The mechanism underlying the regulation of the K-channel by the muscarinic receptor was examined with patch-clamp experiments in atrial cells isolated enzymatically from the rabbit heart. The patch-electrode and the recording chamber were perfused with various solutions while the activity of the K-channels in the membrane-patch was recorded continuously. In the absence of muscarinic agonists, opening of K-channels occurred at a low frequency (basal activity). Application of ACh to the bath did not affect the basal activity, but perfusion of the patch electrode with ACh markedly increased the channel activity in the "cell-attached" patch. Application of oxotremorine, i.e. a specific muscarinic agonist, via the pipette also opened K-channels. When the membrane patch was isolated from the cell body ("inside-out" patch), ACh-induced single K-channel currents were still observed, but the frequency was reduced. Perfusion of atropine or scopolamine, two muscarinic antagonists, through the patch-electrode depressed the basal activity. In the case of scopolamine, channel-activity recovered after washing out the drug. The current voltage relationship determined from the basal activity was similar to that of ACh-induced single K-channel currents. The mean open time was 0.49 ms at basal activity and 1.35 ms during the application of 0.1 microM ACh via the patch electrode. Application of oxotremorine via the pipette hardly affected the open-time, it remained at 99 +/- 4% (n = 7) of the control.(ABSTRACT TRUNCATED AT 250 WORDS)
Post-translational protein modification by tyrosine-sulfation plays an important role in extracellular protein-protein interactions. The protein tyrosine sulfation reaction is catalyzed by the Golgi-enzyme called the tyrosylprotein sulfotransferase (TPST). To date, no crystal structure is available for TPST. Detailed mechanism of protein tyrosine sulfation reaction has thus remained unclear. Here we present the first crystal structure of the human TPST isoform 2 (TPST2) complexed with a substrate peptide (C4P5Y3) derived from complement C4 and 3’-phosphoadenosine-5’-phosphate (PAP) at 1.9Å resolution. Structural and complementary mutational analyses revealed the molecular basis for catalysis being an SN2-like in-line displacement mechanism. TPST2 appeared to recognize the C4 peptide in a deep cleft by using a short parallel β-sheet type interaction, and the bound C4P5Y3 forms an L-shaped structure. Surprisingly, the mode of substrate peptide recognition observed in the TPST2 structure resembles that observed for the receptor type tyrosine kinases.
The inward rectifier K channel in rabbit ventricular cells was studied by the patch-clamp method. Single channel currents were recorded in giga-sealed cell-attached patches with 150 mM K+ in the pipette. The slope conductance in the membrane potential range from -140 to -40 mV was 46.6±6.7 pS (mean±S.D., n=16), and was reduced by decreasing [K+] in the pipette (20 or 50 mM). The channel was blocked by an application of Cs+ or Ba2+ (0.04-1 mM) in the pipette. Outwardly directed current, recorded with 50 mM K+ in the pipette, revealed the inward rectification of the single channel current. The probability of the channel being open was 0.33±0.05 (n=10) at the resting potential (RP=-81.7±1.7 mV, n=16) with 150 mM K+ in the pipette, and it decreased with hyperpolarization. The mean open time of the channel was 178±25 msec (n=6) at RP. The closed time of the channel seemed to have two exponential components, with time constants of 11.0±2.0 msec and 1.92±0.52 sec (n=6) at RP. The slower time constant was increased with hyperpolarization. The averaged patch current recorded upon hyperpolarizing pulses demonstrated a time-dependent current decay as expected from the single channel kinetics. The results indicated that the inward rectifier K+ current has time-and voltage-dependent kinetics.
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