Heredity Part 1: Genetics Biology 10.1

Gregor Mendel 1800’s Austrian (NOT AUSTRALIAN) monk, mathematician, and scientist Began working in the garden at his monastery Father of Genetics His work led to an understanding of how traits are passed from parents to offspring The passing of traits from parents to offspring is called heredity Primarily worked with a variety of garden peas Noticed several traits that appeared to follow certain patterns of inheritance.

Mendel’s Pea Plant Traits

Mendel’s Observations Mendel mated pea plants together until he got plants that were true- breeding Also known as pure-bred Organisms that always pass on a certain trait Ex. Purple plant that always has purple offspring Once he had established 2 true-breeding lines for each trait, he mated them together For example, true-breeding yellow seed and true-breeding green seeds. He noticed that all of the offspring looked like one of the parents, but not the other (Ex. All yellow, no green) Called them hybrids because they got one gene from each parent

Generations in Crosses P=Parental generation First ones to be crossed F1=1st Filial generation Filial=children F2=2nd Filial generation Grandchildren

Mendel’s Observations continued He then self-pollinated each of the offspring He noticed that most looked like the parent, but some did not

Mendel’s Hypotheses He hypothesized that one of the traits was overpowering the other He called these traits dominant Because the other trait was not expressed in the first generation, but reappeared in the second, he hypothesized that the trait was still there, but was being overpowered by the dominant trait He called these traits recessive

Example of Mendel’s Experiment-Yellow and Green seeds Mendel developed a true-breeding line of plants with yellow seeds and a true-breeding line of plants with green seeds. He took one yellow-seeded plant and one green-seeded plant and mated them together. All of the offspring had yellow seeds He then took each of these yellow-seeded plants, and self- pollinated them ¾ of the offspring had yellow seeds and ¼ of them had green seeds. He concluded that Yellow was dominant and green was recessive

Results of Mendel’s Experiment Mendel’s experiments continually showed that ¾ of the plants showed the dominant trait, and ¼ showed the recessive trait 3:1 ratio

Mendel’s Laws of Inheritance Law of Segregation For any particular trait, the pair of alleles from each parent separate and only one allele passes from each parent to an offspring Recall that we have 23 pairs of chromosomes (one set from mom and one set from dad) During meiosis, one of these are sorted into each gamete (sex cell) Which one winds up in each is random. Law of Independent Assortment Different pairs of alleles for one trait are passed to offspring independently of alleles for other traits Most traits are not linked in any way. You could get your mom’s blue eyes without getting her blonde hair, height, etc.

Mendel’s Principle of Dominance Alleles can be dominant or recessive Dominant alleles mask, or cover up, recessive alleles Recessive alleles can only be expressed if the offspring receives 2 of the recessive alleles Any time a dominant allele is present, it will be expressed

Symbols for alleles Dominant alleles are represented by capital letters Example: A, B, C, D Recessive alleles are represented by lowercase letters Example: a, b, c, d The gene is represented by a single letter, and dominant and recessive alleles of the gene are shown by whether they are capital or lowercase

You try it: Indicate whether the following are dominant or recessive P E e

You try it: Indicate whether the following are dominant or recessive T-dominant d-recessive P-dominant E-dominant e-recessive

Homozygous vs Heterozygous Recall that organisms get 2 alleles-1 from each parent Homozygous-2 of the same alleles for a trait “Homo” means same Example: TT or tt Can be homozygous dominant (TT) or homozygous recessive (tt) Heterozygous- 2 different alleles for a trait “Hetero” means different Example: Tt or tT Note: The latter is rarely used, but will sometimes be the result in a Punnett Square

You Try It: Indicate whether the following are heterozygous, homozygous dominant, or homozygous recessive. TT Tt tT tt

You Try It: Indicate whether the following are heterozygous, homozygous dominant, or homozygous recessive. TT-homozygous dominant Tt-heterozygous tT-heterozygous Tt-homozygous recessive

Punnett Squares Tool to predict results of a cross (mating) Usually a 2x2 grid Can be larger if including more traits Couple different types Monohybrid cross (one trait) Dihybrid cross (2 traits) Trihybrid cross (3 traits)-Gets too time consuming for this class And more that are too complicated to be done by hand and are instead done using computers

Punnett Squares Show Probability Not actuality Coin flip If you flip a coin, what is the chance that it comes up heads? 50% If you flip it again, what is the chance it will come up heads a second time? And so on If there is a 1 in 4 chance that your offspring will have blue eyes, and you have 3 children with brown eyes, will the 4th for certain have blue eyes?

Using Punnett Squares Draw example Begin by drawing a 2x2 grid Place one parent’s alleles on top Place the other parent’s alleles on the left side Bring ones on the top down Bring one on the left across A A a A a A a a A a A a

Practice Problem A pea plant with genotype Rr is mated with a pea plant with genotype rr. What genotypes could the offspring have?

R r r R r r r r R r r r Practice Problem Begin by drawing a 2x2 grid Place one parent’s alleles on top Place the other parent’s alleles on the left side Bring ones on the top down Bring one on the left across R r r R r r r r R r r r

Genotype and Phenotype Genotype-The genes (alleles) that an organism has Geno=Gene Example: Aa, BB, cc Phenotype-The expression (appearance) of the genotype Ph-Physical Example: Green eyes, brown hair, tall

You try it: Indicate whether the following are genotypes or phenotypes. Aa Blue eyes Rolling tongue TT

You try it: Indicate whether the following are genotypes or phenotypes. Aa-genotype Blue eyes-phenotype Rolling tongue-phenotype TT-genotype

Principles of heredity Traits are controlled by alleles (different versions of a gene) on a chromosome An allele can be dominant or recessive When a pair of chromosomes separate during meiosis, the different alleles for a trait move into different gametes

Practice Problem #1 A person with brown eyes (BB) has a child with a person with blue eyes (bb). What is the chance that the child will have blue eyes?

Practice problem #2 2 people with brown hair (BB) have a child. What is the chance that they will have a child with brown hair?

Practice Problem #3 A heterozygous brown dog mates with a homozygous recessive white dog. What is the chance that their puppies will be white?

Practice Problem #4 Tongue-rolling is a dominant trait. If two people heterozygous for tongue-rolling have a child, what is the chance that it will not be able to roll its tongue.

Practice Problem #5 Red hair is recessive to all other hair colors. Can 2 people with brown hair have a child with red hair?

Dihybrid Crosses Deals with 2 traits Little bit more complicated Looking at 2 genes, so 4 possible alleles Little bit more complicated Punnett Square will be 4x4 16 possible offspring combinations Principle of Dominance is still followed F1 generation will still show dominant phenotype F2 generation will have a ratio of 9:3:3:1 http://www.showme.com/sh/?h=wBNbIVE

How to set up Punnett Square One allele from each trait will join with one for the other trait, and will give 4 allele combinations EX: AaBb  AB, Ab, aB, ab Do for both parents Draw a 4x4 grid Place alleles for one parent on top, the other on the side Solve like other Punnett Square, only make sure to bring both alleles down and across

Example of Dihybrid Cross If you cross a pea plant with genotype Rryy and one with rrYY, what are the possible genotypes of the offspring? 1st plant allele combinations: Ry, Ry, ry, ry 2nd plant allele combinations: rY, rY, rY, rY Draw 4x4 grid One parent’s alleles on top, the other on the left side

You try it! Tall is dominant to short and Wide is dominant to narrow If you crossed 2 heterozygotes, what number of the offspring would display each of the phenotypes? Tall wide: _________________ Tall narrow: _______________ Short wide: _______________ Short narrow: _____________