Glucosamine increases hyaluronic acid production in human osteoarthritic synovium explants.

BACKGROUND: Glucosamine (GlcN) used by patients with osteoarthritis was demonstrated to reduce pain, but the working mechanism is still not clear. Viscosupplementation with hyaluronic acid (HA) is also described to reduce pain in osteoarthritis. The synthesis of HA requires GlcN as one of its main building blocks. We therefore hypothesized that addition of GlcN might increase HA production by synovium tissue. METHODS: Human osteoarthritic synovium explants were obtained at total knee surgery and pre-cultured for 1 day. The experimental conditions consisted of a 2 days continuation of the culture with addition of N-Acetyl-glucosamine (GlcN-Ac; 5 mM), glucosamine-hydrochloride (GlcN-HCl; 0.5 and 5 mM), glucose (Gluc; 0.5 and 5 mM). Hereafter HA production was measured in culture medium supernatant using an enzyme-linked binding protein assay. Real time RT-PCR was performed for hyaluronic acid synthase (HAS) 1, 2 and 3 on RNA isolated from the explants. RESULTS: 0.5 mM and 5 mM GlcN-HCl significantly increased HA production compared to control (approximately 2 - 4-fold), whereas GlcN-Ac had no significant effect. Addition of 5 mM Gluc also increased HA production (approximately 2-fold), but 0.5 mM Gluc did not. Gene expression of the HA forming enzymes HAS 1, 2 and 3 was not altered by the addition of GlcN or Gluc. CONCLUSION: Our data suggest that exogenous GlcN can increase HA production by synovium tissue and is more effective at lower concentrations than Gluc. This might indicate that GlcN exerts its potential analgesic properties through stimulation of synovial HA production.

Fructose intake as a risk factor for kidney stone disease.

Taylor and Curhan report that consumption of fructose is independently associated with an increased risk of incident kidney stones. What could be the mechanisms underlying the relation between fructose intake and stone risk? And how should we incorporate this finding into the dietary advice that we give to our patients to prevent kidney stone formation?

Proposed mechanisms in renal tubular crystal retention.

The production of concentrated urine inevitably leads to the precipitation of poorly soluble waste salts in the renal tubular fluid. These crystallization processes are physiologic and without consequences as long as all crystals are excreted with the urine. The retention of crystals in the renal tubules, however, may lead to tubular nephrocalcinosis. Here, we present a brief survey of the possible mechanisms involved in this process, which seems to depend predominantly on the presence of regenerating/(re)differentiating cells in the renal tubules. Crystal binding to the surface of these cells can be mediated by a number of luminal membrane molecules, including acidic fragment of nucleolin-related protein, annexin-II, osteopontin, and hyaluronan.

Effects of luminal oxalate or calcium oxalate on renal tubular cells in culture.

Oxalate or calcium oxalate crystal-induced tissue damage could be conducive to renal stone disease. We studied the response of renal proximal (LLC-PK1 and MDCK-II) and collecting (RCCD1 and MDCK-I) tubule cell lines to oxalate ions as well as to calcium oxalate monohydrate (COM) crystals. Cells grown on tissue culture plastic or permeable growth substrates were exposed to high (1 mM) and extremely high (5 and 10 mM) oxalate concentrations, or to a relatively large quantity of crystals (146 microg), after which cell morphology, prostaglandin E(2) (PGE(2)) secretion, [(3)H]thymidine incorporation, total cell numbers and various forms of cell death were studied. Morphological alterations, increased PGE(2) secretion, elevated levels of DNA synthesis and necrotic cell death were induced by extremely high, but not by high oxalate. Crystals were rapidly internalized by proximal tubular cells, which stimulated PGE(2) secretion and DNA synthesis and the release of crystal-containing necrotic cells from the monolayer. Crystals did not bind to, were not taken up by, and did not cause marked responses in collecting tubule cells. These results show that free oxalate is toxic only at supraphysiological concentrations and that calcium oxalate is toxic only to renal tubular cells that usually do not encounter crystals. Based on these results, it is unlikely that oxalate anions or calcium oxalate crystals are responsible for the tissue damage that may precede renal stone formation.

Identification of hyaluronan as a crystal-binding molecule at the surface of migrating and proliferating MDCK cells.

BACKGROUND: The adherence of calcium oxalate crystals to the renal tubule epithelium is considered a critical event in the pathophysiology of calcium nephrolithiasis. Calcium oxalate monohydrate (COM) crystals cannot adhere to the surface of a functional Madin-Darby canine kidney (MDCK) monolayer, but they bind avidly to the surface of proliferating and migrating cells. METHODS: To identify crystal-binding molecules (CBMs) at the surface of crystal-attracting cells, we applied metabolic labeling protocols in combination with differential enzymatic digestion and gel filtration, which was compared with [14C]COM crystal binding and confirmed by confocal microscopy. RESULTS: The indication that hyaluronan [hyaluronic acid (HA)] might act as a CBM in subconfluent cultures came from studies with glycosaminoglycan (GAG)-degrading enzymes. Subsequently, metabolic-labeling studies revealed that hyaluronidase cleaved significantly more radiolabeled glycoconjugates from crystal-attracting cells than from cells without affinity for crystals. During wound repair, crystal binding could be prevented by pretreating the healing cultures with hyaluronate lyase, an enzyme that specifically hydrolyzes HA. Binding to immobilized HA provided evidence that COM crystals physically can become associated with this polysaccharide. Finally, confocal microscopy demonstrated that fluorescently labeled HA binding protein (HABP) adhered to the surface of proliferating cells in subconfluent cultures as well as to cells involved in closing a wound, but not to cells in confluent monolayers. CONCLUSIONS: These results identify HA as binding molecule for COM crystals at the surface of migrating and proliferating MDCK cells.

Sialic acid and crystal binding.

BACKGROUND: We studied the role of cell surface sialic acid in the adherence of calcium oxalate monohydrate (COM) crystals to Madin-Darby canine kidney (MDCK) cells. METHODS: Studies were performed with undifferentiated (crystal-binding) cells in subconfluent cultures and maturated (noncrystal-binding) cells in confluent cultures. Lectins were used to study the emergence and abundance of oligosaccharides at the cell surface during epithelial development. The effect of neuraminidase treatment on crystal binding was studied with [14C]COM crystals, and the enzyme-induced release of cell surface-associated sialic acid molecules was monitored by labeling the cells metabolically with [3H]glucosamine. RESULTS: Binding studies with lectins derived from Maackia Amurensis II (MALII) and Sambucus Nigra (SNA) demonstrated that the cells expressed terminal sialic acids attached to penultimate galactose through alpha 2,3 and alpha 2,6 bonds at different stages of epithelial development. Neuraminidase treatment strongly reduced the affinity of the cell surface for COM crystals in subconfluent cultures. Nevertheless, neuraminidase cleaved more sialic acids from cells in confluent cultures than from those in subconfluent cultures. Peanut agglutinin (PNA), which binds only to sialylated terminal galactose units, adhered to developing but not to maturated cells, unless the latter were pretreated with neuraminidase. Both results indicate that the surface of maturated MDCK cells is more heavily sialylated than that of undifferentiated cells. Free sialic acid molecules showed little or no affinity for COM crystals and did not affect the adherence of the crystals to undifferentiated cells. CONCLUSIONS: There are at least two models that may explain these results. First, sialic acids are presented at the surface of immature cells in an orientation that specifically matches crystal surface characteristics favoring crystal-cell interactions. Second, sialic acid molecules are not directly associated with the crystals, but may be involved in the exposure of another crystal binding molecule at the cell surface.

Changing concepts in the aetiology of renal stones.

In the past two decades an increasing number of nephrolithiasis-related urinary proteins have been identified. This paper focuses on two of them, namely prothrombin fragment 1 and bikunin, members of the prothrombin and inter-alpha-trypsin inhibitor families of proteins, respectively. Besides their role as inhibitors of crystallization, these proteins are also involved in inflammation-mediated tissue repair. This is the basis for the concept that the response of renal tissue to injury might play an important role in the aetiology of kidney stones.

Attachment sites for particles in the urinary tract.

The adherence of crystals to the surface of renal tubule epithelial cells is one of the initial events in the development of nephrolithiasis. The accumulation of crystalline material in the kidney will sooner or later result in the formation of a stone. Calcium crystals occasionally are present in the urine of even healthy individuals, and mechanisms responsible for the selective attachment of crystals to the tubular epithelium of stone-forming individuals must exist. Although several types of cell surface molecules, including phosphatidylserine (PS) and sialic acid, have been proposed as receptors for crystals in the tubular system, the exact nature of these crystal-binding sites has not yet been revealed. Previously, it was demonstrated that calcium oxalate monohydrate crystals adhere to subconfluent, but not to confluent, Madin-Darby canine kidney-I cultures. This model was used here to investigate whether the surface of cells with affinity for crystals is enriched with one of the proposed crystal-binding molecules. Annexin V was used for the detection of PS at the cell surface, and Sambucus nigra lectin was used to reveal terminal sialic acid in a (alpha2,6) linkage to galactose units. FITC-annexin V binding studies showed that PS was not exposed at the surface of proliferating or growth-inhibited cells, unless they were pretreated with an apoptosis-inducing cytotoxic agent. Sambucus nigra lectin binding, of which the specificity was confirmed by blocking with N-acetylneuraminyl-lactose, demonstrated the abundant presence of (alpha2,6)-linked sialic acid residues at the cell surface of both subconfluent and confluent cultures. While these results seem to rule out a role for PS in the adherence of calcium oxalate monohydrate crystals to the surface of maturating Madin-Darby canine kidney-I cells, they question the role for cell surface-associated sialylated glycoconjugates in this process.

LLC-PK1 cells as a model system to study proximal tubule transport of water and other compounds relevant for renal stone disease.

LLC-PK1 cells were cultured on a permeable support in a two-compartment culture system. Confluent monolayers received an ultrafiltrate-like solution at the apical side and a plasma-like solution at the basolateral side. The distribution of various solutes, including phosphate, calcium, and oxalate over both compartments was measured in time. The transport of water was monitored by alterations in fluid concentrations of radiolabeled inulin. Bicarbonate, glucose, and phosphate were transported rapidly from the apical to basolateral side of the monolayer. Sodium and chloride were reabsorbed without major consequences for the osmolality in the apical and basal fluid. Calcium and potassium were also reabsorbed, but to a smaller extent than sodium. The luminal concentration of oxalate gradually increased to values that were at least three times higher (12.0+/-0.4 micromol/l) than those in the contraluminal fluid (3.8+/-0.1 micromol/l). However, since the luminal rise of oxalate completely matched the rise of inulin in the apical fluid this appeared to be the passive consequence of active water reabsorption rather than of net directed oxalate transport. The LLC-PK1 model could prove useful to study the regulation of proximal tubule water transport and its effect on luminal stone salt concentrations under different physiological conditions.

Cell type-specific acquired protection from crystal adherence by renal tubule cells in culture.

BACKGROUND: Adherence of crystals to the surface of renal tubule epithelial cells is considered an important step in the development of nephrolithiasis. Previously, we demonstrated that functional monolayers formed by the renal tubule cell line, Madin-Darby canine kidney (MDCK), acquire protection against the adherence of calcium oxalate monohydrate crystals. We now examined whether this property is cell type specific. The susceptibility of the cells to crystal binding was further studied under different culture conditions. METHODS: Cell-type specificity and the influence of the growth substrate was tested by comparing calcium oxalate monohydrate crystal binding to LLC-PK1 cells and to two MDCK strains cultured on either permeable or impermeable supports. These cell lines are representative for the renal proximal tubule (LLC-PK1) and distal tubule/collecting duct (MDCK) segments of the nephron, in which crystals are expected to be absent and present, respectively. RESULTS: Whereas relatively large amounts of crystals adhered to subconfluent MDCK cultures, the level of crystal binding to confluent monolayers was reduced for both MDCK strains. On permeable supports, MDCK cells not only obtained a higher level of morphological differentiation, but also acquired a higher degree of protection than on impermeable surfaces. Crystals avidly adhered to LLC-PK1 cells, irrespective of their developmental stage or growth substrate used. CONCLUSIONS: These results show that the prevention of crystal binding is cell type specific and expressed only by differentiated MDCK cells. The anti-adherence properties acquired by MDCK cells may mirror a specific functional characteristic of its in situ equivalent, the renal distal tubule/collecting ducts.

Increased calcium oxalate monohydrate crystal binding to injured renal tubular epithelial cells in culture.

The retention of crystals in the kidney is considered to be a crucial step in the development of a renal stone. This study demonstrates the time-dependent alterations in the extent of calcium oxalate (CaOx) monohydrate (COM) crystal binding to Madin-Darby canine kidney (MDCK) cells during their growth to confluence and during the healing of wounds made in confluent monolayers. As determined by radiolabeled COM crystal binding studies and confirmed by confocal-scanning laser microscopy, relatively large amounts of crystals (10.4 +/- 0.4 micrograms/cm2) bound to subconfluent cultures that still exhibited a low transepithelial electrical resistance (TER < 400 omega.cm2). The development of junctional integrity, indicated by a high resistance (TER > 1,500 omega.cm2), was followed by a decrease of the crystal binding capacity to almost undetectable low levels (0.13 +/- 0.03 microgram/cm2). Epithelial injury resulted in increased crystal adherence. The highest level of crystal binding was observed 2 days postinjury when the wounds were already morphologically closed but TER was still low. Confocal images showed that during the repair process, crystals selectively adhered to migrating cells at the wound border and to stacked cells at sites were the wounds were closed. After the barrier integrity was restored, crystal binding decreased again to the same low levels as in undamaged controls. These results indicate that, whereas functional MDCK monolayers are largely protected against COM crystal adherence, epithelial injury and the subsequent process of wound healing lead to increased crystal binding.

Cell cultures and nephrolithiasis.

While the physical chemistry of stone formation has been intensively studied during the last decade, it has become clear that the pathophysiology of renal stone disease cannot be explained by crystallization processes only. In recent years, evidence has emerged that the cells lining the renal tubules can have an active role in creating the conditions under which stones may develop. Since it is difficult to study these mechanisms in vivo, cultured renal tubular cells have become increasingly popular for the study of physiological and cell biological processes that are possibly linked to stone disease. In this paper, we discuss the possible contribution of cellular processes such as transepithelial oxalate transport and crystal--cell interaction to the formation of renal stones. Experimental studies that have been performed with cultured renal cells to elucidate the mechanisms involved in these processes will be summarized.

Does urinary oxalate interfere with the inhibitory role of glycosaminoglycans and semisynthetic sulfated polysaccharides in calcium oxalate crystallization?

OBJECTIVES: Previously it was shown that the polysaccharide G872 in vitro strongly inhibits calcium oxalate monohydrate crystallization processes. However, when rats on a stone-inducing diet of ethylene glycol plus vitamin D3 are given this polysaccharide, no changes in the urine capacity for crystallization inhibition were found. We investigated here how the inhibitory action of polysaccharides changes under high oxalate conditions, as they exist in the stone inducing diet. METHODS: Calcium oxalate monohydrate (COM) crystals were incubated in a series of 0.05 M PBS buffers containing polysaccharides with increasing oxalate concentrations (0-0.4 mmol/l). The coated crystals were collected, washed and resuspended in an artificial urine. We then measured the zeta potential of the crystals, using a Coulter DELSA 440, and the initial rates for crystal growth and agglomeration, using the Coulter Multisizer II. RESULTS: Addition of oxalate to the medium shifts the negative zeta potential distribution of COM crystals coated by polysaccharides in positive direction. Particle size analysis demonstrated that the initial rates of COM crystal growth and agglomeration responding to oxalate concentration changes (0.1-->0.4 mmol/l) in the presence of G872 (0.2 mg/l) are approximately 2.5 times faster than that in the absence of G872. CONCLUSIONS: Oxalate interferes with the binding of polysaccharides to crystals. This can be envisioned to occur through changes in the crystal surface properties or by induction of functional and secondary structural changes of urinary macromolecular inhibitors such as GAGs, resulting in a decrease of their inhibitory activity against COM crystallization. Thus, in urine, a high oxalate may increase the rate of crystallization both by increasing the supersaturation and by decreasing the inhibitory potential of the urine.

Ultrastructural osteopontin localization in papillary stones induced in rats.

OBJECTIVES: To detect in situ the precise osteopontin (OPN) localization in papillary stones. METHODS: Immunocytochemical labelling procedures are applied to detect OPN localizations in crystalline material of renal papillary stones. The tissue-processing procedure for electron microscopy, which includes OsO4 postfixation, preserves both immunocytochemical OPN reactivity and cellular membrane contrast up to the ultrathin section. Reflection-contrast light microscopical images are correlated with high resolution transmission-electron microscopical observations from consecutive ultrathin epon sections. RESULTS: Preserved crystalline material in interstitial and peripheral papillary stones is recognized as calcium oxalate monohydrate. After section incubation with markers conjugated to an antibody against OPN (alpha OPN) the crystals are converted into ghosts. In the ghosts, alpha OPN markers are present around microcrystals. The size of these microcrystals ranges from several nanometers to micrometers. It is observed (due to the OsO4-preserved membranes) that interstitial cells are separated from the stone surfaces by unidentified extracellular material, also present in the center as a stone matrix. CONCLUSION: The microcrystal-growth inhibitor OPN is detected in situ in interstitial stones induced in the rat's papilla and at the surface of the papilla.

Crystal-cell interaction inhibition by polysaccharides.

PURPOSE: We studied the effect of polysaccharides on interactions between calcium oxalate monohydrate (COM) crystals and cultured renal cells. MATERIALS AND METHODS: Monolayers of Madin-Darby canine kidney (MDCK) cells were incubated with radiolabeled crystals in the presence of various concentrations of natural glycosaminoglycans (GAGs) and semisynthetic polysaccharides (SSPs). RESULTS: While most GAGs were found to have relatively little effect, SSPs (SP54, G871 and G872) were potent inhibitors of crystal-cell association. Pretreatment of crystals, but not of cells, was similarly effective, suggesting polysaccharide-induced modification of crystal surface properties. CONCLUSIONS: This result further supports the idea that SSPs, and especially G872, are of potential interest for treatment of recurrent stone disease.

Oxalate transport and calcium oxalate renal stone disease.

Hyperoxaluria is considered to play a crucial role in calcium oxalate (CaOx) renal stone disease. The amount of oxalate excreted into the urine depends on intestinal absorption, endogenous production, renal clearance and renal tubular transport. Since a primary disorder has not been found so far in most CaOx stone formers and since oxalate is freely filtered at the glomerulus, most studies are presently focussed on alterations in epithelial oxalate transport pathways. Oxalate can be transported across an epithelium by the paracellular (passive) and transcellular (active) pathway. Oxalate transport across cellular membranes is mediated by anion-exchange transport proteins. A defect in the structure of these transport proteins could explain augmented transcellular oxalate transport. Little is known about the physiological regulation of oxalate transport. In this review cellular transport systems for oxalate will be summarized with special attention for the progress that has been made to study oxalate transport in a model of cultured renal tubule cells. Better understanding of the physiological processes that are involved in oxalate transport could yield information on the basis of which it might be possible to design new approaches for an effective treatment of CaOx stone disease.

Zeta potential measurement and particle size analysis for a better understanding of urinary inhibitors of calcium oxalate crystallization.

To better understand urinary inhibitors of calcium oxalate crystallization, both zeta potential measurement and particle size analysis were chosen to illustrate: (1) the potential therapeutic efficacy of G872, a semi-synthetic sulfated polysaccharide, in stone prevention; and (2) the relative contribution of various urinary fractions ¿e.g., ultrafiltered urine (UFU), Tamm-Horsfall protein (THP), urinary polyanions precipitated with cetylpyridinium chloride (CPC), urinary macromolecular substances with different concentration ratios (UMS10,50,90 and UMS'10,50,90) and THP-free urine (THPFU)¿ to total urinary inhibitory activity. The results showed: (1) addition of G872 significantly enhances urinary inhibitory activity and negative zeta potential values; (2) re-addition of the CPC to UFU completely restores urinary inhibitory activity; and (3) artificial urines prepared by mixing UMS'10,50,90 from THPFU with UFU differed in inhibitory activity from that prepared by mixing UMS10,50,90 from a pooled normal urine with UFU. Based on these experimental results, the following speculations can be made: (1) normal human urines are considered to be a protective colloidal system; (2) urinary inhibitory activity originates mainly from CPC and/or UMS; (3) normal THP is a protective material to maintain urinary inhibitory activity; and (4) mutual interaction between urinary inhibitors may change the total urinary inhibitory activity.

Lectin-cytochemistry of experimental rat nephrolithiasis.

Lectin reactivity in epithelial apical cell coats of normal rat kidneys was compared to that from animals subjected to crystal inducing diets (CID). The aim was to see whether the absence of lectin reactivity in cell coats is related to intratubular calcium oxalate crystal retention. In normal rat kidneys, after a pre-embedding procedure, it was observed that at the ultrastructural level, reactivity was present but that the lectin specificity for the various parts of the nephron might have to be reconsidered. There was heterogeneity between the epithelial cells with respect to the presence of coat material in the tubular cell apices. Tubular epithelial cell apices from CID rats showed no obvious changes in lectin reactivity pattern. Lectin reactivity was present at the periphery of intratubular crystals but undetectable at true crystal attachment sites or reduced at cell apices in the vicinity of recently attached crystals or agglomerates. After a post-embedding reaction procedure, wheat-germ agglutinin (WGA)-lectin reactivity confirmed the presence of coat material in the cleft between cell apex and retained crystal at crystal-attachment sites. The WGA/Au-10 nm reaction products were also seen inside epithelial cells. WGA/Au-10 nm reaction products mark a crystal matrix component inside intratubular and retained crystals. A similar matrix was also marked by an alpha-osteopontin (alpha OPN/Au-10 nm) reaction product.

Association of calcium oxalate monohydrate crystals with MDCK cells.

Many factors are presently known which determine the risk of calcium oxalate (CaOx) stone formation in the kidney, although the early events in the pathogenesis of this disease are still to be elucidated. One of these early events is the interaction of intraluminal crystals with the epithelial cells lining the renal tubules. In this study we determined the interaction of approximately 2 microns calcium oxalate monohydrate (COM) crystal with monolayers of Madin-Darby canine kidney (MDCK) cells grown on porous supports in a two-compartment culture system. Crystal-cell interaction studies were performed after the monolayers reached their highest level of gamma-glutamyltranspeptidase (gamma GT) enzyme activity, a marker for brush border development. Technical aspects were evaluated, such as the size and morphology of the crystals and the influence of incubation time, temperature and pH on crystal-cell interaction. Kinetic data demonstrated that an equilibrium between free and associated particles was reached within 30 minutes. Crystal-cell interaction was often associated with cell damage. However, evidence is provided that in an environment that was saturated with calcium oxalate, MDCK cells in an environment that was a certain amount of COM crystals without sustaining measurable injury. After initial attachment to the cell surface, crystals were taken up and subsequently eliminated again from the monolayers. The model system described in this paper provides a tool for detailed studies of processes that are involved in renal cellular handling of luminal COM crystals.

Etiology of calcium oxalate nephrolithiasis in rats. I. Can this be a model for human stone formation?

Crystal retention is studied in a rat-model system as a possible mechanism for the etiology of human nephrolithiasis. A crystal-inducing diet (CID) of ethylene glycol plus NH4Cl in their drinking-water is offered to healthy rats to generate intratubular crystals. Subsequently, the fate of retained crystals is investigated by allowing the rats a tissue recovery/crystalluria phase for three, five and ten days, respectively, on normal drinking water. The process of exotubulosis is observed in cortex and medulla of aldehyde-fixed kidneys after three days recovery. After five days, crystals are predominantly seen there in the interstitium. After ten days, cortex and medulla are virtually free of crystals. However, in the papillary regions after five and ten days recovery, three types of calcium oxalate monohydrate (COM) crystals are present: (1) free in the calycine space, (2) sub-epithelially located surrounded by interstitial cells within, and (3) covered by macrophage-like cells, outside the original papillary surface. After a CID plus three days recovery, a further thirty-seven days extra oxalate challenge with solely 0.3 vol% ethylene glycol induced intratubular and interstitial oxalate crystals. In the papillary region, large sub-epithelial crystals are seen. However, no crystals are seen in kidneys from rats given solely (0.5 or 0.8 vol.%) ethylene glycol for thirty days. An oxalate re-challenge retards crystal removal.