Ligand-Specific Allosteric Coupling Controls G-Protein-Coupled Receptor Signaling.

Allosteric coupling describes a reciprocal process whereby G-protein-coupled receptors (GPCRs) relay ligand-induced conformational changes from the extracellular binding pocket to the intracellular signaling surface. Therefore, GPCR activation is sensitive to both the type of extracellular ligand and intracellular signaling protein. We hypothesized that ligand-specific allosteric coupling may result in preferential (i.e., biased) engagement of downstream effectors. However, the structural basis underlying ligand-dependent control of this essential allosteric mechanism is poorly understood. Here, we show that two sets of extended muscarinic acetylcholine receptor M1 agonists, which only differ in linker length, progressively constrain receptor signaling. We demonstrate that stepwise shortening of their chemical linker gradually hampers binding pocket closure, resulting in divergent coupling to distinct G-protein families. Our data provide an experimental strategy for the design of ligands with selective G-protein recognition and reveal a potentially general mechanism of ligand-specific allosteric coupling.

Characterization of methanthelinium binding and function at human M1-M5 muscarinic acetylcholine receptors.

Firstly, it was determined whether methanthelinium bromide (MB) binds to human M1-M5 (hM1-hM5) muscarinic acetylcholine receptors in comparison to the classical muscarinic antagonist N-methylscopolamine (NMS). [3H]NMS dissociation binding experiments revealed an allosteric retardation of dissociation at 100 µM of MB ranging from none in hM3 to 4.6-fold in hM2 receptors. Accordingly, global non-linear regression analysis of equilibrium inhibition binding curves between [3H]NMS (0.2 and 2.0 nM) and MB was applied and compared using either an allosteric or a competitive model. The allosteric cooperativity of MB binding within MB/NMS/hM receptor complexes was strongly negative and undistinguishable from a competitive interaction throughout all subtypes. Applying the competitive model to the equilibrium binding data of MB and NMS, suggested competition at all hM subtypes: logKI (± S.E.) hM3 = 8.71 ± 0.15, hM1 = 8.68 ± 0.14, hM5 = 8.58 ± 0.07, hM2 = 8.27 ± 0.07 to hM4 = 8.25 ± 0.11. Secondly, the effects of MB on acetylcholine (ACh) induced hM receptor function showed very strong negative allosteric cooperativity at all subtypes pointing against an allosteric antagonism of MB with ACh. Competition with ACh was characterized by logKB: hM1 = 9.53 ± 0.05, hM4 = 9.33 ± 0.05, hM5 = 8.80 ± 0.05, hM2 = 8,79 ± 0.06, to hM3 = 8.43 ± 0.04. In conclusion, MB, below 1 µM, binds competitively and non-selectively (except for the difference between hM3 vs. hM4) to all five hM receptor subtypes with nanomolar affinity and is able to functionally inhibit ACh responses in a competitive fashion, with a slight subtype preference for hM1 and hM4.

Repurposing HAMI3379 to Block GPR17 and Promote Rodent and Human Oligodendrocyte Differentiation.

Identification of additional uses for existing drugs is a hot topic in drug discovery and a viable alternative to de novo drug development. HAMI3379 is known as an antagonist of the cysteinyl-leukotriene CysLT2 receptor, and was initially developed to treat cardiovascular and inflammatory disorders. In our study we identified HAMI3379 as an antagonist of the orphan G protein-coupled receptor GPR17. HAMI3379 inhibits signaling of recombinant human, rat, and mouse GPR17 across various cellular backgrounds, and of endogenous GPR17 in primary rodent oligodendrocytes. GPR17 blockade by HAMI3379 enhanced maturation of primary rat and mouse oligodendrocytes, but was without effect in oligodendrocytes from GPR17 knockout mice. In human oligodendrocytes prepared from inducible pluripotent stem cells, GPR17 is expressed and its activation impaired oligodendrocyte differentiation. HAMI3379, conversely, efficiently favored human oligodendrocyte differentiation. We propose that HAMI3379 holds promise for pharmacological exploitation of orphan GPR17 to enhance regenerative strategies for the promotion of remyelination in patients.

Engineered Context-Sensitive Agonism: Tissue-Selective Drug Signaling through a G Protein-Coupled Receptor.

Drug discovery strives for selective ligands to achieve targeted modulation of tissue function. Here we introduce engineered context-sensitive agonism as a postreceptor mechanism for tissue-selective drug action through a G protein-coupled receptor. Acetylcholine M2-receptor activation is known to mediate, among other actions, potentially dangerous slowing of the heart rate. This unwanted side effect is one of the main reasons that limit clinical application of muscarinic agonists. Herein we show that dualsteric (orthosteric/allosteric) agonists induce less cardiac depression ex vivo and in vivo than conventional full agonists. Exploration of the underlying mechanism in living cells employing cellular dynamic mass redistribution identified context-sensitive agonism of these dualsteric agonists. They translate elevation of intracellular cAMP into a switch from full to partial agonism. Designed context-sensitive agonism opens an avenue toward postreceptor pharmacologic selectivity, which even works in target tissues operated by the same subtype of pharmacologic receptor.