Effect of caffeine on K+ efflux in frog skeletal muscle.

The exposure of frog skeletal muscle to caffeine (3-4 mM) generates an increase of the K+ (42K+) efflux rate coefficient (kK,o) which exhibits the following characteristics. First it is promoted by the rise in cytosolic Ca2+ ([Ca2+]i), because the effect is mimicked by ionomycin (1.25 microM), a Ca2+ ionophore. Second, the inhibition of caffeine-induced Ca2+ release from the sarcoplasmic reticulum (SR) by 40 microM tetracaine significantly reduced the increase in kK,o (DeltakK,o). Third, charybdotoxin (23 nM), a blocker of the large-conductance Ca2+-dependent K+ channels (BKCa channels) reduced DeltakK,o by 22%. Fourth, apamin (10 nM), a blocker of the small-conductance Ca2+-dependent K+ channels (SKCa channels), did not affect DeltakK,o. Fifth, tolbutamide (800 microM), an inhibitor of KATP channels, reduced DeltakK,o by about 23%. Sixth, Ba2+, a blocker of most K+ channels, did not preclude the caffeine-induced DeltakK,o. Seventh, omitting Na+ from the external medium reduced DeltakK,o by about 40%. Eight, amiloride (5 mM) decreased DeltakK,o by 65%. It is concluded that the caffeine-induced rise of [Ca2+]i increases K+ efflux, through the activation of: (1) two channels (BKCa and KATP) and (2) an external Na+-dependent amiloride-sensitive process.

Restoration of TATA-dependent transcription in a heat-inactivated extract of tobacco nuclei by recombinant TATA-binding protein (TBP) from tobacco.

We isolated a complementary DNA (cDNA) that encoded a TATA-binding protein (TBP) from a cDNA library of tobacco (Nicotiana tabacum) suspension-cultured cells (BY-2). A comparison among deduced amino acid sequences of plant TBPs revealed the presence of a long conserved region within the amino acid sequence of the TBP. Genomic Southern analysis revealed that tobacco TBP (tTBP) is encoded by only a small number of copies of a gene in the tobacco genome. Addition of recombinant tTBP to an extract of tobacco nuclei (TNE) enhanced the basal transcriptional activity in vitro. This result indicates that the level of tTBP is a rate-limiting factor for basal transcriptional activity in TNE. We subsequently succeeded in the functional complementation of TATA-dependent initiation of transcription that was associated with a plant promoter in a homologous plant system. Addition of bacterially expressed recombinant tTBP to a heat-inactivated TNE restored transcriptional activity, as did the addition of human TBP. Moreover, heating of the recombinant tTBP eliminated its ability to restore transcriptional activity. It appears that the heat inactivation of TNE was caused by the heat inactivation of tTBP in TNE.

Characteristics of Na(+)-Ca2+ exchange in frog skeletal muscle.

1. Fluxes studies were carried out to investigate the Na(+)-dependent outward movement of Ca2+ in intact frog sartorius muscle from Leptodactylus ocellatus, a preparation for which published data on the subject are sparse. 2. Under normal resting conditions the Na(+)-Ca2+ exchange was not readily detectable. 3. When muscles were exposed to 4 mM caffeine, the rate of fractional loss of Ca2+ (kCa,o) increased by about 50%. Most of this increase exhibits characteristics typical of the Na(+)-Ca2+ antiport working in the forward mode found in other cells. 4. The increase in kCa,o promoted by caffeine was decreased by: (a) 72% in the absence of external Na+ (Nao+); (b) 73% in Na(+)-loaded muscles ([Na+]i = 98 mM); (c) 70% when fibres were depolarized to -27 mV ([K+]o = 50 mM); and (d) 80% in the presence of 5 mM amiloride. 5. Ni2+ (5 mM), an inhibitor of the Na(+)-Ca2+ exchanger current, unexpectedly increased the caffeine-promoted rise in kCa,o. This effect of Ni2+ was associated with a concomitant caffeine-stimulated Ni2+ influx. In the absence of caffeine Ni2+ did not affect kCa,o. 6. It was concluded that: (a) under resting conditions the sarcolemmal Ca2+ pump suffices to handle the cytosolic calcium concentration ([Ca2+]i); (b) Na(+)-Ca2+ activity becomes apparent when [Ca2+]i is substantially increased by caffeine-induced Ca2+ release from the sarcoplasmic reticulum; and (c) the blocking effect of Ni2+ on the current generated by a Na(+)-Ca2+ exchange with a coupling ratio > 2 might actually represent a shift of the antiport mode toward an electroneutral 1 Ni(2+)-1Ca2+ exchange.

Ionic movements mediated by monensin in frog skeletal muscle.

Monensin-mediated ionic movements were studied in frog skeletal muscle. The ionophore, which forms electrically neutral complexes with monovalent cations, induced dose dependent fluxes of Na+, K+ and H+ in and out of the fibers. Monensin concentrations ([MON]) ranged from 2 to 40 microM. In the presence of normal Ringer's solution the following maximum ionic exchanges were generated by monensin (in pmol cm-2 s-1): (1) Nai+/Nao+ 112, (2) Nai+/Ho+ 30.7, (3) Ki+/Nao+ 14.2 (4) Hi+/Nao+ 49. The maximum net fluxes produced by these exchanges (i.e. for [MON] = infinity) are (in pmol cm-2 s-1): Na+ (inward) 32.5, K+ (outward) 14.2, H+ (outward) 18.3. The last one appears to be largely offset by a passive (monensin-independent) H+ influx down an inwardly directed electrochemical gradient promoted by pH reduction of the T-tubular lumen content as a consequence of the monensin-mediated net H+ efflux. Maximum unidirectional cationic fluxes mediated by monensin amounted to 206 pmol cm-2 s-1 and had the following composition: influx: 85% Na+ and 15% H+; efflux: 69% Na+, 7% K+, 24% H+.