The Responses of Hyperglycemic Dividing Mesangial Cells to Heparin Are Mediated by the Non-reducing Terminal Trisaccharide

Our previous studies showed: (i) that growth-arrested G₀/G₁ rat mesangial cells stimulated to divide in hyperglycemic medium initiate intracellular hyaluronan synthesis that induces autophagy and the cyclin D3-induced formation of a monocyte-adhesive extracellular hyaluronan matrix after completing cell division; and (ii) that heparin inhibits the intracellular hyaluronan and autophagy responses, but after completing division, induces hyaluronan synthesis at the plasma membrane with the formation of a larger monocyte-adhesive hyaluronan matrix. This study shows: (i) that the non-terminal trisaccharide of heparin is sufficient to initiate the same responses as intact heparin, (ii) that a fully sulfated tetrasaccharide isolated from bacterial heparin lyase 1 digests of heparin that contains a Δ-2S-iduronate on the non-reducing end does not initiate the same responses as intact heparin, and (iii) that removal of the Δ-2S-iduronate to expose the fully sulfated trisaccharide (GlcNS(6S)-IdoUA(2S)-GlcNS(6S)) does initiate the same responses as intact heparin. These results provide evidence that mammalian heparanase digestion of heparin and heparan sulfate exposes a cryptic motif on the non-reducing termini that is recognized by a receptor on dividing cells.     

Cyclin D3 Mediates Synthesis of a Hyaluronan Matrix That Is Adhesive for Monocytes in Mesangial Cells Stimulated to Divide in Hyperglycemic Medium

Serum-starved, growth-arrested, near confluent rat mesangial cell cultures were stimulated to divide in medium with low (5.6 mm) or high (25.6 mm) glucose. In high glucose cultures Western blots showed large increases in cyclin D3 and CCAAT/enhancer-binding protein α (C/EBPα) at 48–72 h, concurrent with the production of a monocyte-adhesive hyaluronan matrix, whereas low glucose and mannitol osmotic control cultures did not. Cyclin D3 small interfering RNA inhibited both the synthesis of this matrix and the up-regulation of C/EBPα in cultures exposed to high glucose, indicating that cyclin D3 is a key mediator in regulating responses of dividing mesangial cells to hyperglycemia. A complex with cyclin D3, cyclin-dependent kinase 4, and C/EBPα was observed at 48–72 h in the hyperglycemic cultures, and cyclin D3 and C/EBPα were spatially co-localized in coalesced perinuclear honeycomb-like structures with embedded hyaluronan. Furthermore, microtubule-associated protein 1 light chain 3, a marker for autophagy, colocalizes with these structures. These results suggest that cyclin D3 is a central coordinator that controls the organization of a complex set of proteins that regulate autophagy, formation of the monocyte-adhesive hyaluronan matrix, and C/EBPα-mediated lipogenesis. Abnormal deposits of hyaluronan, cyclin D3, and C/EBPα were present in glomeruli of kidney sections from hyperglycemic rats 4 weeks after streptozotocin treatment, indicating that similar processes likely occur in vivo. Mesangial cell cultures treated with poly(I:C) or tunicamycin in normal glucose media synthesized monocyte-adhesive hyaluronan matrices but with concurrent down-regulation of cyclin D3. This indicates that the cyclin D3 mechanism is induced by hyperglycemia and is distinct from those involved in these cell stress responses.One of the abnormalities detected after the onset of hyperglycemic diabetes in the streptozotocin rat model is an early (already by 3 days) and self-limited proliferation of glomerular mesangial cells that is associated with de novo expression of α-smooth muscle actin, an activation marker of the proliferative mesangial cell phenotype (1–3). After this early transient proliferation and phenotypic activation, there is a prominent glomerular infiltration of monocytes and macrophages (3). Our previous study showed that abnormal hyaluronan matrices also form in the hyperglycemic glomeruli within 1 week (4). We also showed that quiescent, growth-arrested rat mesangial cells, stimulated to divide in a hyperglycemic level of glucose (25.6 mm), form a hyaluronan matrix that is adhesive for U937 monocytic cells. These results suggest that there is an important link in vivo between mesangial cell division in response to hyperglycemia, glomerular hyaluronan matrix synthesis, and the accumulation of monocytes/macrophages in glomerular diabetic nephritis.Previous studies have shown that smooth muscle cell cultures exposed to tunicamycin (endoplasmic reticulum stress) or poly(I:C) (viral mimetic) synthesize hyaluronan cable-like structures that are adhesive for monocytes (5, 6). The experiments described in this report indicate that growth-arrested mesangial cells stimulated to divide in hyperglycemic medium synthesize similar structures by a distinctly different mechanism that requires protein kinase C up-regulation at the initiation of cell division and subsequent up-regulation of cyclin D3 after completion of cell division. The up-regulation of cyclin D3 in turn appears to control an autophagic response and is coordinate with up-regulation of C/EBPα, a factor that controls lipogenic responses. Evidence is also provided that cyclin D3 and C/EBPα also contribute to glomerular responses to hyperglycemia in vivo.     

Hyaluronan structures synthesized by rat mesangial cells in response to hyperglycemia induce monocyte adhesion

Mesangial expansion, the principal glomerular lesion in diabetic nephropathy, is preceded by a phenotypic activation and transient proliferation of the glomerular mesangial cells and by a prominent glomerular infiltration of monocytes and macrophages. Because this infiltration seems to play a key role in the subsequent mesangial matrix expansion, we tested the response of cultures of rat mesangial cells (RMCs) for monocyte adhesion in response to hyperglycemia. Increasing the medium glucose concentration from 5.6 mm (normal) to 25.6 mm (hyperglycemic) significantly increased hyaluronan in the cell matrix, with a concurrent 3- to 4-fold increase in adhesion of U937 monocytic leukemic cells to cultures of near confluent RMCs. These responses were attributed directly to the high glucose concentration and not to increased extracellular osmolality. The monocytes primarily bind directly to hyaluronan-based structures in vitro. Abnormal deposits of hyaluronan were found in glomeruli of kidney sections from diabetic rats 1 week after streptozotocin treatment, often with closely associated monocytes/macrophages, suggesting that similar structures are relevant in vivo. The monocyte adhesion response to high glucose concentration required growth stimulation of RMCs by serum and activation of protein kinase C, and was inhibited by prior passage of the RMCs in the presence of heparin. These results suggest that the response may be cell growth state and protein kinase C-dependent. When incubated with the viral mimetic, poly I:C, in the presence of normal glucose, heparin-passaged RMCs still increased cell-associated hyaluronan and exhibited hyaluronan-mediated adhesion of monocytes, indicating that the two stimuli, high glucose and viral mimetic, induce the production of the hyaluronan structures that promote monocyte adhesion by distinctly different intracellular signaling mechanisms.     

Hyaluronan matrices in pathobiological processes

Hyaluronan matrices are ubiquitous in normal and pathological biological processes. This remarkable diversity is related to their unique mechanism of synthesis by hyaluronan synthases. These enzymes are normally activated in the plasma membrane and utilize cytosolic substrates directly to form these large polyanionic glycosaminoglycans, which are extruded directly into the extracellular space. The extracellular matrices that are formed interact with cell surface receptors, notably CD44, that often dictate the biological processes, as described in the accompanying minireviews of this series. This article focuses on the discovery in recent studies that many cell stress responses initiate the synthesis of a monocyte-adhesive hyaluronan extracellular matrix, which forms a central focus for subsequent inflammatory processes that are modulated by the dialogue between the matrix and the inflammatory cells. The mechanisms involve active hyaluronan synthases at the cell membrane when cell stresses occur at physiological levels of glucose. However, dividing cells at hyperglycemic levels of glucose initiate the synthesis of hyaluronan in intracellular compartments, which induces endoplasmic reticulum stress and autophagy, processes that probably contribute greatly to diabetic pathologies.     

Hyperglycemia Diverts Dividing Osteoblastic Precursor Cells to an Adipogenic Pathway and Induces Synthesis of a Hyaluronan Matrix That Is Adhesive for Monocytes

Isolated rat bone marrow stromal cells cultured in osteogenic medium in which the normal 5.6 mm glucose is changed to hyperglycemic 25.6 mm glucose greatly increase lipid formation between 21–31 days of culture that is associated with decreased biomineralization, up-regulate expression of cyclin D3 and two adipogenic markers (CCAAT/enhancer binding protein α and peroxisome proliferator-activated receptor γ) within 5 days of culture, increase neutral and polar lipid synthesis within 5 days of culture, and form a monocyte-adhesive hyaluronan matrix through an endoplasmic reticulum stress-induced autophagic mechanism. Evidence is also provided that, by 4 weeks after diabetes onset in the streptozotocin-induced diabetic rat model, there is a large loss of trabecular bone mineral density without apparent proportional changes in underlying collagen matrices, a large accumulation of a hyaluronan matrix within the trabecular bone marrow, and adipocytes and macrophages embedded in this hyaluronan matrix. These results support the hypothesis that hyperglycemia in bone marrow diverts dividing osteoblastic precursor cells (bone marrow stromal cells) to a metabolically stressed adipogenic pathway that induces synthesis of a hyaluronan matrix that recruits inflammatory cells and establishes a chronic inflammatory process that demineralizes trabecular cancellous bone.     

Hyperglycemia,intracellular hyaluronan synthesis,cyclin D3 and autophagy

Hyperglycemia is one of the factors that induces autophagy. Our recent studies demonstrate that dividing cells in hyperglycemic medium initiate an intracellular stress response that involves synthesis of hyaluronan and its extrusion extracellularly into structures that are recognized by inflammatory cells. During the later phase, a complex with cyclin D3, CDK4 and C/EBPα was observed in the hyperglycemic cultures, and cyclin D3 and C/EBPα colocalized in coalesced perinuclear honeycomb-like structures with embedded hyaluronan. Further, microtubule-associated protein 1 light chain 3 (LC3), a marker for autophagy, colocalizes with these structures. These results suggest that cyclin D3 is a central coordinator that controls the organization of a complex set of proteins that regulate autophagy and subsequent formation of the monocyte-adhesive hyaluronan matrix. However, the early intracellular accumulation of hyaluronan could have a critical role in initiating or regulating these downstream events.     

Hyaluronan: Biosynthesis and signaling

Background

Hyaluronan is a critical component of extracellular matrix with several different roles. Besides the contribution to the tissue hydration, mechanical properties and correct architecture, hyaluronan plays important biological functions interacting with different molecules and receptors.

Scope of review

The review addresses the control of hyaluronan synthesis highlighting the critical role of hyaluronan synthase 2 in this context as well as discussing the recent findings related to covalent modifications which influence the enzyme activity. Moreover, the interactions with specific receptors and hyaluronan are described focusing on the importance of polymer size in the modulation of hyaluronan signaling.

Major conclusions

Due to its biological effects on cells recently described, it is evident how hyaluronan is to be considered not only a passive component of extracellular matrix but also an actor involved in several scenarios of cell behavior.

General significance

The effects of metabolism on the control of hyaluronan synthesis both in healthy and pathologic conditions are critical and still not completely understood. The hyaluronan capacity to bind several receptors triggering specific pathways may represent a valid target for new approach in several therapeutic strategies. This article is part of a Special Issue entitled Matrix-mediated cell behaviour and properties.     

α-Crystallin protects RGC survival and inhibits microglial activation after optic nerve crush

Aims

Activation of retinal microglial cells (RMCs) is known to contribute to retinal ganglion cell (RGC) death after optic nerve injury. The purpose of this study was to investigate the effects of intravenous injection of α-crystallin on RGC survival and RMC activation in a rat model of optic nerve crush.

Main methods

RGCs were retrogradely labeled with fluorogold. Rats were intravenously injected with normal saline or α-crystallin (0.05 g/kg, 0.5 g/kg, and 5 g/kg) at 2, 4, 6, 8, 10, and 12 days after the optic nerve crush. Activated RMCs were characterized using immunofluorescence labeling with CD11b, and TNF-α and iNOS expression was detected using immunoblot analyses. We analyzed the morphology and numbers of RGC and RMC 2 and 4 weeks after injury using fluorescence and confocal microscopy.

Key findings

The number of RGCs decreased after optic nerve injury, accompanied by significantly increased numbers of activated RMCs. Intravenous injection of α-crystallin decreased the number of RMCs, and enhanced the number of RGCs compared to saline injection. α-Crystallin administration inhibited TNF-α and iNOS protein expression induced by optic nerve injury.

Significance

Our results suggest that α-crystallin promotes RGC survival and inhibits RMC activation. Intravenous injection of α-crystallin could be a possible strategy for the treatment of optic nerve injury.     

Lignin-derived lignophenols attenuate oxidative and inflammatory damage to the kidney in streptozotocin-induced diabetic rats

Abstract

This study investigated the effects of lignin-derived lignophenols (LPs) on the oxidative stress and infiltration of macrophages in the kidney of streptozotocin (STZ)-induced diabetic rats. The diabetic rats were divided into four groups with 0%, 0.11%, 0.33% and 1.0% LP diets. The vehicle-injected controls were given a commercial diet. At 5 weeks, superoxide (O₂^?) production, macrophage kinetics, the degree of fibrosis in glomeruli and mRNA expression for monocyte chemoattractant protein-1 (MCP-1) were examined. The NADPH-stimulated O₂^? levels in the kidney of the diabetic rats treated with 1.0% LP were significantly lower than those in untreated diabetic rats. The number of macrophages, levels of MCP-1 mRNA expression and degree of glomerular fibrosis increased in untreated LP and these levels were significantly lower in 1.0%LP-treated rats. The results suggested that LPs suppress the excess oxidative stress, the infiltration and activation of macrophages and the glomerular expansion in STZ-induced diabetic kidneys.     

Hyaluronan fragments contribute to the ozone-primed immune response to lipopolysaccharide

Hyaluronan is a high-molecular mass component of pulmonary extracelluar matrix, and lung injury can generate a low-molecular mass hyaluronan (HA) fragment that functions as endogenous ligand to cell surface receptors CD44 and TLR4. This leads to activation of intracellular NF-κB signaling and proinflammatory cytokine production. Based on previous information that ozone exposure causes increased HA in bronchial alveolar lavage fluid and ozone pre-exposure primes immune response to inhaled LPS, we hypothesized that HA production during ozone exposure augments the inflammatory response to LPS. We demonstrate that acute ozone exposure at 1 part per million for 3 h primes the immune response to low-dose aerosolized LPS in C57BL/6J mice, resulting in increased neutrophil recruitment into the airspaces, increased levels of protein and proinflammatory cytokines in the bronchoalveolar lavage fluid, and increased airway hyperresponsiveness. Intratracheal instillation of endotoxin-free HA (25 μg) enhances the biological response to inhaled LPS in a manner similar to ozone pre-exposure. In vitro studies using bone marrow-derived macrophages indicate that HA enhances LPS responses measured by TNF-α production, while immunofluorescence staining of murine alveolar macrophages demonstrates that HA induces TLR4 peripheralization and lipid raft colocalization. Collectively, our observations support that ozone primes macrophage responsiveness to low-dose LPS, in part, due to HA-induced TLR4 peripheralization in lung macrophages.     

Hyaluronan in human malignancies

Hyaluronan, a major macropolysaccharide in the extracellular matrix of connective tissues, is intimately involved in the biology of cancer. Hyaluronan accumulates into the stroma of various human tumors and modulates intracellular signaling pathways, cell proliferation, motility and invasive properties of malignant cells. Experimental and clinicopathological evidence highlights the importance of hyaluronan in tumor growth and metastasis. A high stromal hyaluronan content is associated with poorly differentiated tumors and aggressive clinical behavior in human adenocarcinomas. Instead, the squamous cell carcinomas and malignant melanomas tend to have a reduced hyaluronan content. In addition to the stroma–cancer cell interaction, hyaluronan can influence stromal cell recruitment, tumor angiogenesis and epithelial–mesenchymal transition. Hyaluronan receptors, hyaluronan synthases and hyaluronan degrading enzymes, hyaluronidases, are involved in the modulation of cancer progression, depending on the tumor type. Furthermore, intracellular signaling and angiogenesis are affected by the degradation products of hyaluronan. Hyaluronan has also therapeutic implications since it is involved in multidrug resistance.     

Internalization of the Hyaluronan Receptor CD44 by Chondrocytes

Chondrocytes express CD44 as a primary receptor for the matrix macromolecule hyaluronan. Hyaluronan is responsible for the retention and organization of proteoglycan within cartilage, and hyaluronan-chondrocyte interactions are important for the assembly and maintenance of the cartilage matrix. Bovine articular chondrocytes were used to study the endocytosis and turnover of CD44 and the effects of receptor occupancy on this turnover. Matrix-intact chondrocytes exhibit approximately a 6% internalization of cell surface CD44 by 4 h. Treatment with Streptomyces hyaluronidase to remove endogenous pericellular matrix increased internalization to approximately 20% of cell surface CD44 at 4 h. This turnover could be partially inhibited by the addition of exogenous hyaluronan to these matrix-depleted chondrocytes. Cell surface biotin-labeled CD44 was internalized by chondrocytes and this internalization was decreased in the presence of hyaluronan. Colocalization of internalized CD44 and fluorescein-labeled hyaluronan in intracellular vesicles correlates with the previous results of receptor-mediated endocytosis pathway for the degradation of hyaluronan by acid hydrolases. Taken together, our results indicate that CD44 is internalized by chondrocytes and that CD44 turnover is modulated by occupancy with hyaluronan.     

Heparin interaction with a receptor on hyperglycemic dividing cells prevents intracellular hyaluronan synthesis and autophagy responses in models of type 1 diabetes

Previous studies and ongoing research indicate the importance of an interaction between a putative receptor on dividing cells in hyperglycemia and the non-reducing end motifs of heparin stored in mast cell secretory granules and how this interaction prevents activation of hyaluronan synthesis in intracellular compartments and subsequent autophagy. This suggests a new role for endosomal heparanase in exposing this cryptic motif present in the initial large heparin chains on serglycin and in the highly sulfated (NS) domains of heparan sulfate.     

Hyaluronan export by the ABC transporter MRP5 and its modulation by intracellular cGMP

Hyaluronan must be exported from its site of synthesis, the inner side of plasma membrane, to the extracellular matrix. Here, we identified the multidrug-associated protein MRP5 as the principle hyaluronan exporter from fibroblasts. The expression of the MRP5 (ABC-C5) transporter was silenced in fibroblasts using RNA interference, and a dose-dependent inhibition of hyaluronan export was observed. Hyaluronan oligosaccharides introduced into the cytosol competed with the export of endogenously labeled hyaluronan and the MRP5 substrate fluorescein. Because cGMP is a physiological substrate of MRP5, the intracellular concentrations of cGMP were modulated by the drugs 3-isobutyl-1-methylxanthin, propentofyllin, L-NAME, zaprinast, and bromo-cGMP, and the effects on hyaluronan export were analyzed. Increasing the cGMP levels inhibited hyaluronan export and decreasing it afforded higher concentrations of zaprinast to inhibit the export. Thus, cGMP may be a physiological regulator of hyaluronan export at the level of the export MRP5.     

Hyaluronan substratum holds mesenchymal stem cells in slow-cycling mode by prolonging G<Subscript>1</Subscript> phase

We examined, in vitro, whether hyaluronan induces slow cycling in placenta-derived mesenchymal stem cells (PDMSCs) by comparing cell growth on a hyaluronan-coated surface with cell growth on a tissue-culture polystyrene surface. The hyaluronan-coated surface significantly downregulated the proliferation of PDMSCs, more of which were maintained in the G₀/G₁ phases than were cells on the tissue-culture polystyrene surface. Both PKH-26 labeling and BrdU incorporation assays showed that most PDMSCs grown on a hyaluronan-coated surface duplicated during cultivation indicating that the hyaluronan-coated surface did not inhibit PDMSCs from entering the cell cycle. Mitotic synchronization showed that the G₁-phase transit was prolonged in PDMSCs growing on a hyaluronan-coated surface. Increases in p27^Kip1 and p130 were the crucial factors that allowed hyaluronan to lengthen the G₁ phase. Thus, hyaluronan might be a promising candidate for maintaining stem cells in slow-cycling mode by prolonging their G₁-phase transit. This work was supported by research grant NSC95-2745-B-006-003-MY2 from the National Science Council, Taiwan, and by Landmark Project Grant A25, funded by the Taiwan Ministry of Education, from National Cheng Kung University.     

The antioxidative effect of bone morphogenetic protein-7 against high glucose-induced oxidative stress in mesangial cells

Bone morphogenetic protein-7 (BMP-7) protects kidneys from diabetic nephropathy (DN), and high glucose (HG)-induced oxidative stress is involved in DN. We investigated the antioxidative ability of BMP-7 using HG-treated mesangial cells. We treated rat mesangial cells (RMCs) with recombinant human BMP-7 (rhBMP-7) and examined changes in reactive oxygen species (ROS) levels and intracellular signals in response to HG-induced oxidative stress. rhBMP-7 decreased the level of ROS in HG-treated RMCs. In contrast, lowering endogenous BMP-7 by siRNA or BMP receptor II (BMP-RII) by anti-BMP-RII antibodies increased the level of ROS in HG-treated RMCs. rhBMP-7 increased Smad-1,5,8 phosphorylation, decreased PKCζ and c-Jun N-terminal kinase (JNK) phosphorylation, and decreased fibronectin and collagen IV synthesis in HG-treated RMCs. In conclusion, we found that BMP-7 could protect mesangial cells from HG-induced oxidative stress by activating BMP-RII. The antioxidative activity of BMP-7 was primarily due to inhibition of PKCζ, JNK phosphorylation, and c-jun activation.     

Permeable FGF-1 Nuclear Localization Signal Peptide Stimulates DNA Synthesis in Various Cell Types but Is Cell-Density Sensitive and Unable to Support Cell Proliferation

An earlier report indicated that a 26-amino-acid peptide (SA), comprised of the nuclear localization signal (NLS) of fibroblast growth factor-1 (FGF-1) and a membrane-permeable peptide, was able to stimulate DNA synthesis after it was taken up by NIH3T3 fibroblasts. Here, we report that SA, but not a mutant with the NLS motif destroyed, induced DNA synthesis in BALB/c3T3 murine fibroblasts, human vascular endothelial (HUVE) cells, and primary cultured hepatocytes, although the activity was weaker than that of FGF-1. The kinetics of SA-induced DNA synthesis and G₁cyclin expression were similar to those elicited by FGF-1, indicating that SA induces cell cycle progression. Kinetic analysis also suggested that SA stimulates only a fraction of the DNA replication in BALB/c3T3 cells. At high cell densities, SA-induced G₁cyclin expression and DNA synthesis were more strongly inhibited than those induced by FGF-1. SA did not induce cell division in HUVE and BALB/c3T3 cells and did not interfere with FGF-1-stimulated proliferation of HUVE cells. These results indicate that SA is able to partially induce cell cycle progression through a contact-inhibition sensitive signaling pathway, but it is insufficient to support cell mitosis. We also suggest that signaling by SA does not interfere with that of FGF-1.     

Proliferating Cell Nuclear Antigen Bound to DNA Synthesis Sites: Phosphorylation and Association with Cyclin D1 and Cyclin A

Evidence is presented that association of proliferating cell nuclear antigen (PCNA) with nuclear chromatin in human fibroblasts is related to the phosphorylation status of the protein. Using a hypotonic lysis procedure to extract the soluble form of PCNA, it has been shown that the remaining nuclear-bound form, predominantly in S-phase cells, is highly phosphorylated. Cells in early G₁, or in G₂ + M phases, contain basal levels of the bound form of the protein that is only weakly phosphorylated. Using fractionated immunoprecipitation techniques, PCNA was found to be associated with cyclin A in both soluble and insoluble fractions. In contrast, association of PCNA with cyclin D1 was found in the soluble fraction, while no detectable levels were present in the insoluble fraction. Immunofluorescence labeling and flow cytometric analysis of the cell cycle distribution of cyclin D1 and cyclin A showed that, like PCNA, maximal levels of both proteins were bound to nuclear structures at the G₁/S phase boundary. These results suggest that binding of PCNA to DNA synthesis sites occurs after phosphorylation. Association with cyclin D1 and cyclin A might occur in a macromolecular complex assembled at the G₁/S phase boundary to drive activation of DNA replication factors.