Defective intracellular transport and processing of JAG1 missense mutations in Alagille syndrome.

Jagged1 (JAG1) is a cell surface ligand in the Notch signaling pathway and mutations in this gene cause Alagille syndrome (AGS). JAG1 mutations have been identified in 60-70% of AGS patients studied, and these include total gene deletions ( approximately 6%), protein-truncating mutations (insertions, deletions and nonsense mutations) (82%) and missense mutations (12%). Based on the finding that total JAG1 deletions cause AGS, haploinsufficiency has been hypothesized to be a mechanism for disease causation; however, the mechanism by which missense mutations cause disease is not understood. To date, 25 unique missense mutations have been observed in AGS patients. Missense mutations are non-randomly distributed across the protein with clusters at the 5' end of the protein, in the conserved DSL domain, and two clusters within the EGF repeats. To understand the effect of the missense mutations on protein localization and function, we have studied four missense mutations (R184H, L37S, P163L and P871R). In two assays of JAG1 function, R184H and L37S are associated with loss of Notch signaling activity relative to wild-type JAG1. Neither R184H or L37S is present on the cell surface and both are abnormally glycosylated. Furthermore, these mutations lead to abnormal accumulation of the protein, possibly in the endoplasmic reticulum. Both P163L and P871R are associated with normal levels of Notch signaling activity and are present on the cell surface, consistent with these changes being polymorphisms rather than disease-causing mutations.

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.

Jagged1 (JAG1) mutation detection in an Australian Alagille syndrome population.

Alagille syndrome (AGS) is an autosomal dominant disorder characterized by abnormal development of the liver, heart, skeleton, eye, and face. Mutations in the Jagged1 gene (JAG1) have been found to result in the AGS phenotype and both protein truncating mutations and missense mutations have been identified. Using single stranded conformational polymorphism analysis we have screened 22 AGS affected individuals from 19 families for mutations within Jagged1. Twelve distinct Jagged1 mutations were identified in 15 (68.2%) of the 22 AGS cases, seven of which are novel. The mutations include three small deletions (25%), two small insertions (16.6%), three missense mutations (25%), two nonsense mutations (16.6%), and two splice-site mutations (16.6%). These mutations are spread across the entire coding sequence of the gene and most are localized to highly conserved motifs of the protein predicted to be important for Jagged1 function. One-half of the mutations found in this study are located between exons 9 and 12, a region constituting only 12% of the coding sequence. A splice-donor site mutation in intron 11 was shown to cause aberrant splicing of Jagged1 mRNA, consequently terminating translation prematurely in exon 12. The results of this study are consistent with the proposal that either haploinsufficiency for wild type Jagged1 and/or dominant negative effects produced by mutated Jagged1 are responsible for the AGS phenotype.

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.

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.