Expression of bone matrix protein messenger ribonucleic acids in human breast cancers. Possible involvement of osteopontin in development of calcifying foci.

BACKGROUND: Development of calcifying foci is a fairly common finding in human breast cancers, and the deposition of calcium phosphate is observed in such foci. The calcium phosphate is a physiologic component of bones and teeth. Since the expression of messenger (m) RNAs of osteopontin (OPN), osteocalcin (OC), osteonectin (ON), and matrix gla protein (MGP) has been described in bones and teeth, we examined the mRNA expression of OPN, OC, ON, or MGP in the calcifying foci that were observed in human breast cancers. EXPERIMENTAL DESIGN: Cell types expressing mRNAs of OPN, ON or MGP were identified with combination of in situ hybridization and immunohistochemistry. RESULTS: The OPN mRNA-expressing cells clustered around the necrotic foci within cancer cell nests, and the examination with anti-OPN antibody revealed that OPN protein was localized in such necrotic foci where calcium phosphate deposited. The OPN mRNA-expressing cells were identified as macrophages by staining the adjacent section with the anti-CD68 PG-M1 monoclonal antibody which specifically recognizes macrophages. Neither ON mRNA-expressing cells nor MGP mRNA-expressing cells appeared to correlate with the deposition of calcium phosphate. CONCLUSIONS: The OPN protein produced by macrophages appeared to play a significant role for development of calcifying foci within necrotic area of breast cancers.

Localization of the mRNA for bone matrix proteins during fracture healing as determined by in situ hybridization.

The expression of the mRNAs for osteonectin (ON), osteopontin (OPN), osteocalcin (OC), and matrix Gla protein (MGP) was studied by in situ hybridization during the healing process of an experimental fracture in adult rat femora. At day 1 postoperatively, ON mRNA was detected in the proliferating periosteum. At day 3, ON, OPN, and OC mRNAs were detected in woven bone. From day 5, MGP and ON mRNAs were detected in the immature chondrocytes. From day 7, ON, OPN, and OC mRNAs were detected in the osteoblastic cells in newly formed endosteal trabecular bone. OPN mRNA was also detected in some of the osteocytes in trabecular bone. From day 14, OPN and MGP mRNAs were detected in newly formed periosteal hypertrophic chondrocytes, and the ON, OPN, and OC mRNAs were detected in osteoblastic cells in newly formed periosteal trabecular bone. Although the cell types that expressed each mRNA in fractured bones were similar to those in embryonic bones, the time course of these mRNA expression in fractured bones was different from that in embryonic bones. We considered that this system is useful to investigate the phenotypic change in osteogenic and chondrogenic lineage cells that appears during fracture healing at the molecular level.

Expression of genes encoding connective tissue proteins in androgen-dependent SC115 tumors after androgen removal.

BACKGROUND: Shionogi carcinoma 115 (SC115) is an androgen-dependent medullary carcinoma with a compact cell pattern. When SC115 tumors grow in androgen-depleted hosts, spindle-shaped and round cells with abundant cytoplasm develop. These cells originate from the SC115 cells (Kitamura et al., Cancer Res 1979;39:4717; Terada et al., Lab Invest 1987;57:186). EXPERIMENTAL DESIGN: We investigated whether these spindle-shaped and round cells expressed mRNAs of noncollagenous connective tissue proteins, which are expressed by normal spindle-shaped cells and normal chondrocytes in developing bones. The expression and localization of osteonectin (OSN), osteopontin (OSP), matrix Gla protein (MGP), and osteocalcin (OSC) were determined by Northern blotting and in situ hybridization. RESULTS: No mRNA signals of these proteins were detectable in SC115 medullary carcinoma cells growing in DS mice that had been castrated but received injections of testosterone propionate. However, when the injection of TP was stopped, spindle-shaped and round cells with abundant cytoplasm developed. The former expressed OSN and OSP signals, and the latter OSN, OSP, and MGP signals. CONCLUSIONS: Transcripts of OSN, OSP, and MGP were expressed by some SC115-derived cells during the differentiation events that occurred after androgen removal. These results provide molecular biologic evidence that a tumor of epithelial origin can progress along the connective tissue differentiation pathway.

Epithelial cell nodules developing in the cecum of irradiated mice. Some comparisons with jejunal nodules.

A method for producing macroscopic epithelial nodules was developed in order to investigate the properties of epithelial stem cells in the large intestine of mice. The cecum was exteriorized and exposed to various doses of X-ray radiation. Numbers of nodules subsequently developing were counted and plotted against radiation dose. From the logarithmic regression line, the susceptibility to irradiation of nodule-forming stem cells (NFSC) was determined. The susceptibility of cecal NFSC was comparable to the value reported for jejunal NFSC. Mice of (C57BL/6 x DS) F1-Pgk-1b/Pgk-1a that carried X-chromosome inactivation mosaicism for the phosphoglycerate kinase gene were used for examination of nodule clonality. Most cecal nodules contained only 1 type of phosphoglycerate kinase, suggesting a monoclonal origin of the nodules. Histochemical studies showed the presence of absorptive epithelial, goblet and entero-endocrine cells in 17-day-old nodules, implying multipotentiality of the NFSC. In spite of these similarities between cecal and jejunal NFSC, the macroscopic appearance of cecal nodules was quite different from that of jejunal nodules. Only crypt-like structures were observed in the former, whereas both crypt-like and villus-like structures were present in the latter. A comparison between cecal and jejunal nodules may be useful for understanding the morphogenesis of the intestinal mucosa.

Differences in irradiation susceptibility and turnover between mucosal and connective tissue-type mast cells of mice.

Although precursors of mast cells are derived from the bone marrow, phenotypes of mast cells are influenced by the tissues in which final differentiation occurs. Connective tissue-type mast cells (CTMC) and mucosal mast cells (MMC) are different in morphological, biochemical, immunological, and functional criteria. The purpose of the present study was to obtain information about the differentiation process of MMC. First, we compared changes in irradiation susceptibility in mice during the differentiation process of CTMC and MMC. The decrease in irradiation susceptibility was remarkable in the CTMC differentiation process, but it was moderate in that of MMC. Some morphologically identifiable CTMC in the peritoneal cavity had proliferative potential and were highly radioresistant, whereas such a radioresistant population of MMC was not detectable in the gastric mucosa. Second, we estimated the turnover of CTMC and MMC by determining the proportion of mast cells that were labeled with continuously administered bromodeoxyuridine. The turnover of MMC was significantly faster than that of CTMC. The absence of the radioresistant mast cell population in the gastric mucosa appeared to be related to the short life span of MMC.

[Regulatory mechanisms of mast cell differentiation].

Mast cells are a progeny of the multipotential hematopoietic stem cell. Most of progenies of the stem cell complete their differentiation within the bone marrow, but precursors of mast cells leave the bone marrow, migrate in blood, and invade into tissues. After the invasion, precursors proliferate and differentiate into mast cells. An appreciable proportion of mast cells retain proliferative potential after differentiation, and even after degranulation, some mast cells can proliferate and recover the original morphology. Proliferation of mast cells are regulated by both T cell-derived factors (i.e., IL-3 and IL-4) and fibroblast-derived factor(s). Mice of either W/Wv or Sl/Sld genotype lack mast cells, but mast cells do develop when bone marrow cells of W/Wv or Sl/Sld mice were cultured in the presence of T cell-derived factors. Mast cells derived from W/Wv mice cannot respond fibroblast-derived factor(s) and fibroblasts derived from Sl/Sld mice cannot support mast cells of normal mouse origin. Phenotypes of mast cells are determined by the environment in which the mast cells differentiated. However, when mast cells are transplanted into a new environment which is different from the original one, the mast cells acquire the phenotype which are dependent on the second environment.