Summary

Production, Crystallization, and Structure Determination of the IKK-binding Domain of NEMO

Published: December 28, 2019
doi:

Summary

We describe protocols for the structure determination of the IKK-binding domain of NEMO by X-ray crystallography. The methods include protein expression, purification and characterization as well as strategies for successful crystal optimization and structure determination of the protein in its unbound form.

Abstract

NEMO is a scaffolding protein which plays an essential role in the NF-κB pathway by assembling the IKK-complex with the kinases IKKα and IKKβ. Upon activation, the IKK complex phosphorylates the IκB molecules leading to NF-κB nuclear translocation and activation of target genes. Inhibition of the NEMO/IKK interaction is an attractive therapeutic paradigm for the modulation of NF-κB pathway activity, making NEMO a target for inhibitors design and discovery. To facilitate the process of discovery and optimization of NEMO inhibitors, we engineered an improved construct of the IKK-binding domain of NEMO that would allow for structure determination of the protein in the apo form and while bound to small molecular weight inhibitors. Here, we present the strategy utilized for the design, expression and structural characterization of the IKK-binding domain of NEMO. The protein is expressed in E. coli cells, solubilized under denaturing conditions and purified through three chromatographic steps. We discuss the protocols for obtaining crystals for structure determination and describe data acquisition and analysis strategies. The protocols will find wide applicability to the structure determination of complexes of NEMO and small molecule inhibitors.

Introduction

The NF-κB pathway is activated in response to a variety of stimuli, including cytokines, microbial products and stress, to regulate expression of target genes responsible for inflammatory and immune response, cell death or survival and proliferation1. Pathologies including inflammatory and autoimmune diseases and cancer2,3,4,5 have been correlated to hyperactivation of the pathway, which has made modulation of NF-κB activity a prime target for the development of new therapies6,7.

The canonical NF-κB pathway in particular is distinguished from the non-canonical pathway, responsible for lymphorganogenesis and B-cell activation, by the former's dependence on the scaffolding protein NEMO (NF-κB essential modulator8) for the assembly of the IKK-complex with the kinases IKKα and IKKβ. The IKK complex is responsible for the phosphorylation of IκBα (inhibitor of κB) that targets it for degradation, freeing the NF-κB dimers to translocate to the nucleus for gene transcription1 and is therefore an attractive target for the development of inhibitors to modulate NF-κB activity.

Our research focuses on the characterization of the protein-protein interaction between NEMO and IKKβ, targeting NEMO for the development of small molecules inhibitors of IKK complex formation. The minimal binding domain of NEMO, required to bind IKKβ, encompasses residues 44-111, and its structure has been determined in complex with a peptide corresponding to IKKβ sequence 701-7459. NEMO and IKKβ form a four-helix bundle where the NEMO dimer accommodates the two helices of IKKβ(701-745) in an elongated open groove with an extended interaction interface. IKKβ(734-742), also known as the NEMO-binding domain (NBD), defines the most important hot-spot for binding, where the two essential tryptophans (739,741) bury deeply within the NEMO pocket. The details of the complex structure can aid in the structure-based design and optimization of small molecule inhibitors targeting NEMO. At the same time, it is difficult that binding of a small molecule or peptide would recreate in NEMO the full conformational change (i.e., extensive opening of the NEMO coiled-coil dimer) caused by binding of the long IKKβ(701-745), as observed in the crystal, and the structure of unbound NEMO or NEMO bound to a small molecule inhibitor may represent a better target for structure-based drug design and inhibitor optimization.

Full length NEMO and smaller truncation constructs encompassing the IKK-binding domain have proven intractable for structure determination in the unbound form via X-ray crystallography and nuclear magnetic resonance (NMR) methods10, which prompted us to design an improved version of the IKK-binding domain of NEMO. Indeed, NEMO (44-111) in the unbound form is only partially folded and undergoes conformational exchange and we therefore set to stabilize its dimeric structure, coiled-coil fold and stability, while preserving binding affinity for IKKβ. By appending three heptads of ideal dimeric coiled-coil sequences11 at the N-and C-termini of the protein, and a series of four point mutations, we generated NEMO-EEAA, a construct fully dimeric and folded in a coiled coil, which rescued IKK-binding affinity to the nanomolar range as observed for full length NEMO12. As an additional advantage, we hoped the coiled-coil adaptors (based on the GCN4 sequence) would facilitate crystallization and eventually aid in the X-ray structure determination via molecular replacement. Coiled-coil adaptors have been similarly utilized to both increase stability, improve solution behavior and facilitate crystallization for trimeric coiled coils and antibody fragments13,14. NEMO-EEAA is easily expressed and purified from Escherichia. coli cells with a cleavable Histidine tag, is soluble, folded in a stable dimeric coiled coil and is easily crystallized, with diffraction to 1.9 Å. The presence of the ordered coiled-coil regions of GCN4 could additionally aid in phasing the data from crystals of NEMO-EEAA by molecular replacement using the known structure of GCN415.

Given the results obtained with apo-NEMO-EEAA, we believe the protocols described here could also be applied to the crystallization of NEMO-EEAA in the presence of small peptides (like the NBD peptide) or small molecule inhibitors, with the goal of understanding the requirements for NEMO inhibition and structure-based optimization of initial lead inhibitors to high affinity. Given the plasticity and dynamic nature of many coiled-coil domains16, the use of the coiled-coil adaptors could find more general applicability in aiding structural determination.

Protocol

1. Design of construct for crystallography

  1. Clone the sequence of NEMO-EEAA as in previous publication12 in a vector for expression in E. coli using the T7 promoter, including a N-terminal hexa-histidine tag and a protease cleavage site.
    NOTE: In this protocol, we used a vector modified to include a N-terminal hexa-histidine tag and a Tobacco Etch Virus (TEV) cleavage site10. This vector facilitates cleavage of the His tag for protein crystallization and leaves only the short extension of GSW residues before the start of the desired protein sequence. The vector from which this was derived, and alternative vectors are listed in the Table of Materials. In this protocol, subsequent modifications to the original NEMO(44-111) sequence were introduced stepwise, as described earlier10, using side directed mutagenesis. We initially attempted to stabilize the NEMO coiled-coil dimer appending the ideal coiled-coil adaptors (in a length of at least three heptads) to the N-terminal or C-terminal end or to both. The double coiled coil was the most promising from earlier crystallization trials and it was subsequently modified introducing mutations to improve crystallization as described previously12.

2. Large scale expression of His6 tagged NEMO-EEAA

  1. Transform construct into BL21(DE3) competent cells. Store at -80 °C as a cell glycerol stock.
  2. Day 1 – Prepare a cell starter culture. In a 125 mL Erlenmeyer flask, add 20 mL of Terrific Broth solution and 20 µL of a 100 mg/mL stock of Ampicillin. Add a few microliters of cell glycerol stock (from -80 °C storage of BL21(DE3) competent cells transformed with vector).
  3. Shake the 10 mL starter culture overnight at 37 °C, 220 rpm (approximately 15 h).
  4. Day 2 – From the starter, dilute to an OD600 = 0.1 in 250 mL of Terrific Broth. Add ampicillin to a final concentration of 100 µg/mL. Grow to an OD600 = 0.8-1.0.
    1. Add isopropyl β-D-1-thiogalactopyranoside (IPTG) to 500 µM, and grow for 4 h at 37 °C.
    2. Measure OD600 of induced culture after 4 h. Culture should reach an OD600 = 6-10.

3. Purification of His6 tagged NEMO-EEAA

  1. Spin cell culture down at 3,800 x g for 20 min at 4 °C.
  2. Save the cell pellet and discard the medium.
    NOTE: The cell pellet can be saved and stored at -20 °C at this point, for purification at a later time.
  3. Resuspend the cells in 40 mL of lysis buffer containing 20 mM Tris, 150 mM NaCl, 10 mM imidazole, 2 mM MgCl2, 0.5 mM phenylmethylsulfonyl fluoride, 2 mM Dithiothreitol (DTT), and 3 µL of Benzonase Nuclease.
    NOTE: The Nickel immobilized metal ion affinity chromatography (IMAC) column utilized is compatible with 2 mM DTT. Alternatively, 0.2 mM tris(2-carboxyethyl)phosphine (TCEP) can be utilized.
  4. Split resuspended cells into two 20-25 mL aliquots.
  5. Lyse the cells using French press (approximate pressure 25,000 psi), repeating 2-3 times for each aliquot (in the cold room).
    NOTE: Alternatively, cells could be lysed by sonication (not tested in this protocol).
  6. Add urea to the cell lysate to a final concentration of 8 M, allow to incubate on a rocking platform for a minimum of 2 h or up to overnight. This and all following purification steps, with the exception of the dialysis, can be performed at room temperature.
  7. Day 3 – Transfer the lysate to ultracentrifuge tubes and balance weight, ensuring lysate fills tubes to at least ¾ full. Spin the lysate at 125,000 x g for 45 min at 25 °C. Decant the supernatant into a 100 mL beaker for loading onto column.
    NOTE: Centrifuging at 4 °C will cause urea to crash out.
  8. On a fast liquid chromatography system, remove ethanol from IMAC 5 mL column with 25 mL of ultrapure H2O at 5 mL/min, followed by 25 mL of elution buffer containing 20 mM Tris, 150 mM NaCl, 500 mM imidazole, 2 mM DTT, pH 8.0, then 25 mL of binding buffer containing 20 mM Tris, 150 mM NaCl, 10 mM imidazole, 2 mM DTT, 8 M urea, pH 8.0.
  9. Load urea incubated supernatant at 3 mL/min onto IMAC column, collecting the flow through. Wash the column for 10 column volumes with binding buffer at 3 mL/min.
  10. Refold NEMO-EEAA construct on column by washing column with refolding buffer for 20 column volumes at 3 mL/min, containing 20 mM Tris, 150 mM NaCl, 10 mM imidazole, 2 mM DTT, pH 8.0.
  11. Perform gradient elution of NEMO-EEAA, from 10 to 500 mM Imidazole over a 12-column volume gradient, collecting all eluate in fraction collection plate (1 mL fractions).
  12. Continue elution at 500 mM imidazole for two column volumes, continuing to collect.
  13. Run sodium dodecyl sulfate (SDS)- polyacrylamide gel electrophoresis (PAGE) of fractions to determine NEMO- EEAA presence in elution fractions.
    NOTE: We used 10% acrylamide, MES buffer.
  14. Pool fractions containing pure target protein.
  15. Measure protein concentration by Bradford assay17.
    NOTE: This is necessary to estimate the amount of protease for tag cleavage.

4. His6 tag cleavage and purification

  1. Add TEV in a 1:10 weight ratio of TEV:NEMO-EEAA protein to cleave the His6 tag. The TEV protease was purified in house.
    NOTE: Optimize the amount of TEV, time and temperature required for complete cleavage separately.
    1. Express TEV protease, S219V mutant18 in BL21(DE3)-RIL cells and purify as described earlier19. Briefly grow the cells as described in step 2, lyse by French press and purify using an IMAC column. Store final protein in 25 mM sodium phosphate buffer, pH 7.8, 150 mM NaCl, 1 mM EDTA, 2 mM DTT, 20% v/v glycerol.
  2. Dialyze the sample overnight (approximately 15 h) in 4 L of 20 mM Tris, 150 mM NaCl, 2 mM DTT, pH 8.0, to allow for cleavage and to remove excess imidazole from the sample for the subsequent purification.
  3. Day 4 – Remove the sample from dialysis. Run an SDS-PAGE gel of the sample from TEV cleavage to ensure cleavage is completed.
  4. On a fast liquid chromatography system, remove ethanol from an IMAC 5 mL column with 25 mL of ultrapure H2O at 5 mL/min, followed by 25 mL of elution buffer containing 20 mM Tris, 150 mM NaCl, 500 mM imidazole, 2 mM DTT, pH 8.0, then binding buffer containing 20 mM Tris, 150 mM NaCl, 10 mM imidazole, 2 mM DTT, pH 8.0.
  5. Load the column at 1 mL/min with TEV-cleaved NEMO-EEAA. Cleaved NEMO-EEAA will elute in the flow-through: collect in a 96 well fraction collection plate (1 mL fractions). Wash the column for five column volumes of 20 mM Tris, 150 mM NaCl, 10 mM imidazole at 1 mL/min, continuing to collect in fraction collection plate.
  6. Elute TEV and uncleaved His6-NEMO-EEAA with three column volumes of 20 mM Tris, 150 mM NaCl, 500 mM imidazole, 2 mM DTT, pH 8.0, collecting elution in a 50 mL flask.
  7. Run SDS-PAGE gel of flow-through fractions to determine presence of cleaved NEMO-EEAA.
  8. Pool flow-through fractions containing cleaved NEMO-EEAA construct, and concentrate using a stirred-cell concentrator to 5 mL. Membrane molecular weight cut-off (MWCO) = 3 kDa.
  9. Using a 3 kDa MWCO membrane, dialyze concentrated sample in 2 L of 20 mM Tris, 100 mM NaCl, 2 mM DTT, pH 8.0 for 2 h. Change the dialysis buffer to 2 L of fresh dialysis buffer for overnight dialysis (approximately 15 h), at 4 °C.
  10. Day 5 – Load 5 mL of the dialyzed sample on a size exclusion chromatography (SEC) 16 mm x 60 cm column (34 μm average particle size) at 1 mL/min in 2 mM Tris, 100 mM NaCl, 2 mM DTT, pH 8.0. Repeat with additional columns depending on sample volume.
  11. Pool the fractions corresponding to dimeric NEMO-EEAA.
    NOTE: NEMO-EEAA elutes between 60-65 mL, corresponding to a larger molecular weight protein, due to the elongated nature of the dimeric coiled coil.
  12. Concentrate using a stirred-cell concentrator and a MWCO = 3 kDa membrane to a final concentration of 113 µM (1.65 mg/mL).
  13. Aliquot the protein and store at 4 °C (stable for over 1 month).

5. Sparse matrix screening

NOTE: The protocol performs crystallization trials using commercially available screens and setting up sitting drop experiments using a crystallization robot. Crystal images are collected automatically by an imager.

  1. Using commercially available sparse matrix screens (see Table of Materials), pipette 60 µL of sparse matrix solution into each of the 96 wells of a 2 drop-chamber crystallization plate for sitting drop vapor diffusion (reservoir solution).
  2. Using a robotic drop setter, dispense 100 nL of protein solution at 1.65 mg/mL in a 1:1 ratio with reservoir solution in drop 1 for a final volume of 200 nL; then 66 nL of protein solution with 134 nL of reservoir solution for a final volume of 200 nL in drop 2 (1:2 ratio).
  3. Seal the plate using 3-inch-wide sealing tape immediately after dispensing.
    NOTE: Drops will dry out if left exposed to atmosphere for longer than 2-3 min.
  4. Store the trays in the crystallization imager storage, at 20 °C, checking the images collected automatically for crystal presence, starting after two days.
    NOTE: Crystallization screening proceeded in parallel with construct optimization. Initial crystals formed in the following conditions (commercial screens listed in the Table of Materials): a) 0.1 M Tris, pH 8.0, 30 % v/v polyethylene glycol (PEG) MME 550, 5% poly-γ-glutamic acid, 200-400 kDa low molecular weight polymer (PGA -LM); b) 0.1 M Tris, pH 7.8, 20% w/v PEG MME 2k, 5% PGA-LM; c) 0.1 M Tris, pH 7.8, 20% w/v PEG 3350, 5% PGA-LM. Sparse matrix screen crystals will have poor lattice uniformity; therefore, they will look poor using cross-polarized imaging. Use UV imaging to ensure that the crystals contain protein. The following seed stock generation step is necessary for obtaining the final diffraction quality crystals.

6. Seed stock generation

NOTE: We reproducibly obtain crystals for seed generation in 0.1 M Tris pH 8.0, 5% PGA-LM, 3.6% w/v PEG 20k. However, crystals will show high mosaicity and are unsuitable for data collection at this stage.

  1. Using a kit for seed generation, prepare seed stock by pipetting out entire drop with crystal present, and place into 50 µL of crystallization condition solution in the provided vial.
  2. Vortex the seed stock for 3 min, pulsing 20 s on and 10 s off.
  3. Serially dilute seed stock in 1:10 increments down to 1:10,000. Store all dilutions at 4 °C, for further use.

7. Fine screens

  1. Design fine screens varying the conditions for Tris, PGA-LM, and PEG. Vary PEG length for individual trays.
    NOTE: The fine screen that produced the crystal utilized for structure determination of NEMO-EEAA employed the following conditions: 0.1 M Tris pH 8; PGA-LM varied from 8 to 0% in columns 1-12. Rows A-H screened different PEGs, with concentrations varying in columns 1-12 as follows. A: PEG 200 (0-40% v/v); B: PEG 400 (0-40% v/v); C: PEG MME 500 (0-40% v/v); D: PEG 1000 (0-30% w/v); E: PEG 3350 (0-30% w/v); F: PEG 6k (0-30% w/v); G: PEG 10k (0-20% w/v); H: PEG 20k (0-20% w/v). The crystal appeared in well H4 (5.45% w/v PEG 20k, 5.8% w/v PGA-LM). In this protocol, a protein crystallography screen builder liquid handler was used to build the screens.
  2. Seed a protein stock in a 1:25 volume ratio of 1:1,000 seed dilution.
    NOTE: Concentration of NEMO-EEAA will drop slightly, but crystals will still form.
  3. Repeat step 2 using 1:10,000 seed dilution, same 1:25 volume ratio.
  4. Using the drop setter, dispense 100 nL of protein solution at 1.65 mg/mL, with 1:1,000 dilution of seed stock into a 1:1 ratio with reservoir solution in drop 1 for a final volume of 200 nL. Repeat for drop 2, but with 1:10,000 dilution of seed stock present.
  5. Seal the plate using 3-inch-wide sealing tape immediately after dispensing.
    NOTE: Drops will dry out if left exposed to atmosphere for longer than 2-3 min.
  6. Store the trays in the imager storage, at 20 °C, checking images collected after two days for crystal presence.
  7. Check the crystals with the cross-polarizer imager for lattice uniformity, to select for single conditions to set up following trays.

8. Generation of crystals for data collection

  1. Design single condition screens around Tris, PGA-LM, and PEG condition which produced uniform crystals as analyzed by cross-polarized images, and the largest crystals possible.
    NOTE: Crystals from these conditions are irregular in shape, mostly rectangular thin sheets. It is key to select a condition where the edges of the crystal are well defined and have the greatest thickness possible.
  2. Make 20 mL of crystallization condition by hand.
  3. Using a multi-channel pipettor, dispense 60 µL per well in a 2 drop-chamber, 96 well crystallization plate for sitting drop vapor diffusion.
  4. Prepare seed stock as described in step 6.2.
  5. Dispense the protein as described in step 6.3.
  6. Seal the plate using 3-inch-wide sealing tape immediately after dispensing.
    NOTE: Drops will dry out if left exposed to atmosphere for longer than 2-3 min.
  7. Store the trays in the imager at 20 °C and check the images for crystal presence every day.
  8. Check cross-polarized images of the crystals for lattice uniformity, to select crystals for data collection.

9. Determination of cryo-protectant

  1. To test the cryo-protectants, create stock solutions corresponding to the crystallization conditions but containing 30%, 20%, 10%, and 5% higher concentration of each component. The addition of the cryo-protectant volume will result in a final concentration of components that is the same as the crystallization conditions.
    NOTE: For testing a cryo-protectant at a 30% concentration by volume for a 0.1 M Tris crystallization condition, start with a stock solution of 0.143 M Tris, before adding the cryo-protectant.
  2. From a cryo-reagents kit, create 10 µL of sample for cryo-protectant test by mixing 30% by volume of cryo condition in 70% of crystallization condition stock solution, for a final concentration of 30% cryo-protectant in original crystallization conditions. Mix thoroughly.
    1. Using a 10 µL pipette, take 5 µL of test cryo-protected solution and plunge the pipet tip into liquid nitrogen. If ice is observed, discard.
    2. Test all cryo-protectants at 30%. For the successful solutions, repeat the process at 20%, then 10% and 5% of cryo-protectant.
    3. Utilizing the successful cryo-protectant solution with the smallest percentage of cryo-protectant, add 0.5 µL of solution into a test drop with crystals present. Observe under microscope, timing how long crystal lasts in the condition, if not indefinite.
      NOTE: These crystals are for test only and will be discarded. For NEMO-EEAA, 12% 1,2-propanediol is the optimal cryo-protectant solution. 12% accounts for the dilution the cryo-protectant solution will experience when added to the crystal drop of approximately 100 nL, for an approximate final concentration of 1,2-propanediol of 10%.

10. Crystal looping

  1. Loop crystals 1-2 days before shipment to synchrotron.
    NOTE: Crystals will be roughly 60-100 µm in diameter: 0.05 – 0.10 mm loops are ideal for looping.
  2. Cut the tape from the top of the well.
  3. Add 0.5 µL of crystallization solution containing 12% 1,2-propanediol cryo-protectant directly to the well.
    NOTE: Final concentration of 1,2-propanediol is now at approximately 10%, due to dilution by 100 nL of drop solution (approximate drop volume reduction from initial 200 nL, due to vapor diffusion).
  4. Loop the crystal from the well.
    NOTE: Crystals often grow on the bottom of the well but will dislodge with a gentle nudge from the loop. Once dislodged, loop.
  5. Store the crystal containing cryo-loops in pucks immersed in liquid N2.
  6. Store these pucks in liquid N2 in Dewar flask until they are ready for shipment for X-ray diffraction at the synchrotron.

11. Data collection

  1. Collect X-ray diffraction data. In this protocol, use AMX beamline (ID: 17-ID-1), National Synchrotron Light Source II.
    NOTE: Data was collected on site but can be collected remotely. Collect data in the region of the crystal which showed lattice uniformity in cross-polarized images. Position the crystals in the loop so that data collection does not involve "poor" regions of the crystal while the crystal rotates in the goniometer. Data which provided the best resolution came from collection on the edge of an extension of a crystal about 5 x 5 μm in size. Use rastering to identify the best areas on the crystal to collect20.

12. X-ray data processing

  1. Process dataset to highest resolution collected (1.8 Å) with XDS IDXREF program to determine space group, unit cell, and solvent content.
  2. Integrate data using XDS INTEGRATE program.
  3. Process scaled intensities from XDS XSCALE program using STARANISO Server, using I/σI cutoff mean of 1.2 for diffraction-limit surface for the data.
    NOTE: Data will not be cut in true ellipsoid. Retain all data above the I/σI of 1.2 cutoff. The statistics on the data calculated for spherical completeness will be poor, due to the non-spherical truncation. The elliptical completeness was 88% with highest resolutions of: 1.88 Å, 2.10 Å and 2.55 Å along the a*, b* and c axis, respectively.

13. Structure solution

  1. Utilize the X-ray structure of GCN4 (PDB: 4DMD)15 as a search model for molecular replacement using MRage21 in PHENIX22. The 4DMD structure was defined in MRage as an "ensemble", and the MRage solution successfully built the structure portion corresponding to the N-terminal coiled-coil adaptor of NEMO-EEAA, homologous to the search model, for both chains in the dimer.
    NOTE: Turn off anisotropy correction in PHASER, or data will be further scaled back.
  2. Utilize successive rounds of Autobuild23 in PHENIX and manual building (using 2Fo-Fc and Fo-Fc maps, in Coot24) to build the remainder of the structure.
  3. Manually build the residues still missing into the model based on 2Fo-Fc and Fo-Fc maps, using Coot24.
    NOTE: The last stage involved building the 4 N-terminal residues and 4 C-terminal residues for each monomer. Sidechain placement was also manually adjusted as needed.
  4. Calculate a composite omit map using PHENIX and a 10% omission of the structure.

14. Structure refinement

  1. Refine the structures with PHENIX Refine. Run the initial refinements against bulk-solvent and stereochemistry weights, relaxing RMSbond and RMSangle constraints to 0.01 and 1.0, respectively. Continue refinement on Individual B-factors, TLS parameters, and Occupancies.

Representative Results

Cloning, expression and purification of the IKK-binding domain of NEMO.
The protocol followed in this study to obtain the final sequence of NEMO-EEAA (Figure 1A), which produced diffraction quality crystals, involved the expression and characterization of all the intermediate constructs, including the addition of the coiled-coil adaptors at N- and or C-terminus, the mutations C76A, C95S and the mutations E56A, E57A. Figure 1B displays an SDS-PAGE gel of samples collected throughout the purification procedure as described in the Scheme in Figure 1C. The protein is overexpressed in E. coli and appears as a band approximately at the 14 kDa MW weight marker on the SDS-PAGE gel (lane 3, cells collected at harvest and lysed in Laemmli sample buffer supplemented by 8 M urea). The protein appears pure after the first IMAC column and displays a monomer and a dimer band at the level of the 14 and 28 kDa MW markers on the SDS-PAGE gel (lane 9). TEV cleavage is practically complete following the protocol and the protein elutes with the flow through during the second IMAC column almost entirely as a dimer, at the expected MW (band below 28 kDa). Size exclusion chromatography displays a single peak eluting between 60-65 mL and corresponding in our experience to the dimer (Figure 1D). The dimeric coiled coil always elutes earlier than expected on SEC due to the elongated shape of the coiled coil and the consequently large hydrodynamic radius10. NEMO-EEAA in fractions from SEC peak still appears as a monomer and a dimer on SDS-Page gel (lanes 14-15). Utilizing a stirred-cell concentrator is important to prevent sample possible aggregation and precipitation upon concentration.

Crystallization of NEMO-EEAA
Initial crystals were obtained from a commercial screen using PGA (see Table of Materials), utilizing 1.65 µg/mL of NEMO-EEAA in 2 mM Tris, 100 mM NaCl, 2 mM DTT, pH 8.0. Fine screening produced crystals in 0.1 M Tris pH 8.9, 5% PGA-LM, 3.6% PEG 20k (Figure 2A), which were utilized to produce a seed stock. Final crystals were obtained with seeding in 0.1 M Tris pH 8.0, 5.8% PGA-LM, 5.45% PEG 20k (Figure 2B).

Data collection and structure determination
NEMO-EEAA crystals suffer from mosaicity and anisotropy. Crystals formed in the P 1 21 1 space group, with data resolution varying in the a*, b* and c* axis (1.88 Å, 2.10 Å and 2.55 Å). Examples of diffraction profiles are in Figure 3. Data was acquired at the AMX (17-ID-1) beamline of NSLS II, with a beam size of 7 x 5 μm2. The small beam size was essential to focus on the desired portion of the crystal (Figure 2B) and ensure data quality.

The successful protocol for structure determination requires anisotropic truncation of the data using the STARANISO27 server (http://staraniso.globalphasing.org/cgi-bin/staraniso.cgi), followed by phasing by molecular replacement using MRage21 within PHENIX22 and the structure of dimeric GCN4 (PDB: 4DMD)15 as a search model. In the solution of this structure phasing was initially attempted by labeling the native methionine with SeMet. The anomalous signal was too weak, probably due to the solvent exposed nature of Met95 in the unbound form of NEMO (SeMet95 was successfully used for phasing of the NEMO / IKKβ structure9).

Initial data analysis was attempted with spherical truncation of the data to 2.3 Å. This data set could not be successfully phased by molecular replacement but a solution was obtained using MR-ROSETTA25 and the structure of NEMO(44-111) in complex with IKKβ(701-745) as a search model (PDB: 3BRV)9. This initial model could not be refined successfully. We utilized the Diffraction Anisotropy Server at UCLA26 to elliptically truncate the data and to remove anisotropy by anisotropic scaling. The newly processed dataset could be phased by molecular replacement. To further improve the data, we employed the STARANISO27 server for anisotropic truncation of the data and amplitudes were corrected with an anisotropic correction factor with Bayesian estimation28. This data, resulting in an increase in the number of unique reflections to 19,560, was used for structure refinement. Composite omit maps where calculated with PHENIX, excluding 10% of the atoms at a time, and compared with the final structure model, to confirm that the structure was not biased by the atomic model. The crystallographic model is complete except for the first and last residues in chain A of NEMO-EEAA, for which no electron density was observed.

NEMO-EEAA is a homo-dimeric, irregular, parallel coiled coil of ~175 Å in length. The regular coiled-coil region encompasses the ideal coiled-coil adaptor sequence at the N-terminus (residues 20-50) and the first two heptads of the NEMO proper sequence (residues 51-65). A regular coiled coil is also present at the C-terminus, starting at NEMO residue 97 and encompassing the C-terminal ideal coil-coil adaptor (Figure 4A). The central portion, encompassing NEMO residues 66-98 displays larger interhelical distances (interhelical spacing goes from an average value of 7.6 Å in the regular coiled-coil structure to a maximum of 11.5 Å in the irregular region) and discontinuous hydrophobic interface compared with an ideal coiled coil. This region of NEMO also represents the interface for binding IKKβ and undergoes a conformational change upon ligand binding. The IKKβ-bound structure displays a more open coiled-coil conformation to accommodate the ligand with larger interhelical spacing by 1.0 to 2.2 Å in this region (Figure 4B)12. In the apo structure residues Leu93, Met94, Lys96, Phe97 and Arg101 are shifted toward the center of the coiled coil to invade the ligand binding pocket (the Cα-Cα distance for Phe97 is tighter by 2.9 Å), with the overall effect of closing the large hydrophobic cleft which hosts the ligand in the IKKβ-bound structure.

Figure 1
Figure 1: Purification of NEMO-EEAA. (A) Sequence alignment of NEMO from Homo Sapiens, Mus Musculus and Bos Bovis and the engineered NEMO-EEAA. The coiled-coil adaptors sequence is underlined, and the mutations are highlighted in orange. (B) SDS-PAGE gel of fractions collected during expression and purification (as labeled and referenced in flow chart 1C). 10% Acrylamide, MES buffer. (C) A flow chart for the purification of NEMO-EEAA. (D) Size-exclusion profile indicating the dimer of NEMO-EEAA (blue). In green the molecular weight markers (kDa) are indicated. Please click here to view a larger version of this figure.

Figure 2
Figure 2: Morphology and size of NEMO-EEAA crystals. (A) A crystal of NEMO-EEAA from the initial sparse matrix screen, unseeded. This type of crystal was used for seeding for subsequent crystallization attempts (0.1 M Tris pH 8.0, 5% PGA-LM, 3.6% PEG 20k; with a protein solution in 2 mM Tris, 100 mM NaCl 2 mM DTT, pH 8.0). (B) Crystal used for data collection (0.1 M Tris pH 8.0, 5.8% PGA-LM, 5.45% PEG 20k, with a protein solution in 2 mM Tris, 100 mM NaCl 2 mM DTT, pH 8.0). The approximate area used for data collection is circled in red. The scale bar for 100 µm length is defined in the figure. Please click here to view a larger version of this figure.

Figure 3
Figure 3: Crystallographic data obtained from NEMO crystals. (A) X-ray diffraction profile of early NEMO crystal: elongated streaks indicate mosaicity in the crystal. (B) X-ray diffraction profile of an optimized NEMO-EEAA crystal. The resolution ring is drawn at a spatial resolution of 2.5 Å. Please click here to view a larger version of this figure.

Figure 4
Figure 4: Structure of unbound NEMO. (A) The NEMO-EEAA dimer is shown as a ribbon, light blue = coiled-coil adaptors, blue = NEMO(51-112). (B) Superposition of apo NEMO-EEAA structure (blue, PDB: 6MI3) and NEMO(44-111) from the IKKβ-bound structure (grey, PDB: 3BRV, IKKβ is not displayed), shown as ribbons; the structures are aligned on chain A, region 44-111 only. This figure has been modified from previous publication12. Please click here to view a larger version of this figure.

Discussion

Crystallization attempts of NEMO in the unbound form were unsuccessful, including attempts using the full-length protein and several truncation constructs encompassing the IKK-binding domain. Our biophysical characterization of the IKK-binding domain of NEMO (residues 44-111) by circular dichroism, NMR spectroscopy and fluorescence anisotropy indicated that the construct, albeit able to bind IKKβ, existed in a state of conformational exchange, not suitable for crystallization9,10. Our approach involved engineering a construct of the IKK-binding domain of NEMO that adopted a more stable, folded and native-like conformation, eliminating the flexibility that prevented crystallization. Ideal coiled-coil domain adaptors fused to the N- and C-termini of the NEMO(44-111) sequence offer the advantage of stabilizing the dimeric coiled-coil fold of the native NEMO and facilitating crystallization14. Behavior of a series of protein constructs was monitored at each step through SDS-PAGE, size exclusion chromatography, circular dichroism, fluorescence anisotropy and NMR spectroscopy, as described earlier10,12. Despite the progressive improvement in all desired parameters no construct yielded diffraction quality crystals until the mutations E56A, E57A were introduced. The mutations were the highest impact mutations suggested by the Surface Entropy Reduction Server SERp29 that did not involve residues implicated in hot-spots of binding for IKKβ, as in the NEMO / IKKβ complex structure. Although other constructs stabilizing the ordered structure of the IKK-binding domain of NEMO through cysteine disulfide linkage and binding IKKβ with high affinity have been described30, the protocol here described represents the first successful approach to structure determination of the IKK-binding domain of NEMO in the unbound form.

Protein production and purification followed standard procedures in our laboratory. Upon cell lysis a considerable portion of the protein is present in the insoluble fraction, even when growing the cells after induction at 18 °C, therefore the protein was solubilized in 8 M urea after cell lysis and prior to purification, and refolded while bound to the IMAC column. Extensive washing of the column bound protein both under denaturing conditions and after refolding are critical for a pure product after the first purification step. The pure NEMO-EEAA has a higher tendency to precipitate than the previous constructs but is still sufficiently soluble under crystallization conditions.

A critical step in the structure determination was the use of seeding. In an approach similar to microseed matrix screening31, seeds from crystal obtained during sparse matrix screening were used in an additional screening of conditions, followed by a fine screening round, in order to determine final crystallization conditions. Most of the crystals grown in the final conditions display high mosaicity and are not suitable for data collection. Crystals were screened over several visits to the beamline and best data quality was achieved by collecting datasets at the edge of the crystal, where the newest growth had occurred. As the region which showed lattice uniformity in cross-polarized images was small, it was instrumental to have access to the AMX beamline at NSLS II, due to the small beam size.

We successfully determined the structure of NEMO-EEAA by molecular replacement using as a search model the structure of the dimeric coiled-coil of GCN415, which mapped to the ideal coiled-coil adaptors fused at the N- and C-termini of the NEMO sequence. The molecular replacement was successful as the GCN4 adaptors maintain their native structure when fused to NEMO. At the same time, we could verify that NEMO maintains its native like structure by comparing the portions not involved in IKK-binding with the corresponding structure region in the NEMO / IKKβ complex structure. As an alternative, it could be possible to use the structure of NEMO in the NEMO / IKKβ complex (PDB: 3BRV)9 as a molecular replacement search model, focusing on monomer B, which corresponds to the chain which undergoes the smallest conformational change upon ligand binding. This strategy showed some initial success using the MR-ROSETTA module of PHENIX.

Finally, it was essential for a successful structure determination to utilize all available data in the dataset, by resorting to an anisotropic cut-off of merged intensity data, as provided by the STARANISO27 server or the Diffraction Anisotropy Server at UCLA26.

The essential role played by the NEMO/IKK complex in the NF-kB pathway makes it a desirable target for modulation of the pathway for therapeutic intervention. Protein-protein interactions, especially when involving a large binding interface, are challenging to inhibit with small peptides or small molecules, and structure-based inhibitor design can offer a significant advantage. The constructs of the IKK-binding domain of NEMO that we developed overcome the limits of the flexible NEMO(44-111) to facilitate crystallization and structure determination. As the construct easily crystallizes in the unbound form, we envision that the same protocol can be successfully applied in the crystallization of the complex of NEMO with small molecule inhibitors, to determine a structure that would provide details on binding modes and allow further ligand improvements.

An analysis of crystal packing in the crystallization conditions achieved in this work indicates that ligand co-crystallization may be preferred to ligand soaking into apo-protein crystals. While crystal packing provides some space around chain B of the dimer (6 to 10 Å to the nearest chain) and on one face of the ligand binding site (approximately 13 Å in the hot-spot region between Phe82-Phe87), the symmetric binding pocket is completely occluded by nearby chains, preventing ligand binding.

Coiled coils are present in a significant proportion in the proteome and are essential in their function as molecular spacers, scaffolds and in communicating conformational changes16. Despite their abundance and relevant roles, there are relatively few structures of full-length coiled-coil proteins. The use of coiled-coil adaptors may aid in the stabilization of structural domains of coiled-coil proteins while preserving their native structure and aid in the structural determination and elucidation of their function.

Disclosures

The authors have nothing to disclose.

Acknowledgements

We thank Prof. D. Madden, for many helpful discussions throughout this project. We thank Prof. D. Bolon for the gift of the plasmid containing the optimized GCN4 coiled coil. We thank Dr. B. Guo for NEMO plasmids. We thank Christina R. Arnoldy, Tamar Basiashvili and Amy E. Kennedy for demonstrating the procedure. We thank the BioMT Crystallography Core Facility and the departments of Chemistry and of Biochemistry & Cell Biology at Dartmouth for the use of the crystallography equipment and the BioMT personnel for their support. This research used the AMX beamline of the National Synchrotron Light Source II, a U.S. Department of Energy (DOE) Office of Science User Facility operated for the DOE Office of Science by Brookhaven National Laboratory under Contract No. DE-SC0012704. We thank the staff at NSLS II for their support. This work was funded by NIH grants R03AR066130, R01GM133844, R35GM128663 and P20GM113132, and a Munck-Pfefferkorn Novel and Interactive grant.

Materials

20% w/v γ-PGA (Na+ form, LM) Molecular Dimensions MD2-100-150 For fine screen crystallization of NEMO-EEAA
3.5 kDa MWCO Dialysis Membrane Spectra/Por 132724 For dialysis removal of imidazole
Amicon Stirred Cell Millipose Sigma UFSC 05001 For protein concentration
Ammonium Chloride Millipore Sigma G8270 For minimal media labeling
Benzonase Nuclease Millipore Sigma 9025-65-4 For digestion of nucleic acid
BL21-CodonPlus (DE3)-RIL Competent Cells Agilent Technologies Model: 230245 TEV expression
CryoPro Hampton Research HR2-073 Cryo-protectants kit
D-Glucose (Dextrose) Millipore Sigma A9434 For minimal media labeling
Difco Terrific Broth ThermoFisher DF043817 For culture growth
Dithiothreitol > 99% Goldbio DTT25 For reduction of disulfides
E. coli: Rosetta 2 (DE3) Novagen 71400-3 Expression of unlabeled NEMO-EEAA
FORMULATOR Formulatrix Liquid handler/ screen builder
HCl – 1.0 M Solution Hampton Research HR2-581 For fine screen crystallization of NEMO-EEAA
HiLoad 16/600 Superdex 75 pg GE Healthcare 28989333 For size exclusion purification
HisTrap HP 5 mL column GE Healthcare 17524802 For purification of His-tagged NEMO-EEAA
HT 96 MIDAS Molecular Dimensions MD1-59 For sparse matrix screening of NEMO-EEAA
HT 96 Morpheous Molecular Dimensions MD1-46 For sparse matrix screening of NEMO-EEAA
Imidazole ThermoFisher 288-32-4 For elution from His-trap column
Isopropyl-beta-D-thiogalactoside Goldbio I2481C5 For induction of cultures
MRC2 crystallization plate Hampton Research HR3-083 Crystallization plate
NT8 – Drop Setter Formulatrix Crystallization
pET-16b Millipore Sigma 69662 For cloning of NEMO-EEAA
pET-45b Millipore Sigma 71327 For cloning of NEMO-EEAA
Phenylmethylsulfonyl fluoride ThermoFisher 36978 For inhibition of proteases
Polycarbonate Bottle for use in Ultracentrifuge Rotor Type 45 Ti Beckmann Coulter 339160 Ultracentrifuge bottle
Polyethylene Glycol 20,000 Hampton Research HR2-609 For fine screen crystallization of NEMO-EEAA
pRK793 (TEV) Addgene Plasmid 8827 For TEV production
QuikChange XL II Agilent Technologies 200522 Site directed mutagenesis
Required Cap Assembly: Beckmann Coulter 355623 Ultracenttrifuge bottle cap
ROCK IMAGER Formulatrix Crystallization Imager
Seed Bead Kit Hampton Research HR2-320 Seed generation
Sodium Chloride ≥ 99% Millipore Sigma S9888 For buffering of purification solutions
TCEP (Tris (2-Carboxyethyl) phosphine Hydrochloride) Goldbio TCEP1 Reducing agent
The Berkeley Screen Rigaku MD15-Berekely For sparse matrix screening of NEMO-EEAA
The PGA Screen Molecular Dimensions MD1-50 For fine screen crystallization of NEMO-EEAA
Tris – 1.0 M Solution Hampton Research HR2-589 For fine screen crystallization of NEMO-EEAA
Ultrapure Tris Buffer (powder format) Thermofisher 15504020 For buffering of purification solutions
Urea ThermoFisher 29700 For denaturation of NEMO-EEAA

References

  1. Gilmore, T. D. Introduction to NF-kappaB: players, pathways, perspectives. Oncogene. 25 (51), 6680-6684 (2006).
  2. Bassères, D. S., Baldwin, A. S. Nuclear factor-kappaB and inhibitor of kappaB kinase pathways in oncogenic initiation and progression. Oncogene. 25 (51), 6817-6830 (2006).
  3. Hayden, M. S., West, A. P., Ghosh, S. NF-kappaB and the immune response. Oncogene. 25 (51), 6758-6780 (2006).
  4. Lee, T. I., Young, R. A. Transcriptional regulation and its misregulation in disease. Cell. 152 (6), 1237-1251 (2013).
  5. Courtois, G., Gilmore, T. D. Mutations in the NF-kappaB signaling pathway: implications for human disease. Oncogene. 25 (51), 6831-6843 (2006).
  6. Zhao, J., et al. Development of novel NEMO-binding domain mimetics for inhibiting IKK/NF-κB activation. PLoS biology. 16 (6), 2004663 (2018).
  7. Zhang, Q., Lenardo, M. J., Baltimore, D. 30 Years of NF-κB: a blossoming of relevance to human pathobiology. Cell. 168 (1-2), 37-57 (2017).
  8. Jin, D. Y., Jeang, K. T. Isolation of full-length cDNA and chromosomal localization of human NF-kappaB modulator NEMO to Xq28. Journal of Biomedical Science. 6 (2), 115-120 (1999).
  9. Rushe, M., et al. Structure of a NEMO/IKK-associating domain reveals architecture of the interaction site. Structure. 16 (5), 798-808 (2008).
  10. Guo, B., Audu, C. O., Cochran, J. C., Mierke, D. F., Pellegrini, M. Protein engineering of the N-terminus of NEMO: structure stabilization and rescue of IKKβ binding. 生物化学. 53 (43), 6776-6785 (2014).
  11. Havranek, J. J., Harbury, P. B. Automated design of specificity in molecular recognition. Nature Structural Biology. 10 (1), 45-52 (2003).
  12. Barczewski, A. H., Ragusa, M. J., Mierke, D. F., Pellegrini, M. The IKK-binding domain of NEMO is an irregular coiled coil with a dynamic binding interface. Scientific Reports. 9 (1), 2950 (2019).
  13. Arimori, T., et al. Fv-clasp: an artificially designed small antibody fragment with improved production compatibility, stability, and crystallizability. Structure. 25 (10), 1611-1622 (2017).
  14. Hernandez Alvarez, B., Hartmann, M. D., Albrecht, R., Lupas, A. N., Zeth, K., Linke, D. A new expression system for protein crystallization using trimeric coiled-coil adaptors. Protein Engineering, Design and Selection. 21 (1), 11-18 (2008).
  15. Oshaben, K. M., Salari, R., McCaslin, D. R., Chong, L. T., Horne, W. S. The native GCN4 leucine-zipper domain does not uniquely specify a dimeric oligomerization state. 生物化学. 51 (47), 9581-9591 (2012).
  16. Truebestein, L., Leonard, T. A. Coiled-coils: The long and short of it. BioEssays: News and Reviews in Molecular, Cellular and Developmental Biology. 38 (9), 903-916 (2016).
  17. Bradford, M. M. A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Analytical Biochemistry. 72, 248-254 (1976).
  18. Kapust, R. B., et al. Tobacco etch virus protease: mechanism of autolysis and rational design of stable mutants with wild-type catalytic proficiency. Protein Engineering. 14 (12), 993-1000 (2001).
  19. Miladi, B., et al. A new tagged-TEV protease: construction, optimisation of production, purification and test activity. Protein Expression and Purification. 75 (1), 75-82 (2011).
  20. Miller, M. S., et al. Getting the Most Out of Your Crystals: Data Collection at the New High-Flux, Microfocus MX Beamlines at NSLS-II. Molecules. 24 (3), (2019).
  21. McCoy, A. J., Grosse-Kunstleve, R. W., Adams, P. D., Winn, M. D., Storoni, L. C., Read, R. J. Phaser crystallographic software. Journal of Applied Crystallography. 40, 658-674 (2007).
  22. Adams, P. D., et al. PHENIX: a comprehensive Python-based system for macromolecular structure solution. Acta Crystallographica Section D: Biological Crystallography. 66, 213-221 (2010).
  23. Terwilliger, T. C., et al. Iterative model building, structure refinement and density modification with the PHENIX AutoBuild wizard. Acta Crystallographica. Section D, Biological Crystallography. 64, 61-69 (2008).
  24. Emsley, P., Cowtan, K. Coot: model-building tools for molecular graphics. Acta Crystallographica. Section D, Biological Crystallography. 60, 2126-2132 (2004).
  25. Terwilliger, T. C., et al. phenix.mr_rosetta: molecular replacement and model rebuilding with Phenix and Rosetta. Journal of Structural and Functional Genomics. 13 (2), 81-90 (2012).
  26. Strong, M., Sawaya, M. R., Wang, S., Phillips, M., Cascio, D., Eisenberg, D. Toward the structural genomics of complexes: crystal structure of a PE/PPE protein complex from Mycobacterium tuberculosis. Proceedings of the National Academy of Sciences of the United States of America. 103 (21), 8060-8065 (2006).
  27. Tickle, I. J., et al. . STARANISO. , (2018).
  28. French, S., Wilson, K. On the treatment of negative intensity observations. Acta Crystallographica Section A: Crystal Physics, Diffraction, Theoretical and General Crystallography. 34 (4), 517-525 (1978).
  29. Goldschmidt, L., Cooper, D. R., Derewenda, Z. S., Eisenberg, D. Toward rational protein crystallization: A Web server for the design of crystallizable protein variants. Protein Science: A Publication of the Protein Society. 16 (8), 1569-1576 (2007).
  30. Zhou, L., et al. Disulfide-mediated stabilization of the IκB kinase binding domain of NF-κB essential modulator (NEMO). 生物化学. 53 (50), 7929-7944 (2014).
  31. D’Arcy, A., Bergfors, T., Cowan-Jacob, S. W., Marsh, M. Microseed matrix screening for optimization in protein crystallization: what have we learned. Acta Crystallographica. Section F, Structural Biology Communications. 70, 1117-1126 (2014).

Play Video

Cite This Article
Barczewski, A. H., Ragusa, M. J., Mierke, D. F., Pellegrini, M. Production, Crystallization, and Structure Determination of the IKK-binding Domain of NEMO. J. Vis. Exp. (154), e60339, doi:10.3791/60339 (2019).

View Video