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Linked and Sex-linked genes

Linked and Sex-linked genes. Linkage and sex determination. What determines gender? Record for humans and 2 other examples What is the key feature of sex linked inheritance? Males are more affected What is a definition and diagram for sex linked genes?

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Linked and Sex-linked genes

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  1. Linked and Sex-linked genes

  2. Linkage and sex determination • What determines gender? • Record for humans and 2 other examples • What is the key feature of sex linked inheritance? • Males are more affected • What is a definition and diagram for sex linked genes? • Any gene carried on the non-homologous part of the X chromosome is called sex-linked.

  3. Sex linkage • Any gene carried on the non-homologous part of the X chromosome is called sex-linked • The Y chromosome is genetically empty for that characteristic. • Faulty genes on X will show up in males because Y cannot mask effect • Symbols written above X and Y symbols

  4. Red-green colour blindness • Allele common, so some females affected. • Cross a woman with normal vision (but her father was colour blind) with a colour blind man. Give the genotypes and phenotypes of the children.

  5. Haemophilia • Blood fails to clot • 1/6000-10000 males • Royal disease – Queen Victoria • Examine pedigree chart pg 116

  6. Muscular dystrophy • Muscular dystrophies are characterized by progressive skeletal muscle weakness, defects in muscle proteins, and the death of muscle cells and tissue.

  7. Barr bodies • What are they? • Use page 117 to explain • What can this lead to? • Define varigation

  8. Tortoise-shell cats • Only females can be tortoise shell. • Two alleles B = black and O = orange • Males can be ? • Females can be ? • What is the result of a black male mating with an orange female? • XXY is a male tortoise-shell

  9. Activities for practice • Self check 118 – 121 • 2006 Exam Question

  10. Sex-influenced genes • Traits not located on sex chromosomes have different appearances in males and females • Influenced by presence of sex hormones • Eg – pattern baldness in humans • - bulls and milk production • - horns in sheep

  11. Linkage activity • Create some chromosomes and follow what the teacher says……

  12. Humans have 23 pairs of chromosomes and about 100,000 genes therefore many genes are on the same chromosome Linkage

  13. Genes on the same chromosome are linked genes • Linked genes cannot segregate independently, they move together during meiosis so inherited together • Results in less genetic variation in gametes than when independent assortment takes place

  14. Show how these cells can make gametes: A B a b • What ratio is given when this individual is test crossed? • 1:1 is the ratio for linkage with no crossing over

  15. Linkage with cross over • Create chiasma by performing crossing over and recombination with your chromosomes • Now what gametes can form?

  16. Recombination • This is the exchange of alleles between homologous chromosomes as a result of crossing over • It increases genetic variation by creating new combinations of alleles to be passed on in gametes • Offspring formed from these gametes show new combinations of characteristics and are known as RECOMBINANTS

  17. Perform a backcross • This gives a ratio 9:1:1:9 • which is almost a 1:1 ratio with a ‘little bit over’ means that it is linkage with crossing over

  18. Cross over value (COV) • This is the percentage of offspring which show separation of the genes • Copy example from pg 126 • What happens the closer genes are? number of recombinants COV = total number of offspring x 100%

  19. Chromosome mapping • This is the relative position of genes on a chromosome • The further the genes are apart, the more likely they are to break and rejoin

  20. Mapping activities • Self check pg 128 • Handout ‘Q5 Crossing over’ • Handout ‘Q32 part c’

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