Neuropsychological and neurophysiological features of WAGR syndrome: Detailed comprehensive evaluation of a patient with severe intellectual disability and autism spectrum disorder.

BACKGROUND: Wilms' tumor, aniridia, genitourinary anomalies, and mental retardation (WAGR) syndrome is a contiguous gene deletion syndrome caused by a de novo deletion including the 11p13 region. Although autism spectrum disorder (ASD) is frequently observed in patients with WAGR syndrome, few reports have comprehensively described its characteristics. We herein present the detailed neuropsychological and neurophysiological findings of a patient with WAGR syndrome complicated with severe psychomotor developmental delay and ASD. CASE PRESENTATION: The patient is presently a 6-year-old boy. Microarray analysis revealed a 7.1 Mb loss at 11p14.3-p13 and a 9.3 Mb loss at 11p13-p12, which encompassed the PAX6, WT1, and PRRG4 genes. His behavioral features were characteristic even among the ASD population: severe hypoesthesia to touch, pain, and temperature in addition to remarkable sensory seeking posing a high risk of serious accident. Sensory Profile analysis objectively identified a strong preference for sensory stimulation. Furthermore, his somatosensory evoked potential (SSEP) showed a mild delay in central conduction time, suggesting partial brain stem dysfunction-induced hypoalgesia. DISCUSSION: This first attempt to characterize sensory dysfunction using Sensory Profile and SSEP in WAGR syndrome may contribute to understanding its neuropsychological features and improve the quality of rehabilitation and socioeducational support in affected children.

[WAGR syndrome by heterozygous deletion of the WT1 gene. Pediatric case report]. / Síndrome WAGR por deleción en heterocigosis del gen WT1. Caso clínico pediátrico.

WAGR syndrome (Wilms tumor, aniridia, genitourinary anomalies and mental retardation) is an uncommon genetic disorder due to the deletion of the 11p13 region that contains the WT1 and PAX6 genes. It involves a distinctive combination of clinical conditions, with aniridia and Wilms tumor being the most notable. We present a 17-month-old infant with microcephaly, ocular alterations (buphthalmos, leukocoria, bilateral aniridia), scrotal hypoplasia, undescended testes and neurodevelopmental delay who underwent multiplex ligation-dependent probe amplification study for WT1, showing haploinsufficiency in the probes that hybridize to the 11p13 region, compatible with an heterozygous deletion of the gene. Wilms tumor was later diagnosed. WAGR syndrome is infrequent; its report in Latin America is low. It is important to disseminate its clinical characteristics, emphasizing an interdisciplinary management focused on the early identification of both the syndrome and its possible complications.

El síndrome WAGR (tumor de Wilms, aniridia, anomalías genitourinarias y retraso mental) es un trastorno genético infrecuente debido a la deleción de la región 11p13, que contiene los genes WT1 y PAX6. Comprende una combinación distintiva de afecciones clínicas; la aniridia y el tumor de Wilms son las más notables. Se presenta a un lactante de 17 meses con microcefalia, alteraciones oculares (buftalmos, leucocoria, aniridia bilateral), hipoplasia escrotal, testículos en la región inguinal y retraso en el neurodesarrollo, a quien se le realizó el estudio de amplificación de sondas dependiente de ligandos múltiples para WT1, que mostró haploinsuficiencia en las sondas que hibridaban la región 11p13, compatible con una deleción en heterocigosis del gen. Posteriormente, se diagnosticó tumor de Wilms. Dada su baja prevalencia, es importante difundir sus características clínicas y hacer énfasis en un manejo interdisciplinario centrado en la identificación precoz del síndrome y de sus posibles complicaciones.

Sustained endocrine profiles of a girl with WAGR syndrome.

BACKGROUND: Wilms tumor, aniridia, genitourinary anomalies and mental retardation (WAGR) syndrome is a rare genetic disorder caused by heterozygous deletions of WT1 and PAX6 at chromosome 11p13. Deletion of BDNF is known eto be associated with hyperphagia and obesity in both humans and animal models; however, neuroendocrine and epigenetic profiles of individuals with WAGR syndrome remain to be determined. CASE PRESENTATION: We report a 5-year-old girl with the typical phenotype of WAGR syndrome. She showed profound delays in physical growth, motor and cognitive development without signs of obesity. Array comparative genome hybridization (CGH) revealed that she carried a 14.4 Mb deletion at 11p14.3p12, encompassing the WT1, PAX6 and BDNF genes. She experienced recurrent hypoglycemic episodes at 5 years of age. Insulin tolerance and hormonal loading tests showed normal hypothalamic responses to the hypoglycemic condition and other stimulations. Methylation analysis for freshly prepared DNA from peripheral lymphocytes using the pyro-sequencing-based system showed normal patterns of methylation at known imprinting control regions. CONCLUSIONS: Children with WAGR syndrome may manifest profound delay in postnatal growth through unknown mechanisms. Epigenetic factors and growth-associated genes in WAGR syndrome remain to be characterized.

The WAGR syndrome gene PRRG4 is a functional homologue of the commissureless axon guidance gene.

WAGR syndrome is characterized by Wilm's tumor, aniridia, genitourinary abnormalities and intellectual disabilities. WAGR is caused by a chromosomal deletion that includes the PAX6, WT1 and PRRG4 genes. PRRG4 is proposed to contribute to the autistic symptoms of WAGR syndrome, but the molecular function of PRRG4 genes remains unknown. The Drosophila commissureless (comm) gene encodes a short transmembrane protein characterized by PY motifs, features that are shared by the PRRG4 protein. Comm intercepts the Robo axon guidance receptor in the ER/Golgi and targets Robo for degradation, allowing commissural axons to cross the CNS midline. Expression of human Robo1 in the fly CNS increases midline crossing and this was enhanced by co-expression of PRRG4, but not CYYR, Shisa or the yeast Rcr genes. In cell culture experiments, PRRG4 could re-localize hRobo1 from the cell surface, suggesting that PRRG4 is a functional homologue of Comm. Comm is required for axon guidance and synapse formation in the fly, so PRRG4 could contribute to the autistic symptoms of WAGR by disturbing either of these processes in the developing human brain.

WAGR syndrome and congenital hypothyroidism in a child with a Mosaic 11p13 deletion.

Wilm's tumor, aniridia, genitourinary anomalies, and mental retardation (WAGR) syndrome, a rare genetic disorder, is caused by the loss of 11p13 region including PAX6 and WT1. We report novel findings in a 28-month-old boy with aniridia, Wilm's tumor, congenital hypothyroidism, and sublingual thyroid ectopia. He was found to have a mosaic 5.28 Mb interstitial deletion of chromosome 11p13 deleting PAX6 and WT1. In order to clarify the mechanism underlying his thyroid dysgenesis, sequence analysis of candidate thyroid developmental genes was performed. We identified a FOXE1: c.532_537delGCCGCC p.(Ala178_Ala179del) variant that predisposes to thyroid ectopia. Taken together, this is the first report of mosaic 11p13 deletion in association with thyroid dysgenesis. We also propose a model of complex interactions of different genetic variants for this particular phenotype in the present patient.

LGR4/GPR48 inactivation leads to aniridia-genitourinary anomalies-mental retardation syndrome defects.

AGR syndrome (the clinical triad of aniridia, genitourinary anomalies, and mental retardation, a subgroup of WAGR syndrome for Wilm's tumor, aniridia, genitourinary anomalies, and mental retardation) is a rare syndrome caused by a contiguous gene deletion in the 11p13-14 region. However, the mechanisms of WAGR syndrome pathogenesis are elusive. In this study we provide evidence that LGR4 (also named GPR48), the only G-protein-coupled receptor gene in the human chromosome 11p12-11p14.4 fragment, is the key gene responsible for the diseases of AGR syndrome. Deletion of Lgr4 in mouse led to aniridia, polycystic kidney disease, genitourinary anomalies, and mental retardation, similar to the pathological defects of AGR syndrome. Furthermore, Lgr4 inactivation significantly increased cell apoptosis and decreased the expression of multiple important genes involved in the development of WAGR syndrome related organs. Specifically, deletion of Lgr4 down-regulated the expression of histone demethylases Jmjd2a and Fbxl10 through cAMP-CREB signaling pathways both in mouse embryonic fibroblast cells and in urinary and reproductive system mouse tissues. Our data suggest that Lgr4, which regulates eye, kidney, testis, ovary, and uterine organ development as well as mental development through genetic and epigenetic surveillance, is a novel candidate gene for the pathogenesis of AGR syndrome.