Extra-hepatic expression of serum albumin mRNA in mouse retina.

PURPOSE: In some mammals, serum albumin protein exists in the interphotoreceptor space (IPS), the space between photoreceptor cells and the retinal pigment epithelium. Serum albumin is synthesized largely in the liver, though low levels of extra-hepatic expression have been documented in several other tissues, including fetal rat kidney, pancreas, lung, and heart. The purpose of this study was to investigate whether serum albumin protein and mRNA are found in mouse retina. METHODS: Using albumin rabbit antibodies and HRP goat anti-(rabbit IgG), we performed immunoassays on mouse IPS washes to detect the presence of serum albumin protein. Protein extracts from IPS washes were subjected to Affigel Blue chromatography. This resin has an affinity for serum albumin. Reverse transcription-polymerase chain reaction (RT-PCR) of retina total RNA was performed to search for albumin mRNA. Also, real-time reverse transcription polymerase chain reaction (RT-RT-PCR) was employed to look at the levels of expression in different age groups. RESULTS: A constituent of the IPS washes specifically bound and eluted from Affigel Blue column, suggesting that the washes contained serum albumin. SDS PAGE revealed that the size of the constituent was 67 kDa, the size of serum albumin. This 67 kDa band reacted with mouse serum antibody. An RT-PCR amplified fragment of serum albumin mRNA from retina displayed the expected size. The sequence of this fragment is identical to authentic serum albumin cDNA sequence. RPE and choroid were negative for serum albumin mRNA. However, rd1(-)/rd1(-) retina was positive, suggesting that at least some serum albumin is synthesized in the inner layers of the retina. RT-RT-PCR showed that serum albumin mRNA levels in whole retina reached a maximum at about postnatal day 15 and gradually decreased to about one-sixth of maximum at 12 months age. CONCLUSIONS: Serum albumin protein and mRNA were found in mouse IPS and retina, suggesting that the protein is synthesized in the retina. The previously demonstrated ability of serum albumin to bind fatty acids and retinoids and its presence in the mouse IPS suggest a role for serum albumin in transporting retinoids in the retina or IPS, especially at young ages when concentrations appear greatest.

Increasing membrane-bound MCSF does not enhance OPGL-driven osteoclastogenesis from marrow cells.

Macrophage colony-stimulating factor (MCSF) and osteoprotegerin ligand (OPGL), both produced by osteoblasts/stromal cells, are essential factors for osteoclastogenesis. Whether local MCSF levels regulate the amount of osteoclast formation is unclear. Two culture systems, ST-2 and Chinese hamster ovary-membrane-bound MCSF (CHO-mMCSF)-Tet-OFF cells, were used to study the role of mMCSF in osteoclast formation. Cells from bone marrow (BMM) or spleen were cultured with soluble OPGL on glutaraldehyde-fixed cell layers; osteoclasts formed after 7 days. Osteoclast number was proportional to the amount of soluble OPGL added. In contrast, varying mMCSF levels in the ST-2 or CHO-mMCSF-Tet-OFF cell layers, respectively by variable plating or by addition of doxycycline, did not affect BMM osteoclastogenesis: 20-450 U of mMCSF per well generated similar osteoclast numbers. In contrast, spleen cells were resistant to mMCSF: osteoclastogenesis required > or = 250 U per well and further increased as mMCSF rose higher. Our results demonstrate that osteoclast formation in the local bone environment is dominated by OPGL. Increasing mMCSF above basal levels does not further enhance osteoclast formation from BMMs, indicating that mMCSF does not play a dominant regulatory role in the bone marrow.

Transcriptional regulation of the expression of macrophage colony stimulating factor.

The regulatory regions for transcriptional control of the MCSF gene are unknown. We examined regulatory control in a 774-bp murine MCSF promoter transfected into MC3T3-E1 osteoblast-like and COS-7 cells. Deletion of upstream sequence from -635 increased basal activity of the promoter by at least four-fold, an increase that was maintained when PU.1, NFkappaB and Egr1/Sp1 consensus sequences were subsequently removed. Mutagenesis identified a suppressor element between -635 and -642 from the transcriptional start site and an oligonucleotide representing this sequence was retarded by nuclear cell protein. TNFalpha (1 ng/ml), PTH (5x10(-8) M), and IL-1alpha (100 pg/ml), which increased MCSF protein secretion, failed to enhance the transcriptional rate of the full-length promoter. TNFalpha was able to stimulate transcription of a heterologous reporter transfected into COS-7 containing multiple copies of the murine MCSF NFkappaB site inserted before a minimal promoter. In contrast, deletion of the same NFkappaB response element increased basal activity in the native promoter. Thus, the NFkappaB sequence may act as a negative regulator in the context of the endogenous promoter. Our results indicate that constitutive transcriptional activity conferred by the MCSF promoter may be damped by a suppressor protein. Transcriptional regulation, however, does not appear to be a major stimulatory mechanism for MCSF secretion.

Role of NFkappaB in the regulation of macrophage colony stimulating factor by tumor necrosis factor-alpha in ST2 bone stromal cells.

Expression of MCSF in bone is important to the regulation of osteoclastogenesis. We show here that tumor necrosis factor-alpha (TNFalpha) increases the production of both soluble (sMCSF) and membrane-bound (mMCSF) macrophage colony stimulating factor by ST2 bone stromal cells. Treatment of ST2 cells with TNFalpha caused sMCSF levels to increase by 394+/-5% from basal; mMCSF rose by 316+/-66% from 30+/-10 per 100,000 cells in the same time. These increases were consistent with increased expression of mRNAs encoding both isoforms. Increases in MCSF mRNA are also seen after stimulation with dexamethasone. To investigate the potential role of NFkappaB in this TNFalpha effect, we treated cells with sodium salicylate (NaS), an inhibitor of NFkappaB translocation. NaS decreased TNFalpha-stimulated NFkappaB activation by 50% as assessed by EMSA. Despite inhibition of NFkappaB signaling, NaS enhanced TNFalpha-stimulated MCSF secretion and did not prevent TNFalpha-stimulated increases in sMCSF mRNA, suggesting that NFkappaB was not involved in TNFalpha effect on the gene. TNFalpha failed to stimulate transcription of a 774 nucleotide MCSF promoter-luciferase reporter transfected into ST2 cells which contained the NFkappaB consensus sequence. Deletion of the seven nucleotides containing the NFkappaB homology response sequence from the MCSF promoter increased basal gene transcription by twofold. TNFalpha thus contributes to an osteoclastogenic environment through upregulation of bone expression of both MCSF isoforms. Our data suggests that NFkappaB is not the major signaling pathway through which this occurs.