Calcitonin Receptor mRNA Research Articles

Effects of continuous calcitonin treatment on osteoclast-like cell development and calcitonin receptor expression in mouse bone marrow cultures.

Continuous treatment with calcitonin (CT) to inhibit osteoclastic bone resorption results in acquired resistance. The mechanisms of this "escape" phenomenon are not yet established. The aim of this study was to examine the effects of continuous treatment with CT on the generation of osteoclasts and calcitonin receptor (CTR) expression in mouse bone marrow cultures. This was done by daily CT treatment of mouse bone marrow cultures from day 0, when only undifferentiated mononuclear precursors of osteoclast-like cells were present, or commencing from day 6, when differentiated osteoclast-like cells were abundant. The response to CT treatment was determined by quantitation of cells positive for tartrate-resistant acid phosphatase (TRAP) and binding of 125I-salmon CT. Calcitonin receptor and TRAP mRNA levels were determined using semi-quantitative reverse transcription/polymerase chain reaction. When cultures were treated with CT from day 0, TRAP-positive multinucleated cells appeared. These cells expressed only very low levels of CTR or CTR mRNA and were morphologically indistinguishable from osteoclast-like cells formed in control cultures. They also displayed the ability to resorb bone. Continuous CT treatment of cultures from day 6 rapidly reduced the CTR mRNA levels, with a t1/2 of 6 to 12 h, and these levels remained low thereafter. 125I-salmon CT binding capacity, as determined by autoradiography, was lost in parallel. These effects were specific for the CTR since there was no consistent effect on TRAP mRNA levels. Based on these data, we suggest that the "escape" phenomenon may result from a prolonged CT-induced loss of CT responsiveness due, at least in part, both to reduced synthesis of CTR, and to the appearance in bone of CTR-deficient osteoclasts.

Calcitonin receptor mrna expression in the human prostate

Objectives A subpopulation of prostate neuroendocrine (NE) cells contain calcitonin (CT). It has been postulated that CT-producing cells in the prostate account for the high CT level in the semen, and may be involved in the regulation of other epithelial cells via a paracrine mechanism. The presence of CT binding sites in the plasma membrane fraction of prostate tissue has been demonstrated by radioligand binding assay. In the present study, we investigated the CT receptor gene expression in the human prostate, a key component of the autocrine/paracrine loop in the CT functional pathway. Methods Reverse transcription polymerase chain reaction (RT-PCR) was carried out to evaluate the CT receptor mRNA expression in normal prostate tissue. Subsequent DNA sequencing was used to verify RT-PCR amplified products and to determine the isoform of the receptor. To define the location of the CT receptor expression, nonradioactive in situ hybridization was performed with a digoxigenin-labeled probe complementary to the coding region of the CT receptor mRNA. A polyclonal antibody against CT was used to reveal the CT-secreting cells in the prostate. Results CT receptor mRNA expression was detected in the prostate tissue. Further analysis of the DNA sequence showed that CT receptor expressed in the prostate was the isoform without a 16-amino acid insert in the first intracellular domain. In situ hybridization revealed that CT receptor was present in the prostate NE cells. Immunocytochemical staining of mirror image sections showed that some CT-secreting cells also expressed CT receptor. Conclusions CT receptor expression in the prostate, a key component in the CT functional pathway, is located in subsets of dispersed NE cells (CT secreting and CT nonsecreting), which indicates that prostate CT may play an important role in the autocrine/paracrine regulation of the prostate NE system.

Short treatment of osteoclasts in bone marrow culture with calcitonin causes prolonged suppression of calcitonin receptor mRNA

Cells exhibiting osteoclast characteristics of calcitonin receptors (CTRs) and tartrate-resistant acid phosphatase (TRAP) histochemistry are formed in murine bone marrow cultures treated with 1 alpha,25-dihydroxyvitamin D3 [1,25-(OH)2D3]. We have previously demonstrated that CTR mRNA is highly expressed in these cultures. The aim of this study was to investigate homologous regulation of the CTR, and regulation of TRAP expression in osteoclast-like cells after brief treatment with salmon CT (sCT). Murine bone marrow cells were cultured in 9 cm dishes in the presence of 10 nmol/L 1,25-(OH)2D3. On day 6 of culture, when multinucleated cells were abundant, the cells were treated with 1 nmol/L sCT for 1 h. Both control and treated cells were then harvested at intervals up to 72 h posttreatment, and both CTR and TRAP mRNA levels assessed by reverse-transcription PCR (RT-PCR). In parallel cultures, cells with CTR expression detectable by autoradiography, and TRAP positivity by histochemistry, were counted. The effects of brief sCT treatment could be seen 6 h after treatment when the CTR RT-PCR product was markedly reduced. Total recovery of CTR mRNA levels had not occurred even after 72 h. Calcitonin treatment had little effect on TRAP mRNA levels. There was no difference in the numbers of multinucleated TRAP(+) osteoclast-like cells between treated and control cells. These results indicate that brief sCT treatment, while not influencing multinucleated osteoclast-like cell number, causes specific, acute reduction of CTR mRNA in bone marrow culture-derived osteoclasts. The prolonged decrease in CTR mRNA levels suggests that recovery may require new osteoclast formation, and indicates that regulation of the CTR in cells of the osteoclast lineage is different from that in nonosteoclastic cells and tissues.

Expression of the calcitonin receptor in bone marrow cell cultures and in bone: a specific marker of the differentiated osteoclast that is regulated by calcitonin.

We studied the temporal sequence of osteoclast (OC) differentiation from precursor cells in murine marrow cultures. Two markers of the OC phenotype, calcitonin (CT) receptor (CTR) and tartrate resistant acid phosphatase (TRAP), were assessed. Marrow cells from C57BL/6 mice were cultured for 3, 5, 7, and 9 days with or without 1,25-(OH)2vitamin D3 (10(-8) M). In controls only small numbers of osteoclastic multinucleated cells 9MNCs) formed per well (< 15 per well). In contrast, 1,25-(OH)2D3 strongly stimulated MNC formation (> 80 per well on day 7). Messenger RNA (mRNA) for TRAP was detectable by reverse transcription-polymerase chain reaction amplification in both control and 1,25-(OH)2D3 treated groups at all times. However, TRAP mRNA was detectable in MNCs by the less sensitive in situ hybridization only on days 5, 7, and 9 and only in 1,25-(OH)2D3 treated cells. In control cultures, CTR mRNA was present on day 3 only in nonadherent cells and was not present in adherent cells (where MNCs formed) at any time point. In 1,25-(OH)2D3 treated cultures CTR mRNA was detectable in nonadherent cells on day 3 and in adherent cells on day 5 and thereafter. Peak levels of CTR mRNA were seen in adherent cells on day 7 (15-fold more than day 5 and 4-fold more than day 9). CT (10(-7) M) treatment of 7 day cultures, which had been stimulated to express the osteoclastic phenotype, caused a marked decrease in CTR mRNA expression at 24 h. There was no effect of CT treatment on CTR mRNA expression at 3 h or on TRAP mRNA expression at 3 or 24 h. In neonatal mouse calvaria cultures, CTR mRNA expression was constitutively present and was markedly decreased by 48 h of CT treatment. Similarly, bone resorption in these cultures was inhibited at 24 h by CT treatment, but at 48 and 72 h there was escape from the inhibitory effects of CT on resorption. In the marrow cultures, MNCs were greater than 98% positive for [125I]-salmon calcitonin (sCT) binding and this binding was completely competed away by excess cold sCT (10(-7) M). All primary isolated osteoclasts from 1- to 3-day-old mouse long bones exhibited [125I]-sCT binding and TRAP activity and were strongly positive for CTR and TRAP mRNA by in situ hybridization. Both MNCs that formed in bone marrow cultures and isolated primary osteoclasts formed resorption pits on bone slices.(ABSTRACT TRUNCATED AT 400 WORDS)

Neuroendocrine peptides stimulate adenyl cyclase in normal and malignant prostate cells

Elevations of intracellular cAMP in human prostate cancer cells have been shown to increase invasiveness and to promote neuronal differentiation. since neuroendocrine peptides capable of activating adenyl cyclase are present in prostatic nerves and epithelial neuroendocrine cells, we investigated normal and malignant human prostate cells for changes in intracellular cAMP in response to the prostatic peptides vasoactive intestinal peptide (VIP), calcitonin (CT), and calcitonin gene-related peptide (CGRP). Normal prostate epithelial cells and LNCaP prostate cancer cells exhibited, respectively, 6-and 30-fold increases in intracellular cAMP in response to VIP. ALVA-31 and PPC-1 prostate cancer cells demonstrated 20- to 200-fold increases in cAMP in response to CGRP, while normal epithelial cells and LNCaP cells exhibited smaller (2- to 6-fold) responses. Only DU-145 cells increased cAMP substantially in response to CT. VIP receptor mRNA was identified by Northern blot analysis only in those cells that responded to VIP. CT receptor mRNA was identified only in DU-145 cells by polymerase chain reaction and Southern blot analysis. These results suggest that VIP and possibly CGRP receptors are likely to be present in both normal and malignant prostate cells. VIP or CGRP may regulate secretion of proteases by normal or prostate cancer cells and may influence epithelial cell differentiation.

Expression of two human skeletal calcitonin receptor isoforms cloned from a giant cell tumor of bone. The first intracellular domain modulates ligand binding and signal transduction.

Two distinct calcitonin (CT) receptor (CTR)-encoding cDNAs (designated GC-2 and GC-10) were cloned and characterized from giant cell tumor of bone (GCT). Both GC-2 and GC-10 differ structurally from the human ovarian cell CTR (o-hCTR) that we cloned previously, but differ from each other only by the presence (GC-10) or absence (GC-2) of a predicted 16-amino acid insert in the putative first intracellular domain. Expression of all three CTR isoforms in COS cells demonstrated that GC-2 has a lower binding affinity for salmon (s) CT (Kd approximately 15 nM) than GC-10 or o-hCTR (Kd approximately 1.5 nM). Maximal stimulatory concentrations of CT resulted in a mean accumulation of cAMP in GC-2 transfected cells that was greater than eight times higher than in cells transfected with GC-10 after normalizing for the number of receptor-expressing cells. The marked difference in maximal cAMP response was also apparent after normalizing for receptor number. GC-2 also demonstrated a more potent ligand-mediated cAMP response compared with GC-10 for both human (h) and sCT (the EC50 values for GC-2 were approximately 0.2 nM for sCT and approximately 2 nM for hCT; EC50 values for GC-10 were approximately 6 nM for sCT and approximately 25 nM for hCT). Reverse transcriptase PCR of GCT RNA indicated that GC-2 transcripts are more abundant than those encoding for GC-10. In situ hybridization on GCT tissue sections demonstrated CTR mRNA expression in osteoclast-like cells. We localized the human CTR gene to chromosome 7 in band q22. The distinct functional characteristics of GC-2 and GC-10, which differ in structure only in the first intracellular domain, indicate that the first intracellular domain of the CTR plays a previously unidentified role in modulating ligand binding and signal transduction via the G protein/adenylate cyclase system.

Downregulation of calcitonin receptor mRNA expression by calcitonin during human osteoclast-like cell differentiation.

Calcitonin inhibits both osteoclast formation and bone resorption, and is a primary treatment for patients with hypercalcemia and increased bone turnover. However, the clinical utility of calcitonin is limited because patients become refractory to calcitonin after several days (the calcitonin "escape phenomenon"). The molecular basis for calcitonin "escape" is unclear. To determine the regulatory mechanisms controlling calcitonin receptor (CTR) expression in osteoclasts and their precursors, we treated immature mononuclear precursors for human osteoclast-like multinucleated cells (MNC) formed in vitro with 1,25-(OH)2D3, to induce their differentiation to committed mononuclear precursors, and mature multinucleated osteoclasts, and used reverse transcriptase (RT)-PCR to assess expression of CTR mRNA in both committed mononuclear precursors and MNC. The PCR fragment produced was cloned and sequenced to confirm that it was derived from CTR mRNA. CTR mRNA expression was detected in mononuclear MNC precursors after 7 d of 1,25-(OH)2D3 treatment. It was also present in osteoclast-like MNC and highly purified giant cells from osteoclastomas, but not in monocytes or macrophage polykaryons formed in vitro. Calcitonin markedly decreased CTR but not actin mRNA expression in giant cells and MNC after 12 h, and removal of calcitonin restored CTR mRNA expression. Similarly, calcitonin decreased calcitonin-induced adenylate cyclase activity. These data suggest: (a) downregulation of CTR gene expression by calcitonin may in part explain the calcitonin "escape phenomenon"; and (b) expression of CTR mRNA occurs in mononuclear osteoclast precursors within 7 d after exposure to 1,25-(OH)2D3.

The expression of the calcitonin receptor gene in the brain and pituitary gland of the rat

The distribution of rat calcitonin receptor mRNA in the brain and pituitary gland were examined by in situ hybridization. Labelled cells were found in the nucleus accumbens, the preoptic and medial preoptic areas, the paraventricular nucleus of the hypothalamus, and the arcuate nucleus; a smaller number of cells were found in the brainstem and olfactory bulb. No strongly labelled cells were found in the pituitary gland.

Isolation, characterization, and chromosomal localization of the porcine calcitonin receptor gene. Identification of two variants of the receptor generated by alternative splicing.

The gene encoding the calcitonin receptor (CTR) was isolated from a porcine kidney epithelial cell line (LLC-PK1) genomic library and found to span approximately 70 kilobases. Analysis of the gene sequence revealed that the CTR mRNA encompasses 14 exons with 12 exons encoding the protein. Two splicing acceptor sites separated by 48 nucleotides were found in intron 7. The expression of two mRNA species in LLC-PK1 cells was subsequently confirmed by reverse transcription-polymerase chain reaction (RT-PCR) and DNA sequencing. In LLC-PK1 cells the mRNA encoding the shorter CTR (CTR-1a) is approximately 1,000 times more abundant than the longer variant (CTR-1b), as estimated by the competitive RT-PCR. The transcription initiation site of the CTR gene was mapped by primer extension, S1 nuclease, and RT-PCR analysis. The proximal promoter region of 500 base pair is GC-rich (66%) and CpG-rich (CpG/GpC ratio 0.71). Transient transfection of CTR gene promoter-luciferase chimeras in LLC-PK1 cells led to the expression of luciferase activity. The CTR gene was mapped to chromosome band 9q11-q12.

Murine osteoclasts and spleen cell polykaryons are distinguished by mRNA phenotyping

To probe osteoclast gene expression, we combined the techniques of cell microisolation and RT-PCR to develop a novel and sensitive method for the isolation and mRNA phenotyping of small numbers of authentic osteoclasts and spleen cell polykaryons. Using this method we report (1) direct evidence for the presence of calcitonin receptor mRNA in osteoclasts, (2) confirmation of the recent finding of osteopontin mRNA in osteoclasts, and (3) demonstration that the specific expression of mRNA for tartrate-resistant acid phosphatase, carbonic anhydrase II, calcitonin receptor, and osteopontin enable one to distinguish the osteoclast from the morphologically similar and developmentally related spleen cell polykaryon. We also show that mRNA associated with the osteoblast phenotype, such as alkaline phosphatase, osteocalcin, and type I collagen, are absent in osteoclasts. This is the first report in which such an approach has been used successfully to distinguish the mRNA expression pattern of an authentic osteoclast from a macrophage polykaryon, and as such it should provide an important new tool for evaluating the results of various cell culture model systems designed to examine the origin and ontogeny of osteoclasts. Our results also indicate that these procedures can be used as an alternative to in situ hybridization methods for the cell-specific localization of specific mRNA in a mixed cell preparation and for colocalization of multiple mRNA species to a single cell type.