Structure and function of chicken in vivo

A

P

Wen-Ting Chen, Wen-Yang Huang, Ting Chen ,, DongliWang, Yi-Zong Lee, Yuan-Yu Chang, Lee-WeiYang,, Shih-Che Sue, XinquanWang Yin

in vitro

Interleukin-1 beta (IL-1) plays a central role in coordinating host immune and proinammatory responses, and it has been shown to enhance production of immune-related molecules, e.g., adrenocorticotropin, cytokines, and chemokines14. IL-1 is produced by macrophages and monocytes and is synthesized as a propeptide5. The mature, bioactive form is produced upon caspase 1mediated proteolysis of the pro-IL-1. Interaction of IL-1 with the type I IL-1 receptor (IL-1RI) elicits a cascade of immune responses5. IL-1 has been used as a vaccine adjuvant to enhance the immune response against pathogens such as inuenza virus6, S. pneumonia7, and coccidiosis8.

An increasing number of reports have characterized the structure and function of avian IL-1s912. The

sequence identities for human and avian IL-1s are only 31 to 35%10,13. Three-dimensional structures of chicken and human IL-1s show a similar structural fold, i.e., they contain one or two -helices and 12 to 14 -strands, which form an antiparallel -barrel, with a shallow open face at one end and a closed face at the other11,14.

However, human IL-1 cannot induce chemokine expression in chicken broblasts or elevate the plasma cortisol level in chickens, thereby demonstrating a lack of cross-species bioactivity11,15. Close examination of the chicken and human IL-1s tertiary structures indicates that major dierences are found for loops 3, 4, 7, 8, and 9. The residues located in these loops may be critically important for receptor binding, accounting for the dierences in cross reactivities and immunological responses11,13.

The structure of human IL-1 in complex with its type I interleukin-1 receptor (IL-1RI) has been determined16. A large-scale mutagenesis study revealed that human IL-1 binds to its IL-1RI at two sites, labeled IL-1 A and B16. Site A contacts domains 1 and 2 of IL-1RI and sites B contacts domain 3 of IL-1RI. The crucial residues

Institute of Bioinformatics and Structural Biology, and College of Life Sciences, National Tsing Hua University, No.

SCIENTIFIC REPORTS

1

www.nature.com/scientificreports/

Figure 1. Multiple sequence alignment of human and avian IL-1s. Sequences used in the alignment are those of human IL-1 (UniProtKB:P01584) and chicken IL-1 (UniProtKB:O73909). Accession numbers are given in the parentheses. Residues directly involved in receptor binding are shaded in gray. Residues that form hydrogen bonds or salt bridges with receptor residues are in bold type or underlined, respectively13. The stars indicate the chicken IL-1 residues selected for in this study.

of human IL-1 involved in receptor-mediated biological activity or receptor binding have been identied by site-directed mutagenesis1720. R4, Q15, Q32, and K93 in human IL-1 interact with the receptor via intermolecular hydrogen bonds. L10, R11, H30, F46, I56, K103, and E105 are also involved in receptor binding. In contrast to human IL-1, the residues in chicken IL-1 important for biological activity or receptor binding have not been identied. Recently, a structural model of a chicken IL-1/chicken IL-1RI complex was built11,13. Four chicken IL-1 residues, R8, E25, R52, and R54, are within hydrogen-bonding distance of receptor residues and can be positioned to form salt bridge with the receptor in the model. In addition, 10 residues, T7, N18, Q19, H34, Q36, S39, S40, Q64, T117, and Q138 can be positioned to form hydrogen bonds with the receptor in the model. These residues are shown in black and along with other receptor-binding residues highlighted in gray in Fig.1.

Herein, we report the results of an extensive site-directed mutagenesis study aimed at identifying residues in chicken IL-1 responsible for biological activity as dened by an induced in vivo increase of chicken plasma cortisol. Additionally, circular dichroism (CD) spectroscopy, surface plasmon resonance experiments, and X-ray crystallography were used to characterize the physiological signicant receptor-binding affinity, and structural basis of some of the chicken IL-1 mutants found to decrease in vivo activity. In silico docking and molecular dynamics simulations were used to explore the structural properties and dierences of some of the chicken IL-1 mutants with decreased in vivo activity. This study expands our understanding of residues important to IL-1 biological activity, receptor binding, and the immune response.

We previously performed molecular dynamics (MD) simulations for the chicken complex of IL-1/IL-1RI where the avian IL-1 structure was solved by us and the IL-1RI was homology-modeled from its human equivalent (PDB: 4DEP)13. MD-rened complex structure revealed the IL-1/ IL-1RI interface13 and the residues in chicken IL-1 that made broad contacts with receptor IL-1RI via intermolecular hydrogen bonds were selected for alanine-scanning mutagenesis. Genes for the chicken IL-1 mutants T7A, R8A, N18A, E25A, H34A, Q36A, R52A, R54A Q64A, T117A, E118A, E118K, E118R, and Q138A were designed and then prepared by site-directed mutagenesis. The genes were expressed in E. coli BL21 (DE3) and puried to homogeneity by Co2+-affinity chromatography using their histidine tags (Supplementary Experimental procedures, Supplementary Table 1, and Supplementary Fig. 1). Most of the mutated residues are directly involved in receptor binding via hydrogen-bonds or salt bridges (Fig.1). The residues near the N-terminus, i.e., T7 and R8, are found in the rst strand of IL-1. R8 is conserved in chicken, human, and mouse IL-1s and is important for receptor binding20. Residue N18 is part of loop 1, which is between the rst and second strand. E25 is found in the second strand of IL-1; H34 and Q36 are located in loop 3, which is between the third and fourth strand, and are conserved in human and chicken IL-1. The corresponding residues play a crucial role in the binding of human IL-1 to its receptor17,19. By examining the human and chicken IL-1 structures and sequences, we noted that loop 4, which contains R52, R54, and Q64 and is between fourth and the h strand, and loop 9, which contains T117 and E118, and is between ninth and the tenth strand, are conformationally dierent in comparison with the corresponding loops in human IL-113. Q138 in loop 11, near the C-terminus, is part of site A.

In vivo To test the linearity of the in vivo IL-1 bioassay, various concentrations of WT chicken IL-1s were injected into a wing vein of adult chickens and changes in plasma cortisol levels were measured (Fig.2a). The concentration of cortisol in plasma increased from a basal level of 0.18g/L (obtained from the injection of 0g protein/kg body mass) to the maximal level of 8.77g/L (obtained from the injection of 10g protein/kg body mass). The eects of IL-1 on cortisol induction were concentration dependent. Thus, measurement of corticosterone in chicken serum, post an intravenous injection (10g protein/kg body mass) of recombinant chicken IL-1 into adult chicken, was chosen and used as an indication of biological activity for chicken IL-1 in vivo. The delivery signicantly elevated plasma cortisol that reached its maximal level at 1h post injection9. To compare the eects of the IL-1 mutants on the chicken immune system, we individually injected puried WT human, WT chicken, and mutant chicken IL-1s directly into wing veins of adult chickens, and then measured the plasma cortisol levels at 1h (Fig.2b). Among the mutants tested, T117A and E118A did not increase the plasma cortisol levels to the extent that WT chicken IL-1 did (p<0.05) (Fig.2b). To further assess the biological role of E118, we prepared E118K and E118R with positively charged side-chains replacing the negative side chain of glutamate. The plasma cortisol concentrations remained at near basal levels aer injecting E118K and E118R (Fig.2b,f). The mutants with replacements in loops 1 (N18A), 3 (H34A and Q36A), 4 (R52A, R54A, and Q64A), 11 (Q138A), and in strands 1 (T7A and R8A) and 2 (Q25A) caused an

SCIENTIFIC REPORTS

2

www.nature.com/scientificreports/

Figure 2. In vivo functional assay of IL-1 mutants. (a) Cortisol production is induced in a dose-dependent manner by chicken IL-1 and released into the plasma. (b) To determine the bioactivities of WT chicken IL-1 (ChIL-1), T7A, R8A, N18A, E25A, H34A, Q36A, R52A, R54A, Q64A, T117A, E118A, E118K, E118R, and Q138A, and human IL-1 (HmIL-1), each protein was directly and individually injected into a wing vein of three adult chickens, aer which the plasma cortisol levels were measured. (c) Ribbon diagram of chicken IL-1 (grey) complexed to IL-1R (pink). Mutation sites are shown in blue. Mutated residues in site A, site B, and loop 9 are shown in (df), respectively with the cortisol levels relative to that of WT IL-1 shown to the right of the mutant names.

increase in plasma cortisol expression similar to as that of WT IL-1, whereas injection of phosphate-buered saline or human IL-1 puried from the same protein purication method11 did not increase the plasma cortisol concentration (Fig.2b). It indicated that the increased or decreased cortisol concentration in the serum resulted from responses to a specic stimulus chicken IL-1 (or its mutants). The dierence between the plasma cortisol values induced by WT chicken IL-1 and phosphate-buered saline were statistically signicant (p<0.05).

Upon examination, we noted that mutations of IL-1 residues in site A caused a minor to moderate loss of biologic activity (Fig.2d), with the induced cortisol levels relative to that of WT chicken IL-1 being 78%, 85%, 90%, 77%, and 62% for N18A, E25A, H34A, Q36A, and Q138A respectively. Mutations in site B also induced little loss in biologic activity (Fig.2e), with the cortisol levels relative to that of WT chicken IL-1 being 87%, 71%, 82%, 70% and 75% for T7A, R8A, R52A, R54A, and Q64A, respectively. Conversely, large decreases in activity were found for mutations in loop 9 (Fig.2f), The induced cortisol levels relative to WT IL-1 are 16%, 37%, 4%, and 10% for T117A, E118A, E118K, and E118R, respectively, indicating that these proteins should be able to substantially block in vivo chicken pro-inammatory immune responses.

To determine if the mutations in T117A, E118A, E118K, and/or E118R would substantially disrupt their tertiary structures and would thereby cause reduction in biological activity, the secondary structures of WT IL- and the four aforementioned mutants, were assessed by far-UV CD spectroscopy. The ve spectra are nearly identical and have minima at ~206 nm (Fig.3), which indicates the presence of -sheet.

To assess if the signicantly reduced biological activities of T117A, E118A, and E118K was a consequence of reduced receptor-binding activity, a surface plasmon resonance study was performed using immobilized IL-1RI and a free mutant or WT chicken IL-1 (Fig.4). The Kd values for WT IL-1, T117A, and E118K were 0.12, 0.23, and 0.37nM, respectively, suggesting that that three mutants have similar receptor binding affinities compared with WT chicken IL-1. Thus, the mutated residues in loop 9 seem to have no great eect on receptor binding even though they signicantly reduce biological activity, which suggests that these residues may be involved in signal transduction once IL-1 has bound to the receptor.

SCIENTIFIC REPORTS

3

www.nature.com/scientificreports/

Figure 3. Far-UV CD spectra of WT chicken IL-1 , T117A, E118A, E118K, and E118R.

Figure 4. Surface plasmon resonance assays to determine the binding affinities of WT chicken IL-1 and its mutants to chicken IL-1RI. (a) WT chicken IL-1, (b) T117A, and (c) E118K. Sensorgrams were obtained by injecting various concentrations of WT IL-1 or a mutant over a chip with surface-immobilized IL-1RI. The experimental data (red lines) were t with a 1:1 interaction model (black lines). RU, response unit.

in vitro To evaluate the eects of T117A and E118K on IL-1 signaling in vitro, IL-6 production induced by chicken IL-1 was evaluated by measuring the IL-6 expression level in chicken broblast cell lysates (Fig.5a). The results showed that 10ng/ml of WT chicken IL-1 induced IL-6 synthesis in the DF-1 chicken broblast cells, while the treatment of T117A or E118K showed no eect in increasing the IL-6 expression. The elevation of IL-6 expression induced by chicken IL-1 is statistically higher (p< 0.05) than that by control, T117A and E118K, while the two mutants had a statistically indistinguishable eect on IL-6 production from that of the control. In addition, to determine whether mutants T117A and E118K antagonize chicken IL-1 activity, we examined how much IL-1 induced IL-6 expression in DF-1 cells in the presence of mutants. Interestingly, these mutants of chicken IL-1 exhibited dose-dependent inhibition of IL-1-induced IL-6 production to act as antagonists (Fig.5b).

A total of 154, 149, and 159 residues and 47, 27, 43 water molecules were resolved in the crystal structures of T117A, E118A, and E118K, respectively. No electron densities were found for residues 1, 2, 5559, and 162 in T117A; residues 1, 2, 3740, 5661, and 162 in E118A; and residues 1, 2, and 162 in E118K. In addition, no electron density was found for the His6-T7 tags (34 residues)

in the three mutants. We used PROCHECK21 to examine the stereochemical quality of the nal structures. All stereochemical parameters for side-chain and main-chain atoms were within acceptable limits, with the - values of the residues being in the most favored or allowed regions of the Ramachandran plots (Supplementary Table 2).

The crystal structures of the mutants contain the same -strands and the -helix found in WT IL-1, and the -strands exhibit a typical beta-trefoil fold nearly identical to that of WT IL-111 (Fig.6a). Individual

SCIENTIFIC REPORTS

4

www.nature.com/scientificreports/

Figure 5. (a) Eects of chicken WT IL-1, T117A, and E118K on IL-6 production in DF-1 chicken broblast cell line. DF-1 cells were treated with DMEM (Control) or 10ng/ml of chicken WT IL-1, T117A, and E118K for 8h. (b) Inhibition of chicken WT IL-1 activity by T117A and E118K mutants. DF-1 cells were treated with increasing concentration (040ng/ml) of mutants T117A or E118K for 8h in the presence of xed sub-saturating concentration (0.5ng/ml) of WT IL-1. Those cell lysates were collected and measured for IL-6 production using chicken-specic ELISA. Data are shown as the mean SD of triplicate determinations *p<0.05, IL-1 vs control.

Figure 6. Chicken WT IL-1, T117A, E118A, and E118K structures. (a) Superimposed ribbon diagramsof IL-1, T117A, E118A, and E118K. (be) The electrostatic potential surfaces were generated by PyMOL. Positively charged regions are shown in blue, and negatively charged regions are in red. Arrows identify loop 9 where dierences between the electrostatic potentials for WT IL-1 and its mutants were found.

SCIENTIFIC REPORTS

5

www.nature.com/scientificreports/

Figure 7. Structural models of human and chicken IL-1/IL-1RI/IL-1RAcP complexes. IL-1 is shown asa green ribbon diagram in panels (ac). IL-1RI and IL-1RAcP is shown in red and blue ribbon and/or surface diagrams, respectively. (d) A hydrogen bond is formed between the side chains of IL-1 E118 and IL-1RAcP N223 in the interface pocket (P). (e) Electrostatic potential surface surrounding chicken IL-1 T117 and E118 at the chicken IL-1RI/IL-1RAcP interface. Positively and negatively charged surfaces are shown blue and red, respectively. (f) Interactions surrounding human IL-1 residues N107 (T117 in chicken IL-1) and N108 (E118 in chicken IL-1) at the human IL-1RI/IL-1RAcP interface (PDB: 4DEP).

superimposition of each mutant structure onto that of IL-1 shows that the structures share a very similar fold, i.e., rmsd values for IL-1 compared with T117A, E118A, and E118K are 0.518 , 0.783 , and 0.403 , respectively. Close examination revealed a dramatic conformational change for loop 9 in WT IL-1 and E118K involving residues 116118, i.e., these residues form a loop in WT IL-1, but a short -helix in E118K (Fig.6a).

Our in vivo immune-response bioassays revealed signicant dierences in the activities for WT IL-1, T117A, E118A, E118K, and E118R as noted above. Using our crystal structures we generated electrostatic potential maps for WT IL-1 and the three mutants (Fig.6be). We found that the charge distributions near loop 9 dier for WT IL-1 and E118A and E118K. The loop 9 region is predominantly negatively charged in WT IL-1 (Fig.6b), whereas that region in T117A (Fig.6c) and E118A (Fig.6d) have reduced negative charges; the loop 9 region in E118K has a relatively greater area of positive charge than does WT IL-1 (Fig.6e).

As described in the material and methods, chicken IL-1/IL-1RI/IL-1RAcP complex structure is modeled from its human equivalent (PDB: 4DEP). In the context of the ternary complex, it can be seen that IL-1 loop 9 sticks into a crevice between IL-1RI and IL-1RAcP (Fig.7). The loop 9 interacts with chicken IL-1RAcP and the IL-1RI linker via hydrogen bonds and hydrophobic interactions, respectively (Fig.7a,d). Specically, chicken IL-1 T117 interacts with IL-1RAcP N223 and IL-1RI K202, and IL-1 E118 forms a hydrogen bond with IL-1RAcP N223 with its backbone interacting with IL-1RI N113 (Fig.7d). This conguration is also observed in human IL-1RI/IL-1RAcP (Fig.7c,f). Human IL-1 N108 (T117 in chicken IL-1) hydrogen bonds to IL-1RI N204 (P200 in chicken IL-1RI) and electrostatic interactions are formed between IL-1 N107 (E118 in chicken IL-1) and IL1RAcP E132 (Fig.7f). In general, the electrostatic potential surface involving residues T117 and E118 are more negatively charged than its surroundings, conned by IL-1RI/IL-1RAcP (Fig.7e). Potential energy calculations based on GROMOS96 45A3 force eld show that the loop 9 IL-1RI/ IL-1RAcP interactions are energetically less favorable for the mutant complexes such that mutants T117A, E118A, E118K, and E118R resulted in an increased energy, as compared to the WT, by 177.1, 498.6, 54.1, and 72.6kJ/mol, respectively, which could destabilize the chicken IL-1/IL-1RI/IL-1RAcP complex.

To assess the quality of the MD simulations, we examined the rmsd values of all heavy atoms during the IL-1, IL-1RI, IL-1RAcP, and IL-1/IL-1RI/IL-1RAcP runs (Fig.8a). The complex and its constituent monomers attained their equilibrium structures at ~4.5 ns and remained stable until the 10-ns ends of the trajectories. Overall, the IL-1 simulation had the least structural variation, followed by that of IL-1RI. The

SCIENTIFIC REPORTS

6

www.nature.com/scientificreports/

Figure 8. MD trajectories for free chicken IL-1, IL-1RI, IL-1RAcP and the IL-1/IL-1RI/IL-1RAcP complex. (a) Rmsd values (from the rst frame of the NPT runs) for the heavy atoms in chicken IL-1 (green line), IL-1RI (red line), and IL-1RAcP (blue line) and the ternary complex (black line) during the MD run. (b) Potential energy for IL-1/IL-1RI/IL-1RAcP was plotted as a function of time.

IL-1RAcP simulation had the greatest degree of structural variation. The potential energy of the complex during and at the end of the simulation indicated that the system was stable and at equilibrium over the course of the run (Fig.8b).

The biological activity of the chicken IL-1 mutants was assessed by measuring the plasma cortisol level in chicken. Among the fourteen mutants tested, the three that had a mutation in loop 9 (residues 116118) showed a signicant loss of biological activity, but could still eectively bind chicken IL-1RI, indicating that loop 9 is involved in bioactivity but not in receptor binding.

In this study, three types of mutant chicken IL-1s were designed and expressed that had a single substitution in the N-terminal region or in a loop that might be involved in receptor binding (Fig.2). The rst type involved substitution of alanine for N18, E25, H34, Q36, or Q138 as these residues are part of binding site A of chicken IL-1. Substitution of these residues resulted in a loss of 1040% of the biological activity as dened by an increase in the plasma cortisol level in mice relative to that of WT IL-1. The second type involved substitution of alanine for T7, R8, R52, R54, or Q64 as these residues are located in binding site B of chicken IL-1. Only a slight reduction in biological activity was observed for the corresponding mutants.

Interestingly, four mutants, T117A, E118A, E118K, and E118R with mutations in loop 9, of chicken IL-1 have no signicant eect on receptor binding but signicantly reduce biological activity, which suggests that loop 9 is involved in downstream signal transduction. To characterize whether T117A and E118K stimulate IL-1 signaling pathway in vitro, IL-6, the key inammatory mediator triggered by IL-1 through activation of p38 and NFB signaling pathway, was selected to assess the IL-6 synthesis eect2225. Chicken WT IL-1 induces signicant synthesis of IL-6 and the synthesis majorly occurs in the intracellular compartment. The eect is similar to that of human orbital broblast23. However, T117A and E118K fail to enhance the IL-6 synthesis. It indicates that the two mutations T117A and E118K lack the ability to active the IL-1 signaling in vitro. Treatment of T117A or E118K in DF-1 cells still mildly induces the same level of IL-6 as DF-1 cell alone. It implies that T117A and E118K cannot induce secretion of endogenous IL-1 that exists in chicken broblast cells. Interestingly, T117A and E118K lost the biological activity but maintained binding to IL-1RI. They thus serve antagonists and inhibit WT IL-1-induced IL-6 production competitively. These mutants may become helpful tools for the investigation of chicken IL-1 signal transduction mechanisms. In addition, CD spectroscopy of these mutants showed that they have the same secondary structure content as WT IL-1, i.e., they are mostly -sheet in nature, suggesting that the mutants are properly folded. Our crystallography data indicates that the three mutants and WT IL-1 have the same space group as native IL-1, suggesting that their molecular packing is unrelated to their biological function or receptor binding. We also characterized the structural and functional roles of loop 9 residues T117 and E118 using in silico docking and molecular dynamics of IL-1RI, WT IL-1, T117A, E118A, and E118K as free molecules and in their binary complexes (Supplementary Fig. 2). Loop 9 in WT IL-1 and these mutants closely contacts the linker in IL-1RI that connects domains 2 and 3. Notably the loop 9 residues are extended in E118A (Supplementary Fig. 3c) and form a short helix in E118K (Supplementary Fig. 3d). Loop 9 of human IL-1 also interacts with the domain 2/3 linker in IL-1RI, and this linker helps maintain the domain 3 conguration that appears to be required for signal transduction26. Possibly, the dierent structural features of loop 9 in human and chicken IL-1 are crucial for receptor binding such that the IL-1s from the two species do not cross react. The region surrounding loop 9 is predominantly negatively charged in WT chicken IL-1 but has the opposite charge

SCIENTIFIC REPORTS

7

www.nature.com/scientificreports/

in human IL-1. E118A and E118K also have a charge distribution that is opposite WT chicken IL-1 (Fig.6d,e) and altered structures (Fig.6a) in loop 9. Our results suggest that loop 9 in chicken IL-1 may be involved in IL-1 signal transduction.

Signal transduction of human IL-1 is initiated by forming a heterotrimeric complex involving the ligand IL-1, receptor IL-1RI, and receptor accessory protein IL-1RAcP. Recently, the crystal structure of human IL-1 in complex with the ectodomains of IL-1RI and the IL-1RAcP was determined and showed that the architecture of IL-1/IL-1RI is nearly unchanged when IL-1RAcP binds27. To gain insight into the mechanism by which chicken IL-1 binds to its receptor and receptor accessory protein, 3D structural models for chicken IL-1RI and IL-1RAcP were constructed by homology modeling of the chicken sequence based on known structures of human IL-1RI and IL-1RAcP. We used this structure as the template for our in silico docking and molecular dynamics simulations so as to examine the interface around IL-1 loop 9. By replacing E117 with an alanine or lysine and E118 with an alanine, the resulting mutants would not be able to form the wild-type hydrogen bond and hydro-phobic interaction[s], and would present an unfavorable charge to the IL-1RI/IL-1RAcP interface. The conformation of loop 9 in T117A, E118A, and E118K may disrupt structure packing and protein stability required for IL-1 signaling aer complexation.

In summary, our crystallographic data, in silico simulations, and biological results identify T117 and E118 as hot spots in the IL-1 immune response and help elucidate a mechanism by which IL-1 activity can be inhibited. These ndings should impact the development of new therapeutics that neutralize chicken IL-1 activity.

Ampicillin, imidazole, tris(hydroxymethyl)aminomethane (Tris), sodium chloride, and 2-[4-(2-hydroxyethyl)piperazin-1-yl]ethanesulfonic acid (HEPES) were supplied by USB (Cleveland, OH). Fomblin oil, sodium citrate, lithium sulfate, and ammonium sulfate were purchased from Sigma-Aldrich (St. Louis, MO). Isopropyl -D-1-thiogalactopyranoside was procured from Protech (Taiwan). Escherichia coli BL21 (DE3) was obtained from Yeastern Biotech (Taiwan).

In vivo To evaluate the linearity of the bioactivity of IL-1 in vivo, various concentrations of chicken WT IL-1 (150 g/kg body mass) were injected into adult specic-pathogen-free white leghorn chickens (Animal Health Research Institute, Taiwan)11.

Three independent tests for each concentration of recombinant WT IL-1 on three dierent chicken samples were performed. Aer 1h, the plasma cortisol levels were measured using a Roche E170 Modular immunoassay analyzer (Roche Diagnostics, Mannheim, Germany) as described in9. The Institutional Animal Care and Use Committee (IACUC), National Tsing Hua University, Taiwan approved the animal-use protocol (approval number, IACUC:10115). The methods were carried out in accordance with the approved guidelines.

To measure the in vivo activities of T7A, R8A, N18A, E25A, H34A, Q36A, R52A, Q64A, Q138A, T117A, E118A, E118K, E118R, Q138A, and WT human and chicken IL-1s, each proteins was individually injected at a concentration of 10g/kg body mass into adult specic-pathogen-free white leghorn chickens. For negative control, phosphate-buered saline was injected. Independent experiments for each protein that used three chickens were performed. Plasma cortisol levels were measured as described above. Statistical comparison between the mean cortisol levels of each mutant and to that of WT chicken IL-1 was done using students t-test28.

CD spectra between 190 and 260nm were recorded to estimate the secondary structures of T117A, E118A, E118K, E118R, and WT chicken IL-1 (15 M) at pH 7.4 in 10 mM potassium phosphate buer, at 20C using an Aviv 202 spectropolarimeter (Aviv Biomedical Inc., NJ)29. The average for three CD scans was calculated for each protein, and mean residue ellipticity (degcm2dmol1) was reported for each spectra.

To measure the binding affinities of T117A, E118K, and WT chicken IL-1 for chicken IL-1RI at 25C, surface plasmon resonance measurements were acquired with a BIAcore 3000 system (GE Healthcare)30. The receptor (5g/ml) in 10mM sodium acetate, pH 5.5 was immobilized on a research-grade CM5 sensor chip through the standard amine-coupling method (nal condition, ~370 response units)31. Various concentrations of each mutant and WT IL-1 at pH 7.2 in 10mM HEPES, 150mM NaCl, 0.001% (v/v) Tween-20 were individually washed at a rate of 30lmin1 over the ow cell. Both the association and dissociation of binary complexes were allowed to last for 90s. Data were t with a 1:1 Langmuir-binding model using the BIAcore 3000 evaluation soware BIAevaluation 4.1.

The DF-1 chicken broblast cells32 were seeded into a 6-well plate (Nunc, Rochester, NY) at 1.5 106 cells per well and grown until the monolayer was 8090% conuent. The cells were then washed with phosphate-buered saline (PBS) and treated with WT, T117A, or E118K IL-1s at a concentration of 10ng/ml and the control was treated with Dulbeccos Modied Eagles medium (DMEM). In addition, 0.5ng/ml of sub-saturating xed concentration of WT IL-1 mixed with increasing concentration (0.540ng/ml) of the mutants T117A or E118K were also treated with DF-1 cells. Aer 8 h treatment at 39 C, the inoculum was removed and the IL-6 expression in DF-1 cell lysates was analyzed using a chicken-specific ELISA kit (Cloud-Clone, Houston, TX)22,23. The plate was read with the iMark microplate reader (BioRad, Hercules, CA). The IL-6 samples and standards were evaluated in triplicate.

Crystals of mutants T117A, E118A, and E118K (from a solution of concentration 15 mg/ml) were grown at 20 C using the hanging-drop, vapor-diusion technique. Hundreds of crystallization conditions were tested using reagents from the following commercial screening kits: Wizard I, II, and III (Emerald BioSystems, WA); Crystal Screen, Crystal Screen 2 and PEG/Ion (Hampton

SCIENTIFIC REPORTS

8

www.nature.com/scientificreports/

Research, CA); and Clear Strategy Screen I/II (Molecular Dimensions Ltd., Newmarket, UK). Crystals were found to grow the best in the condition of 1.15M (NH4)2SO4, 0.1M Tris-HCl, 0.2M LiSO4, pH 8.0 at 20C. Each crystal was soaked in fomblin oil before being frozen in liquid nitrogen.

X-ray crystallographic data (Supplementary Table 2) were collected at the SPXF beamline BL13B1 of the National Synchrotron Radiation Research Center in Hsinchu, Taiwan, using a mar345 Image Plate Detector (Marresearch GmbH, Germany). The wavelength was 1.0 . Diraction data sets were collected and processed using the HKL-2000 package (HKL Research Inc., VA). The asymmetric unit for each mutant of chicken IL-1 (namely, T117A, E118A, and E118K) contains a single protein molecule in the crystals of orthorhombic space group P212121. Molecular replacement was performed to generate the mutant structures using the CCP4 program Molrep33 with all residues in chicken IL-1 (PDB ID: 2WRY)11 as the search model. Data between 30.0 to 3.5 and a Patterson radius of 20 were used to calculate translation and rotation functions. In the same way, WT chicken IL-1 was used as a template to build the structures of T117A, E118A, and E118K. The initial mutant chicken IL-1 structures were rebuilt and then rened by Coot34

and Refmac535, respectively. The renement statistics are summarized in the Supplementary Table 2. Structure validation was performed by PROCHECK v.3.5.421, and secondary structures were identied using DSSP36. The atomic coordinates and structure factors for T117A, E118A, and E118K have been deposited in PDB under the accession codes 4X39, 4X38, and 4X37, respectively.

Protein sequences were retrieved from ExPASy Molecular Biology Server (http://www.ebi.expasy. org/). Homology model of the extracellular domain of chicken IL-1RAcP was constructed using the structure of human IL-1RAcP (PDB entry 4DEP) as the template27. The two proteins share a 60.9% sequence identity according to ClustalW37 (http://www.ebi.ac.uk/clustalw). LigPlot38 was used to analyze the atomic interactions between constituent proteins in binary or tertiary (IL-1/IL-1RI/IL/IL-1RAcP) complexes. PyMOL39 was used for molecular visualization and representation of the electrostatic potential surface.

MD simulations for the chicken IL-1/IL-1RI binary complex were reported in13. With the human IL-1/IL-1RI/IL-1RAcP structure (PDB: 4DEP) as the template, we rst modeled chicken IL-1RAcP by superimposition onto that of human IL-1RAcP in human IL-1/IL-1RI/ IL-1RAcP and superimposed the last MD snapshot of chicken IL-1/IL-1RI onto its human equivalent. The resulting chicken ternary complex contained a few steric clashes between pairs of atoms separated by <1 at the IL-1/IL-1RAcP and IL-1RI/IL-1RAcP interfaces To eliminate the steric clashes, we rst translated IL-1RAcP away from the ternary complex through a limited number of steps, 1- at a time in either of the x, y, or z directions, until no clashes were found. We then pulled all the IL-1RAcP atoms, except for those involved in the steric clashes, back to their original coordinates (before the stepping away) using targeted MD simulations, with a time-varying force constant reduced from of 5.0kcal/mol/2 to pull the aforementioned atoms4042. The procedure brought majority of the IL-1RAcP atoms back to the positions suggested by homology modeling and x-ray crystallography data (per human IL-1RAcP) and result in the closest distance between atoms of IL-1RAcP and the binary IL-1/IL-1RI complex to be >1.7 (compared to 0.23 before the treatment). Next, the ternary complex was subjected to energy relaxation and MD-based structural renement. To do so, the ternary complex was solvated in a water box with dimensions of 128.9 118.9 138.5 containing nine neutralizing Na+ ions. The system was rst subjected to energy minimization then heated to 310K in an NVT ensemble and eventually equilibrated in an isothermal-isobaric ensemble for 10 ns. During the energy minimization, a weak restraint of 5.0kcal/mol/2 was applied to restrain the C atoms in their original positions, which led to a total C rmsd of <1.8 between the equilibrated structure and the original ternary structure excluding the atoms involved in original steric clashes. In the MD simulation, the complete electrostatic energy was calculated by Particle Mesh Ewald with a non-bonded distance cuto of 12. The temperature was maintained at 310K using the Langevin thermostat with a collision frequency of 2ps1, and pressure of 1bar using a Berendsen barostat.

1. Dinarello, C. A. Biologic basis for interleukin-1 in disease. Blood 87, 20952147 (1996).2. Introna, M. et al. IL-1 inducible genes in human umbilical vein endothelial cells. Eur Heart J 14 Suppl K, 7881 (1993).3. Sick, C., Schneider, K., Staeheli, P. & Weining, K. C. Novel chicken CXC and CC chemokines. Cytokine 12, 181186 (2000).4. Dinarello, C. A. Interleukin-1, interleukin-1 receptors and interleukin-1 receptor antagonist. Int Rev Immunol 16, 457499 (1998).5. Arend, W. P., Palmer, G. & Gabay, C. IL-1, IL-18, and IL-33 families of cytokines. Immunol Rev 223, 2038 (2008).6. Kayamuro, H. et al. Interleukin-1 family cytokines as mucosal vaccine adjuvants for induction of protective immunity against inuenza virus. J Virol 84, 1270312712 (2010).

7. Gwinn, W. M. et al. Eective induction of protective systemic immunity with nasally administered vaccines adjuvanted with IL-1. Vaccine 28, 69016914 (2010).

8. Min, W. et al. Adjuvant effects of IL-1beta, IL-2, IL-8, IL-15, IFN-alpha, IFN-gamma TGF-beta4 and lymphotactin on DNA vaccination against Eimeria acervulina. Vaccine 20, 267274 (2001).

9. Weining, K. C., Sick, C., Kaspers, B. & Staeheli, P. A chicken homolog of mammalian interleukin-1 beta: cDNA cloning and purication of active recombinant protein. Eur J Biochem 258, 9941000 (1998).

10. Wu, Y. F., Liu, H. J., Chiou, S. H. & Lee, L. H. Sequence and phylogenetic analysis of interleukin (IL)-1beta-encoding genes of ve avian species and structural and functional homology among these IL-1beta proteins. Vet Immunol Immunopathol 116, 3746 (2007).

11. Cheng, C. S. et al. Structural and functional comparison of cytokine interleukin-1 beta from chicken and human. Molecular immunology 48 (2011).

SCIENTIFIC REPORTS

9

www.nature.com/scientificreports/

12. Gyorfy, Z., Ohnemus, A., Kaspers, B., Duda, E. & Staeheli, P. Truncated chicken interleukin-1beta with increased biologic activity. Journal of interferon & cytokine research: the official journal of the International Society for Interferon and Cytokine Research 23, 223228 (2003).

13. Cheng, C. S., Lu, W. S., Tu, I. F., Lyu, P. C. & Yin, H. S. Comparative analysis of receptor binding by chicken and human interleukin-1beta. Journal of molecular modeling 17, 12831294 (2011).

14. Yu, B., Blaber, M., Gronenborn, A. M., Clore, G. M. & Caspar, D. L. Disordered water within a hydrophobic protein cavity visualized by x-ray crystallography. Proc Natl Acad Sci USA 96, 103108 (1999).

15. Chen, W. T. et al. Circular permutation of chicken interleukin-1 beta enhances its thermostability. Chem Commun (Camb) 50, 42484250 (2014).

16. Vigers, G. P., Anderson, L. J., Caes, P. & Brandhuber, B. J. Crystal structure of the type-I interleukin-1 receptor complexed with interleukin-1beta. Nature 386, 190194 (1997).

17. Evans, R. J. et al. Mapping receptor binding sites in interleukin (IL)-1 receptor antagonist and IL-1 beta by site-directed mutagenesis. Identication of a single site in IL-1ra and two sites in IL-1 beta. J Biol Chem 270, 1147711483 (1995).

18. Labriola-Tompkins, E. et al. Identication of the discontinuous binding site in human interleukin 1 beta for the type I interleukin 1 receptor. Proc Natl Acad Sci USA 88, 1118211186 (1991).

19. MacDonald, H. R. et al. Point mutations of human interleukin-1 with decreased receptor binding affinity. FEBS Lett 209, 295298 (1986).

20. Grutter, M. G. et al. A mutational analysis of receptor binding sites of interleukin-1 beta: differences in binding of human interleukin-1 beta muteins to human and mouse receptors. Protein Eng 7, 663671 (1994).

21. Laskowski, R. A., MacArthur, M. W., Moss, D. S. & Thornton, J. M. PROCHECK: A program to check the stereochemical quality of protein structures J. Appl. Cryst. 26, 283291 (1993).

22. Nakazato, Y. et al. Interleukin (IL)-1 and IL-4 synergistically stimulate NF-IL6 activity and IL-6 production in human mesangial cells. Kidney international 54, 7179 (1998).

23. Chen, B., Tsui, S. & Smith, T. J. IL-1 beta induces IL-6 expression in human orbital broblasts: identication of an anatomic-site specic phenotypic attribute relevant to thyroid-associated ophthalmopathy. Journal of immunology 175, 13101319 (2005).

24. Fan, Z., Bau, B., Yang, H. & Aigner, T. IL-1beta induction of IL-6 and LIF in normal articular human chondrocytes involves the ERK, p38 and NFkappaB signaling pathways. Cytokine 28, 1724 (2004).

25. Luo, G., Hershko, D. D., Robb, B. W., Wray, C. J. & Hasselgren, P. O. IL-1beta stimulates IL-6 production in cultured skeletal muscle cells through activation of MAP kinase signaling pathway and NF-kappa B. American journal of physiology. Regulatory, integrative and comparative physiology 284, R12491254 (2003).

26. Koussounadis, A. I., Ritchie, D. W., Kemp, G. J. & Secombes, C. J. Analysis of sh IL-1beta and derived peptide sequences indicates conserved structures with species-specic IL-1 receptor binding: implications for pharmacological design. Curr Pharm Des 10, 38573871 (2004).

27. Thomas, C., Bazan, J. F. & Garcia, K. C. Structure of the activating IL-1 receptor signaling complex. Nat Struct Mol Biol 19, 455457 (2012).

28. Nyirenda, T. S., Seeley, A. E., Mandala, W. L., Drayson, M. T. & MacLennan, C. A. Early interferon-gamma production in human lymphocyte subsets in response to nontyphoidal Salmonella demonstrates inherent capacity in innate cells. PLoS One 5, e13667 (2010).

29. Cheng, C. S. et al. Crystal structure and biophysical characterisation of Helicobacter pylori phosphopantetheine adenylyltransferase. Biochem Biophys Res Commun 408, 356361 (2011).

30. Wang, D. et al. Structural insights into the assembly and activation of IL-1beta with its receptors. Nat Immunol 11, 905911 (2010).31. Johnsson, B., Lofas, S. & Lindquist, G. Immobilization of proteins to a carboxymethyldextran-modied gold surface for biospecic interaction analysis in surface plasmon resonance sensors. Anal Biochem 198, 268277 (1991).

32. Chen, W. T. et al. Proteomics analysis of the DF-1 chicken broblasts infected with avian reovirus strain S1133. PLoS One 9, e92154 (2014).

33. Vagin, A. & Teplyakov, A. MOLREP: an Automated Program for Molecular Replacement Journal of Applied Crystallography 30, 10221025 (1997).

34. Emsley, P. & Cowtan, K. Coot: model-building tools for molecular graphics. Acta Crystallogr D Biol Crystallogr 60, 21262132 (2004).

35. Murshudov, G. N., Vagin, A. A. & Dodson, E. J. Renement of macromolecular structures by the maximum-likelihood method. Acta Crystallogr D Biol Crystallogr 53, 240255 (1997).

36. Kabsch, W. & Sander, C. Dictionary of protein secondary structure: pattern recognition of hydrogen-bonded and geometrical features. Biopolymers 22, 25772637 (1983).

37. Thompson, J. D., Higgins, D. G. & Gibson, T. J. CLUSTAL W: improving the sensitivity of progressive multiple sequence alignment through sequence weighting, position-specic gap penalties and weight matrix choice. Nucleic acids research 22, 46734680 (1994).

38. Wallace, A. C., Laskowski, R. A. & Thornton, J. M. LIGPLOT: a program to generate schematic diagrams of protein-ligand interactions. Protein Eng 8, 127134 (1995).

39. DeLano W. L. The PyMOL Molecular Graphics System. DeLano Scientic LLC, San Carlos, CA, USA URL https://www.pymol.org/ (2003).

40. Maier, J. A. et al. 14SB: Improving the Accuracy of Protein Side Chain and Backbone Parameters from 99SB. J Chem Theory Comput 11, 36963713 (2015).

41. Pearlman, D. A. & Connelly, P. R. Determination of the dierential eects of hydrogen bonding and water release on the binding of FK506 to native and Tyr82>Phe82 FKBP-12 proteins using free energy simulations. J Mol Biol 248, 696717 (1995).

42. Gotz, A. W. et al. Routine Microsecond Molecular Dynamics Simulations with AMBER on GPUs. 1. Generalized Born. J Chem Theory Comput 8, 15421555 (2012).

The authors acknowledge the support of the Ministry of Science and Technology, Taiwan. (MOST grant numbers MOST-103-2311-B-007-003-MY3, MOST-104-2113-M-007-019 and the Toward World-Class University Project). Portions of this research were carried out at the National Synchrotron Radiation Research Center, a national user facility supported by the National Science Council of Taiwan, ROC. The Synchrotron Radiation Protein Crystallography Facility is supported by the National Research Program for Genomic Medicine. We are grateful to the National Center for High-performance Computing, Taiwan, for computer time and facilities. The authors are thankful to Dr. Chien-Chung Cheng for helpful discussions.

W.-T.C. and H.-S.Y. wrote the main manuscript text. W.-T.C., T.C., W.-Y.H., E.O.S., D.W., Y.-Z.L. and Y.-Y.C. carried out experiments. L.-W.Y., S.-C.S., X.W., and H.-S.Y. generated the idea. W.-T.C. and H.-S.Y. designed the experiments. All authors reviewed the manuscript. H.-S.Y. obtained funding.

SCIENTIFIC REPORTS

10

www.nature.com/scientificreports/

Accession codes: PDB ID: 4X39 (T117A chicken IL-1 ), 4X38 (E118A chicken IL-1 ), and 4X37 (E118K chicken IL-1 ).

Supplementary information accompanies this paper at http://www.nature.com/srep

Competing nancial interests: The authors declare no competing nancial interests.

How to cite this article: Chen, W.-T. et al. Structure and function of chicken interleukin-1 beta mutants: uncoupling of receptor binding and in vivo biological activity. Sci. Rep. 6, 27729; doi: 10.1038/srep27729 (2016).

This work is licensed under a Creative Commons Attribution 4.0 International License. The images or other third party material in this article are included in the articles Creative Commons license, unless indicated otherwise in the credit line; if the material is not included under the Creative Commons license, users will need to obtain permission from the license holder to reproduce the material. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/

SCIENTIFIC REPORTS

11