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Chapter 14: Mendel and the Gene Idea
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Inheritance The passing of traits from parents to offspring. Humans have known about inheritance for thousands of years.
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Genetics The scientific study of the inheritance. Genetics is a relatively “new” science (about 150 years).
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Genetic Theories 1. Blending Theory - traits were like paints and mixed evenly from both parents. 2. Incubation Theory - only one parent controlled the traits of the children. Ex: Spermists and Ovists
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3. Particulate Model - parents pass on traits as discrete units that retain their identities in the offspring.
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Gregor Mendel Father of Modern Genetics.
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Mendel’s paper published in 1866, but was not recognized by Science until the early 1900’s.
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Reasons for Mendel's Success Used an experimental approach. Applied mathematics to the study of natural phenomena. Kept good records.
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Mendel was a pea picker. He used peas as his study organism.
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Why Use Peas? Short life span. Bisexual. Many traits known. Cross- and self-pollinating. (You can eat the failures).
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Cross-pollination Two parents. Results in hybrid offspring where the offspring may be different than the parents.
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Self-pollination One flower as both parents. Natural event in peas. Results in pure-bred offspring where the offspring are identical to the parents.
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Mendel's Work Used seven characters, each with two expressions or traits. Example: Character - height Traits - tall or short.
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Monohybrid or Mendelian Crosses Crosses that work with a single character at a time. Example - Tall X short
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P Generation The Parental generation or the first two individuals used in a cross. Example - Tall X short Mendel used reciprocal crosses, where the parents alternated for the trait.
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Offspring F 1 - first filial generation. F 2 - second filial generation, bred by crossing two F 1 plants together or allowing a F 1 to self- pollinate.
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Another Sample Cross P Tall X short (TT x tt) F 1 all Tall (Tt) F 2 3 tall to 1 short (1 TT: 2 Tt: 1 tt)
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Results - Summary In all crosses, the F 1 generation showed only one of the traits regardless of which was male or female. The other trait reappeared in the F 2 at ~25% (3:1 ratio).
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Mendel's Hypothesis 1. Genes can have alternate versions called alleles. 2. Each offspring inherits two alleles, one from each parent.
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Mendel's Hypothesis 3. If the two alleles differ, the dominant allele is expressed. The recessive allele remains hidden unless the dominant allele is absent. Comment - do not use the terms “strongest” to describe the dominant allele.
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Mendel's Hypothesis 4. The two alleles for each trait separate during gamete formation. This now called: Mendel's Law of Segregation
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Law of Segregation
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Mendel’s Experiments Showed that the Particulate Model best fit the results.
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Vocabulary Phenotype - the physical appearance of the organism. Genotype - the genetic makeup of the organism, usually shown in a code. T = tall t = short
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Helpful Vocabulary Homozygous - When the two alleles are the same (TT/tt). Heterozygous- When the two alleles are different (Tt).
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6 Mendelian Crosses are Possible Cross Genotype Phenotype TT X tt all Tt all Dom Tt X Tt 1TT:2Tt:1tt 3 Dom: 1 Res TT X TT all TT all Dom tt X tt all tt all Res TT X Tt 1TT:1Tt all Dom Tt X tt 1Tt:1tt 1 Dom: 1 Res
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Test Cross Cross of a suspected heterozygote with a homozygous recessive. Ex: T_ X tt If TT - all dominant If Tt - 1 Dominant: 1 Recessive
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Dihybrid Cross Cross with two genetic traits. Need 4 letters to code for the cross. Ex: TtRr Each Gamete - Must get 1 letter for each trait. Ex. TR, Tr, etc.
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Number of Kinds of Gametes Critical to calculating the results of higher level crosses. Look for the number of heterozygous traits.
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Equation The formula 2 n can be used, where “n” = the number of heterozygous traits. Ex: TtRr, n=2 2 2 or 4 different kinds of gametes are possible. TR, tR, Tr, tr
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Dihybrid Cross TtRr X TtRr Each parent can produce 4 types of gametes. TR, Tr, tR, tr Cross is a 4 X 4 with 16 possible offspring.
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Results 9 Tall, Red flowered 3 Tall, white flowered 3 short, Red flowered 1 short, white flowered Or: 9:3:3:1
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Law of Independent Assortment The inheritance of 1st genetic trait is NOT dependent on the inheritance of the 2 nd trait. Inheritance of height is independent of the inheritance of flower color.
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Comment Ratio of Tall to short is 3:1 Ratio of Red to white is 3:1 The cross is really a product of the ratio of each trait multiplied together. (3:1) X (3:1)
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Probability Genetics is a specific application of the rules of probability. Probability - the chance that an event will occur out of the total number of possible events.
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Genetic Ratios The monohybrid “ratios” are actually the “probabilities” of the results of random fertilization. Ex: 3:1 75% chance of the dominant 25% chance of the recessive
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Rule of Multiplication The probability that two alleles will come together at fertilization, is equal to the product of their separate probabilities.
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Example: TtRr X TtRr The probability of getting a tall offspring is ¾. The probability of getting a red offspring is ¾. The probability of getting a tall red offspring is ¾ x ¾ = 9/16
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Comment Use the Product Rule to calculate the results of complex crosses rather than work out the Punnett Squares. Ex: TtrrGG X TtRrgg
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Solution “T’s” = Tt X Tt = 3:1 “R’s” = rr X Rr = 1:1 “G’s” = GG x gg = 1:0 Product is: (3:1) X (1:1) X (1:0 ) = 3:3:1:1
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Variations on Mendel 1. Incomplete Dominance 2. Codominance 3. Multiple Alleles 4. Epistasis 5. Polygenic Inheritance
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Incomplete Dominance When the F1 hybrids show a phenotype somewhere between the phenotypes of the two parents. Ex. Red X White snapdragons F1 = all pink F2 = 1 red: 2 pink: 1 white
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Result No hidden Recessive. 3 phenotypes and 3 genotypes (Hint! – often a “dose” effect) Red = C R C R Pink = C R C W White = C W C W
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Another example
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Codominance Both alleles are expressed equally in the phenotype. Ex. MN blood group MM MN NN
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Result No hidden Recessive. 3 phenotypes and 3 genotypes (but not a “dose” effect)
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Multiple Alleles When there are more than 2 alleles for a trait. Ex. ABO blood group I A - A type antigen I B - B type antigen i - no antigen
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Result Multiple genotypes and phenotypes. Very common event in many traits.
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Alleles and Blood Types Type Genotypes A I A I A or I A i B I B I B or I B i AB I A I B O ii
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Comment Rh blood factor is a separate factor from the ABO blood group. Rh+ = dominant Rh- = recessive A+ blood = dihybrid trait
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Epistasis When 1 gene locus alters the expression of a second locus. Ex: 1 st gene: C = color, c = albino 2 nd gene: B = Brown, b = black
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Gerbils
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In Gerbils CcBb X CcBb Brown X Brown F1 = 9 brown (C_B_) 3 black (C_bb) 4 albino (cc__)
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Result Ratios often altered from the expected. One trait may act as a recessive because it is “hidden” by the second trait.
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Epistasis in Mice
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Problem Wife is type A Husband is type AB Child is type O Question - Is this possible?
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Bombay Effect Epistatic Gene on ABO group. Alters the expected ABO outcome. H = dominant, normal ABO h = recessive, no A,B, reads as type O blood.
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Genotypes Wife: type A (I A I A, Hh) Husband: type AB (I A I B, Hh) Child: type O (I A I A, hh) Therefore, the child is the offspring of the wife and her husband.
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Bombay - Detection When ABO blood type inheritance patterns are altered from expected.
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Polygenic Inheritance Factors that are expressed as continuous variation. Lack clear boundaries between the phenotype classes. Ex: skin color, height
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Genetic Basis Several genes govern the inheritance of the trait. Ex: Skin color is likely controlled by at least 4 genes. Each dominant gives a darker skin.
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Result Mendelian ratios fail. Traits tend to "run" in families. Offspring often intermediate between the parental types. Trait shows a “bell-curve” or continuous variation.
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Genetic Studies in Humans Often done by Pedigree charts. Why? Can’t do controlled breeding studies in humans. Small number of offspring. Long life span.
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Pedigree Chart Symbols Male Female Person with trait
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Sample Pedigree
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Dominant Trait Recessive Trait
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Human Recessive Disorders Several thousand known: Albinism Sickle Cell Anemia Tay-Sachs Disease Cystic Fibrosis PKU Galactosemia
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Sickle-cell Disease Most common inherited disease among African-Americans. Single amino acid substitution results in malformed hemoglobin. Reduced O 2 carrying capacity. Codominant inheritance.
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Tay-Sachs Eastern European Jews. Brain cells unable to metabolize type of lipid, accumulation of causes brain damage. Death in infancy or early childhood.
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Cystic Fibrosis Most common lethal genetic disease in the U.S. Most frequent in Caucasian populations (1/20 a carrier). Produces defective chloride channels in membranes.
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Recessive Pattern Usually rare. Skips generations. Occurrence increases with consaguineous matings. Often an enzyme defect.
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Human Dominant Disorders Less common then recessives. Ex: Huntington’s disease Achondroplasia Familial Hypercholsterolemia
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Inheritance Pattern Each affected individual had one affected parent. Doesn’t skip generations. Homozygous cases show worse phenotype symptoms. May have post-maturity onset of symptoms.
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Genetic Screening Risk assessment for an individual inheriting a trait. Uses probability to calculate the risk.
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General Formal R = F X M X D R = risk F = probability that the female carries the gene. M = probability that the male carries the gene. D = Disease risk under best conditions.
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Example Wife has an albino parent. Husband has no albinism in his pedigree. Risk for an albino child?
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Risk Calculation Wife = probability is 1.0 that she has the allele. Husband = with no family record, probability is near 0. Disease = this is a recessive trait, so risk is Aa X Aa =.25 R = 1 X 0 X.25 R = 0
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Risk Calculation Assume husband is a carrier, then the risk is: R = 1 X 1 X.25 R =.25 There is a.25 chance that every child will be albino.
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Common Mistake If risk is.25, then as long as we don’t have 4 kids, we won’t get any with the trait. Risk is.25 for each child. It is not dependent on what happens to other children.
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Carrier Recognition Fetal Testing Amniocentesis Chorionic villi sampling Newborn Screening
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Fetal Testing Biochemical Tests Chromosome Analysis
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Amniocentesis Administered between 11 - 14 weeks. Extract amnionic fluid = cells and fluid. Biochemical tests and karyotype. Requires culture time for cells.
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Chorionic Villi Sampling Administered between 8 - 10 weeks. Extract tissue from chorion (placenta). Slightly greater risk but no culture time required.
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Newborn Screening Blood tests for recessive conditions that can have the phenotypes treated to avoid damage. Genotypes are NOT changed. Ex. PKU
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Newborn Screening Required by law in all states. Tests 1- 6 conditions. Required of “home” births too.
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Multifactorial Diseases Where Genetic and Environment Factors interact to cause the Disease.
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Ex. Heart Disease Genetic Diet Exercise Bacterial Infection
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Summary Know the Mendelian crosses and their patterns. Be able to work simple genetic problems (practice). Watch genetic vocabulary. Be able to read pedigree charts.
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Summary Be able to recognize and work with some of the “common” human trait examples.
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