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TWINS AND GENETICS 

(2)

TWINS

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3

Heritability: Twin Studies

Twin studies are often used to assess  genetic effects on variation in a trait

Comparing MZ/DZ twins can give  evidence for genetic and/or 

environmental influences

(4)

Understanding Genetic and Environmental Influences  Using Twin Studies

100% genes

100% home environment

Monozygotic Twins

(5)

Understanding Genetic and Environmental Influences  Using Twin Studies

100% genes

100% home environment

Monozygotic Twins Dizygotic Twins 50% genes

100% home environment

(6)

Understanding Genetic and Environmental Influences  Using Twin Studies

100% genes

100% home environment

Monozygotic Twins Dizygotic Twins 50% genes

100% home environment

We are a combination of our genes and environment.

(7)

Do both twins show the same characteristic or trait? 

60%

90%

IQ

52%

95%

Height

Dizygotic Monozygotic

Concordance rate

Trait

(8)

Determining the incidence of a disease in twins helps delineate whether there  are genetic and environmental components

56% 11%

Diabetes mellitus

19% 9%

Coronary artery disease

47% 24%

Asthma

34% 7%

Rheumatoid arthritis

38% 8%

Cleft lip and palate

Non‐identical  (DZ)

Identical  (MZ)

Concordance Disease

Both genetic and environmental factors important

(9)

MZ and DZ concordance rates

(10)

GENETIC ENVIRONMENTAL

Duchenne 

muscular dystrophy

Haemophilia

Osteogenesis imperfecta

Club foot Pyloric stenosis Dislocation of hip

Peptic ulcer Diabetes

Tuberculosis

Phenylketonuria Galactosaemia

Spina bifida

Ischaemic heart disease Ankylosing spondylitis

Scurvy

The contributions of genetic and environmental factors to human diseases

Rare Genetics simple Unifactorial High recurrence rate

Common

Genetics complex Multifactorial

Low recurrence rate

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What are Polygenic and  Multifactorial Trait?

Polygenic traits are controlled by two or more genes

Multifactorial traits are polygenic with an environmental component

Example: Height

The Genes are inherited in Mendelian fashion Interaction of genes with environment produce

many different phenotypes

(12)

Height as a Multifactorial Trait

(13)

Bell curve

ƒ Most individuals are clustered at ~average

ƒ Few individuals at extremes of the phenotype

Typical Polygenic Trait in a Population

(14)

Variation in Height

(15)

Characteristics of Multifactorial Tra its

• Several genes control trait

• Not inherited as dominant or recessive

• Genes controlling trait contribute a small  amount to phenotype

• Environmental factors interact with genes to  produce phenotype

• Many phenotypic differences in trait

(16)

How can the probability of recurrence be  determined for multifactorial disorders? 

• The recurrence risk for multifactorial 

disorders has to be determined through  family studies

• Observe the number of affected siblings 

in many families (empiric risk)

(17)

Proband Siblings of proband

Families with  one  child with  multifactorial  condition

50  brothers  and sisters 

(18)

Proband Siblings of proband

50  brothers  and sisters 

2 affected  with  multifactorial  condition Families with 

one  child  with  multifactoria

l condition

(19)

Proband Siblings of proband

Therefore  probability of  recurrence = 1/25  (4%) 2/50 affected  with  multifactorial  condition

Families with  one  child  with  multifactoria

l condition

(20)

Multifactorial:  

cleftlip/palatet

• Examples include some cases of cleft lip and palate; neural  tube defects; diabetes and hypertension

• Caused by a combination of genetic predisposition and  environmental influences

• Pattern – more affected people in family than  expected from 

incidence in population but doesn’t fit  dominant,  recessive 

or X‐linked inheritance  patterns  

(21)

Family studies of the incidence of cleft lip  (± cleft palate)

Anomaly  Risk to sibs %  

 

  Bilateral cleft lip and palate   

  5.7     

  Unilateral cleft lip and palate  

   

  4.2     

  Unilateral cleft lip alone  

   

  2.5 

The more severe the manifestation of a multifactorial condition, the greater 

the probability of recurrence 

(22)

Some multifactorial conditions have an unequal  sex ratio

Condition  Sex ratio 

(males to females)   

Pyloric stenosis  5 to 1 

Hirschprung disease  3 to 1 

Congenital dislocation of hip  1 to 6 

Talipes  2 to 1 

Rheumatoid arthritis  1 to 3 

Peptic ulcer  2 to 1 

For some conditions there must be a different threshold for males and 

females

(23)

Frequency of pyloric stenosis in relatives

Relationship  Frequency %  Increase on general 

population risk for  same sex 

Male relatives of a male  patient 

x10 

Female relatives of a male  patient 

x20 

Male relatives of a female  patient 

17  x35 

Female relatives of a female  patient 

x70 

Pyloric stenosis occurs more commonly in boys than in girls; for a female to be  affected with pyloric stenosis, she must have a particularly strong genetic 

susceptibility 

(24)
(25)

Multifactorial inheritance:

Factors increasing probability of recurrence in a particular family

• Close relationship to proband

• High heritability of disorder (more than 1family member affected)

• Proband of more rarely affected sex

• Severe or early onset disease

• Multiple family members affected

All these suggest that the family has a higher liability to the disorder – genes 

of higher effect or more adverse environmental influences

(26)

Multifactorial inheritance:

Recurrence risk decreases rapidly in 

more remotely related individuals 

(27)

How evidence is gathered for genetic factors in  complex diseases

Familial risks

(what is the incidence of a disorder in relatives compared with the incidence in the  general population?)

Twin studies

(what is the incidence in monozygotic compared with dizygotic twins?)

Adoption studies

(what is the incidence in adopted children of the disorders which their parent had?) 

Population and Migration studies

(what is the incidence in people from a particular ancestry group when they move  to a different geographical area?)

Evidence from these types of studies can estimate the heritability of a condition ‐ the  proportion of the aetiology ascribed to genetic factors rather than environmental factors

(28)
(29)

No.of 

individuals in  population

Liability

In multifactorial disorders, there is a threshold, above  which a person will develop the multifactorial disorder

Threshold

(30)

Multifactorial disorders – practice points

Common conditions

“Environmental” influences act with a genetic  predisposition

Multiple genes with individually small risks often  implicated 

One organ system affected

Recurrence risks:

‐ “empiric figures”

‐ obtained from population studies

‐ use in population from 

which obtained

No.of affected individuals

Liability (genetic and  environmental factors)

Threshold

environment

(31)

Risk factors for coronary artery disease

Uncontrollable (but identifiable)

Family history (genetics) Age

Male sex

Potentially controllable or treatable

Fatty diet

Hypertension Smoking

High serum cholesterol Low serum HDL

High serum LDL Stress

Insufficient exercise Obesity

Diabetes

Major effort to identify common disease susceptibility genes  underway

(32)

Common diseases

• Congenital malformations

Cleft lip/palate

Congenital hip dislocation  Congenital heart defects Neural tube defects

Pyloric stenosis Talipes

Adult onset disorders

Diabetes mellitus Epilepsy

Glaucoma

Hypertension

Ischaemic heart disease Manic depression

Schizophrenia

(33)

Victor A. McKusick

Inheritance of monogenic and complex (multifactorial) disorders.

In monogenic diseases, mutations in a single gene are both necessary and sufficient to produce the clinical phenotype and to cause the disease. The impact of the gene on genetic risk for the disease is the same in all families.

In complex disorders with multiple causes,

variations in a number of genes encoding different proteins result in a genetic predisposition to a clinical phenotype. Pedigrees reveal no Mendelian inheritance pattern, and gene mutations are often neither sufficient nor necessary to explain the disease phenotype. Environment and life-style are major contributors to the pathogenesis of complex diseases.

However, between families the impact of these same genes might be totally different. In one family, a rare gene C (Family 3) might have a large impact on genetic predisposition to a disease. However, because of its rarity in the general population, the overall population effect of this gene would be small. Some genes that

predispose individuals to disease might have minuscule effects in some families (gene D, Family 3).

(34)

Is Intelligence a Multifactorial Trait?

• Head size was used to determine intelligence

• Early 20th century, psychological rather than  physical methods

• Intelligence quotient (IQ) assumes that  intelligence is a biological property

• Concordance in MZ twins raised together and 

apart indicates genetic and environmental factors

(35)

Quantitative Trait Loci (QTLs) 

• Use information from Human Genome Project

• Associated with reading disability (developmental  dyslexia)

• Genes on chromosomes 6, 15, and 4 for cognitive  ability

• Accumulated results indicate intelligence is 

polygenic and multifactorial trait

(36)

IQ and the Bell Curve

(37)

Human Genome and SNPs

• Now that the human genome is (mostly) 

sequenced, attention turning to the evaluation  of variation

• Alterations in DNA involving a single base pair  are called single nucleotide polymorphisms, or SNPs

• Map of ~1.4 million SNPs (Feb 2001)

• It is estimated that ~60,000 SNPs occur within 

exons; 85% of exons within 5 kb of nearest SNP

(38)

Disease‐Marker Association

• A marker locus is associated with a disease if  the distribution of genotypes at the marker  locus in disease‐affected individuals differs 

from the distribution in the general population

• A specific allele may be positively associated 

(over‐represented in affecteds) or negatively

associated (under‐represented)

(39)

Examples:  Alzheimer’s 

• Alzheimer’s disease and ApoE

E4 present E4 absent

Patients 58 33

Controls 16 55

The E4 allele appears to be positively associated with Alzheimer’s disease: 

Odds Ratio = (58/16)/(33/55) = 6

(40)

VOLUME 43 | NUMBER 10 | OCTOBER 2011 , page 1006 Nature Genetics

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Figure 1 Regional association plots of the eight SNPs at seven loci showing genome-wide significant association (P < 5 × 10−8) with pulse pressure (PP) and/or mean arterial pressure (MAP). (a–h) Shown is the statistical

significance of each SNP on the –log10 scale as a function of chromosome position (NCBI build 36) in the meta-analysis of stage 1 only. The sentinel SNP at each locus is shown in blue; the correlations (r2) of each of the

surrounding SNPs to the sentinel SNP are shown in the colors indicated in the key. The fine-scale recombination rate is shown in blue. Gene positions are indicated at the bottom.

(42)

Association is not a specifically genetic phenomenon.

It is simply a statistical statement about the co‐occurence  of alleles  or phenotypes .

Allele A is associated with disease D if people who have D also have  A significantly more often  (or maybe less often) than would  be 

predicted  from the individual frequencies of D and A in the  population.

For example, HLA DR4 is found in 36% of the general UK population 

but in 78% of people with rheumatoid arthritis

(43)

Association has many different explanations not all of them are genetic:

>> direct cause: if you have allele A you are susceptible to disease D

To be a carrier of allele A is not necessary nor sufficient  to develop D, but it  increases the likelihood

>> natural selection: people who have disease D might be more likely to survive and  have children if they also have  allele A

>> population stratification: the general population contains several sub‐groups, and  allele A is more frequent in one of them. 

HLA‐A1 is associated to the ability to eat with chopsticks in San Francisco 

HLA A1 is more frequent in Chinese, who are a large sub group in San Francisco

.

(44)

Comparison of ‘identity by state’ and ‘identity by descent’.

Kok H S et al. Hum. Reprod. Update 2005;11:483-493

© The Author 2005. Published by Oxford University Press on behalf of the European Society of Human Reproduction and Embryology. All rights reserved. For Permissions, please email:

[email protected]

(45)

Examples of ‘identity by descent’ (IBD).

Kok H S et al. Hum. Reprod. Update 2005;11:483-493

© The Author 2005. Published by Oxford University Press on behalf of the European Society of Human Reproduction and Embryology. All rights reserved. For Permissions, please email:

[email protected]

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Affected sib pair analysis

(47)

References

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