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Human Genetics

Human Genetics. How many pairs of chromosomes are in each of our body cells?. 32 23 46 16. 23 pairs! This is 46 total; we get 23 from mom & 23 from dad. Body cells are also known as what?. Gametes Histones Chromatin Somatic Cells. Somatic Cells!.

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Human Genetics

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  1. Human Genetics

  2. How many pairs of chromosomes are in each of our body cells? • 32 • 23 • 46 • 16 23 pairs! This is 46 total; we get 23 from mom & 23 from dad.

  3. Body cells are also known as what? • Gametes • Histones • Chromatin • Somatic Cells Somatic Cells!

  4. Which cells in our bodies do NOT have all 46 chromosomes? • Gametes • Histones • Chromatin • Somatic Cells Gametes! Gametes are also known as sex cells. THESE ARE SPERM & EGG CELLS!

  5. How many chromosomes do human sperm or egg cells contain? • 32 • 23 • 46 • 16 23! They do NOT get 2 copies of each chromosome; they just get 1!

  6. Gametes – Sperm & Egg Cells • All gametes are haploid. • In humans, that means each egg cell & each sperm cell has 1 copy of each chromosome (23 total chromosomes). • Egg Cells: all human egg cells carry 23 chromosomes, 1 of which is a single X chromosome • Sperm Cells: in males, there are 2 types of sperm cells – 1 carries an X chromosome & 1 carries a Y chromosome

  7. The 2 Types of Chromosomes • Autosomes: non-sex chromosomes • Of the 46 chromosomes, 44 of them (22 pairs) are autosomes. • Sex Chromosomes: the last 2 chromosomes; they determine the sex of the person • Females have 2 X chromosomes (XX). • Males have 1 X and 1 Y chromosome (XY). Is this person male or female?

  8. When a sperm & egg cell combine, half the time the fertilized eggs (zygotes) are female & half of the time they’re male.

  9. Karyotypes – what’s that?

  10. Karyotypes • Scientists can analyze an individual’s chromosomes by taking a picture of cells during mitosis. Why does this need to be done during mitosis? • It’s easiest to view chromosomes during mitosis, because they are condensed!

  11. Karyotypes • From a picture of chromosomes, scientists can cut & paste to arrange the chromosomes in pairs to form a karyotype. The last pair (#23) is the sex chromosomes.

  12. A. Man B. Woman Woman! There are 2 X chromosomes, but no Y chromosome!

  13. A. Man B. Woman Man! It’s not labeled, but you can see that 1 of the sex chromosomes is much smaller than the other (the X & the Y).

  14. Why is karyotyping important?

  15. Using Karyotypes • Genetic disorders can be identified by looking at an individual’s karyotype. Down Syndrome can be confirmed even before the baby is born!

  16. Human Chromosome Disorders How often do they occur? • Relatively high frequency in humans, but most embryos are spontaneously aborted • Developmental problems result from biochemical imbalances. About 60% of first trimester miscarriages are due to chromosome disorders. Between 5-10% of stillborn deliveries are due to chromosome disorders.

  17. Human Chromosome Disorders • Some conditions are survivable. How do chromosome disorders occur?

  18. Chromosome Abnormalities • Incorrect number of chromosomes/mutations within the chromosome • Nondisjunction: chromosomes don’t separate properly during meiosis • Chromosome Mutations: deletion, inversion, duplication, translocation

  19. Remember! • During meiosis, a diploid cell (2 copies of each chromosome) divides & produces 4 haploid gametes (sperm or egg). • Gametes only have 1 copy of each chromosome!

  20. Nondisjunction • Sometimes, chromosomes may not separate properly during meiosis; this is called nondisjunction. • If nondisjunction occurs, abnormal numbers of chromosomes (1 extra or 1 missing) are found in gametes & chromosomal disorders may result.

  21. Nondisjunction • Homologous chromosomes don’t separate properly during Meiosis 1. OR • Sister chromatids fail to separate during Meiosis 2.

  22. Nondisjunction • Trisomy: cells have 3 copies of a chromosome • In trisomies, the gamete of one parent donated 2 of one type of chromosome to the child & the gamete of the other parent donated 1 (like normal).

  23. Nondisjunction • Monosomy: missing 1 chromosome • In monosomies, the gamete of one parent donated 1 chromosome & the other parent did not donate any.

  24. Down Syndrome • Trisomy 21 • Every 1 in 700 children born in the US have Trisomy 21. Chromosome 21 is the smallest, but an abnormality still has severe effects.

  25. Down Syndrome vs. Age of Mother Women are born with all the egg cells they’ll ever have. So, a 35 year old woman has 35 year old egg cells.

  26. Other Examples of Disorders caused by Nondisjunction • Klinefelter’s Syndrome – XXY (male) • Turner’s Syndrome – XO (female) As long as there’s at least 1 Y chromosome, the karyotype is male!

  27. Klinefelter’s Syndrome • XXY • 1/2000 live births • Have male sex organs, but are sterile • Feminine characteristics • Some breast development • Lack of facial hair • Tall • Normal intelligence

  28. Turner’s Syndrome • XO (1 X chromosome) • 1/5000 births • Varied degrees of effects • Webbed neck • Short stature • Sterile

  29. Jacob’s Syndrome • XYY • 1/1000 live births • Extra Y chromosome • Slightly taller than average • More active • Normal intelligence, slight learning disabilities • Delayed emotional maturity • Normal sexual development Some men will never know they have Jacob’s Syndrome!

  30. Trisomy X • XXX • 1/2000 live births • Produces healthy females! • All but 1 X chromosome are inactivated. Most mammals leave only 1 X chromosome activated in their cells. The inactivated chromosome(s) are called barr bodies!

  31. Remember! Chromosomal Mutations • Error in replication: • Deletion: loss of a chromosomal segment • Duplication: repeat a segment • Error in crossing over: • Inversion: reverses a segment • Translocation: move segment from 1 chromosome to another

  32. How do we know if a growing embryo has a chromosome abnormality? Genetic Testing! • Amniocentesis: a syringe takes a sample of the embryo cells, then stains & photographs the chromosomes • Analysis of the karyotype

  33. The Human Genome Project • The genome of many organisms has been determined, including the human genome! • Now, we are analyzing the code, finding genes coding for different traits, & discovering ways to isolate them & manipulate them. • In gene therapy, an absent gene or faulty gene is replaced by a normal, working gene! Video – Blind Dog Gene Therapy

  34. Pedigrees – what are those?

  35. Pedigrees • Similar to a family tree; both are used to show relationships in a family • Used to demonstrate how traits are passed from 1 generation to another • Genetic counselors use pedigrees to follow how genetic disorders are inherited.

  36. Pedigrees • People who are heterozygous for a recessive genetic disorder (they are unaffected) are called carriers. • Sometimes, carriers of traits may be represented as a half-shaded shape or a shape with a dot in the middle.

  37. Pedigree Symbols • Square: male • Circle: female • Shaded: affected individual • Open: unaffected • Horizontal Line: marriage • Vertical Line & Bracket: descendants of a marriage

  38. female male children parents marriage

  39. Most genetic disorders are caused by mutations on autosomes (non-sex chromosomes). • Autosomal Recessive Disorders: albinism, cystic fibrosis, tay-sachs disease • Autosomal Dominant Disorders: achondroplasia (common form of dwarfism) • CodominantDisorders

  40. Could this trait be inherited as a simple autosomal recessive? • Could this trait be inherited as a simple autosomal dominant? • Could this trait be inherited as a simple X-linked recessive? • Could this trait be inherited as a simple X-linked dominant? • Could this trait be inherited as a simple Y-linked trait?

  41. Could this trait be inherited as a simple autosomal recessive? • Could this trait be inherited as a simple autosomal dominant? • Could this trait be inherited as a simple X-linked recessive? • Could this trait be inherited as a simple X-linked dominant? • Could this trait be inherited as a simple Y-linked trait?

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