marker alleles shared
If significantly more than 50% of the marker alleles are shared, this indicates linkage to a QTL.
Using sib pairs nicely controls for shared environmental effects.
22 families with a total of 159 pairs of affected sibs were examined
57% of doubly-affected sib pairs shared the same allele from their parents at a microsatellite marker D18S56.
This is significantly different from 50%, suggesting this marker is linked to a DS gene influencing depression.
Hamer (1993) examined 32 pairs of gay bothers. 22 of these shared the same marker allele from their mother (an X-lined marker in region Xq28).
freq = 22/32 = 67%, which (for this sample size) is significantly different from 50%, indicating a QTL influencing male sexual preference linked to this maker.
No such association was found in 36 pairs of lesbian sisters