2,4-dinitrophenol acutely inhibits rabbit atrial Ca2+ -sensitive Cl- current (I(TO2))

We investigated the effects of 2,4-dinitrophenol (DNP), the uncoupler of mitochondrial oxidative phosphorylation, on the Ca2+ -sensitive Cl- current component of the transient outward current (I(TO2)). Amphotericin B perforated-patch, whole-cell patch-clamp technique was employed (35 degrees C) using enzymatically isolated single rabbit atrial myocytes. We defined I(TO2) as the amplitude of the 2 mM 4-aminopyridine resistant transient outward current sensitive to anthracene-9-carboxylic acid (A9C). Between +5 and +45 mV, 0.2 mM A9C inhibited I(TO2) by approximately 70% (n = 13). Within 30 s after application of 0.2 mM DNP, both normal I(TO2) transients (n = 8) and the I(TO2) transients that remained after A9C treatment (n = 8) were inhibited completely. In cells expressing I(TO2) (70% of total), DNP also suppressed an A9C-insensitive slow outward current by approximately 40%, but the holding current at -80 mV was unaffected. There was a approximately 2 min latency between inhibitory effects of DNP and subsequent membrane current increase, presumably caused by activation of the ATP-sensitive K+ channels (n = 16). We conclude that DNP acutely inhibits I(TO2) via a mechanism presumably separate from metabolic inhibition.     

Morphological and functional properties of rat dorsal root ganglion cells cultured in a chemically defined medium

A culture procedure for dorsal root ganglion (DRG) cells is presented using a completely defined culture medium without antibiotics, in combination with mechanical dissociation procedures. This culture procedure allows all dorsal root ganglion cell types to be cocultured for periods of at least 106 days. Some of the dorsal root ganglion neurons, which could be identified by their neurofilaments and the presence of fluoride resistant acid phosphatase, regained their original T-cell appearance within two weeks. After one month in culture ganglion-like reaggregates appeared. Schwann cells, satellite cells and fibroblasts were identified using morphological criteria. All neurons tested maintained excitability during, at least, the first 35 days in culture, since in all cases action potentials could be evoked by current pulses. The method has proved to be useful in the study of morphological, cytochemical and electrophysiological aspects of dorsal root ganglion cell differentiation in vitro.     

Lysosome recruitment and fusion are early events required for trypanosome invasion of mammalian cells.

Trypanosoma cruzi invades most nucleated cells by a mechanism distinct from classical phagocytosis. Although parasites enter at the lysosome-poor peripheral cell margins, lysosomal markers are immediately incorporated into the parasitophorous vacuole. No accumulation of polymerized actin was detected around recently internalized parasites, and disruption of microfilaments significantly facilitated invasion. Lysosomes were observed to aggregate at the sites of trypanosome attachment and to fuse with the vacuole at early stages of its formation. Experimentally induced, microtubule-dependent movement of lysosomes from the perinuclear area to the cell periphery enhanced entry. Conditions that deplete cells of peripheral lysosomes or interfere with lysosomal fusion capacity inhibited invasion. These observations reveal a novel mechanism for cell invasion:recruitment of lysosomes for fusion at the site of parasite internalization.     

Voltage-activated ionic channels and conductances in embryonic chick osteoblast cultures

Summary Patch-clamp measurements were made on osteoblast-like cells isolated from embryonic chick calvaria. Cell-attachedpatch measurements revealed two types of high conductance (100–250 pS) channels, which rapidly activated upon 50–100 mV depolarization. One type showed sustained and the other transient activation over a 10-sec period of depolarization. The single-channel conductances of these channel types were about 100 or 250 pS, depending on whether the pipettes were filled with a low K⁺ (3mm) or high K⁺ (143mm) saline, respectively. The different reversal potentials under these conditions were consistent with at least K⁺ conduction. Whole-cell measurements revealed the existence of two types of outward rectifying conductances. The first type conducts K⁺ ions and activates within 20–200 msec (depending on the stimulus) upon depolarizing voltage steps from <–60 mV to >–30 mV. It inactivates almost completely with a time constant of 2–3 sec. Recovery from inactivation is biphasic with an initial rapid phase (1–2 sec) followed by a slow phase (>20 sec). The second whole-cell conductance activates at positive membrane potentials of >+50 mV. It also rapidly turns on upon depolarizing voltage steps. Activation may partly disappear at the higher voltages. Its single channels of 140 pS conductance were identified in the whole cell and did conduct K⁺ ions but were not highly Cl^– or Na⁺ selective. The results show that osteoblasts may express various types of voltage controlled ionic channels. We predict a role for such channels in mineral metabolism of bone tissue and its control by osteoblasts.     

Voltage-activated ionic channels and conductances in embryonic chick osteoblast cultures

Patch-clamp measurements were made on osteoblast-like cells isolated from embryonic chick calvaria. Cell-attached-patch measurements revealed two types of high conductance (100-250 pS) channels, which rapidly activated upon 50-100 mV depolarization. One type showed sustained and the other transient activation over a 10-sec period of depolarization. The single-channel conductances of these channel types were about 100 or 250 pS, depending on whether the pipettes were filled with a low K+ (3 mM) or high K+ (143 mM) saline, respectively. The different reversal potentials under these conditions were consistent with at least K+ conduction. Whole-cell measurements revealed the existence of two types of outward rectifying conductances. The first type conducts K+ ions and activates within 20-200 msec (depending on the stimulus) upon depolarizing voltage steps from less than -60 mV to greater than -30 mV. It inactivates almost completely with a time constant of 2-3 sec. Recovery from inactivation is biphasic with an initial rapid phase (1-2 sec) followed by a slow phase (greater than 20 sec). The second whole-cell conductance activates at positive membrane potentials of greater than +50 mV. It also rapidly turns on upon depolarizing voltage steps. Activation may partly disappear at the higher voltages. Its single channels of 140 pS conductance were identified in the whole cell and did conduct K+ ions but were not highly Cl- or Na+ selective. The results show that osteoblasts may express various types of voltage controlled ionic channels. We predict a role for such channels in mineral metabolism of bone tissue and its control by osteoblasts.