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AJP - Renal Physiology, Vol 265, Issue 6 863-F874, Copyright © 1993 by American Physiological Society
ARTICLES |
C. L. Chou, S. Nielsen and M. A. Knepper
Laboratory of Kidney and Electrolyte Metabolism, National Heart Lung and Blood Institute, National Institutes of Health, Bethesda, Maryland 20892.
The ultrastructural characteristics of thin limb subsegments from chinchilla long loops of Henle were studied in perfusion-fixed kidneys and in isolated perfused tubules. In sections from the perfusion-fixed kidneys, we noted types I, II, III, and IV thin limb epithelia similar to those previously identified in other rodent species. Sections from the deepest 20% of the papillary tip, however, revealed only a single thin limb epithelial type, which had a combination of structural characteristics distinct from previously identified thin limb subtypes. This "papillary type" epithelium had relatively tall cells and a complex cellular organization with extensive interdigitation, numerous shallow tight junctions, and microvilli. In single-tubule studies, thin limb segments dissected from different levels of the outer and inner medulla were perfused in vitro for osmotic water permeability (Pf) measurements and were fixed for ultrastructural examination. Long-loop thin descending limbs (LDL) dissected from the outer medulla (Pf, 2,637 +/- 336 micron/s) had type II epithelium. LDL dissected from the middle of the inner medulla (Pf, 1,570 +/- 76 microns/s) had a type III epithelium. LDL segments dissected from the deepest 20% of the inner medulla had a low but nonzero Pf (68 +/- 9 micron/s) and had the same novel papillary type epithelium seen in sections from fixed kidneys. Thin ascending limbs dissected from inner 50% of the inner medulla had essentially zero Pf (8 +/- 4 micron/s) and had a type IV epithelium. Immunohistochemical localization of CHIP28 water channel protein confirmed the presence of CHIP28 in thin descending limbs throughout the outer 75% of the inner medulla, whereas labeling was essentially absent in the deep inner medulla where the low-PfLDL (novel papillary type epithelium) is located.
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