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Time-resolved X-ray solution scattering (TR-XSS) is a synchrotron-based methodology that enables real-time structural characterization under near-native conditions to provide insight into dynamic and transient structural changes inaccessible to static high-resolution methods such as cryo-electron microscopy (cryo-EM) or X-ray crystallography. Here, we present a workflow for light-triggered TR-XSS experiments that spans data collection, data processing, kinetic analysis, and structural refinement, with accompanying Python scripts. A calcium-transporting P-type ATPase membrane protein (LMCA1) is used as an illustrative example, but the protocol is broadly applicable to diverse protein systems. This workflow offers a practical framework for collecting TR-XSS synchrotron data and subsequent data analysis and interpretation.

Protein molecules typically carry out their biological function by adopting multiple, transient conformations, which complicates their structural characterization. Synchrotron-based time-resolved X-ray solution scattering (TR-XSS) combined with triggering by caged compounds enables real-time monitoring of protein structural transitions in a wide range of protein targets. However, non-instantaneous release of photosensitive cages and undefined equilibrium states complicate data interpretation. In this work, we addressed these challenges with the Escherichia coli adenylate kinase (AdK) enzyme as a model system. To account for, and visualize, heterogeneity resulting from overlap between the ATP release kinetics and protein catalytic motions, we based the structural refinement on ensembles from a pool of putative target structures generated by molecular dynamics (MD) simulations. Under equilibrium conditions, protein conformations preferentially occupied intermediate states in which the ATP- and AMP-binding domains were never fully opened or closed. Upon ATP availability, ensembles successively shifted toward fully closed and open conformations accompanying partial unfolding, which is consistent with a cracking model for triggering the enzymatic reaction. The findings demonstrate that non-instantaneous substrate release can significantly impact protein transition kinetics but can be tackled with the use of ensemble-based structural refinement. Hence, this work establishes a framework for dissecting rapid protein conformational changes in solution induced by caged compounds.

Calcium (Ca²⁺) signaling is fundamental to cellular processes in both eukaryotic and prokaryotic organisms. While the mechanisms underlying eukaryotic Ca²⁺ transport are well documented, an understanding of prokaryotic transport remains nascent. LMCA1, a Ca²⁺ adenosine triphosphatase (ATPase) from Listeria monocytogenes, has emerged as a prototype for elucidating structure and dynamics in prokaryotic Ca²⁺ transport. Here, we used a multidisciplinary approach integrating kinetics, structure, and dynamics to unravel the intricacies of LMCA1 function. A cryo–electron microscopy (cryo-EM) structure of a Ca²⁺-bound E1 state showed ion coordination by Asp⁷²⁰, Asn⁷¹⁶, and Glu²⁹². Time-resolved x-ray solution scattering experiments identified phosphorylation as the rate-determining step. A cryo-EM E2P state structure exhibited remarkable similarities to a SERCA1a E2-P* state, which highlights the essential role of the unique P-A domain interface in enhancing dephosphorylation rates and reconciles earlier proposed mechanisms. Our study underscores the distinctiveness between eukaryotic and prokaryotic Ca²⁺ ATPase transport systems and positions LMCA1 as a promising drug target for developing antimicrobial strategies.

Proteins are macromolecular machines with roles in all cellular activities and structures. The functional properties of each protein is the result of its combination of 3D-structure and inherent dynamics, and a wealth of structural and dynamic mechanisms have evolved to regulate protein activity. P-type ATPases are membrane transport proteins that hydrolyze ATP to move cations across membranes. These proteins are involved in important biological functions such as Ca²⁺ signaling and Cu⁺ homeostasis, making proper regulation critical. Adenylate kinase (AdK) is a small, soluble protein that plays a role in energy homeostasis by interconverting ATP, AMP, and ADP, which are bound by two substrate binding domains. In this thesis, the effect of regulatory parameters on the structural dynamics of Cu⁺-ATPases and the sarcoplasmic/endoplasmic Ca²⁺-ATPase (SERCA) was investigated, together with the reaction dynamics of AdK.

In Paper III, the human Cu⁺-ATPase ATP7B was simulated with (holo) and without (apo) Cu⁺ bound to the regulatory metal binding domains (MBDs, with MBD^-1 closest to the core protein). In the holo state, the MBD chain was more dynamic and extended, and MBD^-2 approached the membrane Cu⁺ entry site. In Paper IV, the stability of the interaction between MBD^-2 and the Cu⁺-entry site was evaluated using MD simulations, showing that the interaction was stable in the cytosol-open E1 state, but not in the lumen-facing E2P state. An interaction site between MBD^-3 and the cytoplasmic domains was also found, where MBD^-3 might inhibit activity by interfering with functional motions. Finally, in Paper II, Cu⁺ entry into the membrane high-affinity Cu⁺-binding site was simulated, showing that a proposed initial binding site was transient and that the Cu⁺ ion could move deeper into the membrane domain. 

In Paper I, we used time-resolved X-ray solution scattering (TR-XSS) to show a simultaneous closing of the substrate binding domains in AdK, which included a partial unfolding and refolding event in the ATP-binding domain. Paper VI demonstrated that a novel time-resolved setup based on detector readout at the MAX IV beamline CoSAXS could trigger and detect AdK structural dynamics.

In Paper V, TR-XSS experiments showed that the rate-limiting step in skeletal-muscle SERCA1a was an E1-to-E2P intermediate at both low and high Ca²⁺ concentrations. An inhibitory effect at high Ca²⁺ concentration was explained by a fraction of SERCA molecules stalling in the ATP-binding/phosphorylation step. In Paper VII, TR-XSS experiments showed that the housekeeping isoform SERCA2b, which is slower but has higher Ca²⁺ affinity than the other SERCA isoforms, shared the same rate-limiting step as the SERCA1a isoform, but with a longer rise-time. Deletion of the SERCA2b luminal extension (LE) shifted the rate-limiting step to ATP-binding/phosphorylation, possibly because of LE-stabilization of the ATP-bound structure. These papers demonstrated the capability of TR-XSS to detect changes in rate-limiting steps and to investigate how protein structural dynamics respond to mutations and inhibitory conditions.

Copper transporting P-type (P_1B-1-) ATPases are essential for cellular homeostasis. Nonetheless, the E1-E1P-E2P-E2 states mechanism of P_1B-1-ATPases remains poorly understood. In particular, the role of the intrinsic metal binding domains (MBDs) is enigmatic. Here, four cryo-EM structures and molecular dynamics simulations of a P_1B-1-ATPase are combined to reveal that in many eukaryotes the MBD immediately prior to the ATPase core, MBD⁻¹, serves a structural role, remodeling the ion-uptake region. In contrast, the MBD prior to MBD⁻¹, MBD⁻², likely assists in copper delivery to the ATPase core. Invariant Tyr, Asn and Ser residues in the transmembrane domain assist in positioning sulfur-providing copper-binding amino acids, allowing for copper uptake, binding and release. As such, our findings unify previously conflicting data on the transport and regulation of P_1B-1-ATPases. The results are critical for a fundamental understanding of cellular copper homeostasis and for comprehension of the molecular bases of P_1B-1-disorders and ongoing clinical trials.

Protein dynamics are essential to biological function, and methods to determine such structural rearrangements constitute a frontier in structural biology. Synchrotron radiation can track real-time protein dynamics, but accessibility to dedicated high-flux single X-ray pulse time-resolved beamlines is scarce and protein targets amendable to such characterization are limited. These limitations can be alleviated by triggering the reaction by laser-induced activation of a caged compound and probing the structural dynamics by fast-readout detectors. In this work, we established time-resolved X-ray solution scattering (TR-XSS) at the CoSAXS beamline at the MAX IV Laboratory synchrotron. Laser-induced activation of caged ATP initiated phosphoryl transfer in the adenylate kinase (AdK) enzyme, and the reaction was monitored up to 50 ms with a 2-ms temporal resolution achieved by the detector readout. The time-resolved structural signal of the protein showed minimal radiation damage effects and excellent agreement to data collected by a single X-ray pulse approach.

CoSAXS is a state-of-the-art SAXS/WAXS beamline exploiting the high brilliance of the MAX IV 3 GeV synchrotron. By coupling advances in sample environment control with fast X-ray detectors, millisecond time-resolved scattering methods can follow structural dynamics of proteins in solution. In the present work, four sample environments are discussed. A sample environment for combined SAXS with UV–vis and fluorescence spectroscopy (SUrF) enables a comprehensive understanding of the time evolution of conformation in a model protein upon acid-driven denaturation. The use of microfluidic chips with SAXS allows the mapping of concentration with very small sample volumes. For highly reproducible sequences of mixing of components, it is possible using stopped-flow and SAXS to access the initial effects of mixing at 2 millisecond timescales with good signal to noise to allow structural interpretation. The intermediate structures in a protein are explored under light and temperature perturbations by using lasers to "pump" the protein and SAXS as the "probe". The methods described demonstrate that features at low q, corresponding to cooperative motions of the atoms in a protein, could be extracted at millisecond timescales, which results from CoSAXS being a highly-stable, low background, dedicated SAXS beamline.

ATP7B is a human copper-transporting P_1B-type ATPase that is involved in copper homeostasis and resistance to platinum drugs in cancer cells. ATP7B consists of a copper-transporting core and a regulatory N-terminal tail that contains six metal-binding domains (MBD1-6) connected by linker regions. The MBDs can bind copper, which changes the dynamics of the regulatory domain and activates the protein, but the underlying mechanism remains unknown. To identify possible copper-specific structural dynamics involved in transport regulation, we constructed a model of ATP7B spanning the N-terminal tail and core catalytic domains and performed molecular dynamics (MD) simulations with (holo) and without (apo) copper ions bound to the MBDs. In the holo protein, MBD2, MBD3 and MBD5 showed enhanced mobilities, which resulted in a more extended N-terminal regulatory region. The observed separation of MBD2 and MBD3 from the core protein supports a mechanism where copper binding activates the ATP7B protein by reducing interactions among MBD1-3 and between MBD1-3 and the core protein. We also observed an increased interaction between MBD5 and the core protein that brought the copper-binding site of MBD5 closer to the high-affinity internal copper-binding site in the core protein. The simulation results assign specific, mechanistic roles to the metal-binding domains involved in ATP7B regulation that are testable in experimental settings.

Copper is essential for living cells, yet toxic at elevated concentrations. Class 1B P-type (P1B-) ATPases are present in all kingdoms of life, facilitating cellular export of transition metals including copper. P-type ATPases follow an alternating access mechanism, with inward-facing E1 and outward-facing E2 conformations. Nevertheless, no structural information on E1 states is available for P1B-ATPases, hampering mechanistic understanding. Here, we present structures that reach 2.7 Å resolution of a copper-specific P1B-ATPase in an E1 conformation, with complementing data and analyses. Our efforts reveal a domain arrangement that generates space for interaction with ion donating chaperones, and suggest a direct Cu+ transfer to the transmembrane core. A methionine serves a key role by assisting the release of the chaperone-bound ion and forming a cargo entry site together with the cysteines of the CPC signature motif. Collectively, the findings provide insights into P1B-mediated transport, likely applicable also to human P1B-members.

Membrane proteins govern critical cellular processes and are central to human health and associated disease. Understanding of membrane protein function is obscured by the vast ranges of structural dynamics-both in the spatial and time regime-displayed in the protein and surrounding membrane. The membrane lipids have emerged as allosteric modulators of membrane protein function, which further adds to the complexity. In this review, we discuss several examples of membrane dependency. A particular focus is on how molecular dynamics (MD) simulation have aided to map membrane protein dynamics and how enhanced sampling methods can enable observing the otherwise inaccessible biological time scale. Also, time-resolved X-ray scattering in solution is highlighted as a powerful tool to track membrane protein dynamics, in particular when combined with MD simulation to identify transient intermediate states. Finally, we discuss future directions of how to further develop this promising approach to determine structural dynamics of both the protein and the surrounding lipids.