Assembly of a GPCR-G Protein Complex.

The activation of G proteins by G protein-coupled receptors (GPCRs) underlies the majority of transmembrane signaling by hormones and neurotransmitters. Recent structures of GPCR-G protein complexes obtained by crystallography and cryoelectron microscopy (cryo-EM) reveal similar interactions between GPCRs and the alpha subunit of different G protein isoforms. While some G protein subtype-specific differences are observed, there is no clear structural explanation for G protein subtype-selectivity. All of these complexes are stabilized in the nucleotide-free state, a condition that does not exist in living cells. In an effort to better understand the structural basis of coupling specificity, we used time-resolved structural mass spectrometry techniques to investigate GPCR-G protein complex formation and G-protein activation. Our results suggest that coupling specificity is determined by one or more transient intermediate states that serve as selectivity filters and precede the formation of the stable nucleotide-free GPCR-G protein complexes observed in crystal and cryo-EM structures.

The XFP (17-BM) beamline for X-ray footprinting at NSLS-II.

Hydroxyl-radical mediated synchrotron X-ray footprinting (XF) is a powerful solution-state technique in structural biology for the study of macromolecular structure and dynamics of proteins and nucleic acids, with several synchrotron resources available to serve the XF community worldwide. The XFP (Biological X-ray Footprinting) beamline at the NSLS-II was constructed on a three-pole wiggler source at 17-BM to serve as the premier beamline for performing this technique, providing an unparalleled combination of high flux density broadband beam, flexibility in beam morphology, and sample handling capabilities specifically designed for XF experiments. The details of beamline design, beam measurements, and science commissioning results for a standard protein using the two distinct XFP endstations are presented here. XFP took first light in 2016 and is now available for general user operations through peer-reviewed proposals. Currently, beam sizes from 450 µm × 120 µm to 2.7 mm × 2.7 mm (FWHM) are available, with a flux of 1.6 × 1016 photons s-1 (measured at 325 mA ring current) in a broadband (∼5-16 keV) beam. This flux is expected to rise to 2.5 × 1016 photons s-1 at the full NSLS-II design current of 500 mA, providing an incident power density of >500 W mm-2 at full focus.

Dissection of porphyrin-induced conformational dynamics in the heme biosynthesis enzyme ferrochelatase.

Human ferrochelatase (EC 4.99.1.1) catalyzes the insertion ferrous iron into protoporphyrin IX as the last step in heme biosynthesis, an essential process to most organisms given the vast intracellular functions of heme. Even with multiple ferrochelatase structures available, the exact mechanism for iron insertion into porphyrin is still a matter for debate. It is clear, however, that conformational dynamics are important for porphyrin substrate binding, initial chelation of iron, insertion of iron into the macrocycle, and release of protoheme IX. In this work we characterize conformational and dynamic changes in ferrochelatase associated with porphyrin binding using the substrate mesoporphyrin (MPIX) and backbone amide hydrogen/deuterium exchange mass spectrometry (HDX-MS). In general, regions surrounding the active site become more ordered from direct or indirect interactions with the porphyrin. Our results indicate that the lower lip of the active site mouth is preorganized for efficient porphyrin binding, with little changes in backbone dynamics. The upper lip region has the most significant change in HDX behavior as it closes the active site. This movement excludes solvent from the porphyrin pocket, but leads to increased solvent access in other areas. A water lined path to the active site was observed, which may be the elusive iron channel with final insertion via the M76/R164/Y165 side of the porphyrin. These results provide a rigorous view of the ferrochelatase mechanism through the inclusion of dynamic information, reveal new structural areas for functional investigation, and offer new insight into a potential iron channel to the active site.

Heterotrifunctional chemical cross-linking mass spectrometry confirms physical interaction between human frataxin and ISU.

The progressive neurodegenerative disease Friedreich's ataxia is caused by a decreased level of expression of frataxin, a putative iron chaperone. Frataxin is thought to transiently interact with ISU, the scaffold protein onto which iron-sulfur clusters are assembled, to deliver ferrous iron. Photoreactive heterotrifunctional chemical cross-linking confirmed the interaction between frataxin and ISU in the presence of iron and validated that transient interactions can be covalently trapped with this method. Because frataxin may participate in transient interactions with other mitochondrial proteins, this cross-linking approach may reveal new protein partners and pathways in which it interacts and help deduce direct, downstream consequences of its deficiency.

Fast Protein Footprinting by X-ray Mediated Radical Trifluoromethylation.

Synchrotron radiolysis generates hydroxyl radicals (•OH) that are successful footprinting reagents. Here, we describe a new reagent for the synchrotron platform, the trifluoromethyl radical (•CF3). The radical is produced by •OH displacement of •CF3 from sodium triflinate (Langlois reagent). Upon X-ray beam exposure, the reagent labels proteins extensively without any additional chemicals on a millisecond or shorter time scale. The •CF3 is comparably reactive to •OH and produces footprinting information that complements that of •OH alone. This reagent in combination with •OH should enable novel chemistry for protein footprinting on the synchrotron platform.