Amelogenesis imperfecta (AI) is a collective term referring to inherited malformation of tooth enamel without other non-oral symptoms. Junctional epidermolysis bullosa (JEB) is a group of recessive genetic disorders featuring skin fragility, easy blistering and AI. Carriers having only one defective allele usually have no disease phenotype; however, rarely, heterozygous conditions can cause autosomal-dominant AI (ADAI) with no or very mild skin fragility. Recently, LAMB3 mutations causing non-syndromic AI have been identified in three families with an autosomal-dominant inheritance pattern 1, 2. We recruited two families with generalized hypoplastic AI without any other medical conditions. The proband of family 1 was a 2-year-old girl presenting with generalized, irregular hypoplastic enamel in all her primary teeth. Newly erupted primary second molars showed small islands of enamel on the cusp tips and cervical areas. She inherited enamel hypoplasia from her mother. Other family members (a grandmother and uncle) were also affected similarly (Fig. 1a–d). The proband of family 2 was an 8-year-old boy who also presented with enamel hypoplasia in all his primary and permanent teeth. Thermal sensitivity was not severe and hypoplastic grooves and pits accentuated the mamelon structures especially in the mandibular incisors. Interestingly, it was reported by his father that no one else in this family was affected by enamel defects. However, close examination of the father of the proband revealed hypoplastic grooves in several teeth (Fig. 1e–i). Whole exome sequencings identified novel frameshift LAMB3 mutations (NM_000228.2: c.3357_3358insC in family 1 and c.3463_3475delGAGCAGATCCGTG in family 2). The mutation in family 1 (c.3357_3358insC) was located only 25 bp away from the splicing donor site of exon 22. A shift in the reading frame would not generate an early termination codon within this exon and would not affect normal mRNA splicing. Therefore, the mutant transcript would escape non-sense-mediated mRNA decay (NMD) and generate a truncated protein with 39 novel amino acids instead of a C-terminal with 53 amino acids in the wild-type LAMB3 (p.Met1120fs*40). The mutation in family 2 (c.3463_3475delGAGCAGATCCGTG) would also escape NMD because of its location in the last exon producing a truncated protein with 50 novel amino acids replacing the C-terminal 18 amino acids of the wild-type LAMB3 (p.Glu1155fs*51) (Fig. 1J). The extremely mild clinical phenotype in the father and grandmother could be caused by the fact that the mutation replaced only 18 amino acids in the C-terminus. JEB is caused by mutations in LAMA3, LAMB3, LAMC2, and COL17A1. Among them, LAMB3 mutations are responsible for about 80% of all JEB cases. Laminin-332 is a basement membrane protein and a heterotrimer composed of three subunits encoded by the LAMA3, LAMB3, and LAMC2 3. Even though mutations in both alleles cause JEB with AI, a single defective allele in a carrier of JEB could result in AI with little or no skin phenotype. Two cases in COL17A1 and one case in LAMA3 heterozygous carrier have been reported to have ADAI with no or a mild skin phenotype 4, 5. Recently, a heterozygous LAMB3 mutation (c.3392_3393insG) has been reported to cause ADAI in a family 1. Subsequently, two more mutations (c.3446_3453delGACTGGAG and c.3431C>A) have been identified to cause ADAI in two families 2. All three mutations are non-sense or frameshift mutations, but the truncated proteins are expected to be expressed escaping NMD because of their location on the last exon. Two novel LAMB3 mutations identified in this study are also expected to escape NMD and be expressed as truncated proteins. Interestingly, highly variable expressivity was confirmed in family 2, while all the affected members of family 1 exhibited consistently a similar hypoplastic enamel phenotype. The mutation in family 2 replaces only 18 amino acids at the C-terminus and produces 1154 amino acids of wild-type LAMB3. This small replacement would explain the phenotypic variation in family 2 (Fig. 1j). The authors are grateful to all family members who participated in this study. This work was supported by grants from the Bio & Medical Technology Development Program (2013037491), the Science Research Center grant to Bone Metabolism Research Center (2008-0062614) by the Korea Research Foundation Grant funded by the Korean government (MEST). K.-E. Leea J. Koa C.G. Tran Lea T.J. Shina H.-K. Hyuna S.-H. Leea J.-W. Kima,b aDepartment of Pediatric Dentistry & Dental Research Institute, School of Dentistry Seoul National University, Seoul, South Korea bDepartment of Molecular Genetics & Dental Research Institute School of Dentistry, Seoul National University, Seoul, South Korea
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