SummaryWestern blot analysis showed that a monoclonal antibody against recombinant mouse CD14 (mCD14), designated rmC5-3, specifically reacted with mouse macrophage cell line J774, but not myeloma cell line NS1. Fluorographic and immunocytochemical analysis demonstrated specific binding of rmC5-3 with mouse resident macrophages, inflammatory monocytes and neutrophils, and macrophage cell lines. Immunohistochemical staining using rmC5-3 showed that CD14-positive Kupffer cells (KC) were small in number in the liver in nonstimulated mice. The number of stained KC, which were rich in the midzonal and periportal regions, gradually increased with time after intraperitoneal injection of lipopolysaccharide (LPS), peaked 6 h after injection, and returned to normal by 20 h after injection. Staining intensity over time was proportional to the number ofKC. A slight increase in mCD14 expression was observed in peritoneal macrophages 2 h after LPS administration in vivo using flow cytometric analysis, mCD14 mRNA became detectable at 1 h after the intraperitoneal injection of LPS (20 gg/mice), and the level dramatically increased with time, peaking at 3 h, and sharply dropped at 6 h. The resident peritoneal macrophages demonstrated a constitutively high mCD14 mRNA expression, which slightly increased 2 h after LPS (100 ng/ml) stimulation in vitro. The level of mCD14 expression in macrophages did not increase after intraperitoneal injection of LPS (20 gg/mice).
We isolated the human osteopontin (hOP) gene and the 5' upstream region, and analysed its exon-intron structure and potential regulatory sequences of the promoter region in comparison with those of the mouse and porcine gene. The coding sequence is split into 7 exons which are similar to those of the mouse gene, although the hOP gene is longer than the mouse gene. The difference in length is mainly due to variations in intron 3, which is approximately 2.7-fold longer than that of the mouse OP gene. The 5' upstream region of the hOP, which is highly conserved up to nucleotide -250, contains a number of potential cis regulatory consensus sequences. A series of sequentially 5'-deleted chimeric clones was tested for the ability to stimulate chloramphenicol acetyltransferase (CAT). Initial CAT analysis demonstrated that nucleotides at positions -474 to -270, -124 to -80, and -55 to -39 contained cis-acting enhancing sequences in a human monocyte cell line, SCC-3, although the -124 to -80 region was much more active than other regions. Deletion of the sequences between -474 and -270 localized this cis region to the sequence at positions -439 to -410, whereas the deletion between -124 to -80 localized the regions to -124 to -115, and -94 to -80. Gel-shift analysis using as probes synthesized double-stranded DNA corresponding to the 10 and 15 bp region at positions -124 to -115 and -94 to -80 respectively revealed that each probe formed a major band complexed with nuclear proteins prepared from SCC-3 cells.
cDNA clones which strongly hybridized with a 3.1 kb mRNA from mouse macrophages and macrophage cell lines and weakly with mRNA from P815 but not from a variety of other cell lines and tissues were isolated from cDNA libraries constructed using mRNA from murine macrophage cell lines and peritoneal macrophages. Treatment of a macrophage cell line with macrophage stimulators significantly enhanced transcription of the mRNA. Sequencing analysis of these clones demonstrated that the cDNA consisted of 3036 bp insert containing a 2478 bp open reading frame followed by a 538 bp 3' untranslated region. The amino acid sequence, deduced from the nucleotide sequence of the cDNA, predicted a protein containing a signal peptide, an extracellular region, a transmembrane domain, and a cytoplasmic tail. The extracellular region had five putative N-glycosylation sites and a cysteine-rich domain, whereas the cytoplasmic region consisted of a proline-rich amino acid sequence significantly similar to CD2. SDS-PAGE and NEPHGE SDS-PAGE analysis of the immunoprecipitated membrane of the macrophage cell lines prepared by using rabbit anti-MS2 peptide antibody raised against a synthetic peptide preparation relative to a hydrophilic region of the MS2 amino acid sequence confirmed that MS2 protein is a cross-linked protein having approximate molecular sizes of 89 kd and pl 6.5-7.0. These results show that MS2 protein is a novel cell surface antigen expressed mainly in monocytic lineages.
We analysed chromosomal copy number aberrations (CNAs) in renal cell carcinomas by array-based comparative genomic hybridization, using a genome-wide scanning array with 2304 BAC and PAC clones covering the whole human genome at a resolution of roughly 1.3 Mb. A total of 30 samples of renal cell carcinoma were analysed, including 26 cases of clear cell carcinoma (CCC) and four cases of chromophobe renal cell carcinoma (ChCC). In CCCs, gains of chromosomes 5q33.1-qter (58%), 7q11.22-q35 (35%) and 16p12.3-p13.12 (19%), and losses of chromosomes 3p25.1-p25.3 (77%), 3p21.31-p22.3 (81%), 3p14.1-p14.2 (77%), 8p23.3 (31%), 9q21.13-qter (19%) and 14q32.32-qter (38%) were detected. On the other hand, the patterns of CNAs differed markedly between CCCs and ChCCs. Next, we examined the correlation of CNAs with expression profiles in the same tumour samples in 22/26 cases of CCC, using oligonucleotide microarray. We extracted genes that were differentially expressed between cases with and without CNAs, and found that significantly more up-regulated genes were localized on chromosomes 5 and 7, where recurrent genomic gains have been detected. Conversely, significantly more down-regulated genes were localized on chromosomes 14 and 3, where recurrent genomic losses have been detected. These results revealed that CNAs were correlated with deregulation of gene expression in CCCs. Furthermore, we compared the patterns of genomic imbalance with histopathological features, and found that loss of 14q appeared to be a specific and additional genetic abnormality in high-grade CCC. When we compared the expression profiles of low-grade CCCs with those of high-grade CCCs, differentially down-regulated genes tended to be localized on chromosomes 14 and 9. Thus, it is suggested that copy number loss at 14q in high-grade CCC may be involved in the down-regulation of genes located in this region.
Two different metallothionein promoter-mouse CD14 fusion genes were constructed. The membrane form of the CD14 fusion gene, designated M14M, contained the full-length CD14 cDNA sequence, whereas the soluble form of the fusion gene, designated M14S, was truncated to lack the sequence for the phosphatidylinositol-anchoring site. Expression of transgenic RNA in M14M and M14S mice on the basal diet was abundant in the liver. After maintenance with water containing ZnSO4 (50 mM) for 4 days, expression of transgenic RNA in M14M and M14S mice was strong in the small intestine. Immunohistochemical analysis demonstrated CD14 expression in these organs in M14S and M14M mice. Levels of CD14 in sera from M14S mice after zinc administration were significantly higher than these animals maintained with normal water, M14M mice after zinc administration and non-transgenic mice. Sera from M14S and M14M mice after stimulation with lipopolysaccharide LPS (LPS) demonstrated significantly lower levels of tumor necrosis factor-alpha and IL-6 than those from non-transgenic mice. Lethality in endotoxin shock produced by i.p. injection of 30-40 microg/g body wt LPS was not different between M14S, M14M and non-transgenic mice. However, survival rates in the lethal Shwartzman reaction induced by priming and challenge injections of LPS were significantly higher in M14M and M14S mice than in non-transgenic mice.
The polymerase chain reaction (PCR) method was used to determine the presence and amount of human T lymphotropic virus type I (HTLV-I) proviral DNA in central nervous system (CNS) tissue obtained at autopsy from 6 patients with HTLV-I-associated myelopathy (HAM)/tropical spastic paraparesis (TSP), 1 patient with adult T-cell leukemia (ATL) and CNS infiltration of leukemic cells, and 9 control subjects with other neurological disorders. HTLV-I pX and env but not pol DNA were detected in CNS tissue from 5 of 6 patients with HAM/TSP. The ATL samples were positive for pX, env, and pol DNA by PCR. None of the control samples was consistently positive for HTLV-I by PCR, but all showed positive bands on beta-globin PCR. Quantitative PCR combined with histological studies showed no correlation between HTLV-I proviral DNA amounts and extent of perivascular mononuclear cell infiltration in the HAM/TSP CNS. Also, the amounts of pX and probably env DNA were greater in the HAM/TSP samples than in the ATL sample, although the extent of mononuclear cell infiltration was far less in the HAM/TSP samples than in the ATL sample. Therefore, in addition to infiltrating mononuclear cells, constituent cells of the CNS may harbor the HTLV-I genome, at least in the pX and env regions, in patients with HAM/TSP.
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