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Transcript
1
Chapter 11: Patterns of Heredity and Human Genetics
Pedigree
 Diagram that shows how one trait is passed on through a
family
 Each horizontal row with a Roman numeral is a generation
 Has symbols to represent people in the generations
Carriers:
Heterozygous for recessive allele
2
I
I: 2 carriers
II
II: 3 carriers
III
III: 1 affected male
3
Recessive disorders
 Genetic disorders caused by a recessive allele
 Only shows up in people that are homozygous recessive
 Cystic fibrosis: thick mucus builds up in lungs and digestive
system due to a defective protein in the cell membrane
 Tay-Sachs disease: certain lipid cannot be broken down and
builds up in the central nervous system
 Phenylketonuria: phenylalanine amino acid cannot be broken
down and builds up in the central nervous system
Dominant disorders
 Genetic disorders caused by a dominant allele
 Shows up in people that are homozygous dominant or
heterozygous
 Huntington’s disease: certain parts of the brain break
down.
 Symptoms arise around 20-30 years old
Incomplete dominance
 the traits carried by two dominant genes are blended
together in the organism
 Example: red flower (RR) x white flower (WW)
= pink flower (RW) offspring
 All letters are capital because all the genes are dominant
Codominance
 The traits carried by two dominant genes appear in
different locations in the organism
 Example: black chicken (BB) x white chicken (WW)
= spotted black and white chicken (BW)
 All letters are capital because all the genes are dominant.
4
 Sickle cell anemia: Hemoglobin protein, which carries
oxygen in the blood, is mutated which causes red blood
cells, which are normally round, to be shaped like bananas
o Serious, very painful illness. Helps fight Malaria
o Sickle cell anemia shows codominance between the sickle
gene (S) and the normal hemoglobin gene (N)
 NN: healthy individual with all normal hemoglobin
 NS: carrier, mostly healthy because half the
hemoglobin is normal and half the hemoglobin is sickled
 SS: individual has sickle cell anemia with all sickled
hemoglobin
Multiple alleles
 More than 2 alleles exist for a trait
 However, an organism can only have 2 of these alleles for a
trait
 Example: alleles for hair color are blond, brown, red
 Blood type is controlled by multiple alleles (A, B, and O)
o O is recessive, A and B are codominant
o Genotype
Phenotype
AA, AO
Type A blood
BB, BO
Type B blood
OO
Type O blood
AB
Type AB blood (A and B are codominant)
5
Sex determination
 Humans have 46 chromosomes
o 44 of these chromosomes are autosomes (do not
determine the sex of an organism)
o 2 of these chromosomes are sex chromosomes
(determine the sex of an organism)
 Sex chromosomes are X and Y
 Females are XX, Males are XY
 Females can only make eggs with the X chromosome
 Males make sperm with the X or Y chromosome, so it is the
males that determine the sex of a baby
Sex-linked traits
 Traits controlled by genes on the sex chromosomes
 Example: Hemophilia (h) is a recessive disorder in which
you cannot clot your blood. Normal blood clotting (H) is
dominant. These genes are located on the X chromosome.
o For sex-linked traits, you must write genotypes like:
h h
 X X : female with hemophilia
H h
 X X : female carrier
h
 X Y : male with hemophilia
H
 X Y : normal male without hemophilia
 Example: Red-green color blindness: an individual cannot
tell the difference between red and green
 Sex-linked traits occur moreso in males than females
because
o Males only need one “bad” gene on the X chromosome
o But females need two “bad” genes on both X
chromosomes
6
Polygenic trait
 Trait that is controlled by many different genes
 Example: height and skin color for humans is a polygenic trait
Abnormal numbers of chromosomes
Having an extra chromosome is called a Trisomy
Having one less chromosome is called a monosomy.
 Karyotype: picture of an individual’s chromosomes
o Will show if the person has extra or missing chromosomes
o Extra or missing chromosomes : caused by mistakes in
meiosis leading to the wrong number of chromosomes in
an egg or sperm cell (due to nondisjunction which means
fails to separate during gamete formation.)
 Down syndrome: three of chromosome-21, which causes
mental retardation, short stature and digits, extra skin
over eye lids.
 Individuals can have the wrong number of sex chromosomes
o XO (turners syndrome), XXX: female (no Y chromosome)
o XXY (klinefelters syndrome), XYY: male (at least one Y
chromosome)
Healthy individual
Individual with Down syndrome
7
Klinefelter’s syndrome
XXY individual