Abstract
Cytokine receptors receive extracellular cues by binding with cytokines to transduce a signaling cascade leading to gene transcription in cells. Their soluble isoforms, functioning as decoy receptors, contain only the ectodomain. Whether the ectodomains of cytokine receptors at the membrane exhibit different conformational dynamics from their soluble forms is unknown. Using Stimulation-2 (ST2) as an example, we performed microsecond molecular dynamics (MD) simulations to study the conformational dynamics of the soluble and the membrane-bound ST2 (sST2 and ST2). Combined use of accelerated and conventional MD simulations enabled extensive sampling of the conformational space of sST2 for comparison with ST2. Using the interdomain loop conformation as the reaction coordinate, we built a Markov State Model to determine the slowest implied timescale of the conformational transition in sST2 and ST2. We found that the ectodomain of ST2 undergoes slower conformational relaxation but exhibits a faster rate of conformational transition in a more restricted conformational space than sST2. Analyses of the relaxed conformations of ST2 further suggest important contributions of interdomain salt-bridge interactions to the stabilization of different ST2 conformations. Our study elucidates differential conformational properties between sST2 and ST2 that may be exploited for devising strategies to selectively target each isoform.
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Introduction
The interleukin-1 (IL-1) family of cytokines and their receptors are key regulators of innate immunity that can initiate inflammatory response in hosts to fend off foreign antigens1,2. Ten IL-1 receptors (IL-1R) have been identified including the IL-1R1, IL-1R2, IL-1R accessory protein (IL-1RAcP or IL-1R3), IL-1R like 1 (IL-1RL1, ST2 or IL-1R4), IL-18Rα/β (or IL-1R4/7) and IL-1R accessory protein like 1 (IL-1RAPL or IL-1R9)3,4. IL-1R are single pass transmembrane proteins that contain an ectodomain (ECD) and a conserved cytoplasmic Toll-IL-1-Receptor (TIR) domain2. The ectodomain consists of three consecutive immunoglobulin-like C2 type-1,2,3 domains (denoted as D1-D3) connected by short linkers. The current model of the IL-1 pathway activation suggests that the IL-1 cytokine binds to its cognate IL-1R to recruit a second IL-1R member forming a hetero-trimeric protein complex and causing dimerization of TIR domains for downstream signaling5. Activation of the IL-1 pathway by extracellular cytokines can be regulated by negative or decoy receptors. The negative receptors, such as IL-1R2, lack the cytoplasmic domain to induce downstream signaling6. The decoy receptors include circulatory soluble receptors7,8 that sequester cytokines and limit the pool of free cytokines for binding to cytokine receptors on the cell membrane. The interplay of the binding between the cytokines and the membrane and soluble cytokine receptors allows to control the strength and duration of cytokine-mediated inflammatory response after cytokines are secreted to blood circulation.
Among the IL-1R members, ST2 is expressed on hematopoietic cells including T helper type 2 (Th2) cells, group 2 innate lymphoid cells (ILC2), regulatory T cells (Tregs) and mast cells9,10. Membrane-bound ST2 binds with the only known ligand IL-33 to recruits IL-1RAcP resulting in TIR domain dimerization between ST2 and IL-1RAcP5,11. Signal transduction via the ST2/IL-33 pathway leads to p38 MAP kinases phosphorylation and nuclear factor (NF)-κB activation11. Activation of the ST2/IL-33 axis in Th2 cells causes secretion of IL-4, IL-5, IL-1312,13,14 and IL-915 that elicit type 2 immune response16. Dysregulation in the ST2/IL-33 signaling has been associated with several disease progression including excessive induction of ST2/IL-33 in Th2 cells14 found in asthma patients17. In patients developing graft versus host disease (GVHD) after hematopoietic cells transplantation (HCT), excessive increases of the sST2 level reduce the pool of IL-3318 for activation of the ST2/IL-33 axis in Th2, ILC2, and Tregs cells that leads to unrestrained inflammation in early GVHD progression19,20,21.
Antibodies20,22 and small-molecule inhibitors23 targeting membrane-bound and soluble ST2 have been reported. Both isoforms contain the same cytokine binding domains. This presents a challenge to develop specific inhibitors for use in different disease settings. Although antibodies therapeutics targeting the extracellular domains of cytokine receptors22,24 can recognize specific epitopes, no selectivity between the two forms has been reported. We25 and other groups5,26 have studied the conformations of the ectodomain of ST2 (ST2ECD) using Small Angle X-ray scattering (SAXS) and computational simulations. These data showed that ST2ECD possess high conformational flexibility. A recent study indicated that ST2 undergoes a greater conformational motion than IL-1R1 before binding to the cognate cytokine on the cell membrane5. However, the extent of different conformational flexibilities between sST2 and ST2 remains unknown. Despite that sST2 and ST2 both contain the D1-3 domains, we hypothesized that ST2 may have limited conformational flexibility than sST2 because ST2 is fixated on the membrane via the transmembrane and the cytoplasmic domains. A better understanding of the differences between sST2 and ST2 conformations will provide insights to develop selective inhibitors.
In this work, we performed MD simulations of sST2 and ST2 in their glycosylated forms using the physiological salt concentration. A broad conformational space of sST2 was mapped using conformations obtained from conventional MD and accelerated MD (cMD and aMD) simulations. Because aMD was not implemented to sample ST2, we performed cMD simulations using three different orientations of ST2ECD on the membrane (Fig. 1) to map the conformational space of ST2ECD (or ST2 hereafter). We first employed the principal component analysis (PCA) to determine the conformational differences between sST2 and ST2. We then built the Markov State Model (MSM) to calculate the kinetics of conformational transition in sST2 and ST2. We showed ST2 exhibits less conformational mobility by visiting a more confined conformational space and at a slower timescale of transition. Pairs of salt-bridge interactions were found to contribute to the stabilization of the relaxed ST2 conformations.
Methods
Protein structures used in this study
Eleven crystal structures of protein complexes containing the ectodomain of the IL-1R members were used in this study (PDB entries: 4DEP29, 4GAF30, 3O4O31, 1G0Y32, 1IRA33, 1ITB34, 4KC326, 5VI45, 4R6U35, 3WO436, 3WO336). They included IL-1R1/IL-1β (PDBID:1ITB), IL-1R1/IL-1β/IL-1RAcP (PDBID:4DEP), IL-1R2/IL-1β/IL-1RAcP (PDBID:3O4O), IL-1R1/IL-1Ra (PDBID:1IRA), IL-1R1/EBI-005 (PDBID:4GAF), IL-1R1/AF10847 (PDBID:1G0Y), human ST2/IL-33 (PDBID:4KC3), mouse ST2/IL-33/IL-1RAcP (PDBID: 5VI4), IL-18R1/IL-18 (PDBID: 4R6U,3WO3) and IL-18R1/IL-18/IL-18RAPL (PDBID:3WO4). EBI-005 is an IL-1β chimera and binds more potently to IL-1R1 than IL-1β30. The crystal structure of ST2 extracted from ST2/IL-33 (PDBID: 4KC3) was used to construct sST2 (sequence:A18-P323) in which missing amino acids25 were rebuilt using the MOE program37. To construct membrane-bound ST2, a homology modeling of the transmembrane and cytoplasmic domains of ST2 (sequence: K321-A556) was performed using the iTasser server38. Five homology models were obtained and four models gave helical conformations in the transmembrane domain. We selected the first model because the N-terminal segment (K321-H326) of the transmembrane domain had the least clashes with the membrane. The segment (K321-P323) in ST2 from the crystal structure was then superimposed with the same segment in the homology model of the transmembrane and the cytoplasmic domains of ST2 to obtain the ST2 model (sequence: A18-Q556). The same procedures were used to build the transmembrane and the cytosolic domains of mouse IL-1RAcP and mouse ST2 complex using the crystal structure of the ectodomain of mouse IL-1RAcP, mouse ST2 and mouse IL-33 (PDBID: 5VI4)5.
MD simulation setup
In preparation of the simulations, we have used the MOE program37 to determine the protonation state of ionizable groups on sST2 and ST2 under the standard physiological condition. The crystal structure of ST2 (only the ectodomain was resolved) showed three N-acetylglucosamine modified asparagines (N95, N140, N151) and five disulfide bonds. These post-translational modifications were retained in the MD simulations. The crystal structure of human ST2 was used as the initial conformation for sST2. For the initial conformation of membrane-bound ST2, we have set the backbone dihedral angle of L324 at 61°, 68° and 129° to generate three different orientations of ST2ECD (denoted ST21–3) relative to the lipid bilayer. The ectodomain of ST22 deviated from that of ST21 only by 7° whereas a significant backbone rotation of L324 in ST23 from that of ST21 was made. To prepare the sST2 and ST2 systems for simulations, we used the CHARMM-GUI server39. sST2 was solvated in a rectangular waterbox with the edge distance set to 10 Å and under 0.15 M of KCl salt concentration. To prepare the ST2 system, the transmembrane domain of ST2 was first oriented using the Orientations of Proteins in Membranes (OPM) server40. The transmembrane domain of ST2 was then inserted in a POPC lipid bilayer using the CHARMM-GUI server. The x- and y-dimension of the lipid bilayers were 140, 187 and 182 Å in length for ST21–3 and the number of POPC molecules on the top and the bottom lipid layer were ST21 (228,236), ST22 (275,283), ST23 (275,267) respectively. The thickness of the water layer was set at 85 Å on both the top and bottom layers. The KCl salt concentration was set at 0.15 M. After the system preparation, we found that the ectodomain of ST23 was close to the lipid membrane surface. Based on the settings, ST23 conformation will allow us to study how the close contact between the ectodomain of ST2 and lipid affects the motion of the ST2 ectodomain.
The CHARM36 additive force field parameters41 were used for both sST2 and ST2. The force field parameters for glycan and POPC were obtained from Glycan Reader42 and Membrane builder43 in CHARMM-GUI server. The TIP3P model44 was used for the water molecule. The force field parameters of the systems were converted into the AMBER format41 and the MD simulations were performed by using the GPU modification to PMEMD45 from Amber (version 18)46. Preparation of the system for the production runs used the following procedures. For sST2, a 5000-step minimization (steps 1-2500 using conjugated gradient followed by 2500 steps steepest decent) was first carried out in which protein atoms were constrained with a 1.0 kcal/mol/Å2 force constant with reference to the crystal structure. After minimization, a 25 ps constant volume and constant temperature (NVT) simulation was performed by setting the temperature of the system to 303.15 K while constraining protein atoms with a 1.0 kcal/mol/Å2 force constant with reference to the crystal structure using a time step of 1 fs. Another 1 ns constant pressure and constant temperature (NPT) simulation at 303.15 K and P = 1 atm was performed without constraining protein atoms before the production runs were executed using the time step of 2 fs. The SHAKE47 algorithm was used to fix bonds involving hydrogen. The PME method48 was used to account for long-range electrostatic interaction and the non-bonded cutoff distance was set at 12 Å and the force-based switching set at 10 Å. For ST2, a 5000-step minimization (steps 1–2500 using conjugated gradient followed by 2500 steps steepest decent) was first carried out in which protein atoms were constrained with a 10.0 kcal/mol/Å2 force constant and the phosphorus atoms in POPC were constrained with a 2.0 kcal/mol/Å2 force constant with reference to the initial structure. Six equilibration steps were adopted. First, a 25 ps NVT simulation was performed by setting the temperature of the system to 303.15 K while constraining protein atoms with a 10.0 kcal/mol/Å2 force constant and the phosphorus atoms in POPC with a 2.0 kcal/mol/Å2 force constant with reference to the initial structure using a time step of 1 fs. Second, same procedures as the first were used but the constraints to the protein atoms were reduced to a 5.0 kcal/mol/Å2 force constant. Third, a 25 ps NPT (T = 303.15 K, P = 1 atm) simulation was performed by constraining protein atoms with a 2.5 kcal/mol/Å2 force constant and the phosphorus atoms in POPC with a 1.0 kcal/mol/Å2 force constant with reference to the initial structure using a time step of 1 fs. The constant surface tension was set to zero on the xy plane. Forth, same as the third for a 50 ps simulation but the constraints to the protein atoms and the phosphorus atoms in POPC were reduced to 1.0 and 0.5 kcal/mol/Å2 respectively. Fifth, same as the forth for a 100 ps simulation at a time step of 2 fs but constraints to the protein atoms and the phosphorus atoms in POPC were reduced to 0.5 and 0.1 kcal/mol/Å2 respectively. Sixth, same as the fifth but only the protein atoms were restrained to a 0.1 kcal/mol/Å2 force constant. Another 1 ns equilibration at a time step of 2 fs was performed without imposing constraints to the protein atoms before the production run was initiated.
In the aMD simulations, we used the average total and dihedral energy of 2 ns equilibrium run prior to the starting conformation at 10ns of cMD simulation to calculate three threshold potential energies, called aMD1, aMD2 and aMD3, described in our previous work25. The conformation at 10 ns of cMD simulations was selected as the starting conformation for conformational sampling in aMD. Because the rate for the starting conformation to be trapped at local minima differed among AMD1–3, we performed 80, 81.5 and 61.1 ns of simulations using the aMD1–3 parameters respectively.
Principal component analysis (PCA)
The procedures to perform the PCA have been described previously25. Briefly, thirteen crystal structures from the eleven protein complexes containing the ectodomain of the IL-1R members (IL-1R1, IL-1R2,IL-1RAcP, ST2, IL-18R1 and IL-18RAcP) were analyzed in the PCA implemented in the Bio3D version 2.349 in the R program 3.650. Among the crystal structures, only Cα atoms (total of 184) coordinates of non-gap amino acids determined in the sequence alignments were used in the PCA to define the backbone conformational space. Conformations obtained from each trajectory from the simulations were then projected to the principal component (PC) space to analyze the conformational changes. In the PCA, the first three PCs contributed 47.17, 30.64 and 10.95% (Table S1) to the overall structural displacements respectively.
Cluster analysis of sST2 conformations obtained from the aMD1 simulation
We used the template project module from MSMBulider v3.851,52 to perform the analysis. Snapshots of the protein conformations from the aMD1 simulation were taken in every 50 ps. The conformational space of sST2 was defined by the torsional angles of the backbone and the side chains of 9 amino acids (sequence: 201–210, VKDEQGFSL) between the D2 and the D3 domain of ST2. The torsional angles were converted into features that were subjected to time-lagged independent component (tIC) analysis53,54,55 using a lag time of 500 ps. To determine the 15 cluster groups, we performed the K-Medoids clustering analysis52 of the loop conformations using the first five tICs representing five slowest relaxation degrees of freedom. The conformations closest to the centroid of each cluster group were used as representative conformations shown in Fig. S4.
Markov State Model construction
The pyEMMA package 2.5.756 was used in the Markov State Model (MSM) analysis. Snapshots of sST2 or ST2ECD conformations at every 50 ps obtained from the simulations were used in the analysis. Only the backbone dihedral angles of the 9 amino acids at the loop were included in the tIC analysis. We varied the lag time from 0.05 to 20 ns and determined 4, 15, 15 ns were suitable to obtain the plateau values of the implied timescales in the analyses of sST2, ST2ECD and sST2 + ST2ECD ensembles (see Fig. S9). To determine the number of microstates to model the transition events, we varied the number of cluster groups from 10 to 600 and found 300 clusters giving a plateau VAMP-2 score value. In the Robust Perron Cluster Analysis (PCCA+ ) analysis57, we varied the number of macrostates from 6 to 12 and found the 12-macrostate model giving good agreement between the estimated and the predicted transition probability in the Chapman-Kilmogorow test (CK test, cf. Figs. S10 and S12)58.
Results
The D3 domain of sST2 and ST2 exhibited great flexibility observed in the early time of MD simulations
We have previously reported that the D3 domain of ST2ECD (ST2D3) underwent a large amplitude rotational motion relative to the D1 and D2 domains (ST2D1D2)25. Using different force fields parameters including three glycosylated asparagines in sST2, we reached a similar finding in this study (Fig. S1). We first aligned the D1D2 domain of ST2 conformations to the crystal structure of ST2ECD in complex with IL-33 to determine the backbone motions of each domain for the initial 108 ns of sST2, ST21-3 using the cMD simulations. We found the deviation of sST2D2 was small whereas that of sST2D1 was larger. Changes of the backbone root-mean-squared-deviations (RMSDs) of sST2D3 were dramatic and the values rose to around 20 Å at 1.4 ns before increasing to 50 Å at 85 ns. In the case of ST2, we found similar patterns of backbone deviations among the D1-D3 domains. For example, ST2D2 remained close to the crystal structure of ST2 and ST2D1 deviations were less than that found in sST2D1. Increases of backbone RMSDs in ST2D3 however varied in three different ST2 simulations. Rises of RMSDs to 40–60 Å all occurred at a later time in ST2 compared with that in sST2. In all four 108 ns simulations of sST2, ST21-3, the average RMSDs for ST2D1, ST2D2, ST2D3 were 3.71 ± 0.48, 2.50 ± 0.55 and 43.09 ± 13.31 Å respectively. The data confirmed that the large interdomain motion between ST2D1D2 and ST2D3 is a shared property between sST2 and ST2 and is unaffected by the transmembrane and the cytosolic domains of ST2.
The large RMSD values of the D3 domain imply flexible motion of ST2D3, but they are not ideal classifiers to distinguish different ST2 conformations. We then employed the PCA to analyze the conformations of sST2 and ST2ECD obtained from the long-time MD simulations following the procedures reported previously25. In PCA, the overall backbone motion of the protein was decomposed to different types of collective motions described by PCs59,60. The collective motions of the first six PCs were provided in the Supplemental Materials for reference. Only PC1 showed a large amplitude motion of ST2D3 relative to ST2D1D2. The remaining PC2-PC6 characterized either collective backbone vibration or twisted motions. sST2 and ST2ECD conformations from the simulations projected to the PC space further allowed to analyze the differences of the conformational changes associated with each type of motion25.
Although the complete description of ST2 conformational motions required all PCs (552 degrees of freedom) in the analysis, we have shown that the first three PCs (PC1–3) provided a reasonable characterization of the large amplitude ST2 motions in plots25. For example, the first three PCs accounted for 87% of structural variations in the crystal structures here. After the projections of ST2 conformations to PC1-PC3, we found that conformations of sST2 were mapped to a circular path along PC1 and PC2 (Fig. 2A) suggesting a nonlinear coupled motion of large amplitude domain motions (PC1) and collective backbone vibration (PC2) dominated the conformational transition. In the PC1-PC3 space, we also found that sST2 visited conformations close to the cytokine-bound IL-1R1/2 conformations (red open circles) and was trapped in a region close to the conformation of the antagonist-bound IL-1R1 (PDBID: 1G0Y, the cyan dot in Fig. 2A). The final sST2 conformation in Fig. 2A showed that sST2 adopted a close conformation in which the D1 and D3 domains contacted each other25.
In the ST2 conformations obtained from the cMD simulations, circular paths along PC1 and PC2 were not found (Fig. 2B-D). This suggests that ST2ECD underwent less degree of the large amplitude motion along PC1. ST2ECD mainly sampled a larger conformational space along PC2 and PC3, reflecting coupled backbone vibration and twisted motions. In the 386 ns of ST21, 759 ns of ST22, and 1.53 μs of ST23 cMD simulations, conformation overlaps between ST21 and sST2 are greater in the PC1–3 space indicating their similar relaxation paths. The PCA is thus a useful tool to analyze and differentiate the large amplitude conformational transitions between sST2 and ST2. To examine the overall shape changes in ST2, we monitored the distance of the center-of-mass (COM) between the D1 and the D3 domains (COMD1–D3) and the radius of gyration (ROG) of the proteins. Fig. S2 showed that COMD1–D3 of sST2 decreased quickly in less than 100 ns. For ST2, the D1 and the D3 domains made close contacts at a slower pace in the ST21 and ST22 simulations. In contrast, no contact was established in ST23 over the 1.53 μs simulation. Changes of the ROG values showed a similar trend suggesting that the ectodomain of ST23 relaxed to an extended conformation different from the globular shapes found in sST2, ST21 and ST22.
Extensive mapping of the sST2 conformational space was facilitated by the aMD simulations
We have previously demonstrated that aMD allows efficient conformational sampling of IL-1R1ECD and ST2ECD to cover broad conformational spaces inaccessible to cMD using the same simulation times but different simulation paramters25,60. To examine the outcomes of the force field parameters used in this study, we evaluated three sets of acceleration parameters (aMD1–3) in the aMD simulations of sST2 (Fig. S3). Modifications of the potential energy functions by aMD1–3 parameters were expected to sample the sST2 conformations from an elevated to a higher energy states25. This was shown by different densely populated regions in PC1–3 accessed by the three aMD simulations (see Fig. S3A–C). Collectively, sST2 conformations obtained from cMD and aMD1–3 (a total of 240 ns simulations) mapped to a larger PC1–3 space than those of ST2ECD from a total of 2.7 μs cMD simulations (cf. Fig. S3D). To further determine the conformational differences between sST2 and ST2ECD, we analyzed their projections to the first six PCs that account for 99% of structural changes (or variances) in Fig. 3. We used the conformations of the mouse ST2 from the simulations of the complex of mouse IL-1RAcP/ST2/IL-33 (Fig. 1A) as a reference to represent the IL-33-bound ST2 state. Figure 3A showed that ST2ECD generally sampled a more restricted PC space. The plots also indicated that motions along the PC1, PC2 and PC4 differ between sST2 and ST2ECD because of less overlapping population. Because most of the sST2 conformations were sampled from aMD simulations, the dense populations in the PC space do not correspond directly to the lowest free energy of the unmodified potential surface. To visualize the structural differences between sST2 and ST2ECD, we performed the K-Mean cluster analysis using the first seven PCs (99% of variances) and identified 22 and 13 cluster groups in the sST2 and ST2ECD conformations respectively. Representative conformations closest to the centroid of each cluster group were aligned to the crystal structure of ST2D1D2 for comparison. Figure 3B highlighted that the D3 domain of sST2 indeed underwent greater rotational and twisted motions than that of ST2ECD.
Performing multi-trajectory equilibrium cMD simulations using diverse sST2 conformations to investigate the interdomain loop dynamics
Although aMD efficiently sampled the sST2 conformations at a shorter simulation time, estimation of the conformational transition kinetics requires trajectories governed by unmodified potential energy functions. To study the global conformational transition, cMD simulations of sST2 started with diverse conformations in the free energy surface are needed. Our analysis showed conformations sampled by the aMD1 simulation represented the smallest modified potential energy function yet covered a large PC1–3 space (Fig. S3A). We also reported that flexibility of the loop between ST2D2 and ST2D3 led to diverse sST2 conformations25. To select sST2 conformations for multi-trajectory simulations, we used the torsional angles of the backbone and side chains of 9 amino acids in the loop region (sequence: 201–210, VKDEQGFSL) to represent sST2 conformations obtained from the aMD1 simulation. The time-lagged independent component (tIC) analysis of the torsional angles was used to determine the two slowest degrees of freedom of the loop motion (tIC1–2). After mapping the sST2 conformations to tIC1 and tIC2, we performed the K-Medoids cluster analysis52 to identify 15 cluster groups distributed in five distinctive regions (Fig. S4). Representative conformations in each cluster group indeed showed a wide range of sST2D3 orientations relative to sST2D1D2 (Fig. S4). These 15 conformations were used as the initial conformations for 300 ns cMD simulations to generate an equilibrium ensemble of sST2. By monitoring the values of COMD1–D3 in the 15 cMD simulations, we found that sST2 either collapsed to conformations in which ST2D1 contacted ST2D3 or adopted extended conformations at the end of the simulations (Fig. S5).
To analyze the conformational transition kinetics of ST2, we employed Markov State Model (MSM) implemented in pyEMMA56. In this analysis, only the backbone torsional angles of the loop were used as the reaction coordinate to represent the conformational transition. We have varied the lag time and numbers of cluster groups to determine parameters suitable for the MSM. We found 80 steps (or 4 ns lag time) and 300 cluster groups gave converged stationary distribution and weighted free energy surface in tIC1 and tIC2 (Figs. S6, S7). Based on the analysis, sST2 conformations were divided into two connected valleys on the free energy surface (Figs. S6, 7). The stationary distribution indicated a larger population of sST2 at the right valley with a corresponding lower free energy of the loop segment (tIC1 = 1, Fig. S7). The trajectory started from the IL-33 bound sST2 in the cMD simulation also mapped to the right valley (Fig. 4A). The conformational transition flux corresponding to the slowest implied timescale (~5728 ns, Fig. S8) displayed a population flow (or conformational changes) from the lower left valley (tIC1 = −2, tIC2 = −2, Fig. S9) to the right valley. To depict the conformational transition flow using a smaller number of metastable states, we performed the Robust Perron Cluster Analysis (PCCA+ ) analysis57. After conducting the Chapman-Kilmogorow test (CK test)58, we found that 12 metastable states were required to give agreement between the predicted and estimated metastable state relaxation (Fig. S10). By tracking the flux from the right-most metastable state to the left-most state along tIC1 (the slowest degree of freedom of the loop motion), we found that sST2 conformations on the right valley channeled via two pathways (from S1 to S10/S7 and S11 to S7/S6 respectively) to the left valley before reaching B (S8) (Fig. 4B). As demonstrated, the broad conformational space of sST2 generated from the cMD simulations provided a necessary free energy landscape coverage to analyze the ST2ECD conformations obtained from the cMD simulations.
The conformational transition kinetic of ST2ECD in ST2 and its relation to sST2
To analyze conformational transition of ST2 alone, we used the same parameters and procedures in MSM as those in sST2. Fig. S11 showed that ST2ECD conformations were mapped to three regions. The slowest timescale of the conformational transition for ST2 was estimated at ~299 ns (Fig. S8). The first 307 residues (sequence 19–323) of ST2 (i.e. ST2ECD) and sST2 are identical. To compare sST2 with ST2ECD using the same tICs, we combined the loop conformations of sST2 and ST2ECD in the following analysis. Figure 5A showed all conformations were divided to 12 metastable states (macrostates) and the IL-33 bound ST2 (ST2xray) was located in S10. Although the overall free energy landscape of sST2 + ST2ECD was modified (cf. Figs. 4A and 5A, tIC2 changes sign in the free energy surface between sST2 and sST2 + ST2ECD), yet the free energy surface was dominated by sST2 conformations (Fig. 5B). Figure 5C further indicated that ST2ECD sampled additional loop conformations not visited by sST2 after 1 μs of simulations. Similar to the findings in the sST2 analyses (Fig. 4B), the major population flux along tIC1 between two valleys flowed from S12 to S9 (S1 to S10 in Fig. 4A) but much less via the second pathway before reaching state B (Fig. 5D). The second major flux (S8 → S3 → B) is associated with sST2 not ST2ECD. Among the ST2 conformations, we found that conformations of ST21 and ST22 were localized at the right valley (Fig. 6B-C). These conformations corresponded to the relaxation of ST2ECD to a final state that ST2D1D2 made close contact with ST2D3 (Fig. S2). In contrast, conformations obtained from ST23 were mapped to three different regions including those in S9 not accessed by ST21 or ST22 (Fig. 6D).
Because the loop conformations obtained from ST23 covered a broader range in the free energy surface than ST21 and ST22, we further analyzed the time evolution of the conformations in ST23. In Fig. 7, we divided the trajectory of the ST23 simulation into five different time intervals (1–260, 260–500, 500–700, 700–1032, >1032 ns) guided by the changes of COMD1–D3. Figure 7A showed that ST2ECD transited among S9, S10 and S12 in the initial 260 ns. In 260–500 ns (Fig. 7B), ST2ECD underwent conformational transition by shuttling among S12, S11 and S10. This paralleled the large variations of COMD1–D3 in Fig. 7F. In 500–700 and 700–1032 ns, ST2ECD relaxed to the conformational state localized densely in S11 and S10 (cf. Figures 7C,D and 5). In >1032 ns, ST2ECD underwent smaller amplitude interdomain rotation and reached other local regions (S3, S5) not sampled by sST2 (Fig. 7E). In Fig. 7G, we showed the arrangement of the D1-D3 domain in ST2 at 200, 400, 600, 800, and 1500 ns corresponding to five time-windows. We also aligned ST2xray to ST2D3 to demonstrate the rotation of ST2D1D2 from the IL-33 bound ST2xray structure in Fig. 7H. Figure 7H demonstrated that the ST2ECD conformation was close to ST2xray at 200 ns indicated by the close proximity between the D1 and the D1x (D1 of ST2xray) domains. After 260 ns, ST2D1D2 underwent significant rotation relative to ST2D3 and transitioned to extended conformations giving large COMD1–D3 values at ~70 Å in Fig. 7F. In 500–700 ns, ST2ECD adopted a conformation that the D1 domain was about 180° from the D1x domain in ST2xray. After 700 ns, ST2ECD relaxed to the local free energy minima and assumed extended conformations until 1500 ns.
Salt-bridge interactions contribute to the stabilization of the ST2 ECDconformations after long time MD simulations
Based on the COMD1–D3 values, ST2 conformations started with three different initial conformations relaxed and stabilized to different conformations. We asked if specific interactions contributed to the stabilization of the loop conformations by analyzing the final snapshots of each ST2 simulation. We found several pairs of salt-bridge interactions in the loop region may play a role. They included E126-K241, K127-E205, E126-K127, K203-E205 and E205-K241. We then monitored the distances between these salt-bridge interactions in each ST2 simulation (Fig. 8). We found that K127-E205 occasionally formed hydrogen bonds at the end of ST21 simulation whereas a strong E126-K241 interaction and a weaker E205-K241 interaction were found at the end of ST22 simulation. In the ST23 simulation, E205 and K241 formed a strong salt-bridge interaction at the end of the simulation. These salt-bridge interactions were not observed in ST2xray bound with IL-33 and likely contributed to the stabilization of different ligand-free ST2 conformations.
Discussions
Attenuation of cytokine mediated cellular responses by soluble cytokine receptors can limit the cytokine pool in circulation18. Several mechanisms of soluble cytokine receptors production have been reported7 including sST2 that is produced via alternative splicing61 before excretion to extracellular milieu. Aberrant production of sST2 is associated with severity in graft versus host disease62,63,64,65,66,67,68, cardiac transplantation rejection, IBD and other chronic diseases69,70,71. Further, persistent activation of ST2/IL-33 axis also contributes to chronic type 2 inflammation in asthma17 and atopic dermatitis72,73. Despite the different role of membrane-bound and soluble cytokine receptors in diseases, our understanding of the differences between them beyond their sequences remains limited. Characterization of differential conformational preferences and dynamics between the soluble and membrane-bound cytokine receptors may assist in developing novel therapeutic approaches to target specific isoforms.
In this study, we found that the IL-33 bound sST2 relaxed to a conformation similar to our previous report25. From the microsecond cMD simulations of ST2 using three different orientations of ST2ECD, we showed that ST2ECD relaxed to a close state (indicated by small COMD1–D3 values) at a slower rate than that of sST2 (300 versus 50 ns). PCA indicated that the close state of sST2 differs from ST2ECD observed at the end of the ST21 and ST22 simulations. In the ST23 simulation where ST2ECD was initially positioned close to the membrane, ST2ECD did not relaxed to a close state but to an extended conformation in 1.5 μs of simulations. Because the IL-33 bound ST2 structure was used as the initial conformation in sST2 and ST2ECD, the restrain of ST2ECD by the transmembrane and the cytosolic domains or the interaction of ST2ECD with lipids may influence the conformational relaxation of ST2ECD. We also found that the interdomain rotational motion in sST2 causes sST2 relaxed to a local state at <100 ns timescale. In contrast, ST2ECD can relax either to different close states or assume an extended conformation for ~500 ns. Encounter of ST2ECD with the lipids potentially induces a perturbation to modify the free energy surface of ST2ECD. Comparison of the representative sST2 and ST2ECD conformations from the aMD and cMD simulations demonstrated that sST2D3 may undergo a wider rotational motion relative to sST2D1D2 than those in ST2ECD. The data were supported by PCA that showed larger negative values of PC1, reflecting a rotational motion of ST2D3 relative to ST2D1D2, in the sST2 conformations.
Diverse sST2 conformations generated by the aMD simulations also allowed us to perform multi-trajectory cMD simulations to study the kinetics of global conformational transition in sST2. From the 300 ns cMD simulations started with 15 different conformations, we collected conformational transition events of sST2 encompassing different regions in the free energy surface. In comparison, conformational transition events of ST2ECD were generated from microsecond cMD simulations of ST2 using three different orientations relative to the membrane. Because the interdomain loop between ST2D1D2 and ST2D3 governs their relative orientation, we used the backbone torsional angles of the loop to characterize ST2 conformations and analyzed the kinetics of conformational transition. Using the two slowest degrees of freedom (or tIC), we showed that ST2ECD accessed primarily the lowest free energy surface of sST2 during the simulations. Transition of ST2ECD to another higher free energy valley was transiently found in the ST23 simulation in which ST2ECD interacts with the membrane initially. Combined use of multiple shorter time trajectories connecting free energy valleys have been reported to sufficiently model the transition events in the MSM74,75,76. Our CK tests also confirmed that the Markovian properties of transition kinetics underlies the loop dynamics of sST2. Based on the MSM analysis, the slowest implied timescale of conformational transition in sST2 is estimated at 5728 ns, longer than the 300 ns simulation of sST2 in each trajectory, that sST2 accesses higher energy states. In contrast, the simulation times of ST2 far exceeded the slowest implied timescale of 299 ns for ST2. The timescale should be a reasonable estimate of the conformational transition of ST2 in the subspace visited during the simulations.
Although dihedral angles have been used to identify biomolecular conformations by Schütte’s group employing hidden Markov models77, our choice of the dihedral angles of the loop characterizes the conformational transition associated with the relative motion between ST2D1D2 and ST2D3. Other choices of reaction coordinates78,79,80, such as the principal components and/or interdomain salt-bridge interactions, need to be investigated to determine the global conformational transition rate, ideally with experimental data81. Further, our microsecond simulations of ST2 only cover one valley of the free energy surface. Use of diverse initial ST2ECD conformations, similar to that adopted in the sST2 simulations, and a much longer simulation times will be needed to map out the complete ST2ECD conformational space. More extensive sST2 simulations are also needed to obtain accurate estimates of the timescale of the interdomain loop motion and assess if ST2ECD and sST2 exhibit different preferentially relaxed conformations shown in Fig. 6. We anticipate that this computational analysis can be employed to study the conformational flexibility of the membrane-bound IL-1R1 or other cytokine receptors and shed lights on the mechanism of cytokine recruitment and mechanism of signaling5.
Relaxation of the IL-33 bound ST2 structure tends to adopt a close ST2 conformation that ST2D1 contacts ST2D3. This was observed in sST2, ST21 and ST22 using the cMD simulations. We found that salt-bridge interactions around the loop region may assist in the formation of the close ST2 conformations that were subsequently stabilized by the interaction between ST2D1 and ST2D3. Besides the close conformation, the salt-bridge interaction also participates in supporting a metastable extended ST2ECD conformation observed in the ST23 simulation. Modulation of the receptor conformation by interdomain interaction has recently been demonstrated by the study of Li et al.82. Q268 and Q328 in subdomain 3 and 4 in type I interferon receptor (IFNAR1) was hypothesized to be in close location because of conformational flexibility based on modeling. Experimentally, conformational motion of IFNAR1 bringing Q268C and Q328C in close proximity to enable the disulfide bond formation and lock the conformation was observed.
Recent development of monoclonal antibodies targeting the D1 or the D3 domain of ST2 provides one example that epitopes on different domains in ST2 can be exploited22. We did not investigate the differences of the exposed surface areas between sST2 and ST2ECD based on their conformations. The analysis may characterize differentially solvent-exposed epitopes between sST2 or ST2 for antibody development. Our previous study also suggested that targeting transient small molecule binding sites in sST2 conformations may be another strategy to consider25. Whether the metastable ST2 conformations mediated by salt-bridge interaction can be further stabilized by small-molecule modulators for therapeutic purpose60 remains to be determined.
In summary, we have employed computational simulations of sST2 and ST2 to demonstrate relatively restrained interdomain rotational motion in ST2 in comparison to sST2. This is reflected in the timescale estimates of their conformational transition kinetics. The interdomain salt-bridge interactions were found to contribute to the stabilization of the interdomain loop conformations. Future investigation in the cooperativity between ST2ECD and the TIR domain should shed lights on the recruitment mechanism of IL-1RAcP by ST2/IL33 via the TIR domains.
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Acknowledgements
This work was supported in part from the National Institute of Health (R01HL141432) and the startup fund from University of Tennessee Health Science Center. We also thank Shaomeng Wang for providing computing resources for some of this work.
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C.-Y. Yang conceived the concept and performed the experiments. C.-Y. Yang analyzed and interpreted the data. C.-Y. Yang wrote the manuscript.
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Yang, CY. Comparative Analyses of the Conformational Dynamics Between the Soluble and Membrane-Bound Cytokine Receptors. Sci Rep 10, 7399 (2020). https://doi.org/10.1038/s41598-020-64034-z
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DOI: https://doi.org/10.1038/s41598-020-64034-z
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