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www.sciencesignaling.org/cgi/content/full/7/339/ra80/dc1 Supplementary Materials for Manipulation of receptor oligomerization as a strategy to inhibit signaling by TNF superfamily members Julia T. Warren, Christopher A. Nelson, Corinne E. Decker, Wei Zou, Daved H. Fremont,* Steven L. Teitelbaum* *Corresponding author. E-mail: fremont@pathology.wustl.edu (D.H.F.); teitelbs@wustl.edu (S.L.T.) The PDF file includes: Published 19 August 2014, Sci. Signal. 7, ra80 (2014) DOI: 10.1126/scisignal.2004948 Fig. S1. Effect of solubility mutations on RANKL function. Fig. S2. Comparison of wild-type htrankl and scrankl. Fig. S3. Design of RANKL mutants that prevent binding to RANK. Fig. S4. Ability of scrankl variants to inhibit wild-type htrankl induced osteoclastogenesis. Fig. S5. Reversion mutagenesis of YSD htrankl clones. Fig. S6. Identification of htrankl mutants with prolonged off-rates and decreased binding to OPG by a competitive OPG screen. Fig. S7. Effect of htrankl solubility mutations on binding to OPG. Fig. S8. Van der Waals surface model of wild-type htrankl oriented to show the binding cleft. Fig. S9. Combined mutations of htrankl that block binding to RANK and OPG. Fig. S10. Effects of single-block, RANK high on cell number and signaling.

Fig. S1. Effect of solubility mutations on RANKL function. (A) SPR assays were performed to determine the kinetic affinities for RANK of WT RANKL and of WT RANKL containing two mutations that increase its solubility (C220S and E246I, WT-SM RANKL). Curves were generated from triplicate samples. Kinetics values beneath the graphs represent means ± SD from three independent experiments. (B) BMMs were incubated with the indicated concentrations of WT htrankl and WT-SM htrankl, and the extent of osteoclastogenesis was determined by a fluorescent TRAP activity assay. Curves are representative of three independent experiments.

Fig. S2. Comparison of wild-type htrankl and scrankl. (A) MALS analysis of noncovalently linked RANKL (htrankl) or single-chain RANKL (scrankl). Because the predominant scrankl species migrated on a denaturing gel at a position slightly below that of chemically crosslinked htrankl (Fig. 1B), we calculated the precise molecular mass of htrankl (left) and scrankl (right) by MALS. The differences in the calculated and measured molecular masses reflect the presence of substantial glycosylation on these proteins, which are secreted by mammalian cells. Data are representative of three independent experiments. (B) BMMs were incubated with the indicated concentrations of WT htrankl or WT scrankl, and the extent of osteoclastogenesis was measured by a colorimetric solution-based TRAP assay. The curves are representative of three independent experiments.

Fig. S3. Design of RANKL mutants that prevent binding to RANK. (A) The binding of the indicated htrankl variants to RANK-Fc or OPG-Fc was assessed by BLI. Because of the dimeric nature of the analyte, K D values represent the apparent affinity constants generated from triplicate curves. (B to D) The capacity of the indicated recombinant htrankl variants to induce osteoclastogenesis in vitro was assessed by (B) TRAP staining, (C) TRAP-solution assay, and (D) real-time PCR analysis of the relative abundances of mrnas for osteoclastogenic markers. All assays were performed in technical triplicates. Mut16 was selected for incorporation into scrankl and is highlighted in a red box.

Fig. S4. Ability of scrankl variants to inhibit wild-type htrankl induced osteoclastogenesis. BMMs were cultured with WT htrankl (200 ng/ml) and the indicated concentrations of either single-block scrankl or double-block scrankl. Four days later, osteoclastogenesis was assessed by TRAP staining. The addition of a monomeric fragment of OPG (4 µg/ml) to cells treated with WT htrankl was used to demonstrate inhibition of osteoclastogenesis. Images are representative of three independent experiments.

Fig. S5. Reversion mutagenesis of YSD htrankl clones. (A to D) Yeast cells were induced to express RANKL variants and were stained with RANK-Fc (blue) or OPG-Fc (red). The degree of staining detected by flow cytometry was expressed as the percentage relative to that of WT. (A) Top scoring clones from the low (LM3S) or high (HM3S) mutation rate libraries with (B) individual point mutations of these clones. Data are representative of two independent experiments (A and B). (C) A second mutation was added to the most effective individual point mutant (Q236H). (D) A third mutation was added to closely approximate the ideal phenotype. Data are representative of two independent experiments (C and D).

Fig. S6. Identification of htrankl mutants with prolonged off-rates and decreased binding to OPG by a competitive OPG screen. (A) Representation of the competitive OPG YSD screen. In the context of WT htrankl (left), RANK (purple) fused to a 6 His tag is readily displaced by OPG (yellow) because of the higher affinity of OPG. Alternatively, in the context of a htrankl clone that has increased affinity for RANK and that has lost the capacity to bind to the decoy receptor, OPG is incapable of displacing RANK (right). Additionally, only those clones with an increased half-life have sustained binding after washing at room temperature. (B) Individual point mutant htrankl clones retaining high RANK binding, as detected with a monoclonal antibody against the 6 His tag, after 5 min of competition with OPG. (C) Kinetic competition analysis of the binding of WT htrankl and the H270Y, KQF, and KQFH htrankl variants to RANK-6His, in the presence of OPG, based on flow cytometric screening. For (B) and (C), data are expressed as the percentage of htrankl bound to RANK over time relative to that bound in the absence of OPG. Additionally, the binding of RANK (as detected with an APC-conjugated antibody) was normalized to the amount of htrankl expressed on the surface of the yeast (as detected with a FITCconjugated antibody) and expressed as the ratio of the MFIs of the APC and FITC signals. Curves are representative of three independent experiments.

Fig. S7. Effect of htrankl solubility mutations on binding to OPG. The kinetic affinities of WT-htRANKL and WT-SM htrankl for OPG were determined by SPR analysis. Curves were generated from triplicate measurements. Values below the plots are means ± SD of three independent experiments.

Fig. S8. Van der Waals surface model of wild-type htrankl oriented to show the binding cleft. For simplicity, only the two foremost htrankl monomers are shown; one in gray and the other in white. The RANKL substitution positions selected by YSD are shown in blue. The three residues that can be seen in this view, K194, F269, and Q236, have been labeled. The fourth residue, H270, lies just behind F269. A magenta colored ribbon model of RANK is shown in the binding cleft, with disulfide bonds in yellow. Only three of the cysteine-rich domains of RANK are shown. The CD-loop is indicated by a dashed red circle.

Fig. S9. Combined mutations of htrankl that block binding to RANK and OPG. (A) Titration curves of the binding of CDins htrankl and CDins/Q236H htrankl to RANK and OPG as assessed by the flow cytometric analysis of yeast cells displaying htrankl. The binding of RANK or OPG (as detected with APC-conjugated antibodies) was normalized to the amount of htrankl expressed at the yeast cell surface (as detected with a FITC-conjugated antibody) and was expressed as the ratio of the MFIs of the APC and FITC signals. Curves represent three independent experiments. (B) BMMs were left untreated or were treated with the indicated htrankl constructs (500 ng/ml) for 5 and 15 min. Cell lysates were then analyzed by Western blotting with antibodies against the indicated proteins. Western blots are representative of three independent experiments. (C) BMMs were incubated with CDins htrankl or CDins/Q236H htrankl to generate osteoclasts in vitro at concentrations that were saturating for WT htrankl (200 ng/ml) or were 10-fold greater (2,000 ng/ml). Images are representative of three independent experiments.

Fig. S10. Effects of single-block, RANK high on cell number and signaling. (A) D2 osteoclasts were left untreated or were incubated with WT htrankl alone, single-block, RANK high alone, or a combination of both. Cells were then analyzed by MTT assay to determine the effects on cell number. Data are means ± SD from three independent experiments and were analyzed by one-way ANOVA. (B) BMMs were left untreated or were pre-incubated for 15 min with single-block, RANK high (500 ng/ml) before being incubated with WT htrankl (200 ng/ml) or TNF-α (1 ng/ml). Cell lysates were then analyzed by Western blotting with antibodies against the indicated proteins to examine the extent of phosphorylation of IκBα. Western blots are representative of three independent experiments.

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