We report the results of a selection for single-stranded DNA oligonucleotide ligands to the serine protease thrombin using recently developed methods. This selection yielded a family of DNA sequences that conform to a consensus structure comprised of a unimolecular quadruplex motif and complementary flanking sequences capable of forming an additional Watson-Crick duplex motif. This novel quadruplex/duplex structure was not reported in a previous selection for DNA molecules which bind to thrombin [Bock et al. (1992) Nature 355, 564-566]. All quadruplex/duplex molecules tested bound to thrombin with higher affinity than quadruplex structures lacking the duplex structure. However, binding affinities did not always correlate with inhibitory potency since some molecules with high affinity were not potent inhibitors in vitro. 1H NMR spectroscopy studies demonstrated that the complementarity of bases in the duplex portion of a selected sequence allows it to form multimolecular structures. Constraining these molecules to the unimolecular quadruplex/duplex structure by bridging the 5' and 3' ends of the duplex motif with either triethylene glycol or disulfide bonds improved their thrombin inhibitory activity. All bridged quadruplex/duplex molecules were more potent inhibitors than molecules with only a quadruplex motif. Bridging the ends of these structures not only increased thrombin inhibition but also improved resistance to nucleases in serum more than 40-fold over the unbridged quadruplex. In addition, we have found that both the length and sequence of the duplex motif are important for inhibition.
alpha-latrotoxin (LTX), a 120 kDa protein in black widow spider venom, triggers massive neurotransmitter exocytosis. Previous studies have highlighted a role for both intrinsic pore-forming activity and receptor binding in the action of this toxin. Intriguingly, activation of a presynaptic G protein-coupled receptor, latrophilin, may trigger release independent of pore-formation. Here we have utilized a previously identified ligand of nematode latrophilin, emodepside, to define a latrophilin-dependent pathway for neurotransmitter release in C. elegans. In the pharyngeal nervous system of this animal, emodepside (100 nM) stimulates exocytosis and elicits pharyngeal paralysis. The pharynxes of animals with latrophilin (lat-1) gene knockouts are resistant to emodepside, indicating that emodepside exerts its high-affinity paralytic effect through LAT-1. The expression pattern of lat-1 supports the hypothesis that emodepside exerts its effect on the pharynx primarily via neuronal latrophilin. We build on these observations to show that pharynxes from animals with either reduction or loss of function mutations in Gq, phospholipaseC-beta, and UNC-13 are resistant to emodepside. The latter is a key priming molecule essential for synaptic vesicle-mediated release of neurotransmitter. We conclude that the small molecule ligand emodepside triggers latrophilin-mediated exocytosis via a pathway that engages UNC-13-dependent vesicle priming.
The pharynx of C. elegans is a rhythmically active muscle that pumps bacteria into the gut of the nematode. This activity is maintained by action potentials, which qualitatively bear a resemblance to vertebrate cardiac action potentials. Here, the ionic basis of the resting membrane potential and pharyngeal action potential has been characterized using intracellular recording techniques. The resting membrane potential is largely determined by a K(+) permeability, and a ouabain-sensitive, electrogenic pump. As previously suggested, the action potential is at least partly dependent on voltage-gated Ca(2+) channels, as the amplitude was increased as extracellular Ca(2+) was increased, and decreased by L-type Ca(2+) channel blockers verapamil and nifedipine. Barium caused a marked prolongation of action potential duration, suggesting that a calcium-activated K(+) current may contribute to repolarization. Most notably, however, we found that action potentials were abolished in the absence of external Na(+). This may be due, at least in part, to a Na(+)-dependent pacemaker potential. In addition, the persistence of action potentials in nominally free Ca(2+), the inhibition by Na(+) channel blockers procaine and quinidine, and the increase in action potential frequency caused by veratridine, a toxin that alters activation of voltage-gated Na(+) channels, point to the involvement of a voltage-gated Na(+) current. Voltage-clamp analysis is required for detailed characterization of this current, and this is in progress. Nonetheless, these observations are quite surprising in view of the lack of any obvious candidate genes for voltage-gated Na(+) channels in the C. elegans genome. It would therefore be informative to re-evaluate the data from these homology searches, with the aim of identifying the gene(s) conferring this Na(+), quinidine, and veratridine sensitivity to the pharynx.
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