Endochondral bone formation requires the action of cells of the chondrocytic and osteoblastic lineage, which undergo continuous differentiation during this process. To identify subpopulations of resting, proliferating, and hypertrophic chondrocytes and osteoblasts involved in bone formation, we have identified here two novel marker genes present in endochondral and intramembranous ossification. Using Northern blot analysis and in situ hybridization on parallel sections of murine embryos and bones of newborn mice we compared the expression pattern of the recently cloned Itm2a and MMP-13 (collagenase-3) genes with that of established marker genes for bone formation, such as alkaline phosphatase (ALP), osteocalcin (OC), and collagen type X, during endochondral and intramembranous ossification. During embryonic development expression of Itm2a and ALP was detectable at midgestation (11.5 days postcoitum [dpc]) and increased up to 16.5 dpc. MMP-13 and OC expression started at 14.5 dpc and 16.5 dpc, respectively. This temporal expression was reflected in the spatial distribution of these markers in the growth plate of long bones. In areas undergoing endochondral ossification Itm2a expression was found in chondrocytes of the resting and the proliferating zones. Expression of ALP and MMP-13 are mutually exclusive: ALP transcripts were found only in collagen type X positive hypertrophic chondrocytes of the upper zone. MMP-13 expression was restricted to chondrocytes of the lower zone of hypertrophic cartilage also expressing collagen type X. In osteoblasts involved in endochondral and intramembranous ossification Itm2a was not present. ALP, MMP-13, and OC were mutually exclusively expressed in these cells suggesting a differentiation-dependent sequential expression of ALP, MMP-13, and OC. The identification of the continuum of sequential expression of Itm2a, ALP, MMP-13, and OC will now allow us to establish a series of marker genes that are highly suitable to characterize bone cells during chondrocytic and osteoblastic differentiation in vivo. (J Bone Miner Res 2000;15:1257-1265)
With the publication of the sequence of the human genome, we are challenged to identify the functions of an estimated 70,000 human genes and the much larger number of proteins encoded by these genes. Of particular interest is the identification of gene products that play a role in human disease pathways, as these proteins include potential new targets that may lead to improved therapeutic strategies. This requires the direct measurement of gene function on a genomic scale in cell-based, functional assays. We have constructed and validated an individually arrayed, replication-defective adenoviral library harboring human cDNAs, termed PhenoSelect library. The adenoviral vector guarantees efficient transduction of diverse cell types, including primary cells. The arrayed format allows screening of this library in a variety of cellular assays in search for gene(s) that, by overexpression, induce a particular disease-related phenotype. The great majority of phenotypic assays, including morphological assays, can be screened with arrayed libraries. In contrast, pooled-library approaches often rely on phenotype-based isolation or selection of single cells by employing a flow cytometer or screening for cell survival. An arrayed placental PhenoSelect library was screened in cellular assays aimed at identifying regulators of osteogenesis, metastasis, and angiogenesis. This resulted in the identification of known regulators, as well as novel sequences that encode proteins hitherto not known to play a role in these pathways. These results establish the value of the PhenoSelect platform, in combination with cellular screens, for gene function discovery.
To identify novel marker molecules associated with chondro-osteogenic differentiation, we have set up a differential screening system based on a cDNA library subtraction in organ cultures of prenatal mouse mandibular condyles. Differential screening of a cDNA library constructed from in vitro cultured condyles allowed the isolation of a novel gene, named E25. Full-length E25 cDNA is predicted to encode a type II integral membrane protein of 263 amino acid residues. In situ hybridization experiments show that E25 is expressed in the outer perichondrial rim of the postnatal mandibular condyle, which contains the proliferating progenitor cells, but not in the deeper layers of the condyle containing the more differentiated chondroblasts and chondrocytes. Other cartilagenous tissues and their perichondrium were negative. Strong in situ hybridization signals were also detected on bone trabeculae of mature bone in tooth germs and in hair follicles. Northern blot analysis showed strong expression in osteogenic tissues, such as neonatal mouse calvaria, paws, tail, and in skin. This expression profile suggests that E25 could be a useful marker for chondro-osteogenic differentiation. Homology searches of DNA databanks showed that E25 belongs to a novel multigene family, containing three members both in man and mouse. The mouse E25 gene locus (Itm2) was mapped to the X chromosome.
Itm2A is a novel type II integral membrane protein that is involved in osteo- and chondrogenic differentiation. Itm2a cDNA was originally isolated from a cDNA library of organ cultures from prenatal mouse mandibular condyles, by subtractive hybridization and differential screening. The Itm2a gene was isolated from a BALB/c liver genomic library. In total, 9.4 kb of the gene were sequenced, of which 2649 bp are 5' flanking sequences. The Itm2a gene contains six exons and five introns. The splice sites conform to the GT/AG rule. The 5' flanking region, which contains the presumed promoter sequence, lacks the common TATAA and CCAAT sequences, but contains consensus binding sites for various transcription factors. Several of these transcription factors are known to play a role in transcriptional regulation of cartilage- or bone-specific genes (e.g. Cbfa1, Cart-1, MHox, HES-1, and CIIS1). Itm2a was mapped to mouse chromosome position XA2-XA3 by fluorescent in situ hybridization (FISH) analysis. The human homolog, ITM2A, was mapped to chromosome position Xq13.3-Xq21.2.
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