1. Characters which are associate more with one gender
SEX LINKAGE
Characters which are associate more with one gender
© 2007 Paul Billiet ODWS

2. Characters associated with gender
Anhiorotic ectodermal dysplasia
Small teeth, no sweat glands, sparse body hair
Occurs primarily in men
Never transmitted from father to son
Unaffected daughters may pass the condition onto their sons (the grandsons)
© 2007 Paul Billiet ODWS

3. Sex linkage explained
Thomas Hunt Morgan in The Fly Room! (Columbia University 1910)
Fruit Flies (Drosophila melanogaster)
© 2007 Paul Billiet ODWS

4. The case of the white-eyed mutant
Character Traits
Eye colour Red eye (wild type)
White eye (mutant)
P Phenotypes Wild type (red-eyed) female x White-eyed male
F1 Phenotypes All red-eyed
Red eye is dominant to white eye
© 2007 Paul Billiet ODWS

5. Hypothesis
A cross between the F1 flies should give us: 3 red eye : 1 white eye F2
Phenotypes
Red eye
White eye
Numbers
3470
82%
782
18%
So far so good
© 2007 Paul Billiet ODWS

6. An interesting observationF2
Phenotypes
Red-eyed males
Red-eyed females
White-eyed males
White-eyed females
Numbers
1011
2459
782
24%
58%
18% 0%
© 2007 Paul Billiet ODWS

7. A reciprocal cross
Morgan tried the cross the other way round white-eyed female x red-eyed male
Result All red-eyed females and all white-eyed males
This confirmed what Morgan suspected
The gene for eye colour is linked to the X chromosome
© 2007 Paul Billiet ODWS

8. A test cross Red-eyed Males Red-eyed Females White-eyed Males
Phenotypes F1 Red-eyed female x White-eyed male
Expected result
50% red-eyed offspring: 50% white-eyed offspring Regardless of the sex
Observed Results
Red-eyed Males
Red-eyed Females
White-eyed Males
White-eyed Females
132
129 86 88
© 2007 Paul Billiet ODWS

9. Genetic diagram for sex linked genes
Character
Trait
Alleles
Eye colour
Red eye R
White eye r
Genotypes
Phenotypes
XRXR
XRXr
XrXr
XRY
XrY
© 2007 Paul Billiet ODWS

10. Genetic diagrams for sex linked genes
Character
Trait
Alleles
Eye colour
Red eye R
White eye r
Genotypes
Phenotypes
XRXR
XRXr
XrXr
Red-eyed female
White-eyed female
XRY
XrY
Red-eyed male
White-eyed male
© 2007 Paul Billiet ODWS

11. Wild type (red-eyed) female
Phenotypes
Wild type (red-eyed) female x
White-eyed male
Genotypes
XRXR
XrY
Gametes XR Xr Y
Fertilisation Xr Y XR
XRXr
XRY
© 2007 Paul Billiet ODWS

12. F1 Phenotypes Red-eyed female x Red-eyed male Genotypes XRXr XRY
Gametes XR Xr Y
Fertilisation XR Y
XRXR
XRY Xr
XRXr
XrY
© 2007 Paul Billiet ODWS

13. This gene has its LOCUS on the X-chromosome F2
Phenotypes
Females
Males
Red-eyed
White-eyed
Expected
All
None
50%
Observed
2459
1011
782
This gene has its LOCUS on the X-chromosome
It is said to be SEX-LINKED
© 2007 Paul Billiet ODWS

14. X-linked genes
In sex linked characteristics the reciprocal crosses do not give the same results
For X-linked genes fathers do not pass the mutant allele onto their sons
For X-linked genes fathers pass the mutant allele onto their daughters who are carriers
Carrier mothers may pass the allele onto their sons (50% chance)
Females showing the trait for an X-linked mutant allele can exist but they are rare
Female carriers may show patches of cells with either trait due to X chromosome inactivation
© 2007 Paul Billiet ODWS

15. Tortioseshell Cats are Female
© 2007 Paul Billiet ODWS

16. Daltonism = Red-Green Colourblindness
Normal vision
Colour blind simulation
© 2007 Paul Billiet ODWS

17. The retina LIGHT Optic nerve fibres Ganglion layer
Bipolar cells (neurones)
Synapse layer
Nuclear layer
Inner segments packed with mitochondria
Rod and cone outer segments
Rod cell
Cone cell
© 2007 Paul Billiet ODWS

18. PHOTORECEPTION VISION COLOUR MONOCHROME PHOTORECEPTOR CONES:
red sensitive 560nm
green sensitive 530nm
blue sensitive 420nm
RODS: max. sensitivity 505nm
DISTRIBUTION
Concentrated in the fovea
Widely spread over whole retina, absent from fovea
PIGMENTS
3 proteins controlled by 3 genes.
Red and green pigments sex linked
Blue pigment autosomal (Chr.7)
RHODOPSIN = Retinol (Vit A) + Opsin (a protein).
Also called visual purple
BLEACHING
Slow
Fast (very sensitive)
REGENERATION
Slow (after images in bright light, complementary colours)
Fast
USE
Daylight vision
Light adaptation 5 min
Night vision
Dark adaptation 20 min or wear red goggles!
© 2007 Paul Billiet ODWS

19. Blood Clotting and Haemophilia
A simplified scheme of the important steps
Damaged blood vessels
Prothrombin
Inactive enzyme
Thrombin
Active enzyme
Fibrinogen
Globular protein
Fibrin = Clot
Fibrous protein
© 2007 Paul Billiet ODWS

20. Antihaemophilic factor B Antihaemophilic factor A
Contact with collagen fibres in blood vessels
Factor XII (inactive)  Factor XII (active)
Factor XI (inactive)  Factor XI (active)
Factor IX (inactive)  Factor IX (active)
Antihaemophilic factor B
Factor X (inactive)  Factor X (active)
Factor II (inactive)  Factor II (active)
Prothrombin Thrombin
Factor I (inactive)  Factor I (active)
Fibrinogen Fibrin
Factor III
Thromboplastin released from blood vessel walls
Factor VIII
Antihaemophilic factor A
Ca2+ ions and blood platelets
Vitamin K precursor
© 2007 Paul Billiet ODWS

21. The antihaemophilic factors
The blood clotting reaction is an enzyme cascade involving Factors XII, XI, IX, X and II
Each of these enzymes are proteases that cut the next protein in line
Other factors including proteins like Factor VIII are essential as coenzymes
© 2007 Paul Billiet ODWS

22. Heamophilia
About 85% of haemophiliacs suffer from classic haemophilia (1 male in )
They cannot produce factor VIII
The rest show Christmas disease where they cannot make factor IX
The genes for both forms of haemophilia are sex linked
Haemophiliacs do clot their blood slowly because there is an alternative pathway via thromboplastin
© 2007 Paul Billiet ODWS