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New Xlinked recessive mutation

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Title: New Xlinked recessive mutation


1
New X-linked recessive mutation
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Duchenne muscular dystrophy
3
Gower maneuver
4
Duchenne and Becker muscular dystrophy
  • Most common form of muscular dystrophy
  • About 1 per 4000 male births
  • Duchenne muscular dystrophy
  • Onset before 6 yr of progressive proximal muscle
    weakness, cardiomyopathy, skeletal deformities
    (secondary to weakness), may have mental
    retardation, usually die by 20 yr of cardiac or
    respiratory complications
  • Elevated serum creatine kinase myopathic
    electromyogram, abnormal EKG
  • Becker muscular dystrophy
  • Onset by 20 or 30 of progressive proximal
    weakness, survival normal to near normal
  • X-linked recessive, but up to 2.5 of
    heterozygotes are symptomatic

5
Duchenne and Becker dystrophy
  • Caused by mutations of the dystrophin gene
  • Located at Xp21
  • Largest known gene (over 2,300,000 bases)
  • About 70 of mutations are deletions
  • About 20 of mutations are small or point
    mutations
  • About 5 of mutations are duplications
  • About 15 - 25 are new mutations Genetic
    disease with no prior family history
  • Precise nature of mutation, small mutations
    determines disease severity

6
Becker muscular dystrophy allelic heterogeneity
7
Dystrophin and associated proteins
8
Dystrophin immunocytochemistry
9
Multiplex Polymerase chain reaction
10
The deletion endpoints affect the reading frame
for protein translation
11
Multiplex PCR gel
12
Female heterozygotes can develop symptoms in
X-linked recessive disorders X inactivation
or Lyonization
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All Calico cats are females
14
X-inactivation in anhidrotic ectodermal dysplasia
Affected males Lack sweat glands Missing or
pointed teeth Fine hair/alopecia Mental
retardation Mutation in ED1 gene Heterozygous
females Patchy loss of sweat glands revealed by
sweat test
15
X inactivation
  • A process of dosage compensation
  • With supernumerary X chromosomes, all but one X
    chromosome is inactivated
  • When a female carries an X linked recessive
    mutation, some cells will be functionally
    hemizygous for that allele and may be affected by
    the trait

16
X inactivation (Lyonization)
  • In normal females, during early development one X
    chromosome is randomly inactivated
  • Both X chromosomes are used in trophoblast and
    other tissues early in development - probably why
    Turners fetuses usually die in utero
  • The same X chromosome is stably inactivated in
    all descendants of the cell in which the
    particular X was selected
  • Inactivation depends in part upon the protein
    product of the Xist (X inactive specific
    transcript) gene at Xq13
  • Virtually all X chromosome genes except for those
    involved in X inactivation are transcriptionally
    repressed
  • Females are mosaic with respect to whether
    maternal or paternal X chromosome is active in a
    given cell
  • Skewed X inactivation can lead to females being
    symptomatic for X-linked recessive disorders or
    traits

17
X inactivation
18
Barr body
19
A dramatic example of Allelic heterogeneity
  • Different clinical syndromes from mutations in
    the same gene

20
Androgen insensitivity syndrome
21
Androgen insensitivity syndrome (Testicular
feminization)
  • 46,XY phenotypic females except for
  • Blind vaginal pouch, no internal female genital
    structures
  • Inguinal testes (higher abdominal temperature
    predisposes to seminoma development)
  • Breast development though often ample is
    immature, e.g. areolae pale
  • Pubic and axillary hair do not develop at puberty
  • May present because of failure to menstruate
  • Caused by mutation of androgen receptor Xq11-12
    that results in premature termination of protein

22
Androgen receptor
23
The androgen receptor is a ligand-activated
transcription factor
24
Androgen insensitivity syndrome
  • Management
  • Raise as normal females but need to advise that
    will be unable to conceive
  • Removal of undescended testicular tissue to
    prevent seminoma

25
X-linked Spinal and Bulbar Muscular Atrophy
(Kennedy disease)
  • Clinical features Progressive, late onset
    weakness and atrophy of extremities and bulbar
    muscles, gonadal atrophy, gynecomastia
  • Inheritance X-linked recessive
  • Chromosome Xq12
  • Affected gene Androgen receptor gene
  • Mutation Expansion from 20 CAG repeats to 40 or
    more repeats, resulting in expansion in receptor
    protein of polyglutamine stretch

26
Androgen receptor gene trinucleotide expansion
27
X-linked spinal and bulbar muscular atrophy
28
X Linked dominant inheritance
  • Affected males with normal mates have no affected
    sons all daughters are affected.
  • Both sons and daughters of an affected mother
    have a 50 risk of inheriting the trait (same as
    autosomal dominant).
  • Males tend to be more severely affected, or
    under-represented due to early lethality
  • Example X-linked hypophosphatemic rickets

29
X linked dominant, affected father
2 affected daughters 2 normal sons
30
X linked dominant, normal father, affected mother
1 affected daughter 1 normal daughter 1 affected
son 1 normal son (pseudo autosomal dominant)
31
Rett syndrome (RTT)
  • Only seen in females
  • Normal development until 6 to 18 months
  • Then lose speech and purposeful hand movements
  • Microcephaly, seizures, autism, ataxia,
    intermittent hyperventilation, and stereotypic
    hand-wringing movements
  • Later, the condition stabilizes and patients
    usually survive into adulthood

32
Rett syndrome, contd
  • Affected gene identified by positional cloning
  • Xq28
  • Mutations found in the MeCP2 gene
  • Protein is one of several proteins that
    recognizes and binds to methylated CpG bases in
    DNA
  • Methylation of these residues prevents gene
    transcription
  • The pattern of methylation is restricted to
    specific regions of chromosomes

33
Rett Syndrome contd
  • The methylation pattern is stably transmitted
    even after cell division
  • This is one mechanism of imprinting, a form of
    epigenetic inheritance
  • The effect of the mutation in the MeCP2 gene
    likely causes RTT syndrome because of the
    derepression of as yet unidentified genes that
    are normally subject to methylation
  • Mutations of MeCP2 are lethal to male fetuses,
    explaining the restriction of RTT to females.

34
Methyl cytosine
35
Fragile X syndrome
36
A Fragile X chromosome
37
Fragile X syndrome (Martin-Bell)
  • Most common inherited cause of mental retardation
  • Clinical syndrome
  • Large head, long facies, large ears
  • Macroorchidism
  • Moderate to severe mental retardation
  • One third of females with the mutation have
    mental retardation
  • Cytology
  • Experimentally induced fragility of tip of long
    arm of X (q28)

38
Fragile X (FMR1)
  • Prevalence
  • 1/1200 males, 1/2500 females
  • Incompletely penetrant
  • All daughters of transmitting male (normal
    intelligence) have normal intelligence
  • Anticipation (more severe disease in subsequent
    generations)
  • Sons born to such daughters have a 40 of FMR1
    and daughters of these women have a 16 chance
    of being retarded
  • 50 of sons born to a retarded mother will have
    FMRI

39
Fragile X syndrome Sherman paradox
40
Fragile X
  • Mutation is an expansion of a CGG trinucleotide
    repeat of the FRAXA gene at Xq28, readily
    detected by molecular testing
  • Normal repeat length is 6 - 54 repeats
  • Normal transmitting males have 60 - 200 repeats
  • Affecteds have 200 - thousands of repeats
  • Extreme expansions occur when mother is
    transmitting
  • Repeat occurs in 5 untranslated region of gene
  • Pathologic expansions usually associated with
    methylation that inhibits its expression
  • FMRI protein is an RNA binding protein

41
FMR gene and trinucleotide expansion
42
Pelizaeus-Merzbacher disease
  • An X-linked disorder of central nervous system
    (CNS) myelin
  • Recessive in most families
  • Caused by mutations of the proteolipid protein
    (PLP) gene

43
Myelin ultrastructure
44
PMD The clinical spectrum
  • Very severe (connatal)
  • Nystagmus (oscillatory eye movements) at birth
  • Stridor
  • Seizures
  • Severe hypotonia and quadriparesis
  • Severe cognitive impairment Usually never verbal
  • Visual impairment
  • Normal peripheral nerves
  • Death in first or second decade
  • Mutations cause PLP to misfold in the endoplasmic
    reticulum, which activates biochemical pathways
    that kill oligodendrocytes (apoptosis)

45
PMD The clinical spectrum
  • Classical
  • Nystagmus (oscillatory eye movements) at birth
  • Moderate hypotonia and quadriparesis
  • Mild to moderate cognitive impairment Usually
    understand well but have more trouble with speech
  • Variable visual impairment
  • Normal peripheral nerves
  • Survival into sixth or seventh decade is possible
  • Most often caused by duplication of PLP gene

46
Pelizaeus-Merzbacher disease
47
Pelizaeus-Merzbacher disease
48
Oligodendrocytes are membrane factories
  • During the peak of myelination, each
    oligodendrocyte makes about 175 X 10-9 mg protein
    per day 3 times the weight of the perikaryon
  • Each oligodendrocyte makes an area of myelin
    membrane about 1000 times the surface area of its
    perikaryon

49
Proteolipid protein structure
50
Pelizaeus-Merzbacher diseaseFISH
51
No PLP is not as bad as too much PLP
  • Null syndrome
  • Nystagmus
  • Spastic quadriparesis, usually worse in legs
  • Ambulation often possible
  • Ataxia
  • Athetosis
  • Peripheral neuropathy
  • Mild to moderate cognitive impairment usually
    learn to speak
  • Lack of PLP is not deleterious to oligodendrocytes

52
The Big PictureIt helps to understand the
biology and biochemistry as well as genetics of
the disease
53
Cell biology influences whether mutations are
recessive or dominant
  • Females heterozygous for a severe mutation
    usually do not develop neurologic symptoms and
    signs
  • Apoptosis of oligodendrocytes that have
    inactivated healthy X chromosome occurs as in
    affected males
  • Dying cells are replaced by oligodendrocytes that
    have inactivated the abnormal X chromosome

54
Hairy ears Not Y linked
55
Y inheritance
  • The handful of characterized genes on the Y
    chromosome either participate in determining male
    phenotype or testicular function
  • Unequal exchange of a critical region of the Y
    chromosome result in karyotypically normal XX
    males or XY females (sex reversal)
  • A gene, TDF (testis determining factor, aka SRY
    for sex determining region of Yp11.3) that
    encodes a probable transcription control factor
    lies in this region
  • A cascade of genes, including TDF, participate in
    determining testicular development. Some of these
    other genes have homology to SRY and lie on
    autosomes.
  • In principal a Y linked mutation would show ONLY
    male to male transmission, however mutations of
    known Y genes cause sex reversal or male
    sterility, therefore the only cases of
    male-to-male transmission occur with autosomal
    dominant genes
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