Modulation of Calcium Oxalate Dihydrate Growth by Selective Crystal-face Binding of Phosphorylated Osteopontin and Polyaspartate Peptide Showing Occlusion by Sectoral (Compositional) Zoning

Calcium oxalate dihydrate (COD) mineral and the urinary protein osteopontin/uropontin (OPN) are commonly found in kidney stones. To investigate the effects of OPN on COD growth, COD crystals were grown with phosphorylated OPN or a polyaspartic acid-rich peptide of OPN (DDLDDDDD, poly-Asp^86–93). Crystals grown with OPN showed increased dimensions of the {110} prismatic faces attributable to selective inhibition at this crystallographic face. At high concentrations of OPN, elongated crystals with dominant {110} faces were produced, often with intergrown, interpenetrating twin crystals. Poly-Asp^86–93 dose-dependently elongated crystal morphology along the {110} faces in a manner similar to OPN. In crystal growth studies using fluorescently tagged poly-Asp^86–93 followed by imaging of crystal interiors using confocal microscopy, sectoral (compositional) zoning in COD was observed resulting from selective binding and incorporation (occlusion) of peptide exclusively into {110} crystal sectors. Computational modeling of poly-Asp^86–93 adsorption to COD {110} and {101} surfaces also suggests increased stabilization of the COD {110} surface and negligible change to the natively stable {101} surface. Ultrastructural, colloidal-gold immunolocalization of OPN by transmission electron microscopy in human stones confirmed an intracrystalline distribution of OPN. In summary, OPN and its poly-Asp^86–93 sequence similarly affect COD mineral growth; the {110} crystallographic faces become enhanced and dominant attributable to {110} face inhibition by the protein/peptide, and peptides can incorporate into the mineral phase. We, thus, conclude that the poly-Asp^86–93 domain is central to the OPN ability to interact with the {110} faces of COD, where it binds to inhibit crystal growth with subsequent intracrystalline incorporation (occlusion).Calcium oxalate is the major mineral phase of human renal calculi, constituting roughly 70% by weight of the stones (1). Two polymorphs of calcium oxalate, calcium oxalate monohydrate (COM)³ and calcium oxalate dihydrate (COD), are the most abundant mineral types, but others may exist in smaller amounts, including calcium phosphate minerals. It has been reported that the occurrence of COM, the more thermodynamically stable polymorph of calcium oxalate, is often at the core of most kidney stones and is approximately twice as frequent as COD (2), although both crystal types typically exist to some degree in most stones (3, 4). COM is commonly found in the urine of “stone formers,” but seldom is seen in healthy urine; on the other hand, COD crystals are typically found in the urine of both healthy people and stone formers and are routinely excreted during urination (5–7). Importantly, in patients with severe uremia and hypercalciuria, elongated, large rod-shaped COD crystals are not only often observed but are the sole mineral phase present in the kidneys in these pathologies (8, 9).In comparing physiologic differences between calcium oxalate polymorphs, one study has shown that for a given amount of added crystals, ∼50% more COM than COD crystals bound to inner medullary collecting duct cells in vitro (10). Other studies have reported that COD crystals are less prone than COM crystals to adhere to cell surfaces, suggesting that COD might, thus, contribute to a lesser degree than COM to the retention of mineral in the renal collecting ducts leading to kidney stone formation (5, 11). This is supported by the fact that COM crystals are large cationic particulates, presenting more calcium ions than COD crystals at their surface that would have a stronger affinity for anionic molecules on renal epithelial cell membranes (10, 12). Further to this, COM and COD crystals bind to cultured renal cells with different face-selective affinities (13–16), and COM crystals are known to be more injurious to cell membranes than COD crystals (17). In this regard, Wesson et al. (1) proposed that the preferential formation of COD crystals in vivo protects against urolithiasis because they are less likely to adhere to renal tubular cells and are, thus, more readily excreted. This notion is supported by direct experimental measurements of the macromolecular adhesion force on specific crystal faces of COM or COD at the near-molecular level (13, 14). Given this, conversely, inhibition of the formation of COD crystals could lead to preferential COM deposition and the formation of kidney stones.Although calcium and oxalate ionic concentrations are frequently supersaturated with respect to both COM and COD mineral polymorphs, normal human urine likely contains factors that can modulate calcium oxalate crystallization into COD (10). In this context the presence of urinary macromolecular inhibitors of crystal growth can cause preferential crystallization of COD, rather than COM, from a supersaturated solution of calcium chloride and sodium oxalate (10). Substantial elegant work has been performed on COM growth and the effect of citrate and peptides/proteins as crystal growth modifiers. Some macromolecules, including urinary osteopontin (OPN), contain polyanionic regions and net negative charges that have been shown to inhibit calcium oxalate crystallization (14, 18–21) and influence calcium oxalate growth in favor of COD (3, 10, 22, 23). Although there appears to be preferential inhibition of COM, several studies present evidence for higher affinity of OPN binding to COD, and here we investigate this further to show the effects of OPN (and a peptide of OPN) on COD crystal growth and provide information on peptide/protein occlusion that might facilitate crystal dissolution as originally proposed by Ryall et al. (see below) (23, 24).OPN is a highly acidic, glycosylated phosphoprotein produced by many types of epithelial cells and can be found in normal plasma and in various body fluids such as bile, urine, and milk (25, 26). In normal kidneys, OPN is secreted by the thin and thick ascending limbs of the loop of Henle and distal nephrons (27–32). OPN contains a 15–20% aspartic acid residue content, and the mineral binding and inhibitory properties of OPN have often been partly attributed to an aspartic acid-rich sequence within this protein (10, 26, 33, 34). Likewise, post-translational phosphorylation of OPN has been shown to markedly enhance the mineral binding and inhibitory ability of this protein (34, 35). Furthermore, OPN also contains sialic acid (26, 27), which may play an indirect role in crystal binding by forming a bridge between transiently expressed crystal binding molecules and the cell surface (12). Several studies have shown that OPN has a higher affinity for COD than COM in normal urinal precipitates, with some evidence given for the incorporation of protein into calcium oxalate crystals (1, 23, 36).OPN consistently localizes to kidney stones (37) and at physiologically relevant concentrations applied in vitro, acts as a potent inhibitor of the nucleation, growth, and aggregation of calcium oxalate crystals (27, 30, 34). In a rat model of urolithiasis, although increased OPN mRNA expression was associated with increased renal calculi formation, the urinary excretion level of OPN was less than in controls, discussed as being attributable to incorporation of OPN into stones (37, 38). In general, the inclusion of OPN plus other urinary macromolecules into renal calculi has been suggested to be part of a cellular defense mechanism designed to inhibit crystal growth and limit the growth of kidney stones, to interrupt inorganic crystal structure of the calcium oxalate minerals, and to provide an organic volume whose degradation by permeating proteases creates channels facilitating dissolution of the mineral phase (23, 24). Given these possibilities, our aim was to determine whether full-length phosphorylated OPN and a poly-Asp peptide of OPN affect COD crystal growth and morphology, and if so, we further aimed to identify the contribution of face-specific binding and intracrystalline incorporation (occlusion) of OPN peptide into COD. Combining experimental and computational approaches, we have identified preferential binding and unique occlusion of a peptide of OPN at a specific crystallographic face of COD. Furthermore, we present a possible adsorption mechanism in a model where multiple peptide carboxylate groups bind calcium atoms at the COD {110} surface. Taken together, our findings provide new information on the pathogenesis of renal calculi by describing specific actions of phosphorylated full-length OPN and a short peptide sequence of OPN (not having post-translational modifications) on specific COD crystal faces that modulate calcium oxalate growth and crystal morphologies.     

Effects of surface-bound water and surface stereochemistry on cell adhesion to crystal surfaces

Crystals of calcium-(R,S)-tartrate trihydrate were used as adhesion substrates (for A6 epithelial cells), to study specific stages in cell adhesion. Events such as surface recognition, cell attachment, spreading, motility, cell-cell aggregation, and cell penetration into the crystal bulk are all shown to depend on the molecular structure of the various crystal faces. These crystals exhibit three chemically equivalent, yet structurally distinct, faces. On the {100}, a layered surface exposing bound water, the cells attach, are motile, and tend to form multicellular aggregates, but do not spread and do not form focal contacts. Following prolonged incubation, single cells attached to the {100} surface undergo apoptosis, while those interacting with other cells are rescued. Macroscopic spiral dislocations emerging on the {100} face of the crystal are highly adhesive for cells. Cells attached to these sites develop long protrusions that penetrate into the crystal. The {011} faces expose mainly hydroxyls attached to the chiral carbons. The cells interact extensively with these faces, are immobilized, do not spread, do not form focal contacts, and subsequently die. The faces belonging to the {0kl}? family are characterized by molecular and topographical steps. The cells attach to these faces, spread, and form focal contacts and stress fibers. Thus the molecular character of the crystal surfaces, including the presence of bound water, the exposure of determinants that promote rapid surface recognition, and the effective association with extracellular adhesive proteins, affect the patterns of cell adhesive behavior and fate.     

Characterization of hyaluronic acid interaction with calcium oxalate crystals: implication of crystals faces, pH and citrate

Interaction between hyaluronic acid (HA) present at the surface of tubular epithelial cells and calcium oxalate monohydrate (COM) crystals is thought to play an important role in kidney stone formation. AFM-based force spectroscopy, where HA is covalently attached to AFM-probes, was used to quantify the interaction between HA and the surfaces of COM crystals. The work of adhesion of the HA-probe as well as the rupture force of single HA molecules were quantified in order to understand the molecular regulation of HA binding to COM crystals. Our results reveal that HA adsorbs to the crystal surface in physiological conditions. We also observed increased adhesion when the pH is lowered to a value that increases the risk of kidney stone formation. HA adhesion to the COM crystal surface can be suppressed by citrate, a physiological inhibitor of stone retention currently used in the treatment and prevention of kidney stone formation. Interestingly, we also observed preferential binding of HA onto the [100] face versus the [010] face, suggesting a major contribution of the [100] faces in the crystal retention process at the surface of tubular epithelial cells and the promotion of stone formation. Our results clearly establish a direct role for the glycosaminoglycan HA present at the surface of kidney tubular epithelium in the process of COM crystal retention.     

Ultrastructural matrix-mineral relationships in avian eggshell, and effects of osteopontin on calcite growth in vitro

We investigated matrix–mineral relationships in the avian eggshell at the ultrastructural level using scanning and transmission electron microscopy combined with surface-etching techniques to selectively increase topography at the matrix–mineral interface. Moreover, we investigated the distribution of osteopontin (OPN) in the eggshell by colloidal-gold immunolabeling for OPN, and assessed the effects of this protein on calcite crystal growth in vitro. An extensive organic matrix network was observed within the calcitic structure of the eggshell that showed variable, region-specific organization including lamellar sheets of matrix, interconnected fine filamentous threads, thin film-like surface coatings of proteins, granules, vesicles, and isolated proteins residing preferentially on internal {1 0 4} crystallographic faces of fractured eggshell calcite. With the exception of the vesicles and granules, these matrix structures all were immunolabeled for OPN, as were occluded proteins on the {1 0 4} calcite faces. OPN inhibited calcite growth in vitro at the {1 0 4} crystallographic faces producing altered crystal morphology and circular growth step topography at the crystal surface resembling spherical voids in mineral continuity prominent in the palisades region of the eggshell. In conclusion, calcite-occluded and interfacial proteins such as OPN likely regulate eggshell growth by inhibiting calcite growth at specific crystallographic faces and compartmental boundaries to create a biomineralized architecture whose structure provides for the properties and functions of the eggshell.     

Cell-Adhesion to Crystal Surfaces: Adhesion-Induced Physiological Cell Death

Cultured epithelial cells interact massively, rapidly and stereospecifically with the {011} faces of calcium (R,R)-tartrate tetrahydrate crystals. It was suggested that the massive rapid adhesion represents an exaggerated and isolated form of the first initial events in the attachment of cultured cells to conventional tissue culture surfaces (Hanein, et al., Cells and Materials, 5, 197–210: 1995). Attachment is however not followed by normal cell spreading and development of focal adhesions, but results in massive cell death. In this study, the fate of the crystal-bound cells was characterized by electron microscopy, flow cytometry and microscopic morphometry and was found to display the characteristics of physiological cell death. We show that the direct interaction with the highly homogenous and repetitive {011} faces per se does not trigger the transduction of lethal transmembrane signals. We suggest that the excessive direct interactions between the cell membrane and the crystal. by impairing cell motion, prevent the evolution of RGD-dependent cell adhesion. This implies that the deprivation of proper extracellular matrix (ECM)-receptor contacts of substrate-attached epithelial cells eventually triggers physiological cell death.     

Surface heat shock protein 90 serves as a potential receptor for calcium oxalate crystal on apical membrane of renal tubular epithelial cells

Adhesion of calcium oxalate monohydrate (COM) crystals on renal tubular epithelial cells is a crucial step in kidney stone formation. Finding potential crystal receptors on the apical membrane of the cells may lead to a novel approach to prevent kidney stone disease. Our previous study identified a large number of crystal-binding proteins on the apical membrane of MDCK cells. However, their functional role as potential crystal receptors had not been validated. The present study aimed to address the potential role of heat shock protein 90 (HSP90) as a COM crystal receptor. The apical membrane was isolated from polarized MDCK cells by the peeling method and recovered proteins were incubated with COM crystals. Western blot analysis confirmed the presence of HSP90 in the apical membrane and the crystal-bound fraction. Immunofluorescence staining without permeabilization and laser-scanning confocal microscopy confirmed the surface HSP90 expression on the apical membrane of the intact cells. Crystal adhesion assay showed that blocking surface HSP90 by specific anti-HSP90 antibody and knockdown of HSP90 by small interfering RNA (siRNA) dramatically reduced crystal binding on the apical surface of MDCK cells (by approximately 1/2 and 2/3, respectively). Additionally, crystal internalization assay revealed the presence of HSP90 on the membrane of endocytic vesicle containing the internalized COM crystal. Moreover, pretreatment of MDCK cells with anti-HSP90 antibody significantly reduced crystal internalization (by approximately 1/3). Taken together, our data indicate that HSP90 serves as a potential receptor for COM crystals on the apical membrane of renal tubular epithelial cells and is involved in endocytosis/internalization of the crystals into the cells.     

Large-scale identification of calcium oxalate monohydrate crystal-binding proteins on apical membrane of distal renal tubular epithelial cells

Adhesion of calcium oxalate monohydrate (COM) crystals onto apical surface of renal tubular epithelial cells is a crucial mechanism for crystal retention, leading to kidney stone formation. Various proteins on apical membrane may bind to COM crystals; however, these crystal-binding proteins remained unidentified. The present study therefore aimed to identify COM crystal-binding proteins on apical membrane of distal renal tubular epithelial cells. Madin-Darby Canine Kidney (MDCK) cells were cultivated to be polarized epithelial cells and apical membrane was isolated from these cells using a peeling method established recently. Enrichment and purity of isolated apical membrane were confirmed by Western blot analysis for specific markers of apical (gp135) and basolateral (Na(+)/K(+)-ATPase) membranes. Proteins derived from the isolated apical membrane were then resuspended in artificial urine and incubated with COM crystals. The bound proteins were eluted, resolved by SDS-PAGE, and analyzed by Q-TOF MS and MS/MS, which identified 96 proteins. Among these, expression and localization of annexin II on apical surface of MDCK cells were confirmed by Western blot analysis, immunofluorescence staining, and laser-scanning confocal microscopic examination. Finally, the function of annexin II as the COM crystal-binding protein was successfully validated by COM crystal-binding assay. This large data set offers many opportunities for further investigations of kidney stone disease and may lead to the development of new therapeutic targets.     

Nucleation of calcium oxalate crystals on an imprinted polymer surface from pure aqueous solution and urine

Calcium oxalate (CaOx) is the most common component of human kidney stones. Heterogeneous nucleation is regarded as the key mechanism in this process. In this study, we have used an imprinted 6-methacrylamidohexanoic acid/divinylbenzene co-polymer as a biomimetic surface to nucleate CaOx crystal formation. The polymer was imprinted with either calcium oxalate monohydrate (COM) or dihydrate (COD) template crystals. These were washed out of the polymer, which was then immersed in various test solutions. The test solutions were an aqueous solution of calcium chloride and sodium oxalate, artificial urine and a sample of real urine. Crystals that formed on the polymer surface were characterized by X-ray powder diffraction, Fourier transform infrared spectroscopy, atomic absorption spectroscopy and scanning electron microscopy. Results showed that in the aqueous solution the COM-imprinted polymer induced the nucleation of COM. The COD-imprinted polymer induced only trace amounts of COD crystallization, together with larger quantities of COM. In artificial and real urines, COM also specifically precipitated on the COM-imprinted surface. The results show that, at least to some extent, the imprinted polymers direct formation of their morphologically matched crystals. In the case of COD, however, it appears that either rapid hydrate transformation of COD to COM occurs, or the more stable COM polymorph is directly co-precipitated by the polymer. Our results support the hypothesis that heterogeneous nucleation plays a key role in CaOx stone formation and that the imprinted polymer model could provide an additional and superior diagnostic tool for stone researchers to assess stone-risk in urine.Abbreviations COD calcium oxalate dihydrate - COM calcium oxalate monohydrate - COT calcium oxalate trihydrate - dvb divinylbenzene - 6-maaha 6-methylacrylamidohexanoic acid     

Roles of Electrostatics and Conformation in Protein-Crystal Interactions

In vitro studies have shown that the phosphoprotein osteopontin (OPN) inhibits the nucleation and growth of hydroxyapatite (HA) and other biominerals. In vivo, OPN is believed to prevent the calcification of soft tissues. However, the nature of the interaction between OPN and HA is not understood. In the computational part of the present study, we used molecular dynamics simulations to predict the adsorption of 19 peptides, each 16 amino acids long and collectively covering the entire sequence of OPN, to the {100} face of HA. This analysis showed that there is an inverse relationship between predicted strength of adsorption and peptide isoelectric point (P<0.0001). Analysis of the OPN sequence by PONDR (Predictor of Naturally Disordered Regions) indicated that OPN sequences predicted to adsorb well to HA are highly disordered. In the experimental part of the study, we synthesized phosphorylated and non-phosphorylated peptides corresponding to OPN sequences 65–80 (pSHDHMDDDDDDDDDGD) and 220–235 (pSHEpSTEQSDAIDpSAEK). In agreement with the PONDR analysis, these were shown by circular dichroism spectroscopy to be largely disordered. A constant-composition/seeded growth assay was used to assess the HA-inhibiting potencies of the synthetic peptides. The phosphorylated versions of OPN65-80 (IC₅₀ = 1.93 µg/ml) and OPN220-235 (IC₅₀ = 1.48 µg/ml) are potent inhibitors of HA growth, as is the nonphosphorylated version of OPN65-80 (IC₅₀ = 2.97 µg/ml); the nonphosphorylated version of OPN220-235 has no measurable inhibitory activity. These findings suggest that the adsorption of acidic proteins to Ca²⁺-rich crystal faces of biominerals is governed by electrostatics and is facilitated by conformational flexibility of the polypeptide chain.     

Ultrastructure of lamellae, mineral and matrix components of fish otolith twinned aragonite crystals: implications for estimating age in fish

Atomic force microscopy (AFM) of the crystalline ultrastructure of otoliths fromPagrus major(Sparidae),Macruronus novaezelandiae(Merlucciidae),Oncorhynchus tshawytscha(Salmonidae),Sebastes alutus(Scorpaenidae), andHoplostethus atlanticus(Trachichthyidae) showed regular deposition of lamellae in the size range 13-490 nm. The orientation of lamellae in the {010} plane was the same as lamellae in crystals of mineral aragonite. Lamellae in mineral aragonite were in the size range 15-45 nm. Lamellae observed in the otolith ofM. novaezelandiaeby transmission electron microscopy showed a range of widths (25-225 nm) similar to lamellae observed by AFM. The observed lamella widths were in the size range that has been described for sub-daily and daily microincrements in otoliths. Observed lamellae widths were also in the size range of alpha-recoil trajectories of(222)Rn and provide a potential diffusion sink correction for the(222)Rn losses in radionuclide method of ageing otoliths. Comparison of the orientations of lamellae to templates based on the Bragg unit cell structure of twinned aragonite indicated that the lamellae resulted from polysynthetic twinning on the {010} aragonite crystal face. Additional cyclic twinning occurred on the {110} face of the aragonite crystal and sometimes led to pseudohexagonal crystals, whose sizes were orders of magnitude larger than lamellae. The organic matrix of the otolith was visible by atomic force and transmission electron microscopy at the nanometer level of resolution, but the organic matrix was confined to the {110} twinning plane of symmetry of the otolith crystal.     

Macromolecular impurities and disorder in protein crystals.

The mechanisms by which macromolecular impurities degrade the diffraction properties of protein crystals have been investigated using X-ray topography, high-resolution diffraction line shape measurements, crystallographic data collection, chemical analysis, and two-photon excitation fluorescence microscopy. Hen egg-white lysozyme crystals grown from solutions containing a structurally unrelated protein (ovotransferrin) and a related protein (turkey egg-white lysozyme) can exhibit significantly broadened mosaicity due to formation of cracks and dislocations but have overall B factors and diffraction resolutions comparable to those of crystals grown from uncontaminated lysozyme. Direct fluorescence imaging of the three-dimensional impurity distribution shows that impurities incorporate with different densities in sectors formed by growth on different crystal faces, and that impurity densities in the crystal core and along boundaries between growth sectors can be much larger than in other parts of the crystal. These nonuniformities create stresses that drive formation of the defects responsible for the mosaic broadening. Our results provide a rationale for the use of seeding to obtain high-quality crystals from heavily contaminated solutions and have implications for the use of crystallization for protein purification. Proteins 1999;36:270-281.     

Macropinocytosis is the Major Mechanism for Endocytosis of Calcium Oxalate Crystals into Renal Tubular Cells

During an initial phase of kidney stone formation, the internalization of calcium oxalate (CaOx) crystals by renal tubular cells has been thought to occur via endocytosis. However, the precise mechanism of CaOx crystal endocytosis remained unclear. In the present study, MDCK renal tubular cells were pretreated with inhibitors specific to individual endocytic pathways, including nystatin (lipid raft/caveolae-mediated), cytochalasin D (actin-dependent or macropinocytosis), and chlorpromazine (CPZ; clathrin-mediated) before exposure to plain (non-labeled), or fluorescence-labeled CaOx monohydrate (COM) crystals. Quantitative analysis by flow cytometry revealed that pretreatment with nystatin and CPZ slightly decreased the crystal internalization, whereas the cytochalasin D pretreatment caused a marked decrease in crystal uptake. Immunofluorescence study and laser-scanning confocal microscopic examination confirmed that the cytochalasin D-pretreated cells had dramatic decrease of the internalized crystals, whereas the total number of crystals interacted with the cells was unchanged (crystals could adhere but were not internalized). These data have demonstrated for the first time that renal tubular cells endocytose COM crystals mainly via macropinocytosis. These novel findings will be useful for further tracking the endocytosed crystals inside the cells during the course of kidney stone formation.     

Application of spectral imaging microscopy in cytomics and fluorescence resonance energy transfer (FRET) analysis.

BACKGROUND: Specific signal detection has been a fundamental issue in fluorescence microscopy. In the context of tissue samples, this problem has been even more pronounced, with respect to spectral overlap and autofluorescence. METHODS: Recent improvements in confocal laser scanning microscopy combine sophisticated hardware to obtain fluorescence emission spectra on a single-pixel basis and a mathematical procedure called "linear unmixing" of fluorescence signals. By improving both the specificity of fluorescence acquisition and the number of simultaneously detectable fluorochromes, this technique of spectral imaging (SI) allows complex interrelations in cells and tissues to be addressed. RESULTS: In a comparative approach, SI microscopy on a quantitative basis was compared to conventional bandpass (BP) filter detection, demonstrating substantial superiority of SI with respect to detection accuracy and dye combination. An eight-color immunofluorescence protocol for tissue sections was successfully established. Moreover, advanced use of SI in fluorescence resonance energy transfer (FRET) applications using enhanced green fluorescence protein (EGFP) and enhanced yellow fluorescence protein (EYFP) in a confocal set up could be demonstrated. CONCLUSIONS: This novel technology will help to perform complex multiparameter investigations at the cellular level by increasing the detection specificity and permitting simultaneous use of more fluorochromes than with classical techniques based on emission filters. Moreover, SI significantly extends the possibilities for specialized microscopy applications, such as the visualization of macromolecular interactions or conformational changes, by detecting FRET.     

Renal tubular cell membranes inhibit growth but promote aggregation of calcium oxalate monohydrate crystals

Cell membranes have been proposed to serve as promoters for calcium oxalate monohydrate (COM) kidney stone formation. However, direct evidence to demonstrate the modulatory effects of renal tubular cell membranes on COM crystals does not currently exist. We thus examined the effects of intact MDCK cells and their fragmented membranes on COM crystal growth, aggregation and transformation. COM crystals were generated in the absence (control) or presence of intact MDCK cells or their membrane fragments. Intact MDCK cells and their membrane fragments significantly inhibited COM crystal growth (22.6% and 25.2% decreases in size, respectively) and significantly reduced COM total crystal mass (23.1% and 25.6% decreases, respectively). In contrast, both of them markedly promoted crystal aggregation (1.9-fold and 3.2-fold increases, respectively). Moreover, both intact cells and membrane fragments could transform COM to calcium oxalate dihydrate (COD) crystals. Finally, COM crystal growth inhibitory activities of both membrane forms were successfully confirmed by a spectrophotometric oxalate-depletion assay. Our data provide the first direct evidence to demonstrate the dual modulatory effects of MDCK membranes on COM crystals. Although growth of individual COM crystals was inhibited, their aggregation was promoted. These findings provide additional insights into the mechanisms of COM kidney stone formation.     

Atomistic Simulation of Mineral Surfaces

Abstract

Atomistic simulation techniques are now able to model the structure of mineral surfaces at the atomic level. In this paper we begin to address the question of whether surface reactivity can be studied reliably by modelling the surface reactivity of calcite, fluorite and forsterite under aqueous conditions. We first used energy minimisation techniques to investigate the interaction between the minerals calcite and fluorite with water and methanoic acid. The relative adsorption energies suggest that methanoic acid preferentially adsorbs onto fluorite surfaces, while water adsorbs preferentially onto calcite as inferred from experiments on mineral separation. Molecular Dynamics simulations were also used to model the effect of temperature on the adsorption of water on the calcite {1014} and fluorite {111} surfaces. Furthermore we used these techniques to model point defect formation at surfaces. We are also interested in modelling the competition between associative and dissociative adsorption on mineral surfaces. Simulations of adsorption of water on the low-index forsterite surfaces have predicted the adsorption energies and equilibrium morphology. The calculated equilibrium morphology adequately reproduces the experimental morphology of forsterite suggesting that the relative stabilities of the surfaces, both unhydrated and hydroxylated, are calculated correctly.     

Quantifying anisotropic solute transport in protein crystals using 3-D laser scanning confocal microscopy visualization

The diffusion of a solute, fluorescein into lysozyme protein crystals has been studied by confocal laser scanning microscopy (CLSM). Confocal laser scanning microscopy makes it possible to non-invasively obtain high-resolution three-dimensional (3-D) images of spatial distribution of fluorescein in lysozyme crystals at various time steps. Confocal laser scanning microscopy gives the fluorescence intensity profiles across horizontal planes at several depths of the crystal representing the concentration profiles during diffusion into the crystal. These intensity profiles were fitted with an anisotropic model to determine the diffusivity tensor. Effective diffusion coefficients obtained range from 6.2 x 10(-15) to 120 x 10(-15) m2/s depending on the lysozyme crystal morphology. The diffusion process is found to be anisotropic, and the level of anisotropy depends on the crystal morphology. The packing of the protein molecules in the crystal seems to be the major factor that determines the anisotropy.     

Intracrystalline proteins and calcium oxalate crystal degradation in MDCK II cells

We assessed the effects of intracrystalline urinary proteins on the ability of Type II Madin-Darby canine kidney (MDCK-II) cells to bind and degrade calcium oxalate monohydrate (COM) crystals. Binding of [14C]-labelled inorganic crystals (iCOM), and COM crystals precipitated from centrifuged and filtered (CF) or ultrafiltered (UF) human urine was quantified by radioactive analysis. SDS-PAGE confirmed the presence of intracrystalline proteins > 10 kDa in CF crystals and their absence from UF crystals. Morphological effects were assessed qualitatively by field emission scanning electron microscopy. iCOM crystals bound rapidly and extensively and were resistant to degradation. Binding of CF crystals was weaker than UF crystals, and both had markedly less affinity than iCOM. CF and UF crystals were extensively degraded within 90 min, the effect being more pronounced with CF. These results support our hypothesis that intracrystalline proteins protect against urolithiasis by facilitating intracellular proteolytic digestion and destruction of crystals phagocytosed by urothelial cells.     

EGCG decreases binding of calcium oxalate monohydrate crystals onto renal tubular cells via decreased surface expression of alpha-enolase

Crystal retention on tubular cell surface inside renal tubules is considered as the earliest and crucial step for kidney stone formation. Therapeutics targeting this step would cease the development of kidney stone. This study thus aimed to investigate the potential role of epigallocatechin-3-gallate (EGCG), a major antioxidant found in green tea leaves, in the reduction of calcium oxalate monohydrate (COM) crystal binding onto renal tubular cells. Pretreatment of the cells with EGCG for up to 6 h significantly diminished crystal-binding capability in a dose-dependent manner. Indirect immunofluorescence assay without and with cell permeabilization followed by laser-scanning confocal microscopy revealed that EGCG significantly reduced surface expression of alpha-enolase, whereas its intracellular level was increased. Western blot analysis confirmed such contradictory changes in membrane and cytosolic fractions of EGCG-treated cells, whereas the total level in whole cell lysate remained unchanged. Moreover, overexpression of surface alpha-enolase and enhancement of cell–crystal adhesion induced by 10 mM sodium oxalate were completely abolished by EGCG. Taken together, these data indicate that EGCG decreases binding of COM crystals onto renal tubular cells by decreasing the surface expression of alpha-enolase via re-localization or inhibition of alpha-enolase shuttling from the cytoplasm to the plasma membrane. These findings may also explain the effects of EGCG in reducing COM crystal deposition in previous animal models of kidney stone disease. Thus, EGCG may be useful for the prevention of new or recurrent stone formation.     

Crystallographic structure of the foliated calcite of bivalves

The foliated layer of bivalves is constituted by platy calcite crystals, or laths, surrounded by an organic layer, and which are arranged into sheets (folia). Therefore, the foliated microstructure can be considered the calcitic analogue to nacre. In this paper, the foliated microstructure has been studied in detail using electron and X-ray diffraction techniques, together with SEM observations on naturally decalcified shells, to investigate the crystallographic organization on different length scales and to resolve among previous contradictory results. This layer is highly organized and displays a coherent crystallographic orientation. The surface of the laths of the foliated layer is constituted by calcite crystals oriented with their c-axis tilted opposite to the growth direction of the laths and one of its {101 4} rhombohedral faces looking in the growth direction. These faces are only expressed as the terminal faces of the laths, whereas the main surfaces of laths coincide with {101 8} rhombohedral faces. This arrangement was consistently found in all specimens studied, which leads us to the provisional conclusion that, unlike previous studies, there is only one possible crystallographic arrangement for the foliated layer. Future studies on other species will help to ascertain this assertion.