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Transcript
Dihybrid Cross Work through the example below: Black hair is dominant, White hair is recessive Short hair is dominant, Long hair is recessive A homozygous dominant for both traits with a homozygous recessive for both. Show gametes, F1 genotypes, phenotypes and ratios, then do the same for the F2 generation. Pedigree Diagrams Aims: Must be able to recall the basics of monohybrid and dihybrid crosses. Should be able to outline what a pedigree diagram is and what it is used for. Could be able to draw and interpret different pedigree diagrams. Pedigree Diagrams Pedigree diagrams are used to show the inheritance of a particular trait. The diagram can be used to provide information about the trait: Recessive or dominant Located on autosomal or sex chromosome Autosomal Dominant Idealised pattern: (Diagram p329) Males and Females can be affected All affected individuals have at least on affected parent Transmission from either mother or father to either son or daughter Once a trait leaves a branch it will not return In a large sample equal numbers of each sex affected Examples include: Huntington’s Disease (HD gene), Familial Alzheimer’s (AD1 gene) Autosomal Recessive Idealised pattern: (Diagram p330) Males and Females can be affected Two unaffected parents can have an affected child All children of both affected parents MUST show the trait The trait may disappear and reappear in a given branch In a large sample equal numbers of each sex affected Examples include: Cystic Fibrosis (CFTR gene), Thalassaemia (HBB gene) X-Linked Dominant Idealised pattern: (Diagram p331) Male with the trait passes it on to all daughters, no sons Female with the trait may pass on to both daughters and sons Every affected person has at least one parent with the trait If the trait disappears from a branch is does not reappear Over a large number more affected females than males Examples include: Incontinentia pigmenti (IP2 gene) X-Linked Recessive Idealised pattern: (Diagram p331) All sons of a female with the trait are affected All daughters of a father with the trait will be carriers All children of both parents with the trait will have the trait None of the sons of a male with the trait and a female without the trait will show the trait unless the female is a carrier In a large sample more males than females show the trait Examples include: ichthyosis (STS gene), Red-green colour blindness (CBD gene) Activity Answer the questions from the sheet provided.
