THE CHROMOSOMAL BASIS OF INHERITANCE

CHAPTER 15

Warm up1.What is the probability of the following?

a.) Aabb X AaBb -> Aabbb.) AaBB X AaBb -> aaBBc.) AABbcc X aabbCC -> AaBbCcd.) AaBbCc X AaBbcc -> aabbcc

2. Explain what a linkage map is and a map unit.

3. Map the following gene. (pg 281 7th ed.)• J-k 12% k-L 6%• J-m 9% L-m 15%

1. What is the pattern of inheritance of the trait (shaded square/circle) shown in the pedigree?

1. How many chromosomes are in a human cell that is:a) Diploid? b) Triploid?c) Monosomic? d) Trisomic?

Warm-Up

What you must know:• How the chromosome theory of inheritance

connects the physical movement of chromosomes in meiosis to Mendel’s laws of inheritance.

• The unique pattern of inheritance in sex-linked genes.

• How alteration of chromosome number or structurally altered chromosomes (deletions, duplications, etc.) can cause genetic disorders.

• How genetic imprinting and inheritance of mitochondrial DNA are exceptions to standard Mendelian inheritance.

Chromosome theory of inheritance:

• Genes have specific locations (loci) on chromosomes

• Chromosomes segregate and assort independently

Chromosomes tagged to reveal a specific gene (yellow).

Thomas Hunt Morgan

• Drosophila melanogaster – fruit fly– Fast breeding, 4 prs. chromosomes (XX/XY)

• Sex-linked gene: located on X or Y chromosome– Red-eyes = wild-type; white-eyes = mutant– Specific gene carried on specific chromosome

Sex determination varies between

animals

Sex-linked genes

• Sex-linked gene on X or Y• Females (XX), male (XY)

– Eggs = X, sperm = X or Y• Fathers pass X-linked genes to daughters, but not

sons• Males express recessive trait on the only X

(hemizygous)• Females can be affected or carrier

Transmission of sex-linked recessive traits

Sperm

Ova

Sperm

Ova

Sperm

Ova

Sex-linked disorders

• Colorblindness• Duchenne muscular dystrophy• Hemophilia

X-InactivationX-InactivationBarr body = inactive X chromosome; regulate gene dosage in females during embryonic development

Because of this only female cats can be tortoiseshell or calico.

Human development• Y chromosome required for development of testes• Embryo gonads indifferent at 2 months• SRY gene: sex-determining region of Y• Codes for protein that regulates other genes

Linked genes: located on same chromosome and tend to be inherited together during cell division

Genetic Recombination: production of offspring with new combo of genes from parents

• Unlinked genes: follow law of independent assortment– 50% frequency of recombination observed

for any 2 genes on different chromosomes

Crossing over: explains why some linked genes get separated during meiosis

• the furtherfurther apart 2 genes on same chromosome, the higher higher the probability of crossing over and the higherhigher the recombination frequency

Geneticists can use recombination data to map a chromosome's genetic loci

Linkage Map: genetic map that is based on % of cross-over events

• 1 map unit = 1% recombination frequency• Express relative distances along chromosome• 50% = far apart on same chromosome or on different

chromosomes

NondisjunctionNondisjunction: chromosomes fail to separate properly in Meiosis I or Meiosis II

• Aneuploidy: incorrect # chromosomes– Monosomy (1x) or Trisomy (3x)

• Polyploidy: 2+ complete sets of chromosomes; 3n or 4n– Rare in animals, frequent in plants

A tetraploid mammal. Scientists think this species may have arisen when an ancestor doubled its chromosome # by errors in mitosis or meiosis.

Nondisjunction

The structure of an individual chromosome can be altered during DNA replication

Karyotyping can detect nondisjunctions.

Down Syndrome = Trisomy 21

Karyotyping can detect nondisjunctions.

Klinefelters Syndrome: 47XYY, 47XXY

Karyotyping can detect nondisjunctions.

Turners Syndrome = 45XO

Extranuclear GenesExtranuclear Genes• Some genes located in

organelles– Mitochondria, chloroplasts,

plastids– Contain small circular DNA– Do not display Mendelian

inheritance• Mitochondria = maternal

inheritance (eggs)

Variegated (striped or spotted) leaves result from mutations in pigment genes in plastids, which generally are inherited from

the maternal parent.