COMPLEX PATTERNS OF INHERITANCE Simple Dominant Traits Simple

COMPLEX PATTERNS OF INHERITANCE

Simple Dominant Traits • Simple dominant traits need only 1 allele in order to express phenotype – RR or Rr • Examples: Huntington’s disease • Cleft chin, widow’s peak

Simple Dominant Traits 1 homozygous dominant 2 heterozygous 1 homozygous recessive R r R RR Rr rr

Huntington’s Disease • Huntington's disease is an inherited disease that causes the progressive breakdown of nerve cells in the brain. Huntington's disease has a broad impact on a person's functional abilities and usually results in movement, thinking (cognitive) and psychiatric disorders.

Simple Recessive Disorders • Recessive Disorders affect offspring with 2 recessive alleles – (homozygous recessive) • Most genetic disorders are caused by recessive alleles

Recessive Disorders • Cystic Fibrosis – 1 in 28 white Americans carry recessive allele – Defective PROTEIN in plasma membrane – Accumulate mucus in lungs and digestive tract

Recessive Disorders • Tay-Sachs – Absence of ENZYME that breaks down LIPIDS –Lipids accumulate in cells

Recessive Disorders • Phenylketonuria (PKU) –Absence of ENZYME to convert phenylalanine to tyrosine –Phenylalanine cannot be broken down –Accumulates in cells –Damages CNS –Mental retardation

COMPLEX PATTERNS OF INHERITANCE

INCOMPLETE DOMINANCE

INCOMPLETE DOMINANCE • Incomplete dominance occurs when one allele is not completely dominant over another allele • Results in heterozygote being phenotypically expressed as a mix • A third phenotype appears

Snapdragon plant RED PINK RR R R´ WHITE R’ R´

INCOMPLETE DOMINANCE • Flowers contain enzymes that control pigment production • The R allele makes red pigment • W defective enzyme that makes no pigment

INCOMPLETE DOMINANCE • RR plenty red pigment = red • RW has one R allele and can produce half the amount of red pigment = pink • WW can produce no pigment = white

INCOMPLETE DOMINANCE • A red carnation is crossed with a white carnation 1. Write the genotypes of the two parent carnations. 2. Use a Punnett square to determine the percentage of the offspring expected to be pink.

INCOMPLETE DOMINANCE Parents = RR x WW R R W RW RW 100% are expected to be pink!

CODOMINANCE

CODOMINANCE • Heterozygote has both alleles • Use BOTH uppercase letters • Both alleles show equally • What would happen if you bred… x White hen Black rooster

CODOMINANCE Black rooster White hen BB WW Black & White Chicken BW

Black rooster WW BB BW

Sickle Cell Anemia • Sickle Cell Anemia is a genetic disorder found in African Americans • Hemoglobin is the protein in red blood cells that carries oxygen. The normal allele for the gene differs by only one DNA base (what mutation? ) • Results in abnormal hemoglobin that is less soluble in blood, and decreases oxygen levels • Decreased oxygen levels lead to sickle shaped cells that stick together

SICKLE-CELL ANEMIA • (CODOMINANCE) • Hemoglobin, the oxygen-carrying protein, differs by one amino acid, which changes shape of red blood cell • Abnormal shape slows blood flow and blocks small vessels

SICKLE-CELL ANEMIA • Sickled cells have shorter life span anemia (low # of red blood cells) Sickled cells get stuck in blood vessels, preventing blood flow that causes pain, fever, swelling, and tissue damage that can lead to

SICKLE-CELL ANEMIA • Individual who are heterozygous for the allele produce both normal and sickled red blood cells (codominance) • Able to produce enough hemoglobin to have no serious health problems • “have the sickle-cell trait” NN NS SS

SICKLE-CELL ANEMIA • A boy is born with sickle-cell anemia. Neither parent has the disease. 1. Write the boy’s genotype for this disease. 2. Use a Punnett square to determine the genotypes of both parents.

SICKLE-CELL ANEMIA Boy’s genotype = SS Parents’ genotypes = N? x N? N ? N NN N__ ? N__ SS Parents’ genotypes = NS x NS

SICKLE-CELL ANEMIA Why is the sickle cell anemia mutation so common among African Americans? Most carriers can trace their ancestry to west Africa, an area afflicted with malaria.

Why does the sickle cell allele persist? (must be some advantage) Carriers (with one sickle gene and one normal hemoglobin gene) have some protective advantage against malaria The frequencies of sickle cell carriers are high where malaria is prevalent (as great as 40%!)

People who have sickle cell anemia are less likely to die from malaria. The parasite is carried by the Anopheles mosquito. Cells that sickle make a poor home for this parasite. The body can eliminate it before the parasite spreads too widely, before the person gets seriously ill.

Sickle Cell Anemia • In this case, scientists believe that sickle cell carriers have been NATURALLY SELECTED because their trait has some resistance to malaria. • Evolutionary trade off because if both parents are carriers of sickle cell anemia, then they have a 50% chance of their offspring being carriers, 25% of having sickle cell, and 25% of having no trait for sickle cell, and therefore no advantage against malaria.

Sickle Cell Anemia • Scientists now know that sickle cell is an example of CODOMINANCE, because three phenotypes are possible: • 1 – normal hemoglobin • 2 – sickle cell anemia • 3 – carrier of sickle cell disease; advantage against malaria; when infected with parasite, their red blood cells sickle and are filtered out, along with the parasite, by the spleen

POLYGENIC INHERITANCE

POLYGENIC TRAITS • Trait is controlled by more than one gene • EX: skin color controlled by more than four different genes • Different combinations of alleles for these genes produce a range of phenotypes. • All heterozygotes are intermediate phenotype

POLYGENIC INHERITANCE • Eye color • height, weight • intelligence in people

Quick Check 1. In what type of inheritance does the heterozygote show BOTH alleles? 2. What type of inheritance is sickle cell anemia? 3. What is the advantage of having the sickle trait? 4. What type of inheritance can produce a pink flower from a cross between red and white flower? 5. What controls flower pigment? 6. What type of molecule is hemoglobin? 7. Polygenic inheritance produces a __ of phenotypes.