1 / 19

Punnett Squares and Probability

Learn about Punnett squares and how they can be used to predict the genotypes and phenotypes of offspring in different types of genetic crosses. Explore monohybrid crosses, incomplete dominance, co-dominance, dihybrid crosses, and sex-linked inheritance.

vhaywood
Download Presentation

Punnett Squares and Probability

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Punnett Squares and Probability

  2. What is a punnett square and why do we use it? What is it? • A grid system for predicting all possible genotypes of offspring from two parents • The axes of the grid represent the possible gamete genotypes of each parent • The boxes show all possible genotypes of the offspring

  3. Monohybrid Crosses What is a Monohybrid Cross? Showing a Cross Aa x Aa Demonstrates the inheritance of one specific trait Only contains 4 boxes. The parent’s gametes are separated over the boxes Genotypic Ratio: 1 AA: 2Aa: 1aa

  4. Monohybrid Cross Example Walruses are characterized by their tusks. A heterozygous male with long tusks mates with a female that has short tusks. The dominant trait should be represented by (T) and the recessive trait should be represented by (t) • What percentage of the offspring will have short tusks? • Write the genotypic ratio for the scenario • Write the phenotypic ratio for the scenario

  5. Incomplete Dominance What is it? A cross where the heterozygous phenotype is somewhere between the two homozygous phenotypes. Neither allele is completely dominant or recessive. Red (RR) x White (WW) 4 Pink (RW) Since there is no recessive condition, all letters are capital

  6. Incomplete Dominance Example In a particular breed of fish, being red (R) is incompletely dominant to being white (W). What are the genotypes of the parents if for every 100 offspring, 53 are red and 47 are pink?

  7. Co-Dominance What is it? RR x WW A cross where both alleles of a gene are expressed completely and separately, neither allele is dominant or recessive. RR = Red cow RW = Red and White cow (Roan) WW = White cow Since there is no recessive condition, all letters are capital

  8. Co-Dominance Example When studying a certain species of lizard, you are familiar with a yellow species and a green species. When doing research, you find that a third species exists that is green with yellow spots. Show the following cross in a punnett. Green lizard with yellow spots x Green lizard Show the genotypic and phenotypic ratios for the offspring.

  9. Dihybrid Cross What is it? What does it look like? A cross that examines the inheritance of two different traits Uses 16 boxes in total Parental Gametes are separated in pairs Example: Genotype RrYy Gametes: RY, Ry, rY, ry

  10. Dihybrid Cross Example In cows, being spotted (S) is dominant to being a solid (s) color. Also, having curved horns (H) is dominant to having straight horns (h). • A female who is heterozygous for both traits is bred with a male who is homozygous dominant for horn shape and homozygous recessive for pattern. • What are the phenotypic and genotypic ratios of their offspring?

  11. Multiple Alleles (Blood Typing) What is it? Does it look like? Blood types demonstrate co-dominance and the basic principles of dominance and recessiveness There are four general phenotypes for blood types: A, B, AB, and O Another factor that we consider in blood typing is the Rhesus factor. Individuals can either be Rh+ or Rh- All possible phenotypes are: A+, A-, B+, B-, AB+, AB-, O+, O-

  12. People with blood group 0 Rh - are called "universal donors" and people with blood group AB Rh+ are called "universal receivers." Rh+ blood can never be given to someone with Rh - blood, but the other way around works. For example, 0 Rh+ blood can not be given to someone with the blood type AB Rh -.

  13. Multiple Allele Example • What are the potential blood types of children for a man with heterozygous type A blood and a woman with type AB blood? • Show the genotypic and phenotypic ratios

  14. Blood Typing as a Dihybrid Cross Show the cross of a heterozygous A+ male and a heterozygous B+ individual. • Show all genotypes and all phenotypes for the possible offspring Important things to think about: • How is a heterozygous A or B individual’s genotype represent? • Rh+ is dominant to Rh- • How will the gametes assemble in the dihybrid cross?

  15. Sex-Linked Problems What is it? What does it look like? Cross that demonstrates inheritance of genes located on the sex chromosomes Females have two X chromosomes, therefore the start of their genotypes is XX. Males have an X and Y chromosome, therefore the start of their genotypes is XY. 50% of offspring are always male and 50% if the offspring are always female

  16. Important things to know In order to successfully complete the problem: • You must make note of the sex chromosome (X) and the trait • Example: Sex Chromosome  XC  Trait • Never place a trait on a Y chromosome! Traits are only carried on the X chromosomes. Female Results: • Homozygous dominant female XHXH • Heterozygous female XHXh (expresses dominant condition or is a carrier) • Homozygous recessive female XhXh Male Results: • Dominant male XHY • Recessive male XhY

  17. Sex-linked Example Perform a cross between a white-eyed female fruit fly and red-eyed male. White eyes are a recessive condition. • Write the phenotypic and genotypic ratio of all offspring. • What percent of the female offspring will have white eyes?

  18. ProbabilityThe likelihood that a particular event will happen How do we calculate it? (Revisit the punnett) (In an ideal situation) If these parent had 1 offspring, what fraction shows the chance of the offspring being heterozygous? ½ chance of heterozygous offspring If these parents had a second child, what fraction shows the chance of the offspring being heterozygous? ½ x ½ = ¼ chance of 2 heterozygous offspring

  19. Probability Example • Colorblindness is a sex-linked trait. A man, whose mother was a carrier for colorblindness marries a woman who is a carrier for colorblindness. • What are the odds that the man is colorblind? • If he is not colorblind, what is the likelihood that he will have 2 colorblind sons?

More Related