Difference between revisions of "Genetics2"

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==Etiology==
 
==Etiology==
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<table border = 1 cellpadding = 5 style="float:right;background-color:#BFEFFF; border:2px solid black; text-align:center;">
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<tr><th colspan=2><b>Want more information about a<br>specific gene or gene group? Pick one of the categories below!</b></th></tr>
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<tr><td><b>[[Cadherins]]</b></td><td><b>[[Neuroligins/Neurexins/Shank3]]</b></td></tr><tr><td><b>[[MET]]</b></td><td><b>[[CNVs]]</b></td></tr>
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<tr><td><b>[[ERK and P13K]]</b></td><td><b>[[Ubiquitin]]</b></td></tr><tr><td><b>[[RELN]]</b></td><td><b>[[Neurotrophins]]</b></td></tr>
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<tr><td><b>[[CNTNAP-2]]</b></td><td><b>[[Serotoninergic, GABAergic, and glutamatergic pathways|Serotoninergic, GABAergic,<br>and glutamatergic pathways]]</b></td></tr><tr><td><b>[[EIF4E]]</b></td><td><b>[[PTEN]]</b></td></tr>
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<tr><td><b>[[Neurotrophins]]</b></td><td><b>[[Oxytocin and AVP]]</b></td></tr>
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<tr><td><b>[[Cav1.2]]</b></td><td><b>[[NCAM2]]</b></td></tr>
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<tr><td><b>[[PLAUR]]</b></td><td><b>[[Caveolin-1]]</b></td></tr>
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</table>
  
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<br><br><br>
 
Recent studies have suggested that ASD in families where multiple members are affected by autistic traits may be caused more by genetic predisposition.  In contrast, ASD in families where only one member displays autistic traits are more likely to be caused by rare gene mutations which have a large effect or by copy number variations.  One way of studying this difference is by comparing autistic traits in unaffected family members from multiplex autism families to simplex autism families.<sup>5</sup>
 
Recent studies have suggested that ASD in families where multiple members are affected by autistic traits may be caused more by genetic predisposition.  In contrast, ASD in families where only one member displays autistic traits are more likely to be caused by rare gene mutations which have a large effect or by copy number variations.  One way of studying this difference is by comparing autistic traits in unaffected family members from multiplex autism families to simplex autism families.<sup>5</sup>
  
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Endophenotypes can help genetic studies by defining more etiologically homogenous subgroups.  Furthermore, endophenotypes are measurable in both affected and control groups, thus allowing for larger sample sizes.  Language phenotypes such as the age at which the child speaks their first word, are very promising endophenotypes because they show significant linkage in many samples and the support has been lent at implicating the 7q region to this language development, thereby raising hypothesis that the 7q region is home to other loci that are associated with the autism language phenotype<sup>3</sup>.  
 
Endophenotypes can help genetic studies by defining more etiologically homogenous subgroups.  Furthermore, endophenotypes are measurable in both affected and control groups, thus allowing for larger sample sizes.  Language phenotypes such as the age at which the child speaks their first word, are very promising endophenotypes because they show significant linkage in many samples and the support has been lent at implicating the 7q region to this language development, thereby raising hypothesis that the 7q region is home to other loci that are associated with the autism language phenotype<sup>3</sup>.  
  
'''Copy-Number Variation'''
 
CNVs in certain dosage sensitive genes have been suggested as the root cause of ASD.  This theory is particularly appealing because CNVs have a high locus-specific rate of new nucleotide mutations, 3-4 times the rate for single nucleotide polymorphisms. Additionally, CNVs can account for the phenotypic variation seen in ASD. The type of copy number rearrangement and whether it was inherited maternally or paternally can further affect the phenotype.  For example, duplications of chromosome 15q11-q13 that are derived maternally confers a high risk of ASD (>85%) while those inherited paternally have anywhere from no phenotypic affects to mild developmental and cognitive impairment.  There is relative enrichment within CNVs for neuronal synaptic complex genes, particularly SHANK3, NLGN4, and NRXN1. However, it is difficult to know right now how harmful a particular inherited CNV will be because the extent of the CNV and what genes are included, as well as which geens are nearby can influence the phenotypes.  Specifically, other genes can modulate the risk of genes that normally confer genes, and other genes can even act protectively to decrease the risk of developing a particular genetic disease<sup>4</sup>. 
 
  
Some likely candidate genes that have been explored include
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Some areas of investigation include
<table border = 1 cellpadding = 5>
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<tr style="background-color:#87CEFA;"><th>Gene</th><th>Function</th><th>Location</th><th>source</th></tr>
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<tr><td>UBE3A</td><td>transcribed protein is an enzyme that works in protein degradation</td><td>15q11-q13</td><td>PMID 18414403</td></tr>
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#[[Methylation]]
<tr><td>GABRB3</td><td>encodes a member of of a ligand gated ionic channels responsible for inhibition in nervous system</td><td>15q11-q12</td><td>PMID 18414403</td></tr>
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#[[Copy-Number Variation]]
<tr><td>MET</td><td>encodes receptor tyrosine kinase involved in neuroal growth and organization, immunological and gastrointestinal functioning</td><td>7q31</td><td> PMID 18716561</td></tr>
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#[[Micro-RNA]]
<tr><td>SLC6A4</td><td>serotonin transporter</td><td>17q11</td><td>PMID 18716561</td></tr>
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<tr><td>RELN</td><td>encodes protein that controls intercellular interactions involved in neuronal migration and positioning in brain development</td><td>7q22</td><td>PMID 18716561</td></tr>
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<tr><td>CNTNAP2</td><td>part of neurexin superfamily, encodes CASPR2, a transmembrane scaffolding protein </td><td>7q35-q36</td><td>PMID 18179894</td></tr></table>
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<div style="float:right; padding:10px; background:yellow; border:2px solid black;font-size:large;"><b>[[Autism Spectrum Disorders| Main Page]]</b></div>
 
  
<div style="float:left; padding:10px; background:yellow; border:2px solid black;font-size:large;"><b>[[Genetics| Back]]</b></div>
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<div style="float:right; padding:10px; background:yellow; border:2px solid black;font-size:large;"><b>[[:Category:Welcome| Home Page]]</b></div>
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<div style="float:left; padding:10px; background:yellow; border:2px solid black;font-size:large;"><b>[[:Category:Genes|Back]]</b></div>
 
<br><br><br>
 
<br><br><br>
 
===Analytical Techniques===
 
===Analytical Techniques===
 
*[[QTL mapping]]
 
*[[QTL mapping]]
 
====Citations====
 
====Citations====
1. Schmitz C. Autism: neuropathology, alterations of the GABAergic system, and animal models.Int Rev Neurobiol. 2005;71:1-26. PMID 16512344
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See [[Citations_Genes2]]
 
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<br><br><br>
2. Jones, J.R. et. al. Hypothesis: Dysregulation of Methylation of Brain-Expressed Genes on the X Chromosome and Autism Spectrum Disorders. ''American Journal of Medical Genetics Part A'' 146A:2213-2220 (2008). PMID 18698615
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[[Category:Genes]]
 
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3. Lush, Molly et. al. Current Developments in the Genetics of Autism: From Phenome to Genome. ''J Neuropathol Exp Neurol. 2008 September; 67(9):829-837. PMID 18716561
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4. Cook, E.H. and S. W. Scherer. Copy-number variations associated wtih neuropsychiatric conditions. Nature.2008 October;455(16) 919-23. PMID 18923514
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5. Hoekstra RA, et. al. Autistic traits in simplex and multiplex autism families: Focus on unaffected relatives.Am J Med Genet B Neuropsychiatr Genet. 2010 Jan 5;153B(1):356-8. PMID 19367575
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Latest revision as of 11:32, 16 May 2011

Etiology

Want more information about a
specific gene or gene group? Pick one of the categories below!
CadherinsNeuroligins/Neurexins/Shank3
METCNVs
ERK and P13KUbiquitin
RELNNeurotrophins
CNTNAP-2Serotoninergic, GABAergic,
and glutamatergic pathways
EIF4EPTEN
NeurotrophinsOxytocin and AVP
Cav1.2NCAM2
PLAURCaveolin-1




Recent studies have suggested that ASD in families where multiple members are affected by autistic traits may be caused more by genetic predisposition. In contrast, ASD in families where only one member displays autistic traits are more likely to be caused by rare gene mutations which have a large effect or by copy number variations. One way of studying this difference is by comparing autistic traits in unaffected family members from multiplex autism families to simplex autism families.5

Linkage and Association Studies

Successful linkage studies in the past have been mostly based on affected sibling-pair designs in multiplex families. However, there were no genome wide significant results probably because of small effect sizes that were a result of any single gene. Even large scale studies showed only minor overlap, likely because of variety of phenotypes in ASD. Recently though, use of endophenotypes and QTL mapping have increased the power of linkage and association studies.

Endophenotypes can help genetic studies by defining more etiologically homogenous subgroups. Furthermore, endophenotypes are measurable in both affected and control groups, thus allowing for larger sample sizes. Language phenotypes such as the age at which the child speaks their first word, are very promising endophenotypes because they show significant linkage in many samples and the support has been lent at implicating the 7q region to this language development, thereby raising hypothesis that the 7q region is home to other loci that are associated with the autism language phenotype3.


Some areas of investigation include

  1. Methylation
  2. Copy-Number Variation
  3. Micro-RNA


Home Page
Back




Analytical Techniques

Citations

See Citations_Genes2