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Bell Ringer  Look at your classmates. Note how they vary in the shape of the front hairline, the space between the two upper front teeth, and the way.

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Presentation on theme: "Bell Ringer  Look at your classmates. Note how they vary in the shape of the front hairline, the space between the two upper front teeth, and the way."— Presentation transcript:

1 Bell Ringer  Look at your classmates. Note how they vary in the shape of the front hairline, the space between the two upper front teeth, and the way in which the earlobes are attached.  Make a list of the different forms of these traits that you have observed in the class or among other people you know. 1.Could these traits be inherited? From whom could they be inherited? 2.How is it possible that these traits could be found in a person and his or her biological grandparents but not in the biological parents?

2 Bell Ringer 1.Could these traits be inherited? From whom could they be inherited? 2.How is it possible that these traits could be found in a person and his or her biological grandparents but not in the biological parents?

3 Bell Ringer 1.Could these traits be inherited? From whom could they be inherited?  Yes; from parents. 2.How is it possible that these traits could be found in a person and his or her biological grandparents but not in the biological parents?

4 Bell Ringer 1.Could these traits be inherited? From whom could they be inherited?  Yes; from parents. 2.How is it possible that these traits could be found in a person and his or her biological grandparents but not in the biological parents?  Genes are passed from generation to generation, but are not necessarily expressed in every generation. 3. Every living thing – plant or animal, microbe or human being – has a set of characteristics inherited from its parents.

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6 Gregor Mendel  In 1865, Gregor Mendel published studies of inheritance in pea plants.  During sexual reproduction, male and female gametes join to form a zygote in the process known as fertilization.  Genetics= the scientific study of heredity.

7 Heredity is… the passing on of traits from parents to offspring. 1.Controlled by “factors.” 2.Passed from generation to generation. 3.Probability (pg. 267) 4.Traits – characteristics that are inherited.

8 1902 – Chromosome Theory of Heredity  Genes (Mendels “factors”) are located on chromosomes. Genes are segments of DNA. Genes are traits  The different forms (variations) of a gene are called Alleles.  This is the basis for the modern science of Genetics.

9 Genetic Principles 1. Alleles – gene form, Y or y, for each variation of a trait of an organism. 2. Dominant or Recessive D= visible, observable trait of an organism that masks a recessive form of a trait. R = a hidden trait of an organism that is masked by a dominant gene. 3.Separation, or Segregation; each allele will segregate or separate from each other and it will ½ chance that you receive either allele. Ex. Y or y 4.Independent Assortment

10 Other Terms  Phenotype – the way an organism looks and behaves. Physical characteristics of an organism.  Genotype – the gene combination of an organism; the genetic make-up of a trait or gene.  Homozygous – when an organisms two alleles for a trait are the same. Homozygous recessive ex. rr; homozygous dominant ex. RR  Heterozygous – when an organisms two alleles for a trait are not the same.

11 Genes VS Alleles Gene Allele

12 Genes VS Alleles GenePlant HeightFlower Color Allele Tall PlantPurple Flowers Short PlantWhite Flowers

13 R.C. Punnett  In 1905, R.C. Punnett introduced the Punnett square.  Punnett squares can be used to predict and compare the genetic variations that will result from a cross (pg. 268).

14 Using Punnett Squares Yellow pea seed (Y) is DOMINANT to green (y). Genotype:YY x yy Phenotype: Yellowx green Parents (P)YY y y

15 Using Punnett Squares Yellow pea seed (Y) is DOMINANT to green (y). Genotype:YY x yy Phenotype: Yellowx green Parents (P)YY y y

16 Using Punnett Squares Yellow pea seed (Y) is DOMINANT to green (y). Genotype:YY x yy Phenotype: Yellowx green Parents (P)YY yYy y

17 Using Punnett Squares Yellow pea seed (Y) is DOMINANT to green (y). Genotype:YY x yy Phenotype: Yellowx green Parents (P)YY yYy y

18 Using Punnett Squares Yellow pea seed (Y) is DOMINANT to green (y). Genotype:YY x yy Phenotype: Yellowx green Parents (P)YY yYy y

19 Using Punnett Squares Yellow pea seed (Y) is DOMINANT to green (y). Genotype:YY x yy Phenotype: Yellowx green Parents (P)YY yYy y

20 Using Punnett Squares Yellow pea seed (Y) is DOMINANT to green (y). Genotype:YY x yy Phenotype: Yellowx green Parents (P)YY yYy y

21 Using Punnett Squares Yellow pea seed (Y) is DOMINANT to green (y). Genotype:YY x yy Phenotype: Yellowx green Parents (P)YY yYy y

22 Using Punnett Squares Yellow pea seed (Y) is DOMINANT to green (y). Genotype:YY x yy Phenotype: Yellowx green Parents (P)YY yYy y

23 Using Punnett Squares Yellow pea seed (Y) is DOMINANT to green (y). Genotype:YY x yy Phenotype: Yellowx green All (100%) offspring in F 1 Generation are Yellow hybrids. Parents (P)YY yYy y

24 Monohybrid Cross Yyx Yy Yellow xYellow F 1 GenerationYy

25 Monohybrid Cross Genotype: Yyx Yy Phenotype: Yellow x Yellow F 1 GenerationYy Y y

26 Monohybrid Cross Genotype: Yyx Yy Phenotype: Yellow x Yellow F 1 GenerationYy Y y

27 Monohybrid Cross Genotype: Yyx Yy Phenotype: Yellow x Yellow F 1 GenerationYy YYY y

28 Monohybrid Cross Genotype: Yyx Yy Phenotype: Yellow x Yellow F 1 GenerationYy YYY y

29 Monohybrid Cross Genotype: Yyx Yy Phenotype: Yellow x Yellow F 1 GenerationYy YYY yYy

30 Monohybrid Cross Genotype: Yyx Yy Phenotype: Yellow x Yellow F 1 GenerationYy YYY yYy

31 Monohybrid Cross Genotype: Yyx Yy Phenotype: Yellow x Yellow F 1 GenerationYy YYYYy y

32 Monohybrid Cross Genotype: Yyx Yy Phenotype: Yellow x Yellow F 1 GenerationYy YYYYy y

33 Monohybrid Cross Genotype: Yyx Yy Phenotype: Yellow x Yellow F 1 GenerationYy YYYYy y yy

34 Monohybrid Cross Genotype: Yyx Yy Phenotype: Yellow x Yellow Phenotypic Ratio: 75% (3/4) offspring are Yellow; Ratio is 3:4 (Yellow : total) 25% (1/4) offspring are green; Ratio is 1:4 (green : total) F 1 GenerationYy YYYYy y yy

35 Dihybrid Cross  Round pea seed (R) is dominant to wrinkled pea seed (r).  FOIL: YyRr  YR, Yr, yR, yr  (These are the possible genotypic combinations)

36 Dihybrid Cross Round pea seed (R) is dominant to wrinkled pea seed (r). Possible Combinations YRYryRyr YR Yr yR yr

37 Dihybrid Cross Round pea seed (R) is dominant to wrinkled pea seed (r). Possible Combinations YRYryRyr YRYYRRYYRrYyRRYyRr YrYYRrYYrrYyRrYyrr yRYyRRYyRryyRRyyRr yrYyRrYyrryyRryyrr

38 What is the probability that the plant will produce: Yellow, Round Peas: Yellow, Wrinkled Peas: Green, Round Peas: Green, Wrinkled Peas: Possible Combos YRYryRyr YR YYRR Yellow, Round YYRr Yellow, Round YyRR Yellow, Round YyRr Yellow, Round Yr YYRr Yellow, Round Yyrr Yellow, wrinkled YyRr Yellow, Round Yyrr Yellow, wrinkled yR YyRR Yellow, Round YyRr Yellow, Round yyRR green, Round yyRr green, Round yr YyRr Yellow, Round Yyrr Yellow, wrinkled yyRr green, Round Yyrr green, wrinkled

39 What is the probability that the plant will produce: Yellow, Round Peas: 9/16 Yellow, Wrinkled Peas:3/16 Green, Round Peas:3/16 Green, Wrinkled Peas:1/16 Possible Combos YRYryRyr YR YYRR Yellow, Round YYRr Yellow, Round YyRR Yellow, Round YyRr Yellow, Round Yr YYRr Yellow, Round Yyrr Yellow, wrinkled YyRr Yellow, Round Yyrr Yellow, wrinkled yR YyRR Yellow, Round YyRr Yellow, Round yyRR green, Round yyRr green, Round yr YyRr Yellow, Round Yyrr Yellow, wrinkled yyRr green, Round Yyrr green, wrinkled

40 To find the probability that two different events will happen at the same time, multiply the probabilities of each event happening separately.

41 Probability of offspring having YELLOW pea seeds: ¾ Probability of offspring having ROUND pea seeds: ¾ Probability of offspring having BOTH YELLOW AND ROUND PEAS: ¾ X ¾ = 9/16

42 Trihybrid Cross  Tall Stem (T) is dominant to short stem (t).  The probability of producing tall stems in a monohybrid cross is:  What is the probability that the offspring in a trihybrid cross will be Yellow, Round, and Tall?

43 Trihybrid Cross  Tall Stem (T) is dominant to short stem (t).  The probability of producing tall stems in a monohybrid cross is: ¾  What is the probability that the offspring in a trihybrid cross will be Yellow, Round, and Tall? ¾ X ¾ X ¾ = 27/64

44  Incomplete dominance (also called partial dominance) occurs when the phenotype of the heterozygous genotype is distinct from and often intermediate to the phenotypes of the homozygous genotypes. For example, the snapdragon flower color is either homozygous for red or white. Example: Red flowers (RR) crosses with white flowers (WW) shows incomplete dominance for pink flowers (RW)

45 Ex. Of Incomplete Dominance

46  Codominance – when both alleles contribute to the phenotype. Example – black feathers codominant with white feathers in chickens, both white and black feathers are present separately. Also blood types and a cholesterol enzyme in humans.

47 What is the difference?

48 Other Terms  Multiple alleles-genes that have more than 2 alleles This means that there are more than 2 possible alleles in a population Example: rabbit fur colors  Polygenic traits – traits controlled by more than 2 genes Example: human skin color is controlled by more than 4 different genes

49 Blood types

50 Height and Multiple alleles


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