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OUTLINE 14 VI. Extensions to Mendel’s Rules (continued)

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1 OUTLINE 14 VI. Extensions to Mendel’s Rules (continued) D. Sex Linked Inheritance 1. Sex chromosomes 2. Systems of sex determination a. XY system b. X0 systems c. ZW systems d. Haplo-diploid systems e. Non-chromosomalsex determination 3. X-linked inheritance 4. Y-linked inheritance

2 Application of Mendel’s Rules assumes:
1. One allele completely dominates the other 2. All genes have 2 allelic forms 3. All traits are monogenic (affected by only one locus) 4. All chromosomes occur in homologous pairs 5. All genes assort independently 6. An allele is completely expressed when either dominant or heterozygous 7. Each trait is controlled by a different set of factors

3 Hypothetical mechanism for determination of eye color in Humans
Gene for melanin production B (produce) dominant to b (none) 2 Modifier loci affect amount of pigment deposited CC’ and DD’ each non prime allele contributes one unit of deposition G’type at B Modifier loci Phenotype B_ CCDD Dk brown (+4) B_ CCDD’ Med. Brown (+3) B_ CC’DD’ Lt Brown (+2) B_ CC’D’D’ Hazel (+1) BB C’C’D’D’ Green Bb C’C’D’D’ Greenish blue Bb any g’type Blue

4 Hypothetical mechanism for determination of eye color in Humans
A possible cross: P bbCCDD X BbC’C’D’D” (Blue) (Gr-blue) Gametes bCD BC’D’, bC’D’ F1 BbCC’DD” bbCC’DD’ (Lt. Brown) (Blue)

5 XY sex determination In some plants

6 Drosophila melanogaster

7 XO sex determination

8 ZW sex determination

9 Haplo-diploid sex determination

10 Parthenogenesis

11 Environmental control
Alligators Turtles

12 Social control

13 X Y

14 Color blindness: Alleles: X+ = normal vision, Xc = color blind
(X+ is dominant) female genotypes male genotypes normal X+ X+ X+ Y color blind Xc Xc Xc Y carrier X+ Xc

15 Carrier female Xc Xc X+Xc XcY X+ Y Females gametes Colorblind male

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