1. Mendel & Genetics
Chapter 11

2. Gregor Mendel Austrian Monk Researched inheritance using pea plants
Teacher

3. Why pea plants? Variation Characters – heritable feature
Ex: flower color
Trait – variable
Ex: purple or white
Controlled plant “mating” by cutting stamens

4. Mendel's Experiments
Established true breeding lines – offspring the same as the parent
P generation - parent
Hybridized true breeding lines
P X P = F1 generation – first filial
Hybridized F1 generation
F1 x F1 = F2 generation – second filial generation
P Generation
(true-breeding
parents)
Purple
flowers
White 
F1 Generation
(hybrids)
All plants had
purple flowers
F2 Generation

6. Alleles Allele – alternate version of a gene
Accounts for variations in inherited characters
Organisms inherit 2 alleles for each character
One from each parent
Figure 14.4
Allele for purple flowers
Locus for flower-color gene
Homologous
pair of
chromosomes
Allele for white flowers

7. Dominant vs. Recessive
Dominant allele – determines the organisms appearance if present
Represented as a capital
P = purple
Recessive allele – masked if the dominant allele is present
Appears if both alleles are recessive
Represented as lower case
p = white

8. 1st law = law of segregation
Two alleles for a heritable characteristic separate (segregate) during gamete formation and end up in different gametes
Separate during anaphase I
Egg or sperm only gets one of the alleles (haploid)

9. Punnett Square
Predicts the possibilities or possible combinations of offspring from known parental genes.

10. Homozygous vs. Heterozygous
Homozygous – same
Homozygous dominant
PP – genotype
Purple - phenotype
Homozygous recessive
pp – genotype
White - phenotype
Heterozygous – different
Pp – genotype

11. Testcross Possible genotypes for a purple flower?
Pp or PP
Impossible to know just by looking at the flower
Cross with homozygous recessive pp
Analyze results
100% purple – PP
50% purple 50% white - Pp

12. 2nd law – law of independent assortment
Each pair of alleles segregates independently of other allele pairs during gamete formation

14. Monohybrid vs. Dihybrid
One Trait Cross – one pair of contrasting characteristics
Flower color – purple or white
PP, Pp, or pp
Two Trait Cross – two pairs of contrasting traits
Demonstrates law of independent assortment
Flower color and height – purple or white and tall or dwarf
PPTT, PpTT, PPTt, PpTt, PPtt, Pptt, ppTT, ppTt

15. Sample Two Trait Cross PPTt x PpTt Possible Gametes
PPTt – PT or Pt
PpTt – PT, Pt, pT, pt PT Pt pT pt
The size of the punnet square is determined by the number of traits being crossed.
3 traits: 2x = 23 or 8 gametes possible an 8x8 square
4 traits: 2x = 24 or 16 gametes possible a 16x16 square

16. Heterozygous dihybrid cross
GgWw x GgWw
G = green, g = yellow
W = wrinkled, w = round
Gametes for both the same
GW, Gw, gW, gw
Always ends up in a 9:3:3:1 phenotypic ratio
9 – dominant – dominant
Green and wrinkled
3 – dominant – recessive
Green and round
3 – recessive – dominant
Yellow and wrinkled
1 – recessive – recessive
Yellow and round

17. Probability # of times an event occurs # of opportunities it can occur Rr
Segregation of
alleles into eggs
alleles into sperm R r
1⁄2
1⁄4
Sperm
Eggs
Figure 14.9
Multiply individual allele probabilities to calculate overall probability (AND)
Add probability of 2 OR more mutually exclusive events (the heterozygotes can be produced in 2 different ways)
PpTt x PpTt
¼ PP, ½ Pp, ¼ pp
¼ TT, ½ Tt, ¼ tt
Probability of PPTt ?
¼ PP x ½ Tt = 1/8 chance of PPTt
Probability of PpTt?
½ Pp x ½ Tt = ¼ chance of PpTt

18. Practice probability PpTtGg x PPTtgg
What are the chances of producing recessive genotypes for 2 characteristics?
PP = ½, Pp = ½, pp = 0
TT = ¼, Tt = ½, tt = ¼
GG = 0, Gg = ½, gg = ½
PPttgg = ½ x ¼ x ½ = 1/16
Ppttgg = ½ x ¼ x ½ = 1/16
ppTTgg = 0 x ¼ x ½ = 0
ppTtgg = 0 x ½ x ½ = 0
ppttGg = 0 x ¼ x ½ = 0
ppttGG = 0 x ¼ x 0 = 0
Total probability = 2/16 (remember the additional rule!)

19. Incomplete Dominance Incomplete – traits are expressed together
Ex: red (CRCR) + white (CWCW) snapdragon flowers = pink (CRCW)
The heterozygote produces less red pigment so the flower appears pink.
NOT BLENDING!
F2 Phenotypic and genotypic ratios are the same.

20. Codominance
Tay-Sachs Disease: codominant at the molecular level, and equal # of functional and dysfunctional enzymes are produced in the heterozygote, there is enough functional enzyme to break down the lipids in the brain, and the person is phenotypically normal.
Codominance – both phenotypes show up – no recessive trait
Blood Groups: M and N or A and B are Codominant, O is recessive over both
MM: MN: NN
A: Iai or IAIA
B: IBi or IBIB
O: ii
AB: IAIB

21. Multiple Alleles More than two allele forms Ex: blood type A, B, O
AB – codominant
O - recessive
Table 14.2

22. Pleiotropy One gene has more than one phenotypic effect
Ex: Sickle cell anemia & cystic fibrosis

23. Epistasis One gene alters another gene at a different locationBC bC Bc bc
1⁄4
BBCc
BbCc
BBcc
Bbcc
bbcc
bbCc
BbCC
bbCC
BBCC
9⁄16
3⁄16
4⁄16 
Sperm
Eggs
One gene alters another gene at a different location
B = black
b = brown
C = color
c = albino

24. Polygenic Inheritance
AaBbCc
aabbcc
Aabbcc
AaBbcc
AABbCc
AABBCc
AABBCC
20⁄64
15⁄64
6⁄64
1⁄64
Fraction of progeny
Quantitative characteristics
Varied degrees of the characterstic
Multiple genes affect one phenotype
Ex: Skin Color, hair color, eye color

25. Multifactoral Impact
Environment plays a role in gene expression – phenotype
Ex: flower color
Shades may vary based on acidity of the soil
Ex: Height
Actual height may vary based on childhood nutrition and sleep patterns.
Figure 14.13

26. Pedigrees Track traits through generations
Appearance of trait is shaded
Absence of trait is unshaded

28. Recessively inherited disorders
Must have both recessive alleles to have the disease
Heterozygotes are carriers
Increased probability of passing on a recessive disease when close relative mate
Albinism
Cystic Fibrosis
Sickle Cell

29. Dominantly Inherited Dissorders
Figure 14.15
Only need one dominant gene to have the disorder
Achondroplasia
Dwarfism – heterozygous
Deadly when homozygous dominant
Cartilage doesn’t form into bone during development0
Mild response to HGH
Huntington’s Disease

30. Multifactoral Diseases
Genetic component plus environmental factors
Heart Disease
Cancer
Diabetes
Alcoholism
Mental Disorders

31. Genetic Testing and Counseling
Fetal Testing
Amniocentisis
Chronic Villus Sampling – CVS