A reinvestigation of the function of the mammalian urinary bladder

Expression and regulation of ClC-5 chloride channels: effects of antisense and oxidants

Genetic mutations of the Cl(-) channel ClC-5 cause Dent's disease in humans. We recently cloned an amphibian ortholog of Xenopus ClC-5 (xClC-5) from the A6 cell line. We now compare the properties and regulation of ClC-5 currents expressed in mammalian (COS-7) cells and Xenopus oocytes. Whole cell currents in COS-7 cells transfected with xClC-5 cDNA had strong outward rectification, Cl(-) > I(-) anion sensitivity, and were inhibited at low pH, similar to previous results in oocytes. In oocytes, antisense xClC-5 cRNA injection had no effect on endogenous membrane currents or the heterologous expression of human ClC-5. Activators of cAMP and protein kinase C inhibitors had no significant effects on ClC-5 currents expressed in either COS-7 cells or oocytes, whereas H-89, a cAMP-dependent protein kinase (PKA) inhibitor, and hydrogen peroxide decreased the currents. We conclude that the basic properties of ClC-5 currents were independent of the host cell type used for expression. In addition, ClC-5 channels may be modulated by PKA and reactive oxygen species.

Direct visualization of the interrelationship between intramembrane and extracellular structures

The apical surface of the toad urinary bladder is covered by an interconnected mesh of glycocalyx, which appears to attach to the plasma membrane bilayer. To evaluate the interrelationship between these extracellular elements and intramembrane structures, a strategy was devised to produce composite replicas that allow the simultaneous visualization of intramembrane particles by freeze-fracture while the glycocalyx mesh is replicated by rotary shadowing of the extracellular surface after freeze-drying. Evaluation of these composite replicas by electron microscopy reveals that contacts occur between extracellular filamentous elements and intramembrane particles. This structural organization may be important for stabilizing intramembrane components and for anchoring extracellular elements to the membrane.

Urinary kallikrein: a physiological regulator of epithelial Na+ absorption

The apical membrane of the mammalian urinary bladder contains two populations of ionic conductances--one Na+ selective and amiloride blockable, the other cation selective and amiloride insensitive (a leak channel). Addition of kallikrein (an enzyme of unknown function normally found in urine) to the mucosal solution of the mammalian urinary bladder epithelium resulted in the loss (over a 2-hr period) of amiloride-sensitive Na+ current and an increase in the leak current that is amiloride insensitive. The rate of hydrolysis of Na+ channels is a first-order process that is concentration (activity) dependent and described by simple Michaelis-Menten kinetics with a maximum rate of 9.5 X 10(-3) min-1. At the activities measured in human urine, the corresponding rate constant will decrease Na+ channel density by 99.5% in 24 hr. Amiloride protects the amiloride-sensitive Na+ channels from degradation but not the leak pathway. The rate of hydrolysis of the leak pathway as well as the kinetics of hydrolysis are the same as that described for the Na+ channel. Of interest is that the leak pathway is hydrolyzed into a form that seems to partition between the apical membrane and mucosal solution (an unstable leak pathway). These results and previous findings suggest a regulatory role for kallikrein in salt and water homeostasis.

Epithelial cell volume modulation and regulation

Epithelial cell volume is a sensitive indicator of the balance between solute entry into the cell and solute exit. Solute accumulation in the cell leads to cell swelling because the water permeability of the cell membranes is high. Similarly, solute depletion leads to cell shrinkage. The rate of volume change under a variety of experimental conditions may be utilized to study the rate and direction of solute transport by an epithelial cell. The pathways of water movement across an epithelium may also be deduced from the changes in cellular volume. A technique for the measurement of the volume of living epithelial cells is described, and a number of experiments are discussed in which cell volume determination provided significant new information about the dynamic behavior of epithelia. The mechanism of volume regulation of epithelial cells exposed to anisotonic bathing solution is discussed and shown to involve the transient stimulation of normally dormant ion exchangers in the cell membrane.

Resistive artifacts in liquid-ion exchanger microelectrode estimates of Na+ activity in epithelial cells

In experiments on the rabbit urinary bladder epithelium we have identified an electrical artifact in certain liquid ion-sensitive microelectrodes. This artifact arises from the high electrical resistance of the ion-sensitive resins which in some cases are comparable to the resistance of the microelectrode glass wall. For Na+-sensitive microelectrodes this situation led to shunting of the exchanger potential and consequently artifactually high calculations of intracellular Na+ in the rabbit urinary bladder epithelium. A method for minimizing this shunting effect is described. After reduction of the shunt the frequency response of the Na+-sensitive microelectrode was increased and the estimated ai Na+ was decreased to 7 mM.