Entry - #194072 - WILMS TUMOR, ANIRIDIA, GENITOURINARY ANOMALIES, AND IMPAIRED INTELLECTUAL DEVELOPMENT SYNDROME; WAGR - OMIM

 
ICD+
# 194072

WILMS TUMOR, ANIRIDIA, GENITOURINARY ANOMALIES, AND IMPAIRED INTELLECTUAL DEVELOPMENT SYNDROME; WAGR


Alternative titles; symbols

WILMS TUMOR, ANIRIDIA, GENITOURINARY ANOMALIES, AND MENTAL RETARDATION SYNDROME
WAGR SYNDROME
CHROMOSOME 11p13 DELETION SYNDROME


Cytogenetic location: 11p13   Genomic coordinates (GRCh38) : 11:31,000,001-36,400,000


Gene-Phenotype Relationships
Location Phenotype Phenotype
MIM number 		Inheritance Phenotype
mapping key
11p13 Wilms tumor, aniridia, genitourinary anomalies and impaired intellectual development syndrome 194072 AD, SMu 4
Clinical Synopsis
 

INHERITANCE
- Autosomal dominant
- Somatic mutation
GROWTH
Weight
- Obesity
HEAD & NECK
Eyes
- Aniridia
GENITOURINARY
External Genitalia (Male)
- Hypospadias
Internal Genitalia (Male)
- Cryptorchidism
Internal Genitalia (Female)
- Uterine malformations
Kidneys
- Nephroblastoma (Wilms tumor)
- Renal failure
NEUROLOGIC
Central Nervous System
- Mental retardation
NEOPLASIA
- Nephroblastoma (Wilms tumor)
MISCELLANEOUS
- Contiguous gene syndrome
MOLECULAR BASIS
- Caused by microdeletions of 11p13
- Caused by mutations in the Wilms tumor 1 gene (WT1, 607102.0001).
▲ Close

TEXT

A number sign (#) is used with this entry because the WAGR syndrome is a contiguous gene syndrome due to deletion, either microscopic or submicroscopic, at chromosome 11p13 in a region containing the WT1 (607102) and PAX6 (607108) genes.

A subphenotype of WAGR including obesity (WAGRO) has been associated with haploinsufficiency for the BDNF gene (113505) and is discussed in 612469.

Clinical Features

Miller et al. (1964) first described the association of aniridia, hemihypertrophy, and other congenital anomalies with Wilms tumor. The syndrome subsequently became known as the WAGR syndrome. In addition to 'genitourinary abnormalities,' the 'G' in WAGR syndrome may refer to 'ambiguous genitalia' (Riccardi et al., 1978) or 'gonadoblastoma' (Anderson et al., 1978).

Riccardi et al. (1978) observed a triad of aniridia, ambiguous genitalia, and mental retardation (AGR triad) in 3 patients with an interstitial deletion of the short arm of chromosome 11. One patient also had Wilms tumor.

Among 6 cases of aniridia, Francke et al. (1978) showed that Wilms tumor was not present in all cases: monozygotic twins had aniridia and mental retardation, but only 1 had Wilms tumor, and only 1 of the other 4 patients had Wilms tumor. The deleted segment common to all was the distal half of 11p13.

Anderson et al. (1978) described aniridia, cataract, gonadoblastoma, and mental retardation in a girl with an interstitial deletion of the short arm of chromosome 11. Gonadoblastoma occurs as part of the WAGR complex (Junien et al., 1980; Turleau et al., 1981).

In a report that focused on the aniridia component of the WAGR syndrome, Gilgenkrantz et al. (1982) analyzed the reported cases of aniridia with interstitial del(11)p. They reported a unique observation of hypertrophic cardiomyopathy in association with aniridia and catalase (CAT; 115500) deficiency in a patient with del(11)(p15.1p12). Riccardi et al. (1982) reported a patient with Wilms tumor and iris dysplasia, not aniridia. In the UK, Shannon et al. (1982) found the incidence of aniridia in cases of Wilms tumor to be 1 in 43. A survey detected 8 living and 3 dead children with Wilms tumor and aniridia. All 8 living children had deletion of 11p13. A high incidence of bilateral Wilms tumor (36%), male sex, early presentation, and advanced maternal age were features of the combined cases. Among 49 children with Wilms tumor without aniridia, only 1 had bilateral renal tumors.

Using high resolution chromosome banding, Marshall et al. (1982) studied 14 patients with aniridia. Seven were familial and had normal chromosomes; of 7 sporadic cases, 1 showed normal chromosomes and 6 had interstitial deletion of 11p of various lengths. Band 11p13 was included in the deletion in all 6 cases.

Little et al. (1993) suggested that the severe nephropathy associated with Denys-Drash syndrome (194080), which frequently leads to early renal failure, may result from the action of altered WT1 in blocking the normal activity of the wildtype protein. In contrast, because of the less severe genital anomalies and apparent lack of nephropathy associated with WAGR, a reduced WT1 dosage during embryogenesis is thought to have a less pronounced effect on development, especially on that of the renal system.

Breslow et al. (2000) reviewed nearly 6,000 patients enrolled in 4 clinical trials of the U. S. National Wilms Tumor Study Group between 1969 and 1995 who were followed until death or for a median of 11.0 years of survival for the onset of renal failure. Of 22 patients with Denys-Drash syndrome, 13 developed renal failure; of 46 patients with WAGR, 10 developed renal failure. The cumulative risks of renal failure at 20 years were 62% and 38%, respectively. The findings suggested that nephropathy is not associated uniquely with missense mutations in the WT1 gene and that patients with Wilms tumor and aniridia or genitourinary abnormalities should be followed closely throughout life for signs of nephropathy.

WAGR Syndrome with Atypical Eye Findings

Kawase et al. (2001) reported a case of WAGR syndrome with atypical eye findings. The boy presented at 1 month of age with microphthalmos bilaterally, microcornea and corneal cyst in the right eye, and corneal opacity (consistent with Peters anomaly) and absent anterior chamber in the left eye. Electroretinogram was normal in the right eye and subnormal in the left eye, suggesting retinal dysfunction. The child was found to have bilateral Wilms tumors at age 3 years. He also had undescended testes and mental retardation. Chromosome analysis revealed deletion of chromosome 11p15.1-p13.


Cytogenetics

Puissant et al. (1988) reported a patient with WAGR and a de novo reciprocal translocation 46,XY,t(5;11)(q11;p13). On Southern blot analysis, the gene encoding catalase had been deleted, but the gene encoding the beta subunit of follicle-stimulating hormone (FSHB) was intact. Evidence from studies of balanced translocations and other observations had suggested that the genitourinary dysplasia, like aniridia, was due to a separate gene in close proximity to the WT1 gene in band 11p13 (Bickmore et al., 1989; Glaser et al., 1989). By HRAS1-selected chromosome transfer, Porteous et al. (1987) defined 10 distinct regions of the short arm of chromosome 11, 5 of which subdivided band 11p13. They also mapped 2 independent 11p13 translocation breakpoints to within the smallest region of overlap defined by the WAGR deletions. One came from a patient with familial aniridia and the second from a patient with Potter facies and genitourinary dysplasia (urethral and ureteral atresia and bilateral cryptorchidism). Porteous et al. (1987) raised the question of whether Wilms tumor and genitourinary dysplasia are alternative manifestations of mutations at the same locus. A separate gene coding for genitourinary dysplasia (symbolized GUD) was also suggested by Bonetta et al. (1989), who found that the deletion breakpoint of a translocation t(11;2)(p13;p11) in a patient with Potter facies and genitourinary dysplasia mapped to the same 225-kb pulsed field gel electrophoresis fragment as did the fragment deleted in Wilms tumor. However, van Heyningen et al. (1990) suggested that the Wilms tumor gene itself may be responsible for abnormalities of genitourinary development in WAGR as a pleiotropic effect. The suggestion was based on the observations that the tumor predisposition and the genitourinary malformations map to precisely the same area and that the WT candidate gene shows expression in both the developing kidney and gonads. That there is no GUD gene separate from the WT1 gene is supported by the fact that the Denys-Drash syndrome (nephropathy, Wilms tumor, and genital anomalies; 194080) is caused by specific point mutations in the WT1 gene (e.g., 607102.0003).


Diagnosis

Apparent close linkage of the region determining the WAGR syndrome to the catalase locus (CAT; 115500) means that assay of catalase activity could usefully indicate those cases of new-mutation aniridia that should have surveillance for the development of renal or gonadal tumors (Junien et al., 1980).


Molecular Genetics

In WAGR syndrome, aniridia is due to the PAX6 gene, whereas the other features are probably due to the WT1 gene.

Animal Model

AGR syndrome is a subgroup of WAGR syndrome in which patients do not develop Wilms tumor and is associated with deletion of chromosome 11p14.1-p13, where the LGR4 gene (GPR48; 606666) is located. Yi et al. (2014) found that mice lacking Lgr4 had aniridia, polycystic kidney disease, genitourinary abnormalities, and mental retardation, similar to the pathologic defects of AGR syndrome. Inactivation of Lgr4 significantly increased apoptosis and decreased expression of multiple genes involved in development of WAGR syndrome-related organs. Yi et al. (2014) proposed that LGR4 is a candidate gene for the pathogenesis of AGR syndrome.


REFERENCES

  1. Anderson, S. R., Geertinger, P., Larsen, H.-W., Mikkelsen, M., Parving, A., Vestermark, S., Warburg, M. Aniridia, cataract and gonadoblastoma in a mentally retarded girl with deletion of chromosome 11: a clinicopathological case report. Ophthalmologica 176: 171-177, 1978. [PubMed: 613291, related citations] [Full Text]

  2. Bickmore, W. A., Porteous, D. J., Christie, S., Seawright, A., Fletcher, J. M., Maule, J. C., Couillin, P., Junien, C., Hastie, N. D., van Heyningen, V. CpG islands surround a DNA segment located between translocation breakpoints associated with genitourinary dysplasia and aniridia. Genomics 5: 685-693, 1989. [PubMed: 2556343, related citations] [Full Text]

  3. Bonetta, L., Huang, A., Gregoris, M., Yeger, H., Williams, B. R. G. Characterization of a homozygous deletion mapping to the Wilms tumor region on 11p13. (Abstract) Cytogenet. Cell Genet. 51: 965 only, 1989.

  4. Breslow, N. E., Takashima, J. R., Ritchey, M. L., Strong, L. C., Green, D. M. Renal failure in the Denys-Drash and Wilms' tumor-aniridia syndromes. Cancer Res. 60: 4030-4032, 2000. [PubMed: 10945603, related citations]

  5. Francke, U., Riccardi, V. M., Hittner, H. M., Borges, W. Interstitial del(11p) as a cause of the aniridia-Wilms tumor association: band localization and a heritable basis. (Abstract) Am. J. Hum. Genet. 30: 81A, 1978.

  6. Gilgenkrantz, S., Vigneron, C., Gregoire, M. J., Pernot, C., Raspiller, A. Association of del(11)(p15.1p12), aniridia, catalase deficiency, and cardiomyopathy. Am. J. Med. Genet. 13: 39-49, 1982. [PubMed: 6127950, related citations] [Full Text]

  7. Glaser, T., Jones, C. A., Lewis, W. H., Call, K., Rose, E. A., Buckler, A., Ito, C., Housman, D. E. The ultrafine structure of the WAGR gene complex. (Abstract) Cytogenet. Cell Genet. 51: 1005 only, 1989.

  8. Junien, C., Turleau, C., de Grouchy, J., Said, R., Rethore, M.-O., Tenconi, R., Dufier, J. L. Regional assignment of catalase (CAT) gene to band 11p13: association with the aniridia-Wilms' tumor-gonadoblastoma (WAGR) complex. Ann. Genet. 23: 165-168, 1980. [PubMed: 6252821, related citations]

  9. Kawase, E., Tanaka, K., Honna, T., Azuma, N. A case of atypical WAGR syndrome with anterior segment anomaly and microphthalmos. Arch. Ophthal. 119: 1855-1856, 2001. [PubMed: 11735802, related citations]

  10. Little, M. H., Williamson, K. A., Mannens, M., Kelsey, A., Gosden, C., Hastie, N. D., van Heyningen, V. Evidence that WT1 mutations in Denys-Drash syndrome patients may act in a dominant-negative fashion. Hum. Molec. Genet. 2: 259-264, 1993. [PubMed: 8388765, related citations] [Full Text]

  11. Marshall, L. S., Qureshi, A. R., DiGeorge, A. M., Kistenmacher, M. L., Punnett, H. H. Aniridia and the 11p13 deletion. (Abstract) Am. J. Hum. Genet. 34: 74A, 1982.

  12. Miller, R. W., Fraumeni, J. F., Jr., Manning, M. D. Association of Wilms' tumor with aniridia, hemihypertrophy and other congenital malformations. New Eng. J. Med. 270: 922-927, 1964. [PubMed: 14114111, related citations] [Full Text]

  13. Porteous, D. J., Bickmore, W., Christie, S., Boyd, P. A., Cranston, G., Fletcher, J. M., Gosden, J. R., Rout, D., Seawright, A., Simola, K. O. J., van Heyningen, V., Hastie, N. D. HRAS1-selected chromosome transfer generates markers that colocalize aniridia- and genitourinary dysplasia-associated translocation breakpoints and the Wilms tumor gene within band 11p13. Proc. Nat. Acad. Sci. 84: 5355-5359, 1987. [PubMed: 3037545, related citations] [Full Text]

  14. Puissant, H., Azoulay, M., Serre, J.-L., Piet, L., Junien, C. Molecular analysis of a reciprocal translocation t(5;11)(q11;p13) in a WAGR patient. Hum. Genet. 79: 280-282, 1988. [PubMed: 2841227, related citations] [Full Text]

  15. Riccardi, V. M., Hittner, H. M., Strong, L. C., Fernbach, D. J., Lebo, R., Ferrell, R. E. Wilms tumor with aniridia/iris dysplasia and apparently normal chromosomes. J. Pediat. 100: 574-577, 1982. [PubMed: 6278119, related citations] [Full Text]

  16. Riccardi, V. M., Sujansky, E., Smith, A. C., Francke, U. Chromosomal imbalance in the aniridia--Wilms' tumor association: 11p interstitial deletion. Pediatrics 61: 604-610, 1978. [PubMed: 208044, related citations]

  17. Shannon, R. S., Mann, J. R., Harper, E., Harnden, D. G., Morten, J. E. N., Herbert, A. Wilms's tumour and aniridia: clinical and cytogenetic features. Arch. Dis. Child. 57: 685-690, 1982. [PubMed: 6289758, related citations] [Full Text]

  18. Turleau, C., de Grouchy, J., Dufier, J. L., Phuc, L. H., Schmelck, P. H., Rappaport, R., Nihoul-Fekete, C., Diebold, N. Aniridia, male pseudohermaphroditism, gonadoblastoma, mental retardation, and del 11p13. Hum. Genet. 57: 300-306, 1981. [PubMed: 6114032, related citations]

  19. van Heyningen, V., Bickmore, W. A., Seawright, A., Fletcher, J. M., Maule, J., Fekete, G., Gessler, M., Bruns, G. A. P., Huerre-Jeanpierre, C., Junien, C., Williams, B. R. G., Hastie, N. D. Role for the Wilms tumor gene in genital development? Proc. Nat. Acad. Sci. 87: 5383-5386, 1990. [PubMed: 1973540, related citations] [Full Text]

  20. Yi, T., Weng, J., Siwko, S., Luo, J., Li, D., Liu, M. LGR4/GPR48 inactivation leads to aniridia-genitourinary anomalies-mental retardation syndrome defects. J. Biol. Chem. 289: 8767-8780, 2014. [PubMed: 24519938, images, related citations] [Full Text]


Contributors:
Paul J. Converse - updated : 10/22/2015
Victor A. McKusick - updated : 4/26/2005
Jane Kelly - updated : 4/19/2002
Victor A. McKusick - updated : 1/17/2002
Victor A. McKusick - updated : 9/29/2000
Creation Date:
Victor A. McKusick : 4/6/1994
Edit History:
carol : 12/22/2022
carol : 12/19/2022
carol : 12/18/2022
mgross : 10/22/2015
terry : 8/18/2009
terry : 8/18/2009
carol : 7/22/2009
carol : 12/24/2008
alopez : 12/11/2008
carol : 9/9/2008
carol : 8/29/2008
carol : 8/29/2008
tkritzer : 4/29/2005
terry : 4/26/2005
ckniffin : 8/26/2002
mgross : 4/19/2002
mgross : 4/19/2002
ckniffin : 3/12/2002
carol : 1/31/2002
mcapotos : 1/22/2002
terry : 1/17/2002
mcapotos : 10/9/2000
terry : 10/6/2000
mcapotos : 10/6/2000
terry : 9/29/2000
alopez : 7/31/1997
carol : 4/6/1994

# 194072

WILMS TUMOR, ANIRIDIA, GENITOURINARY ANOMALIES, AND IMPAIRED INTELLECTUAL DEVELOPMENT SYNDROME; WAGR


Alternative titles; symbols

WILMS TUMOR, ANIRIDIA, GENITOURINARY ANOMALIES, AND MENTAL RETARDATION SYNDROME
WAGR SYNDROME
CHROMOSOME 11p13 DELETION SYNDROME


SNOMEDCT: 4135001, 715215007;   ORPHA: 893;   DO: 14515;  


Cytogenetic location: 11p13   Genomic coordinates (GRCh38) : 11:31,000,001-36,400,000


Gene-Phenotype Relationships

Location Phenotype Phenotype
MIM number 		Inheritance Phenotype
mapping key
11p13 Wilms tumor, aniridia, genitourinary anomalies and impaired intellectual development syndrome 194072 Autosomal dominant; Somatic mutation 4

TEXT

A number sign (#) is used with this entry because the WAGR syndrome is a contiguous gene syndrome due to deletion, either microscopic or submicroscopic, at chromosome 11p13 in a region containing the WT1 (607102) and PAX6 (607108) genes.

A subphenotype of WAGR including obesity (WAGRO) has been associated with haploinsufficiency for the BDNF gene (113505) and is discussed in 612469.

Clinical Features

Miller et al. (1964) first described the association of aniridia, hemihypertrophy, and other congenital anomalies with Wilms tumor. The syndrome subsequently became known as the WAGR syndrome. In addition to 'genitourinary abnormalities,' the 'G' in WAGR syndrome may refer to 'ambiguous genitalia' (Riccardi et al., 1978) or 'gonadoblastoma' (Anderson et al., 1978).

Riccardi et al. (1978) observed a triad of aniridia, ambiguous genitalia, and mental retardation (AGR triad) in 3 patients with an interstitial deletion of the short arm of chromosome 11. One patient also had Wilms tumor.

Among 6 cases of aniridia, Francke et al. (1978) showed that Wilms tumor was not present in all cases: monozygotic twins had aniridia and mental retardation, but only 1 had Wilms tumor, and only 1 of the other 4 patients had Wilms tumor. The deleted segment common to all was the distal half of 11p13.

Anderson et al. (1978) described aniridia, cataract, gonadoblastoma, and mental retardation in a girl with an interstitial deletion of the short arm of chromosome 11. Gonadoblastoma occurs as part of the WAGR complex (Junien et al., 1980; Turleau et al., 1981).

In a report that focused on the aniridia component of the WAGR syndrome, Gilgenkrantz et al. (1982) analyzed the reported cases of aniridia with interstitial del(11)p. They reported a unique observation of hypertrophic cardiomyopathy in association with aniridia and catalase (CAT; 115500) deficiency in a patient with del(11)(p15.1p12). Riccardi et al. (1982) reported a patient with Wilms tumor and iris dysplasia, not aniridia. In the UK, Shannon et al. (1982) found the incidence of aniridia in cases of Wilms tumor to be 1 in 43. A survey detected 8 living and 3 dead children with Wilms tumor and aniridia. All 8 living children had deletion of 11p13. A high incidence of bilateral Wilms tumor (36%), male sex, early presentation, and advanced maternal age were features of the combined cases. Among 49 children with Wilms tumor without aniridia, only 1 had bilateral renal tumors.

Using high resolution chromosome banding, Marshall et al. (1982) studied 14 patients with aniridia. Seven were familial and had normal chromosomes; of 7 sporadic cases, 1 showed normal chromosomes and 6 had interstitial deletion of 11p of various lengths. Band 11p13 was included in the deletion in all 6 cases.

Little et al. (1993) suggested that the severe nephropathy associated with Denys-Drash syndrome (194080), which frequently leads to early renal failure, may result from the action of altered WT1 in blocking the normal activity of the wildtype protein. In contrast, because of the less severe genital anomalies and apparent lack of nephropathy associated with WAGR, a reduced WT1 dosage during embryogenesis is thought to have a less pronounced effect on development, especially on that of the renal system.

Breslow et al. (2000) reviewed nearly 6,000 patients enrolled in 4 clinical trials of the U. S. National Wilms Tumor Study Group between 1969 and 1995 who were followed until death or for a median of 11.0 years of survival for the onset of renal failure. Of 22 patients with Denys-Drash syndrome, 13 developed renal failure; of 46 patients with WAGR, 10 developed renal failure. The cumulative risks of renal failure at 20 years were 62% and 38%, respectively. The findings suggested that nephropathy is not associated uniquely with missense mutations in the WT1 gene and that patients with Wilms tumor and aniridia or genitourinary abnormalities should be followed closely throughout life for signs of nephropathy.

WAGR Syndrome with Atypical Eye Findings

Kawase et al. (2001) reported a case of WAGR syndrome with atypical eye findings. The boy presented at 1 month of age with microphthalmos bilaterally, microcornea and corneal cyst in the right eye, and corneal opacity (consistent with Peters anomaly) and absent anterior chamber in the left eye. Electroretinogram was normal in the right eye and subnormal in the left eye, suggesting retinal dysfunction. The child was found to have bilateral Wilms tumors at age 3 years. He also had undescended testes and mental retardation. Chromosome analysis revealed deletion of chromosome 11p15.1-p13.


Cytogenetics

Puissant et al. (1988) reported a patient with WAGR and a de novo reciprocal translocation 46,XY,t(5;11)(q11;p13). On Southern blot analysis, the gene encoding catalase had been deleted, but the gene encoding the beta subunit of follicle-stimulating hormone (FSHB) was intact. Evidence from studies of balanced translocations and other observations had suggested that the genitourinary dysplasia, like aniridia, was due to a separate gene in close proximity to the WT1 gene in band 11p13 (Bickmore et al., 1989; Glaser et al., 1989). By HRAS1-selected chromosome transfer, Porteous et al. (1987) defined 10 distinct regions of the short arm of chromosome 11, 5 of which subdivided band 11p13. They also mapped 2 independent 11p13 translocation breakpoints to within the smallest region of overlap defined by the WAGR deletions. One came from a patient with familial aniridia and the second from a patient with Potter facies and genitourinary dysplasia (urethral and ureteral atresia and bilateral cryptorchidism). Porteous et al. (1987) raised the question of whether Wilms tumor and genitourinary dysplasia are alternative manifestations of mutations at the same locus. A separate gene coding for genitourinary dysplasia (symbolized GUD) was also suggested by Bonetta et al. (1989), who found that the deletion breakpoint of a translocation t(11;2)(p13;p11) in a patient with Potter facies and genitourinary dysplasia mapped to the same 225-kb pulsed field gel electrophoresis fragment as did the fragment deleted in Wilms tumor. However, van Heyningen et al. (1990) suggested that the Wilms tumor gene itself may be responsible for abnormalities of genitourinary development in WAGR as a pleiotropic effect. The suggestion was based on the observations that the tumor predisposition and the genitourinary malformations map to precisely the same area and that the WT candidate gene shows expression in both the developing kidney and gonads. That there is no GUD gene separate from the WT1 gene is supported by the fact that the Denys-Drash syndrome (nephropathy, Wilms tumor, and genital anomalies; 194080) is caused by specific point mutations in the WT1 gene (e.g., 607102.0003).


Diagnosis

Apparent close linkage of the region determining the WAGR syndrome to the catalase locus (CAT; 115500) means that assay of catalase activity could usefully indicate those cases of new-mutation aniridia that should have surveillance for the development of renal or gonadal tumors (Junien et al., 1980).


Molecular Genetics

In WAGR syndrome, aniridia is due to the PAX6 gene, whereas the other features are probably due to the WT1 gene.

Animal Model

AGR syndrome is a subgroup of WAGR syndrome in which patients do not develop Wilms tumor and is associated with deletion of chromosome 11p14.1-p13, where the LGR4 gene (GPR48; 606666) is located. Yi et al. (2014) found that mice lacking Lgr4 had aniridia, polycystic kidney disease, genitourinary abnormalities, and mental retardation, similar to the pathologic defects of AGR syndrome. Inactivation of Lgr4 significantly increased apoptosis and decreased expression of multiple genes involved in development of WAGR syndrome-related organs. Yi et al. (2014) proposed that LGR4 is a candidate gene for the pathogenesis of AGR syndrome.


REFERENCES

  1. Anderson, S. R., Geertinger, P., Larsen, H.-W., Mikkelsen, M., Parving, A., Vestermark, S., Warburg, M. Aniridia, cataract and gonadoblastoma in a mentally retarded girl with deletion of chromosome 11: a clinicopathological case report. Ophthalmologica 176: 171-177, 1978. [PubMed: 613291] [Full Text: https://doi.org/10.1159/000308711]

  2. Bickmore, W. A., Porteous, D. J., Christie, S., Seawright, A., Fletcher, J. M., Maule, J. C., Couillin, P., Junien, C., Hastie, N. D., van Heyningen, V. CpG islands surround a DNA segment located between translocation breakpoints associated with genitourinary dysplasia and aniridia. Genomics 5: 685-693, 1989. [PubMed: 2556343] [Full Text: https://doi.org/10.1016/0888-7543(89)90109-2]

  3. Bonetta, L., Huang, A., Gregoris, M., Yeger, H., Williams, B. R. G. Characterization of a homozygous deletion mapping to the Wilms tumor region on 11p13. (Abstract) Cytogenet. Cell Genet. 51: 965 only, 1989.

  4. Breslow, N. E., Takashima, J. R., Ritchey, M. L., Strong, L. C., Green, D. M. Renal failure in the Denys-Drash and Wilms' tumor-aniridia syndromes. Cancer Res. 60: 4030-4032, 2000. [PubMed: 10945603]

  5. Francke, U., Riccardi, V. M., Hittner, H. M., Borges, W. Interstitial del(11p) as a cause of the aniridia-Wilms tumor association: band localization and a heritable basis. (Abstract) Am. J. Hum. Genet. 30: 81A, 1978.

  6. Gilgenkrantz, S., Vigneron, C., Gregoire, M. J., Pernot, C., Raspiller, A. Association of del(11)(p15.1p12), aniridia, catalase deficiency, and cardiomyopathy. Am. J. Med. Genet. 13: 39-49, 1982. [PubMed: 6127950] [Full Text: https://doi.org/10.1002/ajmg.1320130108]

  7. Glaser, T., Jones, C. A., Lewis, W. H., Call, K., Rose, E. A., Buckler, A., Ito, C., Housman, D. E. The ultrafine structure of the WAGR gene complex. (Abstract) Cytogenet. Cell Genet. 51: 1005 only, 1989.

  8. Junien, C., Turleau, C., de Grouchy, J., Said, R., Rethore, M.-O., Tenconi, R., Dufier, J. L. Regional assignment of catalase (CAT) gene to band 11p13: association with the aniridia-Wilms' tumor-gonadoblastoma (WAGR) complex. Ann. Genet. 23: 165-168, 1980. [PubMed: 6252821]

  9. Kawase, E., Tanaka, K., Honna, T., Azuma, N. A case of atypical WAGR syndrome with anterior segment anomaly and microphthalmos. Arch. Ophthal. 119: 1855-1856, 2001. [PubMed: 11735802]

  10. Little, M. H., Williamson, K. A., Mannens, M., Kelsey, A., Gosden, C., Hastie, N. D., van Heyningen, V. Evidence that WT1 mutations in Denys-Drash syndrome patients may act in a dominant-negative fashion. Hum. Molec. Genet. 2: 259-264, 1993. [PubMed: 8388765] [Full Text: https://doi.org/10.1093/hmg/2.3.259]

  11. Marshall, L. S., Qureshi, A. R., DiGeorge, A. M., Kistenmacher, M. L., Punnett, H. H. Aniridia and the 11p13 deletion. (Abstract) Am. J. Hum. Genet. 34: 74A, 1982.

  12. Miller, R. W., Fraumeni, J. F., Jr., Manning, M. D. Association of Wilms' tumor with aniridia, hemihypertrophy and other congenital malformations. New Eng. J. Med. 270: 922-927, 1964. [PubMed: 14114111] [Full Text: https://doi.org/10.1056/NEJM196404302701802]

  13. Porteous, D. J., Bickmore, W., Christie, S., Boyd, P. A., Cranston, G., Fletcher, J. M., Gosden, J. R., Rout, D., Seawright, A., Simola, K. O. J., van Heyningen, V., Hastie, N. D. HRAS1-selected chromosome transfer generates markers that colocalize aniridia- and genitourinary dysplasia-associated translocation breakpoints and the Wilms tumor gene within band 11p13. Proc. Nat. Acad. Sci. 84: 5355-5359, 1987. [PubMed: 3037545] [Full Text: https://doi.org/10.1073/pnas.84.15.5355]

  14. Puissant, H., Azoulay, M., Serre, J.-L., Piet, L., Junien, C. Molecular analysis of a reciprocal translocation t(5;11)(q11;p13) in a WAGR patient. Hum. Genet. 79: 280-282, 1988. [PubMed: 2841227] [Full Text: https://doi.org/10.1007/BF00366252]

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Contributors:
Paul J. Converse - updated : 10/22/2015
Victor A. McKusick - updated : 4/26/2005
Jane Kelly - updated : 4/19/2002
Victor A. McKusick - updated : 1/17/2002
Victor A. McKusick - updated : 9/29/2000

Creation Date:
Victor A. McKusick : 4/6/1994

Edit History:
carol : 12/22/2022
carol : 12/19/2022
carol : 12/18/2022
mgross : 10/22/2015
terry : 8/18/2009
terry : 8/18/2009
carol : 7/22/2009
carol : 12/24/2008
alopez : 12/11/2008
carol : 9/9/2008
carol : 8/29/2008
carol : 8/29/2008
tkritzer : 4/29/2005
terry : 4/26/2005
ckniffin : 8/26/2002
mgross : 4/19/2002
mgross : 4/19/2002
ckniffin : 3/12/2002
carol : 1/31/2002
mcapotos : 1/22/2002
terry : 1/17/2002
mcapotos : 10/9/2000
terry : 10/6/2000
mcapotos : 10/6/2000
terry : 9/29/2000
alopez : 7/31/1997
carol : 4/6/1994



NOTE: OMIM is intended for use primarily by physicians and other professionals concerned with genetic disorders, by genetics researchers, and by advanced students in science and medicine. While the OMIM database is open to the public, users seeking information about a personal medical or genetic condition are urged to consult with a qualified physician for diagnosis and for answers to personal questions.
OMIM® and Online Mendelian Inheritance in Man® are registered trademarks of the Johns Hopkins University.
Copyright® 1966-2025 Johns Hopkins University.

NOTE: OMIM is intended for use primarily by physicians and other professionals concerned with genetic disorders, by genetics researchers, and by advanced students in science and medicine. While the OMIM database is open to the public, users seeking information about a personal medical or genetic condition are urged to consult with a qualified physician for diagnosis and for answers to personal questions.
OMIM® and Online Mendelian Inheritance in Man® are registered trademarks of the Johns Hopkins University.
Copyright® 1966-2025 Johns Hopkins University.
Printed: March 5, 2025