Prenatal profile of Pallister-Killian syndrome: Retrospective analysis of 114 pregnancies, literature review and approach to prenatal diagnosis.

Pallister-Killian syndrome (PKS) is a tissue limited mosaic disorder, characterized by variable degrees of neurodevelopmental delay and intellectual disability, typical craniofacial findings, skin pigmentation anomalies and multiple congenital malformations. The wide phenotypic spectrum of PKS in conjunction with the mosaic distribution of the i(12p) makes PKS an underdiagnosed disorder. Recognition of prenatal findings that should raise a suspicion of PKS is complicated by the fragmentation of data currently available in the literature and challenges in diagnosing a mosaic diagnosis on prenatal testing. Ultrasound anomalies, especially congenital diaphragmatic hernia, congenital heart defects, and rhizomelic limb shortening, have been related to PKS, but they are singularly not specific and are not present in all affected fetuses. We have combined prenatal data from 86 previously published reports and from our cohort of 114 PKS probands (retrospectively reviewed). Summarizing this data we have defined a prenatal growth profile and identified markers of perinatal outcome which collectively provide guidelines for early recognition of the distinctive prenatal profile and consideration of a diagnosis of PKS as well as for management and genetic counseling.

Recognition of the Cornelia de Lange syndrome phenotype with facial dysmorphology novel analysis.

Facial analysis systems are becoming available to healthcare providers to aid in the recognition of dysmorphic phenotypes associated with a multitude of genetic syndromes. These technologies automatically detect facial points and extract various measurements from images to recognize dysmorphic features and evaluate similarities to known facial patterns (gestalts). To evaluate such systems' usefulness for supporting the clinical practice of healthcare professionals, the recognition accuracy of the Cornelia de Lange syndrome (CdLS) phenotype was examined with FDNA's automated facial dysmorphology novel analysis (FDNA) technology. In the first experiment, 2D facial images of CdLS patients with either an NIPBL or SMC1A gene mutation as well as non-CdLS patients which were assessed by dysmorphologists in a previous study were evaluated by the FDNA technology; the average detection rate of experts was 77% while the system's detection rate was 87%. In the second study, when a new set of NIPBL, SMC1A and non-CdLS patient photos was evaluated, the detection rate increased to 94%. The results from both studies indicated that the system's detection rate was comparable to that of dysmorphology experts. Therefore, utilizing such technologies may be a useful tool in a clinical setting.

Cornelia de Lange syndrome, cohesin, and beyond.

Cornelia de Lange syndrome (CdLS) (OMIM #122470, #300590 and #610759) is a dominant genetic disorder with multiple organ system abnormalities which is classically characterized by typical facial features, growth and mental retardation, upper limb defects, hirsutism, gastrointestinal and other visceral system involvement. Mutations in three cohesin proteins, a key regulator of cohesin, NIPBL, and two structural components of the cohesin ring SMC1A and SMC3, etiologically account for about 65% of individuals with CdLS. Cohesin controls faithful chromosome segregation during the mitotic and meiotic cell cycles. Multiple proteins in the cohesin pathway are also involved in additional fundamental biological events such as double-strand DNA break repair and long-range regulation of transcription. Moreover, chromosome instability was recently associated with defective sister chromatid cohesion in several cancer studies, and an increasing number of human developmental disorders is being reported to result from disruption of this pathway. Here, we will discuss the human disorders caused by alterations of cohesin function (termed 'cohesinopathies'), with an emphasis on the clinical manifestations of CdLS and mechanistic studies of the CdLS-related proteins.

Jagged1 (JAG1) mutations in Alagille syndrome: increasing the mutation detection rate.

Alagille syndrome (AGS) is caused by heterozygous mutations in JAG1, and mutations have been previously reported in about 70% of patients who meet clinical diagnostic criteria. We studied a cohort of 247 clinically well-defined patients, and using an aggressive and sequential screening approach we identified JAG1 mutations in 94% of individuals. Mutations were found in 232 out of 247 patients studied and 83 of the mutations were novel. This increase in the mutation rate was accomplished by combining rigorous clinical phenotyping, with a combination of mutation detection techniques, including fluorescence in situ hybridization (FISH), genomic and cDNA sequencing, and quantitative PCR. This higher rate of mutation identification has implications for clinical practice, facilitating genetic counseling, prenatal diagnosis, and evaluation of living-related liver transplant donors. Our results suggest that more aggressive screening may similarly increase the rate of mutation detection in other dominant and recessive disorders.

Consequences of JAG1 mutations.

BACKGROUND: Alagille syndrome (AGS) is a multi-system, autosomal dominant disorder with highly variable expressivity, caused by mutations within the Jagged1 (JAG1) gene. METHODS: We studied 53 mutation positive relatives of 34 AGS probands to ascertain the frequency of clinical findings in JAG1 mutation carriers. RESULTS: Eleven of 53 (21%) mutation positive relatives had clinical features that would have led to a diagnosis of AGS. Seventeen of the 53 (32%) relatives had mild features of AGS, revealed only after targeted evaluation following the diagnosis of a proband in their family. Twenty five of the 53 (47%) mutation positive relatives did not meet clinical criteria, and two of these individuals had no features consistent with AGS at all. The frequency of cardiac and liver disease was notably lower in the relatives than in the probands, characterising the milder end of the phenotypic spectrum. The characteristic facies of AGS was the feature with the highest penetrance, occurring almost universally in mutation positive probands and relatives. CONCLUSIONS: This study has implications for genetic counselling of families with AGS and JAG1 mutations.

Homozygosity for the V37I Connexin 26 mutation in three unrelated children with sensorineural hearing loss.

Mutations in the Connexin 26 (Cx26) gene have been found to account for approximately 20% of all childhood deafness. This number approaches 50% in documented recessive cases of hearing loss. Two mutations, 35delG and 167delT, account for the majority of reported mutations in this gene, but to date, more than 60 mutations have been described. No other single gene has yet been identified that contributes this significantly to the aetiology of hearing loss. Several mutations in this gene have been found to predominate in specific ethnic populations (167delT in Ashkenazi Jews and 235delC in Japanese individuals). While the majority of mutations found in Cx26 result in frame shifts and premature terminations, a number of missense mutations have also been identified. The V37I missense mutation has been reported as both a polymorphism and as a potentially disease-causing missense mutation. The present authors have identified three unrelated individuals with sensorineural hearing loss who are homozygous for this mutation. One individual is of Philippine ancestry, another is from a Chinese and Cambodian background, while the third is of Chinese ancestry, raising the possibility that this mutation may be more frequent among populations in eastern Asia.

Dominant paternal transmission of Cornelia de Lange syndrome: a new case and review of 25 previously reported familial recurrences.

The Cornelia de Lange syndrome (CdLS) is an autosomal dominant multisystem disorder characterized by somatic and cognitive retardation, characteristic facial features, limb abnormalities, hearing loss, and other organ system involvement. The vast majority of cases (99%) are sporadic, with rare familial occurrences having been reported. Most individuals with CdLS do not reproduce as a result of the severity of the disorder. Maternal transmission has been well documented, as have several cases of multiple-affected children being born to apparently unaffected parents. Paternal transmission has rarely been reported. A case is reported here of a father with classic features of CdLS with a similarly affected daughter. A review of the reported familial cases of CdLS is summarized.

Exclusion of linkage to the CDL1 gene region on chromosome 3q26.3 in some familial cases of Cornelia de Lange syndrome.

Cornelia de Lange Syndrome (CdLS) is a complex developmental disorder consisting of characteristic facial features, limb abnormalities, hirsutism, ophthalmologic involvement, gastroesophageal dysfunction, hearing loss, as well as growth and neurodevelopmental retardation. Most cases of CdLS appear to be sporadic. Familial cases are rare and indicate autosomal dominant inheritance. Several individuals with CdLS have been reported with chromosomal abnormalities, suggesting candidate genomic regions within which the causative gene(s) may lie. A CdLS gene location (CDL1) has been assigned to 3q26.3 based on phenotypic overlap with the duplication 3q syndrome (critical region 3q26.2-q27) and the report of a CdLS individual with a balanced de novo t(3;17)(q26.3;q23.1). It has been postulated that a gene within the dup3q critical region results in the CdLS when deleted or mutated. We have performed a linkage analysis to the minimal critical region for the dup3q syndrome (that encompasses the translocation breakpoint) on chromosome 3q in 10 rare familial cases of CdLS. Nineteen markers spanning a region of approximately 40 Mb (37 cM) were used. Results of a multipoint linkage analysis demonstrated total lod-scores that were negative across the chromosome 3q26-q27 region. In 4/10 families, lod-scores were less than -2 in the 2 cM region encompassing the translocation, while in the remaining 6/10 families, lod-scores could not exclude linkage to this region. These studies indicate that in some multicase families, the disease gene does not map to the CDL1 region at 3q26.3.

Mutation analysis of Jagged1 (JAG1) in Alagille syndrome patients.

Alagille syndrome (AGS) is an autosomal dominant disorder caused by mutations in Jagged1 (JAG1), a ligand in the evolutionarily conserved Notch signaling pathway. Previous studies have demonstrated that a wide spectrum of JAG1 mutations result in AGS. These include total gene deletions, protein truncating, splicing and missense mutations which are distributed across the coding region of the gene. Here we present results of JAG1 mutation screening by SSCP and FISH in 105 patients with AGS. For these studies, new primers were designed for 12 exons. Mutations were identified in 63/105 patients (60%). The spectrum of the JAG1 mutations presented here is consistent with previously reported results. Eighty three percent (52/63) of the mutations were protein truncating, 11% (7/63) were missense, 2% (1/63) were splice site, and 5% (3/63) were total gene deletions demonstrable by FISH. Six of the missense mutations are novel. As has been reported previously, there is no apparent relationship between genotype and clinical phenotype.

Jagged1 mutations in alagille syndrome.

We have summarized data on 233 Alagille syndrome patients reported with mutations in Jagged1 (JAG1). This data has been published by seven different laboratories in Europe, the United States, Australia, and Japan. Mutations have been demonstrated in 60-75% of patients with a clinically confirmed diagnosis of Alagille syndrome. Total gene deletions have been reported in 3-7% of patients, and the remainder have intragenic mutations. Seventy two percent (168/233) of the reported mutations lead to frameshifts that cause a premature termination codon. These mutations will either lead to a prematurely truncated protein, or alternatively, nonsense mediated decay might lead to lack of a product from that allele. Twenty three unique missense mutations were identified (13% of mutations). These were clustered in conserved regions at the 5' end of the gene, or in the EGF repeats. Splicing consensus sequence changes were identified in 15% of patients. A high frequency of de novo mutations (60-70%) has been reported. The spectrum of mutations identified is consistent with haploinsufficiency for JAG1 being a mechanism for Alagille syndrome.

Duplication of chromosome region 4q28.3-qter in monozygotic twins with discordant phenotypes.

We describe monozygotic twins with partially discordant phenotypes who were found to have a duplication of chromosome region 4q28.3-qter. The duplicated region of chromosome 4 resulted from an unbalanced segregation of a balanced maternal (4;22)(q28.3;p13) translocation. Duplication of the long arm of chromosome 4 has been described in >60 patients; however, it usually results from the unbalanced segregation of a parental balanced translocation and has an associated monosomy. Twenty cases of dup 4q without an associated monosomy have been reported, and this is the only case of dup 4q28. 3-qter. All cases of dup 4q are reviewed, and phenotypic aspects are analyzed. Issues of monozygotic twinning and other birth defects also are addressed.

Chromosomal localization, genomic characterization, and mapping to the Noonan syndrome critical region of the human Deltex (DTX1) gene.

The human Deltex (DTX1) gene encodes a cytoplasmic protein that functions as a positive regulator of the Notch signaling pathway. We have determined the genomic organization and map location of the human gene. DTX1 encodes a 2.5-kb cDNA that is composed of nine exons. The DTX1 gene maps to chromosomal region 12q24 in the vicinity of the Noonan syndrome critical region. We have fine-mapped DTX1 to within this critical region and evaluate it as a candidate gene for this disorder.

Clinical and molecular genetics of Alagille syndrome.

Alagille syndrome (AGS) is a dominantly inherited disorder characterized by bile duct paucity and resultant liver disease in combination with cardiac, skeletal, ocular, and facial abnormalities. Jagged1 (JAG1) has been identified as the AGS disease gene. It encodes a ligand in the Notch signaling pathway that is involved in cell fate determination. AGS is the first developmental disorder to be associated with this pathway. It shows highly variable expressivity, and diagnosis in mildly affected persons can be difficult without molecular analysis. Currently, JAG1 mutations are detected in about 70% of patients with AGS and include total gene deletions as well as protein truncating, splicing, and missense mutations. Mutations are located across the gene within the evolutionarily conserved motifs of the protein. There is no phenotypic difference between patients with deletion of the entire JAG1 gene and those with intragenic mutations. This suggests that haploinsufficiency for JAG1 is a mechanism causing AGS.

Jagged1 mutations in patients ascertained with isolated congenital heart defects.

Mutations in Jagged1 cause Alagille syndrome (AGS), a pleiotropic disorder with involvement of the liver, heart, skeleton, eyes, and facial structures. Cardiac defects are seen in more than 95% of AGS patients. Most commonly these are right-sided defects ranging from mild peripheral pulmonic stenosis to severe forms of tetralogy of Fallot. AGS demonstrates highly variable expressivity with respect to all of the involved systems. This leads us to hypothesize that defects in Jagged1 can be found in patients with presumably isolated heart defects, such as tetralogy of Fallot or pulmonic stenosis. Two patients with heart defects of the type seen in AGS and their relatives were investigated for alterations in the Jagged1 gene. Jagged1 was screened by a combination of cytogenetic and molecular techniques. Patient 1 was studied because of a four-generation history of pulmonic stenosis. Molecular analysis showed a point mutation in Jagged1 in the patient and her mother. Patient 2 was investigated owing to the finding of tetralogy of Fallot and a "butterfly" vertebra on chest radiograph first noted at age 5 years. She was found to have a deletion of chromosome region 20p12 that encompassed the entire Jagged1 gene. The identification of these two patients suggests that other patients with right-sided heart defects may have subtle findings of AGS and Jagged1 mutations.

Features of Alagille syndrome in 92 patients: frequency and relation to prognosis.

We have studied 92 patients with Alagille syndrome (AGS) to determine the frequency of clinical manifestations and to correlate the clinical findings with outcome. Liver biopsy specimens showed paucity of the interlobular ducts in 85% of patients. Cholestasis was seen in 96%, cardiac murmur in 97%, butterfly vertebrae in 51%, posterior embryotoxon in 78%, and characteristic facies in 96% of patients. Renal disease was present in 40% and intracranial bleeding or stroke occurred in 14% of patients. The presence of intracardiac congenital heart disease was the only clinical feature statistically associated with increased mortality (P <.001). Initial measures of hepatic function in infancy including absence of scintiscan excretion were not predictive of risk for transplantation or increased mortality. The hepatic histology of these AGS patients showed a significant increase in the prevalence of bile duct paucity (P =.002) and fibrosis (P <.001) with increasing age. Liver transplantation for hepatic decompensation was necessary in 21% (19 of 92) of patients with 79% survival 1-year posttransplantation. Current mortality is 17% (16 of 92). The factors that contributed significantly to mortality were complex congenital heart disease (15%), intracranial bleeding (25%), and hepatic disease or hepatic transplantation (25%). The 20-year predicted life expectancy is 75% for all patients, 80% for those not requiring liver transplantation, and 60% for those who required liver transplantation.

Spectrum and frequency of jagged1 (JAG1) mutations in Alagille syndrome patients and their families.

Alagille syndrome (AGS) is a dominantly inherited disorder characterized by liver disease in combination with heart, skeletal, ocular, facial, renal, and pancreatic abnormalities. We have recently demonstrated that Jagged1 (JAG1) is the AGS gene. JAG1 encodes a ligand in the Notch intercellular signaling pathway. AGS is the first developmental disorder to be associated with this pathway and the first human disorder caused by a Notch ligand. We have screened 54 AGS probands and family members to determine the frequency of mutations in JAG1. Three patients (6%) had deletions of the entire gene. Of the remaining 51 patients, 35 (69%) had mutations within JAG1, identified by SSCP analysis. Of the 35 identified intragenic mutations, all were unique, with the exceptions of a 5-bp deletion in exon 16, seen in two unrelated patients, and a C insertion at base 1618 in exon 9, also seen in two unrelated patients. The 35 intragenic mutations included 9 nonsense mutations (26%); 2 missense mutations (6%); 11 small deletions (31%), 8 small insertions (23%), and 1 complex rearrangement (3%), all leading to frameshifts; and 4 splice-site mutations (11%). The mutations are spread across the coding sequence of the gene within the evolutionarily conserved motifs of the JAG1 protein. There is no phenotypic difference between patients with deletions of the entire JAG1 gene and those with intragenic mutations, which suggests that one mechanism involved in AGS is haploinsufficiency. The two missense mutations occur at the same amino acid residue. The mechanism by which these missense mutations lead to the disease is not yet understood; however, they suggest that mechanisms other than haploinsufficiency may result in the AGS phenotype.

Mutations in the human Jagged1 gene are responsible for Alagille syndrome.

Alagille syndrome (AGS) is an autosomal-dominant disorder characterized by intrahepatic cholestasis and abnormalities of heart, eye and vertebrae, as well as a characteristic facial appearance. Identification of rare AGS patients with cytogenetic deletions has allowed mapping of the gene of 20p12. We have generated a cloned contig of the critical region and used fluorescent in situ hybridization on cells from patients with submicroscopic deletions to narrow the candidate region to only 250 kb. Within this region we identified JAG1, the human homologue of rat Jagged1, which encodes a ligand for the Notch receptor. Cell-cell Jagged/Notch interactions are known to be critical for determination of cell fates in early development, making this an attractive candidate gene for a developmental disorder in humans. Determining the complete exon-intron structure of JAG1 allowed detailed mutational analysis of DNA samples from non-deletion AGS patients, revealing three frame-shift mutations, two splice donor mutations and one mutation abolishing RNA expression from the altered allele. We conclude that AGS is caused by haploinsufficiency of JAG1.

Alagille syndrome is caused by mutations in human Jagged1, which encodes a ligand for Notch1.

Alagille syndrome is an autosomal dominant disorder characterized by abnormal development of liver, heart, skeleton, eye, face and, less frequently, kidney. Analyses of many patients with cytogenetic deletions or rearrangements have mapped the gene to chromosome 20p12, although deletions are found in a relatively small proportion of patients (< 7%). We have mapped the human Jagged1 gene (JAG1), encoding a ligand for the developmentally important Notch transmembrane receptor, to the Alagille syndrome critical region within 20p12. The Notch intercellular signalling pathway has been shown to mediate cell fate decisions during development in invertebrates and vertebrates. We demonstrate four distinct coding mutations in JAG1 from four Alagille syndrome families, providing evidence that it is the causal gene for Alagille syndrome. All four mutations lie within conserved regions of the gene and cause translational frameshifts, resulting in gross alterations of the protein product Patients with cytogenetically detectable deletions including JAG1 have Alagille syndrome, supporting the hypothesis that haploinsufficiency for this gene is one of the mechanisms causing the Alagille syndrome phenotype.

Deletions of 20p12 in Alagille syndrome: frequency and molecular characterization.

Alagille syndrome is an autosomal dominant disorder comprising cholestasis (associated with intrahepatic bile duct paucity), characteristic facial appearance, and cardiac, ocular and skeletal defects. Multiple patients have been reported with deletions or translocation involving 20p11.23-p12, providing evidence for the localization of the disease gene to this region. Fifty-six Alagille syndrome patients have been studied by cytogenetic and/or molecular analysis to determine the frequency of detectable abnormalities of 20p12. Two of fifty-six patients studied by cytogenetic analysis had abnormalities: an interstitial deletion in one patient and a translocation in another. Of forty-five patients studied by molecular analysis, three were found to have deletions of 20p, including the two patients identified with cytogenetic abnormalities. Molecular and molecular cytogenetic (FISH) analysis of the translocation (46,XX,t(2;20)(q21.3p12)) demonstrated a deletion at the translocation breakpoint. The deletions identified in the three patients are overlapping, contributing to the delineation of an Alagille syndrome critical region within 20p12. This region lies between markers D20S41 and D20S162. The frequency of detectable cytogenetic abnormalities of 20p12 in this group of Alagille patients is 2/56 (3.6%), and the frequency of molecular deletions is 3/45 (6.7%). This is considerably lower than the frequency of deletions observed in contiguous gene deletion syndromes suggesting that Alagille syndrome may be caused by the alteration of a single gene.