Mendelian Genetics

Inherited traits Mendelian Genetics

Gregor Mendel Mendel’s Legacy • The “Father” of genetics. • Studied inherited traits in pea plants • Discovered dominant and recessive traits and was able to predict what pea offspring would look like!

Mendel’s Ideas A Mendelian Genetic Primer • Genes come in pairs that separate in the formation of gametes, or sex cells. • The members of the pair may be identical (homozygous) or non-identical (heterozygous). • Each form of a particular gene is called an allele • For simplification, only two alleles of a given gene are possible in an individual although many alleles of a gene are possible within a population. • One allele is dominant over another (or so Mendel believed). .

Mendel’s Ideas A Mendelian Genetic Primer .

Mendel’s Ideas A Mendelian Genetic Primer • Genotype: What alleles the organism has. • Phenotype: How the alleles are expressed. Often, this means what the organism looks like. • Why is this not always the case? .

Genes, Alleles, and Chromosomes

Response Cards • Hold up one or more of the three response cards to answer the following prompts…

Response Cards • Homozygous

Response Cards • Heterozygous

Response Cards • Homozygous Recessive

Response Cards • One dominant allele and one recessive allele

Response Cards • Homozygous Dominant

Response Cards • Homozygous Recessive

Response Cards • Homozygous Dominant

Response Cards • A species of rabbit can have either brown fur, or white fur (there is no in-between). The brown fur allele is dominant, and the white fur allele is recessive. What genotype(s) can a rabbit with brown fur have?

Response Cards • A species of rabbit can have either brown fur, or white fur (there is no in-between). The brown fur allele is dominant, and the white fur allele is recessive. What genotype(s) can a rabbit with white fur have?

Different Genotypes Can Produce the Same Phenotype

Response Cards • Two rabbits are brown and each have one copy of the gene for brown fur and one of the gene for white fur. • What are their genotypes?

Punnett Squares • Two rabbits are brown and each have one copy of the gene for brown fur and one of the gene for white fur. • What are the chances that one of their offspring will have white fur?

Punnett Square • We combine the father’s genotype with the mother’s genotype. • It doesn’t matter which parent goes on which part of the square.

Punnett Square • The four squares represent the 4 possible offspring these parent can have with regard to this one gene. • Now lets fill in the squares to see what offspring are possible.

Use your response cards! • What is the genotype of offspring #1? 1 2 3 4

Use your response cards! 2 3 4

Use your response cards! • What is the genotype of offspring #2? 2 3 4

Use your response cards! 3 4

Use your response cards! • What is the genotype of offspring #3? 3 4

Use your response cards! 4

Use your response cards! • What is the genotype of offspring #4? 4

Use your response cards!

Use your response cards! • Now we see the 4 possible offspring for this mating. • These offspring have 3 different genotypes. • BUT there are only 2 phenotypes! • What are they?

Use your response cards! • 3 offspring out of the 4 have brown fur. Hold up the cards that represent the genotype(s) that make brown rabbits. • BB and Bb • ¾ rabbits = 75% of offspring • If the parents have 40 offspring, how many would probably be brown?

Use your response cards! • 1 offspring out of the 4 has whit fur. Hold up the cards that represent the genotype(s) that make white rabbits. • bb • 1/4 rabbits = 25% of offspring • If the parents have 40 offspring, how many would probably be white?

Use your response cards! • So two brown rabbits produced some offspring that are white! • What is the genotype for white rabbits?

Punnett Squares • Some rabbits may be brown, but carry a copy of the white gene. The white gene doesn’t show up because it is recessive. What is the genotype of these rabbits? • We call organisms like these carriers of an allele, because they do not show the phenotype, but they carry the allele in their genotype. • These rabbits were not white their offspring may be.

Response Cards • A brown rabbit has two copies of the gene for brown fur. • What is its genotype? • There is also a white rabbit. • What is its genotype? • The two rabbits mate, what is the genotype of 100% of their offspring? • Draw a punnett square • Hold up your answer • What color are the offspring rabbits?

Response Cards • A brown rabbit has one copy of the gene for brown fur and one of the gene for white fur. • What is its genotype? • There is also a white rabbit. • What is its genotype? • The two rabbits mate, what are the two possible genotypes of their offspring? • Draw a punnett square • Hold up your answer • What color are the offspring rabbits?

Punnett Squares • What percent of the offspring are heterozygous? • 50% • Hold up the card that represents these rabbits. • What color would these rabbits be? • What percent of the offspring are homozygous for the recessive allele? • 50% • Hold up the card that represents these rabbits. • What color would these rabbits be?

Human Genetics What Works for Peas Also Works for Humans • In the cross Bb x Bb, where B is a dominant allele for standard pigmentation and b is a recessive allele for no pigmentation (albinism). • Are the parents albino? • No, because the standard pigementation allele (B) is dominant. So it is the one the shows up! An albino woman

Human Genetics What Works for Peas Also Works for Humans • In the cross Bb x Bb, where B is a dominant allele for standard pigmentation and b is a recessive allele for no pigmentation (albinism). • Are the parents heterozygous or homozygous? • Heterozygous (Bb) • Why do we call the parents carriers of the albinism gene? An albino woman

Human Genetics What Works for Peas Also Works for Humans • In the cross Bb x Bb, where B is a dominant allele for standard pigmentation and b is a recessive allele for no pigmentation (albinism). • What genotype does a person need to have to look albino? • Homozygous recessive (bb) An albino woman

Human Genetics What Works for Peas Also Works for Humans • In the cross Bb x Bb, where B is a dominant allele for standard pigmentation and b is a recessive allele for no pigmentation (albinism) • Draw a punnett square for this cross, to see what their children would look like. An albino woman

Use your response cards! • Now we see the 4 possible offspring for this mating. • These offspring have 3 different genotypes. • BUT there are only 2 phenotypes! • What are they?

Human Genetics What Works for Peas Also Works for Humans • In the cross Bb x Bb, where B is a dominant allele for standard pigmentation and b is a recessive allele for no pigmentation (albinism) • What fraction of the offspring will be albino? • ¼ will be albino. • Hold up the card that represents a person with albinism. An albino woman

Human Genetics What Works for Peas Also Works for Humans • In the cross Bb x Bb, where B is a dominant allele for standard pigmentation and b is a recessive allele for no pigmentation (albinism) • What fraction of the offspring will look normal? • ¾ of offspring will be normal. • Hold up the card(s) that represent(s) a person that has standard skin pigmentation. An albino woman

Human Genetics What Works for Peas Also Works for Humans • In the cross Bb x Bb, where B is a dominant allele for standard pigmentation and b is a recessive allele for no pigmentation (albinism) • What fraction of the offspring will be carriers? • Hold up the card that represents a carrier. An albino woman

Human Genetics What Works for Peas Also Works for Humans • In the cross Bb x Bb, where B is a dominant allele for standard pigmentation and b is a recessive allele for no pigmentation (albinism) • Hold up the card that represents a homozygous dominant genotype. • What fraction of the offspring will homozygous dominant? An albino woman

Mendelian Genetics