Analysis of human enamel genes: insights into genetic disorders of enamel

A number of inherited craniofacial diseases are known to be associated with gene mutations. Inherited genetic disorders of enamel formation called amelogenesis imperfecta (AI) affect the human population with a prevalence of 1 in 14,000 in the United States. Amelogenins, the major proteins in developing enamel matrix of mammalian teeth, have been suggested to participate in normal enamel matrix biomineralization, as well as with abnormal biomineralization such as seen in AI. The complementary DNA for mouse amelogenin gene (AMEL) has been cloned, characterized, and used as a probe to establish the chromosomal locations of AMEL for mouse and man. The human AMEL gene sequences have been located to the distal short arm p22.1----p22.3 region of the X chromosome, and the pericentromeric region of the Y chromosome. An assignment of human AMEL gene to the X chromosome p22 region together with a recent assignment of the X-linked AI disease locus to the Xp22.2 region support the association of the AMEL-X gene with AI. This also leads us to propose that a mutated AMEL-X gene produces altered amelogenin polypeptide, which is defective in its ability to participate in mineralization of enamel matrix, thus giving rise to the X-linked phenotypes of AI.

Cartilage, bone and tooth induction during early embryonic mouse mandibular morphogenesis using serumless, chemically-defined medium

Studies were designed to test the hypothesis that plasma- and serum-deprived embryonic cells and tissues in vitro are capable of producing growth regulating factors which augment cartilage, bone and tooth induction during mouse mandibular process development. Embryonic mouse first branchial arch-derived mandibular processes (E11-E12, Theiler stages 18-19) or cap stage molar tooth (M1) organs (E15-E16, Theiler stage 23) expressed morphogenesis, histogenesis and cytodifferentiation (e.g., Meckel's cartilage and mandibular bone) when cultured as explants in permissive serumless and chemically-defined BGJB medium for periods up to 31 days in vitro. Organ cultures of early mandibular process explants in serumless conditions showed DNA synthesis comparable to the time- and position-restricted patterns characteristic for control in vivo development. As a paradigm for embryonic cell expression of putative growth factors, sense and antisense oligodeoxynucleotide probes corresponding to amino acids 1070-1081 for preproEGF, and antibodies directed against amino acids 348-691 of preproEGF, were used to identify and localize mRNA transcripts and translation products. Our preliminary evidence suggests that odontogenic epithelial and ectomesenchyme cells produce EGF-like products during instructive phases of tooth development. We suggest that plasma- and serum-deprived cells and tissues in vitro produce autocrine and/or paracrine growth factors which mediate embryonic mandibular morphogenesis, histogenesis and cytodifferentiation.

Mouse ameloblasts do not transcribe the albumin gene

The interpretation of recent experimental evidence has lead to several discussions at international meetings which have included the suggestion that enamelins are not tissue-specific gene products but rather are similar to, or are identical to, albumin. Further complicating the issue has been the proposal by several investigators that albumin participates in the organization of hard tissues. The experimental strategy described in this study was to hybridize the mouse albumin gene cDNA clone, palb-3, to a Northern blot of secretory phase mouse mandibular first molar RNAs. This approach would permit the evaluation of the potential transcription of the albumin gene by differentiated ameloblasts as well as other cells of the odontogenic organ. The results of this approach indicated that odontogenic cells did not transcribe the albumin gene. Albumin polypeptides, therefore, cannot be synthesized by odontogenic cells and cannot be identical to odontogenic tissue-specific gene products. If albumin is incorporated into developing enamel matrix wherein it participates in undefined roles during enamel matrix organization, it cannot arise as a biosynthetic product of the odontogenic organ.

Human amelogenins: sequences of "TRAP" molecules

The extracellular protein matrix of developing enamel includes a major class of proteins, the amelogenins, which are believed to be concerned in regulating enamel biomineralization. Previous studies have shown the amelogenins of the extracellular matrix to be a complex of proline-rich hydrophobic proteins which, it is suggested, arise through posttranslational and postsecretory processing of a primary ameloblast gene product. More recently, it has been shown that the human amelogenin gene is located on both the X and Y chromosomes raising the possibility that polymorphism at the level of the gene may also contribute to the observed complexity of these enamel matrix proteins. To investigate such possible amelogenin polymorphism in developing human dental enamel, individual fractionated by size-exclusion and reversed-phase high pressure liquid chromatography (HPLC). Two tyrosine-rich amelogenin polypeptides (TRAPs) of approximately 5 kDa in size were isolated from an individual human dentition and characterized by automated gas-phase sequencing. These polypeptides were found to be of 42 (TRAP-2) and 44 (TRAP-1) amino acid residues in length; TRAP-2 lacked a carboxy-terminal -Gly-Trp sequence as has previously been described for analogous bovine TRAP molecules. However, residue #25 of the human TRAP-2 sequence was refractory to sequencing, apparently differing from the Trp-25 identified in TRAP-1. These findings suggest (1) two forms of TRAP molecules, differing only by cleavage of a carboxy-terminal dipeptide, are a general feature of human and other mammalian enamel proteins, probably being derived by postsecretory cleavage from the primary extracellular amelogenin; and (2) in human developing enamel four forms of TRAPs may arise either from polymorphism at the level of the gene, or by posttranscriptional alternative splicing of amelogenin mRNAs, coupled with specific post-secretory proteolytic processing.

Localization of epidermal growth factor precursor in tooth and lung during embryonic mouse development

The murine epidermal growth factor (EGF) precursor is a 1217 amino acid protein which contains mature EGF (amino acid residues 977-1029) as well as eight EGF-like repeats. Although the highest levels of EGF are found in the adult male mouse submandibular gland, the results of in situ hybridization studies and mRNA analyses suggest that EGF precursor mRNA is synthesized in several adult mouse tissues including the lung and the incisor. To determine if EGF precursor gene expression is intrinsic to the developmental program for either embryonic tooth or lung organogenesis, sense and antisense oligodeoxyribonucleotide probes corresponding to amino acids 1070-1081 of the precursor were used to localize cellular sites of synthesis of EGF precursor mRNA by in situ hybridization. Antibodies directed against amino acid residues 348-691 of the precursor were used in immunodetection techniques to identify either EGF precursor protein or processed derivatives. In contrast to earlier reports indicating that embryonic mouse tissues do not synthesize EGF precursor mRNA, we found that EGF precursor mRNA is present in clusters of ectoderm-, mesoderm-, and ectomesenchyme-derived cells associated with embryonic teeth and lung organs. Moreover, epitopes common to the EGF precursor were immunolocalized in both the epithelial and mesenchymal tissues of embryonic mouse tooth and lung organs. These results suggest that the EGF precursor and/or motifs contained within the precursor molecule, including mature EGF, may play an instructive or permissive role in epithelial-mesenchymal interactions pursuant to organogenesis.

Amelogenin gene expression in mouse incisor heterotopic recombinations

Mouse incisor tooth organs express the genes responsible for enamel extracellular matrix formation exclusively on the labial surface of the organ. A previous investigation has suggested that lingual inner dental epithelium of mouse incisor did not contain potential ameloblasts. The present work extends our histological observations, by analyzing the presence of mouse amelogenin mRNA in heterotopic mouse incisor tissue recombinations using in situ hybridization to 35S-labelled asymmetric complementary RNA probes from a cDNA specific to the mouse Mr 26 x 10(3) amelogenin. Labial polarized ameloblasts located in front of the lingual predentin layer were associated with numberous hybridization signals indicating an increased density of amelogenin mRNA. In contrast, the lingual inner dental epithelium in contact with labial predentin never showed amelogenin hybridization signals, indicating the absence of amelogenin transcripts. These results confirm our observation that the lingual inner dental epithelium does not contain potential ameloblasts, since these cells do not transcribe nor accumulate mRNA amelogenin even when in contact with a favorable microenvironment provided by the labial predentin.

Amelogenesis in vitro: a model for studies of epithelial postsecretory processing during tissue-specific extracellular matrix biomineralization

The extracellular matrix (ECM) of developing mammalian enamel comprises a complex of unusual epithelial-derived proteins, which appear to function in concert to initiate and propagate tissue-specific biomineralization. Following enamel protein synthesis by ameloblast cells within the enamel organ, the subsequent steps of posttranslational modification, secretion, postsecretory processing and eventual removal of these proteins from forming enamel are largely unknown. To address this issue we have designed studies to investigate the hypothesis that enamel proteins are removed from enamel and translocated into the vasculature as relatively high-molecular-weight components. We examined enamel proteins recovered from serumless medium during prolonged organ culture of mouse capstage mandibular first molars. By 21 days in vitro the tooth crown formed and dentine and enamel biomineralization were apparent. At 31 days, explants retained metabolic activity and the enamel matrix showed extensive transformation. Immunologically identified enamel proteins of 26-18 k Da were produced by cultured tooth organs, translocated from tooth explants to the culture medium, recovered from the medium and then compared to control enamel protein from in vivo preparations. Comparable postsecretory processing of the 26-k Da amelogenin protein was observed in vitro and in vivo. We speculate that the pathway reported in the present studies is comparable to the processing of the enamel protein polypeptides of the maturing enamel which occurs in vivo. The in vitro organ culture model described in this report provides an approach with which to investigate the molecular events associated with epithelial-derived postsecretory processing of ECM molecules associated with tissue-specific biomineralization.

Human and mouse cementum proteins immunologically related to enamel proteins

SDS-polyacrylamide gel electrophoresis, immunoblot and amino acid composition analyses were applied to human and mouse acellular cementum proteins immunologically related to enamelins and amelogenins. In this analysis, anti-mouse amelogenin, anti-human enamelin and synthetic peptide (e.g., -LPPHPGHPGYIC-) antibodies were shown to cross-react with tooth crown-derived enamelin with a molecular mass of 72,000 Da (72 kDa), amelogenins (26 kDa), and also to four human cementum proteins (72, 58, 50 and 26 kDa) and two mouse cementum proteins (72 and 26 kDa). Each of the antibodies recognized tooth root-derived cementum polypeptides which share one or more epitopes with tooth crown-derived enamel proteins. The molecular mass and isoelectric points for crown-derived and root-derived enamel-related proteins were similar. Analysis of human and mouse cementum proteins revealed a characteristic amino acid composition enriched in glutamyl, serine, glycine, alanine, proline, valine and leucine residues; compared to the major enamel protein amelogenin, cementum proteins were low in proline, histidine and methionine. The human and mouse putative intermediate cementum proteins appear to represent a distinct class of enamel-related proteins. Moreover, these results support the hypothesis that epithelial root sheath epithelia express several cementum proteins immunologically related to canonical enamel proteins.

Human and mouse amelogenin gene loci are on the sex chromosomes

Enamel is the outermost covering of teeth and is the hardest tissue in the vertebrate body. The enamel matrix is composed of enamelin and amelogenin classes of protein. We have determined the chromosomal locations for the human and mouse amelogenin (AMEL) loci using Southern blot analyses of DNA from human, mouse, or somatic cell hybrids by hybridization to a characterized mouse amelogenin cDNA. We have determined that human AMEL sequences are located on the distal short arm of the X chromosome in the p22.1----p22.3 region and near the centromere on the Y chromosome, possibly at the proximal long arm (Yq11) region. These chromosomal assignments are consistent with the hypothesis that perturbation of the amelogenin gene is involved in X-linked types of amelogenesis imperfecta, as well as with the Y-chromosomal locations for genes that participate in regulating tooth size and shape. Unlike the locus in humans, the mouse AMEL locus appears to be assigned solely to the X chromosome. Finally, together with the data on other X and Y chromosome sequences, these data for AMEL mapping support the notion of a pericentric inversion occurring in the human Y chromosome during primate evolution.

Hertwig's epithelial root sheath differentiation and initial cementum and bone formation during long-term organ culture of mouse mandibular first molars using serumless, chemically-defined medium

Studies were designed to test the hypothesis that Hertwig's epithelial root sheath (HERS) synthesizes and secretes enamel-related proteins that participate in the process of acellular cementum formation. Our experimental strategy was to examine sequential root development of the mouse mandibular first molar in vivo and in long-term organ culture in vitro using serumless, chemically-defined medium. Using anti-amelogenin, anti-enamelin and anti-peptide antibodies, enamel-related antigens were localized within intermediate cementum during HERS differentiation and root formation in vivo. Cap stage molars maintained for periods of up to 31 days in organ culture expressed morphogenesis and cytodifferentiation as identified by tooth crown and initial root, cementum and bone formation. Metabolically-labeled HERS products were analyzed by immunodetection using enamel-related antibodies and one- and two-dimensional SDS gel electrophoresis. A 72 kDa and 26 kDa polypeptide were identified in forming mouse cementum. Both of these root putative cementum proteins yield similar (identical) amino acid compositions; however, both proteins differed from the compositions of either mouse crown enamelin or amelogenin proteins. This approach provides a new and novel in vitro model towards understanding HERS differentiation and functions related to root and bone formation. The data support the hypothesis that HERS cells synthesize polypeptides related to but also different from canonical crown enamel proteins.

In situ hybridization analysis of keratin gene expression in human ameloblastomas

Complementary DNA (cDNA) clones corresponding to the 55 kDa (K 14) and 59 kDa (K 10) keratins were used as probes for in situ hybridization analysis for the expression of keratin genes in human ameloblastomas and in oral mucosa. Transcripts for either the K 14 keratin or the K 10 keratin were restricted in their spatial distribution within stratified epithelia consistent with the stage of differentiation of the keratinocyte: the K 14 keratin gene transcript was restricted to the basal cell layers of the mucosa, while the K 10 keratin transcript was expressed predominantly in suprabasal cells, within the granular and prickle layers. In contrast, only the K 14 keratin transcript could be identified within the epithelial cells of human ameloblastomas. The differentiation-specific keratin transcript (K 10) was not present at detectable levels in this type of odontogenic tumors. In an atypical, infiltrating ameloblastoma, neither the K 10 nor the K 14 transcript could be identified. Granular cells within one ameloblastoma expressed the K 14 transcript. A detailed examination of the pattern of gene expression in these unique tumors may lead to a better understanding of their pathogenesis.

Spatial- and temporal-restricted pattern for amelogenin gene expression during mouse molar tooth organogenesis

Position- and time-restricted amelogenin gene transcription was analysed in developing tooth organs using in situ hybridization with asymmetric complementary RNA probes produced from a cDNA specific to the mouse 26 × 10(3) Mr amelogenin. In situ analysis was performed on developmentally staged fetal and neonatal mouse mandibular first (M1) and maxillary first (M1) molar tooth organs using serial sections and three-dimensional reconstruction. Amelogenin mRNA was first detected in a cluster of ameloblasts along one cusp of the M1 molar at the newborn stage of development. In subsequent developmental stages, amelogenin transcripts were detected within foci of ameloblasts lining each of the five cusps comprising the molar crown form. The number of amelogenin transcripts appeared to be position-dependent, being more abundant on one cusp surface while reduced along the opposite surface. Amelogenin gene transcription was found to be bilaterally symmetric between the developing right and left M1 molars, and complementary between the M1 and M1 developing molars; indicating position-restricted gene expression resulting in organ stereoisomerism. The application of in situ hybridization to forming tooth organ geometry provides a novel strategy to define epithelial-mesenchymal signal(s) which are believed to be responsible for organ morphogenesis, as well as for temporal- and spatial-restricted tissue-specific expression of enamel extracellular matrix.

Biosynthesis and characterization of rabbit tooth enamel extracellular-matrix proteins

Tooth enamel biomineralization is mediated by enamel proteins synthesized by ameloblast cells. Two classes of proteins have been described: enamelins and amelogenins. In lower vertebrates the absence of amelogenins is believed to give rise to aprismatic enamel; however, rabbit teeth, which apparently do not synthesize amelogenins, form prismatic enamel. The present study was designed to characterize the enamel proteins present in rabbit tooth organs and to gain an insight into the process of biomineralization. Rabbit enamel extracellular-matrix proteins were isolated and characterized during sequential stages of rabbit tooth organogenesis. The biosynthesis of enamel proteins was analysed by metabolic 'pulse-chase' experiments as well as mRNA-translation studies in cell-free systems. Our results indicated that rabbit enamel extracellular matrix contains 'amelogenin-like' proteins. However, these proteins are not synthesized as typical amelogenins, as in other mammalian species, thus suggesting that they are the processing products of higher-molecular-mass precursors. An N-terminal amino acid sequence of 29 residues, considered characteristic of mammalian amelogenins, was present in the rabbit 'amelogenin-like' proteins. By using anti-peptide antibodies to this region, similar epitopes were detected in all nascent enamel proteins, including enamelins. These studies suggest that the N-terminal sequence might be characteristic of all enamel proteins, not only amelogenins.

Sequential expression and differential function of multiple enamel proteins during fetal, neonatal, and early postnatal stages of mouse molar organogenesis

We have established the time and position of expression for multiple enamel proteins during the development of the mouse molar tooth organ. Using high-resolution two-dimensional gel electrophoresis coupled with immunoblotting and immunocytochemistry, a 46-kDa enamel protein (pI, 5.5) was detected during late cap stage (18-days gestation, E18d) within differentiation-zone-II inner enamel epithelia associated with an intact basal lamina. At E19d a second enamel polypeptide of 72 kDa (pI, 5.8) was identified at the time and position of initial biomineralization in differentiation zone V. At 20 days, differentiation-zone-VI ameloblasts without basal lamina (late bell stage) expressed 46- and 72-kDa enamel proteins and, in addition, expressed a relatively more basic 26-kDa enamel protein (pI, 6.5-6.7); detected after initial formation of calcium hydroxyapatite crystals. Antibodies raised against chemically synthesized enamel peptides cross-reacted with both the 72-kDa and 26-kDa polypeptides, but did not cross-react with the 46-kDa enamel polypeptide. The sequential expression of multiple enamel proteins suggests several functions: (a) the anionic enamel proteins may provide an instructive template for calcium hydroxyapatite crystal formation; (b) the more neutral proteins possibly serve to regulate size, shape and rates of enamel crystal formation. We suggest that initial expression of enamel gene products during mouse tooth development possibly recapitulates ancestral features of amelogenesis documented in prereptilian vertebrates. These results imply that multiple instructive signals may be responsible for mammalian enamel protein induction and that the sequential expression of a family of enamel proteins reflects the evolutionary acquisition of a more complex genetic program for amelogenesis.

Molecular determinants of cranial neural crest-derived odontogenic ectomesenchyme during dentinogenesis

Positional information on tooth morphogenesis is investigated by the identification of when and where phenotypic markers are expressed during odontogenesis. This temporal and positional information is correlated with the instructive and permissive signaling required for both dentinogenesis and amelogenesis. Of particular interest is the establishment of a map for the cranial neural crest-derived dental papilla ectomesenchyme and the odontoblast cell lineages. The expression of ectomesenchyme-derived cytotactin, dentin phosphoprotein, and epithelial-derived enamel proteins was studied in mice using embryonic, fetal, and postnatal mandibular first molar tooth organ development. This review summarizes the observations in the context of instructive epithelial-mesenchymal interactions and suggests that amelogenesis imperfecta and dentinogenesis imperfecta may in part be explained by alterations in these differentiation markers. Recombinant DNA methods should facilitate future investigations of these inherited dental disorders.

Examining the possible molecular origins for enamel protein complexity

Our strategy was to examine each of the three loci capable of contributing to the observed complexity 0 of mouse amelogenin proteins recovered from forming enamel: the genome (gene); the transcription apparatus (messenger RNA); and the translation apparatus (proteins). Our approach was based on recombinant DNA technology and a complementary DNA (cDNA) clone, pMa5-5, specific to the predominant mouse amelogenin protein. An "artificial ameloblast" was engineered based on pMa5-5 and the resulting synthetic products compared to those from authentic ameloblasts. First, the genome probably is not responsible for amelogenin complexity: Southern analysis indicates that the amelogenin gene exists as a single copy in either differentiated dental tissue or germ line tissue. Thus, ectomesenchymal-derived instructive signals for ameloblast differentiation do not lead to re-arrangement or amplification of the amelogenin gene. Next, using nucleic acid hybridization techniques, we examined messenger RNA from mouse ameloblasts. Northern analysis of authentic mRNA from mouse ameloblasts, with either the intact or 3'-end of pMa 5-5 used as the reporter molecule, indicates that only one size class of mRNA was detectable. We conclude that at the sensitivity of this assay there is no evidence for multiple mRNAs. Last, "artificial ameloblasts" were engineered so that the translation apparatus could be examined as a source of amelogenin complexity. Capped, artificial mRNAs were constructed to the pMa 5-5 template and used to program the synthesis of amelogenin polypeptides by translation in a cell-free system. When the resulting total translation products were immunoprecipitated with the rabbit anti-mouse amelogenin antibody, we observed multiple polypeptides, suggesting that the utilization of alternative start sites may also contribute to the observed complexity of amelogenin proteins, at least for artificial mRNAs translated in vitro.

Amelogenin antigenic domain defined by clonal epitope selection

To experimentally examine the participation of amelogenins in controlled mineral-phase maturation of mammalian enamel, the identification of the individual proteins and their corresponding gene(s) is required. For this purpose, cDNAs were constructed from polyadenylated RNA from 2-day postnatal murine teeth, molecularly cloned into lambda-gt11 expression vectors and transfected into E. coli. The cDNA library was screened for amelogenin gene(s) by using either antibody or nucleic acid probes. An amelogenin cDNA clone encoding 79 carboxy-terminal amino acid residues and 100 nucleotides of the 3' noncoding sequence was demonstrated to contain a major antigenic site for amelogenin protein by immunostaining of specific amelogenin proteins from total extracted enamel protein blots using clonal epitope selected antibody. This is the first report linking amelogenin epitope(s) to a defined DNA sequence, and consequently a defined portion of the amino acid sequence for amelogenins. Secondary structure analysis, based on the relative average linear hydropathy of the amino acid sequence of amelogenin, predicted epitopes in the amino terminus of the molecule rather than the carboxy terminus. Our present data suggest that the carboxy terminus of the amelogenins is sufficiently externalized to be an antigenic domain. These data may be useful in subsequent structural analysis of amelogenin proteins and enhancing our understanding of their physicochemical participation in biomineralization.

Immunochemical and biochemical studies of human enamel proteins during neonatal development

The present communication provides descriptions of the developmental, biochemical, and immunological properties of the human enamel extracellular matrix proteins. We report the isolation and partial characterization of the major human enamel proteins, the production of polyclonal antibodies directed against the human enamelins, and a comparison between the immunogenicity of enamelins and amelogenins from human and mouse enamel extracellular matrices. Our results indicate that although enamelins and amelogenins share some epitopes, each one of these proteins appears to invoke a different degree of immunogenicity.

DNA sequence for cloned cDNA for murine amelogenin reveal the amino acid sequence for enamel-specific protein

Enamel is the unique and highly mineralized extracellular matrix that covers vertebrate teeth. Amelogenin proteins represent the predominate subfamily of gene products found in developing mammalian enamel, and are implicated in the regulation of the formation of the largest hydroxyapatite crystals in the vertebrate body. Previous attempts to isolate, purify and characterize amelogenins extracted from developing matrix have proven difficult. We now have determined the DNA sequence for a cDNA for the 26-kDa class of murine amelogenin and deduced its corresponding amino acid sequence. The murine amino acid sequence is homologous to bovine or porcine amelogenins extracted from developing enamel matrices. However, an additional 10-residues were found at the carboxy terminus of the murine amelogenin. This is the most complete sequence database for amelogenin peptides and the only DNA sequence for enamel specific genes.

De novo gene expression detected by amelogenin gene transcript analysis

Reciprocal epithelial-mesenchymal interactions are responsible for mouse molar tooth organogenesis. Only dental ectomesenchymal cells are capable of instructing adjacent epithelial cells to become determined to synthesize and secrete enamel-specific proteins termed the amelogenins. To identify when inner enamel epithelial cells first express enamel specific gene products, cytoplasmic RNA has been analyzed from developing teeth by hybridization to a cloned cDNA probe to one of the amelogenins. It is reported that the de novo expression of amelogenin-encoding RNA as well as immunoprecipitated amelogenin polypeptides are first detected at Theiler stage 27. These data indicate that ectomesenchymal-mediated induction of inner enamel organ epithelia results in both the nascent transcription of amelogenin RNA and subsequent translation of amelogenin polypeptides, which are first detected at birth.

Concepts of epithelial-mesenchymal interactions during development: tooth and lung organogenesis

One of the major problems in developmental biology concerns how differential gene activity is regionally controlled. One approach to this problem is the use of mesenchyme specification of epithelial-specific gene expression, such as, during tooth morphogenesis or lung morphogenesis. In the example of tooth morphogenesis, dental papilla ectomesenchyme induces de novo gene expression as assayed by detection of amelogenin transcripts, or immunodetection of amelogenin polypeptides within ameloblast cells. This process does not require serum supplementation or exogenous factors during epithelial-mesenchymal interactions in vitro. In contrast, lung morphogenesis requires hormones to mediate mesenchyme-derived influences upon type II epithelial cell differentiation and the production of pulmonary surfactant (eg, neutral and phospholipids, surfactant proteins). Glucocorticoids are required to stimulate the release of fetal pneumonocyte factor (FPF) from fibroblasts which, in turn, enhance the production of pulmonary surfactant. Thyroxin appears to regulate the relative responsiveness of progenitor type II cells to steroid-stimulated release of FPF. This review will highlight key concepts associated with these developing organ systems and emphasize the problem of regional controls which regulate epithelial cell-specific gene activity.

Construction and identification of mouse amelogenin cDNA clones

The determination of the biochemical phenotype of tooth epithelium requires specification by the dental mesenchyme. This is a general feature of epithelial-mesenchymal interaction in a number of different epidermal organ systems (e.g., salivary gland, mammary gland, feather, skin, and hair morphogenesis). To investigate these developmental processes, we have identified a cDNA clone representing the major group of gene products associated with enamel extracellular matrix formation. The mRNAs for mouse amelogenins, representing approximately equal to 90% of the total enamel proteins, have been isolated and partially characterized by specific immunoprecipitation. The poly(A)-containing RNAs were used for the synthesis and cloning of the mouse amelogenin cDNA. Recombinant plasmids containing amelogenin cDNA sequences were identified by differential hybridization, hybrid-selected translation, and blot hybridization analyses. A cloned sequence was used to identify the expression of amelogenins during tooth development. The mouse cDNA sequence hybridized to genomic mouse and human DNAs. This amelogenin cDNA probe now enables molecular investigations of a number of classical problems in developmental biology.

Bromodeoxyuridine-DNA interactions associated with arrest of rat odontogenesis in vitro

To better characterize the molecular mechanism responsible for the bromodeoxyuridine (BrdU)-mediated arrest of mammalian odontogenesis in vitro, the nature of nuclear DNA-analogue interactions was determined. Bioactive doses of the radiolabelled analogue were added to tissue culture medium of 16-day old embryonic rat incisor primordia. Control rudiments were similarly exposed to equimolar, radiolabelled thymidine. After 16-18 h, DNA was isolated and purified from the labelled organ cultures. Following sedimentation to equilibrium through neutral CsCl density gradients, [3H]-BrdU-labelled DNA revealed a buoyant density indicative of a 12-15 per cent level of substitution in place of thymidine. Furthermore, similar centrifugation of DNA through alkaline density gradients suggested that the substitution was localized predominantly within a single-strand. DNA-DNA reassociation kinetics subsequently revealed that disproportionately more radiolabelled BrdU was concentrated within repetitive DNA nucleotide sequences in contrast to the more random distribution of [3H]-thymidine moieties. Thus it is likely that BrdU exerts its inhibitory effects on odontogenic differentiation through a relatively small proportion of rat embryo nuclear DNA.