1 / 21

The study of heredity started with the work of Gregor Mendel and his pea plant garden

The study of heredity started with the work of Gregor Mendel and his pea plant garden. Mendel was an Austrian Monk that lived in the mid 1800’s (the father of genetics).

drago
Download Presentation

The study of heredity started with the work of Gregor Mendel and his pea plant garden

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. The study of heredity started with the work of Gregor Mendel and his pea plant garden Mendel was an Austrian Monk that lived in the mid 1800’s (the father of genetics)

  2. -- presence of observable traits with contrasting forms -- produces many offspring in one cross -- short life cycle -- ease in manipulating pollination (cross pollination)

  3. Mendel’s cross between tall pea plants yielded all tall pea plants. His cross between small pea plants yielded all small pea plants. X = X = Mendels’ cross between tall pea plants and small pea plants yielded all tall pea plants. x =

  4. Mendel then crossed these second generation tall pea plants and ended up with 1 out 4 being small. x =

  5. Parent A Parent A Parent B Parent B Offspring Offspring New Idea Inherited traits behave as discrete units Old Idea Blending of parental traits Mendel’s View of Inheritance • He showed that inheritance was particulate in its nature (not blending as was previously thought).

  6. Mating P X F1 Male parent Female parent F2 F1 mated together produced these offspring Genetic Crosses • In genetic crosses, the offspring are referred to by how many generations removed they are from the parental (P) generation: • F1 = the heterozygous offspring of a cross between two true breeding parents. • F2 = offspring of a cross between two F1 offspring.

  7. F1 F2 3 purple (PP, Pp, Pp); 1 white (pp) Pp Pp Pp Pp PP Pp Pp pp Homozygous purple Homozygous white P X PP pp Gametes p p P P p p Gametes P P Monohybrid Cross • A monohybrid cross examines the inheritance of one trait, e.g. the inheritance of flower color in peas. • The F1 offspring of a cross between two true breeding parent plants are all purple (Pp). • Note: F1 notation is only used to denote the heterozygous offspring of true breeding parents. • A cross between these offspring (Pp x Pp) would yield a 3:1 ratio in the F2 generation:

  8. Monohybrid cross • Monohybrid crosses are made when 1 trait is analyzed. • Problem: • Tallness (T) is dominant over shortness (t) in pea plants. A Homozygous tall plant (TT) is crossed with a short plant (tt). What is the genotypic makeup of the offspring? The phenotypic makeup ?

  9. Punnett Squares • Genetic problems can be easily solved using a tool called a punnett square. • Tool for calculating genetic probabilities A punnett square

  10. Punnet process • Determine alleles of each parent, these are given as TT, and tt respectively. • Take each possible allele of each parent, separate them, and place each allele either along the top, or along the side of the punnett square.

  11. X Parents pp Pp PP Pp Pp Pp Offspring p P Gametes P Gametes p Using a Punnett Square • The British geneticistR. Punnett devised a method of calculating all possible combinations of gametes and offspring using a grid structure, now called the Punnett square. • The Punnett square is now used to represent the outcome of crosses; the gametes from each parent are separated on each axis and recombined in the spaces within the grid. Each parent provides two gametes for the grid

  12. Dihybrid crosses • Dihybrid crosses are made when 2 independant traits are analyzed • Example: • Plant height (Tt) with tall being dominant to short, • Flower color (Ww) with Purple flowers being dominant to white.

  13. Dihybrid cross example continued • Take the offspring and cross them since they are donating alleles for 2 traits, each parent in the f1 generation can give 4 possible combination of alleles. TW, Tw, tW, or tw. The cross should look like this. (The mathematical “foil” method can often be used here) F2 Generation

  14. Green-round Yellow-round Green-wrinkled Yellow-wrinkled Dihybrid Cross Explained Homozygous yellow-round Homozygous green-wrinkled Parents X Gametes yr YR F1 All yellow-round YyRr YyRr X Offspring F2 Female gametes yr YR Yr yR Possiblefertilizations YR Yr Male Gametes yR yr

  15. Homozygous black, short BbLl Homozygous white, long BbLl bl BL bbll BBLL As there is only one kind of gamete from each parent, there is only one kind of offspring produced in the first generation: heterozygous black, short hair. Possible fertilizations Gametes Only one type of gamete is produced from each parent X X P Dihybrid Cross 1 • In the example below, the characters involved are coat color and coat length in guinea pigs. The alleles for short hair and blackcolor are dominant. • The parental types are homozygous and produce only one type of gamete for each trait. • The F1 offspring are all heterozygotes.

  16. BBLL BBLl BbLL BbLl BbLl BBLl BBll Bbll BbLl BbLl bbLL bbLl BbLl bbll bbLl Bbll Dihybrid Cross 2 • If the F1 heterozygotes from the previous example are crossed with each other four kinds of gamete are produced: BL, BI, bL, bl • A Punnett square displays the expected ratio of the offspring genotypes and phenotypes. The offspring are produced in an expected 9 : 3 : 3 : 1 ratio. Female gametes bL bl Bl BL Possiblefertilizations Offspring (F2) BL Each of the 16 animals shown here represents the possible zygotes formed by different combinations of gametes coming together at fertilization. Bl Male gametes bL bl

  17. aaB BCC AaB BCC AAB BCC AAB Bcc AaB bCc AAb bCC AAB BCc AAB bCC AA aa AABb Aabb AaBb AAbb aaBb aabb AABB AaBB Aa aaBB AaBb Aa Aa AaBb X Parents X Parents Possibleoffspring Possibleoffspring Monohybrid cross Dihybrid cross AaBb Cc AaBb Cc X Parents Possible offspring (plus many more) Trihybrid cross Genetic Crosses • Crosses can be shown by separating the parental alleles (or allele combinations) and recombining them in the offspring: • Monohybrid cross: The inheritanceof one gene (A) is studied. • Dihybrid cross: The inheritance oftwo genes (A and B) is studied. • Trihybrid cross: The inheritance ofthree genes (A , B, and C) is studied.

  18. Some particular genetic crosses will reveal specific information about the parental lines. These simple breeding tests are designed to reveal the genotype of the parents: • Examples: selfing, testcross, backcross.

  19. Selfing X X Selfed Selfed Progeny all red. Parent must be homozygous Progeny 3:1 red: white. Parent must be heterozygous e.g. red flower x red flower If parent is Rr: 3:1 ratio of red to white flower If parent is RR: All offspring will have red flowers • Selfing(self-fertilization) is used only in plant breeding. • A plant of unknown genotype is fertilized with its own pollen and the phenotypic ratios of the progeny indicate the likely parental genotype.

  20. Testcross Dominant phenotype with unknown genotype Recessive phenotype with known genotype RRorRr X If unknown genotype is RR, then all of the offspring should be red If unknown genotype is Rr, then 50% of offspring should be red and 50% white rr r r r r R R r R All Rr 50% Rr, 50% rr An individual with the dominant phenotype may be homozygous dominant or heterozygous. The genotype of individuals with the dominant phenotype can be established by carrying out a testcross (right) which the unknown genotype is crossed with a homozygous recessive. The results of a testcross are definitive in that the unknown genotype will be revealed. Where an individual is crossed with one of its parents for the same purpose, it is referred to as a backcross.

  21. Back cross • Where an individual is crossed with one of its parents for the same purpose, it is referred to as a backcross.

More Related