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Fundamentals of Genetics. Chapter 9. Mendel’s Legacy. Section 9.1. Genetics. The field of biology dedicated to understanding how characteristics are transmitted from parent to offspring. Gregor Mendel. Austrian monk & science teacher Studied heredity Worked with pea plants in his garden
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Fundamentals of Genetics Chapter 9
Mendel’s Legacy Section 9.1
Genetics • The field of biology dedicated to understanding how characteristics are transmitted from parent to offspring.
Gregor Mendel • Austrian monk & science teacher • Studied heredity • Worked with pea plants in his garden • Mid 1800s • “Father of Genetics”
Mendel’s Peas: • Studied 7 characteristics of peas • Each characteristics had 2 different traits • Page 176
Mendel’s Experiments: 1. Started off with 2 pure (true breeding) plant groups for a particular characteristic • P generation (parent) 2. Cross pollinated these plant groups (sexual reproduction) to produce the next generation of plants • F1 generation (first filial)
When the seeds matured from the F1 generation, he counted & recorded the traits of the offspring. • Then he allowed the F1 generation plants self pollinate (sexual reproduction with self) to produce the next generation of plants • F2 generation (second filial) When the seeds matured from the F2 generation, he counted & recorded the traits of the offspring.
Notice that the predicted ratios & the actual ratios are not exact!
Mendel’s Results: • The F1 generation always showed only 1 of the 2 traits for the characteristic • Mendel named this the dominant factor • The F2 generation always showed a 3:1 (or a 75% to a 25%) ratio between the 2 traits • Mendel named the second the recessive factor
Purple is dominant White is recessive F1 generation: all purple F2 generation: 75% purple 25% white
Mendel’s Laws of Inheritance 1) Law of Segregation • Mendel stated that… a pair of factors is segregated, or separated, during the formation of gametes. • So, What does this mean? • Each egg and sperm receives only one factor from each parent.
2. Law of Independent Assortment • Mendel also stated that … factors for different characteristics are distributed to gametes independently. • So, What does this mean? • The factors for different characteristics are not connected.
Molecular Genetics • The study of the structure & function of chromosomes & genes • Allele: alternate form of a gene • Mendel called them “factors” • Abbreviations: • Dominant allele = capital letter (B) • Recessive allele = lower case letter (b)
Genetic Crosses 9.2
Vocab: • Genotype:gene combination for a trait (BB, Bb, bb) • Phenotype:the physical feature resulting from a genotype (Black, white)
Genotype Vocab: • Homozygous: “same genes” • When the organism has the same alleles for the characteristic (also called pure) Ex.) BB = homozygous dominant bb = homozygous recessive • Heterozygous: “different genes” • When the organism has different alleles for the characteristic (also called hybrid) Ex.) Bb
Genetic Probability: • The likelihood (probability) of offspring of known parents can be determined by Punnett squares
Types of Genetic Crosses: • Monohybrid Cross- cross involving a single trait ex.) flower color
2) Dihybrid Cross Cross involving 2 traits
Let’s Practice Punnett Squares! Monohybrid Cross Dihybrid Cross
How do you find an unknown genotype? Testcross • Example) Is the red flower a pure (RR) or hybrid (Rr) ? • Cross the unknown flower with a pure recessive flower (rr). • This will allow the recessives to show up in the next generation.
The results: • If the flower is hybrid, the offspring will be 50% red and 50% white. • If the flower is pure, the offspring will be all red. Result if flower is hybrid Result if flower is pure
Complications! Incomplete Dominance and Codominance • Incomplete Dominance:occurs when the F1 offspring has a phenotype between that of the parents. • neither allele is completely dominant
Example) Japanese Four o’clock flowers The flowers may be red or white in the purebred form, but the hybrid form of the flowers is pink. Q- What would happen if you crossed a red four o’clock flower with a white four o’clock flower? A- a pink flower!
2) Codominance • Occurs when both alleles are expressed in a heterozygous offspring. • Neither allele is dominant or recessive Example) Q- What would happen if you crossed a horse with a white coat (rr) with a horse with a red coat (RR)? A- A horse with a roan coat (Rr) ~ both red and white hairs
Question: In rabbits, the allele for black coat color (B) is dominant over the allele for brown coat color (b). Predict the results of a cross between a rabbit heterozygous for black coat color and a rabbit homozygous for brown coat color. What is the genotypic ratio? What is the phenotypic ratio?
Question: • Albinism is a recessive disorder (aa) that results in a lack of pigment in the eyes, skin, and hair. • What are the genotypes and phenotypes of the parents if they have 2 children with albinism and 2 children normally pigmented. Use a Punnett square to complete this problem
Brown hair color is dominant over blonde hair, and brown eyes are dominant over blue eyes. • Q- If 2 heterozygous parents for both traits mate, what is the phenotypic ratio of their offspring? __________ Brown hair, Brown eyes __________ Brown hair, Blue eyes __________ Blonde hair, Brown eyes __________ Blonde hair, Blue eyes
Incomplete Dominance Q: • Scottish fold cats are heterozygotes whose ears fold down onto their heads several days after birth. The homozygote genotype, rr, for this trait causes death. Construct a Punnett square to determine the genotypic and phenotypic ratios of a cross between 2 cats with folded ears.
B. Complications: Multiple alleles • ABO blood groups Dominant Dominant Codominant Recessive
C. Complications: Pleiotropy • - One gene affects many characters • - Sickling allele of hemoglobin
D. Complications: Polygenic Inheritance and Quantitative Characters • - One trait determined by multiple genes • - Converse of pleiotropy • - e.g., skin color: at least 3 genes
Complications: Epistasis • - Expression of one gene depends on another • - Mouse coat color: • B - black coat • b - brown coat • C - pigment • c - no pigment
What are my chances? • Obtain 2 pennies. • Flip each coin simultaneously 50 times. Record the results of each set of flips. • Total the number of combinations of your results: __ Heads-Heads __ Heads-Tails __ Tails-Tails
Record your results on the board. • Calculate your percent chance of each combination. (# of combos) 50 • Calculate the class average percent chance of each combination.