BKCa channels activating at resting potential without calcium in LNCaP prostate cancer cells.

Large-conductance Ca2+-dependent K+ (BK(Ca)) channels are activated by intracellular Ca2+ and membrane depolarization in an allosteric manner. We investigated the pharmacological and biophysical characteristics of a BK(Ca)-type K+ channel in androgen-dependent LNCaP (lymph node carcinoma of the prostate) cells with novel functional properties, here termed BK(L). K+ selectivity, high conductance, activation by Mg2+ or NS1619, and inhibition by paxilline and penitrem A largely resembled the properties of recombinant BK(Ca) channels. However, unlike conventional BK(Ca) channels, BK(L) channels activated in the absence of free cytosolic Ca2+ at physiological membrane potentials; the half-maximal activation voltage was shifted by about -100 mV compared with BK(Ca) channels. Half-maximal Ca2+-dependent activation was observed at 0.4 microM: for BK(L) (at -20 mV) and at 4.1 microM: for BK(Ca) channels (at +50 mV). Heterologous expression of hSlo1 in LNCaP cells increased the BK(L) conductance. Expression of hSlo-beta1 in LNCaP cells shifted voltage-dependent activation to values between that of BK(L) and BK(Ca) channels and reduced the slope of the P (open) (open probability)-voltage curve. We propose that LNCaP cells harbor a so far unknown type of BK(Ca) subunit, which is responsible for the BK(L) phenotype in a dominant manner. BK(L)-like channels are also expressed in the human breast cancer cell line T47D. In addition, functional expression of BK(L) in LNCaP cells is regulated by serum-derived factors, however not by androgens.

Effects of imipramine on ion channels and proliferation of IGR1 melanoma cells.

Human IGR1 cells are a model for malignant melanoma. Since progression through the cell cycle is accompanied by transient cell hyperpolarization, we studied the properties of potassium and chloride ion channels and their impact on cell growth. The major potassium current components were mediated by outward rectifying ether à go-go (hEAG) channels and Ca2+-activated channels (KCa) of the IK/SK type. The major chloride channel component was activated by osmotic cell swelling (Clvol). To infer about the contribution of these channels to proliferation, specific inhibitors are required. Since there is no specific blocker for hEAG available, we used the tricyclic antidepressant imipramine, which blocked all channels mentioned, in combination with blockers for KCa (charybdotoxin) and Clvol (DIDS and pamoic acid). Incubation of IGR1 cells for 48 hr in 10-15 mM imipramine reduced DNA synthesis and metabolism without significant effects on apoptosis. hEAG channels were most sensitive to imipramine (IC50: 3.4 microM at +50 mV), followed by KCa (13.8 microM at +50 mV) and Clvol (12 microM at -100 mV), indicating that hEAG expression may be of importance for proliferation of melanoma cells. The contribution of KCa channels could be excluded, as 500 nM charybdotoxin, which completely blocked KCa, had no effect on proliferation. The impact of Clvol also seems to be minor, because 500 microM pamoic acid, which completely blocked Clvol, did not affect proliferation either.

Case reports. Disseminated cryptococcoses without cryptococcal antigen detection.

During the last decade cryptococcoses were most frequently diagnosed in AIDS patients, where serologically high amounts of glucoronoxylomannan (GXM) were detectable. Disseminated cryptococcoses without cryptococcal antigen detection is unusual. Between August and October 1998 disseminated cryptococcoses were diagnosed in three patients consecutively although cryptococcal antigen was not detectable. Only one of the patients was HIV infected.

Fusion and metabolism of plant cells as affected by microgravity.

Plant cell protoplasts derived from leaf tissue of two different tobacco species (Nicotiana tabacum., N. rustica L.) were exposed to short-term (sounding rocket experiments) and long-term (spacelab) microgravity environments in order to study both (electro) cell fusion and cell metabolism during early and later stages of tissue regeneration. The period of exposure to microgravity varied from 10 min (sounding rocket) to 10 d (space shuttle). The process of electro fusion of protoplasts was improved under conditions of microgravity: the time needed to establish close membrane contact between protoplasts (alignment time) was reduced (5 as compared to 15 s under 1 g) and numbers of fusion products between protoplasts of different specific density were increased by a factor of about 10. In addition, viability of fusion products, as shown by the ability to form callus, increased from about 60% to more than 90%. Regenerated fusion products obtained from both sounding-rocket and spacelab experiments showed a wide range of intermediate properties between the two parental plants. This was verified by isozyme analysis and random amplified polymorphic DNA-polymerase chain reaction (RAPD-PCR). In order to address potential metabolic responses, more general markers such as the overall energy state (ATP/ADP ratio), the redox charge of the diphosphopyridine nucleotide system (NADH/NAD ratio), and the pool size of fructose-2,6-bisphosphate (Fru 2,6 bisp), a regulator of the balance between glycolysis and gluconeogenesis, were determined. Responses of these parameters were different with regard to short-term and long-term exposure. Shortly after transition to reduced gravitation (sounding rocket) ratios of ATP/ADP exhibited strong fluctuation while the pool size of NAD decreased (indicating an increased NADH/NAD ratio) and that of Fru 2,6 bisp increased. As similar changes can be observed under stress conditions, this response is probably indicative of a metabolic stress compensation. Samples taken for up to 7 d of exposure to microgravity showed the opposite effect. Here, the ratios of ATP/ADP and of NADH/NAD, and the pool size of Fru 2,6 bisp were decreased. We take this an an indication of metabolic relaxation, i.e. decreased metabolic turnover. As rates of protoplast regeneration and cell division were obviously similar to 1-g controls, we conclude that under conditions of microgravity regenerating tobacco mesophyll protoplasts need less metabolic energy for the same effort.

Regeneration of plant cell protoplasts under microgravity: investigation of protein patterns by SDS-PAGE and immunoblotting.

As part of the D-2 Spacelab mission, tobacco (Nicotiana tabacum L.) protoplasts were cultured for 10 days in microgravity and successfully regenerated into microcalli, which, after further cultivation on the ground, gave rise to intact plants. Protein analysis was performed on samples taken during the initial microgravity period and compared to ground controls. Total protein content and protein patterns were monitored, as well as the cytoskeletal proteins tubulin and actin, a key enzyme of secondary metabolism, phenylalanine ammonia lyase, and the pathogenesis-related protein osmotin. None of the investigated proteins showed a gravity-dependent effect. Since relative changes due to culture age were detectable in the immunoblots as well as in the total protein pattern, an adaptation of the cells to microgravity without major modifications of their protein complement may be assumed.

Regeneration of plant cell protoplasts under microgravity: Investigation of protein patterns by SDS-PAGE and immunoblotting.

As part of the D-2 Spacelab mission, tobacco (Nicotiana tabacum L.) protoplasts were cultured for 10 days in microgravity and successfully regenerated into microcalli, which, after further cultivation on the ground, gave rise to intact plants. Protein analysis was performed on samples taken during the initial microgravity period and compared to ground controls. Total protein content and protein patterns were monitored, as well as the cytoskeletal proteins tubulin and actin, a key enzyme of secondary metabolism, phenylalanine ammonia lyase, and the pathogenesis-related protein osmotin. None of the investigated proteins showed a gravity-dependent effect. Since relative changes due to culture age were detectable in the immunoblots as well as in the total protein pattern, an adaptation of the cells to microgravity without major modifications of their protein complement may be assumed.

Electrofusion of plant cell protoplasts under microgravity--a D-2 spacelab experiment.

Plant cell protoplasts, derived from sexually incompatible plant species, have proved to be a good system for somatic hybridization by electrofusion. Under microgravity, an increase in fusion yield can be expected, especially if the parental cells differ markedly in size or specific density. On the D-2 spacelab mission flown in 1993, electrofusion experiments were performed with three different objects, i.e. tobacco as model system, Helianthus as an important crop, and Digitalis as a plant of pharmacological interest. The resulting fusion products were cultivated (along with parental cells) for 10 days under microgravity, and subsequently regenerated on ground for biochemical analysis. Results are presented on the observation of the fusion process during flight, heterofusion yields, ultrastructural investigation of fusion products immediately after fusion, and characterization of the resulting hybrids. The results are interpreted on the background of earlier microgravity-experiments on sounding rockets or parabolic flights.