Acid-sensing ion channels (ASICs) are voltage-independent, proton-activated receptors that belong to the epithelial sodium channel/degenerin family of ion channels and are implicated in perception of pain, ischaemic stroke, mechanosensation, learning and memory. Here we report the low-pH crystal structure of a chicken ASIC1 deletion mutant at 1.9 A resolution. Each subunit of the chalice-shaped homotrimer is composed of short amino and carboxy termini, two transmembrane helices, a bound chloride ion and a disulphide-rich, multidomain extracellular region enriched in acidic residues and carboxyl-carboxylate pairs within 3 A, suggesting that at least one carboxyl group bears a proton. Electrophysiological studies on aspartate-to-asparagine mutants confirm that these carboxyl-carboxylate pairs participate in proton sensing. Between the acidic residues and the transmembrane pore lies a disulphide-rich 'thumb' domain poised to couple the binding of protons to the opening of the ion channel, thus demonstrating that proton activation involves long-range conformational changes.
Leucine rich repeat kinase 2 (LRRK2) has been genetically linked to Parkinson's disease (PD) by genome-wide association studies (GWAS). The most common LRRK2 mutation, G2019S, which is relatively rare in the total population, gives rise to increased kinase activity. As such, LRRK2 kinase inhibitors are potentially useful in the treatment of PD. We herein disclose the discovery and optimization of a novel series of potent LRRK2 inhibitors, focusing on improving kinome selectivity using a surrogate crystallography approach. This resulted in the identification of 14 (PF-06447475), a highly potent, brain penetrant and selective LRRK2 inhibitor which has been further profiled in in vivo safety and pharmacodynamic studies.
Sickle cell disease (SCD) is a genetic
disorder caused by a single
point mutation (β6 Glu → Val) on the β-chain of
adult hemoglobin (HbA) that results in sickled hemoglobin (HbS). In
the deoxygenated state, polymerization of HbS leads to sickling of
red blood cells (RBC). Several downstream consequences of polymerization
and RBC sickling include vaso-occlusion, hemolytic anemia, and stroke.
We report the design of a noncovalent modulator of HbS, clinical candidate
PF-07059013 (23). The seminal hit molecule was discovered
by virtual screening and confirmed through a series of biochemical
and biophysical studies. After a significant optimization effort,
we arrived at 23, a compound that specifically binds
to Hb with nanomolar affinity and displays strong partitioning into
RBCs. In a 2-week multiple dose study using Townes SCD mice, 23 showed a 37.8% (±9.0%) reduction in sickling compared
to vehicle treated mice. 23 (PF-07059013) has advanced
to phase 1 clinical trials.
This is the first structural observation of a plant product showing high affinity for phospholipase A(2) and regulating the synthesis of arachidonic acid, an intermediate in the production of prostaglandins. The crystal structure of a complex formed between Vipera russelli phospholipase A(2) and a plant alkaloid aristolochic acid has been determined and refined to 1.7 A resolution. The structure contains two crystallographically independent molecules of phospholipase A(2) in the form of an asymmetric dimer with one molecule of aristolochic acid bound to one of them specifically. The most significant differences introduced by asymmetric molecular association in the structures of two molecules pertain to the conformations of their calcium binding loops, beta-wings, and the C-terminal regions. These differences are associated with a unique conformational behavior of Trp(31). Trp(31) is located at the entrance of the characteristic hydrophobic channel which works as a passage to the active site residues in the enzyme. In the case of molecule A, Trp(31) is found at the interface of two molecules and it forms a number of hydrophobic interactions with the residues of molecule B. Consequently, it is pulled outwardly, leaving the mouth of the hydrophobic channel wide open. On the other hand, Trp(31) in molecule B is exposed to the surface and moves inwardly due to the polar environment on the molecular surface, thus narrowing the opening of the hydrophobic channel. As a result, the aristolochic acid is bound to molecule A only while the binding site of molecule B is empty. It is noteworthy that the most critical interactions in the binding of aristolochic acid are provided by its OH group which forms two hydrogen bonds, one each with His(48) and Asp(49).
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