Class 9 BIO3320 Complex Traits PDF

Summary

These lecture notes cover complex traits in biology, including topics such as causes and types of variation, and how to identify genes affecting complex traits. This material explores concepts related to quantitative traits and the impact of environmental factors on genetic expression.

Full Transcript

Recap Class 8: human karyotype
 Recap Class 8: Dosage
compensation of X-linked genes
Drosophila: an increase of transcriptional activity on X
chromosome of males
C. elegans: a decrease of transcriptional activity of both
X chromosomes of females
Mammals: X-chromosome inactivation
 Recap Class 8: Chromosome
abnormalities in human
pregnancy
Aneuploid: Possessing an abnormal number of one
chromosome (or region of chromosome)
Monosomy: One copy (not compatible with life, very early
pregnancy failure)
Trisomy: Three copies (most not compatible with life, trisomy
13, 18, 21)
Sex chromosome abnormalities (not detrimental)
 Recap Class 8: Chromosomal
abnormalities
Deletions
Duplications (red-green color blindness)
Inversions
Translocations (Robertsonian translocation)
 Recap Class 8: Hybridization and
polyploidization in origin of wheat
Complex Traits
Genetics BIO3320
10/04/2024
 Outline
Complex traits
Causes of variation
Identifying genes affecting complex traits
 Outline
Complex traits
Causes of variation
Identifying genes affecting complex traits
 What are complex traits
Affected by the alleles of two or more genes (genetic
factors)
Also affected by environmental factors
Three categories of complex traits:
continuous traits (quantitative traits)
categorical traits
threshold traits
Categorical and threshold traits
Categorical: the phenotype corresponds to any one of
a number of discrete categories
e.g, the # of puppies in a litter; flower colors; animal fur colors
Threshold: a few phenotypic classes, determined by
multiple genes + the environment. When a threshold is
reached, it shows one phenotype; otherwise, it shows
another phenotype
adult-onset diabetes
 Examples of continuous traits
Heights
Weights
Milk production in cattle
Yield in corn
Blood pressure in humans
Distribution of height among
British women
Distribution of height in a graph

X axis: height intervals xi
Y axis: # of people within the range fi
 Useful parameters of this
distribution – the mean
The mean: average, the peak of the distribution

xi : the midpoint of height interval numbered i
fi : the number of women in the height interval
numbered i
the summation of all classes of data

N : the total sample size
 Useful parameters of this
distribution – the variance
A measure of the spread of the distribution
Estimated in terms of the squared deviation of each
observation from the mean

A large variance: the distribution is spread out
A small variance: the distribution is clustered around the mean
 Useful parameters of this
distribution – the variance
The standard deviation: the square root of variance
In the British women height example:

s2 = 7.24 in2
s = 2.69 inch
 Parameters of the distribution

μ, the mean of the population, estimated by
σ, the standard deviation of the population, estimated by s
σ2, the variance of the population, estimated by s2
 The Normal Distribution
When the data are symmetrical, the distribution can be
approximated by a smooth, bell-shaped curve known as
the normal distribution

Figure 7.2: Graphs showing that the variance of a distribution measures the spread of the
distribution around the mean. The area under each curve covering any range of
phenotypes equals the proportion of individuals having phenotypes within that range.
Features of a normal
distribution
 In-class exercise 1
The distribution of height among 1000 newborn boys has a mean
of 50 cm and a standard deviation of 2 cm. How many boys are
expected to be between 46 and 54 cm tall?
A. 100
B. 680
C. 950
D.990
E. 1000
In-class exercise 2
 Reconciling Mendelian
inheritance with continuous
traits

For continuous traits, how can they be determined by discrete particles proposed by Mendel (genes)?
 Reconciling Mendelian
inheritance with continuous
traits
Three Generations of a
Single
Two parental strains of distinct seed oil content
Gene Trait Both homozygotes

(assuming the trait is
determined by a single
gene; F1 generation has intermediate seed oil content
no dominance between
two different alleles)

F2 generation has 1:2:1 ratio of low,
intermediate and high seed oil content
Low High
seed oil content
 Reconciling Mendelian
inheritance with continuous
traits
Hypothetical distributions of seed oil content in cases of:
One gene two genes

three genes
 Reconciling Mendelian
inheritance with continuous
traits
Hypothetical distributions of seed oil content in cases of:

One gene two genes

When a trait is affected by a large # of loci, the distribution of
phenotypes in a population approximates a normal continuous
distribution

three genes
 Outline
Complex traits
Causes of variation
Identifying genes affecting complex traits
 Causes of variation
Genotypic variation
Environmental variation
Variation due to genotype-by-environment interaction
Variation due to genotype-by-environment association
 Causes of variations #1:
genotypes
Genotypic variance: differences in genotypes that cause
phenotypic variance
Segregation of three genes
affecting a quantitative trait

Assumption:
Each uppercase allele adds one unit to phenoty
Each lowercase has no effect

Result:
7 phenotypic categories, mean = 3; variance =
Segregation of three genes
affecting a quantitative trait
The distribution of phenotypes
as determined by 3 genes or 30
genes
 Genotypic variations
Even in the absence of environmental variation, the
distribution of phenotypes alone provides only limited
information about the # of genes involved, and no
information about the dominance relations of alleles
 Causes of variations #2:
environment
Environmental variance: differences in the environment
that cause phenotypic variance

Fig. 7.8 Seed weight
distribution in a
homozygous line of
edible beans
 Causes of variations #3:
genotype-by-environment
interaction and association
Take a step back:
If genotype and environment separately and
independently affect phenotype:
Phenotypic variance = genotypic variance +
environmental variance

σp2 = σg2 +σe2
 Causes of variations #3:
genotype-by-environment
interaction and association
However:
Genotype and environment may NOT act separately and
independently:
G-E interaction
G-E association
 G-E interaction
Environmental effects on phenotype differ according to
genotype
 Example of G-E interaction

Figure 7.10: Strain A is
superior when
environmental quality is
low (negative numbers),
but strain B is superior
when environmental
quality is high.
 Example #2 of G-E interaction

Mineral supplementation
has the biggest growth effect on
UDUD genotype and has no effect
on UNUN genotype
 G-E association
Different genotypes are not distributed at random in all
possible environments
Certain genotypes are preferentially associated with
certain environments
Farmers feed their cows in proportion to their milk
production levels
 Outline
Complex traits
Causes of variation
Identifying genes affecting complex traits
 Identifying genes affecting
complex traits
Linkage analysis in mapping QTLs
GWAS
Candidate genes for complex traits
 Quantitative-trait Loci mapping
QTL: a gene that affects a complex trait
QTL cannot usually be identified in pedigrees (WHY?)
Identifying QTL through linked genetic marker
Quantitative Trait Loci Mapped
in the Tomato Genome

© Photos.com
Data from A. H. Paterson, et al., Nature 335 (1988): 721-725.
Genome-wide association
studies
 Figure 05.F26: Results of Genome-Wide Association Studies involving seven traits. Each line is a whole-genome Manhattan
plot showing associations between SNPs and a particular condition. SNPs shown in green are ones for which significant
associations with the trait in question were determined.

Reproduced from WTCCC. (2007). Genome-wide association study of 14,000 cases of seven common diseases and 3,000 shared
 Common alleles affecting complex traits
account for a small fraction of total
heritability
Crohn’s disease
GWAS identified 71 associating loci
71 loci account for only 23% of phenotypic variation

Yes, GWAS are informative in the physiological basis of
disease, but some of the diseases / conditions are complex
 Candidate genes for complex
traits
Based on previous knowledge, we suspect that one
gene could be contributing to a trait
We test the function of these genes (candidate genes)
Example:
Identifying natural genetic polymorphism in depression
Candidate gene for depression: a gene that encode a
serotonin transporter (SLC6A4)
 Candidate genes for complex
traits
Serotonin: a neurotransmitter that influences anxiety
and depression
Serotonin transporter SLC6A4: transport serotonin from
neurons that make it to neurons that receive it; also
recycles serotonin (uptake)
SLC6A4 is a target of antidepressant drugs (inhibiting
uptake)
 Candidate genes for complex
traits
S form: the short allele
L form: the long allele
They differ in the # of tandem repeats in the promoter region
L/L genotype: cells make more mRNA, and more SLC6A4 protein
S/L and S/S genotype: higher risk of depression
 Candidate genes for complex
traits

G-E interaction:
Among Ecstasy users (environment
factor),
depression score highest in S/S
genotype

In other words:
depression score difference between
users and nonusers biggest in the S/S
genotype