Genetic disturbances during dental development influence variation of number and shape of the dentition. In this study, we tested if genetic variation in enamel formation genes is associated with molar-incisor hypomineralization (MIH), also taking into consideration caries experience. DNA samples from 163 cases with MIH and 82 unaffected controls from Turkey, and 71 cases with MIH and 89 unaffected controls from Brazil were studied. Eleven markers in five genes [ameloblastin (AMBN), amelogenin (AMELX), enamelin (ENAM), tuftelin (TUFT1), and tuftelin-interacting protein 11 (TFIP11)] were genotyped by the TaqMan method. Chi-square was used to compare allele and genotype frequencies between cases with MIH and controls. In the Brazilian data, distinct caries experience within the MIH group was also tested for association with genetic variation in enamel formation genes. The ENAM rs3796704 marker was associated with MIH in both populations (Brazil: p=0.03; OR=0.28; 95% C.I.=0.06–1.0; Turkey: p=1.22e–012; OR=17.36; 95% C.I.=5.98–56.78). Associations between TFIP11 (p=0.02), ENAM (p=0.00001), and AMELX (p=0.01) could be seen with caries independent of having MIH or genomic DNA copies of Streptococcus mutans detected by real time PCR in the Brazilian sample. Several genes involved in enamel formation appear to contribute to MIH.
Amelogenesis imperfecta (AI) is a genetically and clinically heterogeneous group of inherited dental enamel defects without any other nonoral symptoms. Recently, a disease-causing nonsense mutation (c.406C>T) in a novel gene, FAM20A, was identified in a large consanguineous family affected by AI with gingival hyperplasia. We performed mutational analyses on nine AI families with similar phenotypes and identified three homozygous mutations (c.34_35delCT, c.813-2A>G, c.1175_1179delGGCTC) in three families and a compound heterozygous mutation (c.[590-2A>G] + [c.826C>T]) in one family. An in vitro splicing assay with a minigene confirmed the mutations located in the splicing acceptor site caused the deletion of exons 3 and 6, respectively. Taking into consideration the locations of the nonsense and frameshift mutations, the mutant transcripts are most likely degraded by nonsense-mediated mRNA degradation and it results in a loss of the FAM20A protein. This study confirms the importance of the FAM20A protein in enamel biomineralization as well as tooth eruption.
Non-syndromic amelogenesis imperfecta (AI) is a collection of isolated inherited enamel malformations that follow X-linked, autosomal-dominant, or autosomal-recessive patterns of inheritance. The AI phenotype is also found in syndromes. We hypothesized that whole-exome sequencing of AI probands showing simplex or recessive patterns of inheritance would identify causative mutations among the known candidate genes for AI. DNA samples obtained from 12 unrelated probands with AI were analyzed. Disease-causing mutations were identified in three of the probands: a novel single-nucleotide deletion in both KLK4 alleles (g.6930delG; c.245delG; p.Gly82Alafs*87) that shifted the reading frame, a novel missense transition mutation in both MMP20 alleles (g.15390A>G; c.611A>G; p.His204Arg) that substituted arginine for an invariant histidine known to coordinate a structural zinc ion, and a previously described nonsense transition mutation in a single allele of FAM83H (c.1379G>A; g.5663G>A; p.W460*). Erupted molars and cross-sections from unerupted parts of the mandibular incisors of Mmp20 null mice were characterized by scanning electron microscopy. Their enamel malformations closely correlated with the enamel defects displayed by the proband with the MMP20 mutation. We conclude that whole-exome sequencing is an effective means of identifying disease-causing mutations in kindreds with AI, and this technique should prove clinically useful for this purpose.
Amelogenesis imperfecta (AI) is a collection of isolated (non‐syndromic) inherited diseases affecting dental enamel formation or a clinical phenotype in syndromic conditions. We characterized three consanguineous AI families with generalized irregular hypoplastic enamel with rapid attrition that perfectly segregated with homozygous defects in a novel gene: RELT that is a member of the tumor necrosis factor receptor superfamily (TNFRSF). RNAscope in situ hybridization of wild‐type mouse molars and incisors showed specific Relt mRNA expression by secretory stage ameloblasts and by odontoblasts. Relt −/− mice generated by CRISPR/Cas9 exhibited incisor and molar enamel malformations. Relt −/− enamel had a rough surface and underwent rapid attrition. Normally unmineralized spaces in the deep enamel near the dentino‐enamel junction (DEJ) were as highly mineralized as the adjacent enamel, which likely altered the mechanical properties of the DEJ. Phylogenetic analyses showed the existence of selective pressure on RELT gene outside of tooth development, indicating that the human condition may be syndromic, which possibly explains the history of small stature and severe childhood infections in two of the probands. Knowing a TNFRSF member is critical during the secretory stage of enamel formation advances our understanding of amelogenesis and improves our ability to diagnose human conditions featuring enamel malformations.
Molar incisor hypomineralization (MIH) is an enamel condition characterized by lesions ranging in color from white to brown which present rapid caries progression, and mainly affects permanent first molars and incisors. These enamel defects usually occur when there are disturbances during the mineralization or maturation stage of amelogenesis. Both genetic and environmental factors have been suggested to play roles in MIH’s development, but no conclusive risk factors have shown the source of the disease. During head and neck development, the interferon regulatory factor 6 (IRF6) gene is involved in the structure formation of the oral and maxillofacial regions, and the transforming growth factor alpha (TGFA) is an essential cell regulator, acting during proliferation, differentiation, migration and apoptosis. In this present study, it was hypothesized that these genes interact and contribute to predisposition of MIH. Environmental factors affecting children that were 3 years of age or older were also hypothesized to play a role in the disease etiology. Those factors included respiratory issues, malnutrition, food intolerance, infection of any sort and medication intake. A total of 1,065 salivary samples from four different cohorts were obtained, and DNA was extracted from each sample and genotyped for nine different single nucleotide polymorphisms. Association tests and logistic regression implemented in PLINK were used for analyses. A potential interaction between TGFA rs930655 with all markers tested in the cohort from Turkey was identified. These interactions were not identified in the remaining cohorts. Associations (p<0.05) between the use of medication after three years of age and MIH were also found, suggesting that conditions acquired at the age children start to socialize might contribute to the development of MIH.
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