Angelman syndrome

Angelman Syndrome
Classification and external resources
ICD-10 Q93.5
ICD-9 759.89
OMIM 105830
DiseasesDB 712
MeSH D017204

Angelman syndrome (AS) is a neuro-genetic disorder characterized by intellectual and developmental delay, sleep disturbance, seizures, jerky movements especially hand-flapping, frequent laughter or smiling, and usually a happy demeanour. AS is a classic example of genetic imprinting in that it is usually caused by deletion or inactivation of genes on the maternally inherited chromosome 15. The sister syndrome, Prader-Willi syndrome, is caused by a similar loss of paternally-inherited genes.

AS is named after a British pediatrician, Dr. Harry Angelman, who first described the syndrome in 1965.[1] An older, alternative term for AS, happy puppet syndrome, is generally considered pejorative and stigmatizing so it is no longer used, though it remains useful as a diagnostic heuristic.

People with AS are sometimes known as "Angels", both because of the syndrome's name and because of their youthful, happy appearance.

Contents

History

"Boy with a Puppet" or "A child with a drawing" by Giovanni Francesco Caroto.

Dr. Harry Angelman, a pediatrician working in Warrington (then in Lancashire) first reported three children with this condition in 1965.[1] He titled the paper "Puppet Children" and later explained that this was because of an oil painting he had seen:

"I happened to see an oil painting...called... "Boy with a Puppet". The boy's laughing face and the fact that my patients exhibited jerky movements gave me the idea of writing an article about the three children with a title of Puppet Children."[1]

The condition was initially incorrectly presumed to be rare.

In 1987, it was first noted that around half of the children with Angelman syndrome have a small piece of chromosome 15 missing (chromosome 15q partial deletion).

Prevalence

Though the prevalence of Angelman syndrome is not precisely known, there are some estimates. The best data available is from studies of school age children, ages 6-13 years, living in Sweden and from Denmark where the diagnosis of AS children in medical clinics was compared to an 8 year period of about 45,000 births. The Swedish study showed an AS prevalence of about 1/20,000[2] and the Danish study showed a minimum AS prevalence of about 1/10,000.[3] Note that it is desirable to use the term prevalence, since estimates of AS diagnosis have been made in relatively small cohorts of children over various periods of time.

Pathophysiology

Angelman.PNG

Angelman syndrome is caused by the loss of the normal maternal contribution to a region of chromosome 15, most commonly by deletion of a segment of that chromosome. Other causes include uniparental disomy, translocation, or single gene mutation in that region. A healthy person receives two copies of chromosome 15, one from the mother, the other from the father. However, in the region of the chromosome that is critical for Angelman syndrome, the maternal and paternal contribution express certain genes very differently. This is due to sex-related epigenetic imprinting; the biochemical mechanism is DNA methylation. In a normal individual, the maternal allele is expressed and the paternal allele is silenced. If the maternal contribution is lost or mutated, the result is Angelman syndrome. (When the paternal contribution is lost, by similar mechanisms, the result is Prader-Willi syndrome.) Please note that the methylation test that is performed for Angelman syndrome (a defect in UBE3A) is actually looking for the gene's neighbour SNRPN (which has the opposite pattern of methylation).[4]

Angelman syndrome can also be the result of mutation of a single gene. This gene (UBE3A,[5] part of the ubiquitin pathway) is present on both the maternal and paternal chromosomes, but differs in the pattern of methylation (Imprinting). The paternal silencing of the UBE3A gene occurs in a brain region-specific manner; the maternal allele is active almost exclusively in the hippocampus and cerebellum. The most common genetic defect leading to Angelman syndrome is an ~4Mb (mega base) maternal deletion in chromosomal region 15q11-13 causing an absence of UBE3A expression in the maternally imprinted brain regions. UBE3A codes for an E6-AP ubiquitin ligase, which chooses its substrates very selectively and the four identified E6-AP substrates have shed little light on the possible molecular mechanisms underlying the human Angelman syndrome mental retardation state.

Initial studies of mice that do not express maternal UBE3A show severe impairments in hippocampal memory formation. Most notably, there is a deficit in a learning paradigm that involves hippocampus-dependent contextual fear conditioning. In addition, maintenance of long-term synaptic plasticity in hippocampal area CA1 in vitro is disrupted in Ube3a-/- mice. These results provide links amongst hippocampal synaptic plasticity in vitro, formation of hippocampus-dependent memory in vitro, and the molecular pathology of Angelman syndrome.

Features

Diagnosis

The diagnosis of Angelman syndrome is based on:

The Angelman Syndrome Foundation, which first defined criteria for diagnosis in 1995[6], has been updated in 2005.[7]

Treatment

Because Angelman syndrome is not an illness, but a genetic condition, there is no currently available cure. The epilepsy can be controlled by the use of one or more types of anticonvulsant medications. However, there are difficulties in ascertaining the levels and types of anticonvulsant medications needed to establish control, because AS is usually associated with having multiple varieties of seizures, rather than just the one as is normal cases of epilepsy. Many families use melatonin to promote sleep in a condition which often affects sleep patterns. Many individuals with Angelman Syndrome sleep for a maximum of 5 hours at any one time. Mild laxatives are also used frequently to encourage regular bowel movements and early intervention with physiotherapy is important to encourage joint mobility and prevent stiffening of the joints. Occupational therapy, speech therapy, hydrotherapy and music therapy are also used in the management of this condition.

Living with Angelman syndrome

Although a diagnosis of AS is life changing, it does not need to be life destroying. Individuals with Angelman Syndrome are generally happy and contented individuals, who like human contact and play. AS individuals exhibit a profound desire for personal interaction with others. Communication can be difficult at first, but as an AS child develops, there is a definite character and ability to make themselves understood. It is widely accepted that their understanding of communication directed to them is much larger than their ability to return conversation. Most afflicted individuals will not develop more than 5-10 words, if at all.[8]

Actor Colin Farrell, author Ian Rankin, and professional hockey player Peter McDuffe have sons with AS.

Prognosis

Note that the severity of the symptoms associated with AS varies significantly across the population of affected persons. Some speech and a greater degree of self-care are possible among the least profoundly affected. Unfortunately, walking and the use of simple sign language may be beyond the reach of the more profoundly affected. Early and continued participation in physical, occupational (related to the development of fine-motor control skills), and communication (speech) therapies are believed to improve significantly the prognosis (in the areas of cognition and communication) of individuals affected by AS. Further, the specific genetic mechanism underlying the condition is thought to correlate to the general prognosis of the affected person. On one end of the spectrum, a mutation to the UBE3A gene is thought to correlate to the least affected, whereas larger deletions on chromosome 15 are thought to correspond to the most affected.

The clinical features of Angelman syndrome alter with age. As adulthood approaches, hyperactivity and poor sleep patterns improve. The seizures decrease in frequency and often cease altogether and the EEG abnormalities are less obvious. Medication is typically advisable to those with seizure disorders. Often overlooked is the contribution of the poor sleep patterns to the frequency and/or severity of the seizures. Medication may be worthwhile in order to help deal with this issue and improve the prognosis with respect to seizures and sleep. Also noteworthy are the reports that the frequency and severity of seizures temporarily escalate in pubescent AS girls but do not seem to affect long-term health.

The facial features remain recognizable but many adults with AS look remarkably youthful for their age.

Puberty and menstruation begin at around the normal time. Sexual development is thought to be normal, as evidenced by a single reported case of a woman with Angelman syndrome conceiving a female child who also had Angelman syndrome. [9]

The majority of those with AS achieve continence by day and some by night.

Dressing skills are variable and usually limited to items of clothing without buttons or zippers. Most adults are able to eat with a knife or spoon and fork and can learn to perform simple household tasks. General health is fairly good and life-span near normal. Particular problems which have arisen in adults are a tendency to obesity (more in females), and worsening of scoliosis[10] if it is present. The affectionate nature which is also a positive aspect in the younger children may also persist into adult life where it can pose a problem socially, but this problem is not insurmountable.

See also

References

  1. 1.0 1.1 1.2 Angelman's syndrome at Who Named It
  2. Steffenburg S, Gillberg CL, Steffenburg U, Kyllerman M (1996). "Autism in Angelman syndrome: a population-based study". Pediatr. Neurol. 14 (2): 131–6. doi:10.1016/0887-8994(96)00011-2. PMID 8703225. 
  3. Petersen MB, Brøndum-Nielsen K, Hansen LK, Wulff K (1995). "Clinical, cytogenetic, and molecular diagnosis of Angelman syndrome: estimated prevalence rate in a Danish county; the disorder predominantly affects Anglo-Saxons.". Am. J. Med. Genet. 60 (3): 261–2. doi:10.1002/ajmg.1320600317. PMID 7573182. 
  4. White HE, Durston VJ, Harvey JF, Cross NC (2006). "Quantitative analysis of SNRPN(correction of SRNPN) gene methylation by pyrosequencing as a diagnostic test for Prader-Willi syndrome and Angelman syndrome". Clin. Chem. 52 (6): 1005–13. doi:10.1373/clinchem.2005.065086. PMID 16574761. 
  5. Weeber E, Levenson J, Sweatt J (2002). "Molecular genetics of human cognition.". Mol Interv 2 (6): 376–91, 339. doi:10.1124/mi.2.6.376. PMID 14993414. 
  6. Williams CA, Angelman H, Clayton-Smith J, et al (1995). "Angelman syndrome: consensus for diagnostic criteria. Angelman Syndrome Foundation". Am. J. Med. Genet. 56 (2): 237–8. doi:10.1002/ajmg.1320560224. PMID 7625452. 
  7. Williams CA, Beaudet AL, Clayton-Smith J, et al (2006). "Angelman syndrome 2005: updated consensus for diagnostic criteria". Am. J. Med. Genet. A 140 (5): 413–8. doi:10.1002/ajmg.a.31074. PMID 16470747. 
  8. Andersen WH, Rasmussen RK, Strømme P (2001). "Levels of cognitive and linguistic development in Angelman syndrome: a study of 20 children". Logopedics, phoniatrics, vocology 26 (1): 2–9. doi:10.1080/140154301300109044. PMID 11432411. 
  9. Lossie A, Driscoll D. "Transmission of Angelman syndrome by an affected mother.". Genet Med 1 (6): 262–6. PMID 11258627. 
  10. Laan LA, den Boer AT, Hennekam RC, Renier WO, Brouwer OF (1996). "Angelman syndrome in adulthood". Am. J. Med. Genet. 66 (3): 356–60. doi:10.1002/(SICI)1096-8628(19961218)66:3<356::AID-AJMG21>3.0.CO;2-K. PMID 9072912. 

External links


Pathology: chromosome abnormalities (Q90-Q99 · 758)
Autosomal
Trisomies
Down syndrome (21) · Edwards syndrome (18) · Patau syndrome (13)
Trisomy 9 · Warkany syndrome 2 (8) · Trisomy 22/Cat eye syndrome (22) · Trisomy 16
Monosomies/deletions
Wolf-Hirschhorn syndrome (4) · Cri du chat (5) · Williams syndrome (7) · Jacobsen syndrome (11) · Miller-Dieker syndrome/Smith-Magenis syndrome (17) · 22q11.2 deletion syndrome (22)
genomic imprinting (Angelman syndrome/Prader-Willi syndrome (15))
X/Y linked
Monosomy
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other karyotypes
Klinefelter's syndrome (47,XXY) · 48,XXYY · 49,XXXXY

Triple X syndrome (47,XXX) · 48,XXXX · 49,XXXXX

47,XYY
Translocations
leukemia/lymphoma: Philadelphia chromosome t(9;22) · Burkitt's lymphoma t(8;14) · Anaplastic large cell lymphoma t(2;5) · Follicular lymphoma t(14;18) · Mantle cell lymphoma t(11:14)
other: Ewing's sarcoma t(11;22)
Gonadal dysgenesis
Mixed gonadal dysgenesis · XX gonadal dysgenesis
Other
Fragile X syndrome · Uniparental disomy
Non-Mendelian inheritance: genomic imprinting
Chromosome 15
Angelman syndrome · Prader-Willi syndrome
Chromosome 11
Beckwith-Wiedemann syndrome · Silver-Russell dwarfism