There is some evidence to suggest that microbial growth inhibition may occur in chronic abscesses. A substance perhaps responsible for this phenomenon is calprotectin, a neutrophil cytoplasmic protein that inhibits microbial growth and that belongs to a class of proteins often having specific binding sites for zinc. In the present study, the suppressive effects of either human or mouse neutrophil lysates on Candida albicans growth were found to be completely reversed by micromolar quantities of zinc but not by iron or other trace elements. Similarly, supernatants of exudates from experimental abscesses in mice or from clinical specimens of abscesses in humans markedly inhibited the proliferation of C. albicans, and this effect was also completely reversed by zinc. A protein complex characteristic of calprotectin was identified in the abscess fluids. Preparations of the neutrophil growth-inhibiting protein, containing predominantly calprotectin, were shown to have zinc-binding activity by a dialysis technique. These findings suggest that the major mechanism of C. albicans growth inhibition by abscess fluids is through competition for zinc by a cytoplasmic protein apparently released from dying neutrophils.
Crystal polymorphism is exhibited by calcium oxalates in nephrolithiasis, and we have proposed that a shift in the preferred crystalline form of calcium oxalate (CaOx) from monohydrate (COM) to dihydrate (COD) induced by urinary macromolecules reduces crystal attachment to epithelial cell surfaces, thus potentially inhibiting a critical step in the genesis of kidney stones. We have tested the validity of this hypothesis by studying both the binding of monohydrate and dihydrate crystals to renal tubule cells and the effect of macromolecular urinary solutes on crystal structure. Renal tubule cells grown in culture bound 50% more CaOx monohydrate than dihydrate crystals of comparable size. The effects of macromolecules on the spontaneous nucleation of CaOx were examined in HEPES-buffered saline solutions containing Ca2+ and C2O4(2-) at physiologic concentrations and supersaturation. Many naturally occurring macromolecules known to be inhibitors of crystallization, specifically osteopontin, nephrocalcin and urinary prothrombin fragment 1, were found to favor the formation of calcium oxalate dihydrate in this in vitro system, while other polymers did not affect CaOx crystal structure. Thus, the natural defense against nephrolithiasis may include impeding crystal attachment by an effect of macromolecular inhibitors on the preferred CaOx crystal structure that forms in urine.
Studies of experimental infections in animals indicate that phagocytic cells may sometimes control infective foci without actually ingesting or contacting the invading microorganisms. In the present study, an effective inhibitor of Candida albicans growth, previously detected in neutrophils cytoplasm and found to be released only after lysis of the cells, was identified as an abundant calcium-binding protein originally described in neutrophils as the L1 myelomonocytic antigen or the cystic fibrosis antigen. This substance was demonstrated also to have static activity against several other important human pathogens, including Aspergillus fumigatus, Staphylococcus aureus, and Escherichia coli. Growth of the various microorganisms was inhibited to considerably different degrees by the neutrophil protein, with the effects on S. aureus (the least responsive organism) being significantly enhance by addition of calcium to the medium. These findings suggest that after its release by the death of neutrophils at sites of tissue infection, this abundant calcium-binding protein could have a host defense function by controlling the growth of pathogenic microorganisms that escape being killed initially and would otherwise be free to proliferate.
This study indicates that both individual cell injury (loss of lipid asymmetry) and generalized cell monolayer injury (loss of cell polarity) result in the presentation of different cell surfaces and that both forms of injury result in an increased affinity for crystal attachment. Both mechanisms could be important independently or collectively in the retention of microcrystals to renal collecting duct cells in urolithiasis.
The development of urolithiasis is a multifaceted process, starting at urine supersaturation and ending with the formation of mature renal calculi. The retention of microcrystals by the urothelial cell membrane is a critical event in the process. The current study examines calcium oxalate monohydrate (COM) crystal attachment to inner medullary collecting duct (IMCD) cells following selective changes in cell membrane phospholipid composition. Both primary culture of IMCD cells and a continuous IMCD cell line were used for these studies. Cell membrane composition was selectively altered by either exogenous addition of membrane phospholipids or using membrane lipid scrambling agents. Enrichment with anionic phospholipids was found to greatly increase attachment of crystals to the cells. This increased attachment correlated with the exposure of phosphatidylserine (PS) on the exofacial leaflet of the cell membrane as demonstrated by the use of the membrane scrambling agent A-23187. Furthermore, the increased COM attachment following PS exposure could be blocked by incubating the cells with the PS-specific binding protein, annexin V. These results support the hypothesis that exposure of PS head groups on the papillary epithelial cell surface may mediate stone crystal attachment to the kidney tubule cell epithelium in the renal papilla, possibly as an initiating event in urolithiasis.
Crystal polymorphism is exhibited by calcium oxalates in nephrolithiasis, and we have proposed that a shift in the preferred crystalline form of calcium oxalate (CaOx) from monohydrate (COM) to dihydrate (COD) induced by urinary macromolecules reduces crystal attachment to epithelial cell surfaces, thus potentially inhibiting a critical step in the genesis of kidney stones. We have tested the validity of this hypothesis by studying both the binding of monohydrate and dihydrate crystals to renal tubule cells and the effect of macromolecular urinary solutes on crystal structure. Renal tubule cells grown in culture bound 50% more CaOx monohydrate than dihydrate crystals of comparable size. The effects of macromolecules on the spontaneous nucleation of CaOx were examined in HEPES-buffered saline solutions containing Ca2+ and C2O4(2-) at physiologic concentrations and supersaturation. Many naturally occurring macromolecules known to be inhibitors of crystallization, specifically osteopontin, nephrocalcin and urinary prothrombin fragment 1, were found to favor the formation of calcium oxalate dihydrate in this in vitro system, while other polymers did not affect CaOx crystal structure. Thus, the natural defense against nephrolithiasis may include impeding crystal attachment by an effect of macromolecular inhibitors on the preferred CaOx crystal structure that forms in urine.
The relationship between cell membrane polarity and calcium oxalate (CaOx) crystal binding was studied in rat renal inner medullary collecting duct (IMCD) cells in primary culture. Cultures grew as simple monolayers (M) with interspersed cellular aggregates (A), and CaOx bound preferentially to A. An antibody that recognizes an exclusively basolateral epitope in intact IMCD binds to some of the cells in A but not to cells in M. Lysing of intercellular junctions with 3 mM EGTA (monitored by transepithelial resistance, R) resulted in basolateral antibody binding to the previously negative cells in M and a 21-fold increase in CaOx adherence to M over control (P less than 0.01). Enhanced CaOx attachment appeared to lag behind the fall in R by 5-10 min. Crystal attachment returned to control between 30 and 120 min after removal of EGTA and readdition of Ca. These data suggest that loss of epithelial membrane polarity may result in enhanced capacity to bind CaOx. Such loss of cell membrane polarity may occur in IMCD with some forms of epithelial injury and repair and may provide a site of crystal fixation to initiate nephrolithiasis.
Attachment of microcrystallites to cellular membranes may be an important component of the pathophysiology of many diseases including urolithiasis. This study attempts to characterize the interaction of calcium oxalate (CaOx) crystals and apatite (AP) crystals with renal papillary collecting tubule (RPCT) cells in primary culture. Primary cultures of RPCT cells showed the characteristic monolayer growth with sporadically interspersed clumped cells. Cultures were incubated with [14C]CaOx crystals, and the crystals that bound were quantified by microscopy and adherent radioactivity. Per unit of cross-sectional area, 32 times more CaOx crystals were bound to the clumps than to the monolayer. CaOx adherence demonstrated concentration-dependent saturation with a beta value (fraction of cell culture area binding CaOx crystals) of 0.179 and a 1/alpha ox value (maximum micrograms of crystallites adhering to 1 cm2 of binding area) of 287 micrograms/cm2. On coincubation with AP crystals, CaOx binding demonstrated concentration-dependent inhibition with a 1/alpha AP value of 93 micrograms/cm2. Microcrystallite adherence to RPCT cells demonstrates selectivity for cellular clumps, saturation, and inhibition. These features suggest specific binding.
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