Characterization of the upstream mouse Cbfa1/Runx2 promoter.

Cbfa1 (or Runx2/AML-3/PEPB2alpha) is a transcriptional activator of osteoblastic differentiation. To investigate the regulation of Cbfa1 expression, we isolated and characterized a portion of the 5'-flanking region of the Cbfa1 gene containing its "bone-related" or P1 promoter and exon 1. We identified additional coding sequence in exon 1 and splice donor sites that potentially give rise to a novel Cbfa1 isoform containing an 18 amino acid insert. In addition, primer extension mapping identified in the Cbfa1 promoter a minor mRNA start site located approximately 0.8 kb 5' upstream of the ATG encoding the MASN/p57 isoform and approximately 0.4 kb upstream of the previously reported start site. A luciferase reporter construct containing 1.4 kb of the mouse Cbfa1 promoter was analyzed in Ros 17/2.8 and MC3T3-E1 osteoblast cell lines that express high levels of Cbfa1 transcripts. The activity of this construct was also examined in non-osteoblastic Cos-7 and NIH3T3 cells that do not express Cbfa1 and mesenchymal-derived cell lines, including CH3T101/2, C2C12, and L929 cells, that express low levels of mature Cbfa1 transcripts. The 1.4 kb 5' flanking sequence of the Cbfa1 gene directed high levels of transcriptional activity in Ros 17/2.8 and MC3T3-E1 osteoblasts compared to non-osteoblasts Cos-7 cells, but this construct also exhibited high levels of expression in C310T1/2, L929, and C2C12 cells as well as NIH3T3 cells. In addition, Cbfa1 mRNA expression, but not the activity of the Cbfa1 promoter, was upregulated in a dose-dependent manner in pluripotent mesenchymal C2C12 by bone morphogenetic protein-2 (BMP-2). These data indicate that Cbfa1 is expressed in osteogenic as well as non-osteogenic cells and that the regulation of Cbfa1 expression is complex, possibly involving both transcriptional and post-transcriptional mechanisms. Additional studies are needed to further characterize important regulatory elements and to identify additional regions of the promoter and/or post-transcriptional events responsible for the cell-type restricted regulation of Cbfa1 expression.

Cbfa1 isoform overexpression upregulates osteocalcin gene expression in non-osteoblastic and pre-osteoblastic cells.

The mouse Cbfa1 gene potentially encodes several proteins that differ in their N-terminal sequences, including an osteoblast-specific transcription factor, Cbfa1/Osf2, a Cbfa1 isoform (Cbfa1/iso), and the originally described Cbfa1 gene product (Cbfa1/org). Uncertainty exists about the function of these potential isoforms of the Cbfa1 gene. To examine the transactivation potential of different Cbfa1 gene products, we compared the ability of Cbfa1/Osf2, Cbfa1/iso, and Cbfa1/org overexpression to activate an osteocalcin promoter/reporter construct in NIH3T3 fibroblasts, C3H10T1/2 pluripotent cells and MC3T3-E1 pre-osteoblasts. These three cell lines were transiently cotransfected with a 1.3-kb mouse osteocalcin promoter luciferase-fusion construct (p1.3OC-luc) and different amounts of expression vectors containing the respective full-length Cbfa1 isoform cDNAs. Using transfection protocols with lower amounts of expression plasmid DNAs, we found that all three Cbfa1 isoforms stimulated osteocalcin promoter activity in each of the cell types, consistent with the their ability to induce expression of an osteoblast-specific gene both in non-osteoblast cells and in osteoblast cell lines. However, using transfection protocols with higher amounts of expression plasmids containing Cbfa1 cDNAs, we found that the Cbfa1/Osf2 and Cbfa1/org had less transactivating potential compared with Cbfa1/iso. Our studies suggest that the 87-amino acid N-terminus of Cbfa1/Osf2 is not crucial for optimal transactivation, whereas the 19-amino acid N-terminal sequence of Cbfa1/iso augments transcriptional activation only at high doses of the expression plasmid. The physiological significance of these in vitro findings remain to be determined.

Failure to detect the extracellular calcium-sensing receptor (CasR) in human osteoblast cell lines.

Whether the known calcium-sensing receptor (CasR) is present in osteoblasts is a source of considerable controversy. Prior studies failed to detect CasR in osteoblasts, but more recent investigations purport the detection of CasR in several osteoblast cell lines by immunoblot analysis with polyclonal anti-CasR antisera (4637) and low stringency reverse transcriptase-polymerase chain reaction (RT-PCR). To explain these disparate findings, we performed immunoblot analysis with the 4637 anti-CasR antisera and a highly specific monoclonal antibody to CasR (ADD), and we compared the ability of low and high stringency RT-PCR to amplify CasR transcripts. We found that the ADD antibody detected the anticipated CasR immunoreactive bands, including a approximately 165 kDa and approximately 140 kDa glycosylated doublet and a >250 kDa dimerized receptor, in positive control mouse kidney, human parathyroid, and human embryonic kidney (HEK) 293 cells transfected with rat CasR, but we did not detect these bands in either wild-type HEK 293 cells or Saos2, MG-63, or U-2 OS osteoblast-like cell lines. Standard two-step RT-PCR using CasR-specific primers confirmed these results by detecting CasR transcripts in positive controls but not in negative control HEK 293 cells or osteoblast cell lines. In contrast, the 4637 antisera did not recognize CasR by immunoblot analysis under the conditions studied and our low stringency RT-PCR procedure amplified nonspecific products in wild-type HEK 293 cells and osteoblasts. Since we failed to detect CasR in human osteoblast cell lines using either the highly specific ADD antibody or RT-PCR under standard conditions, it is possible that the cation response in osteoblasts is mediated by a functionally similar but molecularly distinct calcium sensing receptor.

Genomic structure and isoform expression of the mouse, rat and human Cbfa1/Osf2 transcription factor.

Although the CBFA1 gene encodes an osteoblast-specific transcription factor that regulates osteoblast differentiation, uncertainty exists about the organization of its 5' end and the relevance of a novel N-terminal sequence identified in the mouse Cbfa1/Osf2 isoform. We found the novel 5' Cbfa1/Osf2 sequence is encoded by a previously unrecognized upstream exon, designated exon -1, which is highly conserved in mouse, rat and human. In addition, two splice donor sites may be utilized to generate Cbfa1/Osf2 cDNAs containing different N-terminal sequences. The first ATG and splice donor site in exon -1 is predicted to transcribe a cDNA containing the unique Osf2 5' sequence, whereas a second donor splice site gives rise to cDNAs that contain sequences encoding an 11 amino acid insert. In the human CBFA1 gene, an additional 2-bp nucleotide insert shifts the reading frame and results in stop codons in the cDNA sequence derived from exon -1. The 5'-most exon of the human CBFA1 gene, therefore, contains the 5' non-coding region rather than a human OSF2 homolog. The absence of a homologous OSF2 coding sequence in the human CBFA1 cDNA suggests that the novel mouse N-terminal Osf2 sequence is not essential for functioning of the CBFA1 gene product. In addition, multiple transcripts derived from a single CBFA1/Cbfa1 gene were detected in osteoblasts by Northern analysis and RT-PCR, including additional Cbfa1/Osf2 isoforms containing deletions of exons 1 and 4. Thus, the alternative use of transcription start sites and splicing leads to the genesis of CBFA1/Cbfa1 isoforms with possible differences in transactivation potentials.

Identification of putative transmembrane receptor sequences homologous to the calcium-sensing G-protein-coupled receptor.

The sensing of extracellular calcium is a general paradigm for regulating diverse cellular functions in many tissues. A calcium-sensing receptor (Casr) belonging to the metabotropic glutamate family of G-protein-coupled receptors (GPCR) that transduces the effects of extracellular calcium in the parathyroid gland as well as other tissues has been identified. The diversity of GPCR families and the recent finding of calcium sensing in cells lacking the known Casr suggest the existence of additional receptors related to Casr. By polymerase chain reaction (PCR) amplification and screening of genomic libraries, we have identified multiple Casr-related sequences (Casr-rs) in the mouse. Using primers designed to regions of the first and third intracellular loops of Casr, we initially PCR amplified a 497-bp Casr-related sequence (Casr-rs1) with high homology to Casr. The deduced protein sequence of Casr-rs1 is 63% similar and 40% identical to Casr over the available transmembrane region. We screened a mouse genomic library with a Casr-rs1 probe and identified two additional Casr-related sequences (Casr-rs2 and Casr-rs3). In the predicted transmembrane domain, Casr-rs2 and Casr-rs3 are 95% identical to Casr-rs1. We mapped Casr-rs1 to mouse Chromosome (Chr) 7 by interspecific backcross analysis, whereas the known Casr localizes to mouse Chr 16. By fluorescence in situ hybridization, Casr-rs2 also localized to mouse Chr 7 and Casr-rs3 mapped to mouse Chr 4. We were able to distinquish Casr-rs1 from Casr-rs2 by PCR using specific primers, suggesting that they are distinct genes clustered on Chr 7. By RT-PCR, we identified additional Casr-rs transcripts in mouse kidney, brain, testis, embryo, and MC3T3-E1 osteoblasts, but not in lung or liver. The homologous sequence in mouse kidney, embryo, and MC3T3-E1 osteoblasts, designated Casr-rs4, has a deduced amino acid sequence that is 100% similar and 97% identical to that of Casr-rs1. The sequence amplified from mouse brain, Casr-rs5, has a deduced protein sequence that is 96% similar and 92% identical to that of Casr-rs1. Our findings establish the existence of a novel multimembered family of Casr-related sequences in the mouse which may encode receptors that transduce responses to diverse extracellular cations.

A distinct cation-sensing mechanism in MC3T3-E1 osteoblasts functionally related to the calcium receptor.

The presence of a cation-sensing mechanism in osteoblasts is suggested by the ability of specific cations to stimulate osteoblastic proliferation in culture and to induce de novo bone formation in some experimental models. Our study examines whether extracellular cations stimulate osteoblasts through the recently identified G protein-coupled calcium receptor (CaR). We found that CaR agonists, calcium (Ca2+), gadolinium (Gd3+), aluminum (Al3+), and neomycin, stimulated DNA synthesis in murine-derived MC3T3-E1 preosteoblasts, whereas magnesium (Mg2+), nickel (Ni2+), cadmium (Cd2+), and zinc (Zn2+) had no effect. With the exception of Mg2+, the cation specificities and apparent affinities were similar to that reported for CaR. CaR agonists also stimulated DNA synthesis in C3HT10(1/2) fibroblasts, but not in mesangial PVG, CHO, hepatic HTC, COS-7 cells, or malignant transformed ROS17/2.8 and UMR-106 osteoblasts. In addition, similar to other growth factors, CaR agonists activated transcription of a serum response element luciferase reporter construct (SRE-Luc) stably transfected into MC3T3-E1 osteoblasts, but had no effect on SRE-Luc transfected into CHO and COS-7 cells. We were unable to detect CaR expression by Northern analysis using a mouse CaR-specific probe or to amplify CaR mRNA by reverse transcribed polymerase chain reaction in MC3T3-E1 osteoblasts. These findings suggest that an extra-cellular cation-sensing mechanism is present in murine-derived osteoblasts that is functionally similar to but molecularly distinct from CaR.

Quantitative analysis of the calcium-sensing receptor messenger RNA in parathyroid adenomas.

BACKGROUND: In primary hyperparathyroidism, hypercalcemia fails to suppress adequately secretion of parathyroid hormone by the parathyroid gland, which may result from failure of the cell-surface calcium receptor (CaR) to sense calcium correctly. Quantification of mRNA concentrations should provide important information on the role of expression of Call in primary hyperparathyroidism. METHODS: We have developed a quantitative reverse transcriptase-polymerase chain reaction assay with a competitive template (CaR-M). Amplified cDNAs for CaR and CaR-M are quantified, and the concentration of CaR mRNA is determined from the ratio of CaR-M/CaR versus known CaR-M concentrations. RESULTS: In parathyroid adenomas (n = 12) the CaR mRNA was 19.2 +/- 2.4 (mean +/- SE) fg/ng total RNA (range, 7.4 to 32.8 fg/ng). Extracellular ionized calcium levels ranged from 1.38 to 1.74 mmol/L (normal 1.19 to 1.31 mmol/L) and parathyroid hormone from 69 to 345 pg/ml (normal, 14 to 65 pg/ml). In spite of the wide variability in CaR expression in the various adenomas, there was no correlation between mRNA and either extracellular ionized calcium (r2 = 0.013) parathyroid hormone levels (r2 = 0.001). Normal human parathyroid glands gave values of 8.0 and 16.6 fg/ng, whereas normal bovine parathyroid glands had a mean of 20 +/- 0.6 fg/ng (n = 4). CONCLUSIONS: There is no apparent relationship between CaR mRNA levels in adenomas and preoperative Ca and PTH levels. Our findings suggest that defective Ca sensing in adenomas may involve post-translational modification or signal transduction distal to the receptor. Our highly sensitive assay for CaR mRNA should prove useful in examining further the role of CaR in Ca sensing in parathyroid tissue.