1. Biology Sylvia S. Mader Michael Windelspecht
Chapter 11
Mendelian Patterns of Inheritance
Lecture Outline
See separate FlexArt PowerPoint slides for all figures and tables pre-inserted into PowerPoint without notes. 1
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. 1

2. Biology, 9th ed,Sylvia Mader
Chapter 11
Outline
Mendelian Inheritance
11.1 Gregor Mendel
11.2 Mendel’s Laws
11.3 Extending the Range of Mendelian Genetics 2

3. Biology, 9th ed,Sylvia Mader
Chapter 11
11.1 Gregor Mendel
Mendelian Inheritance
Concept of Blending Inheritance:
Parents of contrasting appearance produce offspring of intermediate appearance
Popular concept during Mendel’s time
Mendel’s findings were in contrast with this
He formulated the Particulate Theory of Inheritance
Inheritance involves reshuffling of genes from generation to generation

4. Biology, 9th ed,Sylvia Mader
Chapter 11
Gregor Mendel
Mendelian Inheritance
Austrian monk
Studied science and mathematics at the University of Vienna
Conducted breeding experiments with the garden pea Pisum sativum
Carefully gathered and documented mathematical data from his experiments
Formulated fundamental laws of heredity in the early 1860s
Had no knowledge of cells or chromosomes
Did not have a microscope

5. Biology, 9th ed,Sylvia Mader
Chapter 11
Mendelian Inheritance
Gregor Mendel
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
© Ned M. Seidler/Nationa1 Geographic Image Collection

6. Biology, 9th ed,Sylvia Mader
Chapter 11
Gregor Mendel
Mendelian Inheritance
The garden pea:
Organism used in Mendel’s experiments
A good choice for several reasons:
Easy to cultivate
Short generation
Normally self-pollinating, but can be cross-pollinated by hand
True-breeding varieties were available
Simple, objective traits 6

7. Biology, 9th ed,Sylvia Mader
Garden Pea Anatomy
Chapter 11
Mendelian Inheritance
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Flower Structure
anther
stamen
filament
stigma
style
carpel
ovules in
ovary a.

8. Biology, 9th ed,Sylvia Mader
Garden Pea Anatomy
Chapter 11
Mendelian Inheritance
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Cutting away
anthers
Brushing
on pollen
from another
plant
All peas are yellow when
one parent produces yellow
seeds and the other parent
produces green seeds.

9. Biology, 9th ed,Sylvia Mader
Garden Pea Anatomy
Chapter 11
Mendelian Inheritance
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Characteristics
Trait
*Dominant
*Recessive
Stem length
Tall
Short
Pod shape
Inflated
Constricted
Seed shape
Round
Wrinkled
Seed color
Yellow
Green
Flower position
Axial
Terminal
Flower color
Purple
White
Pod color
Green
Yellow b.

10. Biology, 9th ed,Sylvia Mader
Chapter 11
11.2 Mendel’s Laws
Mendelian Inheritance
Mendel performed cross-breeding experiments
Used “true-breeding” (homozygous) plants
Chose varieties that differed in only one trait (monohybrid cross)
Performed reciprocal crosses
Parental generation = P
First filial generation offspring = F1
Second filial generation offspring = F2
Formulated the Law of Segregation

11. Monohybrid Cross done by Mendel
Biology, 9th ed,Sylvia Mader
Monohybrid Cross done by Mendel
Chapter 11
Mendelian Inheritance
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Allele Key
Phenotypic Ratio T =
tall plant 3
tall t =
short plant 1
short TT tt

12. Monohybrid Cross done by Mendel
Biology, 9th ed,Sylvia Mader
Monohybrid Cross done by Mendel
Chapter 11
Slide #12
Mendelian Inheritance
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Allele Key
Phenotypic Ratio T =
tall plant 3
tall
P generation t =
short plant 1
short TT tt 12

13. Monohybrid Cross done by Mendel
Biology, 9th ed,Sylvia Mader
Chapter 11
Slide #13
Mendelian Inheritance
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Allele Key
Phenotypic Ratio
P generation T =
tall plant 3
tall t =
short plant 1
short TT tt
P gametes T t 13

14. Monohybrid Cross done by Mendel
Biology, 9th ed,Sylvia Mader
Monohybrid Cross done by Mendel
Chapter 11
Slide #14
Mendelian Inheritance
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Allele Key
Phenotypic Ratio
P generation T =
tall plant 3
tall t =
short plant 1
short TT tt
P gametes T t tt
F1 generation Tt 14

15. Monohybrid Cross done by Mendel
Biology, 9th ed,Sylvia Mader
Chapter 11
Slide #15
Mendelian Inheritance
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Allele Key
Phenotypic Ratio
P generation TT tt T =
tall plant 3
tall t =
short plant 1
short
P gametes T t
F1 generation Tt
eggs
F1 gametes T t T
sperm t 15

16. Monohybrid Cross done by Mendel
Biology, 9th ed,Sylvia Mader
Monohybrid Cross done by Mendel
Chapter 11
Slide #16
Mendelian Inheritance
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
P generation
Allele Key
Phenotypic Ratio TT tt T =
tall plant 3
tall t =
short plant 1
short
P gametes T t
F1 generation Tt
eggs
F1 gametes T t T TT
sperm t 16

17. Monohybrid Cross done by Mendel
Biology, 9th ed,Sylvia Mader
Chapter 11
Slide #17
Mendelian Inheritance
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
F1 generation
Allele key
Phenotypic Ratio TT tt T =
tall plant 3
tall t =
short plant 1
short
P gametes T t
F1 generation Tt
eggs
F1 gametes T t T TT Tt
sperm t 17

18. Monohybrid Cross done by Mendel
Biology, 9th ed,Sylvia Mader
Monohybrid Cross done by Mendel
Chapter 11
Slide #18
Mendelian Inheritance
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
P generation
Allele Key
Phenotypic Ratio TT tt T =
tall plant 3
tall t =
short plant 1
short
P gametes T t
F1 generation Tt
eggs
F1 gametes T t T TT Tt
sperm t Tt 18

19. Monohybrid Cross done by Mendel
Biology, 9th ed,Sylvia Mader
Chapter 11
Slide #19
Mendelian Inheritance
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
P generation TT tt
P gametes T t
F1 generation Tt
eggs
F1 gametes T t T
sperm TT Tt
F2 generation t Tt tt
Offspring
Allele Key
Phenotypic Ratio T =
tall plant 19 3
tall t =
short plant 1
short

20. Biology, 9th ed,Sylvia Mader
Chapter 11
Mendel’s Laws
Mendelian Inheritance
Law of Segregation:
Each individual has a pair of factors (alleles) for each trait
The factors (alleles) segregate (separate) during gamete (sperm & egg) formation
Each gamete contains only one factor (allele) from each pair of factors
Fertilization gives the offspring two factors for each trait

21. Biology, 9th ed,Sylvia Mader
Chapter 11
Mendel’s Laws
Mendelian Inheritance
Classical Genetics and Mendel’s Cross:
Each trait in a pea plant is controlled by two alleles (alternate forms of a gene)
Dominant allele (capital letter) masks the expression of the recessive allele (lower-case)
Alleles occur on a homologous pair of chromosomes at a particular gene locus
Homozygous = identical alleles
Heterozygous = different alleles

22. Classical View of Homologous Chromosomes
Biology, 9th ed,Sylvia Mader
Chapter 11
Classical View of Homologous Chromosomes
Mendelian Inheritance
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
sister chromatids
alleles at a
gene locus G g G G g g
Replication R r R R r r S s S S s s
a. Homologous
chromosomes
have alleles for
same genes at
specific loci.
b. Sister chromatids
of duplicated
chromosomes
have same alleles
for each gene. t T t t T T

23. Relationship Between Observed Phenotype and F2 Offspring
Biology, 9th ed,Sylvia Mader
Chapter 11
Relationship Between Observed Phenotype and F2 Offspring
Mendelian Inheritance
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Characteristics
F2Results
Trait
Dominant
Recessive
Dominant
Recessive
Ratio
Stem length
Tall
Short
787
277
2.84:1
Inflated
Pod shape
Constricted
882
299
2.95:1
Seed shape
Round
Wrinkled
5,474
1,850
2.96:1
Seed color
Yellow
Green
6,022
2,001
3.01:1
Flower position
Axial
Terminal
651
207
3.14:1
705
224
3.15:1
Flower color
Purple
White
Pod color
Green
Yellow
428
152
2.82:1
Totals:
14,949
5,010
2.98:1

24. Biology, 9th ed,Sylvia Mader
Chapter 11
Mendel’s Laws
Mendelian Inheritance
Genotype
Refers to the two alleles an individual has for a specific trait
If identical, genotype is homozygous
If different, genotype is heterozygous
Phenotype
Refers to the physical appearance of the individual

25. Biology, 9th ed,Sylvia Mader
Chapter 11
Mendel’s Laws
Mendelian Inheritance
A dihybrid cross uses true-breeding plants differing in two traits
Mendel tracked each trait through two generations.
Started with true-breeding plants differing in two traits
The F1 plants showed both dominant characteristics
F1 plants self-pollinated
Observed phenotypes among F2 plants
Mendel formulated the Law of Independent Assortment
The pair of factors for one trait segregate independently of the factors for other traits
All possible combinations of factors can occur in the gametes
P generation is the parental generation in a breeding experiment.
F1 generation is the first-generation offspring in a breeding experiment.
F2 generation is the second-generation offspring in a breeding experiment

26. Dihybrid Cross Done by Mendel
Biology, 9th ed,Sylvia Mader
Dihybrid Cross Done by Mendel
Chapter 11
Mendelian Inheritance
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. ×
P generation
TTGG
ttgg
P gametes TG tg
F1 generation
TtGg
eggs
F1 gametes TG Tg tG tg TG
TTGG
TTGg
TtGG
TtGg
F2 generation Tg
TTGg
TTgg
TtGg
Ttgg
sperm tG
TtGG
TtGg
ttGG
ttGg tg
TtGg
Ttgg
ttGg
ttgg
Offspring
Allele Key
Phenotypic Ratio T =
tall plant 9
tall plant, green pod t =
short plant 3
tall plant, yellow pod G =
green pod 3
short plant, green pod g =
Yellow pod 1
short plant, yellow pod

27. Independent Assortment and Segregation during Meiosis
Biology, 9th ed,Sylvia Mader
Independent Assortment and Segregation during Meiosis
Chapter 11
Mendelian Inheritance
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. A a B b
Parent cell has two
pairs of homologous
chromosomes.

28. Independent Assortment and Segregation during Meiosis
Biology, 9th ed,Sylvia Mader
Independent Assortment and Segregation during Meiosis
Chapter 11
Slide #28
Mendelian Inheritance
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. A A a a B B b b
either A a B b
Parent cell has two
pairs of homologous
chromosomes. 28

29. Independent Assortment and Segregation during Meiosis
Biology, 9th ed,Sylvia Mader
Independent Assortment and Segregation during Meiosis
Chapter 11
Slide #29
Mendelian Inheritance
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. A A a a B B b b
either A a B b or A A a a
Parent cell has two
pairs of homologous
chromosomes. b b B B 29

30. Independent Assortment and Segregation during Meiosis
Biology, 9th ed,Sylvia Mader
Independent Assortment and Segregation during Meiosis
Chapter 11
Slide #30
Mendelian Inheritance
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. A A a a B B b b
either A a B b or A A a a
Parent cell has two
pairs of homologous
chromosomes. b b B B
All orientations of ho-
mologous chromosomes
are possible at meta-
phase I in keeping with
the law of independent
assortment. 30

31. Independent Assortment and Segregation during Meiosis
Biology, 9th ed,Sylvia Mader
Independent Assortment and Segregation during Meiosis
Chapter 11
Slide #31
Mendelian Inheritance
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. A A B B A A a a B B b b a a b b
either A a B b or A A a a
Parent cell has two
pairs of homologous
chromosomes. b b B B
All orientations of ho-
mologous chromosomes
are possible at metaphase
I in keeping with the
law of independent
assortment. 31

32. Independent Assortment and Segregation during Meiosis
Biology, 9th ed,Sylvia Mader
Independent Assortment and Segregation during Meiosis
Chapter 11
Slide #32
Mendelian Inheritance
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. A A B B A A a a B B b b a a b b
either A a B b A A or b b A A a a
Parent cell has two
pairs of homologous
chromosomes. b b B B a a B B
All orientations of ho-
mologous chromosomes
are possible at metaphase
I in keeping with
the law of independent
assortment. 32

33. Independent Assortment and Segregation during Meiosis
Biology, 9th ed,Sylvia Mader
Independent Assortment and Segregation during Meiosis
Chapter 11
Slide #33
Mendelian Inheritance
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. A A B B A A a a B B b b a a b b
either A a B b A A or b b
Parent cell has two
pairs of homologous
chromosomes. A A a a b b B B a a B B
All orientations of ho-
mologous chromosomes
are possible at meta-
phase I in keeping with
the law of independent
assortment.
At metaphase II, each
daughter cell has only
one member of each
homologous pair in
keeping with the law of
segregation 33

34. Independent Assortment and Segregation during Meiosis
Biology, 9th ed,Sylvia Mader
Independent Assortment and Segregation during Meiosis
Chapter 11
Slide #34
Mendelian Inheritance
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. A B A A AB B B A B A A a a B B b b a a a b b b ab
either a b A a B b A A A b or b b Ab A
Parent cell has two
pairs of homologous
chromosomes. b A A a a b b B B a a a B B B aB a B
All orientations of ho-
mologous chromosomes
are possible at
metaphase I in keeping
with the law of
Independent assortment.
At metaphase II, each
daughter cell has only
one member of each
homologous pair in
keeping with the law of
segregation
All possible combi -
tions of chromosomes
and alleles occur in
the gametes as
suggested by Mendel's
two laws. 34

35. Biology, 9th ed,Sylvia Mader
Chapter 11
Mendel’s Laws
Mendelian Inheritance
Punnett Square
Table listing all possible genotypes resulting from a cross
All possible sperm genotypes are lined up on one side
All possible egg genotypes are lined up on the other side
Every possible zygote genotypes are placed within the squares

36. Biology, 9th ed,Sylvia Mader
Chapter 11
Mendel’s Laws
Mendelian Inheritance
Punnett Square
Allows us to easily calculate probability, of genotypes and phenotypes among the offspring
Punnett square in next slide shows a 50% (or ½) chance
The chance of E = ½
The chance of e = ½
An offspring will inherit:
The chance of EE =½  ½=¼
The chance of Ee =½  ½=¼
The chance of eE =½  ½=¼
The chance of ee =½  ½=¼

37. Biology, 9th ed,Sylvia Mader
Punnett Square
Chapter 11
Mendelian Inheritance
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Parents Ee Ee
eggs E e E EE Ee
spem
Punnett square e Ee ee
Offspring
Allele key
Phenotypic Ratio
E =
unattached earlobes 3
unattached earlobes
e =
attached earlobes 1
attached earlobes

38. Biology, 9th ed,Sylvia Mader
Chapter 11
Mendel’s Laws
Mendelian Inheritance
Testcrosses
Individuals with recessive phenotype always have the homozygous recessive genotype
However, individuals with dominant phenotype have indeterminate genotype
May be homozygous dominant, or
Heterozygous
A testcross determines the genotype of an individual having the dominant phenotype

39. Biology, 9th ed,Sylvia Mader
Chapter 11
Mendel’s Laws
Mendelian Inheritance
Two-trait testcross:
An individual with both dominant phenotypes is crossed with an individual with both recessive phenotypes.
If the individual with the dominant phenotypes is heterozygous for both traits, the expected phenotypic ration is 1:1:1:1. 39

40. Biology, 9th ed,Sylvia Mader
Chapter 11
Mendel’s Laws
Mendelian Inheritance
Genetic disorders are medical conditions caused by alleles inherited from parents
Autosome - Any chromosome other than a sex chromosome (X or Y)
Genetic disorders caused by genes on autosomes are called autosomal disorders
Some genetic disorders are autosomal dominant
An individual with AA has the disorder
An individual with Aa has the disorder
An individual with aa does NOT have the disorder
Other genetic disorders are autosomal recessive
An individual with AA does NOT have the disorder
An individual with Aa does NOT have the disorder, but is a carrier
An individual with aa DOES have the disorder

41. Autosomal Recessive Pedigree
Biology, 9th ed,Sylvia Mader
Autosomal Recessive Pedigree
Chapter 11
Mendelian Inheritance
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. I aa A? II A? Aa Aa A?
Generations *
III Aa Aa A? A? IV aa aa A?
Key
aa = affected
Aa = carrier (unaffected)
AA = unaffected
A? = unaffected
(one allele unknown)
Autosomal recessive disorders
• Most affected children have unaffected
parents.
• Heterozygotes (Aa) have an unaffected phenotype.
• Two affected parents will always have affected children.
• Close relatives who reproduce are more likely to have
affected children.
• Both males and females are affected with equal frequency.

42. Autosomal Dominant Pedigree
Biology, 9th ed,Sylvia Mader
Chapter 11
Autosomal Dominant Pedigree
Mendelian Inheritance
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. I Aa Aa *
Generations II aa Aa A? aa aa aa
III Aa Aa aa aa aa aa
Key
AA = affected
Aa = affected
A? = affected
(one allele unknown)
aa = unaffected
Autosomal dominant disorders
• Affected children will usually have an
affected parent.
• Heterozygotes (Aa) are affected.
• Two affected parents can produce an unaffected child.
• Two unaffected parents will not have affected children.
• Both males and females are affected with equal frequency.

43. 11.3 Extending the Range of Mendelian Genetics
Biology, 9th ed,Sylvia Mader
Chapter 11
11.3 Extending the Range of Mendelian Genetics
Mendelian Inheritance
Some traits are controlled by multiple alleles (multiple allelic traits)
The gene exists in several allelic forms (but each individual only has two alleles)
ABO blood types
The alleles:
IA = A antigen on red blood cells, anti-B antibody in plasma
IB = B antigen on red blood cells, anti-A antibody in plasma
i = Neither A nor B antigens on red blood cells, both anti-A and anti-B antibodies in plasma
The ABO blood type is also an example of codominance
More than one allele is fully expressed
Both IA and IB are expressed in the presence of the other

44. Biology, 9th ed,Sylvia Mader
Chapter 11
ABO Blood Type
Mendelian Inheritance
Phenotype A B AB O
Genotype
IAIA, IAi
IBIB, IBi
IAIB ii

45. Extending the Range of Mendelian Genetics
Biology, 9th ed,Sylvia Mader
Chapter 11
Extending the Range of Mendelian Genetics
Mendelian Inheritance
Incomplete Dominance:
Heterozygote has a phenotype intermediate between that of either homozygote
Homozygous red has red phenotype
Homozygous white has white phenotype
Heterozygote has pink (intermediate) phenotype
Phenotype reveals genotype without a test cross

46. Biology, 9th ed,Sylvia Mader
Chapter 11
Incomplete Dominance
Mendelian Inheritance
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. R R R R 1 2 1 2
eggs R R 1 2 R 1 R R R R 1 1 1 2
sperm
Key
1 R R
red 1 1 R
2 R R
pink 2 1 2
1 R R
white 2 2 R R R R 1 2 2 2
Offspring

47. Extending the Range of Mendelian Genetics
Biology, 9th ed,Sylvia Mader
Chapter 11
Extending the Range of Mendelian Genetics
Mendelian Inheritance
Human examples of incomplete dominance:
Incomplete penetrance
The dominant allele may not always lead to the dominant phenotype in a heterozygote
Many dominant alleles exhibit varying degrees of penetrance
Example: polydactyly
Extra digits on hands, feet, or both
Not all individuals who inherit the dominant polydactyly allele will exhibit the trait 47

48. Extending the Range of Mendelian Genetics
Biology, 9th ed,Sylvia Mader
Chapter 11
Mendelian Inheritance
Extending the Range of Mendelian Genetics
Pleiotropy occurs when a single mutant gene affects two or more distinct and seemingly unrelated traits.
Marfan syndrome is pleiotropic and results in the following phenotypes:
disproportionately long arms, legs, hands, and feet
a weakened aorta
poor eyesight

49. Extending the Range of Mendelian Genetics
Biology, 9th ed,Sylvia Mader
Chapter 11
Extending the Range of Mendelian Genetics
Mendelian Inheritance
Polygenic Inheritance:
Occurs when a trait is governed by two or more genes having different alleles
Each dominant allele has a quantitative effect on the phenotype
These effects are additive
Results in continuous variation of phenotypes within a population
The traits may also be affected by the environment
Examples
Human skin color
Height
Eye color

50. Polygenic Inheritance
Biology, 9th ed,Sylvia Mader
Polygenic Inheritance
Chapter 11
Mendelian Inheritance
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
P generation
F1 generation
F2 generation 20 — 64 15 — 64
Proportion of Population 6 — 64 1 — 64
aabbcc
Aabbcc
AaBbcc
AaBbCc
AABbCc
AABBCc
AABBCC
Genotype Examples

51. Extending the Range of Mendelian Genetics
Biology, 9th ed,Sylvia Mader
Chapter 11
Extending the Range of Mendelian Genetics
Mendelian Inheritance
X-Linked Inheritance
In mammals
The X and Y chromosomes determine gender
Females are XX
Males are XY

52. Extending the Range of Mendelian Genetics
Biology, 9th ed,Sylvia Mader
Chapter 11
Extending the Range of Mendelian Genetics
Mendelian Inheritance
X-Linked Inheritance
The term X-linked is used for genes that have nothing to do with gender
X-linked genes are carried on the X chromosome.
The Y chromosome does not carry these genes
Discovered in the early 1900s by a group at Columbia University, headed by Thomas Hunt Morgan.
Performed experiments with fruit flies
They can be easily and inexpensively raised in simple laboratory glassware
Fruit flies have the same sex chromosome pattern as humans

53. X-Linked Recessive Pedigree
Biology, 9th ed,Sylvia Mader
Chapter 11
X-Linked Recessive Pedigree
Mendelian Inheritance
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
XBXB
XbY
grandfather
XBY
XBXb
daughter
XBY
XbXb
XbY
XBY
XBXB
XBXb
XbY
grandson
Key
XBXB = Unaffected female
XBXb = Carrier female
XbXb = Color-blind female
XbY = Unaffected male
XbY = Color-blind male
X-Linked Recessive
Disorders
• More males than females are affected.
• An affected son can have parents who have the
normal phenotype.
• For a female to have the characteristic, her father must
also have it. Her mother must have it or be a carrier.
• The characteristic often skips a generation from the
grandfather to the grandson.
• If a woman has the characteristic, all of her sons will
have it.

54. Biology, 9th ed,Sylvia Mader
Chapter 11
Muscular Dystrophy
Mendelian Inheritance
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
fibrous
tissue
abnormal
muscle
normal
tissue
(Abnormal): Courtesy Dr. Rabi Tawil, Director, Neuromuscular Pathology Laboratory, University of Rochester Medical Center; (Boy): Courtesy Muscular Dystrophy Association; (Normal): Courtesy Dr. Rabi Tawil, Director, Neuromuscular Pathology Laboratory, University of Rochester Medical Center.