Maternally inherited deletion encompassing the RTL1as and MEG8 genes of the human 14q32 imprinted region in a patient with a mild Kagami-Ogata syndrome phenotype.

Kagami-Ogata syndrome and Temple syndrome are imprinting disorders caused by the abnormal expression of genes in an imprinted cluster on chromosome 14q32. Here, we report a female with mild features of the Kagami-Ogata syndrome phenotype with polyhydramnios, neonatal hypotonia, feeding difficulties, abnormal foot morphology, patent foramen ovale, distal arthrogryposis, normal facial profile, and a bell-shaped thorax without coat hanger ribs. The single nucleotide polymorphism array revealed the interstitial deletion of chromosome 14q32.2-q32.31 (117 kb in size), involving the RTL1as and MEG8 genes, and other small nucleolar RNAs and microRNAs. The differentially methylated regions (DMRs) appeared unaltered. The RTL1as gene deletion and the normal methylation pattern of the MEG3 gene loci were confirmed by methylation-specific multiplex ligation-dependent probe amplification. Deletions of the 14q32 region without involving DMRs, and encompassing only the RTL1as and MEG8 genes, are poorly described in the literature. The mother's chromosomal microarray also confirmed the identical 14q32.2 deletion, although she presented a normal phenotype. The maternally inherited 14q32 deletion was responsible for Kagami-Ogata syndrome in our patient. It was not sufficient, however, to produce Temple syndrome or any other pathogenic phenotype in the patient's mother.

Multisuture craniosynostosis: a case report of unusual presentation of chromosome 14q32 deletion.

Multisuture craniosynostosis is associated with a number of syndromes and underlying gene mutations. It is rarely caused by chromosome disorders. For the management, multisuture craniosynostosis raises concerns about abnormal head shape and risks of increased intracranial pressure in affected patients. Calvarial reconstruction to reshape the skull shape and expand the intracranial volume plays an essential role in correcting particular problems. Here, we report a 2-month-old female infant presenting with low birth weight, abnormal head shape, dysmorphic facies and pinnae, hypotonia, and feeding difficulty. Three-dimensional computed tomographic scans revealed left unicoronal and sagittal synostoses. Chromosome microarray analysis revealed de novo chromosome 14q32.12-q32.31 deletion. Among the deleted genes, YY1 and BCL11B are the most likely candidate genes causing craniosynostosis. Some clinical features of the patient are similar to Temple syndrome indicating that the deleted region is paternal in origin. In summary, this is a rare case of chromosome 14q32 deletion with multisuture craniosynostosis. We also report the multidisciplinary management and clinical outcomes after early cranial vault remodelling procedures.

New patients with Temple syndrome caused by 14q32 deletion: Genotype-phenotype correlations and risk of thyroid cancer.

Temple syndrome (TS) is caused by abnormal expression of genes at the imprinted locus 14q32. A subset of TS patients carry 14q32 deletions of paternal origin. We aimed to define possible genotype-phenotype correlations and to highlight the prevalence of thyroid dysfunction, which is a previously unreported feature of TS. We described four new patients who carry deletions of paternal origin at 14q32 detected by array-CGH and reviewed nine patients reported in the medical literature. We compared clinical features with respect to deletion size and position. Expression of DLK1 is altered in all the patients with TS, but intellectual disability (ID) is present only in patients with larger deletions extending proximally to the imprinted locus. This study led to the identification of an ID "critical region" containing four annotated genes including YY1 as the strongest candidate. Furthermore, we described three patients with thyroid dysfunction, which progressed to papillary carcinoma at a very young age in two of them. We conclude that DLK1 loss of function is likely to be responsible for the core features of TS, while haploinsufficiency of a gene outside the imprinted region causes ID. Thyroid cancer may be an unrecognized feature and monitoring for thyroid dysfunction should thus be considered in TS patients.

Identification of two 14q32 deletions involving DICER1 associated with the development of DICER1-related tumors.

DICER1 encodes an RNase III endonuclease protein that regulates the production of small non-coding RNAs. Germline mutations in DICER1 are associated with an autosomal dominant hereditary cancer predisposition syndrome that confers an increased risk for the development of several rare childhood and adult-onset tumors, the most frequent of which include pleuropulmonary blastoma, ovarian sex cord-stromal tumors, cystic nephroma, and thyroid gland neoplasia. The majority of reported germline DICER1 mutations are truncating sequence-level alterations, suggesting that a loss-of-function type mechanism drives tumor formation in DICER1 syndrome. However, reports of patients with germline DICER1 whole gene deletions are limited, and thus far, only two have reported an association with tumor development. Here we report the clinical findings of three patients from two unrelated families with 14q32 deletions that encompass the DICER1 locus. The deletion identified in Family I is 1.4 Mb and was initially identified in a 6-year-old male referred for developmental delay, hypotonia, macrocephaly, obesity, and behavioral problems. Subsequent testing revealed that this deletion was inherited from his mother, who had a clinical history that included bilateral multinodular goiter and papillary thyroid carcinoma. The second deletion is 5.0 Mb and was identified in a 15-year-old female who presented with autism, coarse facial features, Sertoli-Leydig cell tumor, and Wilms' tumor. These findings provide additional supportive evidence that germline deletion of DICER1 confers an increased risk for DICER1-related tumor development, and provide new insight into the clinical significance of deletions involving the 14q32 region.