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{{WBRQuestion
{{WBRQuestion
|QuestionAuthor=William J Gibson
|QuestionAuthor=William J Gibson (Reviewed by  {{YD}} and  {{Rim}})
|ExamType=USMLE Step 1
|ExamType=USMLE Step 1
|MainCategory=Genetics
|MainCategory=Genetics
Line 8: Line 8:
|MainCategory=Genetics
|MainCategory=Genetics
|SubCategory=General Principles
|SubCategory=General Principles
|MainCategory=Genetics
|MainCategory=Genetics
|MainCategory=Genetics
|MainCategory=Genetics
|MainCategory=Genetics
Line 20: Line 21:
|MainCategory=Genetics
|MainCategory=Genetics
|SubCategory=General Principles
|SubCategory=General Principles
|Prompt=A 4 year old boy in Brazil has immigrated to the United States with his family.  His mother reports that the boy has begun bumping into furniture very often, and has concerns that his vision may be compromised. She shows you an image in which the pupil of his left eye has a bright reflection due to the camera flash. Upon further questioning, it is revealed that the boy’s father underwent surgery at a young age, leaving him blind in both eyes. The offending lesion is surgically removed and the tissue analyzed for molecular genetic features. Chromosome 13 displays a normal karyotype. A set of common single nucleotide polymorphisms on chromosome 13q is profiled and the resulting SNP identities are displayed below. Assume all of the SNPs have an allelic fraction in the general population of approximately 50%. The RB1 gene spans positions positions 48,934,153-48,951,170 on chromosome 13. Which of the following molecular events most likely occurred in the boy’s somatic tissues to cause his condition?
|Prompt=A 4-year-old boy is brought by his mother to the physician's office for an immigration medical exam. He has recently immigrated with his family from Brazil to the United States.  His mother reports that the boy has begun bumping into furniture very often; she has concerns that his vision may be compromised. She shows you an image in which the pupil of his left eye has a bright whitish reflection due to the camera flash. Upon further questioning, it is revealed that the boy’s father underwent surgery at a young age, leaving him blind in both eyes. Two days later, the offending lesion is surgically removed and the tissue is analyzed for molecular genetic features. Chromosome 13 displays a normal karyotype. A set of common single nucleotide polymorphisms (SNPs) on chromosome 13q is profiled and the resulting SNP identities are displayed below. Assume all of the SNPs have an allelic fraction in the general population of approximately 50%. The ''RB1'' gene spans positions 48,934,153 to 48,951,170 on chromosome 13. Which of the following molecular events most likely occurred in the boy’s somatic tissues to cause his condition?


<table>
<table>
Line 50: Line 51:
<tr><td>rs6562010</td><td>13</td><td>59711493</td><td>TT</td></tr>
<tr><td>rs6562010</td><td>13</td><td>59711493</td><td>TT</td></tr>
</table>
</table>
|Explanation=The patient in this vignette has familial retinoblastoma, a rapidly developing cancer that develops from the immature cells of a retina, caused by defects in the Retinoblastoma gene on chromosome 13. Children often have germline mutations in the retinoblastoma protein which can be passed down to descendents. The retinoblastoma protein functions as a tumor suppressor, and therefore the sole germline mutation acts as a recessive trait at the cellular level. A “second hit” which alters the remaining wildtype allele in somatic tissues is required for the initiation of tumorigenesis. In this case, we have clear evidence of mitotic recombination in which the maternal chromosome 13 has been replaced by the paternal alleles after rs111033222. Thus, the cell which inherits both paternal alleles has no wildtype retinoblastoma protein and will go on to form a tumor.  Familial retinoblastoma functions as an autosomal dominant trait, as the probability of a second hit in somatic tissues is certain due to the number of cells in the developing retina.  Patients with familial retinoblastoma have an increased risk of other tumors such as osteosarcomas.
|Explanation=Familial [[retinoblastoma]] is a highly penetrant autosomal dominant disorder that is considered the most common intraocular tumor of childhood. It is a rapidly developing cancer that originates from the immature cells of the retina, caused by defects in the retinoblastoma gene on [[chromosome 13]]. Most patients present with leukocoria (white pupillary reflex) before the age of 4 years, but other symptoms include strabismus (deviating eyes), unilateral/bilateral decreased visual acuity, retinal detachment, glaucoma, pain, or even hypopyon (cancer cells in the anterior chamber of the eye).  
 
Retinoblastoma is in fact inherited by an autosomal recessive trait at the cellular level. Nonetheless, it is classified as an autosomal dominant because unlike normal patients, patients with one mutant allele are considered to be predisposed to the development of retinoblastoma due to the decreased function of retinoblastom, a tumor suppressor that regulates cellular division. Thus, predisposition to the disease requires 1 mutant allele, but expressing the disease require 2 mutant alleles. Retinoblastoma may be classified as either somatic or germline. In somatic cases, the retinoblastoma locus of both alleles is mutated within one retinal cell leading to the development of a unilateral retinoblastoma (60% of cases). In contrast, germline mutations may occur and patients develop bilateral lesions because ''RB'' genes are mutated in every cell, as observed in cases of familial retinoblastoma or Li-Fraumeni syndrome. Patients with retinoblastoma due to germline mutations have an increased risk of other non-ocular tumors such as [[osteosarcoma]], [[pinealoma]], and [[melanoma]].
 
The patient in this vignette must have received one mutant allele of the ''RB1'' gene from his father and one wild-type allele from his mother. The patient must have had a "loss of heterozygosity" event in his left retina. ''RB'' gene follows the classical Knudson's two-hit hypothesis. A sole germline mutation acts as a recessive trait at the cellular level. A “second hit”, which alters the remaining wild type allele in [[somatic tissues]], is required for the initiation of tumorogenesis. In the case presented in the vignette, there is clear evidence of mitotic recombination in which the maternal chromosome 13 has been replaced by the paternal alleles after rs2044732. Thus, the cell which inherits both paternal alleles has no wild-type retinoblastoma protein and will go on to form a tumor.


<img src='http://static.wikidoc.org/f/f6/WJG_Mitotic_recombination_figure_copy.svg' height='500px'>
<br>
|AnswerA=Mutation
|AnswerA=Mutation
|AnswerAExp=While a de novo mutation causing a “second hit” to the retinoblastoma gene is possible, there is no evidence that this has occurred. The SNPs above clearly show recombination on chromosome 13, making loss of heterozygosity most likely.
|AnswerAExp=While a de novo mutation causing a “second hit” to the ''[[RB]]'' gene is possible, there is no evidence that this has occurred. The SNPs clearly show recombination on chromosome 13, making loss of heterozygosity more likely.
|AnswerB=Gene Deletion
|AnswerB=Gene deletion
|AnswerBExp=While a deletion of the wild type allele of the Rb gene could cause the “second hit” to the Rb gene, the normal karyotype of chromosome 13 makes this possibility less likely.
|AnswerBExp=While a deletion of the wild type allele of the ''RB'' gene could cause the “second hit” to the ''RB'' gene, the normal karyotype of chromosome 13 makes this possibility less likely.
|AnswerC=Mitotic recombination
|AnswerC=Mitotic recombination
|AnswerCExp=Note that all of the SNPs after rs2044732 are homozygous.   
|AnswerCExp=Note that all of the SNPs after rs2044732 are homozygous. Since there are two copies of chromosome 13 remaining from the [[karyotype]], the only possibilities for the presence of homozygous rs2044732 are either the child is homozygous for all of these [[alleles]] in the germline or chromosome 13q underwent mitotic recombinationPossibility 1 is unlikely, because as was stated in the question prompt, all of these alleles have an allelic fraction of around 50%. Additionally, the probability of 15 consecutive homozygous alleles is (0.5)^15 = 0.00003, making this hypothesis very unlikely.
|AnswerD=Gene duplication
|AnswerD=Gene duplication
|AnswerDExp=There is no evidence for duplication of the RB gene, and such a duplication would not be expected to cause a retinoblastoma tumor.
|AnswerDExp=There is no evidence for duplication of the ''RB'' gene, and such a duplication would not be expected to cause a [[retinoblastoma]] tumor.
|AnswerE=Methylation
|AnswerE=Methylation
|AnswerEExp=While methylation is responsible for silencing genes, methylation is most associated with Prader-Willi syndrome and Angelman syndrome. There is no evidence for gene methylation in this question, but there is clear evidence of mitotic recombination leading to loss of heterozygosity.
|AnswerEExp=While [[methylation]] is responsible for silencing genes, methylation is most associated with [[Prader-Willi syndrome]] and [[Angelman syndrome]]. There is no evidence for gene methylation in this question, but there is clear evidence of mitotic recombination leading to loss of heterozygosity.
|EducationalObjectives=Loss of heterozygosity is a common mechanism for the "second-hit" in tumor suppressor gene inactivation.
|EducationalObjectives=Loss of heterozygosity is a common mechanism for the "second-hit" in tumor suppressor gene inactivation.
|References=First Aid 2014 page 84  
|References=Abramson DH, Mendelsohn ME, Servodidio CA, et al. Familial retinoblastoma: where and when? Acta Ophthalmol Scand. 2003;76(3):334-8<br>O'Brien JM. Retinoblastoma: clinical presentation and the role of neuroimaging. AJNR Am J Neuroradiol. 2001;22(3):426-8<br>First Aid 2014 page 84<br>Knudson AG. Mutation and cancer: statistical study of retinoblastoma. Proc Natl Acad Sci USA. 1971;68(4):820-3.
|RightAnswer=C
|RightAnswer=C
|WBRKeyword=Cancer, Genetics, Tumor suppressor, Retinoblastoma, Tumor,
|WBRKeyword=Cancer, Genetics, Tumor suppressor, Retinoblastoma, Tumor, Cell division, Recombination, Cancer, Childhood cancer
|Approved=Yes
|Approved=Yes
}}
}}

Latest revision as of 23:20, 27 October 2020
Author [[PageAuthor::William J Gibson (Reviewed by Yazan Daaboul, M.D. and Rim Halaby, M.D. [1])]]
Exam Type ExamType::USMLE Step 1
Main Category MainCategory::Genetics
Sub Category SubCategory::General Principles
Prompt [[Prompt::A 4-year-old boy is brought by his mother to the physician's office for an immigration medical exam. He has recently immigrated with his family from Brazil to the United States. His mother reports that the boy has begun bumping into furniture very often; she has concerns that his vision may be compromised. She shows you an image in which the pupil of his left eye has a bright whitish reflection due to the camera flash. Upon further questioning, it is revealed that the boy’s father underwent surgery at a young age, leaving him blind in both eyes. Two days later, the offending lesion is surgically removed and the tissue is analyzed for molecular genetic features. Chromosome 13 displays a normal karyotype. A set of common single nucleotide polymorphisms (SNPs) on chromosome 13q is profiled and the resulting SNP identities are displayed below. Assume all of the SNPs have an allelic fraction in the general population of approximately 50%. The RB1 gene spans positions 48,934,153 to 48,951,170 on chromosome 13. Which of the following molecular events most likely occurred in the boy’s somatic tissues to cause his condition?
SNP IDChromosomeGenomic PositionGenotype
rs47710541327562342CC
rs176265531328968770CT
rs27769611330101280GT
rs1444300401331085367CC
rs49417311333568060GG
rs95285331334588335CT
rs95486441339720610AA
rs93158031341623184GT
rs96347671342270305CT
rs20447321342833400AG
rs175360021343035209TT
rs116195281344826355TT
rs128664731346037501CC
rs14130771347875303AA
rs73298651349154165AA
rs8959671349347566GG
rs21912261350940143AA
rs49430031352090383GG
rs4761361353413498GG
rs105075811354154463GG
rs95916321355611511CC
rs48859621356863954AA
rs25928661358226942GG
rs14116451359052343CC
rs65620101359711493TT
]]
Answer A AnswerA::Mutation
Answer A Explanation [[AnswerAExp::While a de novo mutation causing a “second hit” to the RB gene is possible, there is no evidence that this has occurred. The SNPs clearly show recombination on chromosome 13, making loss of heterozygosity more likely.]]
Answer B AnswerB::Gene deletion
Answer B Explanation AnswerBExp::While a deletion of the wild type allele of the ''RB'' gene could cause the “second hit” to the ''RB'' gene, the normal karyotype of chromosome 13 makes this possibility less likely.
Answer C AnswerC::Mitotic recombination
Answer C Explanation [[AnswerCExp::Note that all of the SNPs after rs2044732 are homozygous. Since there are two copies of chromosome 13 remaining from the karyotype, the only possibilities for the presence of homozygous rs2044732 are either the child is homozygous for all of these alleles in the germline or chromosome 13q underwent mitotic recombination. Possibility 1 is unlikely, because as was stated in the question prompt, all of these alleles have an allelic fraction of around 50%. Additionally, the probability of 15 consecutive homozygous alleles is (0.5)^15 = 0.00003, making this hypothesis very unlikely.]]
Answer D AnswerD::Gene duplication
Answer D Explanation [[AnswerDExp::There is no evidence for duplication of the RB gene, and such a duplication would not be expected to cause a retinoblastoma tumor.]]
Answer E AnswerE::Methylation
Answer E Explanation [[AnswerEExp::While methylation is responsible for silencing genes, methylation is most associated with Prader-Willi syndrome and Angelman syndrome. There is no evidence for gene methylation in this question, but there is clear evidence of mitotic recombination leading to loss of heterozygosity.]]
Right Answer RightAnswer::C
Explanation [[Explanation::Familial retinoblastoma is a highly penetrant autosomal dominant disorder that is considered the most common intraocular tumor of childhood. It is a rapidly developing cancer that originates from the immature cells of the retina, caused by defects in the retinoblastoma gene on chromosome 13. Most patients present with leukocoria (white pupillary reflex) before the age of 4 years, but other symptoms include strabismus (deviating eyes), unilateral/bilateral decreased visual acuity, retinal detachment, glaucoma, pain, or even hypopyon (cancer cells in the anterior chamber of the eye).

Retinoblastoma is in fact inherited by an autosomal recessive trait at the cellular level. Nonetheless, it is classified as an autosomal dominant because unlike normal patients, patients with one mutant allele are considered to be predisposed to the development of retinoblastoma due to the decreased function of retinoblastom, a tumor suppressor that regulates cellular division. Thus, predisposition to the disease requires 1 mutant allele, but expressing the disease require 2 mutant alleles. Retinoblastoma may be classified as either somatic or germline. In somatic cases, the retinoblastoma locus of both alleles is mutated within one retinal cell leading to the development of a unilateral retinoblastoma (60% of cases). In contrast, germline mutations may occur and patients develop bilateral lesions because RB genes are mutated in every cell, as observed in cases of familial retinoblastoma or Li-Fraumeni syndrome. Patients with retinoblastoma due to germline mutations have an increased risk of other non-ocular tumors such as osteosarcoma, pinealoma, and melanoma.

The patient in this vignette must have received one mutant allele of the RB1 gene from his father and one wild-type allele from his mother. The patient must have had a "loss of heterozygosity" event in his left retina. RB gene follows the classical Knudson's two-hit hypothesis. A sole germline mutation acts as a recessive trait at the cellular level. A “second hit”, which alters the remaining wild type allele in somatic tissues, is required for the initiation of tumorogenesis. In the case presented in the vignette, there is clear evidence of mitotic recombination in which the maternal chromosome 13 has been replaced by the paternal alleles after rs2044732. Thus, the cell which inherits both paternal alleles has no wild-type retinoblastoma protein and will go on to form a tumor.



Educational Objective: Loss of heterozygosity is a common mechanism for the "second-hit" in tumor suppressor gene inactivation.
References: Abramson DH, Mendelsohn ME, Servodidio CA, et al. Familial retinoblastoma: where and when? Acta Ophthalmol Scand. 2003;76(3):334-8
O'Brien JM. Retinoblastoma: clinical presentation and the role of neuroimaging. AJNR Am J Neuroradiol. 2001;22(3):426-8
First Aid 2014 page 84
Knudson AG. Mutation and cancer: statistical study of retinoblastoma. Proc Natl Acad Sci USA. 1971;68(4):820-3.]]

Approved Approved::Yes
Keyword WBRKeyword::Cancer, WBRKeyword::Genetics, WBRKeyword::Tumor suppressor, WBRKeyword::Retinoblastoma, WBRKeyword::Tumor, WBRKeyword::Cell division, WBRKeyword::Recombination, WBRKeyword::Cancer, WBRKeyword::Childhood cancer
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