Amelogenesis imperfecta, dentinogenesis imperfecta and dentin dysplasia revisited: problems in classification

The classification and prevalence of amelogenesis imperfecta is updated based upon new information in the literature. Problems with the currently used classification of inherited dentin defects are discussed.

DSPP mutation in dentinogenesis imperfecta Shields type II

We identified a nonsense mutation (Gln45stop) in exon 3 of the dentin sialophosphoprotein (DSPP) gene in a Chinese family with dentinogenesis imperfecta Shields type II (DGI-II), in which the affected members showed discoloration and severe attrition of their teeth, with obliterated pulp chambers.

Hereditary Dentin Defects

By the Shields classification, articulated over 30 years ago, inherited dentin defects are divided into 5 types: 3 types of dentinogenesis imperfecta (DGI), and 2 types of dentin dysplasia (DD). DGI type I is osteogenesis imperfecta (OI) with DGI. OI with DGI is caused, in most cases, by mutations in the 2 genes encoding type I collagen. Many genes are required to generate the enzymes that catalyze collagen’s diverse post-translational modifications and its assembly into fibers, fibrils, bundles, and networks. Rare inherited diseases of bone are caused by defects in these genes, and some are occasionally found to include DGI as a feature. Appreciation of the complicated genetic etiology of DGI associated with bony defects splintered the DGI type I description into a multitude of more precisely defined entities, all with their own designations. In contrast, DD-II, DGI-II, and DGI-III, each with its own pattern of inherited defects limited to the dentition, have been found to be caused by various defects in DSPP (dentin sialophosphoprotein), a gene encoding the major non-collagenous proteins of dentin. Only DD-I, an exceedingly rare condition featuring short, blunt roots with obliterated pulp chambers, remains untouched by the revolution in genetics, and its etiology is still a mystery. A major surprise in the characterization of genes underlying inherited dentin defects is the apparent lack of roles played by the genes encoding the less-abundant non-collagenous proteins in dentin, such as dentin matrix protein 1 ( DMP1), integrin-binding sialoprotein ( IBSP), matrix extracellular phosphoglycoprotein ( MEPE), and secreted phosphoprotein-1, or osteopontin ( SPP1, OPN). This review discusses the development of the dentin extracellular matrix in the context of its evolution, and discusses the phenotypes and clinical classifications of isolated hereditary defects of tooth dentin in the context of recent genetic data respecting their genetic etiologies.

Disorders of human dentin

Dentin, the most abundant tissue in teeth, is produced by odontoblasts, which differentiate from mesenchymal cells of the dental papilla. Dentinogenesis is a highly controlled process that results in the conversion of unmineralized predentin to mineralized dentin. By weight, 70% of the dentin matrix is mineralized, while the organic phase accounts for 20% and water constitutes the remaining 10%. Type I collagen is the primary component (>85%) of the organic portion of dentin. The non-collagenous part of the organic matrix is composed of various proteins, with dentin phosphoprotein predominating, accounting for about 50% of the non-collagenous part. Dentin defects are broadly classified into two major types: dentinogenesis imperfectas (DIs, types I-III) and dentin dysplasias (DDs, types I and II). To date, mutations in DSPP have been found to underlie the dentin disorders DI types II and III and DD type II. With the elucidation of the underlying genetic mechanisms has come the realization that the clinical characteristics associated with DSPP mutations appear to represent a continuum of phenotypes. Thus, these disorders should likely be called DSPP-associated dentin defects, with DD type II representing the mild end of the phenotypic spectrum and DI type III representing the severe end.

Mutational hot spot in the DSPP gene causing dentinogenesis imperfecta type II

The current system for the classification of hereditary defects of tooth dentin is based upon clinical and radiographic findings and consists of two types of dentin dysplasia (DD) and three types of dentinogenesis imperfecta (DGI). However, whether DGI type III should be considered a distinct phenotype or a variation of DGI type II is debatable. In the 30 years since the classification system was first proposed, significant advances have been made regarding the genetic etiologies of inherited dentin defects. DGI type II is recognized as an autosomal dominant disorder with almost complete penetrance and a low frequency of de novo mutations. We have identified a mutation (c.52G-->T, p.V18F) at the first nucleotide of exon 3 of the DSPP (dentin sialophosphoprotein) gene in a Korean family (de novo) and a Caucasian family. This mutation has previously been reported as causing DGI type II in a Chinese family. These findings suggest that this mutation site represents a mutational "hot spot" in the DSPP gene. The clinical and radiographic features of these two families include the classic phenotypes associated with both DGI type II and type III. Finding that a single mutation causes both phenotypic patterns strongly supports the conclusion that DGI type II and DGI type III are not separate diseases but rather the phenotypic variation of a single disease. We propose a modification of the current classification system such that the designation "hereditary opalescent dentin" or "DGI type II" should be used to describe both the DGI type II and type III phenotypes.

Dentin phosphoprotein compound mutation in dentin sialophosphoprotein causes dentinogenesis imperfecta type III

A rare compound mutation involving a 36 bp deletion and 18 bp insertion within exon 5 of the dentin sialophosphoprotein (DSPP) gene has been identified in a family with dentinogenesis imperfecta type III (DGI-III). The DSPP gene encodes two major tooth matrix proteins dentin sialoprotein (DSP) and dentin phosphoprotein (DPP). DSPP mutations associated with DGI-III results in an in frame truncation of the serine aspartic acid triplet repeat found in DPP near the highly conserved carboxyl terminal region shortening the protein by six amino acids. Clinically this family presents with discolored amber opalescent teeth and severe attrition of the tooth structure. This study is the first report of a mutation within DPP associated with a genetic dentin disease. Our study indicates that DGI-III is allelic with some forms of DGI-II with and without progressive hearing loss and dentin dysplasia type II that have been shown to be caused by mutations within the DSP coding or signal peptide regions.

Oral findings in osteogenesis imperfecta

The dentitions of twenty-eight patients, each of whom had either an autosomal dominant or a sporadic osteogenesis imperfecta (OI) syndrome, were evaluated. The diagnosis of dentinogenesis imperfecta (DI) could be established in all seven patients with dominantly inherited OI in three families, while all eight persons with dominant OI in three other families had normal teeth. Of the thirteen remaining patients with OI, twelve had no family history of the disorder; four had DI and eight had normal teeth. One person had a family history of OI and DI. All patients with abnormal tooth wear and spontaneous tooth fractures had DI. The DMF ratio increased with age in all patients with OI type I and was higher among the patients with OI type III and DI. Class III malocclusions were found in 66% of the patients. A statistically significant high incidence of impacted first and second molars was noted.

Phenotypic variation in dentinogenesis imperfecta/dentin dysplasia linked to 4q21

Dentinogenesis imperfecta (DGI) and dentin dysplasia (DD) are allelic disorders that primarily affect the formation of tooth dentin. Both conditions are autosomal-dominant and can be caused by mutations in the dentin sialophosphoprotein gene (DSPP, 4q21.3). We recruited 23 members of a four-generation kindred, including ten persons with dentin defects, and tested the hypothesis that these defects are linked to DSPP. The primary dentition showed amber discoloration, pulp obliteration, and severe attrition. The secondary dentition showed either pulp obliteration with bulbous crowns and gray discoloration or thistle-tube pulp configurations, normal crowns, and mild gray discoloration. Haplotype analyses showed no recombination between three 4q21-q24 markers and the disease locus. Mutational analyses identified no coding or intron junction sequence variations associated with affection status in DMP1, MEPE, or the DSP portion of DSPP. The defects in the permanent dentition were typically mild and consistent with a diagnosis of DD-II, but some dental features associated with DGI-II were also present. We conclude that DD-II and DGI-II are milder and more severe forms, respectively, of the same disease.

Elucidation of the sequence and the genomic organization of the human dentin matrix acidic phosphoprotein 1 (DMP1) gene: exclusion of the locus from a causative role in the pathogenesis of dentinogenesis imperfecta type II

The dentin matrix acidic phosphoprotein 1 (DMP1) gene has been mapped to human chromosome 4q21 and shown to exhibit no recombination with the autosomal dominant disorder of dentin formation, dentinogenesis imperfecta type II. In the current study, sequencing of DMP1 cDNA and genomic clones has indicated that the human gene contains an open reading frame of 1539 bp, which predicts a highly acidic, serine-rich protein of 513 amino acids. Comparison of the human DMP1-coding sequence with that of the rat, mouse, and cow indicated that the predicted protein contains a conserved hydrophobic signal peptide sequence and an Arg-Gly-Asp cell attachment sequence. The gene is encoded by six exons, the splicing phase of which is type 0, the first exon containing solely 5' untranslated sequence. Sequencing of each of the coding exons in individuals affected by dentinogenesis imperfecta type II failed to reveal any disease-specific mutations, suggesting that mutations in DMP1 are not causative of this condition at least in the two families examined in this study.

Genomic organization of the human osteopontin gene: exclusion of the locus from a causative role in the pathogenesis of dentinogenesis imperfecta type II

Osteopontin (SPP1) is the principal phosphorylated glycoprotein of bone that is also expressed in a limited number of other tissues including dentine. In the current investigation we report the genomic organization of the SPP1 gene, which comprises seven exons, six of which contain coding sequence. The splice sites for exon donor and acceptor positions are in close agreement with previously published consensus sequences. Comparison of the human gene with its murine and bovine counterparts revealed a highly homologous organization. A highly informative short tandem repeat polymorphism isolated at the SPP1 locus showed no recombination with the autosomal dominant disorder dentinogenesis imperfecta type II. Nevertheless, sequencing of each exon in individuals affected by this disorder failed to reveal any disease-specific mutations.

Refined mapping of the human dentin sialophosphoprotein (DSPP) gene within the critical dentinogenesis imperfecta type II and dentin dysplasia type II loci

Dentinogenesis imperfecta type II and dentin dysplasia type II are diseases resulting in abnormal dentin formation, which have been mapped to overlapping regions of human chromosome 4q defined by markers D4S2691 and D4S2692 (6.6 cM) and D4S3291 and SPP1 (14.1 cM), respectively. Recently, two of the major non-collagenous proteins of dentin, dentin sialoprotein (DSP) and dentin phosphoprotein (DPP, phosphophoryn) have been shown to be encoded by a single gene, termed dentin sialophosphoprotein (DSPP), which has been mapped to human chromosome 4. The purpose of this study was to perform refined mapping of DSPP related to these disease loci by gene content mapping, as well as to place the DSPP gene on the physical map of human chromosome 4 by sequence tagged site (STS) content mapping. Human genomic DSPP clones were isolated, and gene content mapping performed with specific primers for dentin matrix protein 1 (DMP1), bone sialoprotein (BSP) and osteopontin (secreted phosphoprotein 1, SPP1). STS content mapping was then performed with flanking STS markers to these dentin/bone gene loci. Our results demonstrate that the DSPP and DMP1 genes are within a maximum distance of 110 kb. Both DSPP and DMP-1 have been placed on the physical map of human chromosome 4 within the interval defined by markers D4S564 and D4S1292. DSPP is thereby strengthened as a candidate gene for both DGI-II and DD-II.

Amelogenesis imperfecta with taurodontism and the tricho-dento-osseous syndrome: separate conditions or a spectrum of disease?

Various authors have allocated a diagnosis of tricho-dento-osseous syndrome to cases originally reported as amelogenesis imperfecta (hypomaturation-hypoplasia type) with taurodontism. The resulting confusion has prompted this critical review of the literature, and further information has been obtained from the authors concerned. Criteria for diagnosis of the two conditions are proposed.

Assessment of dysplastic dentin in osteogenesis imperfecta and dentinogenesis imperfecta

Two semiquantitative scoring systems, Clinical Radiographic Score (CRS) and Dysplastic Dentin Score (DDS), were introduced for analyzing degree of dysplastic manifestations in dentin. The utility of both systems was demonstrated in a large material of teeth from patients with dentinogenesis imperfecta (DI) and osteogenesis imperfecta (OI). Twenty teeth from healthy controls, 81 teeth from 40 patients with OI, and 18 teeth with DI without OI (DI type II) were examined. The degree of dysplasia was correlated with type and form of OI and type of DI. The median DDS did not differ between DI associated with OI (DI type I) and DI type II. DDS in OI patients without clinical signs of DI was above that of control teeth. Both circumpulpal and mantle dentin showed increased DDS, although circumpulpal dentin was more severely affected. The median DDS was highest for the most severe type of non-lethal OI (type III). DDS increased significantly with form (severity) of OI. A significant association between DDS and CRS was found, although diagnosis of DI in less severe cases was not possible based on radiographic or clinical signs alone. Thus, the DDS system proved valuable when the CRS system based on radiographic/clinical manifestations failed, the most significant finding being subclinical histological manifestations of DI in patients with OI but without clinical or radiographic signs of DI. These subtle dysplastic changes are most likely an expression of genetic disturbances associated with OI and should not be diagnosed as DI, but rather be termed histologic manifestations of dysplastic dentin associated with OI.

An unusual presentation of opalescent dentin and Brandywine isolate hereditary opalescent dentin in an Ashkenazic Jewish family

Two children of Austrian Ashkenazic Jewish background, related as second cousins, have a variant of opalescent dentin in their deciduous teeth. This has been classified by Witkop as Brandywine isolate hereditary opalescent dentin and by Shields as dentinogenesis imperfecta type III. One of the children also has dysmorphic facial features, seizures, and severe mental retardation. Her mother has dysmorphic facial features and mild mental retardation. The mothers of both children and several other family members have classic opalescent dentin (dentinogenesis imperfecta type II). Radiographs of the deciduous and permanent dentitions of one mother showed obliterated pulp chambers. Confirmation of obliterated pulp chambers in the deciduous teeth of the mother of a child with Brandywine isolate hereditary opalescent dentin makes it unlikely that classic opalescent dentin and Brandywine isolate hereditary opalescent dentin are separate genetic disorders. Evidence from this family supports the hypothesis that Brandywine isolate hereditary opalescent dentin is a variant of opalescent dentin.

Refinement of the dentinogenesis imperfecta type II locus to an interval of less than 2 centiMorgans at chromosome 4q21 and the creation of a yeast artificial chromosome contig of the critical region

Dentinogenesis imperfecta type II is an autosomal-dominant disorder of dentin formation which has been mapped to the 6.6 centiMorgan D4S2691-D4S2692 interval at human chromosome 4q21. In the current investigation, the use of four short tandem repeat polymorphisms has allowed the critical region to be refined to an interval of less than 2 centiMorgans defined by recombination events in unrelated, affected individuals from two families both of which show independent evidence for linkage to chromosome 4q21. The creation of a yeast artificial chromosome contig of this newly defined interval has allowed us to demonstrate that the critical region encompasses approximately 2 Mb of DNA and that the dentin-specific gene, dentin sialoprotein, maps to this interval within 300 kb of dentin matrix acidic phosphoprotein 1 and bone sialoprotein. Moreover, dentin sialoprotein shows no recombination with the dentinogenesis imperfecta type II phenotype. Dentin sialoprotein is therefore a candidate for the dentinogenesis imperfecta type II locus.

A probable common disturbance in the early stage of odontoblast differentiation in Dentinogenesis imperfecta type I and type II

Deciduous teeth from 7 patients with dentinogenesis imperfecta (DI) Type I and Type II were examined by conventional microscopy. A defective layer was found which runs parallel with the dentinal surface in the outer portion of dentin in teeth of both types. Dentinal tubules were interrupted in the vicinity of this layer. When the ground sections were examined after being stained by the phosphophoryn staining method, the DI Type I dentin was found to contain phosphophoryn at the same low level as the DI Type II dentin, suggesting similar deficiency in phosphophoryn concentration. These results suggest that both types of DI have a common primary disturbance in the early stage of odontoblast differentiation.

Genetic linkage of the dentinogenesis imperfecta type III locus to chromosome 4q

Dentinogenesis imperfecta type III (DGI-III) is an autosomal-dominant disorder of dentin formation which appears in a tri-racial southern Maryland population known as the "Brandywine isolate". This disease has suggestive evidence of linkage to the long arm of human chromosome 4 (LOD score of 2.0) in a family presenting with both juvenile periodontitis and DGI-III. The purpose of this study was to screen a family presenting with only DGI-III to determine if this locus was indeed on chromosome 4q. Furthermore, we wanted to determine if DGI-III co-localized with dentinogenesis imperfecta type II (DGI-II), which has been localized to 4q21-q23. Therefore, a large kindred from the Brandywine isolate was identified, oral examination performed, and blood samples collected from 21 family members. DNA from this family was genotyped with 6 highly polymorphic markers that span the DGI-II critical region of chromosome 4q. Analysis of the data yielded a maximum two-point LOD score of 4.87 with a marker for the dentin matrix protein 1 (DMP1) locus, a gene contained in the critical region for DGI-II. Our results demonstrated that the DGI-III locus is on human chromosome 4q21 within a 6.6 cM region that overlaps the DGI-II critical region. These results are consistent with the hypothesis that DGI-II is either an allelic variant of DGI-III or the result of mutations in two tightly linked genes.

Diagnostic features and pedodontic-orthodontic management in dentinogenesis imperfecta type II: a case report

Dentinogenesis imperfecta type II, also known as hereditary opalescent dentin, is an isolated inherited condition transmitted as an autosomal dominant trait affecting the primary and permanent dentition. The combined pedodontic-orthodontic management of a 4-year-old child is described. Following orthodontic analysis to encourage a favourable growth outcome, treatment comprised restoration of the primary teeth with stainless steel crowns and composite crowns. Differential diagnosis and alternative therapies, including orthodontic considerations, are discussed.

Familial tarda type osteogenesis imperfecta with dentinogenesis imperfecta Type I. Case report

This paper presents a case of dentinogenesis imperfecta Type I occurring in a patient with familial tarda type osteogenesis imperfecta. The investigation and management of this patient is described.

[The radiology of osteogenesis imperfecta]

The term "osteogenesis imperfecta" refers to a heterogeneous group of hereditary diseases characterized by osteopenia, increased bone fragility, blue sclerae and dentinogenesis imperfecta. The abnormal synthesis of type-I collagen is responsible for the pathologic changes occurring not only in bone, but also in skin, tendons and ligaments, sclerae and teeth. The clinical and radiographic features of 5 cases (2 males and 3 females; age range: 1 month to 29 years) were analyzed. The patients were unrelated with each other. The diagnosis of the different types of osteogenesis imperfecta is as difficult as the identification of the various genotypes which are responsible for the different clinical pictures. The most characteristic radiographic pattern--which is observed in any type of the disease--consists in osteopenia associated, in most cases, with multiple fractures and deformities--e.g., micromelia, large metaphysis, archon long bones. Typically, "pop corn" calcifications are observed in both epiphysis and metaphysis of long bones. Dentinogenesis imperfecta is one of the most significant clinical patterns, and it can be the only bone abnormality. The prognosis of osteogenesis imperfecta is as varied as its genetics--i.e., the fractures discovered at birth are not necessarily a negative prognostic sign.

Management of dentinogenesis imperfecta: a review of two case reports

Dentinogenesis imperfecta (DI) is an inherited disorder that affects dentin and often manifests as tooth discoloration; in addition, the dentition is also extremely susceptible to wear. Treatment of DI focuses primarily on protecting affected dentin, reducing sensitivity, and improving esthetics. Routine restorative materials, such as amalgams and composites, may be used. In more severe cases, the treatment of choice is full coverage crowns, while bonding of veneers may be used to improve the esthetics of the anterior teeth. This study presents two cases of Type II DI in the same family and the management of each case. Restorative management included amalgams, composite veneers, crowns, bridges, and overdentures.