Complex rearrangements of chromosome 15 in two patients with mild/atypical Prader Willi syndrome

Multiple mechanisms are responsible for the development of Prader Willi syndrome (PWS), the most common genetic cause of obesity in childhood. Molecular findings are usually deletions and uniparental disomy (UPD) of the 15q11-13 region. Rarely, structural rearrangements of the pericentromeric region of chromosome 15 are also detected. Two cases with mild PWS phenotype and complex maternal UPD identified by microsatellite analysis are described: the first patient had uniparental iso and heterodisomy and the second displayed biallelic inheritance and uniparental isodisomy.     

An unusual case of Cat-Eye syndrome phenotype and extragonadal mature teratoma: review of the literature

BACKGROUND Cat-Eye syndrome (CES) with teratoma has not been previously reported. We present the clinical and molecular findings of a 9-month-old girl with features of CES and also a palpable midline neck mass proved to be an extragonadal mature teratoma, additionally characterized by array comparative genomic hybridization (aCGH). RESULTS High resolution oligonucleotide-based aCGH confirmed that the supernumerary marker chromosome (SMC) derived from chromosome 22, as was indicated by molecular cytogenetic analysis with fluorescence in situ hybridization (FISH). Additionally, aCGH clarified the size, breakpoints, and gene content of the duplication (dup 22q11.1q11.21; size:1.6 Mb; breakpoints: 15,438,946-17,041,773; hg18). The teratoma tissue was also tested with aCGH, in which the CES duplication was not found, but the analysis revealed three aberrations: del Xp22.3 (108,864-2788,689; 2.7 Mb hg18), dup Yp11.2 (6688,491-7340,982; 0.65 Mb, hg18), and dup Yq11.2q11.23 (12,570,853-27,177,133; 14.61 Mb, hg18). These results indicated 46 XY (male) karyotype of the teratoma tissue, making this the second report of mature extragonadal teratoma in a female neonate, probably deriving from an included dizygotic twin of opposite sex (fetus in fetu). CONCLUSIONS Our findings extend the phenotypic spectrum of CES syndrome, a disorder with clinical variability, pointing out specific dosage-sensitive genes that might contribute to specific phenotypic features.     

Microdeletion and microduplication 17q21.31 plus an additional CNV, in patients with intellectual disability, identified by array-CGH

The recognition of the 17q21.31 microdeletion and microduplication syndrome has been facilitated by high resolution oligonucleotide array comparative genome hybridization technology (aCGH). Molecular analysis of the 17q21.31 microdeletion/duplication syndrome demonstrated a critical region involving at least six genes, including STH and MAPT. The 17q21.31 microdeletion syndrome has an incidence of 1 in 16,000 births, while the microduplication 17q21.31 has been reported so far in only five patients. In general, phenotypes associated with 17q21.31 microduplication seem to be milder than those associated with the microdeletion. Here, we present four patients who have been referred for genetic evaluation by clinical geneticists due to developmental delay and minor congenital abnormalities. Previous standard karyotypes were negative, while aCGH analysis revealed three patients with 17q21.31 microdeletion and one with the respective microduplication, being the sixth reported case so far. Most importantly one of the microdeletion cases involves only partial MAPT gene deletion while leaving the STH gene intact. Two of our patients, one with the 17q21.31 microdeletion and another with the respective microduplication, carried additional clinically relevant microdeletions (del Xq21.31 and del 15q11.2, respectively), possibly modifying their phenotype.     

An unusual case of cat‐eye syndrome phenotype and extragonadal mature teratoma: Review of the literature

BACKGROUND Cat‐Eye syndrome (CES) with teratoma has not been previously reported. We present the clinical and molecular findings of a 9‐month‐old girl with features of CES and also a palpable midline neck mass proved to be an extragonadal mature teratoma, additionally characterized by array comparative genomic hybridization (aCGH). RESULTS High resolution oligonucleotide‐based aCGH confirmed that the supernumerary marker chromosome (SMC) derived from chromosome 22, as was indicated by molecular cytogenetic analysis with fluorescence in situ hybridization (FISH). Additionally, aCGH clarified the size, breakpoints, and gene content of the duplication (dup 22q11.1q11.21; size:1.6 Mb; breakpoints: 15,438,946‐17,041,773; hg18). The teratoma tissue was also tested with aCGH, in which the CES duplication was not found, but the analysis revealed three aberrations: del Xp22.3 (108,864‐2788,689; 2.7 Mb hg18), dup Yp11.2 (6688,491‐7340,982; 0.65 Mb, hg18), and dup Yq11.2q11.23 (12,570,853‐27,177,133; 14.61 Mb, hg18). These results indicated 46 XY (male) karyotype of the teratoma tissue, making this the second report of mature extragonadal teratoma in a female neonate, probably deriving from an included dizygotic twin of opposite sex (fetus in fetu). CONCLUSIONS Our findings extend the phenotypic spectrum of CES syndrome, a disorder with clinical variability, pointing out specific dosage‐sensitive genes that might contribute to specific phenotypic features. Birth Defects Research (Part A) 2012. © 2012 Wiley Periodicals, Inc.     

Screening Human Genes for Small Alterations Performing an Enzymatic Cleavage Mismatched Analysis (ECMA) Protocol

Many human diseases are caused by small alterations in the genes and in the majority of cases sophisticated protocols are required for their detection. In this study we estimated the efficacy of an enzymatic protocol, which using a new mismatch-specific DNA plant endonuclease from celery (CEL family) recognizes and cleaves mismatched alleles between mutant and normal PCR products. The protocol was standardized on a variety of known mutations, in 11 patients with cystic fibrosis (CF), Fabry’s disease (FD), steroid 21-hydroxylase deficiency (21-HD) and Duchenne/Becker muscular dystrophy (DMD/BMD). The method does not require special equipment, labeling or standardization for every PCR product, since conditions of heteroduplex formation and enzyme digestion are universal for all products. The results showed that the method is rapid, effective, safe, reliable, and very simple, as the mutations are visualized on agarose or nusieve/agarose gels. The protocol was furthermore evaluated in three DMD patients with the detection of three alterations which after sequencing, were characterized as disease causative mutations. The proposed assay, which was applied for the first time in a variety of monogenic disorders, indicates that point mutation identification is feasible in any conventional molecular lab even for cases, where other techniques have failed.     

Evaluation of YO-PRO-1 as an early marker of apoptosis following radiofrequency ablation of colon cancer liver metastases

Radiofrequency (RF) ablation (RFA) is a minimally invasive treatment for colorectal-cancer liver metastases (CLM) in selected nonsurgical patients. Unlike surgical resection, RFA is not followed by routine pathological examination of the target tumor and the surrounding liver tissue. The aim of this study was the evaluation of apoptotic events after RFA. Specifically, we evaluated YO-PRO-1 (YP1), a green fluorescent DNA marker for cells with compromised plasma membrane, as a potential, early marker of cell death. YP1 was applied on liver tissue adherent on the RF electrode used for CLM ablation, as well as on biopsy samples from the center and the margin of the ablation zone as depicted by dynamic CT immediately after RFA. Normal pig and mouse liver tissues were used for comparison. The same samples were also immunostained for fragmented DNA (TUNEL assay) and for active mitochondria (anti-OxPhos antibody). YP1 was also used simultaneously with propidium iodine (PI) to stain mouse liver and samples from ablated CLM. Following RFA of human CLM, more than 90 % of cells were positive for YP1. In nonablated, dissected pig and mouse liver however, we found similar YP1 signals (93.1 % and 65 %, respectively). In samples of intact mouse liver parenchyma, there was a significantly smaller proportion of YP1 positive cells (22.7 %). YP1 and PI staining was similar for ablated CLM. However in dissected normal mouse liver there was initial YP1 positivity and complete absence of the PI signal and only later there was PI signal. Conclusion: This is the first time that YP1 was applied in liver parenchymal tissue (rather than cell culture). The results suggest that YP1 is a very sensitive marker of early cellular events reflecting an early and widespread plasma membrane injury that allows YP1 penetration into the cells.     

Screening Human Genes for Small Alterations Performing an Enzymatic Cleavage Mismatched Analysis (ECMA) Protocol

Many human diseases are caused by small alterations in the genes and in the majority of cases sophisticated protocols are required for their detection. In this study we estimated the efficacy of an enzymatic protocol, which using a new mismatch-specific DNA plant endonuclease from celery (CEL family) recognizes and cleaves mismatched alleles between mutant and normal PCR products. The protocol was standardized on a variety of known mutations, in 11 patients with cystic fibrosis (CF), Fabry’s disease (FD), steroid 21-hydroxylase deficiency (21-HD), and Duchenne/Becker muscular dystrophy (DMD/BMD). The method does not require special equipment, labeling or standardization for every PCR product, since conditions of heteroduplex formation and enzyme digestion are universal for all products. The results showed that the method is rapid, effective, safe, reliable, and very simple, as the mutations are visualized on agarose or nusieve/agarose gels. The protocol was furthermore evaluated in three DMD patients with the detection of three alterations, which after sequencing, were characterized as disease causative mutations. The proposed assay, which was applied for the first time in a variety of monogenic disorders, indicates that point mutation identification is feasible in any conventional molecular lab even for cases where other techniques have failed.