Crystal Matrix Protein: a Potent Inhibitory Component of Calcium Oxalate Crystals

1994 ◽  
pp. 313-313 ◽  
Author(s):  
I. R. Doyle ◽  
V. R. Marshall ◽  
R. L. Ryall
1991 ◽  
Vol 37 (9) ◽  
pp. 1589-1594 ◽  
Author(s):  
I R Doyle ◽  
R L Ryall ◽  
V R Marshall

Abstract The abundance of protein in the matrix of calcium oxalate uroliths has fueled speculation regarding its role in stone genesis. In this study, we wanted to characterize the composition of the proteins associated with early stages of calcium oxalate crystallization in urine. Calcium oxalate crystallization was induced in urine from healthy men and women by the addition of an oxalate load. The crystals were harvested and demineralized, and the proteins remaining were separated and characterized by polyacrylamide gel electrophoresis and Western blotting. Most urinary proteins were not detected in the crystals or were present in only small quantities. The most abundant urinary macromolecule, Tamm-Horsfall glycoprotein, was notably absent from the crystal extracts. The predominant protein associated with the crystals, a previously unknown urinary constituent that we call crystal matrix protein (CMP; molecular mass, 30,000 Da), was more prevalent in the crystals derived from female urine. We conclude that most urinary proteins play no direct role in calcium oxalate crystal formation. However, the protein CMP exhibits a remarkable affinity for calcium oxalate crystals and may be important in stone pathogenesis.


Author(s):  
H. J. Arnott ◽  
M. A. Webb ◽  
L. E. Lopez

Many papers have been published on the structure of calcium oxalate crystals in plants, however, few deal with the early development of crystals. Large numbers of idioblastic calcium oxalate crystal cells are found in the leaves of Vitis mustangensis, V. labrusca and V. vulpina. A crystal idioblast, or raphide cell, will produce 150-300 needle-like calcium oxalate crystals within a central vacuole. Each raphide crystal is autonomous, having been produced in a separate membrane-defined crystal chamber; the idioblast''s crystal complement is collectively embedded in a water soluble glycoprotein matrix which fills the vacuole. The crystals are twins, each having a pointed and a bidentate end (Fig 1); when mature they are about 0.5-1.2 μn in diameter and 30-70 μm in length. Crystal bundles, i.e., crystals and their matrix, can be isolated from leaves using 100% ETOH. If the bundles are treated with H2O the matrix surrounding the crystals rapidly disperses.


1987 ◽  
Vol 65 (9) ◽  
pp. 1952-1956 ◽  
Author(s):  
J. A. Traquair

Oxalic acid and crystals of calcium oxalate were produced during growth of Leucostoma cincta and L. persoonii on potato dextrose agar and in peach bark tissues. The identification of calcium oxalate was based on solubility characteristics, the results of KMnO4 titration, positive staining with silver nitrate – dithiooxamide, and crystal morphology as observed with light and scanning electron microscopes. Oxalic acid was detected by gas chromatography. This is the first report of oxalic acid production by both Leucostoma species causing peach canker. Calcium oxalate crystals observed on or near hyphae in culture were similar to crystals in artificially inoculated peach bark tissues. Addition of oxalic acid solutions alone to inner bark tissues caused maceration and necrosis. These results indicate a role for oxalic acid in the early stages of pathogenesis by Leucostoma spp. Tetragonal (bipyramidal) and prismatic calcium oxalate crystals formed on bark wounds treated with oxalic acid solutions were similar to those observed in infected tissues and in culture media amended with oxalic acid.


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