Overview: mechanisms of the regulation of hemoglobin synthesis at the cellular level.

The concept that has emerged from our experiments and those of others is that erythroid stem cells are committed to undergo a program of erythroid differentiation with respect to the ultimate hemoglobin phenotype of their progeny erythrocytes. A clear distinction can be drawn between the switch from Hb A (or Hb F) to Hb C in sheep and the switch from Hb F to adult hemoglobin in humans. The former appears to be regulated in a relatively late erythroid stem cell with characteristics of CFU-E. In contrast, the CFU-E found in adult sheep bone marrow from animals that lack the beta C gene appear to be preprogrammed to produce only adult hemoglobin. Fetal stem cells may be induced to synthesize Hb C within a time frame that is similar to that seen in cultures of adult bone marrow. Thus, a common mechanism modulating the potential for expression of this gene and commitment of erythroid stem cells with respect to Hb C production in progeny erythroblasts seems quite likely. Again fetal CFU-E and BFU-E in animals lacking the beta C gene appear to be, for the most part, committed toward producing erythroblasts making Hb F. Further analysis will be required to determine at exactly which stage of stem cell differentiation this programming occurs and also the factors that are important in modulating the potential for fetal and adult hemoglobin synthesis.

Identification of four extracellular-matrix enamel proteins during embryonic-rabbit tooth-organ development.

1. Investigations were designed to identify the proteins which characterize the ameloblast phenotype, and to determine to what extent these extracellular-matrix proteins were degraded as a function of enamel matrix mineralization and maturation. 2. The identification of enamel proteins was based on comparisons between the electrophoretic patterns of enamel-containing and non-enamel-containing matrix extracts isolated from specific regions within 26-day embryonic New Zealand White rabbit incisor and molar tooth organs. 3. Since enamel proteins become mineralized on secretion, matrix specimens were demineralized in cold 5% (w/v) trichloroacetic acid, extracted with buffered 6M-urea and reduced with mercaptoethanol, and then the solubilized proteins were fractionated by urea/polyacrylamide-gel electrophoresis. 4. Three enamel-specific electrophoretic components were identified in newly secreted enamel-matrix specimens and this number increased as a function of mineralization and maturation. 5. Antibodies were prepared against embryonic rabbit extracellular matrix containing enamel. Comparison between immunoelectrophoretic patterns demonstrated that two of the three enamel components were antigenic. 6. Polyacrylamide-gel electrophoresis in sodium dodecyl sulphate was used to identify four enamel proteins of mol.wts. (1) 65 000 (2) 58000 (3) 22 000 and (4) 20 000, localized within enamel matrix. Enamel proteins (1) and (3) were phosphorylated, whereas (2) and (4) did not contain detectable phosphate. Labelled proline, leucine, tryptophan and glucosamine were incorporated into each of the four enamel proteins extracted from tooth explants incubated in the presence of radioactive precursors for 6 h. Whereas four proteins were identified in newly secreted enamel matrix, the concentrations of high-molecular-weight proteins (1) and (2) were found to decrease and the number (greater than 10) and concentration of low-molecular-weight polypeptides increased as a function of advanced enamel-matrix mineralization and maturation.

Matrix vesicle heterogeneity: possible morphogenetic functions for matrix vesicles.

Extracellular membranous matrix vesicles were localized and described using electronmicroscopy during chondrogenesis, osteogenesis, and dentinogenesis. Evidence indicates that matrix vesicles in each of these specific tissue types function to concentrate and transport ions and enzymes which serve as nucleation sites for the mineralization of hydroxylapatite. We have examined different developmental stages of Meckel's cartilage, alveolar bone and epithelial-mesenchymal interactions associated with tooth formation in newborn mice. These ultrastructural studies indicate matrix vesicle heterogeneity. Whereas most matrix vesicles contain alkaline phosphatase activity during cartilage, bone and dentine mineralization, in earlier developmental stages matrix vesicles contain acid phosphatase activities and little, if any, alkaline phosphatase. Tissue type, specific developmental stage, and ultrastructural criteria indicate various "classes" of matrix vesicles. During epithelial-mesenchymal interactions in tooth development, mesenchymal cells (preodontoblasts) appear to be the source of matrix vesicles as indicated by the complementarity between H-2 histocompatibility alloantigen specificity on the cell surface and that of the matrix vesicle outer surface; matrix vesicles are limited by a trilaminar membrane derived from the mesenchymal cells. Some of the vesicles located adjacent to dividing inner enamel epithelial cells contain RNA's as determined by electron microscopic autoradiography in situ, as well as by direct biochemical assays. We postulate that matrix vesicles have many different and important biological functions, one of which may be to mediate developmental information from mesenchyme to epithelia during "instructive" stages of tooth development.