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2. PAX9 mutations and genetic synergism in familial tooth agenesis

Author

Kuan‐Yu Chu, Yin‐Lin Wang, Jung‐Tsu Chen, Chia‐Hui Lin, Chung‐Chen Jane Yao, Yi‐Jane Chen, Huan‐Wen Chen, James P. Simmer, Jan C.‐C. Hu, and Shih‐Kai Wang

Subjects
History and Philosophy of Science, General Neuroscience, General Biochemistry, Genetics and Molecular Biology
Published
2023
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4. Mouse Dspp frameshift model of human dentinogenesis imperfecta

Author

Qian Xu, Tian Liang, Charles E. Smith, Hong Zhang, Jan C.-C. Hu, Jung-Wook Kim, Yongbo Lu, Yuanyuan Hu, Chuhua Zhang, James P. Simmer, Thomas L. Saunders, and Shih Kai Wang

Subjects
Male, Molar, Dentinogenesis imperfecta, Sialoglycoproteins, Science, Diseases, Mice, Transgenic, Article, Frameshift mutation, Mice, Dentin sialophosphoprotein, stomatognathic system, Dentinogenesis Imperfecta, Developmental biology, Genetics, medicine, Dentin, Animals, Humans, Dental Enamel, Frameshift Mutation, Extracellular Matrix Proteins, Multidisciplinary, Enamel paint, Chemistry, Dentin dysplasia, Phosphoproteins, medicine.disease, Molecular biology, Disease Models, Animal, stomatognathic diseases, Phenotype, medicine.anatomical_structure, Dentinal Tubule, visual_art, visual_art.visual_art_medium, Medicine, Female, Structural biology, Tooth
Abstract

Non-syndromic inherited defects of tooth dentin are caused by two classes of dominant negative/gain-of-function mutations in dentin sialophosphoprotein (DSPP): 5′ mutations affecting an N-terminal targeting sequence and 3′ mutations that shift translation into the − 1 reading frame. DSPP defects cause an overlapping spectrum of phenotypes classified as dentin dysplasia type II and dentinogenesis imperfecta types II and III. Using CRISPR/Cas9, we generated a Dspp−1fs mouse model by introducing a FLAG-tag followed by a single nucleotide deletion that translated 493 extraneous amino acids before termination. Developing incisors and/or molars from this mouse and a DsppP19L mouse were characterized by morphological assessment, bSEM, nanohardness testing, histological analysis, in situ hybridization and immunohistochemistry. DsppP19L dentin contained dentinal tubules but grew slowly and was softer and less mineralized than the wild-type. DsppP19L incisor enamel was softer than normal, while molar enamel showed reduced rod/interrod definition. Dspp−1fs dentin formation was analogous to reparative dentin: it lacked dentinal tubules, contained cellular debris, and was significantly softer and thinner than Dspp+/+ and DsppP19L dentin. The Dspp−1fs incisor enamel appeared normal and was comparable to the wild-type in hardness. We conclude that 5′ and 3′ Dspp mutations cause dental malformations through different pathological mechanisms and can be regarded as distinct disorders.

Published
2021

6. Phenotypic variability in LAMA3-associated amelogenesis imperfecta

Author

Shih‐Kai Wang, Hong Zhang, Yin‐Lin Wang, Figen Seymen, Mine Koruyucu, James P. Simmer, and Jan C.‐C. Hu

Subjects
Otorhinolaryngology, General Dentistry
Abstract

Amelogenesis imperfecta (AI) is defined as inherited enamel malformations. LAMA3 (laminin alpha-3) encodes a critical protein component of the basement membrane (laminin-332). Individuals carrying heterozygous LAMA3 mutations have previously been shown to have localized enamel defects. This study aimed to define clinical phenotypes and to discern the genetic etiology for four AI kindreds.Whole-exome analyses were conducted to search for sequence variants associated with the disorder, and micro-computed tomography (μCT) to characterize the enamel defects.The predominant enamel phenotype was generalized thin enamel with defective pits and grooves. Horizonal bands of hypoplastic enamel with chalky-white discoloration and enamel hypomineralization were also observed and demonstrated by μCT analyses of affected teeth. Four disease-causing LAMA3 mutations (NM_198129.4:c.3712dup; c.5891dup; c.7367del; c.9400G C) were identified. Compound heterozygous MMP20 mutations (NM_004771.4:c.539A G; c.692C T) were also found in one proband with more severe enamel defects, suggesting a mutational synergism on disease phenotypes. Further analyses of the AI-causing mutations suggested that both α3A (short) and α3B (long) isoforms of LAMA3 are essential for enamel formation.Heterozygous LAMA3 mutations can cause generalized enamel defects (AI1A) with variable expressivity. Laminin-332 is critical not only for appositional growth but also enamel maturation.

Published
2022

7. Enamel defects in Acp4

Author

Tian, Liang, Shih-Kai, Wang, Charles, Smith, Hong, Zhang, Yuanyuan, Hu, Figen, Seymen, Mine, Koruyucu, Yelda, Kasimoglu, Jung-Wook, Kim, Chuhua, Zhang, Thomas L, Saunders, James P, Simmer, and Jan C-C, Hu

Subjects
Mice, Dental Enamel Proteins, Amelogenesis, Amelogenesis Imperfecta, Acid Phosphatase, Mutation, Ameloblasts, Animals, Humans, Histidine
Abstract

Human ACP4 (OMIM*606362) encodes a transmembrane protein that belongs to histidine acid phosphatase (ACP) family. Recessive mutations in ACP4 cause non-syndromic hypoplastic amelogenesis imperfecta (AI1J, OMIM#617297). While ACP activity has long been detected in developing teeth, its functions during tooth development and the pathogenesis of ACP4-associated AI remain largely unknown. Here, we characterized 2 AI1J families and identified a novel ACP4 disease-causing mutation: c.774_775del, p.Gly260Aspfs*29. To investigate the role of ACP4 during amelogenesis, we generated and characterized Acp4

Published
2022

8. FAM83H and Autosomal Dominant Hypocalcified Amelogenesis Imperfecta

Author

Shih Kai Wang, J F Liu, J.-W. Kim, C Y Hu, Honghao Zhang, James P. Simmer, S Chadha, and J.C.-C. Hu

Subjects
0301 basic medicine, Genetics, Scaffold protein, Mutation, Endoplasmic reticulum, Genetic disorder, Research Reports, FAM83H, 030206 dentistry, Biology, medicine.disease_cause, medicine.disease, Phenotype, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Secretory protein, medicine, Casein kinase 1, General Dentistry
Abstract

Autosomal dominant hypocalcified amelogenesis imperfecta (ADHCAI; OMIM #130900) is a genetic disorder exhibiting severe hardness defects and reduced fracture toughness of dental enamel. While the condition is nonsyndromic, it can be associated with other craniofacial anomalies, such as malocclusions and delayed or failed tooth eruption. Truncation mutations in FAM83H (OMIM *611927) are hitherto the sole cause of ADHCAI. With human genetic studies, Fam83h knockout and mutation–knock-in mouse models indicated that FAM83H does not serve a critical physiologic function during enamel formation and suggested a neomorphic mutation mechanism causing ADHCAI. The function of FAM83H remains obscure. FAM83H has been shown to interact with various isoforms of casein kinase 1 (CK1) and keratins and to mediate organization of keratin cytoskeletons and desmosomes. By considering FAM83H a scaffold protein to anchor CK1s, further molecular characterization of the protein could gain insight into its functions. In this study, we characterized 9 kindreds with ADHCAI and identified 3 novel FAM83H truncation mutations: p.His437*, p.Gln459*, and p.Glu610*. Some affected individuals exhibited hypoplastic phenotypes, in addition to the characteristic hypocalcification enamel defects, which have never been well documented. Failed eruption of canines or second molars in affected persons was observed in 4 of the families. The p.Glu610* mutation was located in a gap area (amino acids 470 to 625) within the zone of previously reported pathogenic variants (amino acids 287 to 694). In vitro pull-down studies with overexpressed FAM83H proteins in HEK293 cells demonstrated an interaction between FAM83H and SEC16A, a protein component of the COP II complex at endoplasmic reticulum exit sites. The interaction was mediated by the middle part (amino acids 287 to 657) of mouse FAM83H protein. Results of this study significantly extended the phenotypic and genotypic spectrums of FAM83H-associated ADHCAI and suggested a role for FAM83H in endoplasmic reticulum–to–Golgi vesicle trafficking and protein secretion (dbGaP phs001491.v1.p1).

Published
2020
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9. The Modified Shields Classification and 12 Families with Defined

Author

James P, Simmer, Hong, Zhang, Sophie J H, Moon, Lori A-J, Donnelly, Yuan-Ling, Lee, Figen, Seymen, Mine, Koruyucu, Hui-Chen, Chan, Kevin Y, Lee, Suwei, Wu, Chia-Lan, Hsiang, Anthony T P, Tsai, Rebecca L, Slayton, Melissa, Morrow, Shih-Kai, Wang, Edward D, Shields, and Jan C-C, Hu

Subjects
Extracellular Matrix Proteins, Mice, Dentinogenesis Imperfecta, Sialoglycoproteins, Mutation, Animals, Humans, Phosphoproteins, Pedigree
Abstract

Mutations in Dentin Sialophosphoprotein (

Published
2022

10. Enamel defects in Acp4R110C/R110C mice and human ACP4 mutations

Author

Tian Liang, Shih-Kai Wang, Charles Smith, Hong Zhang, Yuanyuan Hu, Figen Seymen, Mine Koruyucu, Yelda Kasimoglu, Jung-Wook Kim, Chuhua Zhang, Thomas L. Saunders, James P. Simmer, Jan C.-C. Hu, and Seymen, Figen

Subjects
Multidisciplinary, ACP4
Abstract

Human ACP4 (OMIM*606362) encodes a transmembrane protein that belongs to histidine acid phosphatase (ACP) family. Recessive mutations in ACP4 cause non-syndromic hypoplastic amelogenesis imperfecta (AI1J, OMIM#617297). While ACP activity has long been detected in developing teeth, its functions during tooth development and the pathogenesis of ACP4-associated AI remain largely unknown. Here, we characterized 2 AI1J families and identified a novel ACP4 disease-causing mutation: c.774_775del, p.Gly260Aspfs*29. To investigate the role of ACP4 during amelogenesis, we generated and characterized Acp4R110C mice that carry the p.(Arg110Cys) loss-of-function mutation. Mouse Acp4 expression was the strongest at secretory stage ameloblasts, and the protein localized primarily at Tomes’ processes. While Acp4 heterozygous (Acp4+/R110C) mice showed no phenotypes, incisors and molars of homozygous (Acp4R110C/R110C) mice exhibited a thin layer of aplastic enamel with numerous ectopic mineralized nodules. Acp4R110C/R110C ameloblasts appeared normal initially but underwent pathology at mid-way of secretory stage. Ultrastructurally, sporadic enamel ribbons grew on mineralized dentin but failed to elongate, and aberrant needle-like crystals formed instead. Globs of organic matrix accumulated by the distal membranes of defective Tomes’ processes. These results demonstrated a critical role for ACP4 in appositional growth of dental enamel probably by processing and regulating enamel matrix proteins around mineralization front apparatus.

Published
2022

11. The Modified Shields Classification and 12 Families with Defined DSPP Mutations

Author

James P. Simmer, Hong Zhang, Sophie J. H. Moon, Lori A-J. Donnelly, Yuan-Ling Lee, Figen Seymen, Mine Koruyucu, Hui-Chen Chan, Kevin Y. Lee, Suwei Wu, Chia-Lan Hsiang, Anthony T. P. Tsai, Rebecca L. Slayton, Melissa Morrow, Shih-Kai Wang, Edward D. Shields, and Jan C.-C. Hu

Subjects
stomatognathic diseases, stomatognathic system, dentinogenesis imperfecta, Shields Classification, DSPP mutations, dentin dysplasia, enamel malformations, whole-exome sequencing (WES), Single Molecule Real-Time (SMRT) DNA sequencing, Genetics, Genetics (clinical)
Abstract

Mutations in Dentin Sialophosphoprotein (DSPP) are known to cause, in order of increasing severity, dentin dysplasia type-II (DD-II), dentinogenesis imperfecta type-II (DGI-II), and dentinogenesis imperfecta type-III (DGI-III). DSPP mutations fall into two groups: a 5′-group that affects protein targeting and a 3′-group that shifts translation into the −1 reading frame. Using whole-exome sequence (WES) analyses and Single Molecule Real-Time (SMRT) sequencing, we identified disease-causing DSPP mutations in 12 families. Three of the mutations are novel: c.53T>C/p.(Val18Ala); c.3461delG/p.(Ser1154Metfs*160); and c.3700delA/p.(Ser1234Alafs*80). We propose genetic analysis start with WES analysis of proband DNA to identify mutations in COL1A1 and COL1A2 causing dominant forms of osteogenesis imperfecta, 5′-DSPP mutations, and 3′-DSPP frameshifts near the margins of the DSPP repeat region, and SMRT sequencing when the disease-causing mutation is not identified. After reviewing the literature and incorporating new information showing distinct differences in the cell pathology observed between knockin mice with 5′-Dspp or 3′-Dspp mutations, we propose a modified Shields Classification based upon the causative mutation rather than phenotypic severity such that patients identified with 5′-DSPP defects be diagnosed as DGI-III, while those with 3′-DSPP defects be diagnosed as DGI-II.

Published
2022
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12. Synergistic Mutations of LRP6 and WNT10A in Familial Tooth Agenesis

Author

Jung-Tsu Chen, Yi-Ping Wang, Yu-Ren Chou, Shih Kai Wang, Jan C.-C. Hu, Kuan-Yu Chu, James P. Simmer, and Yin-Lin Wang

Subjects
Proband, precision medicine, Medicine (miscellaneous), Biology, digenic inheritance, Article, stomatognathic system, variable expressivity, WNT signaling, medicine, Missense mutation, oligodontia, Exome, Gene, Exome sequencing, Genetics, incomplete penetrance, tooth development, medicine.disease, Phenotype, Penetrance, Hypodontia, stomatognathic diseases, genetic mutation, hypodontia, Medicine, exome sequencing
Abstract

Familial tooth agenesis (FTA), distinguished by developmental failure of selected teeth, is one of the most prevalent craniofacial anomalies in humans. Mutations in genes involved in WNT/β-catenin signaling, including AXIN2&nbsp, WNT10A, WNT10B, LRP6, and KREMEN1, are known to cause FTA. However, mutational interactions among these genes have not been fully explored. In this study, we characterized four FTA kindreds with LRP6 pathogenic mutations: p.(Gln1252*), p.(Met168Arg), p.(Ala754Pro), and p.(Asn1075Ser). The three missense mutations were predicted to cause structural destabilization of the LRP6 protein. Two probands carrying both an LRP6 mutant allele and a WNT10A variant exhibited more severe phenotypes, suggesting mutational synergism or digenic inheritance. Biallelic LRP6 mutations in a patient with many missing teeth further supported the dose-dependence of LRP6-associated FTA. Analysis of 21 FTA cases with 15 different LRP6 loss-of-function mutations revealed high heterogeneity of disease severity and a distinctive pattern of missing teeth, with maxillary canines being frequently affected. We hypothesized that various combinations of sequence variants in WNT-related genes can modulate WNT signaling activities during tooth development and cause a wide spectrum of tooth agenesis severity, which highlights the importance of exome/genome analysis for the genetic diagnosis of FTA in this era of precision medicine.

Published
2021

13. A Genetic Model for the Secretory Stage of Dental Enamel Formation

Author

Jan C.-C. Hu, Charles E. Smith, Yong-Hee Chun, Yuanyuan Hu, James P. Simmer, Jung-Wook Kim, Yasuo Yamakoshi, Tian Liang, Shih Kai Wang, Shelly Zhang, and John D. Bartlett

Subjects
Integrins, Integrin, Article, Mice, stomatognathic system, Dental Enamel Proteins, Structural Biology, Laminin, Amelogenesis, Genetic model, Dentin, medicine, Ameloblasts, Animals, Humans, Dental Enamel, biology, Enamel paint, Models, Genetic, Chemistry, Cell biology, stomatognathic diseases, medicine.anatomical_structure, visual_art, Ultrastructure, biology.protein, visual_art.visual_art_medium, Microscopy, Electron, Scanning, Collagen, Ameloblast
Abstract

The revolution in genetics has rapidly increased our knowledge of human and mouse genes that are critical for the formation of dental enamel and helps us understand how enamel evolved. In this graphical review we focus on the roles of 41 genes that are essential for the secretory stage of amelogenesis when characteristic enamel mineral ribbons initiate on dentin and elongate to expand the enamel layer to the future surface of the tooth. Based upon ultrastructural analyses of genetically modified mice, we propose a molecular model explaining how a cell attachment apparatus including collagen 17, α6s4 and αvs6 integrins, laminin 332, and secreted enamel proteins could attach to individual enamel mineral ribbons and mold their cross-sectional dimensions as they simultaneously elongate and orient them in the direction of the retrograde movement of the ameloblast membrane.

Published
2021

14. Transcriptome analysis of gingival tissues of enamel‐renal syndrome

Author

Yi-Ping Wang, Wen‐Lan Zhong, James P. Simmer, Shih Kai Wang, and Hung‐Ying Lin

Subjects
Adult, Male, 0301 basic medicine, Pathology, medicine.medical_specialty, Amelogenesis Imperfecta, Gingiva, Biology, Article, Transcriptome, 03 medical and health sciences, Exon, 0302 clinical medicine, Dental Enamel Proteins, medicine, Humans, Frameshift Mutation, Gene Expression Profiling, ALPL, Histology, 030206 dentistry, Hyperplasia, medicine.disease, Epithelium, Nephrocalcinosis, 030104 developmental biology, medicine.anatomical_structure, Periodontics, Immunohistochemistry, Extracellular matrix organization
Abstract

BACKGROUND AND OBJECTIVE: Biallelic loss-of-function mutations of human FAM20A have been known to cause enamel-renal syndrome (ERS), featured by agenesis of dental enamel, nephrocalcinosis, and other orodental abnormalities, including gingival hyperplasia. However, while the histopathology of this gingival anomaly has been analyzed, its underlying molecular mechanism remains largely unknown. This study aimed to unravel the pathogenesis of gingival hyperplasia in ERS. METHODS: Whole exome sequencing was conducted for an ERS case. Transcriptome analyses, using RNA sequencing, of the patient’s gingiva were performed to unravel dysregulated molecules and aberrant biological processes underlying the gingival pathology of ERS, which was further confirmed by histology and immunohistochemistry. RESULTS: Two novel frameshift FAM20A mutations in Exon 1 (g.5417delG; c.129delG; p.Cys44Alafs*101) and Exon 5 (g.62248_62249delAG; c.734_735delAG; p.Glu245Glyfs*11) were identified. Transcriptional profiling of patient’s gingival tissue revealed a total of 1683 genes whose expression had increased (1129 genes) or decreased (554 genes) at least 2-fold compared to control gingival tissues. There were 951 Gene Ontology (GO) terms of biological process being significantly over-represented or under-represented. While GOs involved in extracellular matrix organization, angiogenesis, biomineralization, and epithelial cell proliferation appeared to be activated in ERS gingiva, genes related to keratinocyte differentiation, epithelial development, and keratinization were of decreased expression. FAM20A immunohistochemistry revealed a strong reactivity at the suprabasal layers of epithelium in control gingiva but showed a significantly diminished and scattered signal in ERS tissues. For genes showing significant over-expression in the transcriptome analyses, namely ALPL, SPARC, and ACTA2, an increased immunoreactivity was observed. CONCLUSION: Our results unraveled a potential role for FAM20A in homeostasis of both gingival epithelium and connective tissues.

Published
2019
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15. Ameloblast transcriptome changes from secretory to maturation stages

Author

James P. Simmer, Jan C.-C. Hu, Yuanyuan Hu, Bryan M. Reid, Shih Kai Wang, Yongsheng Bai, and Amelia S. Richardson

Subjects
Biology, Biochemistry, Article, Transcriptome, Mice, Rheumatology, Dental Enamel Proteins, stomatognathic system, Amelogenesis, Complementary DNA, Ameloblasts, Animals, Orthopedics and Sports Medicine, Molecular Biology, Gene, Genetics, cDNA library, Gene Expression Profiling, Enamel organ, Enamel Organ, High-Throughput Nucleotide Sequencing, Cell Biology, Cell biology, Gene expression profiling, Ameloblast
Abstract

The purpose of this study was to identify the major molecular components in the secretory and maturation stages of amelogenesis through transcriptome analyses. Ameloblasts (40 sections per age group) were laser micro-dissected from Day 5 (secretory stage) and Days 11–12 (maturation stage) first molars. PolyA+ RNA was isolated from the lysed cells, converted to cDNA, and amplified to generate a cDNA library. DNA sequences were obtained using next generation sequencing and analyzed to identify genes whose expression had increased or decreased at least 1.5-fold in maturation stage relative to secretory stage ameloblasts. Among the 9198 genes that surpassed the quality threshold, 373 showed higher expression in secretory stage, while 614 genes increased in maturation stage ameloblasts. The results were cross-checked against a previously published transcriptome generated from tissues overlying secretory and maturation stage mouse incisor enamel and 34 increasing and 26 decreasing expressers common to the two studies were identified. Expression of F2r, which encodes protease activated receptor 1 (PAR1) that showed 10-fold higher expression during the secretory stage in our transcriptome analysis, was characterized in mouse incisors by immunohistochemistry. PAR1 was detected in secretory, but not maturation stage ameloblasts. We conclude that transcriptome analyses are a good starting point for identifying genes/proteins that are critical for proper dental enamel formation and that PAR1 is specifically expressed by secretory stage ameloblasts.

Published
2020
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16. ENAM mutations and digenic inheritance

Author

Hong Zhang, Jung-Wook Kim, John Timothy Wright, Yuanyuan Hu, Shih Kai Wang, Mine Koruyucu, Jan C.-C. Hu, Figen Seymen, Chuhua Zhang, James P. Simmer, Michael W. Havel, and Yelda Kasimoglu

Subjects
Male, 0301 basic medicine, Heterozygote, Candidate gene, lcsh:QH426-470, 030105 genetics & heredity, Biology, Polymorphism, Single Nucleotide, Frameshift mutation, 03 medical and health sciences, stomatognathic system, Exome Sequencing, Genetics, medicine, Humans, AMBN, Amelogenesis imperfecta, tooth, Allele, Frameshift Mutation, Molecular Biology, Exome, Genetics (clinical), hypoplasia, Extracellular Matrix Proteins, enamel, Original Articles, amelogenesis imperfecta, medicine.disease, Molecular biology, Digenic inheritance, Pedigree, lcsh:Genetics, stomatognathic diseases, Phenotype, 030104 developmental biology, Original Article, Female, Laminin, ENAM, Gene Deletion
Abstract

Background ENAM mutations cause autosomal dominant or recessive amelogenesis imperfecta (AI) and show a dose effect: enamel malformations are more severe or only penetrant when both ENAM alleles are defective. Methods Whole exome sequences of recruited AI probands were initially screened for mutations in known AI candidate genes. Sanger sequencing was used to confirm sequence variations and their segregation with the disease phenotype. The co-occurrence of ENAM and LAMA3 mutations in one family raised the possibility of digenic inheritance. Enamel formed in Enam+/+ Ambn+/+ , Enam+/- , Ambn+/- , and Enam+/- Ambn+/- mice was characterized by dissection and backscattered scanning electron microscopy (bSEM). Results ENAM mutations segregating with AI in five families were identified. Two novel ENAM frameshift mutations were identified. A single-nucleotide duplication (c.395dupA/p.Pro133Alafs*13) replaced amino acids 133-1142 with a 12 amino acid (ATTKAAFEAAIT*) sequence, and a single-nucleotide deletion (c.2763delT/p.Asp921Glufs*32) replaced amino acids 921-1142 with 31 amino acids (ESSPQQASYQAKETAQRRGKAKTLLEMMCPR*). Three families were heterozygous for a previously reported single-nucleotide ENAM deletion (c.588+1delG/p.Asn197Ilefs*81). One of these families also harbored a heterozygous LAMA3 mutation (c.1559G>A/p.Cys520Tyr) that cosegregated with both the AI phenotype and the ENAM mutation. In mice, Ambn+/- maxillary incisors were normal. Ambn+/- molars were also normal, except for minor surface roughness. Ambn+/- mandibular incisors were sometimes chalky and showed minor chipping. Enam+/- incisor enamel was thinner than normal with ectopic mineral deposited laterally. Enam+/- molars were sometimes chalky and rough surfaced. Enam+/- Ambn+/- enamel was thin and rough, in part due to ectopic mineralization, but also underwent accelerated attrition. Conclusion Novel ENAM mutations causing AI were identified, raising to 22 the number of ENAM variations known to cause AI. The severity of the enamel phenotype in Enam+/- Ambn+/- double heterozygous mice is caused by composite digenic effects. Digenic inheritance should be explored as a cause of AI in humans.

Published
2019
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17. AMBN mutations causing hypoplastic amelogenesis imperfecta and Ambn knockout‐NLS‐lacZ knockin mice exhibiting failed amelogenesis and Ambn tissue‐specificity

Author

Charles E. Smith, Shih Kai Wang, Yong Hee P Chun, Yuanyuan Hu, Jan C.-C. Hu, Jung-Wook Kim, James P. Simmer, Brent Lin, Amelia S. Richardson, Tian Liang, Hong Zhang, and Jie Yang

Subjects
0301 basic medicine, lcsh:QH426-470, Amelogenesis Imperfecta, Ambn ‐/‐ Amelx ‐, matrix proteins, Mice, Transgenic, 030105 genetics & heredity, amelin, Mice, 03 medical and health sciences, ameloblastin, Dental Enamel Proteins, stomatognathic system, Ameloblasts, Genetics, medicine, Dentin, Animals, Humans, mineralization, AMBN, Amelogenesis imperfecta, Gene Knock-In Techniques, dental enamel formation, Molecular Biology, Genetics (clinical), Chemistry, missense mutation, Enamel organ, Original Articles, sheath protein, Amelogenesis, medicine.disease, amelogenin, Molecular biology, lcsh:Genetics, stomatognathic diseases, 030104 developmental biology, medicine.anatomical_structure, Organ Specificity, Mutation, Original Article, sheathlin, Dentin mineralization, Amelogenin, Ameloblast
Abstract

Background Ameloblastin (AMBN) is a secreted matrix protein that is critical for the formation of dental enamel and is enamel‐specific with respect to its essential functions. Biallelic AMBN defects cause non‐syndromic autosomal recessive amelogenesis imperfecta. Homozygous Ambn mutant mice expressing an internally truncated AMBN protein deposit only a soft mineral crust on the surface of dentin. Methods We characterized a family with hypoplastic amelogenesis imperfecta caused by AMBN compound heterozygous mutations (c.1061T>C; p.Leu354Pro/ c.1340C>T; p.Pro447Leu). We generated and characterized Ambn knockout/NLS‐lacZ (Ambn lacZ/lacZ) knockin mice. Results No AMBN protein was detected using immunohistochemistry in null mice. ß‐galactosidase activity was specific for ameloblasts in incisors and molars, and islands of cells along developing molar roots. Ambn lacZ/lacZ 7‐week incisors and unerupted (D14) first molars showed extreme enamel surface roughness. No abnormalities were observed in dentin mineralization or in nondental tissues. Ameloblasts in the Ambn lacZ/lacZ mice were unable to initiate appositional growth and started to degenerate and deposit ectopic mineral. No layer of initial enamel ribbons formed in the Ambn lacZ/lacZ mice, but pockets of amelogenin accumulated on the dentin surface along the ameloblast distal membrane and within the enamel organ epithelia (EOE). NLS‐lacZ signal was positive in the epididymis and nasal epithelium, but negative in ovary, oviduct, uterus, prostate, seminal vesicles, testis, submandibular salivary gland, kidney, liver, bladder, and bone, even after 15 hr of incubation with X‐gal. Conclusions Ameloblastin is critical for the initiation of enamel ribbon formation, and its absence results in pathological mineralization within the enamel organ epithelia.

Published
2019
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18. Novel REST Truncation Mutations Causing Hereditary Gingival Fibromatosis

Author

T P Yang, J T Chen, Y P Wang, C H Lin, P C Kao, Shih Kai Wang, and H W Huang

Subjects
0301 basic medicine, Lamina propria, Molecular pathology, Genetic disorder, 030105 genetics & heredity, Biology, medicine.disease, Hereditary gingival fibromatosis, Pathogenesis, 03 medical and health sciences, Exon, 030104 developmental biology, medicine.anatomical_structure, medicine, Cancer research, General Dentistry, Transcription factor, Rest (music)
Abstract

Hereditary gingival fibromatosis (HGF) is a rare genetic disorder featured by nonsyndromic pathological overgrowth of gingiva. The excessive gingival tissues can cause dental, masticatory, and phonetic problems, which impose severe functional and esthetic burdens on affected individuals. Due to its high recurrent rate, patients with HGF have to undergo repeated surgical procedures of gingival resection, from childhood to adulthood, which significantly compromises their quality of life. Unraveling the genetic etiology and molecular pathogenesis of HGF not only gains insight into gingival physiology and homeostasis but also opens avenues for developing potential therapeutic strategies for this disorder. Recently, mutations in REST (OMIM *600571), encoding a transcription repressor, were reported to cause HGF (GINGF5; OMIM #617626) in 3 Turkish families. However, the functions of REST in gingival homeostasis and pathogenesis of REST-associated HGF remain largely unknown. In this study, we characterized 2 HGF families and identified 2 novel REST mutations, c.2449C>T (p.Arg817*) and c.2771_2793dup (p.Glu932Lysfs*3). All 5 mutations reported to date are nonsenses or frameshifts in the last exon of REST and would presumably truncate the protein. In vitro reporter gene assays demonstrated a partial or complete loss of repressor activity for these truncated RESTs. When coexpressed with the full-length protein, the truncated RESTs impaired the repressive ability of wild-type REST, suggesting a dominant negative effect. Immunofluorescent studies showed nuclear localization of overexpressed wild-type and truncated RESTs in vitro, indicating preservation of the nuclear localization signal in shortened proteins. Immunohistochemistry demonstrated a comparable pattern of ubiquitous REST expression in both epithelium and lamina propria of normal and HGF gingival tissues despite a reduced reactivity in HGF gingiva. Results of this study confirm the pathogenicity of REST truncation mutations occurring in the last exon causing HGF and suggest the pathosis is caused by an antimorphic (dominant negative) disease mechanism.

Published
2021
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19. Fam83h null mice support a neomorphic mechanism for human <scp>ADHCAI</scp>

Author

Koray Gençay, Charles E. Smith, Yuanyuan Hu, Jie Yang, Jung-Wook Kim, Yasuo Yamakoshi, Yuan-Ling Lee, Jan C.-C. Hu, Moses Lee, James P. Simmer, Amelia S. Richardson, Shih Kai Wang, Mine Koruyucu, Murim Choi, and Figen Seymen

Subjects
0301 basic medicine, Scaffold protein, Biology, Pathogenesis, 03 medical and health sciences, hair defects, Amelogenesis imperfecta, Genetics, medicine, Molecular Biology, Genetics (clinical), FAM83H, Original Articles, medicine.disease, Molecular biology, truncation mutation, skin defects, 030104 developmental biology, Knockout mouse, Phosphorylation, Original Article, Casein kinase 1, knockout mouse, Ameloblast, gain‐of‐function
Abstract

Truncation mutations in FAM83H (family with sequence similarity 83, member H) cause autosomal dominant hypocalcified amelogenesis imperfecta (ADHCAI), but little is known about FAM83H function and the pathogenesis of ADHCAI. We recruited three ADHCAI families and identified two novel (p.Gln457*; p.Lys639*) and one previously documented (p.Q452*) disease-causing FAM83H mutations. We generated and characterized Fam83h-knockout/lacZ-knockin mice. Surprisingly, enamel thickness, density, Knoop hardness, morphology, and prism patterns were similar in Fam83h (+/+), Fam83h (+/-), and Fam83h (-/-) mice. The histology of ameloblasts in all stages of development, in both molars and incisors, was virtually identical in all three genotypes and showed no signs of pathology, although the Fam83h (-/-) mice usually died after 2 weeks and rarely survived to 7 weeks. LacZ expression in the knockin mice was used to report Fam83h expression in the epithelial tissues of many organs, notably in skin and hair follicles, which manifested a disease phenotype. Pull-down studies determined that FAM83H dimerizes through its N-terminal phospholipase D-like (PLD-like) domain and identified potential FAM83H interacting proteins. Casein kinase 1 (CK1) interacts with the FAM83H PLD-like domain via an F(270)-X-X-X-F(274)-X-X-X-F(278) motif. CK1 can phosphorylate FAM83H in vitro, and many phosphorylation sites were identified in the FAM83H C-terminus. Truncation of FAM83H alters its subcellular localization and that of CK1. Our results support the conclusion that FAM83H is not necessary for proper dental enamel formation in mice, but may act as a scaffold protein that localizes CK1. ADHCAI is likely caused by gain-of-function effects mediated by truncated FAM83H, which potentially mislocalizes CK1 as part of its pathological mechanism.

Published
2015
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20. Critical roles for <scp>WDR</scp> 72 in calcium transport and matrix protein removal during enamel maturation

Author

James P. Simmer, Jie Yang, Amelia S. Richardson, Jan C.-C. Hu, Yuanyuan Hu, Charles E. Smith, Stephanie M. Nunez, Andrew C. Samann, Shih Kai Wang, and Soumya Pal

Subjects
stomatognathic system, Amelogenesis imperfecta, Genetics, medicine, SLC24A4, Molecular Biology, Genetics (clinical), Reduced enamel epithelium, Enamel paint, enamel maturation, Chemistry, Outer enamel epithelium, Inner enamel epithelium, Original Articles, Amelogenesis, Anatomy, medicine.disease, Cell biology, stomatognathic diseases, Enamel mineralization, scaffold protein, visual_art, hypomaturation, visual_art.visual_art_medium, Ameloblast
Abstract

Defects in WDR72 (WD repeat-containing protein 72) cause autosomal recessive hypomaturation amelogenesis imperfecta. We generated and characterized Wdr72-knockout/lacZ-knockin mice to investigate the role of WDR72 in enamel formation. In all analyses, enamel formed by Wdr72 heterozygous mice was indistinguishable from wild-type enamel. Without WDR72, enamel mineral density increased early during the maturation stage but soon arrested. The null enamel layer was only a tenth as hard as wild-type enamel and underwent rapid attrition following eruption. Despite the failure to further mineralize enamel deposited during the secretory stage, ectopic mineral formed on the enamel surface and penetrated into the overlying soft tissue. While the proteins in the enamel matrix were successfully degraded, the digestion products remained inside the enamel. Interactome analysis of WDR72 protein revealed potential interactions with clathrin-associated proteins and involvement in ameloblastic endocytosis. The maturation stage mandibular incisor enamel did not stain with methyl red, indicating that the enamel did not acidify beneath ruffle-ended ameloblasts. Attachment of maturation ameloblasts to the enamel layer was weakened, and SLC24A4, a critical ameloblast calcium transporter, did not localize appropriately along the ameloblast distal membrane. Fewer blood vessels were observed in the papillary layer supporting ameloblasts. Specific WDR72 expression by maturation stage ameloblasts explained the observation that enamel thickness and rod decussation (established during the secretory stage) are normal in the Wdr72 null mice. We conclude that WDR72 serves critical functions specifically during the maturation stage of amelogenesis and is required for both protein removal and enamel mineralization.

Published
2015
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21. Ectodermal Dysplasia - A Family Study

Author

Shih-Kai Wang, D. Pandurić, A. Baraba, V. Čulić, G. Liović, M. Jurić, and I. Žeko

Subjects
ectodermal dysplasia, hypodontia, hypotrichosis, hypohidrotic, Ectodermal dysplasia, Taurodontism, integumentary system, business.industry, Anatomy, medicine.disease, General Biochemistry, Genetics and Molecular Biology, Hypodontia, Micrognathism, medicine, Microdontia, Hypotrichosis, Ectodysplasin A, Family history, General Agricultural and Biological Sciences, business
Abstract

Ectodermal dysplasias (ED) are group of genetically heterogenous conditions that are characterized by abnormal development of ectodermal structures. The most affected structures are teeth, skin and its derivatives (hair, sweat glands) along with other ectodermal structures. The purpose of this work was to present the family with four boys affected with ED. We described the clinical report of male infant (affected twin) aged two months and his older brothers with absence of eyebrows and eyelashes, saddle nose, dry flaky skin, rare thin blond hair, and large number of dental anomalies with pathohistological-skin positive analysis for ectodermal dysplasia. Only a few abnormally formed teeth erupted (microdontia and conical teeth) and at the later then average age. Radiographic examination confirmed previous clinical findings and determined taurodontism of the molar teeth. They also presented pseudoprognathism of the mandible due to micrognathism of the maxilla. Based on the positive family history (two older brothers), clinical picture and pathohistological findings of the skin we concluded that the child (and his twin brother) were also affected. EDA gene missense mutation, Ala349Thr (GCA --> ACA), was responsible for the condition of observed family. Hair hypotriyhosis, brittle, scanty hair, absent or scanty eyelashes and eyebrows, blonde, fine scalp hair, as minor clinical signs at grandmother and only scanty eyelashes at mother were observed. Mutation analysis in families with X-linked ED help in genetic counseling, prenatal diagnosis, and confirmation of carrier status.

Published
2014
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22. ITGB6 loss-of-function mutations cause autosomal recessive amelogenesis imperfecta

Author

Susan J. Wang, Brent Lin, Jung-Wook Kim, Jan C.-C. Hu, James P. Simmer, Bryan M. Reid, Amelia S. Richardson, Shih Kai Wang, and Murim Choi

Subjects
Male, Proband, Heterozygote, Integrin beta Chains, Amelogenesis Imperfecta, Molecular Sequence Data, Genes, Recessive, Biology, Real-Time Polymerase Chain Reaction, Compound heterozygosity, medicine.disease_cause, Cataract, Immunoenzyme Techniques, Mice, Exon, stomatognathic system, Ameloblasts, Genetics, medicine, Animals, Humans, Amelogenesis imperfecta, Amino Acid Sequence, RNA, Messenger, Child, Dental Enamel, Molecular Biology, Genetics (clinical), Mutation, Sequence Homology, Amino Acid, Reverse Transcriptase Polymerase Chain Reaction, Tooth Abnormalities, Homozygote, Genetic Diseases, X-Linked, Articles, General Medicine, Amelogenesis, medicine.disease, Molecular biology, Pedigree, Phenotype, Knockout mouse, Female, Ameloblast
Abstract

Integrins are cell-surface adhesion receptors that bind to extracellular matrices (ECM) and mediate cell–ECM interactions. Some integrins are known to play critical roles in dental enamel formation. We recruited two Hispanic families with generalized hypoplastic amelogenesis imperfecta (AI). Analysis of whole-exome sequences identified three integrin beta 6 (ITGB6) mutations responsible for their enamel malformations. The female proband of Family 1 was a compound heterozygote with an ITGB6 transition mutation in Exon 4 (g.4545G > A c.427G > A p.Ala143Thr) and an ITGB6 transversion mutation in Exon 6 (g.27415T > A c.825T > A p.His275Gln). The male proband of Family 2 was homozygous for an ITGB6 transition mutation in Exon 11 (g.73664C > T c.1846C > T p.Arg616*) and hemizygous for a transition mutation in Exon 6 of Nance–Horan Syndrome (NHS Xp22.13; g.355444T > C c.1697T > C p.Met566Thr). These are the first disease-causing ITGB6 mutations to be reported. Immunohistochemistry of mouse mandibular incisors localized ITGB6 to the distal membrane of differentiating ameloblasts and pre-ameloblasts, and then ITGB6 appeared to be internalized by secretory stage ameloblasts. ITGB6 expression was strongest in the maturation stage and its localization was associated with ameloblast modulation. Our findings demonstrate that early and late amelogenesis depend upon cell–matrix interactions. Our approach (from knockout mouse phenotype to human disease) demonstrates the power of mouse reverse genetics in mutational analysis of human genetic disorders and attests to the need for a careful dental phenotyping in large-scale knockout mouse projects.

Published
2013
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23. FAM20C Functions Intracellularly Within Both Ameloblasts and Odontoblasts In Vivo

Author

Jan C.-C. Hu, James P. Simmer, Shih Kai Wang, and Andrew C. Samann

Subjects
Enamel paint, MMP20, Endocrinology, Diabetes and Metabolism, Enamel organ, Biology, Golgi apparatus, stomatognathic diseases, symbols.namesake, Odontoblast, stomatognathic system, Biochemistry, visual_art, visual_art.visual_art_medium, Extracellular, symbols, Orthopedics and Sports Medicine, Amelogenin, Ameloblast
Abstract

FAM20C, also known as Golgi Casein Kinase (G-CK), is proposed to be the archetype for a family of secreted kinases that phosphorylate target proteins in the Golgi and in extracellular matrices, but FAM20C serving an extracellular function is controversial. FAM20C phosphorylates secretory calcium-binding phosphoproteins (SCPPs), which are associated with the evolution of biomineralization in vertebrates. Current models of biomineralization assume SCPP proteins are secreted as phosphoproteins and their phosphates are essential for protein conformation and function. It would be a radical departure from current theories if proteins in mineralizing matrices were dephosphorylated as part of the mineralization mechanism and rephosphorylated in the extracellular milieu by FAM20C using ATP. To see if such mechanisms are possible in the formation of dental enamel, we tested the hypothesis that FAM20C is secreted by ameloblasts and accumulates in the enamel extracellular matrix during tooth development. FAM20C localization was determined by immunohistochemistry in Day 5 mouse incisors and molars and by Western blot analyses of proteins extracted from pig enamel organ epithelia (EOE) and enamel shavings. FAM20C localized intracellularly within ameloblasts and odontoblasts in a pattern consistent with Golgi localization. Western blots detected FAM20C in the EOE extracts but not in the enamel matrix. We conclude that FAM20C is not a constituent of the enamel extracellular matrix and functions intracellularly within ameloblasts.

Published
2013
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24. Novel KLK4 and MMP20 Mutations Discovered by Whole-exome Sequencing

Author

Subodh Chandra Pal, M. Yildirim, Bryan M. Reid, Merve Bayram, James P. Simmer, Ninna M R P Estrella, Jan C.-C. Hu, Yuanyuan Hu, Figen Seymen, Shih Kai Wang, and John D. Bartlett

Subjects
Male, Adolescent, Amelogenesis Imperfecta, DNA Mutational Analysis, Mutation, Missense, Biology, medicine.disease_cause, Frameshift mutation, Mice, stomatognathic system, medicine, Animals, Humans, Missense mutation, Exome, Amelogenesis imperfecta, Child, Dental Enamel, Frameshift Mutation, General Dentistry, Alleles, Exome sequencing, Genetics, Mutation, MMP20, Proteins, Research Reports, FAM83H, medicine.disease, Molecular biology, Mice, Mutant Strains, Pedigree, Matrix Metalloproteinase 20, Codon, Nonsense, Female, Kallikreins
Abstract

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.

Published
2013
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25. Enamel malformations associated with a defined dentin sialophosphoprotein mutation in two families

Author

James P. Simmer, Shih Kai Wang, Rachel N. Milkovich, Jan C.-C. Hu, Hui Chen Chan, Karen A. Uston, Sudha Rajderkar, and Jung-Wook Kim

Subjects
Genetics, Dental Enamel Hypoplasia, Cellular pathology, Dentinogenesis imperfecta, Dentin dysplasia, Context (language use), Biology, medicine.disease, Dentin phosphoprotein, stomatognathic diseases, stomatognathic system, Dentin sialophosphoprotein, medicine, Ameloblast, General Dentistry
Abstract

Dentin sialophosphoprotein (DSPP) mutations cause dentin dysplasia type II (DD-II) and dentinogenesis imperfecta types II and III (DGI-II and DGI-III, respectively). We identified two kindreds with DGI-II who exhibited vertical bands of hypoplastic enamel. Both families had a previously reported DSPP mutation that segregated with the disease phenotype. Oral photographs and dental radiographs of four affected and one unaffected participant in one family and of the proband in the second family were used to document the dental phenotypes. We aligned the 33 unique allelic DSPP sequences showing variable patterns of insertions and deletions (indels), generated a merged dentin phosphoprotein (DPP) sequence that includes sequences from all DSPP length haplotypes, and mapped the known DSPP mutations in this context. Analyses of the DSPP sequence changes and their probable effects on protein expression, as well as published findings of the dental phenotype in Dspp null mice, support the hypothesis that all DSPP mutations cause pathology through dominant-negative effects. Noting that Dspp is transiently expressed by mouse pre-ameloblasts during formation of the dentino-enamel junction, we hypothesize that DSPP dominant-negative effects potentially cause cellular pathology in pre-ameloblasts that, in turn, causes enamel defects. We conclude that enamel defects can be part of the dental phenotype caused by DSPP mutations, although DSPP is not critical for dental enamel formation.

Published
2011
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26. Potential contribution of neural crest cells to dental enamel formation

Author

Yoshihiro Komatsu, Yuji Mishina, and Shih Kai Wang

Subjects
Genetically modified mouse, Lineage (genetic), Mesenchyme, Population, Biophysics, Mice, Transgenic, Hindbrain, Biology, Biochemistry, Article, Mice, stomatognathic system, parasitic diseases, medicine, Animals, Cell Lineage, Transgenes, Dental Enamel, education, Molecular Biology, education.field_of_study, urogenital system, Enamel organ, Neural crest, Cell Biology, Anatomy, beta-Galactosidase, Embryonic stem cell, Cell biology, stomatognathic diseases, medicine.anatomical_structure, Neural Crest, embryonic structures, Myelin P0 Protein
Abstract

Neural crest cells (NCCs) are a multipotent embryonic cell population that contributes to the formation of various craniofacial structures including teeth. It has been generally believed that dental enamel is an ectodermal derivative, whereas the dentin-pulp complex and the surrounding supporting tissues originate from NCC-derived mesenchyme. These traditional concepts stem mainly from several early studies of fishes and amphibians. Recently, Wnt1-Cre/R26R mice, a mouse model for NCC lineage analysis, revealed the contribution of NCCs to mammalian tooth development. However, the discrepancy of expression patterns between different NCC-specific transgenic mouse lines makes it compulsory to revisit the cell lineage in mammalian tooth development. Here, we reevaluated the NCC lineage during mouse tooth development by using P0-Cre/R26R mice, another NCC-specific transgenic mouse line. Inconsistent with the traditional concepts, we observed the potential contribution of NCCs to developing enamel organ and enamel formation. We also demonstrated that the P0-Cre transgene was specifically expressed in migrating NCC in the hindbrain region, where NCC contributes to tooth, validating their applicability for NCC lineage analysis. Our unanticipated finding may change the general understanding of tooth development and provide new insights into dental stem cell biology.

Published
2011
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27. Photocatalytic activities of Pd-loaded mesoporous TiO2 thin films

Author

Jerry Lin, Wen-Chia Hsu, Chung-Chieh Chang, Shih-Kai Wang, and Chih-Chieh Chan

Subjects
Spin coating, Thermogravimetric analysis, Materials science, Scanning electron microscope, General Chemical Engineering, Analytical chemistry, General Chemistry, Industrial and Manufacturing Engineering, Nanocrystalline material, law.invention, Titanium oxide, Chemical engineering, law, Photocatalysis, Environmental Chemistry, Calcination, Mesoporous material
Abstract

In the present study, transparent nanocrystalline Pd–TiO 2 films were prepared by a sol–gel spin coating technique. By introducing non-ionic surfactant Triton X-100 into the sol, transparent mesoporous Pd–TiO 2 films were also prepared after calcination at 500 °C. To reveal the structural and morphological differences, the as-prepared TiO 2 and Pd–TiO 2 films were characterized by scanning electron microscope with energy dispersive spectrometer, thermal gravimetric analysis, X-ray diffraction and UV–vis spectrophotometer. In addition, the photocatalytic activities of these films were investigated by degrading methylene blue under UV and visible light irradiation. Sol–gel TiO 2 film, processed without surfactant, exhibited a pore-free smooth surface. Mesoporous TiO 2 and Pd–TiO 2 films with pore sizes ranging from 4 to 20 nm were obtained when surfactant was introduced and removed after calcination. In this study, the mesoporous Pd–TiO 2 film with molar ratio of Pd/Ti = 0.05 exhibited the best photocatalytic activity while specifically maintained good transparency.

Published
2009
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28. Homopolymerization and copolymerization oftert-butyl methacrylate and norbornene with nickel-based methylaluminoxane catalysts

Author

Shih-Kai Wang, Chih-Feng Huang, Shiao-Wei Kuo, Wu-Jang Huang, and Feng-Chih Chang

Subjects
Materials science, Polymers and Plastics, Methylaluminoxane, General Chemistry, Methacrylate, Surfaces, Coatings and Films, chemistry.chemical_compound, Crystallinity, Monomer, chemistry, Polymer chemistry, Materials Chemistry, Copolymer, Reactivity (chemistry), Aluminoxane, Norbornene
Abstract

The homopolymerization and copolymeriza- tion of tert-butyl methacrylate (tBMA) and norbornene (NB) with nickel(II) acetylacetonate in combination with methyl- aluminoxane were systematically investigated. This catalytic system showed high activity toward the homopolymeriza- tion of both NB and tBMA. For these copolymerizations, activity was gradually lost with an addition of tBMA to NB or of NB to tBMA. This result was qualitatively explained with the trigger coordination mechanism. Furthermore, the determination of the reactivity ratios indicated a signifi- cantly higher reactivity for NB than for tBMA (rNB 4.14 and rtBMA 0.097), and this was interpreted by the coordi- nation mechanism. The synthesized acrylate/NB copoly- mers exhibited glass-transition temperatures of 100 -250°C. The absence of crystallinity and the homogeneous reparti- tion of the monomer units along the main chain yielded products with high transparency and high stability © 2004

Published
2004
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29. Taurodontism, variations in tooth number, and misshapened crowns in Wnt10a null mice and human kindreds

Author

Hera Kim-Berman, Paul J. Benke, Shih Kai Wang, Jie Yang, Curtis R. Herzog, Jan C.-C. Hu, Kevin C K Lloyd, Moses Lee, Murim Choi, Bryan M. Reid, Yuanyuan Hu, Yuan-Ling Lee, and James P. Simmer

Subjects
Molar, Taurodontism, EDARADD, Familial tooth agenesis, Clinical Sciences, Original Articles, Oligodontia, Anatomy, Biology, medicine.disease, Penetrance, oligodontia, taurodontism, Hypodontia, stomatognathic diseases, Medicinal and Biomolecular Chemistry, stomatognathic system, taurodontism, medicine, hypodontia, Genetics, Cusp (anatomy), Supernumerary, oligodontia, Molecular Biology, Genetics (clinical)
Abstract

WNT10A is a signaling molecule involved in tooth development, and WNT10A defects are associated with tooth agenesis. We characterized Wnt10a null mice generated by the knockout mouse project (KOMP) and six families with WNT10A mutations, including a novel p.Arg104Cys defect, in the absence of EDA,EDAR, or EDARADD variations. Wnt10a null mice exhibited supernumerary mandibular fourth molars, and smaller molars with abnormal cusp patterning and root taurodontism. Wnt10a (-/-) incisors showed distinctive apical-lingual wedge-shaped defects. These findings spurred us to closely examine the dental phenotypes of our WNT10A families. WNT10A heterozygotes exhibited molar root taurodontism and mild tooth agenesis (with incomplete penetrance) in their permanent dentitions. Individuals with two defective WNT10A alleles showed severe tooth agenesis and had fewer cusps on their molars. The misshapened molar crowns and roots were consistent with the Wnt10a null phenotype and were not previously associated with WNT10A defects. The missing teeth contrasted with the presence of supplemental teeth in the Wnt10a null mice and demonstrated mammalian species differences in the roles of Wnt signaling in early tooth development. We conclude that molar crown and root dysmorphologies are caused by WNT10A defects and that the severity of the tooth agenesis correlates with the number of defective WNT10A alleles.

Published
2015

30. STIM1 and SLC24A4 Are Critical for Enamel Maturation

Author

M. Yildirim, Elif Bahar Tuna, Bryan M. Reid, Figen Seymen, Amelia S. Richardson, Koray Gençay, Jan C.-C. Hu, James P. Simmer, Murim Choi, and Shih Kai Wang

Subjects
Mutation, Missense, Clinical Investigations, Biology, Arginine, Antiporters, Consanguinity, Cytosine, Mice, stomatognathic system, Amelogenesis, Extracellular, Ameloblasts, Animals, Humans, Calcium Signaling, Cysteine, Stromal Interaction Molecule 1, Child, General Dentistry, Genetics, Alanine, Enamel paint, Homozygote, Genetic Variation, Membrane Proteins, STIM1, Valine, Solute carrier family, Cell biology, Neoplasm Proteins, Pedigree, stomatognathic diseases, visual_art, Child, Preschool, visual_art.visual_art_medium, Dental Enamel Hypoplasia, Female, Ameloblast, Intracellular, Homeostasis, Thymine
Abstract

Dental enamel formation depends upon the transcellular transport of Ca2+ by ameloblasts, but little is known about the molecular mechanism, or even if the same process is operative during the secretory and maturation stages of amelogenesis. Identifying mutations in genes involved in Ca2+ homeostasis that cause inherited enamel defects can provide insights into the molecular participants and potential mechanisms of Ca2+ handling by ameloblasts. Stromal Interaction Molecule 1 (STIM1) is an ER transmembrane protein that activates membrane-specific Ca2+ influx in response to the depletion of ER Ca2+ stores. Solute carrier family 24, member 4 (SLC24A4), is a Na+/K+/Ca2+ transporter that exchanges intracellular Ca2+ and K+ for extracellular Na+. We identified a proband with syndromic hypomaturation enamel defects caused by a homozygous C to T transition (g.232598C>T c.1276C>T p.Arg426Cys) in STIM1, and a proband with isolated hypomaturation enamel defects caused by a homozygous C to T transition (g.124552C>T; c.437C>T; p.Ala146Val) in SLC24A4. Immunohistochemistry of developing mouse molars and incisors showed positive STIM1 and SLC24A4 signal specifically in maturation-stage ameloblasts. We conclude that enamel maturation is dependent upon STIM1 and SLC24A4 function, and that there are important differences in the Ca2+ transcellular transport systems used by secretory- and maturation-stage ameloblasts.

Published
2014

31. FAM20A mutations associated with enamel renal syndrome

Author

Lisa Read, Bryan M. Reid, Jan C.-C. Hu, A.P.H. Taheri, Shih Kai Wang, M.Z. Yeganeh, P. Aref, S. Dugan, Jennifer Roggenbuck, and James P. Simmer

Subjects
Proband, Male, Adenosine, Guanine, Amelogenesis Imperfecta, Genetic Vectors, Mutation, Missense, Genes, Recessive, Biology, Polymorphism, Single Nucleotide, Tooth Eruption, Cytosine, Mice, Dental Enamel Proteins, medicine, Missense mutation, Animals, Humans, Amelogenesis imperfecta, Kinase activity, Child, General Dentistry, Sequence Deletion, Genetics, Dental Enamel Hypoplasia, Tooth Abnormalities, Homozygote, Research Reports, Exons, Enamel hypoplasia, medicine.disease, Molecular biology, Introns, Nephrocalcinosis, HEK293 Cells, Phenotype, Child, Preschool, Gingival Hyperplasia, Mutation, Dental Pulp Calcification, Female, Ameloblast, Minigene, Follow-Up Studies
Abstract

We identified two families with an autosomal-recessive disorder manifested by severe enamel hypoplasia, delayed and failed tooth eruption, misshapen teeth, intrapulpal calcifications, and localized gingival hyperplasia. Genetic analyses identified novel FAM20A mutations associated with the disease phenotype in both families. The proband of Family 1 had an altered splice junction in Intron 1 (g.502011G>C; c.405-1G>C) and a missense mutation in Exon 8 (g.65094G>A; c.1207G>A; p.D403N). The missense mutation is notable because D403 is strictly conserved among FAM20A homologues, and the corresponding defect in FAM20C caused osteosclerotic bone dysplasia and a loss of kinase activity. The proband at age 12 yrs tested negative for nephrocalcinosis. The proband and her affected father in Family 2 were homozygous for a single nucleotide deletion that altered a splice junction in Intron 10 (g.66622del; c.1361+4del). Minigene analyses demonstrated that this alteration precluded normal splicing. Immunohistochemistry (IHC) of mouse maxillary first molars localized FAM20A in secretory-stage ameloblasts, in odontoblasts, and in the eruption pathway. IHC of kidneys localized FAM20A in the renal tubules. We conclude that FAM20A is likely a secretory pathway kinase and that loss-of-function mutations cause pathology where its phosphorylations are necessary for normal development or homeostasis.

Published
2013

32. Secreted protein kinases?

Author

James P. Simmer, Shih Kai Wang, and Andrew C. Samann

Subjects
Kinase, Golgi apparatus, Biology, Biochemistry, Article, Transmembrane protein, Cell biology, symbols.namesake, Transmembrane domain, Secretory protein, symbols, Extracellular, Animals, Humans, Secretion, Golgi localization, Molecular Biology, Protein Kinases
Abstract

The Trends in Biochemical Sciences review ‘Secreted protein kinases’ portrays FAM20C (family with sequence similarity 20), recently discovered to be Golgi casein kinase (G-CK), as the archetypal member of the four-jointed family of secreted protein kinases that phosphorylate target proteins in the Golgi and in extracellular matrices [1,2]. Although the review is scholarly and interesting, we feel that the existing literature does not support the underlying assumption that these kinases are secreted in physiological quantities, or that any of them serve a necessary function in the extracellular matrix in vivo. We believe that the weight of evidence is currently against this being a family of secreted kinases and that additional efforts should be directed at better localization of the kinases before posing and testing hypotheses about their possible roles in extracellular matrices. FAM20C is one of three members of the FAM20 family, which comprises FAM20A, FAM20B, and FAM20C in mammals. This family was originally discovered in hematopoietic cells and, based upon behavior of the ectopically expressed proteins in cell lines, was described as being a family of secreted proteins [3]. A similar result was obtained for ectopically expressed FAM20C when it was identified as G-CK [1]. However, there are reasons to doubt that the FAM20 kinases are secreted. Immunolocalization of ectopically expressed FAM20A and FAM20B in HEK293T cells localized these proteins to the Golgi, and western blot analyses of the cell extracts and medium detected FAM20A and FAM20B only in the cell extracts [4]. FAM20B is a Golgi kinase that helps regulate glycosaminoglycan synthesis by phosphorylating xylose in the glycosaminoglycan–protein linkage region of proteoglycans [5], which precedes and influences subsequent steps in GAG synthesis (including chain termination) that occur within the Golgi [6]. The known function of FAM20B strongly suggests it could not carry out its function in the extracellular matrix. The evidence supports that the proteins most closely related to G-CK are resident in the Golgi and are not secreted. The conclusion that FAM20C is secreted rests principally on in vitro studies using ectopically expressed protein that may not reflect the situation in vivo. FAM20C has no predicted transmembrane domain, so Golgi localization of FAM20C may require interactions with a Golgi transmembrane protein [7]. If G-CK and the interacting proteins that hold it in the Golgi are normally expressed in similar amounts, overexpression of the kinase could exceed the capacity of the cells for retaining the recombinant protein in the Golgi. Cell death in culture releases intracellular proteins into the media and the amount of cells and media compared for relative localization can be arbitrary. The only in vivo evidence cited for possible FAM20C secretion was the detection of G-CK activity in cows’ milk [8]. However, in that study it was calculated that the ratio of G-CK in the Golgi relative to milk was 47.7 to 1 and was similar to that of galactosyltransferase; a Golgi enzyme with no putative extracellular function. They developed a straight-forward two-step fractionation procedure that achieved an 84 000-fold enrichment while retaining 46% of the original G-CK activity, but still did not obtain sufficient protein for identification. Thus, the only in vivo FAM20C data are not consistent with a high proportion of FAM20C being secreted in vivo, as can occur in vitro during ectopic overexpression, and does not support the assumption of the review that FAM20C is secreted and is likely to serve an extracellular function. Four-jointed (Fj) is the FAM20 homolog in Drosophila [9]. Fj is cleaved intracellularly and its C terminus is secreted. It was proposed that its C terminus acts as a signaling molecule. However, elegant studies using transgenic rescues of an Fj mutant phenotype demonstrated that Fj is largely localized to the Golgi in vivo and that cleavage and secretion of Fj is not essential for its activity, and may be a mechanism to downregulate Fj activity during normal development [10]. We conclude that the current literature does not support an assumption that the four-jointed family of kinases in mammals are secreted in appreciable quantities in vivo, or that they function in extracellular matrices. Testing hypotheses concerning their specific roles in the extracellular matrix is premature and should be preceded by demonstrations that the kinase is actually secreted at levels comparable to that found in the Golgi, and if possible, demonstration that a failure to secrete the kinase results in a loss of function.

Published
2013

33. Novel PAX9 and COL1A2 missense mutations causing tooth agenesis and OI/DGI without skeletal abnormalities

Author

James P. Simmer, Jan C.-C. Hu, Hui Chen Chan, Igor Makovey, and Shih Kai Wang

Subjects
Male, Anatomy and Physiology, Heredity, Dentinogenesis imperfecta, lcsh:Medicine, Social and Behavioral Sciences, 0302 clinical medicine, Dentin sialophosphoprotein, Sociology, Missense mutation, Human Families, lcsh:Science, Musculoskeletal System, Genetics, 0303 health sciences, Multidisciplinary, Linkage (Genetics), Osteogenesis Imperfecta, 3. Good health, Pedigree, Osteogenesis imperfecta, Child, Preschool, Medicine, Female, Research Article, Molecular Sequence Data, Oral Medicine, Mutation, Missense, Biology, Bone and Bones, Collagen Type I, 03 medical and health sciences, stomatognathic system, Dentinogenesis Imperfecta, medicine, AXIN2, Humans, Genetic Predisposition to Disease, Bone, 030304 developmental biology, Base Sequence, Tooth Abnormalities, Dentin dysplasia, lcsh:R, Computational Biology, 030206 dentistry, medicine.disease, Radiography, Hypodontia, stomatognathic diseases, Dentistry, Genetics of Disease, Genetic Polymorphism, lcsh:Q, PAX9 Transcription Factor, Gene Function, PAX9, Tooth, Population Genetics, Developmental Biology
Abstract

Inherited dentin defects are classified into three types of dentinogenesis imperfecta (DGI) and two types of dentin dysplasia (DD). The genetic etiology of DD-I is unknown. Defects in dentin sialophosphoprotein (DSPP) cause DD type II and DGI types II and III. DGI type I is the oral manifestation of osteogenesis imperfecta (OI), a systemic disease typically caused by defects in COL1A1 or COL1A2. Mutations in MSX1, PAX9, AXIN2, EDA and WNT10A can cause non-syndromic familial tooth agenesis. In this study a simplex pattern of clinical dentinogenesis imperfecta juxtaposed with a dominant pattern of hypodontia (mild tooth agenesis) was evaluated, and available family members were recruited. Mutational analyses of the candidate genes for DGI and hypodontia were performed and the results validated. A spontaneous novel mutation in COL1A2 (c.1171G>A; p.Gly391Ser) causing only dentin defects and a novel mutation in PAX9 (c.43T>A; p.Phe15Ile) causing hypodontia were identified and correlated with the phenotypic presentations in the family. Bone radiographs of the proband's dominant leg and foot were within normal limits. We conclude that when no DSPP mutation is identified in clinically determined isolated DGI cases, COL1A1 and COL1A2 should be considered as candidate genes. PAX9 mutation p.Phe15Ile within the N-terminal β-hairpin structure of the PAX9 paired domain causes tooth agenesis.

Published
2012

34. Enamel malformations associated with a defined dentin sialophosphoprotein mutation in two families

Author

Shih-Kai, Wang, Hui-Chen, Chan, Sudha, Rajderkar, Rachel N, Milkovich, Karen A, Uston, Jung-Wook, Kim, James P, Simmer, and Jan C-C, Hu

Subjects
Male, Extracellular Matrix Proteins, Adolescent, Genotype, Sialoglycoproteins, DNA Mutational Analysis, Molecular Sequence Data, Phosphoproteins, Article, Pedigree, stomatognathic diseases, Dentin Dysplasia, Phenotype, stomatognathic system, Haplotypes, Dentinogenesis Imperfecta, Mutation, Ameloblasts, Humans, Dental Enamel Hypoplasia, Female, Amino Acid Sequence, Genes, Dominant
Abstract

Dentin sialophosphoprotein (DSPP) mutations cause dentin dysplasia type II (DD-II) and dentinogenesis imperfecta types II and III (DGI-II and DGI-III, respectively). We identified two kindreds with DGI-II who exhibited vertical bands of hypoplastic enamel. Both families had a previously reported DSPP mutation that segregated with the disease phenotype. Oral photographs and dental radiographs of four affected and one unaffected participant in one family and of the proband in the second family were used to document the dental phenotypes. We aligned the 33 unique allelic DSPP sequences showing variable patterns of insertions and deletions (indels), generated a merged dentin phosphoprotein (DPP) sequence that includes sequences from all DSPP length haplotypes, and mapped the known DSPP mutations in this context. Analyses of the DSPP sequence changes and their probable effects on protein expression, as well as published findings of the dental phenotype in Dspp null mice, support the hypothesis that all DSPP mutations cause pathology through dominant-negative effects. Noting that Dspp is transiently expressed by mouse pre-ameloblasts during formation of the dentino-enamel junction, we hypothesize that DSPP dominant-negative effects potentially cause cellular pathology in pre-ameloblasts that, in turn, causes enamel defects. We conclude that enamel defects can be part of the dental phenotype caused by DSPP mutations, although DSPP is not critical for dental enamel formation.

Published
2012

35. Altered Enamelin Phosphorylation Site Causes Amelogenesis Imperfecta

Author

H.L. Chan, Shih Kai Wang, L. Mai, A. Oikonomopoulou, Jan C.-C. Hu, Hui Chen Chan, James P. Simmer, and Amelia S. Richardson

Subjects
Proband, Male, congenital, hereditary, and neonatal diseases and abnormalities, Guanine, Amelogenesis Imperfecta, Mutation, Missense, Golgi Apparatus, Biology, Frameshift mutation, Cytosine, Young Adult, stomatognathic system, Dental Enamel Proteins, Leucine, medicine, Serine, Missense mutation, Humans, Amelogenesis imperfecta, Amino Acid Sequence, Phosphorylation, Frameshift Mutation, General Dentistry, Alleles, Sequence Deletion, Genetics, Dental Enamel Hypoplasia, Adenine, Research Reports, Exons, Enamel hypoplasia, Tooth enamel, medicine.disease, Pedigree, Mutagenesis, Insertional, medicine.anatomical_structure, Calcium, ENAM, Casein Kinases, Thymine
Abstract

Defects in the enamelin gene ( ENAM) cause amelogenesis imperfecta (AI). Our objective was to identify the genetic etiology of enamel hypoplasia in a Caucasian proband. Our hypothesis was that ENAM was defective. The proband and his father have an AG insertion (g.13185_13186insAG; p.422FsX448) in ENAM previously identified in AI kindreds from Slovenia and Turkey. The proband, his brother, and his mother have a novel missense mutation (g.12573C>T) that substitutes leucine for a phosphorylated serine (p.S216L) in the 32-kDa enamelin cleavage product. In this family, a defect in one ENAM allele caused minor pitting or localized enamel hypoplasia, whereas defects in both alleles caused severe enamel malformations, with little or no mineral covering dentin. Ser216 is one of two serines on the 32-kDa enamelin that is phosphorylated by Golgi casein kinase and is thought to mediate calcium binding. We propose that phosphorylation of enamelin is critical for its function.

Published
2010

36. FAM20A Mutations Can Cause Enamel-Renal Syndrome (ERS)

Author

Yuanyuan Hu, James P. Simmer, Hinda Daggag, Jan C.-C. Hu, Rachel N. Milkovich, Mohammad El-khateeb, Zaid H. Baqain, Parissa Aref, and Shih Kai Wang

Subjects
Proband, Cancer Research, Pathology, medicine.medical_specialty, lcsh:QH426-470, Amelogenesis Imperfecta, Golgi Apparatus, Biology, Kidney, Mice, 03 medical and health sciences, 0302 clinical medicine, Dental Enamel Proteins, stomatognathic system, Genetics, medicine, Animals, Humans, Amelogenesis imperfecta, Dental Enamel, Molecular Biology, Genetics (clinical), Ecology, Evolution, Behavior and Systematics, Fibromatosis, Gingival, 030304 developmental biology, 0303 health sciences, Enamel paint, Phosphotransferases, Calcinosis, Kidney metabolism, 030206 dentistry, Anatomy, Enamel hypoplasia, medicine.disease, Hypercementosis, lcsh:Genetics, Nephrocalcinosis, stomatognathic diseases, visual_art, Mutation, visual_art.visual_art_medium, Research Article, Calcification
Abstract

Enamel-renal syndrome (ERS) is an autosomal recessive disorder characterized by severe enamel hypoplasia, failed tooth eruption, intrapulpal calcifications, enlarged gingiva, and nephrocalcinosis. Recently, mutations in FAM20A were reported to cause amelogenesis imperfecta and gingival fibromatosis syndrome (AIGFS), which closely resembles ERS except for the renal calcifications. We characterized three families with AIGFS and identified, in each case, recessive FAM20A mutations: family 1 (c.992G>A; g.63853G>A; p.Gly331Asp), family 2 (c.720-2A>G; g.62232A>G; p.Gln241_Arg271del), and family 3 (c.406C>T; g.50213C>T; p.Arg136* and c.1432C>T; g.68284C>T; p.Arg478*). Significantly, a kidney ultrasound of the family 2 proband revealed nephrocalcinosis, revising the diagnosis from AIGFS to ERS. By characterizing teeth extracted from the family 3 proband, we demonstrated that FAM20A −/− molars lacked true enamel, showed extensive crown and root resorption, hypercementosis, and partial replacement of resorbed mineral with bone or coalesced mineral spheres. Supported by the observation of severe ectopic calcifications in the kidneys of Fam20a null mice, we conclude that FAM20A, which has a kinase homology domain and localizes to the Golgi, is a putative Golgi kinase that plays a significant role in the regulation of biomineralization processes, and that mutations in FAM20A cause both AIGFS and ERS., Author Summary FAM20A belongs to a family of 3 genes (FAM20A, FAM20B, and FAM20C) that encode kinases (phosphorylating enzymes) that modify proteins within the secretory pathway. FAM20C phosphorylates secretory calcium-binding phosphoproteins (SCPPs) that are critical for bone, dentin, and enamel biomineralization, and other calcium-binding proteins in milk and saliva. The function of FAM20A is unknown, but defects in the FAM20A gene have recently been shown to cause dental enamel defects along with enlarged gingiva (amelogenesis imperfecta and gingival fibromatosis syndrome or AIGFS; OMIM #614253). We identified three families with disease-causing mutations in FAM20A. All of the symptoms of AIGFS are also found in enamel-renal syndrome (ERS, OMIM #204690), which in addition features kidney calcifications known as nephrocalcinosis. We were only able to acquire a kidney ultrasound from one of our patients with FAM20A mutations, and it showed these kidney calcifications. We conclude that FAM20A mutations cause ERS and that persons diagnosed with AIGFS should have their kidneys examined. We also were able to obtain teeth from a patient with defined FAM20A mutations and to characterize the unusual mineral deposits that replace and add to normal tooth structures and may provide clues to the function of FAM20A.

Published
2013
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