Pedigree Analysis Have you ever seen a family tree… do you have one??

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Presentation transcript:

Pedigree Analysis Have you ever seen a family tree… do you have one?? Pedigree of Queen Victoria Have you ever seen a family tree… do you have one?? Graphic representation of family inheritance.

Why would we want to use a pedigree in genetics? What is a pedigree? Shows a pattern of inheritance in a family for a specific trait (phenotype) Genotypes can usually be determined Why would we want to use a pedigree in genetics? Track the occurrence of diseases such as: Huntington’s – simple dominant – lethal allele – causes breakdown of the brain Cystic fibrosis – 1/2500 – mucus accumulates (white North Amer.) Tay-Sachs disease – lipids accumulate in CNS (Jewish) Phenylketonuria – missing enzyme causes problems in CNS (Nordic/Swedish)

The Symbols used: (related)

Sample pedigree: generations are numbered with Roman Numerals oldest offspring are on the left How many males are present? How many females? How many females show the trait being studied? What is the sex of offspring III-9? How many offspring did the generation I parents have? What is the difference between the II-3 & 4 and IV-2 & 3?

Inheritance patterns: Autosomal dominant: The disease is passed from the father (II-3) to the son (III-5), this never happens with X-linked traits. The disease occurs in three consecutive generations, this never happens with recessive traits. Males and females are affected, with roughly the same probability. Examples: Polydactyly Huntington’s disease

Inheritance patterns: Autosomal recessive Males and females are equally likely to be affected. The recurrence risk to the unborn sibling of an affected individual is 1/4. The trait is characteristically found in siblings, not parents of affected or the offspring of affected. Parents of affected children may be related. The rarer the trait in the general population, the more likely a consanguineous mating is involved. Cystic fibrosis Tay-Sach’s disease

Inheritance patterns: Sex-linked recessive conditions The disease is never passed from father to son. Males are much more likely to be affected than females. All affected males in a family are related through their mothers. Trait or disease is typically passed from an affected grandfather, through his carrier daughters, to half of his grandsons. Examples: Colour-blindness Duchenne Muscular Dystrophy