HK2 Proximal Tubule Epithelial Cells Synthesize and Secrete Plasma Proteins Predominantly Through the Apical Surface.

Renal proximal tubule epithelial cells (PTECs) are known to reabsorb salts and small plasma proteins filtered through Bowman's capsule. Following acute kidney injury, PTECs assume some characteristics of hepatocytes in producing various plasma proteins. We now demonstrate that even at a resting state, a PTEC cell line, HK2 expresses mRNAs for and synthesizes and secretes plasma proteins in a complex with complement C3, an α2 -macroglobulin family chaperone, including albumin, transferrin, α1 -antitrypsin, α1 -antichymotrypsin, α2 -HS-glycoprotein, ceruloplasmin, haptoglobin, C1-inhibitor, secreted phosphoprotein-24, and insulin-like growth factor-1. When grown on transwell inserts, HK2 cells predominantly secrete (∼90%) plasma proteins into the apical side and a smaller fraction into the basolateral side as determined by ELISA assays. When cultured in the presence of exogenous cytokines such as IL1ß, IL6, TNFα, BMP2, or TGFß1, HK2 cell mRNA expressions for plasma proteins were variably affected whereas basolateral secretions were elevated to or in excess of those of the apical level. In addition, HK2 cells produce proTGFß1 with its intact N-terminal latency associated peptide and latent-TGF-ß-binding proteins. The complex cannot be dissociated under conditions of SDS, heating, and electrophoresis. Moreover, HK2 cells maintain their ability to quickly uptake exogenously added serum proteins from the culture medium, as if they are recognized differently by the endocytic receptors. These results provide new insight into the hepatization of PTECs. In addition to their unique uptake of plasma proteins and salts from the filtrate, they are a source of urinary proteins under normal conditions as wells as in chronic and acute kidney diseases. J. Cell. Biochem. 118: 924-933, 2017. © 2016 Wiley Periodicals, Inc.

Fibroblastic synoviocytes secrete plasma proteins via α2 -macroglobulins serving as intracellular and extracellular chaperones.

Changes in plasma protein levels in synovial fluid (SF) have been implicated in osteoarthritis and rheumatoid arthritis. It was previously thought that the presence of plasma proteins in SF reflected ultrafiltration or extravasation from the vasculature, possibly due to retraction of inflamed endothelial cells. Recent proteomic analyses have confirmed the abundant presence of plasma proteins in SF from control and arthritic patients. Systematic depletion of high-abundance plasma proteins from SF and conditioned media from synoviocytes cultured in serum, and protein analysis under denaturing/reducing conditions have limited our understanding of sources and the native structures of "plasma protein" complexes in SF. Using Western blotting, qPCR, and mass spectrometry, we found that Hig-82 lapine fibroblastic synovicytes cultured under serum-free conditions expressed and secreted plasma proteins, including the cytokine-binding protein secreted phosphoprotein 24 kDa (Spp24) and many of the proteases and protease inhibitors found in SF. Treating synoviocytes with TGF-ß1 or BMP-2 for 24 h upregulated the expression of plasma proteins, including Spp24, α2 -HS-glycoprotein, α1 -antitrypsin, IGF-1, and C-reactive protein. Furthermore, many of the plasma proteins of mass <151 kDa were secreted as disulfide-bound complexes with members of the α2 -macroglobulin (A2M) family, which serve as intracellular and extracellular chaperones, not protease inhibitors. Using brefeldin A to block vesicular traffic and protease inhibitors to inhibit endogenous activation of naïve A2M, we demonstrated that the complexes were formed in the endoplasmic reticulum lumen and that Ca(2+) cysteine protease-dependent processes are involved.

Spp24 derivatives stimulate a Gi-protein coupled receptor-Erk1/2 signaling pathway and modulate gene expressions in W-20-17 cells.

Secreted phosphoprotein 24 kDa (Spp24) is an apatite- and BMP/TGF-ß cytokine-binding phosphoprotein found in serum and many tissues, including bone. N-terminally intact degradation products ranging in size from 14 kDa to 23 kDa have been found in bone. The cleavage sites in Spp24 that produce these short forms have not been definitively identified, and the biological activities and mechanisms of action of Spp24 and its degradation products have not been fully elucidated. We found that the C-terminus of Spp24 is labile to proteolysis by furin, kallikrein, lactoferrin, and trypsin, indicating that both extracellular and intracellular proteolytic events could account for the generation of biologically-active Spp18, Spp16, and Spp14. We determined the effects of these truncation products on kinase-mediated signal transduction, gene expression, and osteoblastic differentiation in W-20-17 bone marrow stromal cells cultured in basal or pro-osteogenic media. After culturing for five days, all forms inhibited BMP-2-stimulated osteoblastic differentiation, assessed as induction of alkaline phosphatase activity, in basal, but not pro-osteogenic media. After 10 days, they also inhibited BMP-2-stimulated mineral deposition in pro-osteogenic media. Spp24 had no effect on Erk1/2 phosphorylation, but Spp18 stimulated short-term Erk1/2, MEK 1/2, and p38 phosphorylation. Pertussis toxin and a MEK1/2 inhibitor ablated Spp18-stimulated Erk 1/2 phosphorylation, indicating a role for Gi proteins and MEK1/2 in the Spp18-stimulated Erk1/2 phosphorylation cascade. Truncation products, but not full-length Spp24, stimulated RUNX2, ATF4, and CSF1 transcription. This suggests that Spp24 truncation products have effects on osteoblastic differentiation mediated by kinase pathways that are independent of exogenous BMP/TGF-ß cytokines.

Late adherent human bone marrow stromal cells form bone and restore the hematopoietic microenvironment in vivo.

Bone marrow stromal cells (BMSCs) are a valuable resource for skeletal regenerative medicine because of their osteogenic potential. In spite of the very general term "stem cell," this population of cells is far from homogeneous, and different BMSCs clones have greatly different phenotypic properties and, therefore, potentially different therapeutic potential. Adherence to a culture flask surface is a primary defining characteristic of BMSCs. We hypothesized that based on the adherence time we could obtain an enriched population of cells with a greater therapeutic potential. We characterized two populations of bone marrow-derived cells, those that adhered by three days (R-cells) and those that did not adhere by three days but did by six days (L-cells). Clones derived from L-cells could be induced into adipogenic, chondrogenic, and osteogenic differentiation in vitro. L-cells appeared to have greater proliferative capacity, as manifested by larger colony diameter and clones with higher CD146 expression. Only clones from L-cells developed bone marrow stroma in vivo. We conclude that the use of late adherence of BMSCs is one parameter that can be used to enrich for cells that will constitute a superior final product for cell therapy in orthopedics.

Secreted phosphoprotein-24 kDa (Spp24) attenuates BMP-2-stimulated Smad 1/5 phosphorylation and alkaline phosphatase induction and was purified in a protective complex with alpha2 -Macroglobulins From Serum.

Secreted phosphoprotein-24 kDa (Spp24) binds cytokines of the bone morphogenetic protein/transforming growth factor-ß (BMP/TGFß) superfamily and is one of the most abundant serum phosphoproteins synthesized by the liver. Little is known about how Spp24 binding affects BMP signal transduction and osteoblastic differentiation or how this labile protein is transported from the liver to remote tissues, such as bone. When Spp24 was administered to W-20-17 mesenchymal stem cells with rhBMP-2, short-term Smad1/5 phosphorylation was inhibited, intermediate-term alkaline phosphatase (ALP) induction was blunted, and long-term mineralization was unaffected. This supports the hypothesis that Spp24 proteolysis restricts the duration of its regulatory effects, but offers no insight into how Spp24 is transported intact from the liver to bone. When Spp24 was immunopurified from serum and subjected to native PAGE and Western blotting, a high molecular weight band of >500 kDa was found. Under reducing SDS-PAGE, a 24 kDa band corresponding to monomeric Spp24 was liberated, suggesting that Spp24 is bound to a complex linked by disulfide bonds. However, such a complex cannot be disrupted by 60 mM EDTA under non-reducing condition or in purification buffers containing 600 mM NaCl and 0.1% Tween-20 at pH 2.7-8.5. LC-MS/MS analysis of affinity-purified, non-reducing SDS-PAGE separated, and trypsin digested bands showed that the Spp24 was present in a complex with three α(2) -macroglobulins (α(2) -macroglobulin [α(2) M], pregnancy zone protein [PZP] and complement C3 [C3]), as well as ceruloplasmin and the protease inhibitor anti-thrombin III (Serpin C1), which may protect Spp24 from proteolysis.

Recombinant expression, isolation, and proteolysis of extracellular matrix-secreted phosphoprotein-24 kDa.

Secreted phosphoprotein-24 kDa (spp24) is an extracellular matrix protein first cloned from bone. Bovine spp24 is transcribed as a 203 amino acid residue protein that undergoes cleavage of a secretory peptide to form the mature protein (spp24, residues 24 to 203). While not osteogenic itself, spp24 is degraded to a pro-osteogenic protein, spp18.5, in bone. Both spp18.5 and spp24 contain a cyclic TRH1 (TGF-beta receptor II homology-1) domain similar to that found in the receptor itself and in fetuin. A synthetic peptide corresponding to the TRH1 domain of spp18.5 and spp24 specifically binds BMP-2 and enhances the rate and magnitude of BMP-2-induced ectopic bone formation in vivo. The parental protein, spp24, exhibits a high affinity for bone and mineral complexes, but its abundance there is low, suggesting that it is rapidly degraded. The availability of recombinant spp24 and its degradation products would facilitate the elucidation of their structure:function relationships. We describe here the expression of His(6)-tagged bovine spp24 (residues 24 to 203) in E. coli, its purification by high-resolution IMAC (immobilized metal affinity chromatography), and the characterization of the full-length recombinant 21.5 kDa protein and its two major 16 kDa and 14.5 kDa degradation products (spp24, residues 24 to 157, and spp24, residues 24 to 143) by mass spectroscopy. The recombinant spp24 protein was resistant to proteolysis by MC3T3-E1 osteoblastic cell extracts in the absence of calcium; however, in the presence of 4 mM Ca, it can undergo essentially complete proteolysis to small peptides, bypassing the 16 kDa and 14.5 kDa intermediates. This confirms the proteolytic susceptibility of spp24. It also suggests that the levels of spp24 in bone may be regulated, in part, by calcium-dependent proteolysis mediated by osteoblastic cells.

The effects of lovastatin on proteasome activities in highly purified rabbit 20 S proteasome preparations and mouse MC3T3-E1 osteoblastic cells.

A number of clinical studies suggest that the use of the lipid-lowering agents collectively referred to as statins (hydroxymethyl glutaryl coenzyme A [HMG-CoA] reductase inhibitors) is associated with increased bone density, reduced fracture risk, and net bone anabolism. Statins (< or =5 micromol/L) stimulate rodent bone formation, but the mechanistic basis remains unclear. Since statins and the proteasome inhibitor lactacystin are structurally similar, and high doses (> or =40 micromol/L) of statins can inhibit the chymotryptic activity of the proteasome, it has been hypothesized that statins exert their anabolic effects on bone, in part, by inhibiting the proteasome, the major eukaryotic intracellular regulatory protease. This hypothesis conflicts with reports that statins stimulate proteasome activity and that proteasome-catalyzed degradation of specific substrates is required for cell proliferation, differentiation, and survival. Our chief objective was to determine the effects of statins (< or =10 micromol/L) on the chymotryptic activity of the proteasome in the 20 S proteasome and intact murine MC3T3-E1 cells cultured to low density (preosteoblasts) or high density (differentiated osteoblasts). Lovastatin (0.001 micromol/L to 5.0 micromol/L) stimulated the chymotryptic activity of the highly purified 20 S proteasome. Preosteoblasts and differentiated osteoblasts treated with 1, 5, or 10 micromol/L lovastatin for 1 hour exhibited morphologic abnormalities that were ameliorated by preincubation and treatment with 20 micromol/L mevalonate. The chymotryptic activity of the preosteoblast proteasome increased after 2 days of 1.0 micromol/L or 5.0 micromol/L lovastatin treatment. In addition, the DNA and protein contents of 1.0 micromol/L or 5.0 micromol/L lovastatin-treated preosteoblast cultures were lower those that observed in vehicle-, 0.01 micromol/L lovastatin-, or 0.10 micromol/L lovastatin-treated cultures. The chymotryptic activity of the proteasome was much lower in differentiated osteoblasts than in preosteoblasts. Two days of treatment with 1 micromol/L lovastatin modestly stimulated the chymotryptic activity of the proteasome in differentiated osteoblasts, but had no effects on total protein or DNA, compared to cultures treated with vehicle or lower doses of lovastatin. Thus, the data support the hypothesis that statins stimulate proteasome activities in highly purified proteasome preparations and preosteoblastic cells. Treating preosteoblastic or differentiated MC3T3-E1 cells with lovastatin concentrations > or = 1 micromol/L resulted in abnormal morphology and reduced the DNA and protein levels in preosteoblastic cultures, confirming the adverse effects of statins previously reported for other cells. In conclusion, the hypothesis that lovastatin exerts its anabolic effects on bone by inhibiting the proteasome activity of the osteoblast was refuted, and the effects of lovastatin on MC3T3-E1 cells were found to be highly dose- and development-dependent.