1. GENETIC PROBABILITIES
SEX CHROMOSOMES

2. TYPES OF CHROMOSOMES
Just like our cells are categorized as either normal body cells (somatic cells), our chromosomes are categorized the same way.

3. TYPES OF CHROMOSOMES
Just like our cells are categorized as either normal body cells (somatic cells), our chromosomes are categorized the same way.
Chromosomes (DNA) that code for all your non-sex traits are called “autosomes” and those are chromosomes

4. TYPES OF CHROMOSOMES
Just like our cells are categorized as either normal body cells (somatic cells), our chromosomes are categorized the same way.
Chromosomes (DNA) that code for all your non-sex traits are called “autosomes” and those are chromosomes
Chromosome 23 is our “sex chromosome” and it codes for all of our sex/gender (male/female) traits.

5. SEX CHROMOSOMES
Chromosome 23 from each parent are the only chromosomes that are not homologous pairs.

6. SEX CHROMOSOMES
Chromosome 23 from each parent are the only chromosomes that are not homologous pairs.
They come in 2 forms (shapes), one that looks like the normal “X” shape and one that is missing much of the bottom part of the legs so it resembles a “Y”.
Y chromosome
X chromosome

7. CHROMOSOME GENOTYPES
Males have one of each type of sex chromosome, an X and a Y so their genotype is referred to as “XY” even though we’re talking about whole chromosomes, not just alleles on a chromosome.

8. CHROMOSOME GENOTYPES
Males have one of each type of sex chromosome, an X and a Y so their genotype is referred to as “XY” even though we’re talking about whole chromosomes, not just alleles on a chromosome.
Females have 2 X chromosomes so their genotype is referred to as “XX”.

9. A BABY’S GENDER
Remember that a mom only has X chromosomes to donate to her baby. Dad can donate either an X or a Y to his baby, so dads determine the gender of the baby.

10. A BABY’S GENDER
Remember that a mom only has X chromosomes to donate to her baby. Dad can donate either an X or a Y to his baby, so dads determine the gender of the baby.
Dad can donate an X that joins Mom’s X to make a baby girl ( ) XX

11. A BABY’S GENDER
Remember that a mom only has X chromosomes to donate to her baby. Dad can donate either an X or a Y to his baby, so dads determine the gender of the baby.
Dad can donate an X that joins Mom’s X to make a baby girl ( ) XX
Dad can also donate a Y that joins Mom’s X to make a baby boy ( ) XY

12. HERE’S WHY IT’S UP TO DAD
P = XY x XX
dad mom
X Y
X XX XY XX = daughter = 50%
X XX XY XY = son = 50%

13. SEX-LINKED TRAITS Look again at the photo of the X and Y chromosomes.
The X chromosome is much bigger and has room for extra genes (codes for traits).
The Y chromosome is much smaller and only has room for gender related genes.
Extra space for some non-gender traits like baldness, color vision and blood clotting.

14. SEX-LINKED TRAITS Look again at the photo of the X and Y chromosomes.
It’s like the X chromosome has an extra leg that the Y doesn’t have.
The X chromosome is much bigger and has room for extra genes (codes for traits).
The Y chromosome is much smaller and only has room for gender related genes.
Extra space for some non-gender traits like baldness, color vision and blood clotting.

15. SEX-LINKED TRAITS Look again at the photo of the X and Y chromosomes.
It’s like the X chromosome has an extra leg that the Y doesn’t have.
Because these extra genes are on a sex chromosome, they are called “sex-linked traits” (linked to the X)
The X chromosome is much bigger and has room for extra genes (codes for traits).
The Y chromosome is much smaller and only has room for gender related genes.
Extra space for some non-gender traits like baldness, color vision and blood clotting.

16. SYMBOLS
The symbols for the alleles that are sex-linked (linked to the X chromosome) follow all the same rules you’ve already learned.

17. SYMBOLS
The symbols for the alleles that are sex-linked (linked to the X chromosome) follow all the same rules you’ve already learned.
Normal color vision is dominant, colorblindness is recessive so the 2 alleles are represented by N and n.

18. SYMBOLS
The symbols for the alleles that are sex-linked (linked to the X chromosome) follow all the same rules you’ve already learned.
Normal color vision is dominant, colorblindness is recessive so the 2 alleles are represented by N and n.
Hair is dominant, baldness is recessive so the alleles are represented by H and h.

19. SYMBOLS
The symbols for the alleles that are sex-linked (linked to the X chromosome) follow all the same rules you’ve already learned.
Normal color vision is dominant, colorblindness is recessive so the 2 alleles are represented by N and n.
Hair is dominant, baldness is recessive so the alleles are represented by H and h.
Blood clotting is dominant, hemophilia (your blood doesn’t clot) is recessive so the symbols are B and b.

20. SYMBOLS
The difference is that you show they are linked to the X chromosome, you put the symbols as a superscript on the X:

21. SYMBOLS
The difference is that you show they are linked to the X chromosome, you put the symbols as a superscript on the X:
XN = normal color vision (dominant) on the X
Xn = colorblindness (recessive) on the X

22. SYMBOLS
The difference is that you show they are linked to the X chromosome, you put the symbols as a superscript on the X:
XN = normal color vision (dominant) on the X
Xn = colorblindness (recessive) on the X
XH = hair (dominant) on the X
Xh = baldness (recessive) on the X

23. SYMBOLS
The difference is that you show they are linked to the X chromosome, you put the symbols as a superscript on the X:
XN = normal color vision (dominant) on the X
Xn = colorblindness (recessive) on the X
XH = hair (dominant) on the X
Xh = baldness (recessive) on the X
XB = blood clotting (dominant) on the X
Xb = hemophilia (recessive) on the X

24. GENOTYPES AND PHENOTYPES
Since women have a genotype of XX, sex-linked traits for them behave normally:

25. GENOTYPES AND PHENOTYPES
Since women have a genotype of XX, sex-linked traits for them behave normally:
the only way for a woman to express a recessive trait on her X chromosome is if she is purebred / homozygous for it.

26. GENOTYPES AND PHENOTYPES
Since women have a genotype of XX, sex-linked traits for them behave normally:
the only way for a woman to express a recessive trait on her X chromosome is if she is purebred / homozygous for it.
XNXN or XNXn = normal vision
XnXn = colorblindness

27. GENOTYPES AND PHENOTYPES
Since women have a genotype of XX, sex-linked traits for them behave normally:
the only way for a woman to express a recessive trait on her X chromosome is if she is purebred / homozygous for it.
XNXN or XNXn = normal vision
XnXn = colorblindness
* A girl gets an allele from each parent on the X chromosome.

28. GENOTYPES AND PHENOTYPES
Since men have a genotype of XY, sex-linked traits for them behave differently:

29. GENOTYPES AND PHENOTYPES
Since men have a genotype of XY, sex-linked traits for them behave differently:
the trait is only on the X not on the Y. Therefore, whatever he receives from his mom is going to be expressed. There is no matching allele on the Y chromosome from his dad.

30. GENOTYPES AND PHENOTYPES
Since men have a genotype of XY, sex-linked traits for them behave differently:
the trait is only on the X not on the Y. Therefore, whatever he receives from his mom is going to be expressed. There is no matching allele on the Y chromosome from his dad.
XNY = normal vision
XnY = colorblindness

31. GENOTYPES AND PHENOTYPES
Since men have a genotype of XY, sex-linked traits for them behave differently:
the trait is only on the X not on the Y. Therefore, whatever he receives from his mom is going to be expresses. There is no matching gene on the Y chromosome from his dad.
XNY = normal vision
XnY = colorblindness
A boy gets only 1 allele in a sex-linked trait and it’s from his mom on the X chromosome.

32. Test your knowledge (and your family tree)
Most types of baldness are sex-linked traits.

33. Test your knowledge (and your family tree)
Most types of baldness are sex-linked traits.
If “hair” is dominant and baldness is recessive, what would a male’s genotype be if he had hair?

34. Test your knowledge (and your family tree)
Most types of baldness are sex-linked traits.
If “hair” is dominant and baldness is recessive, what would a male’s genotype be if he had hair? XHY

35. Test your knowledge (and your family tree)
Most types of baldness are sex-linked traits.
If “hair” is dominant and baldness is recessive, what would a male’s genotype be if he had hair? XHY
What would a bald male’s genotype be?

36. Test your knowledge (and your family tree)
Most types of baldness are sex-linked traits.
If “hair” is dominant and baldness is recessive, what would a male’s genotype be if he had hair? XHY
What would a bald male’s genotype be? XhY

37. Test your knowledge (and your family tree)
Most types of baldness are sex-linked traits.
If “hair” is dominant and baldness is recessive, what would a male’s genotype be if he had hair? XHY
What would a bald male’s genotype be? XhY
Question: If a boy’s father is bald, does the boy have to worry about going bald when he is older?

38. Test your knowledge (and your family tree)
Most types of baldness are sex-linked traits.
If “hair” is dominant and baldness is recessive, what would a male’s genotype be if he had hair? XHY
What would a bald male’s genotype be? XhY
Question: If a boy’s father is bald, does the boy have to worry about going bald when he is older?
NO! He is a boy because he received a Y from his dad that does not carry that trait!

39. A boy can only get a sex-linked trait from his mother.

40. A boy can only get a sex-linked trait from his mother.
Therefore, if he is wondering if he’ll go bald when he’s older, he needs to look at the males on his mother’s side of the family.
A bald uncle or grandfather on Mom’s side of the family means there is a good chance the boy will go bald when he gets older.
A bald uncle or grandfather on Dad’s side of the family is nothing to worry about for the boy!

41. Use your notes to help you with the symbols and genotypes/phenotypes.
Now it’s time to write your summaries – there’s one on both sides of your paper.
When you’re done, do your practice problems –
Use your notes to help you with the symbols and genotypes/phenotypes.
THE END