The chloride cell: definitive identification as the salt-secretory cell in teleosts.

Chloride-secreting isolated opercular membranes from the seawater-adapted teleost Sarotherodon mossambicus contain the several cell types also seen in the branchial epithelium. The vibrating probe technique has been used to localize conductance and chloride current specifically to the so-called chloride cells, thereby establishing these cells definitively as the extrarenal salt-secretory cells.

The voltage-dependent chloride current conductance of toad skin is localized to mitochondria-rich cells.

The chloride current across the isolated epithelium from saline-acclimated Bufo viridis toads was studied using the extracellular vibrating probe technique. Local peak current densities varying between 5 and 100 microA/cm2 were recorded over subpopulation of mitochondria-rich cells, but never over granulosum cells. These local transepithelial currents had characteristics similar to the activated chloride current observed in the whole skin (Katz, U. and Larsen, E.H. (1984) J. Exp. Biol. 109, 353-371). Replacement of the apical Ringer with chloride-free (nitrate) ringer resulted in reversible reduction in the current at the mitochondria-rich cells. It is concluded that the mitochondria-rich cells are the principal site of passive chloride conductance across the epithelium.

Cycloheximide-induced mitotic delay in Physarum polycephalum.

Cycloheximide pulses applied to Physarum polycephalum surface plasmodia delay mitosis. Pulses applied in G2 cause a delay of mitosis which is linearly dependent on the phase in the cell cycle at which the pulse is applied. A 30 min pulse of 10 micrograms/ml cycloheximide starting in G2 at time t after mitosis induces an excess delay (delay in excess of pulse duration) of the next mitosis of (0.55) t-1.3 h. The excess delays induced by 7 h pulses during G2 are at most 1 h larger. Pulses applied less than 30 min before mitosis induce only small delays.

Ionic currents flow through Micrasterias and Closterium cells during expansion of the primary cell wall.

The results of studies of Micrasterias rotata (Grev.) Ralfs, M. thomasiana Archer (biradiate and uniradiate forms) and Closterium sp. using one- and two-dimensional vibrating probes show that transcellular ionic currents are detectable only around cells undergoing expansion of the primary cell wall (half-cell); current enters local regions of expansion and exits over both the rigid surface of the secondary wall and regions of the primary wall where hardening of the wall prevents further expansion. Current densities remain at steady levels until expansion stops with maturation of the primary wall, whereupon currents are no longer detectable. The temporal and spatial correlation between the currents and regions of wall expansion is particularly evident because morphogenesis of the half-cell is a determinate process. Measurements of inward currents ranged from 0.1 to 5.4 µA · cm(-2), and outward currents ranged from-0.05 to -1.5 µA · cm(-2) measured at 18 µ from the cell surface. The results of ion substitution and channel-blocker studies indicate that the currents may be carried at least in part by Ca(2+), Cl(-), H(+) and K(+) ions. The possible role of a Ca(2+) influx during tip growth in desmids is discussed.

The role of mitochondria-rich cells in the chloride current conductance across toad skin.

In early studies of salt transport across frog and toad skin, it was assumed that chloride movement is extracellular. However, later studies suggested that chloride movement is largely transcellular. Chloride transport across toad skin is greatly diminished in skins of salt-acclimated toads (Bufo viridis) and was correlated with the number of mitochondria-rich (m.r.) cells in the epithelium. The activated chloride conductance could be recovered upon in vitro incubation with theophylline. It was found that the short-circuit current (Isc) and the chloride conductance (Gcl) in toad skin could be separated experimentally by selective use of synthetic oxytocin (Syntocinon) or theophylline, and by substituting impermeable anions for chloride. With the use of the vibrating probe we demonstrated directly that chloride-dependent peak currents are localized only over m.r. cells, under hyperpolarized (V = -100 mV) conditions. It is concluded that the m.r. cells form the principal site for passive chloride movement across amphibian skin. This cellular pathway is regulated through a cyclic AMP-mediated process. It is suggested that the spatial separation of the sodium and chloride channels is essential to maintain the granulosum cells which are engaged in sodium transport hyperpolarized, and thus providing the driving force for the sodium entry into the cells.

Localization and regulation of acid-base secretory currents from individual epithelial cells.

The turtle urinary bladder is composed of different epithelial cell types that are suspected to separately produce electrogenic acid and alkali excretion. We measured the electrical currents produced by individual cells, scanning a two-dimensional vibrating probe over the luminal surface of the bladder. Acidification (outward current) was produced by the type of epithelial cell rich in carbonic anhydrase (CA cells). The measured currents of these cells quantitatively accounted for the total epithelial acidification current. When alkali secretion was induced by adenosine 3',5'-cyclic monophosphate and acidification was inhibited (by luminal pH 4), we measured inward currents localized to a small number of epithelial cells in four bladders but found no localization in the other seven treated bladders. When alkali secretion was localized and induced without inhibiting acidification, we found both cells producing inward current and cells producing outward current, which demonstrated that the two transport functions can occur simultaneously. We conclude that net acid-base secretion can be determined by regulating the transport rates of separate cells.

Localization of ionic pathways in the teleost opercular membrane by extracellular recording with a vibrating probe.

We have adapted the vibrating probe extracellular recording technique to use on an epithelium under voltage clamp in an Ussing chamber. The vibrating probe allows very low drift measurements of current density immediately over the epithelial surface. These measurements allowed sites of electrogenic transport in the epithelium to be localized with a spatial resolution of 5 micrometers. The technique was applied to the opercular membrane of the teleost fish, the tilapia, Sarotherodon mossambicus. The mitochondrion-rich "chloride cells" were shown to be the only sites of electrogenic ion transport in this heterogeneous epithelium. Cell sampling experiments demonstrated variable negative short-circuit currents associated with nearly all of approximately 300 chloride cells examined, which appeared to account for all of the tissue short-circuit current. Current-voltage relations for individual cells were also measured. Conductance associated with chloride cells (i.e. cellular and junctional pathways) accounted for all but 0.5 mS/cm2 of the tissue conductance, with the balance apparently accounted for by leak pathways near the edge of the tissue. Current and conductance associated with other cell types was at least 50-fold smaller than for the chloride cell. Chloride-free solutions reduced chloride cell current and conductance by 98 and 95%, respectively.

Segregation of gastric Na and Cl transport: a vibrating probe and microelectrode study.

The short-circuit current (Isc) of resting Necturus gastric mucosa (approximately 20 microA/cm2) can be attributed to the algebraic sum of the net Cl- secretion and amiloride-inhibitable net Na+ absorption. We have attempted to identify the cell types [surface epithelial cells (SCs) or oxyntic cells (OCs)] responsible for the transport of these ions in Necturus gastric mucosa using microelectrodes (ME) and a vibrating probe (VP). Mucosae were mounted horizontally in an open-topped Plexiglas chamber either serosal side up for basolateral ME impalements of OCs or mucosal side up for apical impalements of SCs and VP measurements. Cell impalements were made under open-circuit conditions, and VP measurements were performed under short-circuit conditions. Impalements of OCs indicate that neither the ratio of their apical to basolateral cell membrane resistances (Ra/Rb = 1.3 +/- 0.2) nor their cell membrane potentials were affected by 10(-6) M mucosal amiloride. In contrast, impalements of SCs indicate that amiloride increased their Ra/Rb from 3.5 +/- 0.2 to 15.6 +/- 1.8 and hyperpolarized both cell membrane potentials by greater than 20 mV. VP measurements showed that the amiloride-induced change in the current from SCs (5.6 microA/cm2) accounted for the amiloride-induced change in the Isc (5.5 microA/cm2). A non-zero current (4.4 +/- 1.0 microA/cm2) measured over SCs in the presence of amiloride was due to contamination from current arising from the gastric crypts that contain the OCs.(ABSTRACT TRUNCATED AT 250 WORDS)