Effect of diuretics on intestinal transport of electrolytes, glucose, and amino acid.

The jejunal mucosal membrane of albino mice was used to study the electrical properties and ion transport. The membrane was bathed in Krebs-Ringer solution with or without glucose.When ethacrynic acid (EA), furosemide, or amiloride was added to the bathing fluid of both sides, a transient increase followed by a decrease of both potential difference (PD) and short circuit current (Isc) were observed. In glucose-containing bathing medium, EA inhibited both net Na and Cl flux and residual flux; however, EA had little effect on both Na and Cl flux in glucose-free bathing medium. Studies using everted intestinal sac technique showed that EA inhibited both glucose and L-tyrosine across the mucosal membrane against concentration gradients. Furosemide and amiloride were less potent than EA in inhibiting the Na and Cl flux when the bathing solution contained glucose. But these two compounds had no effect on glucose and L-tyrosine transport across the intestinal mucosa. Furthermore, they did inhibit Cl flux even in the condition of glucose-free bathing medium. It is postulated that all three diuretics act on the brush-border membrane of the intestine. EA probably inhibits the Na-glucose cotransporting system; furosemide and amiloride inhibit the simple diffusion process of Na entry of Cl exit by decreasing the conductance of the membrane.     

Cation selectivity of the apical membrane of the turtle colon: sodium entry in the presence of lithium

Exposure of the apical surface of the isolated turtle colon to Li produced a marked transient in short-circuit current (ISC) and total tissue conductance (GT) which was abolished by amiloride but was unaffected by ouabain or by removing Na or Cl from the mucosal bathing solution. Despite marked changes in Isc, Na uptake across the apical membrane was a linear function of time during exposure to Li-containing solutions, and except at very high Li concentrations, the initial rate of Na uptake, JiNa, was identical to its pre-Li value. In the presence of Li, however, JiNa was significantly less than the total Isc. The apparent "transference number" for Na in the apical membranes was a function of the Li:Na concentration ratio in the mucosal bathing solution. These results suggest that Li can carry substantial amounts of current through amiloride-sensitive channels in the apical membrane of the colon without having any effect on the rate coefficient for Na entry. This behavior is not consistent with "competition" of Na and Li for a membrane "carrier" but rather suggests that the Na entry mechanism may be a population of pores or channels through which Na and Li may pass with negligible interaction.     

Sodium dependence of intestinal active transport of sugars in snail (Cryptomphalus hortensis Müller).

Active transport of sugars (D-galactose, D-glucose, 3-0-methylglucose and L-arabinose) by sacs of everted intestine of snail (Cryptomphalus hortensis) was strongly inhibited, but not abolished, when all Na from the bathing solutions was substituted by K, Tris, Mg or Ca. Absence of Na produced also a marked inhibition of O2 consumption by the tissue. Omission of other cations (K, Ca, Mg), substituted by Tris, did not affect sugar transport or O2 uptake. Sodium seems to play a specific and important but not indispensable r?le in sugar active transport by snail intestine. Since anaerobiosis did not affect sugar transport, this Na role is independent of its effect on O2 uptake.     

Membrane mechanisms for electrogenic Na(+)-independent L-alanine transport in the lizard duodenal mucosa

The active Na(+)-independent transport of L-alanine across the duodenal mucosa of the lizard Gallotia galloti was studied in Ussing-type chambers using a computer-controlled voltage clamp. Addition of L-alanine to the Na(+)-free bathing solutions resulted in a significant L-alanine absorption (J(net)) that was paralleled by an increase in transepithelial short-circuit current (I(sc)) and potential difference (PD) without apparent changes in the tissue conductance. The concentration dependence of J(net), PD, and I(sc) displayed Michaelis-Menten kinetics. L-alanine-induced electrical changes were completely inhibited by external alkaline pH or by the H(+)-ionophore carbonyl cyanide m-chlorophenyl-hydrazone in the bathing solution. The alanine-induced electrogenicity was dependent on the presence of extracellular K(+) and could be blocked by serosal Ba(2+) or mucosal orthovanadate. These results suggest the existence of an H(+)-coupled L-alanine cotransport at the apical membrane of enterocytes. The favorable H(+) driving force is likely to be maintained by an apical vanadate-sensitive H(+)-K(+)-ATPase, allowing the extrusion of H(+) in an exchange with K(+). Potassium exit through a basolateral barium-sensitive conductance provides the key step for the electrogenicity of L-alanine absorption.     

Metabolism of depleted turtle bladder

Summary Oxygen consumption, glycogen content, transmural potential difference (PD), and short-circuit current (SCC) were measured in fresh turtle hemibladder sacs and in matching sacs depleted by 18 hr of incubation in aerated, substrate-free Ringer's solution. Percent of original values after depletion were: oxygen consumption, 61%; glycogen content, 36%; PD, 28%; SCC, 19%. PD and SCC responded to addition of substrate (5.5mm glucose plus 2mm pyruvate) by a lag period of approximately 2 hr followed by progressive increases lasting for many hours. Other experiments utilized split bladders. The epithelium and adhering connective tissue (mucosal fraction) were separated from the underlying smooth muscle and connective tissue (serosal fraction) and the oxygen consumption and glycogen content of slices of the two fractions determined. Mucosal oxygen consumption declined to 48% of the original value during depletion while serosal oxygen consumption (initially much lower than mucosal) was well-maintained at 95% of the original value. Substantial net synthesis of glycogen took place in both fractions of depleted bladders after addition of substrate. The ratio of moles of oxygen consumed to moles of glucose (from glycogen) disappearing during the 18-hr depletion period was approximately 5.5 for serosal tissue and within the range 30 to 61 for mucosal tissue. The mucosal ratio was incompatible with the utilization of glycogen as the major endogenous substrate during depletion under aerobic conditions. It is suggested that the oxidation of lipid supports most of the endogenous metabolism in the mucosal tissue of the turtle bladder.     

Effect of sodium transport inhibition on active phosphate transport by toad bladder

Summary The relationship between active Na transport (estimated by the short-circuit (SCC)) and active inorganic phosphate (P_i) transport was studied in the toad bladder. When SCC was inhibited by amiloride, ouabaim, or removal of K from the serosal bathing solution, active P_i transport was totally inhibited. When Na was replaced isotonically by choline in either the mucosal bathing solution or both the mucosal and serosal bathing solutions, there was no measurable SCC or active P_i transport. These experiments are compatible with the hypothesis that active P_i transport occurs only in the presence of active Na transport.     

Pathways for movement of ions and water across toad urinary bladder

Hypertonicity of the mucosal bathing medium increases the electrical conductance of toad urinary bladder by osmotic distension of the epithelial "tight" or limiting junctions. However, toad urine is not normally hypertonic to plasma. In this study, the transmural osmotic gradient was varied strictly within the physiologic range; initially hypotonic mucosal bathing media were made isotonic by addition of a variety of solutes. Mucosal NaCl increased tissue conductance substantially. This phenomenon could not have reflected soley an altered conductance of the transcellular active transport pathway since mucosal KCl also increased tissue conductance, whether or not Na+ was present in the bathing media. The effect of mucosal NaCl could not have been mediated solely by a parallel transepithelial pathway formed by damaged tissue since mucosal addition of certain nonelectrolytes also increased tissue conductance. Finally, the osmotically-induced increase in conductance could not have occurred soley in transcellular transepithelial channels in parallel with the active pathway for Na+, since the permeability to 22Na from serosa to mucosa (s to m) was also increased by mucosal addition of NaCl; a number of lines of evidence suggest that s-to-m movement of Na+ proceeds largely through paracellular transepithelial pathways. The results thus establish that the permeability of the limiting junctions is physiologically dependent on the magnitude of the transmural osmotic gradient. A major role is proposed for this mechanism, serving to conserve the body stores of NaCl from excessive urinary excretion.     

Effect of furosemide on ion transport in the turtle bladder: evidence for direct inhibition of active acid-base transport

The diuretic furosemide inhibits acid-base transport in the short-circuited turtle bladder. It inhibits luminal acidification when present in either mucosal or serosal bathing fluids, but decreases alkalinization only from the serosal side of the tissue. The inhibition of both acid-base transport processes is independent of ambient Cl-; and the disulfonic stilbene, SITS, an inhibitor of Cl--HCO3- exchange, fails to prevent the furosemide-elicited inhibition of alkalinization. These results preclude an absolute requirement of a furosemide-sensitive Cl--HCO3- exchange by these transport processes. The drug also interferes with the CO2-induced stimulation of acidification and alkalinization. The inhibition of the residual acidification in acetazolamide-treated, acidotic bladders, however, suggests an action at sites other than cytosolic carbonic anhydrase. Although active Na+ and Cl- reabsorption and tissue oxygen uptake are also decreased by furosemide, the rate of oxygen consumption uncoupled by 2,4-dinitrophenol is not diminished, indicating a primary inhibition of the various ion transport processes, not of metabolism. It is proposed that inhibition of transepithelial acid-base transport by furosemide in the turtle bladder includes inhibition of the acid-base pumps.     

Sodium uptake across the apical border of the isolated turtle colon: Confirmation of the two-barrier model

Summary The initial rate of Na uptake by the turtle colon from the mucosal bathing solution consists of two operationally distinct components. One component is a linear function of mucosal Na concentration, is unaffected by amiloride, and appears to represent Na uptake into the paracellular shunt path. The major component of Na uptake is abolished by amiloride and is virtually equal to the short-circuit current over a wide range of. mucosal Na concentrations, suggesting that this portion of Na uptake represents Na movement into Na-transporting cells of the colon. The amiloride-sensitive component of Na uptake, at low mucosal Na concentrations, was unaffected if net Na transport was abolished by ouabain. Similarly, at low mucosal Na concentrations the amiloride-sensitive conductance of the colon was identical in the presence and in the absence of net Na transport.These results show that the isolated turtle colon behaves, as two distinct barriers to transmural Na transport, an apical barrier blocked by amiloride and a more basal-lying barrier where active, transmural Na transport is blocked by ouabain. In addition, these experiments appear to provide the first unambiguous demonstration that the initial-rate isotope uptake technique can provide adirect measure of the properties of the amiloridesensitive barrier to transmural Na movement, presumably the apical membranes of the Na-transporting cells. The results are consistent with the notion that the rate of transmural active Na transport and the conductance of the active Na-transport path are determined by the properties of the apical membrane.     

Active pyrimidine absorption by chicken colon

Pyrimidine absorption by chicken large intestine was investigated employing the everted sac and flux chamber techniques. 3H-labelled uracil was used as substrate. The small intestine and the colon unlike the caecum, transported uracil from the mucosal to the serosal surface against a concentration gradient in the everted sac experiments. Furthermore, there was a net transport of uracil from the mucosal to the serosal side of the colon and jejunum in the flux chamber experiments. Uracil transport by the everted colon sacs against a concentration gradient was inhibited when the purine hypoxanthine was present in the incubation medium. Uracil transport by the everted colon sacs was also inhibited under anaerobic conditions and when 2,4-dinitrophenol was present in the incubation medium. Replacing the Na+ ions of the incubation medium by Li+ ions also caused an inhibition of uracil transport. It is concluded from these results that uracil (and probably other pyrimidines) are absorbed from the chicken colon by a Na+ ion-dependent active transport process having also an affinity for purines.     

Response of transmural electrical parameters across in vitro everted sacs of hamster jejunum to variations in oxygenation rate.

1. The response of the electrical potential difference, short circuit current, and resistance across everted sacs of hamster jejunum to variations in the mucosal solution gassing rate was investigated. 2. Contrary to previous reports by others, it was found that the potential difference responds to increases in mucosal solution gassing rate by increasing in magnitude during the first 20 min of incubation. 3. The increases in potential difference were parallelled by increases in short circuit current but not by changes in resistance. 4. Increases in mucosal solution gassing rate increased epithelial cell O2 availability and this effect was determined to be due to increased stirring by gas bubbles. From the data, it was deduced that the minimum thickness of the mucosally located functional unstirred layer is between 0.08 and 0.16 cm when less than the full magnitude of electrical activity is observed across the everted sac preparation. 5. Serosal N2 or O2 had little or no effect on electrical parameters under maximum mucosal oxygenating conditions but dramatically affected these parameters when less than maximum mucosal oxygenating conditions were used. 6. Qualitative variations in the magnitude of the short circuit current across this preparation with respect to Cl- dependence were demonstrated. These variations were dependent upon the level of O2 availability, being apparent at high levels of O2 and absent at low levels. 7. It is concluded that the thickness of mucosally located unstirred layers can determine the O2 availability to the mucosa of everted sacs of hamster jejunum and thereby influence the observable magnitude and pattern of ionic dependence of the short circuit current across this preparation.     

Steady-state metabolism and transport of d-glucose by rat small intestine in vitro

1. Conditions of incubation of everted sacs of rat small intestine were selected to ensure that absorption of d-glucose by mucosal tissue from the incubation medium, intracellular metabolism of the absorbed glucose and transport of glucose through the intact intestinal tissue proceeded linearly with respect to time of incubation within stated time intervals. 2. Under these experimental conditions, steady intracellular concentrations of glucose and lactate were demonstrated. 3. The quantitative translocational and metabolic fate of absorbed glucose was determined under these steady-state conditions. About 25% of glucose absorbed from the external mucosal solution was accumulated (temporarily) within mucosal tissue and about 25% transported through the intact tissue into the external serosal solution; the remainder (about 50%) of the absorbed glucose was metabolized, 90% to lactate and 10% to CO₂. Concomitant respiration rates were comparable with those reported for several other preparations of intestine and were stoicheiometrically in excess of the O₂ metabolism required to account for the production of CO₂ from the absorbed glucose. 4. Water transport through the everted sacs proceeded at an optimum rate under the experimental conditions selected. 5. Some other observations are recorded which influenced the design of the experiments and the interpretation of results; these include the initial physiological state of the animal, the anaesthetic used and the ionic composition of the incubation medium.     

Polycations. A new class of inhibitors for in vitro small intestinal transport of sugars and amino acids in the rat

Polycationic compounds like polylysine, protamine or polyethylenimine may interfere with a cation-related membrane transport system depending on superficially accessible binding sites for particular cations. In vitro experiments were performed using either everted segments of rat small intestine to measure tissue accumulation or everted sacs to determine mucosal-to-serosal transport. The effect of polycations was also tested using brush-border membrane vesicles of rat jejunum. Polycations inhibited the tissue accumulation of methyl α-d-glucoside as well as binding of phlorizin. Inhibition of accumulation was increased by raising the polycation concentration and by preincubation of the tissue with the polycations. Kinetic experiments revealed a competitive type of inhibition for the uptake of neutral amino acids and actively transported sugars. Using everted sacs to compare the monomeric cations with their corresponding polymeric forms for their inhibitory effect, it was found that only polymers applied to the mucosal compartment impaired active transport. The passive diffusion of solutes, e.g. 2-deoxy-d-glucose or mannitol, was slightly increased by polycations. With some intermediate oligomers of lysine it could be shown that more than 20 cationic groups are required for approximate complete inhibition. That membrane-related events are responsible for the observed inhibition is suggested by the reduced uptake of d-glucose by brush-border membrane vesicles in the presence of polycations. Therefore an interaction with transport-related cation binding sites, i.e. anionic residues, at the mucosal surface may be assumed.     

Intracellular activities of chloride, potassium and sodium ions in rabbit corneal epithelium

The mechanism of ion transport in the epithelium of rabbit cornea was studied by determining the intracellular ion activity of Cl-, Na+ and K+ under various conditions. Ionic activities were measured by means of microelectrodes containing liquid ion-exchangers selective for Cl-, Na+ or K+. The Cl- activity in basal cells of the epithelium in Na+ containing bathing solutions amounts to 28 +/- 2 mM (n = 11). This value is 1.9-times greater than expected on the basis of passive distribution across the tear side membrane. This finding suggests the existence of a Cl- accumulating process. Replacement of Na+ in the aqueous bathing solution by choline or tetraethylammonium results in a reversible decrease in Cl- activity to 22 +/- 1 mM (n = 11, P less than 0.025). The ratio of observed and predicted Cl- activity decreased significantly from 1.9 to 1.4 (P less than 0.05). The decrease in Cl- activity due to Na+ replacement was rather slow. In contrast, after readmittance of Na+ to the aqueous bathing solution, Cl- activity rose to a stable level within 30 min. These results indicate involvement of Na+ in Cl- accumulation into the basal cells of the epithelium. The K+ and Na+ activities of the basal cells of rabbit corneal epithelium in control bathing solutions were 75 +/- 4 mM (n = 13) and 24 +/- 3 mM (n = 12), respectively. The results can be summarized in the following model for Cl- transport across corneal epithelium. Cl- is accumulated in the basal cells across the aqueous side membrane, energized by a favourable Na+ gradient. Cl- will subsequently leak out across the tear side membranes. Na+ is extruded again across the aqueous side membrane of the epithelium by the (Na+ + K+)-ATPase.     

P-chloromercuribenzene sulfonate blocks and reverses the effect of amiloride on sodium transport across rabbit colon in vitro.

The addition of 10(-3) M p-chloromercuribenzene sulfonate (PCMBS) to the solution bathing the mucosal surface of rabbit colon has no effect on the rate of active Na transport but blocks or reverses the inhibitory action of amiloride. The tissue must be exposed to PCMBS for 20-30 min for a complete blocking effect, and removal of PCMBS from the mucosal solution after this period of exposure does not restore the sensitivity of the tissue to amiloride. The slow time-courses of the blocking and reversal effects suggest that PCMBS does not irreversibly interact with groups directly involved in the binding of amiloride.     

Interaction between the Effects of Inside and Outside Na and K on Bullfrog Skin Potential

The composition of the solution bathing one border of the isolated frog skin affects the response of the potential across the skin to changes in the composition of the solution bathing the opposite border. Increasing the K concentration of the inside (corium) bathing solution decreased the sensitivity of the potential to a change in outside Na concentration. Decreasing the outside Na concentration decreased the sensitivity of the potential to a change in inside K concentration. Increasing the total ionic strength of the outside bathing solution or of both bathing solutions decreased the sensitivity of the potential to a change in outside Na concentration.     

Salt and water transport by rabbit and guinea pig gallbladder: Effect of amphotericin B on NaCl influx

Summary Previous studies have led to the suggestion that salt and water absorption by rabbit and guinea pig gallbladders exposed to Amphotericin B proceeds by a rheogenic Na pump at the basolateral cell membrane. The present studyin vitro was designed to further characterize transport properties of rabbit and guinea pig gallbladders under control conditions and to identify the properties of gallbladder mucosa which are altered by Amphotericin B to allow for the induced serosa-positive electrical potential differences (PD). Potassium is required in the bathing solution at a low concentration to maintain normal tissue O₂ consumption, fluid absorption and the ability of the tissue to develop the maximum Amphotericin B-induced PD; the relative effectiveness of alkali metal cations in substituting for K is KRb>Cs>Li>Na. The carrier mechanism for coupled influx of Na and Cl across the mucosal border of gallbladder appears to be functional in the presence of Amphotericin B; in addition, the diffusional influx of chloride is not significantly altered by the antibiotic. The primary action of Amphotericin B which appears to modify rabbit and guinea pig gallbladders from having transmural PD's of less than ±1 mV to having serosa-positive PD's of 5–30 mV is an increase in the mucosal cell membrane permeability to Na. This permeability change has the effect of partially uncoupling NaCl influx. A rheogenic Na pump mechanism at the basolateral membrane, presumably in operation under control conditions also, may account for the PD.     

Role of exchange transport in the absorption of L-tryptophan in the small intestine of chicks

1. In in vitro experiments with accumulating mucosal preparations (AMP) and everted intestinal sacs, as well as in in vivo experiments with isolated loops of the small intestine the stimulating effect of a number of amino acids on L-tryptophan uptake was investigated. 2. Under "switched off" active transport (anoxia, 2,4-DNF treatment, sodium ion replacement by lithium ions in the mucosal solution) an expressed stimulation of L-tryptophan transport was observed within the mucosa and across the wall of the small intestine in the presence of L-proline, glycine, L-alpha-alanine, L-histidine and L-lysine. 3. Preincubation of AMP in the solutions of glycine, L-alpha-alanine and L-lysine was characterized by a stimulation of L-tryptophan transport, and the increase of its concentration in tissue was accompanied by the exit of an equivalent amount of glycine from it. 4. These observations show the participation of exchange transport in the uptake of L-tryptophan in the small intestine of chicks. 5. The mechanism of exchange transport in chicks starts to function on the 25th day after hatching and its intensity depends on the character of amino acid-modifier participating in the process. 6. Maximum activity of the exchange transport of L-tryptophan is demonstrated in the middle ileum. 7. L-alpha-Alanine stimulates the absorption of L-tryptophan from the isolated intestinal loop proving the existence of an exchange transport mechanism in a living organism. 8. An increased intensity of exchange transport is observed when feeding chicks with diets deficient and enriched in tryptophan.     

Evidence for electronogenic sodium pumping in the ductal epithelium of rabbit salivary gland and its relationship with (Na+ plus K+)-ATPase.

The temperature dependence of the transepithelial potential difference (PD) of the main duct of the submaxillary gland has been measured during in vitro perfusion studies. The magnitude of the PD depends strongly on the anion composition of the perfusing and bathing fluids. The following combinations of perfusion and bathing fluids respectively were used: (1) Na2SO4/NaCl, (2) Na2SO4, (3) NaCl/-NaCl, (4) NaCl/Na2SO4. The mean transepithelial potential differences at 35 degrees C with these four sets of conditions were respectively: 144, 148, 10 and - 15 mV, serosal side positive with respect to lumen. From the data obtained it was possible to construct Arrhenius plots of temperature dependence of the PD for the four sets of experimental conditions. They all show a breakpoint between 16 and 19 degrees C. The apparent activation energies in the four situations above the breakpoint are 4.2, 1.4, 12.0 and 10.6 kcal/mol, respectively. Below the breakpoint they are 29.9, 37.5, 29.0 and 31.3 kcal/mol, respectively. The rapid change in the PD as a function of temperature (which can also be achieved by the addition of ouabain), the effects of the removal of K+ on the serosal side on the PD, the decrease in the PD after the addition of ouabain or CN-, and the activation energies and breakpoints all lead to the conclusion that a large part of the PD is caused by an electrogenic sodium pump which is very probably the enzyme (Na+ plus K+)-ATPase. When the duct is perfused with Na2SO4 we find, above the breakpoint in the Arrhenius plots, a lower activation energy than is found when perfusing with NaCl.     

Stages of uptake and incorporation of micellar palmitic acid by hamster proximal intestinal mucosa

The stages of uptake and incorporation of micellar palmitic acid by hamster proximal intestinal mucosa were investigated by incubation of everted sacs at 4 degrees C and 37 degrees C for 2, 5, 10, and 15 min in a micellar solution (10 micro moles of [1-(14)C]palmitic acid, 10 micro moles of monoolein, and 100 micro moles of sodium taurodeoxycholate) and subsequent serial rinsing of the sacs in ice-cold solutions as follows: one 20-sec rinse in unlabeled micellar solution, five 1-min rinses in Krebs-Ringer buffer (0.15 m, pH 6.3), and ten 2-min rinses in 2.5% albumin solution. The fatty acid-solubilizing capacity of all the rinsing solutions was always in excess of the amounts of radioactive palmitic acid released during each rinse. Radioactivity was determined in the tissue homogenates, rinsing solutions, and serosal fluids. The results indicate that a significant proportion of radioactive palmitic acid taken up by the sacs during the short incubation was released into the rinsing solutions. Rinsing in Krebs-Ringer buffer resulted in release of 15.5 +/- 2.4% of the labeled fatty acid, and this fraction was independent of the temperature of incubation. In contrast, the amounts of palmitic acid released in albumin were significantly greater and were markedly dependent on the temperature of incubation; a total of 48.6 +/- 7.0% and 26.3 +/- 5.1% was released from sacs incubated at 4 degrees C and 37 degrees C, respectively. While the proportion of radioactive palmitic acid in the free fatty acid fraction of the tissue after the rinsing sequence remained reasonably constant regardless of the temperature and duration of incubation, the radioactivity of the esterified palmitic acid in the tissue was much greater in the sacs incubated at 37 degrees C and tended to increase linearly up to 10 min of incubation. A highly significant inverse relationship was found between the fraction of radioactive palmitic acid released by rinsing in albumin and the fraction of the label in the tissue esterified fatty acids. The results suggest that the initial uptake of micellar fatty acid by intestinal mucosa may involve reversible binding to superficial sites with at least two strengths of binding: a weak, temperature-independent binding which could be easily dissociated by rinsing in Krebs-Ringer buffer, and a stronger, temperature-dependent binding which could be dissociated by rinsing in albumin, but not in Krebs-Ringer buffer. Analogous binding of micellar palmitic acid occurred in a brush border preparation of proximal intestine which was devoid of any fatty acid esterifying activity. This suggested that the reversible binding of fatty acid by the intestinal mucosa may be a property of its superficial components, namely the glycocalyx or microvillous membranes, and that it may be independent of the esterifying capacity of the tissue.