Conny Bessem

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.

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.

Human developing enamel proteins exhibit a sex-linked dimorphism.

SummaryThe amelogenin protein of developing dental enamel is generally accepted to mediate the regulation of the form and size of the hydroxyapatite crystallites during enamel biomineralization (1). A genetic disorder of enamel development (amelogenesis imperfecta) has been linked to theamelogenin geneAMEL (2–3), and loci regulating enamel thickness and tooth size have been mapped to the human sex chromosomes (4). In the human genome there are twoAMEL loci with one copy of the gene on each of the sex chromosomes (AMELX andAMELY), whereas in the mouse only anAMELX locus is present (5). It is presently unknown if humanAMELY is transcriptionally active. These observations prompted us to examine specimens of human developing enamel for sexual dimorphism at the protein level. We report here, for the first time, a diagnosis of differences in human enamel proteins which permits the distinction of specimens according to the sex of the individual.

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.

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., Meckels 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.

Total poly(A+)-messenger RNA from bovine lens cofractionates with sucrose purified fiber cell plasma membrane

Poly(A+)-messenger RNA was isolated from bovine lens as well as poly(A+)-mRNA from crude and sucrose-purified plasma membrane. Bovine lens MP26 antisera was also propagated in rabbits, from which anti-MP26 IgG was partially purified and used to assay for the specific synthesis of MP26 during in vitro translation of the isolated poly(A+)-mRNAs. We found that membrane-associated poly(A+)-mRNA supported the synthesis of proteins which were identical to those translated from total lens fiber cell poly(A+)-mRNA. These proteins included MP26, as assayed by immunoprecipitation of [35S]-labeled MP26.

Epidermal growth factor regulates gene expression of both epithelial and mesenchymal cells in mouse molar tooth organs in culture

Epidermal growth factor and cis-hydroxyproline specifically inhibited synthesis of type 1 collagen, a major gene product of the differentiated dental mesenchymal cells (odontoblasts). In tandem, synthesis of enamel proteins, specific gene products of differentiated dental epithelial cells (ameloblasts), was also inhibited. Under these culture conditions, total protein synthesis in tooth organs was not inhibited but rather increased. Inhibition curves of the gene products specific for epithelial and mesenchymal phenotypes were quite similar, indicating coordinate and intimately associated regulation of gene expression under conditions that perturb cytodifferentiation.

Analysis of Embryonic Cartilage and Bone Induction in a Defined Culture System

The primary means by which vertebrate mineralized tissues become determined during development is by interaction between different regions of the embryo, a process known as embryonic induction. Numerous examples of embryonic induction were intensively studied problems in developmental biology during the first 70 years of the 20th century (see reviews by Spemann, 1938, Grobstein, 1967; Hall, 1988). Progress in the last few years has in part been the result of applications of recombinant DNA technology to classical questions in the field of embryonic induction (e.g. see recent reviews by Gurdon, 1987; 1988; Edelman, 1988). The key issues appear to be when, where and which sequence of regulatory factor expression activate signal transduction processes resulting in the allocation, determination and differentiation of specific phenotypes. There are probably multiple signals and multiple receptors required for inductive processes.