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Epilepsy
A Comprehensive Guide
Genetic Testing
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© 2020 GeneDx, Inc. All rights reserved. 40227 V2 01/20 Information current as of 01/20
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COMPREHENSIVE EPILEPSY GUIDE 1
Epilepsy
Epilepsy is a common neurological disorder that affects at least 0.8% of the population. It is defined by the occurrence of at least two unprovoked seizures occurring more than 24 hours apart. Seizures are the manifestation of abnormal hypersynchronous discharges of cortical neurons that can last for several seconds, minutes, or longer. The clinical presentation of seizures depends upon both the location of the epileptic discharges in the cortex and the extent and pattern of propagation of the electrical discharges in the brain.
Epilepsy can be an isolated neurological symptom, or it may occur as part of a more complex syndrome. There are many different causes of epilepsy, including genetic disorders, metabolic diseases, and structural brain abnormalities. However, in some cases, the cause of epilepsy is not known.
The International League against Epilepsy (ILAE) has described the underlying causes of epilepsy as the following.
• Genetic: “The concept of genetic epilepsy is that the epilepsy is, as best as understood, the direct result of a known or presumed genetic defect(s) in which seizures are the core symptoms of the disorder.”3 The genetic contribution must be evident by extensive and replicable molecular studies or familial studies, e.g., SCN1A gene has been demonstrated to be associated with generalized epilepsy with febrile seizures plus (EFS+).9
• Structural/Metabolic: There are also specific structural or metabolic disorders that have been proven in various studies to be associated with increased risk of epilepsy; the cause of epilepsy can be defined as structural or metabolic. The cause for such a disorder can be acquired (e.g., trauma, stroke, infection), genetic (e.g., malformations of cortical development) or both (e.g., West syndrome).
• Unknown: There are also cases where the underlying cause is yet unknown. Epilepsy may be caused by an unidentified genetic defect or acquired cause.
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Diagnosis
The diagnosis of epilepsy is made based on via a number of factors, including a combination of personal health history, family health history, electroencephalogram (EEG) findings and genetic testing.
In some cases these may not be recognized as a seizure by patients, their family members, or even health care professionals. Seizures can be classified into various categories in Figure 1.
FIGURE 1: Types of seizures
Other possible seizure manifestations include:
• Blank stares
• Lip smacking
• Intermittent eye movements
• Jerking movements of the extremities
Infantile Spasms 1-9%
Absence 5-22%
Generalized Tonic-Clonic 12-24%
Myoclonic 1-11%Other Generalized
<1-3%
Unclassified/Mixed 4-43%
Complex Partial 8-31%
Simple Partial 2-12%
Other Partial 7-29%
Clinical Presentation/Course
In many cases, seizures result in convulsions and loss of consciousness. Seizures may also manifest in other ways that affect personality, mood, memory, sensation, and/or movement.
COMPREHENSIVE EPILEPSY GUIDE 3
Normal EEG (9yr-old child)
Modified hypsarrhythmia during sleep in patient with infantile spasms (8mo-old infant)
Generalized spike wave in patient with absence epilepsy (3yr-old child)
A detailed clinical history also may help clarify potential triggers and diurnal patterns related to seizure events. The medical history will help to determine if the seizures are isolated or part of a larger syndrome. In addition to clinical history for the affected individual, a family medical history should be obtained, including any history of seizures and other neurodevelopmental disorders in any relatives. This information may help clarify the type of epilepsy in a family, including the mode of inheritance and the prognosis.
Electroencephalogram (EEG)
Children with a known or suspected diagnosis of epilepsy based on clinical and family history should undergo an EEG to help
FIGURE 2: Typical EEG abnormalities for different types of seizures
Clinical and Family History
The detailed clinical history may help confirm that the seizure events are in fact epileptic seizures, rather than non-epileptic events such as fainting, breath-holding, transient ischemic attacks, strokes, arrhythmias, or hypoglycemia, all of which can manifest similarly to epileptic seizures.
confirm the seizure type and to evaluate recurrence risk for future seizures. An EEG may also provide important information for making treatment decisions (Figure 2).
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Physical Examination
In some cases, an individual with epilepsy may have other related neurological abnormalities, medical problems, or dysmorphic features that can be identified by physical examination. For example, many genetic syndromes involving epilepsy also cause developmental delay, hypotonia, birth defects, ataxia, dystonia, microcephaly or macrocephaly, dysmorphic facial features, or other features that can be noted in a physical examination.
Genetic Testing
A genetic etiology underlies epilepsy in approximately 40% of individuals.1 Genes have been identified that cause both generalized seizures and focal seizures, as well as unclassified epilepsy types such as infantile spasms. A genetic etiology is identified most often in individuals who have severe, early-onset seizures, seizures in conjunction with other neurodevelopmental symptoms, and/or in individuals whom seizures are refractory to treatment.
The genetic etiology of idiopathic generalized epilepsy (IGE) is frequently complex because it is due to a combination of multiple genetic factors that each confer a small risk for epilepsy and may be modified by environmental influences.1 Currently, approximately 2% of patients with IGE harbor an identifiable pathogenic variant in a single gene associated with Mendelian inheritance of epilepsy.10 However, the percentage of patients with inherited identifiable genetic forms of epilepsy is higher for specific epilepsy types such as infantile spasms, benign familial neonatal and neonatal-infantile seizures (BFNS and BFNIS), generalized epilepsy with febrile seizures plus (GEFS+), Lafora disease, and others.1,2,7,11,12
The information obtained from clinical and family histories, physical examination, and EEG can help a clinician determine whether genetic testing should be offered to a patient with epilepsy and which specific genetic test(s) may be appropriate.2
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Genetic Heterogeneity
The inheritance pattern can be autosomal dominant, autosomal recessive, or X-linked. Variants in a single gene may be associated with different types of seizures (clinical heterogeneity), and conversely, variants in different genes can cause the same epilepsy phenotype (genetic heterogeneity). In many cases, children with severe, early-onset seizures may harbor a de novo variant not inherited from either parent.13
The last decade has witnessed the discovery of many genes involved in epilepsy. Most of these genes are expressed in the brain and encode subunits of ion channels that play vital roles in stabilizing or propagating neuronal activity. Disruption of these genes in general induces neuronal hyperexcitability, thus causing seizures. As described above, there are many forms of epilepsy. A single gene may be associated with different forms of epilepsy, but one type of epilepsy may also result from defects in any one of a variety of genes.5 Examples of monogenic causes of epilepsy are pyridoxine-dependent epilepsy and neuronal ceroid lipofuscinoses (NCL). In some cases, copy number variations associated with neuropsychiatric disorders can be involved in epilepsy also. It is well known that the 1p36 microdeletion, Wolf-Hirshhorn, Miller-Dieker, Pallister-Killian, and Angelman syndromes include epilepsy as a major feature, but these disorders also involve various other clinical features as well.2
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COMPREHENSIVE EPILEPSY GUIDE 7
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Clinical Indications
1. Diagnostic testing in an individual with epilepsy
a. Confirm a clinical diagnosis of a specific genetic syndrome or type of epilepsy
b. Distinguish between syndromic and non-syndromic forms of epilepsy
c. Establish the genetic cause of idiopathic epilepsy
d. Provide information about prognosis
2. Assistance with selection of optimal treatment options
3. Predictive testing for asymptomatic family members of a proband with a known pathogenic variant associated with a genetic form of epilepsy
a. Enable clinical monitoring, follow-up, and optimal treatment when symptoms develop in an individual with a positive result
b. Reduce anxiety and forego clinical monitoring if result is negative
4. Prenatal diagnosis in at-risk pregnancies for known, pathogenic variants
5. Genetic counseling, recurrence risk determination, and family planning
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Test Name Genes TAT
EpiXpanded Panel (Trio-based test)
1000+ Genes (please see website for a full gene list)
6 weeks
Epilepsy Del/Dup Panel (95 Genes)
ADSL, ALDH7A1, ALG13, ARHGEF9, ARID1B, ARX, ATP1A2, ATP6AP2, ATRX, CACNA1A, CASK, CDKL5, CHD2, CHRNA2, CHRNA4, CHRNA7, CHRNB2, CLN3, CLN5, CLN6, CLN8, CNTNAP2, CREBBP, CSTB, CTSD, DNAJC5, DYRK1A, EEF1A2, EHMT1, EPM2A, FOLR1, GABRA1, GABRB2, GABRB3, GABRG2, GAMT, GATM, GOSR2, GRIN1, GRIN2A, GRIN2B, HNRNPU, IQSEC2, KANSL1, KCNB1, KCNJ10, KCNQ2, KCNQ3, KCNT1, KCTD7, LGI1, MAGI2, MBD5, MECP2, MEF2C, MFSD8, NHLRC1, NR2F1, NRXN1, OPHN1, PCDH19, PHF6, PIGA, PIGO, PIGV, PLCB1, PNKP, PNPO, POLG, PPT1, PRICKLE1, PRRT2, QARS, SCARB2, SCN1A, SCN1B, SCN2A, SCN8A, SLC13A5, SLC25A22, SLC2A1, SLC9A6, SMC1A, SPTAN1, STXBP1, SYNGAP1, TBC1D24, TCF4, TPP1 (CLN2), TSC1, TSC2, UBE3A, WDR45, WWOX, ZEB2
4 weeks
Comprehensive Epilepsy Panel (87 Genes)
ADSL, ALDH7A1, ALG13, ARHGEF9, ARX, ATP1A2, ATP6AP2, CACNA1A, CDKL5, CHD2, CHRNA2, CHRNA4, CHRNA7, CHRNB2, CLN3, CLN5, CLN6, CLN8, CNTNAP2, CSTB, CTSD, DNAJC5, DNM1, DYRK1A, EEF1A2, EPM2A, FOLR1, FOXG1, GABRA1, GABRB2, GABRB3, GABRG2, GAMT, GATM, GOSR2, GRIN1, GRIN2A, GRIN2B, IQSEC2, KANSL1, KCNB1, KCNJ10, KCNQ2, KCNQ3, KCNT1, KCTD7, LGI1, MAGI2, MBD5, MECP2, MEF2C, MFSD8, NHLRC1, NR2F1, NRXN1, PCDH19, PIGA, PIGO, PIGV, PNKP, PNPO, POLG, PPT1, PRICKLE1, PRRT2, QARS, SCARB2, SCN1A, SCN1B, SCN2A, SCN8A, SLC13A5, SLC25A22, SLC2A1, SLC6A8, SLC9A6, SPTAN1, STXBP1, TBC1D24, TCF4, TPP1 (CLN2), TSC1, TSC2, UBE3A, WDR45, WWOX, ZEB2
4 weeks
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Test Options
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Test Name Genes TATSTAT Epilepsy Panel (22 Genes)
ALDH7A1, ARX, CDKL5, FOLR1, KCNQ2, KCNQ3, KCNT1, MECP2, MEF2C, PCDH19, PNPO, POLG, SCN1A, SCN1B, SCN2A, SCN8A, SLC2A1, SLC6A8, SPTAN1, STXBP1, TSC1, TSC2
2 weeks
Infantile Epilepsy Panel (75 Genes)
ADSL, ALDH7A1, ALG13, ARHGEF9, ARX, ATP6AP2, CACNA1A, CDKL5, CHD2, CHRNA7, CLN3, CLN5, CLN6, CLN8, CNTNAP2, CTSD, DNM1, DYRK1A, EEF1A2, FOLR1, FOXG1, GABRA1, GABRB2, GABRB3, GABRG2, GAMT, GATM, GRIN1, GRIN2A, GRIN2B, IQSEC2, KANSL1, KCNB1, KCNJ10, KCNQ2, KCNQ3, KCNT1, KCTD7, MAGI2, MBD5, MECP2, MEF2C, MFSD8, NR2F1, NRXN1, PCDH19, PIGA, PIGO, PIGV, PNKP, PNPO, POLG, PPT1, PRRT2, QARS, SCN1A, SCN1B, SCN2A, SCN8A, SLC13A5, SLC25A22, SLC2A1, SLC6A8, SLC9A6, SPTAN1, STXBP1, TBC1D24, TCF4, TPP1 (CLN2), TSC1, TSC2, UBE3A, WDR45, WWOX, ZEB2
4 weeks
Childhood Epilepsy Panel (58 Genes)
ADSL, CACNA1A, CDKL5, CHD2, CHRNA2, CHRNA4, CHRNA7, CHRNB2, CLN3, CLN5, CLN6, CLN8, CNTNAP2, CSTB, CTSD, DYRK1A, EEF1A2, EPM2A, FOLR1, FOXG1, GABRA1, GABRB2, GABRB3, GABRG2, GAMT, GATM, GOSR2, GRIN1, GRIN2A, IQSEC2, KANSL1, KCNT1, KCTD7, LGI1, MAGI2, MBD5, MECP2, MEF2C, MFSD8, NHLRC1, NRXN1, PCDH19, PNKP, POLG, PPT1, PRICKLE1, SCN1A, SCN1B, SCN2A, SLC2A1, SLC6A8, SLC9A6, TBC1D24, TCF4, TPP1 (CLN2), UBE3A, WDR45, ZEB2
4 weeks
Progressive Myoclonic Epilepsy Panel (17 Genes)
CLN3, CLN5, CLN6, CLN8, CSTB, CTSD, DNAJC5, EPM2A, FOLR1, GOSR2, KCTD7, MFSD8, NHLRC1, PPT1, PRICKLE1, SCARB2, TPP1
4 weeks
Test Options
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Additional testing options are available, including targeted variant testing for a previously identified pathogenic or likely pathogenic variant. Appropriate test selection depends on the specific clinical history of a patient, including family and personal health histories as well as familial test results. Testing for most genes includes sequencing and deletion/duplication analysis via next-generation sequencing and/or exon array testing.
Test Name Genes TATRett/Angelman Syndrome Panel (12 Genes)
CDKL5, CNTNAP2, FOXG1, MBD5, MECP2, MEF2C, NRXN1, SLC9A6, TCF4, UBE3A, WDR45, ZEB2
4 weeks
Tuberous Sclerosis Panel (2 Genes)
TSC1, TSC2 4 weeks
Test Options
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Sample Submission
Genetic testing can be performed on blood, oral rinse or extracted DNA samples. GeneDx test kits are available to ordering providers, and include sample collection items (such as mouthwash, collection tubes), the necessary sample submission paperwork, and a self-addressed return shipping label.
Additionally all, test requisition forms are available for download from the GeneDx website: www.genedx.com/forms
Please note that all testing must be performed under the guidance of a healthcare provider. For more information on the sample submission process, please visit our website: www.genedx.com/supplies or email us at: [email protected]
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COMPREHENSIVE EPILEPSY GUIDE 13
Genetic Test Results
Nearly all test results fall into one of four categories:
1. Positive (pathogenic variant(s) identified)
2. Likely pathogenic variant(s) identified
3. Variant(s) of uncertain significance (VUS) identified
4. Negative (no variants of clinical significance identified)
GeneDx test reports contain detailed information about a specific genetic result and, if available, medical management options. Genetic counseling is recommended prior to genetic testing to understand the benefits and limitations of testing and after genetic testing to discuss the implications of the genetic test results. Genetic counseling services across the country can be found at www.nsgc.org
Positive Result
A positive result indicates a pathogenic (disease-causing) genetic variant (change) was identified in a specific disease gene. This finding confirms an underlying genetic cause for the patient’s symptoms and provides a diagnosis of a specific genetic disorder or indicates an increased risk for developing a genetic disorder. Knowledge of the specific pathogenic variant(s) provides valuable information to the patients, their healthcare providers and family members because it helps to determine the recurrence risk and to develop an appropriate medical management plan. A medical management plan may include lifestyle modifications, ongoing screening, preventative medications and measures, and/or surgical/medical device interventions. Furthermore, a positive genetic test result allows targeted testing of at-risk relatives to determine if any of them carry the pathogenic variant(s) as well as to address the recurrence risk of the disorder in future offspring.
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Likely Pathogenic Result
A likely pathogenic result indicates the presence of genetic variant(s) in a specific disease gene for which there is significant, but not conclusive, evidence that the variant(s) are disease-causing. This finding strongly suggests an underlying genetic cause of the patient’s disorder or indicates an increased risk for developing a genetic disorder. With this type of result, medical management options and testing of family members are often similar as described above for a positive result.
Variant of Uncertain Significance (VUS)
A variant of uncertain significance (VUS) result indicates an inconclusive outcome of a genetic test. A VUS is a change in a gene for which the association with disease cannot be clearly established. The available information for the variant is either insufficient or conflicting, and it cannot be determined at this time whether the variant is associated with a specific genetic disorder or if the variant is a unrelated (benign) variant unrelated to the patient’s disorder.
In the case of a VUS test result, all medical management recommendations should be based on clinical symptoms, and past personal and family history. Predictive genetic testing of family members for a VUS is not indicated. Nevertheless, in some circumstances, it can be useful to test other family members through our Variant Testing Program to gain more evidence about the variant itself and its possible association with disease. Over time, additional clinical evidence may be collected about certain VUS, which could ultimately lead to the reclassification of the variant and test result.
Negative Result
A negative result indicates that the genetic test did not identify reportable, medically relevant variant(s) in any of the genes tested. Therefore, the cause for the patient’s disorder or family history remains unknown. Although the patient’s disorder may be caused by non-genetic factors, a negative genetic test result does not completely rule out an underlying genetic cause. For example, the patient’s disorder may be due to unidentified genetic changes in gene regions or genes not included in the initial test. Depending on the patient’s personal and family health history, additional genetic testing may be indicated for the patient or another family
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Epilepsy Genes with Treatment Implications
GeneDisorder/Syndrome
Treatment Implications
Panels
ALDH7A1 Pyridoxine-dependent epilepsy Folinic-acid responsive seizures
Supplemental vitamin B6 and/or folinic acid treatment
Comprehensive, Infantile, STAT, EpiXpanded & Epi Del/Dup panels
CSTB Unverricht-Lundborg disease
Avoid sodium channel blockers and GABAergic drugs, which can increase myoclonus, dementia, and ataxia
Comprehensive, Childhood, Progressive Myoclonic Epilepsy, EpiXpanded & Epi Del/Dup panels
EPM2A, EPM2B, (NHLRC1)
Lafora disease Avoid phenytoin, lamotrigine, carbamazepine, and oxcarbazepine
Comprehensive, Childhood, Progressive Myoclonic Epilepsy, EpiXpanded & Epi Del/Dup panels
member. A genetic specialist or other healthcare providers can determine if further genetic testing is appropriate.
In case of a negative genetic test result, all medical management recommendations should be based on clinical symptoms in addition to past personal and family history. Predictive genetic testing of family members is not available.
When an individual tests negative for a familial pathogenic variant that was previously identified in another affected family member, this is considered a ‘true’ negative test result. In most cases, this means that the individual has no greater risk for developing the specific genetic disorder that runs in the family than anyone in the general population.
Medical Management
The treatment of epilepsy depends upon the type of seizure, age of the patient, and other factors. Knowledge of the genetic etiology of epilepsy may guide selection of the most appropriate treatment options in some cases. A number of antiepileptic medications are used in the treatment of epilepsy. The specific type and etiology of seizures may influence the selection of antiepileptic medication for each patient.
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GeneDisorder/Syndrome
Treatment Implications
Panels
FOLR1 Cerebral folate deficiency
Supplemental folinic acid treatment
Comprehensive, STAT, Infantile, Childhood, Progressive Myoclonic Epilepsy, EpiXpanded & Epi Del/Dup panels
GAMT, GATM
Creatine deficiency syndromes
Oral creatine (GAMT, AGAT)
Comprehensive, Infantile, Childhood, EpiXpanded & Epi Del/Dup panels
KCNQ2 KCNQ2-related disorders
Carbamazepine and phenytoin
Comprehensive, STAT, Infantile, EpiXpanded & Epi Del/Dup panels
KCNT1 KCNT1-related disorders
Cardiac Screening. Consider treatment with quinidine
Comprehensive, STAT, Infantile, Childhood, EpiXpanded & Epi Del/Dup panels
PNPO Pyridoxal 5’-phosphate dependent epilepsy
Supplemental pyridoxal 5-phosphate (PLP)
Comprehensive, STAT, Infantile, EpiXpanded & Epi Del/Dup panels
POLG Alpers-Huttenlocher and other POLG-related disorders
Avoid valproic acid, which can induce or accelerate liver disease
Comprehensive, STAT, Infantile, Childhood, EpiXpanded & Epi Del/Dup panels
SCN1A Dravet syndrome and other SCN1A-related disorders
Valproate, clobazam, stiripentol, levetiracetam, topiramate, and avoid phenytoin, carbamazepine, and lamotrigine
Comprehensive, STAT, Infantile, Childhood, EpiXpanded & Epi Del/Dup panels
SLC2A1 Glucose transporter type 1 deficiency syndrome
Seizures typically respond to a ketogenic diet
Comprehensive, STAT, Infantile, Childhood, EpiXpanded & Epi Del/Dup panels
TSC1, TSC2
Tuberous sclerosis complex
Vigabatrin for infantile spasms
Comprehensive, STAT, TSC, Infantile, Childhood, EpiXpanded & Epi Del/Dup panels
Epilepsy Genes with Treatment Implications Cont.
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Implications for Family Members
Regardless of the result, patients should share their test report with their blood relatives, who can then discuss the results with their healthcare providers. Sharing a copy of the test result with family members and healthcare providers will help to determine if additional testing is necessary and will ensure that the proper test is ordered for relatives, if indicated.
For positive or likely pathogenic test results in autosomal dominant conditions, first-degree relatives (including parents, siblings, and children) have a 50% chance to have the same variant. The risk for other family members to carry the variant depends on how closely related they are to the person with a positive or likely pathogenic test result. It is important to remember that for most of these genes, not all people who inherit a pathogenic or likely pathogenic variant will experience seizures due to reduced penetrance.
In cases where the gene is associated with an autosomal recessive condition, an individual inherits two pathogenic variants, one from each parent. Siblings of the individual with seizures have a 25% chance to inherit both pathogenic variants and develop epilepsy.
Genetic Counseling
Prior to genetic testing, patients should speak with their healthcare provider and/or a genetics specialist about their personal and family health history. Healthcare providers should discuss the benefits and limitations of testing, as well as possible test results. These conversations help to determine if the patient is an appropriate candidate for testing, facilitate the ordering of appropriate test(s) and ensure that the patient has agreed to the proposed genetic testing (written informed consent).
If pathogenic variant(s) have already been identified in a family member, testing of the specific variant(s) is appropriate. If no pathogenic variant(s) are known in a family with a specific genetic disorder, an affected family member with the highest likelihood of a positive test outcome (an individual manifesting associated clinical symptoms) is ideally the best person for initial testing within a family. In instances when an affected family member is not available, testing of an unaffected family member may be
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considered, although a negative test result will not guarantee that the unaffected individual does not have an increased risk to develop the clinical symptoms that are present in the family.
Once a patient makes the decision to undergo genetic testing, post-test genetic counseling is recommended to understand the implications of the results, including a discussion of the appropriate medical management based on both the test results and the patient’s medical and family history. Genetic counseling services across the country can be found at www.nsgc.org
Insurance Coverage and Cost for Genetic Testing
GeneDx accepts all commercial insurance plans and is a Medicare provider. Additionally, GeneDx is a registered provider with several Medicaid plans. If a patient does not have health insurance coverage or cannot afford to pay the cost of testing, GeneDx offers a financial assistance program to help ensure that all patients have access to medically necessary genetic testing.
For more information on the paperwork that is required by some insurance carriers, as well as additional details on patient billing and our financial assistance program, please visit our website: www.genedx.com/billing
Genetic Information Nondiscrimination Act
The Genetic Information Nondiscrimination Act of 2008, also referred to as GINA, is a federal law that protects Americans from discrimination by health insurance companies and employers based on their genetic information. However, this law does not cover life insurance, disability insurance, or long-term care insurance. GINA’s employment protections do not extend to individuals in the U.S. military, federal employees, Veterans Health Administration and Indian Health Service. Some of these organizations may have internal policies to address genetic discrimination. For more information, please visit: http://genome.gov/10002328
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Genetic Testing Process
Healthcare provider discusses the test results, medical management options, and implications for family members with the patient
The patient’s sample and necessary paperwork are sent to the laboratory
Genetic Test Results
Post-Test Discussion
Sample Submission
Genetic Testing
Discussion of personal and family history
Explanation of genetic testing options
At the laboratory, genetic testing for most genes includes next-generation sequenc-ing and/or exon array analysis
Contains information on the results of the genetic test and available medical management options
The final report is sent to the ordering healthcare provider
Patient Identification
Patient Name: SAMPLE, EpilepsyDate of Birth: Not ProvidedSpecimen Type: Blood in EDTASubmitters ID No: NoneOrdered By: Dr. Neurology Genetics
Test(s) requested: Comprehensive Epilepsy Panel / Sequencing and Deletion/Duplication Analysis of 53 Genes
Test Indication(s): Epileptic encephalopathy.
Result: POSITIVE
Gene Variant Zygosity Classification
STXBP1 Partial gene deletion, exons 6-8
Heterozygous Disease-causing mutation
No other reportable variants were detected by sequencing and deletion/duplication analysis of the 53 genes included on this panel.
Interpretation: This individual is heterozygous for a partial deletion of the STXBP1 gene, which is consistent with the diagnosis of epileptic encephalopathy.
STXBP1 partial deletion: Intragenic deletion including exons 6-8 of the STXBP1 gene [transcript NM_003165.2]. Genomic coordinates: chr9:130414231-130417633 [hg19/GRCh37]
This individual is heterozygous for a partial deletion of the STXBP1 gene that includes exons 6-8. Both partial and complete STXBP1 gene deletions have been identified in patients with epilepsy (Boone et al., 2010; Saitsu et al., 2010; Milh et al., 2011; Mignot et al., 2011). The presence of the deletion is consistent with the diagnosis of epileptic encephalopathy in this individual.
Mutations in the STXBP1 gene have been identified in patients with early infantile epileptic encephalopathy, also called Ohtahara syndrome. Most individuals with STXBP1 mutations exhibit clonic spasms with a suppression-burst pattern on EEG, intractable seizures, and severe intellectual disability (Saitsu et al., 2008; Mignot et al., 2011). Some individuals with STXBP1 mutations have been reported with myoclonic seizures, hypomyelination or delayed myelination, and/or a non-epileptic movement disorder characterized by tremor, dystonic posturing, or choreaform movements (Saitsu et al., 2010; Saitsu et al., 2008; Milh et al., 2011). More recently, STXBP1 mutations have been identified in patients with isolated intellectual disability or intellectual disability and nonsyndromic epilepsy (Hamdan et al., 2011; Hamdan et al., 2009). Mutations in the STXBP1 gene are inherited in autosomal dominant manner and are typically de novo, although inheritance of a mutation from an unaffected parent with somatic mosaicism has been reported (Saitsu et al., 2011).
Recommendation: 1. Testing for the partial deletion in the STXBP1 gene is available to the parents of this child to determine if the deletion was inherited or arose de novo. If desired, molecular prenatal diagnosis is available to at-risk family members to address the recurrence risk.
2. Genetic counseling is recommended to discuss the implications of this test report, specifically including the risk of recurrence for this family and testing options for other at-risk family members.
Neurogenetic Test ReportComprehensive Epilepsy Panel
GeneDx Accession No: MockTest015Date Specimen Obtained: Not ProvidedDate Specimen Received: 3/9/2012Date Test(s) Started: 3/9/2012Date of Report: 4/11/2012
Page 1 of 2 GeneDx - 207 Perry Parkway - Gaithersburg, MD 20877 - Tel (301) 519-2100 - Fax (301) 519-2892 - www.genedx.com
an OPKO Health Company
Gene
Patient Name: PROVIDED, Not
Date of Birth: Not Provided
Specimen Type: Other: Validation Test
Submitters ID No: None
Ordered By:GENEDX - VALIDATION TESTS
Test(s) Requested:Diagnostic Testing / Sequence Analysis of 2000 Genes / Autism/ID Xpanded Panel
Relevant History:Female with reported history of autism spectrum disorder, developmental delay, and seizures.
A sample from this individual's mother (GeneDx# 0000001) and father (GeneDx# 0000002) were also submitted for
variant segregation analysis.
Result:POSITIVE
GeneDisease
Mode of
InheritanceVariant Coding DNA Zygosity
Inherited
From
Classification
WDR45 Neurodegeneration
with brain iron
accumulation
X-linked p.Q16X c.46 C>T Heterozygous DeNovo
Variant of
Uncertain
Significance
Interpretation:This individual is heterozygous for a pathogenic variant in the WDR45 gene. This gene is associated with an
X-linked disorder. This result is consistent with the diagnosis of neurodegeneration with brain iron
accumulation.
WDR45 Summary: The WDR45 gene encodes one of the WD repeat proteins, which form multi-protein complexes involved in signal
transduction, transcriptional regulation, autophagy and cell cycle control (Haack et al., 2012). De novo pathogenic
variants in the X-linked WDR45 gene cause neurodegeneration with brain iron accumulation (NBIA) (Haack et al.,
2012). The clinical features are similar in males and females, including early-onset global developmental delay with
static encephalopathy in childhood followed by adolescent or adult onset of dystonia, parkinsonism, and dementia
(Haack et al., 2012; Saitsu et al., 2013). Approximately 50% of patients with pathogenic WDR45 variants have
epilepsy (Nishioka et al., 2015). The clinical features in childhood may overlap with Rett syndrome (Ohba et al.,
2014; Hayflick et al., 2013).
WDR45 p.Q16X:p.Gln16Ter (CAA>TAA): c.46 C>T in exon 3 in the WDR45 gene (NM_007075.3). For this gene, [93.40]% of the
coding region was covered at a minimum of 10x by the Autism/ID Xpanded Panel.
This individual's mother (GeneDx# 0000001) and father (GeneDx# 0000002) do not harbor the Q16X variant in the
WDR45 gene.
A pathogenic variant has been identified in the WDR45 gene. The Q16X nonsense variant is predicted to cause loss
of normal protein function either through protein truncation or nonsense-mediated mRNA decay. It was not observed
in approximately 6,500 individuals of European and African American ancestry in the NHLBI Exome Sequencing
Project, indicating it is not a common benign variant in these populations. Although this pathogenic variant has not
been reported previously to our knowledge, its presence is consistent with the diagnosis of neurodegeneration with
brain iron accumulation (NBIA) in this individual.
Genetic Testing Report
GeneDx Accession No: 9910000
Date Specimen Obtained: Not Provided
Date Specimen Received: 12/11/2015
Date Test(s) Started: 3/7/2016
Date of Report:3/22/2016
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Resources
GeneDx neurology page: www.genedx.com/neurology
GeneReviews, a database of genetic diseases: www.geneclinics.org
National Society of Genetic Counselors, to help you find a counselor near you: www.nsgc.org
American Epilepsy Society: www.aesnet.org
Epilepsy Foundation: www.epilepsyfoundation.org
COMPREHENSIVE EPILEPSY GUIDE 21
References1. Pong, et al. Developments in molecular genetic diagnostics: An update
for the pediatric epilepsy specialist, Pediatr Neurol (2011) 44:317-327.
2. Pal, et al. Genetic evaluation and counseling for epilepsy. Nat Rev Neurol (2010) 6:445-453.
3. Berg, et al. Revised terminology and concepts for organization of seizures and epilepsies: Report of the ILAE Commission on Classification and Terminology, 2005-2009. Epilepsia (2010) 51: 676-685.
4. Deprez, et al. Genetics of epilepsy syndromes starting in the first year of life. Neurology (2009) 72:273-281.
5. Baulac, S and Baulac, M. Advances on the genetics of Mendelian idiopathic epilepsies. Neurol Clin (2009) 27:1041-1061.
6. Macdonald, et al. Mutations in GABAA receptor subunits associated with genetic epilepsies. J Physiol (2010) 588:1861-1869.
7. Ottman, et al. Genetic testing in the epilepsies – Report of the ILAE Genetics Commission. Epilepsia (2010) 51:655-670.
8. Ramachandran, et al. The autosomal recessively inherited progressive myoclonus epilepsies and their genes. Epilepsia (2009) 50:29-36.
9. Steinlein, et al. Genetic mechanisms that underlie epilepsy. Nat Rev Neurosci (2004) 5:401-408.
10. Weber et al., (2008) Dev Med Child Neurol 50:648-654.
11. Nicita et al., (2011) Seizure: Eur J Epilepsy doi:10.1016/j.seizure.2011.08.007
12. Wirrell et al. (2015) Epilepsia 56 (4):617-25
13. Allen et al. (2013) Nature 501 (7466):217-21
About GeneDx
GeneDx was founded in 2000 by two scientists from the National Institutes of Health (NIH) to address the needs of patients diagnosed with rare disorders and the clinicians treating these conditions. Today, GeneDx has grown into a global industry leader in genomics, having provided testing to patients and their families in over 55 countries. Led by its world-renowned clinical genomics program, and an unparalleled comprehensive genetic testing menu, GeneDx has a continued expertise in rare and ultra-rare disorders. Additionally, GeneDx also offers a number of other genetic testing services, including: diagnostic testing for hereditary cancers, cardiac, mitochondrial, and neurological disorders, prenatal diagnostics, and targeted variant testing. At GeneDx, our technical services are backed by our unmatched scientific expertise and our superior customer support. Our growing staff includes more than 35 geneticists and 140 genetic counselors specializing in clinical genetics, molecular genetics, metabolic genetics, and cytogenetics who are just a phone call or email away to assist you with your questions and testing needs. We invite you to visit our website: www.genedx.com to learn more about us.
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