Unbalanced translocation (15;17)(q13;13.3) with apparent Prader-Willi syndrome but without Miller-Dieker syndrome

We studied after death a 3-month-old girl whose karyotype was 45,XX,-15,-17,+der(17),t(15;17)(q13;p13.3) and thus combines abnormalities of chromosome 15 associated with the Prader-Willi syndrome and of chromosome 17 associated with the Miller-Dieker syndrome. This infant had several manifestations of the Prader-Willi syndrome in infancy but none of the Miller-Dieker syndrome. We propose that essentially no loss of 17p material has occurred and confirm previous reports that the critical region for the production of the Miller-Dieker phenotype is located subterminally in the 17p13.3 region.     

Miller-Dieker syndrome due to maternal cryptic translocation t(10;17)(q26.3;p13.3)

We report on a 3-month-old girl with Miller-Dieker syndrome resulting from a maternal full-cryptic translocation t(10;17)(q26.3;p13.3) detectable only by using fluorescence in situ hybridization (FISH). Parental studies using FISH are crucial for genetic counselling in cases of Miller-Dieker syndrome with submicroscopic deletion at 17p13.3. In a family with a parental cryptic translocation and high recurrence risk, prenatal diagnosis using FISH is feasible. © 1995 Wiley-Liss, Inc.     

Omphalocele in Miller-Dieker syndrome: Expanding the phenotype

We report on a patient prenatally diagnosed with omphalocele, mild cerebral ventriculomegaly, nuchal fold thickening, and cystic changes in the umbilical cord who was found postnatally to have lissencephaly type I. Prenatal chromosome analysis showed a normal male karyotype; however, postnatal high resolution banding and FISH analysis, using a probe for locus D17S379 in chromosome region 17p13.3, demonstrated a deletion at 17p13.3 consistent with Miller-Dieker syndrome (MDS). A review documented four more cases with MDS/isolated lissencephaly/17p-, with omphalocele. Because MDS is a contiguous gene disorder, we speculate that a gene or genes in this region have a major role in the closure of the lateral folds or the return of the midgut from the body stalk to the abdomen at 5–11 weeks of gestation. Prenatal diagnosis of omphalocele with mild ventriculomegaly should prompt FISH analysis for a deletion in 17p13.3. Am. J. Med. Genet. 69:293–298, 1997. © 1997 Wiley-Liss, Inc.     

Clinical and molecular genetic findings in five patients with Miller-Dieker syndrome

Five patients with type 1 lissencephaly, typical features of Miller-Dieker syndrome and apparently normal karyotypes were investigated for microdeletions in chromosome 17p13.3. Analysis of loci D17S5 and D17S379 by polymerase chain reaction and fluorescence in situ hybridization revealed a deletion in three cases. No deletion was observed in the remaining two cases. Given the almost identical clinical picture of the five patients, the great variation in the molecular findings argues against Miller-Dieker syndrome being a contiguous gene syndrome.     

Miller-Dieker syndrome and trisomy 5p in a child carrying a derivative chromosome with a microdeletion in 17p13.3 telomeric to the LIS1 and the D17S379 loci

Trisomy 5p and Miller-Dieker syndromes frequently are the result of unbalanced segregations of reciprocal translocations of chromosomes 5 and 17 with other autosomes. The critical regions for the expression of the mentioned syndromes have been mapped to 5p13→pter, and 17p13.3→pter. In this report, we describe an 8-year-old girl with mental retardation, postnatal growth deficiency, generalized muscular hypotonia, seizures, microcephaly, cortical atrophy, partial agenesis of corpus callosum, cerebral ventriculomegaly, facial anomalies, patent ductus arteriosus, pectus excavatum, long fingers, and bilateral talipes equinovarus caused by the presence of a 46,XX,der(17)t(5;17)(p13.1;p13.3)mat chromosome complement. Cytogenetic studies of the family confirmed a balanced reciprocal translocation (5;17)(p13.1;p13.3) in her mother, maternal grandfather, maternal aunt, and a female first cousin. Fluorescence in situ hybridization studies on the mother and the proposita using three probes, which map to distal 17p, confirmed the reciprocal translocation in the mother and a terminal deletion in the patient, which resulted in the retention of LIS1 and D17S379 loci and deletion of the 17p telomere. These findings and the phenotype of the proposita, strongly suggest that genes telomeric to LIS1 and locus D17S379 are involved in many clinical findings, including the minor facial anomalies of the Miller-Dieker syndrome. Am. J. Med. Genet. 85:99–104, 1999 © 1999 Wiley-Liss, Inc.     

Polymicrogyria associated with 17p13.3p13.2 duplication: Case report and review of the literature

We present the case of a male infant with bilateral perisylvian polymicrogyria associated with a de novo duplication of chromosome region 17p13.3p13.2. To our knowledge, this is the first report of polymicrogyria associated with the 17p13.3 contiguous gene duplication syndrome. Testing for known monogenic causes of polymicrogyria was negative and there was no clinical evidence of an acquired prenatal cause. Given the critical, dose-sensitive role that the 17p13.3 region plays in brain development, we suggest that the chromosome duplication is the most likely explanation for the polymicrogyria. Clinical and functional studies have demonstrated deleterious effects of increased LIS1 expression on the developing brain and the contribution of YWHAE to the brain phenotype of the 17p13 duplication syndrome. There is also evidence that CRK, the other candidate gene in this region, via interaction with LIS1, plays a critical role in cortical development. In addition to LIS1, YWHAE and CRK, our patient's chromosome duplication involves at least 100 other genes, less than half of which are annotated at the time of writing. It is expected that the ongoing use of chromosome microarray and next-generation sequencing to investigate the genetic causes of brain malformations will continue to extend our understanding of the 17p13 region and of the contributions of the genes in this region to cortical development.     

A new 17p13.3 microduplication including the PAFAH1B1 and YWHAE genes resulting from an unbalanced X;17 translocation

Submicroscopic duplications of the genomic interval deleted in Miller-Dieker syndrome (MDS) were recently identified by array-based comparative genomic hybridization (a-CGH) studies, describing new genomic disorders in the MDS locus. These rearrangements of varying size, from 59-88 kb to 4 Mb, were non-recurrent, and appear to result from diverse molecular mechanisms. Only five patients had overlapping 17p13.3 duplications including the entire MDS critical region. We describe here a 13-year-old girl with a novel microduplication of the MDS critical region, involving the PAFAH1B1 and YWHAE genes. She presented with moderate psychomotor retardation, speech delay, behavioral problems, and bilateral cleft lip and palate, a previously unreported manifestation. Initially diagnosed as having an apparently simple terminal Xq26 deletion on standard cytogenetic analysis, she was found to have an associated terminal 4.2 Mb 17p13.3 submicroscopic duplication, identified by subtelomere FISH analysis, further characterized by high-resolution array CGH, resulting from an unbalanced X;17 translocation. Phenotypic comparison with the 5 other patients previously described, revealed common phenotypic features, such as hypotonia, mild to moderate developmental delay/mental retardation, speech abnormalities, behavioral problems, recurrent infections, relatively increase of body weight, discrete facial dysmorphism including downslanting palpebral fissures, broad midface, pointed chin, contributing to further delineate this new 17p13.3 microduplication syndrome.     

Lissencephaly with der(17)t(17;20)(p13.3;p12.2)mat

The isolated lissencephaly sequence may be caused by point mutations of the LIS1 gene or by FISH-detectable microdeletions of the 17p13.3 region, which carries the LIS1 gene. These have various patterns of phenotypic presentations, including the Miller-Dieker syndrome (MDS). Approximately 20% of these deletions are associated with a derivative chromosome 17 inherited from a parent who has a balanced reciprocal translocation involving chromosome 17 and another chromosome. We report a case of lissencephaly associated with a maternally inherited unbalanced translocation involving chromosome arms 17p and 20p. This results in partial monosomy of 17p13.3-->pter and partial trisomy of 20p12.2-->pter. To our knowledge, this is the first report of a reciprocal translocation between 17p and 20p. Our patient has a combination of findings of the MDS and trisomy 20p, along with several unique anomalies not described in either of those two conditions. This report may contribute to the delineation of a phenotype resulting from partial monosomy 17p and partial trisomy of 20p.     

Oral-facial-digital syndrome with retinal abnormalities: Report of a new case

Smith-Magenis syndrome (SMS) is a multiple congenital anomalies/mental retardation syndrome associated with deletion of band p11.2 of chromosome 17. The deletion is typically detected by high-resolution cytogenetic analysis of chromosomes from peripheral lymphocytes. Fluorescence in situ hybridization (FISH) has been previously used to rule out apparent mosaicism for del(17)(p11.2p11.2) indicated by routine cytogenetics. We now report mosaicism for del(17)(p11.2p11.2) in a child with SMS. The mosaicism had gone undetected during previous routine cytogenetic analysis. FISH analysis of peripheral lymphocytes as well as immortalized lymphoblasts using markers from 17p11.2 revealed that approximately 60% of cells carried the deletion. To our knowledge, this is the first case of SMS associated with mosaicism for del(17)(p11.2p11.2). © 1996 Wiley-Liss, Inc.     

Prenatal diagnosis of Smith-Lemli-Opitz syndrome

The availability of markers for the 17p11.2 region has enabled the diagnosis of Smith-Magenis syndrome (SMS) by fluorescence in situ hybridization (FISH). SMS is typically associated with a discernible deletion of band 17p11.2 upon cytogenetic analysis at a resolution of 400–550 bands. We present a case that illustrates the importance of using FISH to confirm a cytogenetic diagnosis of del(17)(p11.2). Four independent cytogenetic analyses were performed with different conclusions. Results of low resolution analyses of amniocytes and peripheral blood lymphocytes were apparently normal, while high resolution analyses of peripheral blood samples in two laboratories indicated mosaicism for del(17)(p11.2). FISH clearly demonstrated a 17p deletion on one chromosome of all peripheral blood cells analyzed and ruled out mosaicism unambiguously. The deletion was undetectable by flow cytometric quantitation of chromosomal DNA content, suggesting that it is less than 2 Mb. We conclude that FISH should be used to detect the SMS deletion when routine chromosome analysis fails to detect it and to verify mosaicism. © 1995 Wiley-Liss, Inc.     

Further expansion and confirmation of phenotype in rare loss of YWHAE gene distinct from Miller–Dieker syndrome

Deletion of 17p13.3 has varying degrees of severity on brain development based on precise location and size of the deletion. The most severe phenotype is Miller–Dieker syndrome (MDS) which is characterized by lissencephaly, dysmorphic facial features, growth failure, developmental disability, and often early death. Haploinsufficiency of PAFAH1B1 is responsible for the characteristic lissencephaly in MDS. The precise role of YWHAE haploinsufficiency in MDS is unclear. Case reports are beginning to elucidate the phenotypes of individuals with 17p13.3 deletions that have deletion of YWHAE but do not include deletion of PAFAH1B1. Through our clinical genetics practice, we identified four individuals with 17p13.3 deletion that include YWHAE but not PAFAH1B1. These patients have a similar phenotype of dysmorphic facial features, developmental delay, and leukoencephalopathy. In a review of the literature, we identified 19 patients with 17p13.3 microdeletion sparing PAFAH1B1 but deleting YWHAE. Haploinsufficiency of YWHAE is associated with brain abnormalities including cystic changes. These individuals have high frequency of epilepsy, intellectual disability, and dysmorphic facial features including prominent forehead, epicanthal folds, and broad nasal root. We conclude that deletion of 17p13.3 excluding PAFAH1B1 but including YWHAE is associated with a consistent phenotype and should be considered a distinct condition from MDS.     

Familial Miller-Dieker syndrome associated with pericentric inversion of chromosome 17

Recently it has been shown that most cases of the Miller-Dieker syndrome (MDS) are caused by deletion 17p13.3. All familial cases have been associated with a balanced reciprocal translocation in a carrier parent and unbalanced translocations in their affected offspring. We report a new case of familial MDS in whom the mother carries a pericentric inversion of chromosome 17. She has had two children with MDS, one of whom was shown to carry a recombinant 17 consisting of dup(17q) and del(17p). The high frequency of familial MDS and its consistent association with balanced chromosomal rearrangements in one of the parents makes it important to do high-resolution chromosome analysis on all patients with MDS and possibly all patients with lissencephaly. Finding a familial balanced rearrangement makes prenatal diagnosis of this condition feasible.     

Syndromes with lissencephaly. I: Millerdieker and Norman-Roberts syndromes and isolated lissencephaly

Lissencephaly (smooth-brain) is an abnormality of brain development characterized by incomplete neuronal migration and a smooth cerebral surface. At least 2, and possibly more, distinct pathological types occur, each associated with several distinct syndromes. In this paper, the manifestations of 3 disorders associated with type I (classical) lissencephaly are discussed, including the Miller-Dieker syndrome with or without deficiency of 17p13, Norman-Roberts syndrome, and isolated lissencephaly sequence.     

A case of Miller-Dieker syndrome associated with satellite on chromosome 17p

In this report, we describe a one-year-old girl of the Miller-Dieker syndrome(MDS) with lissencephaly, seizures, microcephaly and mental disorders. Cytogenetic studies of this patient confirmed the presence of a 46,XX, 17ps+ chromosome karyotype, but it could not find the microdeletion of 17p13.3. Fluorescence in situ hybridization(FISH) studies confirmed a terminal deletion in the patient using the LIS1 gene probe which mapped to 17p13.3. Further it was also found the satellite on 17p13(17ps) in the patient who was rare associated with MDS. These findings suggest that FISH analysis may be useful method to detect microdeletion of LIS1 gene as 17-specific probe in the investigation of MDS patients.     

A newborn with a 790 kb chromosome 17p13.3 microduplication presenting with aortic stenosis,microcephaly and dysmorphic facial features - Is cardiac assessment necessary for all patients with 17p13.3 microduplication?

While deletion of chromosome 17p13.3 (encompassing PAFAH1B1 and YWHAE genes) is known to result in Miller–Dieker syndrome (OMIM 247200), 17p13.3 microduplication gives rise to a condition commonly associated with developmental delay and autism spectrum disorder. We report a Chinese newborn presenting with dysmorphic features, microcephaly and valvar aortic stenosis, who was confirmed to have a 790 kb microduplication in chromosome 17p13.3 by array comparative genomic hybridization (aCGH). The patient passed away at 4 months of age with presumably life-threatening event associated with his cardiac condition. From literature review, congenital heart diseases of various kinds were identified in up to 20% of patients with 17p13.3 microduplication. We propose cardiac assessment should be part of the comprehensive evaluation of these patients.     

Smith-Magenis syndrome deletion: A case with equivocal cytogenetic findings resolved by fluorescence in situ hybridization

The availability of markers for the 17p11.2 region has enabled the diagnosis of Smith-Magenis syndrome (SMS) by fluorescence in situ hybridization (FISH). SMS is typically associated with a discernible deletion of band 17p11.2 upon cytogenetic analysis at a resolution of 400–550 bands. We present a case that illustrates the importance of using FISH to confirm a cytogenetic diagnosis of del(17)(p11.2). Four independent cytogenetic analyses were performed with different conclusions. Results of low resolution analyses of amniocytes and peripheral blood lymphocytes were apparently normal, while high resolution analyses of peripheral blood samples in two laboratories indicated mosaicism for del(17)(p11.2). FISH clearly demonstrated a 17p deletion on one chromosome of all peripheral blood cells analyzed and ruled out mosaicism unambiguously. The deletion was undetectable by flow cytometric quantitation of chromosomal DNA content, suggesting that it is less than 2 Mb. We conclude that FISH should be used to detect the SMS deletion when routine chromosome analysis fails to detect it and to verify mosaicism. © 1995 Wiley-Liss, Inc.     

Clinical and genomic delineation of the new proximal 19p13.3 microduplication syndrome

A small but growing body of scientific literature is emerging about clinical findings in patients with 19p13.3 microdeletion or duplication. Recently, a proximal 19p13.3 microduplication syndrome was described, associated with growth delay, microcephaly, psychomotor delay and dysmorphic features. The aim of our study was to better characterize the syndrome associated with duplications in the proximal 19p13.3 region (prox 19p13.3 dup), and to propose a comprehensive analysis of the underlying genomic mechanism. We report the largest cohort of patients with prox 19p13.3 dup through a collaborative study. We collected 24 new patients with terminal or interstitial 19p13.3 duplication characterized by array-based Comparative Genomic Hybridization (aCGH). We performed mapping, phenotype–genotype correlations analysis, critical region delineation and explored three-dimensional chromatin interactions by analyzing Topologically Associating Domains (TADs). We define a new 377 kb critical region (CR 1) in chr19: 3,116,922–3,494,377, GRCh37, different from the previously described critical region (CR 2). The new 377 kb CR 1 includes a TAD boundary and two enhancers whose common target is PIAS4. We hypothesize that duplications of CR 1 are responsible for tridimensional structural abnormalities by TAD disruption and misregulation of genes essentials for the control of head circumference during development, by breaking down the interactions between enhancers and the corresponding targeted gene.     

Lissencephaly gene product. Localization in the central nervous system and loss of immunoreactivity in Miller-Dieker syndrome.

The Miller-Dieker syndrome, a disorder of neuronal migration, is caused by deletions of chromosome 17p13.3. Recently, a gene on 17p13.3, named LIS-1, was identified as the causative gene for this cerebral anomaly. Here we immunochemically and immunohistochemically localized the gene product, LIS-1 protein, among control normal subjects and patients with Miller-Dieker syndrome, using specific antibodies raised against synthetic peptide fragments of LIS-1 protein. Western blot analyses identified LIS-1 protein as a 45-kd, heparin-binding protein abundant in the cytosolic fraction. The protein was restricted to the central nervous system and detectable in brains of controls of all ages, from the early fetal to adult period. Immunostaining demonstrated the widespread distribution of LIS-1 protein in the brain and spinal cord of controls and a loss of immunoreactivity in individuals with Miller-Dieker syndrome. These results are consistent with the notion that a deficiency of LIS-1 protein is the direct cause of the brain malformation and that the protein plays a critical role in neuronal migration.     

一例Miller-Dieker综合征胎儿的产前诊断及遗传学分析

目的对1例无脑回畸形胎儿进行遗传学诊断,分析其可能的发生机制,为临床诊断和遗传咨询提供依据。方法应用拷贝数变异分析(copy number variation,CNV)技术检测分析胎儿羊水细胞DNA。结果CNV检测结果显示胎儿染色体17p13.3p13.2区存在5.02 Mb杂合缺失,该缺失片段完全覆盖Miller-Dieker综合征所在区域(chr17:1~2588909)。结论胎儿诊断为Miller-Dieker综合征,17号染色体短臂末端PAFAH1B1基因缺失可能是造成胎儿无脑回畸形的关键基因。     

Maternal disomy and Prader-Willi syndrome consistent with gamete complementation in a case of familial translocation (3;15) (p25;q11.2)

Maternal uniparental disomy (UPD) for chromosome 15 is responsible for an estimated 30% of cases of Prader-Willi syndrome (PWS). We report on an unusual case of maternal disomy 15 in PWS that is most consistent with adjacent-1 segregation of a paternal t(3;15)(p25;q11.2) with simultaneous maternal meiotic nondisjunction for chromosome 15. The patient (J.B.), a 17-year-old white male with PWS, was found to have 47 chromosomes with a supernumerary, paternal der(15) consisting of the short arm and the proximal long arm of chromosome 15, and distal chromosome arm 3p. The t(3;15) was present in the balanced state in the patient's father and a sister. Fluorescent in situ hybridization analysis demonstrated that the PWS critical region resided on the derivative chromosome 3 and that there was no deletion of the PWS region on the normal pair of 15s present in J.B. Methylation analysis at exon alpha of the small nuclear ribonucleoprotein-associated polypeptide N (SNRPN) gene showed a pattern characteristic of only the maternal chromosome 15 in J.B. Maternal disomy was confirmed by polymerase chain reaction analysis of microsatellite repeats at the gamma-aminobutyric acid receptor beta3 subunit (GABRB3) locus. A niece (B.B.) with 45 chromosomes and the derivative 3 but without the der(15) demonstrated a phenotype consistent with that reported for haploinsufficiency of distal 3 p. Uniparental disomy associated with unbalanced segregation of non-Robertsonian translocations has been reported previously but has not, to our knowledge, been observed in a case of PWS. Furthermore, our findings are best interpreted as true gamete complementation resulting in maternal UPD 15 and PWS. Am. J. Med. Genet. 78:134–139, 1998. © 1998 Wiley-Liss, Inc.