Precipitation of calcium oxalate monohydrate at phospholipid monolayers

Studies of calcium oxalate monohydrate (COM) precipitation at Langmuir monolayers of the phospholipids dipalmitoylphosphatidylglycerol (DPPG), dipalmitoylphosphatidylcholine (DPPC), and dipalmitoylphosphatidylserine (DPPS) are reported. The precipitation is heterogeneous and selective, with a majority of crystals orienting with the COM (101) face toward the monolayer interface for each phospholipid. The number density of COM crystals depends on the identity of the phospholipid monolayer, decreasing in the order DPPG > DPPS > DPPC. It was also found that COM precipitation increases as the surface pressure of the monolayer is lowered and with the addition of low levels (<0.1%) of cholesterol. The possibility that changes in monolayer fluidity influence COM attachment is discussed.

Role of urinary bikunin in the inhibition of calcium oxalate crystallization

Several urinary macromolecules are known to modulate calcium oxalate (CaOx) crystallization. One of these is urinary bikunin, the light chain of inter-alpha-inhibitor. Bikunin has been demonstrated to be an efficient inhibitor of CaOx crystal growth; however, its inhibitory activity against other events in CaOx crystallization has not been fully investigated. To assess the potential of urinary bikunin as an effective inhibitor, its effects on CaOx crystal nucleation and aggregation were evaluated. Nucleation and aggregation of CaOx crystals were studied by measuring turbidity at 620 nm. In the nucleation assay, crystallization was induced by mixing calcium chloride and sodium oxalate, at final concentrations of 3 and 0.5 mM, respectively. Both solutions were buffered with 0.05 M Tris, 0.15 M NaCl, pH 6.5. Nucleation measurements were performed at 37 degrees C, with stirring at 800 rpm. Inhibition of nucleation was estimated by comparing the induction time in the presence of the inhibitor with control values. In the aggregation assay, the optical density of the solution containing CaOx monohydrate crystals was monitored. Inhibition of aggregation was evaluated by comparing the turbidity slope in the presence of the inhibitor with control values. The data showed that urinary bikunin, at concentrations of 2.5 to 20 microg/ml, retarded crystal nucleation by 67 to 58% and inhibited crystal aggregation by 59 to 80%. According to these results, it seems that urinary bikunin is an efficient inhibitor of crystal nucleation and aggregation. Its presence in the kidneys and urine may protect subjects against CaOx crystallization and kidney stone formation.

Expression of bikunin mRNA in renal epithelial cells after oxalate exposure

PURPOSE

To determine the changes in expression of bikunin in renal epithelial cells on exposure to oxalate and calcium oxalate crystals.

MATERIALS AND METHODS

This study used reverse transcription polymerase chain reaction (RT-PCR) to examine bikunin mRNA expression levels in MDCK cells exposed to oxalate or calcium oxalate crystals. Poly(A)+ RNA was isolated directly from renal epithelial cells, then converted to cDNA with random primers and reverse transcriptase. To quantify the expression level ofbikunin mRNA, we developed a competitive DNA template for competitive PCR analysis. The PCR products were resolved by electrophoresis on 1.3% agarose gel and visualized with ethidium bromide. In this system, we could quantify the exact number of bikunin mRNA transcripts. Bikunin mRNA from rat liver was expressed as a positive control.

RESULTS

Bikunin mRNAs and competitive templates from renal epithelial cells were expressed in all samples as 434 bp and 312 bp bands, respectively. Bikunin expression was significantly increased in oxalate exposed cells. Cells exposed to calcium oxalate monohydrate crystals or latex beads showed no significant change in expression of bikunin. Western blotting analysis also showed increased expression of bikunin and inter-alpha-inhibitor-related proteins in the culture medium of oxalate exposed cells.

CONCLUSIONS

These findings suggest that renal epithelial cells express bikunin gene and have the capability to produce bikunin when stimulated by certain agents such as oxalate. This increased expression and production of bikunin may represent a protective response of renal epithelial cells to nephrotoxic challenges of oxalate.

Temporal changes in mRNA expression for bikunin in the kidneys of rats during calcium oxalate nephrolithiasis

Inter-alpha-inhibitor and other bikunin-containing proteins are synthesized in relatively large quantities by the liver. These proteins function as Kunitz-type serine protease inhibitors and appear capable of inhibiting calcium oxalate (CaOx) crystallization in vitro. Preliminary studies have shown that renal tubular epithelial cells synthesize bikunin in response to CaOx challenge. To examine this response in vivo, a sensitive reverse transcription-quantitative competitive template-PCR was developed to detect and quantify poly(A)+ -tailed bikunin mRNA expression in kidney tissue from normal rats and rats developing CaOx nephrolithiasis after challenge with ethylene glycol. Bikunin mRNA expression in rat liver tissue was assessed as a positive control. The expression of bikunin mRNA in liver did not differ significantly between normal control rats and experimental rats with induced hyperoxaluria and renal CaOx crystallization. In contrast, there were significant temporal increases in the levels of bikunin mRNA expression in rat kidneys during CaOx nephrolithiasis after challenge with ethylene glycol. Urinary excretion of bikunin-containing proteins seemed to increase concomitantly. These findings indicate an association between the induction of hyperoxaluria/CaOx nephrolithiasis and the expression of the bikunin gene in rat kidneys.

Role of inter-alpha-inhibitor and its related proteins in urolithiasis. Purification of an inter-alpha-inhibitor related protein from the bovine kidney

Urine contains several macromolecules that inhibit calcium oxalate (CaOx) crystallization. Among them is bikunin, the light chain of most of the inter-alpha-inhibitor (IalphaI) family of glycoproteins. This study aimed to verify whether bikunin and other members of the IalphaI family are synthesized in the kidneys or derived exclusively from the plasma. Proteins extracted from homogenized bovine kidney were applied successively to three chromatographic steps on DEAE-Sephacel, Sephacryl S-300, and Mono Q column. The inhibitory activity was assayed using a CaOx crystallization system. The presence of IalphaI-related proteins was determined by electrophoresis and Western blotting. The results showed that kidney extract contained a 125-kDa protein that cross-reacted with anti-IalphaI antibodies. This protein inhibited CaOx crystallization efficiently. According to its molecular weight and immunoreaction with anti-IalphaI antibody, the 125-kDa protein could be pre-alpha-inhibitor. The latter is known to encompass a heavy chain and bikunin, which may explain its inhibitory activity against CaOx crystallization. Consequently, we hypothesize that kidneys may produce some IalphaI-related proteins that are involved in the inhibition of stone formation.

Role of inter-alpha-inhibitor and its related proteins in experimentally induced calcium oxalate urolithiasis. Localization of proteins and expression of bikunin gene in the rat kidney

Our earlier studies indicated that members of the inter-alpha-inhibitor (IalphaI) family of glycoproteins may play an important role in urolithiasis. Indeed bikunin, the light chain of IalphaI is a potent inhibitor of calcium oxalate crystallization. In order to understand this role, the distribution of IalphaI and its related proteins, as well as the expression of bikunin, were studied in normal and nephrolithic rats. In normal rats, IalphaI immunoreactivity was located mainly in proximal tubules. However, in nephrolithic rats, in addition to proximal tubules, the staining was intensively extended to tubules in the corticomedullary junction. Furthermore, by using polymerase chain reaction technique, we demonstrated that gene encoding for bikunin was activated in kidneys of nephrolithic rats. We have previously demonstrated increased staining for osteopontin in association with calcium oxalate crystal deposition in rat kidneys. Others have shown an increase in osteopontin production by renal epithelial cells on exposure to calcium oxalate crystals. Based on these observations we conclude that kidney cells possess an auto-defense system against calcium oxalate crystallization and stone formation in which members of the IalphaI family may be closely involved.

Inter-alpha-inhibitor: a protein family involved in the inhibition of calcium oxalate crystallization

Inter-alpha-inhibitor (I alpha I) is a serine protease inhibitor present in human plasma. It has a molecular weight of about 220 kDa which encompasses 3 chains including two heavy chains and one light chain. The light chain, known as bikunin, is responsible for the antitryptic activity of I alpha I in the inhibition of various enzymes, such as trypsin and chymotrypsin. Under physiologic or certain pathologic circumstances, several macromolecules related to I alpha I appear in plasma and urine. However, the physiologic role of I alpha I remains unclear. As far as urolithiasis is concerned, two urinary macromolecules related to I alpha I have been isolated and shown to be potent inhibitors of calcium oxalate formation. One of these inhibitors, uronic-acid-rich protein (UAP), has been identified and well characterized. The sequence of the first 18 amino acid residues of UAP is identical with that of bikunin. Furthermore, the immunoreaction between UAP and I alpha I antibody using immunoblot analysis was positive. UAP isolated from the urine of stone formers exhibited less inhibitory activity towards calcium oxalate crystallization than that derived from the urine of healthy subjects. This suggests a structural abnormality of the inhibitor obtained from stone patients. The organic matrix extracted from kidney stones contained a protein antigenically related to I alpha I. We conclude that UAP is a member of I alpha I family taking part in inhibiting calcium oxalate crystallization, and modulating the formation of stones in the urinary tract.

Identification of proteins extracted from calcium oxalate and calcium phosphate crystals induced in the urine of healthy and stone forming subjects

The purpose of our study was to identify the proteins and investigate the differences, if any, between protein components of the matrices of calcium oxalate (CaOx) and calcium phosphate (CaP) crystals induced in vitro in whole human urine of healthy individuals and kidney stone patients. In addition, preliminary studies were performed to understand the effect of centrifugation and filtration of urine on its protein contents. Crystallization in urine was induced by addition of an oxalate or phosphate load. Crystals were collected, washed, and analyzed by scanning electron microscopy, X-ray diffraction, and energy dispersive X-ray microanalysis. Matrix proteins were obtained by demineralization with ethylene diamine tetraacetic acid (EDTA), analyzed by polyacrylamide gel electrophoresis, and identified by western blotting technique. No significant differences were detected between protein components of the matrices of CaOx and CaP crystals and between the crystal matrices obtained from the urine of normal and stone forming subjects. Albumin (AB), inter-alpha-inhibitor (IalphaI) related proteins, alpha-1 microglobulin (alpha-1 m), osteopontin (OPN), prothrombin (PT)-related proteins and Tamm-Horsfall protein (THP) were identified in matrices of both CaOx and CaP crystals induced in urine from both the normal subjects and stone formers. AB, PT-related proteins and OPN were the main constituents. The other proteins were present in smaller but detectable amounts. However, CaP crystal matrix, contained a large amount of THP. In addition CaP crystals contained significantly more proteins than CaOx crystals. Centrifugation and/or filtration of the urine resulted in reduction of many high molecular weight proteins including THP, AB and OPN in the urine.

Occurrence and susceptibility to antibiotics of Shigella species in stools of hospitalized children with bloody diarrhea in Pakistan

The aim of the present investigation was to study the frequency of Shigella spp. in patients with bloody diarrhea in Pakistan and the susceptibility of isolated Shigella to three antibiotics: ampicillin, cotrimoxazole and nalidixic acid. In addition, the frequency of Campylobacter and Salmonella was also determined. Stool samples (n = 152) were collected from 152 diarrheic children less than six years of age passing blood and mucus in their stools who were admitted to Paediatric Department of Mayo Hospital in Lahore, Pakistan from June to September 1990. The samples were cultivated on standard media for Shigella, Campylobacter, and Salmonella. Susceptibility of Shigella isolates was tested by disk diffusion method. The frequency of isolation was 19.1% for Shigella spp., 7.9% for Campylobacter, and 4.6% for Salmonella. Shigella flexneri (7.9%) was the most frequently isolated species, followed by S. dysenteriae (6.6%), S. boydii, (3.3%) and S. sonnei (1.3%). All Shigella isolates were susceptible to nalidixic acid (100%), while only a few were susceptible to cotrimoxazole (7.0%) and ampicillin (3.5%). In Pakistan, self-medication and purchases of drugs without a prescription are commonly practiced. Thus, there is a greater possibility of development of resistant strains due to over use of antibiotics.

Oxalate and calcium oxalate crystals are injurious to renal epithelial cells: results of in vivo and in vitro studies

Calcium oxalate (CaOx) nephrolithiasis was induced in male Sprague-Dawley rats by administration of 0.75% ethylene glycol. Urinary excretion of lactate dehydrogenase (LDH) was used as a marker of cellular injury. Lipid peroxides (LP), as marker for free radical injury, were measured as malondialdehyde (MDA) in urine and the kidneys. Urinary oxalate (Ox), LDH, LP, CaOx crystals, and renal LP and CaOx crystal deposits were examined on day 0, 5, 30 and 60 of the experiment. There were significant differences between control and experimental rats in all the parameters except LDH which did not show a significant increase after 15 days. Subconfluent cultures of MDCK and LLCPK1 cells were exposed to various concentrations of oxalate and/or 500 fg/ml CaOx crystals. Cell viability was assayed by trypan blue exclusion, cellular injury was determined by measuring LDH in the media, and free radical injury was measured as MDA contents of the cells. On exposure to both Ox and/or CaOx crystals trypan blue exclusion decreased and LDH and MDA increased significantly in both tissue cultures. LLC-PK1 appeared more sensitive. The results indicate that both oxalate and calcium oxalate crystals are injurious to renal epithelial cells in the kidneys as well as in culture.

Biochemical and quantitative analysis of Tamm Horsfall protein in rats

The involvement of Tamm Horsfall protein (THP) in nephrolithiasis is currently under investigation in several laboratories. Although rat is a commonly used species as an in vivo model for such studies, there is only limited information available about the biochemical properties and excretion profile of THP in normal rats. In order to characterize rat THP, we purified and analyzed normal male rat THP, and compared it with normal human male urinary THP by gel electrophoresis. Both THPs migrated at approximately 90 KDa, and stained similarly for protein (Coomassie blue) as well as carbohydrates (periodic acid Schiff reagent). Compositional analysis revealed that rat THP was largely similar to human THP in amino acid and carbohydrate contents but showed differences in the individual sugar components from other mammals. There was considerable variation in the day-to-day urinary excretion of THP in normal rats, with values ranging from 552.96 micrograms to 2865.60 micrograms and a mean value of 1679.54 micrograms per 24 h. It was concluded from this study that rat THP did not contain any unusual biochemical components and was primarily similar to human THP in composition and mean urinary concentration.

Mood and the correction of positive versus negative stereotypes

The present research examined the effects of sadness on the correction of social stereotypes. Participants who either were not induced to feel sad were asked to form an impression of a single individual who belonged to a group that had either stereotypically positive or negative implications. Experiments 1 and 2 showed that sad people corrected for their negative, but not for their positive stereotypes. Experiment 3 demonstrated that this asymmetry was not due to stereotype valence per se but to whether the stereotype was perceived as an inappropriate basis for judgment. A model is presented that suggests that sad people do not simply ignore category-based information, but rather correct for their stereotypes only when they are perceived as inappropriate, which tends to be more often the case if the stereotype is negative than if it is positive. The implications of the present results for 4 extant models of mood and information processing are discussed.

Lipid peroxidation in ethylene glycol induced hyperoxaluria and calcium oxalate nephrolithiasis

PURPOSE

To determine if lipid peroxidation plays a role in renal injury associated with experimental nephrolithiasis.

MATERIALS AND METHODS

Hyperoxaluria was produced in rats by ethylene glycol in drinking water. At 15, 30 and 60 days of treatment, urinary oxalate, lipid peroxide, calcium oxalate crystals, enzymes and tissue lipid peroxide were measured.

RESULTS

Urinary oxalate increased significantly at all time periods and was associated with crystalluria. Lipid peroxides in kidney tissue and urine increased at all time periods. Tissue calcium oxalate crystal deposits from 0 to 1+ were present on day 15, but present in all animals on days 30 and 60. Renal tubular cell damage was confirmed by an increase in urinary marker enzymes.

CONCLUSIONS

Renal cell damage is associated with lipid peroxide production indicating cell injury due to the production of free radicals. The damage appears due primarily to hyperoxaluria and is augmented by crystal deposition in the renal tubules.

Animal models of kidney stone formation: an analysis

Calcific kidney stones in both humans and mildly hyperoxaluric rats are located on renal papillary surfaces and consist of an organic matrix and crystals of calcium oxalate and/or calcium phosphate. The matrix is intimately associated with the crystals and contains substances that can promote as well as inhibit calcification. Osteopontin, Tamm-Horsfall protein, bikunin, and prothrombin fragment 1 have been identified in matrices of both human and rat stones. Hyperoxaluria can provoke calcium oxalate nephrolithiasis in both humans and rats. Kidney-stone-forming rats are hypomagnesuric and hypocitraturic during nephrolithiasis. Human stone formers may have the same disorders. Males of both species are prone to develop calcium oxalate nephrolithiasis, whereas females tend to form calcium phosphate stones. Oxalate metabolism is considered to be almost identical between rats and humans. Thus, there are many similarities between experimental nephrolithiasis induced in rats and human kidney-stone formation, and a rat model of calcium oxalate nephrolithiasis can be used to investigate the mechanisms involved in human kidney stone formation.

Calcium phosphate/calcium oxalate crystal association in urinary stones: implications for heterogeneous nucleation of calcium oxalate

PURPOSE

Most stones contain more than one type of crystals, and some combinations, such as calcium phosphate/calcium oxalate, are more common than others. Epitaxy between the crystals has been suggested to play a role in growth of such stones. The specific aim of this study is to investigate the involvement of calcium phosphate in crystallization of calcium oxalate.

MATERIALS AND METHODS

Twenty calcium oxalate stones or stone fragments were examined using various microscopic techniques, including scanning, transmission and back-scattered electron microscopy. Similarly, calcium oxalate stones induced on a plastic foreign body implanted inside urinary bladders of laboratory rats were also investigated. Examination of the interface between calcium phosphate and calcium oxalate crystals was emphasized.

RESULTS

Close association between crystals of calcium phosphate and calcium oxalate were found in both the human and rat stones. All crystals examined were associated with an organic matrix on the surface and contained copious amounts of organic material within the crystalline entities. Interface between the crystals also appeared to be occupied by organic matrix.

CONCLUSIONS

Results of this and other studies from our laboratory indicate that epitaxy between various crystals, even though theoretically possible, appears unlikely in vivo. The appearance of specific crystalline combinations in stones is probably a result of the urinary environment being conducive for crystallization of those components. Heterogeneous nucleation of calcium oxalate is most probably induced by biological elements, including membranous cellular degradation products.

Lipids and membranes in the organic matrix of urinary calcific crystals and stones

The ultrastructure of the organic matrix of demineralized urinary stones was examined by standard transmission and scanning electron microscopy as well as after malachite green-glutaraldehyde fixation. Crystal ghosts of both calcium oxalate and calcium phosphate were made of amorphous material and were dispersed in a matrix containing amorphous, fibrillar, and membranous substances. Malachite green positive material was seen to be associated with the ghosts, as well as with the membranous and fibrillar components of the organic matrix. Calcium oxalate and calcium-phosphate crystals, induced in human urine in vitro were also found to be associated with an organic matrix containing lipids and proteins. It is suggested that the intimate association between crystals and lipids is a result of the involvement of cellular membranes in the nucleation of these crystals.

Immunocytochemical localization of Tamm-Horsfall protein in the kidneys of normal and nephrolithic rats

Studies using in vitro systems have indicated that Tamm-Horsfall protein (THP) can interact with calcium oxalate (CaOx) crystals during kidney stone formation. However, information regarding the nature of its participation in this process remains controversial and unclear. In order to better understand the putative interaction of THP and crystals in vivo, we compared the localization of THP in normal rats and in chronic and semi-acute rat models of nephrolithiasis. In these rats, CaOx crystal deposits were induced in the kidneys by administering ethylene glycol (EG) in drinking water. The formation of CaOx mono- and dihydrate aggregates in the urine was confirmed by scanning electron microscopy. Immunohistochemical localization, as well as protein A-gold labeling at the ultrastructural level, demonstrated that in addition to its normal distribution, THP specifically associated with the renal crystal deposits. The THP-containing, organic matrix-like material consisted of a fine, fibrillar meshwork surrounding individual crystals and their aggregates. In addition, THP also appeared in the papilla, where it is normally absent, concurrent with the appearance of crystal deposits in the kidneys. These observations indicate that in nephrolithic rats the normal localization of THP is altered. Such an alteration may indicate an important physiological event related to crystal aggregation and kidney stone formation.

Increased urinary excretion of lipids by patients with kidney stones

OBJECTIVE

To test the hypothesis that patients with calcific kidney stones (stone formers) excrete more lipids and cell membranes in their urine than do normal individuals.

PATIENTS, SUBJECTS AND METHODS

Lipids were isolated from the urine of patients with calcific stones (four women and six men, age range 28-69 years) and from normal subjects (three men and three women, age range 31-54 years). Different phospholipids, neutral lipids and glycolipids were identified using thin layer chromatography and individual lipids were characterized by several assays after scraping the spots from the plates, or by densitometry.

RESULTS

Stone formers excreted more lipids and acidic phospholipids than did normal individuals; the urinary excretion of glycolipid, cholesterol and cholesterol esters was also increased.

CONCLUSIONS

The greater excretion of lipids may reflect the increased turnover of cells in the tubular epithelium and sloughing of cells into the urine in response to a challenge by oxalate and calcium oxalate crystals. Acidic phospholipids from cellular membranes of the sloughed epithelial cells may be involved in crystal nucleation and retention within the kidneys and thus the initial development of stone nidus and the continued growth thereafter.

Identification of uronic-acid-rich protein as urinary bikunin, the light chain of inter-alpha-inhibitor

Uronic-acid-rich protein (UAP) is a urinary glycoprotein that inhibits calcium oxalate crystallization in vitro. It shows a structural similarity to bikunin, a component of inter-alpha-inhibitor (IalphaI) known for its inhibition of the action of many serine proteinases like trypsin and chymotrypsin. To clarify the relationship between these macromolecules, UAP, IalphaI, urinary bikunin, and plasma bikunin were purified and studied. Their calcium oxalate crystallization inhibitory activity was assayed before and after treatment with chondroitinase AC and pronase. Their molecular mass was determined by using SDS/PAGE before and after these treatments. Polyclonal bikunin antibody was used on Western blots for immunological identification. The partial amino acid sequence of UAP before and after chondroitinase treatment was determined. Also, the antitryptic activity of UAP was measured and compared to that of bikunin, which is responsible for the antiprotease activity of IalphaI. UAP exhibited a strong calcium oxalate crystallization inhibitory activity. IalphaI and both bikunins were less inhibitory. Chondroitinase AC had no effect on inhibitory activity of these proteins even when their molecular mass changed. However, after pronase treatment, the inhibitory activity of both bikunins and UAP was completely destroyed. The antitryptic activity of UAP was found to be 0.78 U/mg which is lower than that of bikunin which is about 1.9 U/mg. On Western blotting, bikunin antibody immunoreacted with UAP and both urinary and plasma bikunins. Partial amino acid sequence confirmed the identity of UAP as urinary bikunin.

Association of urinary macromolecules with calcium oxalate crystals induced in vitro in normal human and rat urine

This study was undertaken to identify proteins which are found associated with calcium oxalate crystals induced in vitro in normal human and rat urine. Crystallization was initiated by adding sodium oxalate individually to each urine sample without centrifugation and filtration. Crystals were collected and analyzed by scanning electron microscopy and X-ray diffraction. Crystal matrix proteins (CMPs) were obtained by demineralization of the crystals with ethylenediaminetetra-acetic acid (EDTA) and analyzed by western blotting technique for immunological identification. Crystals produced in human urine were found to be a mixture of calcium oxalate monohydrate (COM) and calcium oxalate dihydrate (COD) while those produced in rat urine were exclusively COD. CMPs extracted from crystals in human urine comprised, in addition to prothrombin-related proteins, osteopontin and albumin. However, CMPs extracted from crystals in rat urine contained only osteopontin and albumin. Prothrombin-related proteins were found only in trace amounts. In a separate experiment, rat urine samples were supplemented with COM before inducing crystallization. Similar results were observed showing that CMP contained osteopontin, albumin and trace amounts of prothrombin-related proteins. We conclude that several urinary macromolecules including not only prothrombin-related proteins, but also osteopontin and albumin, become associated with CaOx crystals. The incorporation of these proteins in growing stones is not only due to the presence of gamma-carboxyglutamic acid as it was suggested for prothrombin-related proteins, but may be due to other factors such as urinary chemistry, presence of glutamic and aspartic acid residues, and calcium-binding sites.

Localization of tamm-horsfall protein and osteopontin in a rat nephrolithiasis model

The possibility of more than one urinary protein being simultaneously associated with calcium oxalate (CaOx) crystallization in vivo was investigated by examining the localization of Tamm-Horsfall protein (THP) and osteopontin (Opn) in a rat model of nephrolithiasis. CaOx crystal deposits were induced in male Sprague-Dawley rats by feeding 0.75% ethylene glycol in drinking water. THP and Opn were localized on kidney sections by immunoperoxidase technique, using specific polyclonal antibodies. When only occasional crystal deposits were seen in the kidney, THP showed a similar to normal pattern of distribution, with positive staining in the thick ascending limbs of the loop of Henle. Opn was localized in some nephrons in the thin limb of loop of Henle and on the papillary surface in the calyceal fornix. In contrast, in samples with a significantly increased number of deposits in the kidneys, the staining for both THP and Opn was strikingly enhanced and altered, with positive staining around the crystals as well as abnormal localization in the papilla. Interestingly, the occurrence of Opn was, however, more consistent than that of THP. This is a first study showing that in this nephrolithiasis model, normal localization of THP and Opn is altered and they are closely and concurrently associated with crystal deposits in vivo.

Ultrastructural immunodetection of osteopontin and osteocalcin as major matrix components of renal calculi

The organic matrix of renal calculi has long been considered to influence the crystal growth that occurs in these pathological mineral deposits. Recent advances in characterizing individual organic moieties from mineralized tissues in general and the combined use of antibodies raised against these molecules with different immunocytochemical approaches have allowed their precise distribution to be visualized in a variety of normal and pathological mineralized tissues. The present ultrastructural study reports on the epithelial expression and extracellular localization of several noncollagenous proteins in rat and human kidney stones using high-resolution colloidal-gold immunocytochemistry. To this end, we have examined in an ethylene glycol-induced calcium oxalate model of urolithiasis in the rat, and in human kidney stones, the distribution of certain noncollagenous and plasma proteins known to accumulate in bone and other mineralized tissues that include osteopontin, osteocalcin, bone sialoprotein, albumin, and alpha 2HS-glycoprotein. Of these proteins, osteopontin (uropontin) and osteocalcin (or osteocalcin-related gene/protein) were prominent constituents of the calcium oxalate-associated crystal "ghosts" found in the nuclei, lamellae, and striations of the organic matrix of lumenal renal calculi in the rat and of small crystal ghosts found within epithelial cells. Immunocytochemical labeling for both proteins of the content of secretory granules in tubular epithelial cells from treated rats, together with labeling of a similarly textured organic material in the tubular lumen, provides evidence for cosecretion of osteopontin and osteocalcin by epithelial cells, their transit through the urinary filtrate, and ultimately their incorporation into growing renal calculi. In normal rat kidney, osteopontin was localized to the Golgi apparatus of thin loop of Henle cells. In human calcium oxalate monohydrate stones, osteopontin was similarly detected in the lamellae and striations of the organic matrix. Based on these data, it is proposed that during urolithiasis, secretion of osteopontin (uropontin) and osteocalcin (or osteocalcin-related gene/protein), and the subsequent incorporation of these proteins into kidney stone matrix, may influence the nucleation, growth processes, aggregation, and/or tubular adhesion of renal calculi in mammalian kidneys.