An investigation of the molecular pharmacology of G protein-coupled receptor 35

G protein-coupled receptors (GPCRs) are seven-pass integral membrane proteins that act as transducers of extracellular signals across the lipid bilayer. Their location and involvement in basic and pathological physiological processes has secured their role as key targets for pharmaceutical intervention. GPCRs are targeted by many of the best-selling drugs on the market and there are a substantial number of GPCRs that are yet to be characterised; these could offer interest for therapeutic targeting. GPR35 is one such receptor that, as a result of gene knockout and genome wide association studies, has attracted interest through its association with cardiovascular and gastrointestinal disease. Elucidation of the basic physiological function of GPR35 has, however, been difficult due a paucity of potent and selective ligands in addition to a lack of consensus on the endogenous ligand. Herein, a focussed drug discovery effort was carried out to identify agonists of GPR35. Various in vitro cellular assays were employed in conjunction with N- or C-terminally manipulated forms of the receptor to investigate GPR35’s signalling profile and to provide an assay format suitable for the characterisation of newly identified ligands. Although GPR35 associates with both Gαi/o and Gα13 families of small heterotrimeric G proteins, the G protein-independent β-arrestin-2 recruitment format was found to be the most suited to drug screening efforts. Small molecule compound screening, carried out in conjunction with the Medical Research Council Technology, identified compound 1 as the most potent ligand of human GPR35 reported at that time. However, the lower efficacy and potency of compound 1 at the rodent species orthologues of GPR35 prevented its use in in vivo studies. A subsequent effort, carried out with Novartis, focused on mast cell stabilisers as putative agonists of GPR35, revealed lodoxamide and bufrolin as highly potent agonists that activated human and rat GPR35 with equal potency. This finding offered–for the first time–the opportunity to employ the same GPR35 ligand between species at a similar concentration, an important factor to consider when translating rodent in vivo functional studies to those in man. Additionally, using molecular modelling and site directed mutagenesis studies, these newly identified compounds were used to aid characterisation of the ligand binding pockets of human and rat GPR35 to reveal the molecular basis of species selectivity at this receptor. In summary, this research effort presents GPR35 tool compounds that can now be used to dissect the basic biology of GPR35 and investigate its contribution to disease.

Quantification of variable palmar ligaments around the triquetrum-hamate joint determined by lunate type

The ligaments of the wrist are highly variable and poorly described, which is more obvious on the ulnar side of the wrist. Previous studies highlighted the potential differences within the ligaments of the wrist but no consensus has been reached. Poor tissue description and inconsistent use of terminology hindered the reproducibility of the results. Improved understanding of the morphological variations between carpal bones may facilitate improved understanding of the ligamentous structure within the wrist. This study aims to identify the potential variations between carpal bones that could be used to separate palmar ligamentous patterns around the triquetrum-hamate joint into subgroups within the sample population. Investigations were performed following a detailed nomenclature and a clear definition of ligamentous structures to facilitate detailed description and reproducible results. Quantitative analyses were conducted using 3D modelling technique. Histological sections were then analysed to identify the structure of each ligamentous attachment. Variable patterns of ligamentous attachments were identified. Differences were not only obvious between samples but also between the right and left hands of the same person. These identifications suggested that the palmar ligamentous patterns around the triquetrum-hamate joint are best described as a spectrum with a higher affinity of the triquetrum-hamate-capitate ligament and the lunate-triquetrum ligament to be associated with type I lunate wrists on one extreme and type II lunate wrists with the palmar triquetrum-hamate ligament, triquetrum-hamate-capitate ligament and palmar radius-lunate-triquetrum ligament attachments at the other extreme. Histological analyses confirmed pervious established work regarding the mechanical role of ligaments in wrist joint biomechanics. Also, there were no significant differences between the quantitative data obtained from the Genelyn-embalmed and unembalmed specimens (p>0.05). The current study demonstrated variable ligamentous patterns that suggest different bone restraints and two different patterns of motion. These findings support previous suggestions regarding separating the midcarpal joint into two distinct functional types. Type I wrists were identified with ligamentous attachments that are suggestive of rotating/translating hamate whilst type II wrists identified with ligamentous attachments that are suggestive of flexing/extending hamate motion based upon the patterns of the ligamentous attachments in relation to the morphological features of the underlying lunate type of the wrist. This opens the horizon for particular consideration and/or modification of surgical procedures, which may enhance the clinical management of wrist dysfunction.