Ronald R. Gomes

Potential Role for Heparan Sulfate Proteoglycans in Regulation of Transforming Growth Factor-β (TGF-β) by Modulating Assembly of Latent TGF-β-binding Protein-1

Latent transforming growth factor-β-binding proteins (LTBPs) are extracellular matrix (ECM) glycoproteins that play a major role in storage of latent TGF-β in the ECM and regulate its availability. We have previously identified fibronectin as a key molecule for incorporation of LTBP1 and TGF-β into the ECM of osteoblasts and fibroblasts. Here we provide evidence that heparan sulfate proteoglycans may mediate binding between LTBP1 and fibronectin. We have localized critical domains in the N terminus of LTBP1 that are required for co-localization with fibronectin in osteoblast cultures and have identified heparin binding sites in the N terminus of LTBP1 between residues 345 and 487. Solid-phase binding assays suggest that LTBP1 does not bind directly to fibronectin but that the binding is indirect. Heparin coupled to bovine serum albumin (heparin-BSA) was able to mediate binding between fibronectin and LTBP1. Treatment of primary osteoblast cultures with heparin or heparin-BSA but not with chondroitin sulfate impaired LTBP1 deposition onto fibronectin without inhibiting expression of LTBP1. Inhibition of LTBP1 incorporation was accompanied by reduced incorporation of latent TGF-β into the ECM, with increased amounts of soluble latent TGF-β. Inhibition of attachment of glycosaminoglycans to the core proteins of proteoglycans by β-d-xylosides also reduced incorporation of LTBP1 into the ECM. These studies suggest that heparan sulfate proteoglycans may play a critical role in regulating TGF-β availability by controlling the deposition of LTBP1 into the ECM in association with fibronectin.

Chondrogenic activity of the heparan sulfate proteoglycan perlecan maps to the N-terminal domain I.

C3H10T1/2 cells differentiate along a chondrogenic pathway when plated onto the extracellular matrix (ECM) protein perlecan (Pln). To identify the region(s) within the large Pln molecule that provides a differentiation signal, recombinant Pln‐sequence‐based polypeptides representing distinct structural domains were assayed for their ability to promote chondrogenesis in C3H10T1/2 cells. Five distinct domains, along with structural variations, were tested. The N‐terminal domain I was tested in two forms (IA and IB) that contain only heparan sulfate (HS) chains or both HS and chondroitin sulfate (CS) chains, respectively. A mutant form of domain I lacking attachment sites for both HS and CS (Pln Imut) was tested also. Other constructs consecutively designated Pln domains II, III(A‐C), IV(A,B), and V(A,B) were used to complete the structure‐function analysis. Cells plated onto Pln IA or Pln IB but no other domain rapidly assembled into cellular aggregates of 40‐120 μm on average. Aggregate formation was dependent on the presence of glycosaminoglycan (GAG) chains, because Pln I‐based polypeptides lacking GAG chains either by enzymatic removal or mutation of HS/CS attachment sites were inactive. Aggregates formed on GAG‐bearing Pln IA stained with Alcian Blue and were recognized by antibodies to collagen type II and aggrecan but were not recognized by an antibody to collagen type X, a marker of chondrocyte hypertrophy. Collectively, these studies indicate that the GAG‐bearing domain I of Pln provides a sufficient signal to trigger C3H10T1/2 cells to enter a chondrogenic differentiation pathway. Thus, this matrix proteoglycan (PG) found at sites of cartilage formation in vivo is likely to enhance early stage differentiation induced by soluble chondrogenic factors.

Soluble perlecan domain i enhances vascular endothelial growth factor-165 activity and receptor phosphorylation in human bone marrow endothelial cells

BackgroundImmobilized recombinant perlecan domain I (PlnDI) binds and modulates the activity of heparin-binding growth factors, in vitro. However, activities for PlnDI, in solution, have not been reported. In this study, we assessed the ability of soluble forms to modulate vascular endothelial growth factor-165 (VEGF165) enhanced capillary tube-like formation, and VEGF receptor-2 phosphorylation of human bone marrow endothelial cells, in vitro.ResultsIn solution, PlnDI binds VEGF165 in a heparan sulfate and pH dependent manner. Capillary tube-like formation is enhanced by exogenous PlnDI; however, PlnDI/VEGF165 mixtures combine to enhance formation beyond that stimulated by either PlnDI or VEGF165 alone. PlnDI also stimulates VEGF receptor-2 phosphorylation, and mixtures of PlnDI/VEGF165 reduce the time required for peak VEGF receptor-2 phosphorylation (Tyr-951), and increase Akt phosphorylation. PlnDI binds both immobilized neuropilin-1 and VEGF receptor-2, but has a greater affinity for neuropilin-1. PlnDI binding to neuropilin-1, but not to VEGF receptor-2 is dependent upon the heparan sulfate chains adorning PlnDI. Interestingly, the presence of VEGF165 but not VEGF121 significantly enhances PlnDI binding to Neuropilin-1 and VEGF receptor-2.ConclusionsOur observations suggest soluble forms of PlnDI are biologically active. Moreover, PlnDI heparan sulfate chains alone or together with VEGF165 can enhance VEGFR-2 signaling and angiogenic events, in vitro. We propose PlnDI liberated during basement membrane or extracellular matrix turnover may have similar activities, in vivo.

Perlecan Functions in Chondrogenesis: Insights from in vitro and in vivo Models

Perlecan is a large heparan sulfate proteoglycan that is typically found in basal lamina of adult and embryonic tissues. Recent studies have demonstrated that perlecan accumulates impressively during cartilage development and is maintained as the major heparan sulfate proteoglycan of adult cartilage. In vertebrates, perlecan mutations result in skeletal defects. Moreover, in vitro studies indicate that perlecan can stimulate early stages of cartilage differentiation and cooperate with chondrogenic growth factors to promote this process. This short article will summarize these results and propose a model for perlecan function that incorporates these genetic and cell biological findings.

P2Y2 RECEPTORS AND GRK2 ARE INVOLVED IN OSCILLATORY FLUID FLOW INDUCED ERK1/2 RESPONSES IN CHONDROCYTES

Mechanical loading is an important factor regulating cartilage metabolism maintained by chondrocytes. However, some of its underlying mechanisms remain poorly understood. In this study, we employed a chondrogenic cell line ATDC5 to investigate roles of P2Y2 and GRK2 in chondrocyte mechanotransduction. We first confirmed the expression of chondrocyte markers in differentiated ATDC5 cells. We then exposed both differentiated and undifferentiated ATDC5 cells to oscillatory fluid flow, and found that differentiated ATDC5 cells responded to oscillatory fluid flow by increasing COX‐2 and aggrecan expressions. More importantly, fluid flow induced ERK1/2 response in differentiated cells was increased more than 10 times compared to those in undifferentiated cells. Furthermore, we found that P2Y2 mRNA and protein levels in differentiated ATDC5 cells were significantly higher than those in undifferentiated cells. In contrast, GRK2 protein levels in differentiated cells were significantly lower than those in undifferentiated cells. Finally, overexpressions of P2Y2 and GRK2 in differentiated ATDC5 cells result in a 34% increase and a 21% decrease of the ERK1/2 phosphorylation, respectively, in response to oscillatory fluid flow, suggesting important roles of P2Y2 and GRK2 in chondrocyte mechanotransduction.

Spatiotemporal distribution of heparan sulfate epitopes during murine cartilage growth plate development.

Heparan sulfate proteoglycans (HSPGs) are abundant in the pericellular matrix of both developing and mature cartilage. Increasing evidence suggests the action of numerous chondroregulatory molecules depends on HSPGs. In addition to specific functions attributed to their core protein, the complexity of heparan sulfate (HS) synthesis provides extraordinary structural and functional heterogeneity. Understanding the interactions of chondroregulatory molecules with HSPGs and their subsequent outcomes has been limited by the absence of a detailed analysis of HS species in cartilage. In this study, we characterize the distribution and variety of HS species in developing cartilage of normal mice. Cryo-sections of femur and tibia from normal mouse embryos were evaluated using immunostaining techniques. A panel of unique phage display antibodies specific to particular HS species were employed and visualized with secondary antibodies conjugated to Alexa-fluor dyes. Confocal microscopy demonstrates that HS species are dynamic structures within developing growth plate cartilage and the perichondrium. GlcNS6S-IdoUA2S-GlcNS6S species are down regulated and localization of GlcNS6S-IdoUA-GlcNS6S species within the hypertrophic zone of the growth plate is lost during normal development. Regional differences in HS structures are present within developing growth plates, implying that interactions with and responses to HS-binding proteins also may display regional specialization.

Small Animal Models for the Study of Cancer in Bone

Advanced cancers commonly result in metastasis to bone where interactions between the cancer cell and the bone microenvironment produce predominantly osteoblastic or osteolytic lesions. In humans bone metastasis is observed in 60–85% of advanced cancers from tissues as disparate as prostate, breast, kidney, and lung [9]. In animals, however, spontaneous bone metastases are uncommon and investigation of the patterns of bone metastasis mimicking human cancer dissemination is challenging. Experimental models of bone metastasis consist of injections of cancer cells or tissue orthotopically, intracardially, intravenously (via the tail vein), or directly intraosseously into immunocompromised hosts, mostly mice, and, rarely, other small mammals such as dogs and cats.