Satish K. Singh

Fluid absorption in isolated perfused colonic crypts.

A spatial segregation of ion transport processes between crypt and surface epithelial cells is well-accepted and integrated into physiological and pathophysiological paradigms of small and large intestinal function: Absorptive processes are believed to be located in surface (and villous) cells, whereas secretory processes are believed to be present in crypt cells. Validation of this model requires direct determination of fluid movement in intestinal crypts. This study describes the adaptation of techniques from renal tubule microperfusion to hand-dissect and perfuse single, isolated crypts from rat distal colon to measure directly fluid movement. Morphologic analyses of the isolated crypt preparation revealed no extraepithelial cellular elements derived from the lamina propria, including myofibroblasts. In the basal state, crypts exhibited net fluid absorption (mean net fluid movement = 0.34 +/- 0.01 nl.mm-1.min-1), which was Na+ and partially HCO3- dependent. Addition of 1 mM dibutyryl-cyclic AMP, 60 nM vasoactive intestinal peptide, or 0.1 mM acetylcholine to the bath (serosal) solution reversibly induced net fluid secretion (net fluid movement approximately -0.35 +/- 0.01 nl.mm-1.min-1). These observations permit speculation that absorption is a constitutive transport function in crypt cells and that secretion by crypt cells is regulated by one or more neurohumoral agonists that are released in situ from lamina propria cells. The functional, intact polarized crypt described here that both absorbs and secretes will permit future studies that dissect the mechanisms that govern fluid and electrolyte movement in the colonic crypt.

Differential localization of colonic H+-K+-ATPase isoforms in surface and crypt cells

Two distinct colonic H+-K+-adenosinetriphosphatase (H+-K+-ATPase) isoforms can be identified in part on the basis of their sensitivity to ouabain. The colonic H+-K+-ATPase α-subunit (HKcα) was recently cloned, and its message and protein are present in surface (and the upper 20% of crypt) cells in the rat distal colon. These studies were performed to establish the spatial distribution of the ouabain-sensitive and ouabain-insensitive components of both H+-K+-ATPase activity in apical membranes prepared from surface and crypt cells and K+-dependent intracellular pH (pHi) recovery from an acid load both in isolated perfused colonic crypts and in surface epithelial cells. Whereas H+-K+-ATPase activity in apical membranes from surface cells was 46% ouabain sensitive, its activity in crypt apical membranes was 96% ouabain sensitive. Similarly, K+-dependent pHi recovery in isolated crypts was completely ouabain sensitive, whereas in surface cells K+-dependent pHi recovery was insensitive to ouabain. These studies provide compelling evidence that HKcα encodes the colonic ouabain-insensitive H+-K+-ATPase and that a colonic ouabain-sensitive H+-K+-ATPase isoform is present in colonic crypts and remains to be cloned and identified.

HCO3− secretion in the rat colonic crypt is closely linked to Cl− secretion☆☆☆

BACKGROUND & AIMSnThe mechanism of colonic HCO(3)(-) secretion has not been established largely because of a lack of experimental methods for its detailed study. The present studies were designed to establish whether the isolated, perfused crypt of the rat distal colon is an excellent model to study HCO(3)(-) movement and the mechanism of colonic HCO(3)(-) secretion.nnnMETHODSnHCO(3)(-) secretion was determined in isolated, microperfused crypts by measuring [HCO(3)(-)] by microcalorimetry on nanoliter samples.nnnRESULTSnNet HCO(3)(-) absorption was observed during lumen and bath perfusion with an HCO(3)(-)-Ringer solution. Vasoactive intestinal polypeptide (60 nmol/L), acetylcholine (100 nmol/L), or dibutyryl adenosine 3,5-cyclic monophosphate (DBcAMP, 0.5 mmol/L) induced active HCO(3)(-) secretion that required bath but not lumen HCO(3)(-)/CO(2). DBcAMP-stimulated HCO(3)(-) secretion was not affected by acetazolamide, an inhibitor of carbonic anhydrase. Removal of lumen Cl(-) did not alter DBcAMP-stimulated HCO(3)(-) secretion but reduced fluid secretion. DBcAMP-stimulated HCO(3)(-) secretion was closely linked to active Cl(-) secretion because HCO(3)(-) secretion was substantially reduced by removal of bath Cl(-), by addition of bath bumetanide, an inhibitor of Na-K-2Cl cotransport and Cl(-) secretion, and by addition of lumen NPPB, a Cl(-) channel inhibitor.nnnCONCLUSIONSnThese studies establish that colonic crypt HCO(3)(-) secretion (1) is not a result of an apical membrane Cl(-)-HCO(3)(-) exchange, (2) is tightly associated with Cl(-) secretion, and (3) primarily occurs via an apical membrane Cl(-) channel.

NOVEL TRANSPORT PROPERTIES OF COLONIC CRYPT CELLS : FLUID ABSORPTION AND CL-DEPENDENT NA-H EXCHANGE

Colonic ion transport is heterogeneous including the long-accepted spatial separation of absorptive and secretory processes between surface and crypt cells. We recently described the isolation of individual crypts from the rat distal colon that were studied using microperfusion technology. Na-dependent fluid absorption was consistently demonstrated in these crypts during perfusion with a Ringer-like solution; dibutyryl cyclic AMP, VIP and acetylcholine, when added to the bath solution, all induced net fluid secretion. As several morphologic techniques, including immunocytochemistry, failed to provide evidence for the presence of myofibroblasts in the isolated crypt preparation, we propose that a Na-dependent absorptive process is a constitutive transport mechanism in crypt cells, while secretory processes are regulated by the release of one or more neurohumoral agonists from lamina propria cells including myofibroblasts. The mechanism of Na-dependent fluid movement was also studied by determining [H] gradient stimulation of 22Na uptake in isolated apical membrane vesicles (AMV) from crypt cells. In contrast to Na-H exchange in surface cell AMV, Na-H exchange in crypt cells is Cl-dependent. Intracellular pH determined in crypt cells using video-imaging fluorescence microscopy established that the response to an acid load requires both lumen Na and Cl. As a result, these studies have identified a novel Cl-dependent Na-H exchange in crypt AMV that may mediate apical membrane Na uptake and regulate pHi.

Morphology of isolated colonic crypts

The traditional paradigm of colonic fluid and electrolyte transport includes a spatial separation of absorptive and secretory processes to surface and crypt cells, respectively. Recent studies of isolated microperfused colonic crypts revealed constitutive Na-dependent fluid absorption while secretion is regulated by one or more neurohumoral agonists. One obvious reason for the difference found in microdissected crypts is their separation from the lamina propria milieu. While it has been shown that isolated crypts are devoid of obvious lamina propria elements, including pericryptal fibroblasts, detailed morphologic information of the content of isolated crypts has been lacking. To characterize the morphology of the isolated crypt, we performed transmission electron microscopy (TEM) and immunofluorescence on microdissected and Ca2+ chelated crypts. Crypt cell type analysis was carried out separately on intact rat colon using light microscopy. TEM revealed a complete lack of either lamina propria cells or extracellular material in crypts isolated by either technique. TEM also revealed a subtle difference between the two isolation methods, with intact basal membranes in microdissected crypts but focal disruption of basal membranes in Ca2+- chelated crypts. Immunofluorescent stains for two basement membrane components (laminin and collagen type IV) revealed the presence of adherent basement membrane only on microdissected crypts; evidence that the plane of separation differs in these two preparations. Crypt cell type analysis on intact rat colon revealed an equal proportion of goblet cells in the right and left colon (approximately 50%) when measuring the middle 70% of the crypts – the area studied during crypt microperfusion. This morphologic analysis will increase our understanding of the observed physiology of isolated colonic crypts.

An apical permeability barrier to NH3 in isolated, perfused colonic crypts

Fermentation of nonabsorbed nutrients in the colon generates high concentrations of NH3/NH4+ in the colonic lumen. NH3 is a small, lipophilic neutral weak base that readily permeates almost all cell membranes, whereas its conjugate weak acid NH4+ generally crosses membranes much more slowly. It is not known how colonocytes maintain intracellular pH in the unusual acid-base environment of the colon, where permeant acid-base products of fermentation exist in high concentration. To address this issue, we hand dissected and perfused single, isolated crypts from rabbit proximal colon, adapting techniques from renal-tubule microperfusion. Crypt perfusion permits control of solutions at the apical (luminal) and basolateral (serosal) surfaces of crypt cells. We assessed apical- vs. basolateral-membrane transport of NH3/NH4+ by using fluorescent dyes and digital imaging to monitor intracellular pH of microvacuolated crypt cells as well as luminal pH. We found that, although the basolateral membranes have normal NH3/NH4+ permeability properties, there is no evidence for transport of either NH3 or NH4+ across the apical borders of these crypt cells. Disaggregating luminal mucus did not increase the transport of NH3/NH4+ across the apical border. We conclude that, compared to the basolateral membrane, the apical border of crypt colonocytes has a very low permeability-area product for NH3/NH4+. This barrier may represent an important adaptation for the survival of crypt cells in the environment of the colon.

Chapter 3 Specialized properties of colonic epithelial membranes: Apparent permeability barrier in colonic crypts

Publisher Summary This chapter presents several observations that describe heterogeneity in the permeability of plasma membranes of the rabbit proximal colon and stomach. The mammalian large intestine has several functions and the epithelial cells lining the colon have specialized transport properties that reflect these functions. The colon plays a major role in fluid and electrolyte homeostasis. In addition, the colon is a fermentation compartment that controls the disposal of digestive waste material. In health, the colon absorbs substantial amounts of water, serving to dehydrate feces. The normal human colon absorbs Na + , Cl – , and water and secretes K + and HCO3 – . The apical membrane of the colonic crypt appears to possess a diffusion barrier to weak acid, weak base, and gas movement that serves to maintain the intracellulax pH (pH i ) of crypt epithelial cells relatively constant. In view of the high concentration of weak acids and bases produced by colonic microflora from nonabsorbed dietary material, a diffusion barrier would be crucial for the less mature crypt cells because proliferative functions are especially pH sensitive.