1. Variations to Mendel’s Laws
Extensions and Exceptions

2. Alterations to Mendel’s Ratios
In these cases, genotypic ratio is as Mendel predicted but phenotypic ratio is altered
Lethal allele combinations
Multiple alleles
Different dominance relationships
Epistasis
Penetrance and expressivity
Pleiotropy
Genetic heterogeneity
Phenocopies

3. Lethal Allele Combinations

4. Multiple Alleles Give a range of phenotypes
Each of us has 2 alleles for any given gene
1 from mom and 1 from dad
There can be many different alleles for a gene
Different alleles are formed by mutations

5. Example of Multiple Alleles -PKU
Phenylketonuria (PKU)
Enzyme that breaks down phenylalanine is deficient
Phenylalanine accumulates
There are hundreds of possible alleles
Allelic combinations give rise to different phenotypes
Severe mental retardation
Moderate PKU
Mild PKU
Asymptomatic PKU

6. Different Dominance Relationship –Incomplete dominance
The heterozygous phenotype is intermediate between the homozygous dominant and the homozygous recessive
Blended phenotype

7. Different Dominance Relationship –codominance
Phenotypes of both alleles are expressed

8. Codominance –Blood Type

9. Codominance –Blood Type

10. Epistasis One gene affects the expression of another
Example: If a dog has the hairless gene, the genes that affect hair color will not be expressed

11. Penetrance and Expressivity
Describe degrees of inheritance
Due to multifactorial inheritance
Expression of a gene is influenced by other genes and by environment
Penetrance =all-or-none expression of a gene
100% of the people who inherit mutant amyloid precursor protein (mAPP) develop Alzheimer disease so mAPP is 100% penetrant
Expressivity =severity of gene expression
Polydactyly has variable expressivity
Some have an extra toe and others have an extra toe and an extra finger.

12. Pleiotropy Gene affects several functions Example: Porphyria variegata
Phenotype is varied
Example: Porphyria variegata

13. Genetic Heterogeneity
Different genes produce the same phenotype
Example:
Hearing loss may be due to one of 132 different genes that follow autosomal recessive inheritance
B, b =gene for hearing loss type 1
R, r =gene for hearing loss type 2
BBrr
bbRR
BbRr
deaf
deaf
NOT deaf

14. Phenocopy An environmentally caused trait that appears to be inherited
Example: Phocomelia is a rare genetic disorder whose effects are mimicked by the teratogen, thalidomide
Example: AIDs transmission from mother to offspring

15. Mitochondrial Genes

17. Mitochondrial Inheritance Pattern
Mitochondrial genes are passed from mothers to offfspring.
Only females pass on the genes

18. The 37 Mitochondrial Genes
24 encode proteins important for protein synthesis
Mutations can have devastating effects
13 encode proteins needed for energy production
Mutations often affect skeletal muscle and cause fatigue

19. Heteroplasmy
A mutation can occur in one mitochondrial DNA ring and not another.
When the mitochondria divide, different batches of daughter mitochondria are produced (some with the mutation, some without)
It is therefore possible to have mutant mitochondrial DNA in some tissues but not others
Causes variation is expressivity of a mitochondrial disease depending on which tissues/organs have cells with mutated mitochondrial DNA

20. Linkage Two genes on the same chromosome may “co-segregate”
Example: Dihybrid cross of pea plants with purple flowers (Pp) and long pollen grains (Ll)

21. Figure 5.10 Parents P p P L p l L l Genotype PpLl Genes not linked
Genes linked
Self-cross
Self-cross
Figure 5.10

22. Parents F1 P p P L p l L l Genotype PpLl Genes not linked
Genes linked
Self-cross
Self-cross F1
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

23. Parents F1 P p P L p l L l Genotype PpLl Genes not linked
Genes linked
Self-cross
Self-cross F1
Female gametes PL Pl pL pl
Female gametes PL pl PL PL
Male
gametes Pl pl
Male
gametes pL pl

24. Parents F1 P p P L p l L l Genotype PpLl Genes not linked
Genes linked
Self-cross
Self-cross F1
Female gametes PL Pl pL pl
Female gametes PL pl
PPLL
PPLl
PpLL
PpLl
PPll
Ppll
ppLL
ppLl
ppll
Male
gametes PL Pl pL pl
Male
gametes PL pl
PPLL
PpLl
ppll

25. Parents F1 Phenotypic ratio 3: Phenotypic ratio 9:3 P p P L p l L l
Genotype PpLl
Genes not linked
Genotype PpLl
Genes linked
Self-cross
Self-cross F1
Female gametes PL Pl pL pl
Female gametes PL pl
PPLL
PPLl
PpLL
PpLl
Male
gametes PL Pl pL pl
Male
gametes PL pl
PPLL
PpLl
ppll
PPLl
PPll
PpLl
Ppll
PpLL
PpLl
ppLL
ppLl
Phenotypic ratio 3:
PpLl
Ppll
ppLl
ppll
Phenotypic ratio 9:3

26. Parents F1 P p P L p l L l Genotype PpLl Genes not linked
Genes linked
Self-cross
Self-cross F1
Female gametes PL Pl pL pl
Female gametes PL pl
PPLL
PPLl
PpLL
PpLl
Male
gametes PL Pl pL pl
Male
gametes PL pl
PPLL
PpLl
ppll
PPLl
PPll
PpLl
Ppll
PpLL
PpLl
ppLL
ppLl
Phenotypic ratio 3:
PpLl
Ppll
ppLl
ppll
Phenotypic ratio 9:3:3

27. Parents F1 Phenotypic ratio 9:3:3:1 P p P L p l L l Genotype PpLl
Genes not linked
Genotype PpLl
Genes linked
Self-cross
Self-cross F1
Female gametes PL Pl pL pl
Female gametes PL pl
PPLL
PPLl
PpLL
PpLl
Male
gametes PL Pl pL pl
Male
gametes PL pl
PPLL
PpLl
PPLl
PPll
PpLl
Ppll
PpLl
ppll
PpLL
PpLl
ppLL
ppLl
Phenotypic ratio 3:1
PpLl
Ppll
ppLl
ppll
Phenotypic ratio 9:3:3:1

28. Crossing Over May Disrupt Linkage

29. Linkage Maps
The farther apart 2 genes are, the more likely their linkage will be disrupted during crossing over
% recombination tells us the relative location of the genes