Prenylation is an important modification on peripheral membrane binding proteins. Insect cells can be manipulated to produce farnesylated and carboxymethylated KRAS4b in quantities that enable biophysical measurements of protein-protein and protein-lipid interactions
Protein prenylation is a key modification that is responsible for targeting proteins to intracellular membranes. KRAS4b, which is mutated in 22% of human cancers, is processed by farnesylation and carboxymethylation due to the presence of a 'CAAX' box motif at the C-terminus. An engineered baculovirus system was used to express farnesylated and carboxymethylated KRAS4b in insect cells and has been described previously. Here, we describe the detailed, practical purification and biochemical characterization of the protein. Specifically, affinity and ion exchange chromatography were used to purify the protein to homogeneity. Intact and native mass spectrometry was used to validate the correct modification of KRAS4b and to verify nucleotide binding. Finally, membrane association of farnesylated and carboxymethylated KRAS4b to liposomes was measured using surface plasmon resonance spectroscopy.
Posttranslational modifications play a key role in defining the functional activity of proteins. Modifications such as phosphorylation and glycosylation are well established. Lipid modifications are less well characterized, however. It is estimated that as much as 0.5% of all cellular proteins may be prenylated1. Prenylation is the transfer of a 15-carbon farnesyl or a 20-carbon geranylgeranyl lipid chain to an acceptor protein containing the CAAX motif2. Prenylated proteins have been implicated in the progression of several human diseases including premature aging3, Alzheimer's4, cardiac dysfunction5, choroideremia6, and cancer7. The small GTPases, HRAS, NRAS, and KRAS1, nuclear laminins, and the kinetochores CENP-E and F are farnesylated proteins under the basal condition. Other small GTPases, namely RhoA, RhoC, Rac1, cdc-42, and RRAS are geranylgeranylated8, whereas RhoB can be farnesylated or geranylgeranylated9.
The small GTPase KRAS4b functions as a molecular switch, essentially transmitting extracellular growth factor signaling to intracellular signal transduction pathways that stimulate cell growth and proliferation, via multiple protein-protein interactions. There are two key aspects of KRAS4b biochemistry that are essential for its activity. First, the protein cycles between an inactive GDP and an active GTP bound state whereby it actively engages with effectors. Second, a C-terminal poly-lysine region and a farnesylated and carboxymethylated cysteine direct the protein to the plasma membrane, enabling recruitment and activation of downstream effectors. Mutant KRAS4b is an oncogenic driver in pancreatic, colorectal, and lung cancer10, and as such, therapeutic intervention would have a huge clinical benefit. Production of authentically modified recombinant protein that is farnesylated and carboxymethylated would enable biochemical screening using KRAS4b in combination with membrane surrogates such as liposomes or lipid nanodiscs11,12.
Farnesyl transferase (FNT) catalyzes the addition of farnesyl pyrophosphate to the C-terminal cysteine in the CAAX motif in KRAS4b. After prenylation, the protein is trafficked to the endoplasmic reticulum (ER) where the Ras converting enzyme (RCE1) cleaves the three C-terminal residues. The final step in processing is methylation of the new C-terminal farnesylcysteine residue by the ER membrane protein, isoprenylcysteine carboxyl methyltransferase (ICMT). Expression of recombinant KRAS4b in E. coli results in the production of an unmodified protein. Previous attempts to produce processed KRAS4b have been limited due to insufficient yields for structural or drug screening experiments or have failed to recapitulate the native full-length mature protein13,14. The protocol presented here utilizes an engineered baculovirus-based insect cell expression system and purification method that generates highly purified, fully processed KRAS4b at yields of 5 mg/L of cell culture.
Careful protein characterization is essential to validate the quality of recombinant proteins prior to embarking on structural biology or drug screening studies. Two key parameters of fully processed KRAS4b are validation of the correct prenyl modification and the availability of the farnesylated and carboxymethylated C-terminus (FMe) for interaction with membrane substitutes or lipids. Electrospray ionization mass spectrometry (ESI-MS) of the KRAS4b-FMe was used to measure the molecular weight and confirm the presence of the farnesyl and carboxymethyl modifications. Native mass spectrometry, where samples are sprayed with nondenaturing solvents, was used to demonstrate that KRAS4b-FMe was also bound to its GDP cofactor. Finally, surface plasmon resonance spectroscopy was used to measure the direct binding of KRAS4b-FMe with immobilized liposomes.
1. Protein purification
Buffer solution | Buffering agent (all 20 mM) | pH | NaCl (mM) | imidazole (mM) | MgCl2 | TCEP |
A | HEPES | 7.3 | 300 | – | 5 | 1 |
B | HEPES | 7.3 | 300 | 35 | 5 | 1 |
C | HEPES | 7.3 | 300 | 500 | 5 | 1 |
D | MES | 6.0 | 200 | – | 5 | 1 |
E | MES | 6.0 | – | – | 5 | 1 |
F | MES | 6.0 | 100 | – | 5 | 1 |
G | MES | 6.0 | 1000 | – | 5 | 1 |
H | HEPES | 7.3 | 300 | – | 1 | 1 |
2. Sample preparation for intact mass analysis and native mass analysis
3. Validation of KRAS4b-FMe binding to liposomes
One of the largest variables in the protocol is the amount of expressed target protein (His6-MBP-tev-KRAS4b). This protocol was developed using an isolate from a Trichoplusia ni cell line, Tni-FNL17, adapted for suspension growth and weaned from serum. Given the wide range of results reported across the various insect cell lines with the baculovirus expression system, it is advisable that Tni-FNL be used, at least initially, to produced KRAS4b-FMe.
A dark protein that migrates to ~65 kDa should be obvious in the clarified lysate as well as the elution fractions (Figure 1A). The fusion protein should be one of the two most prominent stained bands in the lysate with the other being the co-expressed FNTA/B that comigrates at ~48 kDa.
Within the purification, the CEX step is critical for two reasons: 1) it serves to reduce the extent of proteolysis as the hypervariable region (HVR) is quite susceptible, and 2) it enriches for the fully processed protein as indicated in the notes for this step of the protocol. It is, however, the most complicated part of the protocol. This is because the processed protein tends to precipitate at lower salt concentrations, even fused to MBP. Fortunately, this is not an all-or-none phenomenon, and it also takes place somewhat slowly over time. The protocol takes advantage of this by dialyzing to 200 mM NaCl prior to the CEX step. At this concentration, the precipitation was not as significant as at 100 mM. Therefore, the protocol is designed to limit the length of time the protein is in a buffer of this salt concentration. The mixing of small aliquots of the CEX column load with equal volumes of zero-salt buffer immediately prior to column loading limits the exposure (in terms of time) to low salt conditions and thus limits precipitation. Figure 2A depicts the most typical result from the CEX step, with the most prominent being peak 3, which contains predominantly KRAS4b-FMe. Figure 2B depicts elution profiles that have been observed to give a sense of the variability of the procedure's outcome. Because these can sometimes be misleading, it is prudent to create pools of all peaks and store these at -80 °C until the peak of interest has been fully purified and passed quality tests.
As noted in the protocol, the use of HiPrep SP Sepharose High Performance columns seems to be critical in achieving the separation observed in Figure 2A. While it is not yet clear why peak three frequently harbors farnesylated-only KRAS4b in addition to the desired farnesylated and carboxymethylated KRAS4b, the poor resolution others have reported with alternative CEX resins (personal communication) suggests this phenomenon is not solely a result of ionic interactions.
Typical yields ranged from 1–6 mg/L, with 3–5 mg/L achieved frequently (>90%, n > 50). Intact mass analysis using ESI-MS confirmed the precise molecular mass of the proteins and thereby the relative proportion of farnesylation and/or carboxymethylation (Figure 3). While typical final lots contained some detectable KRAS4b-FARN, this proportion was less than 15% in terms of peak height from this analysis. Figure 3A shows representative data for KRAS4b that is not prenylated expressed in E. coli, Figure 3B shows KRAS4b-FMe eluted in peaks 3 and 5 from CEX, and Figure 3C shows KRAS4b-Farn eluted in peak 2 from CEX.
The mass of the KRAS4b bound to GDP was also determined for these samples using native mass analysis (Figure 3D). Exchanging the samples into ammonium acetate ensured a "softer" ionization and the native complex stayed intact, providing confirmation of the nature of the nucleotide bound to KRAS4b.
To validate that farnesylation and carboxymethylation are required for KRAS4b-FMe to bind to membranes, we measured the interaction of KRAS4b-FMe to liposomes via SPR. As shown in Figure 4, KRAS4b-FMe bound to the liposomes while unprocessed KRAS4b did not, thereby demonstrating that processed KRAS4b-FMe is required for interaction with membranes.
Figure 1: SDS-PAGE gels of the purification process. (A) IMAC capture from lysate. FNTA/B are the dark bands migrating at ~48 kDa and the His6-MBP-tev-KRAS4b is the dark band migrating at ~67 kDa. M = protein molecular weight ladder; T = total protein; L = clarified lysate/column load; F = column flow through. Fractions are eluted with an increasing imidazole concentration gradient. (B) CEX fractions labelled 1–5 correspond to the peak fractions from the elution peaks shown in the chromatogram of Figure 2. (C) TEV digestion and second IMAC. C = pool from CEX step pre-TEV cleavage; L = load sample post-TEV cleavage. The species of interest are labeled. (D) One and five micrograms of final KRAS4b-FMe protein. The gels depicted are representative results from multiple productions. Please click here to view a larger version of this figure.
Figure 2: CEX chromatography elution profile. (A) The typical CEX elution profile has four to five major peaks. Aside from peak 1, which typically is a proteolyzed form of unprocessed KRAS4b lacking the four C-terminal amino acids, the four peaks numbered 2 through 5 in the panel result from variability in the processing of the N- and C-termini of the protein, with progressively more positively charged molecules eluting later in the gradient (see step 1.15). (B) Additional examples of CEX elution profiles. Please click here to view a larger version of this figure.
Figure 3: Intact and native mass spectrometry analysis of purified KRAS4b proteins. Intact mass spectrum and deconvoluted peak analysis results for (A) unprocessed KRAS4b 2-185, predicted MW = 21,064; (B) KRAS4b 2-185-FMe, peaks 3 and 5 from CEX, predicted MW = 21,281; (C) KRAS4b 2-185-Farn, peak 2 from CEX, predicted MW = 21,267. (D) Native mass deconvolved peak analysis for E. coli expressed KRAS4b 2-185 (i), KRAS-FMe 2-185 (ii), and KRAS-Farn 2-185 (iii), all in the GDP-nucleotide bound state. Please click here to view a larger version of this figure.
Figure 4: KRAS4b-FMe binding to liposomes via SPR. Size distribution of 70:30 POPC:POPS liposomes obtained by DLS. (A) DLS data show an average diameter of ~200 nm for the liposomes with an 18% polydispersity. (B) SPR binding sensorgrams of 60–0.6 μM KRAS4b-FMe to 70:30 liposomes captured onto a sensor L1 chip. (C) Fit of the steady state binding isotherms derived from the SPR data provided an apparent KD of 1 μM of KRAS4b-FMe binding to liposomes. The binding response is normalized by dividing by the surface capture level of the liposomes. (D) SPR binding kinetics of 60–0.6 μM KRAS4b-2-185 to 70:30 liposomes captured onto a sensor L1 chip. Please click here to view a larger version of this figure.
As noted in the Representative Results section, the most critical step during the purification is the handling of the sample during the time it is in lower salt. Limiting the time that the sample is exposed to less than 200 mM NaCl will help reduce precipitation and increase sample yield. Interpretation of the results of the CEX can be difficult if the profile does not match the expectations (see Figure 2). Until the protocol has become routine, it is advised that the CEX elution fractions that are not taken forward be stored at -80 °C until the intact mass analysis has been completed to ensure that the proper material was taken forward. Outside of the parameters noted above for the CEX step, the protocol is relatively easy to modify at the lysis and IMAC steps. It is also worth noting that there is no size exclusion chromatography (SEX) separation step in the protocol. This is omitted due to losses we have observed during early method development (unpublished results). It is noteworthy that these losses are not observed when the protein is in complex with nanodiscs, suggesting the loss in the absence of lipids is due to hydrophobic interaction between the protein and the resin.
This method represents a large increase in both the quantity (>10x higher) and quality (in comparison to bona fide processed KRAS4b expressed in human cells) that has been reported in the literature14,18,19. The yield of 3–5 mg/L has enabled structural biology efforts that require high protein requirements16,20. Additional posttranslational modifications for other members of the RAS family as well as additional posttranslational modification in general are currently being investigated.
For intact mass analysis of KRAS4b, a concentration of 0.1 mg/mL works well. Lower concentrations can be used due to the ability of the relaxed protein configuration to accept charges. However, in native mass analysis, where the protein is in its native folded conformation, there are lower mass-to-charge ratios and higher concentrations are required. Thus, using lower concentrations of protein results in a decrease of the signal and produces less reliable results. The advantage of native mass spectrometry is that the buffer is compatible with retaining the complex of nucleotide bound to KRAS4b. Therefore, it is possible to confirm the nucleotide-bound forms of the proteins (Figure 3D). As with any mass spectrometry analysis, neutral losses (such as a methyl group) are observed (see minor species with a loss of 18 in intact mass analysis, Figure 3A–C). In native mass spectrometry analysis, protein adducts with Na+ or K+, present after extensive buffer exchange, can be observed. This is evident in the minor peaks of +23 in Figure 3D, panels i-iii).
Our SPR data (Figure 4) show that the fully processed form of KRAS4b is required for recapitulating KRAS4b-membrane interaction in vitro. A major advantage of using the L1 chip to capture the liposomes in our SPR experiments is that the L1 chip surface is dextran coated and modified with lipophilic groups21, thus allowing for direct capture of the liposomes without any further modification. SPR is a powerful technique to study ligand-ligand interactions providing information on stoichiometry and binding affinity. Sensorgrams that work properly should have an association phase that reaches a steady state. This maximal binding response (Rmax) provides an estimate of the stoichiometry for the interaction. The dissociation rate should follow a single exponential decay, assuming a 1:1 binding interaction22. However, proteins binding to a membrane surface usually occur with more complex stoichiometries23 and multiple affinities that result in sensorgrams with more complex kinetics. We have not managed to fit the kinetics to a multisite binding model. However, the equilibrium binding isotherms can be fit using commercial evaluation software to provide an apparent equilibrium binding affinity (KD). Regardless, our SPR data clearly differentiates between how unprocessed KRAS4b and KRAS4b-FMe bind to liposomes. Thus, SPR still provides a useful tool in deciphering protein-lipid interactions.
Collectively, using SPR we demonstrate that fully processed KRAS4b-FMe is required for membrane binding. Production of the fully farnesylated and carboxymethylated form of KRAS4b using this approach provides the quantity and quality of material necessary for structural biology20, biophysical characterization of membrane interactions23, and screening studies against the KRAS4b-FMe:RAF complex in the presence of lipid bilayers.
The authors have nothing to disclose.
We acknowledge cloning and expression support from Carissa Grose, Jen Melhalko, and Matt Drew in the Protein Expression Laboratory, Frederick National Laboratory for Cancer Research. This project has been funded in whole or in part with Federal funds from the National Cancer Institute, National Institutes of Health, under Contract No. HHSN261200800001E. The content of this publication does not necessarily reflect the views or policies of the Department of Health and Human Services, nor does mention of trade names, commercial products, or organizations imply endorsement by the U.S. Government
1.8 mL Safe-Lock Tubes, Natural | Eppendorf | 22363204 | |
11 mm Cl SS Interlocked Insert Autosampler Vials | Thermo Scientific | 30211SS-1232 | |
1-palmitoyl-2-oleoyl-glycero-3-phosphocholine (POPC) | AVANTI POLAR LIPIDS | 850457 | purchase as liquid stocks in chloroform |
1-palmitoyl-2-oleoyl-glycero-3-phospho-L-serine (POPS) | AVANTI POLAR LIPIDS | 840034 | purchase as liquid stocks in chloroform |
5427R Centrifuge | Eppendorf | ||
Acetonitrile, HPLC Grade | Fisher Chemical | A998-1 1L | |
Ammonium Acetate | Sigma-Aldrich | 09689-250g | |
Argon gas | Airgas | ARUP | |
Assay Plate 384 | CORNING | 3544 | |
Biacore T200 Instrument | GE Healthcare | ||
Blue Snap-It Seals, T/S | Thermo Scientific | C4011-54B | |
Branson Ultrasonic Bath | Thermo Fisher | 15-336-1000 | |
Cation Exchange Chromatography (CEX) column | GE Healthcare Life Sciences | 29018183 | HiPrep SP Sepharose High Performance |
CHAPS | Sigma | C3023 | |
Dyna Pro Plate Reader | Wyatt Technologies | ||
Exactive Plus EMR Mass Spectrometer | Thermo Scientific | ||
Formic Acid | Sigma-Aldrich | F0507-500Ml | Use Reagent Grade or better |
Gilson vials 7×14 mm Tubes | GE Healthcare | BR-1002-12 | |
Glass screw thread vials with PTFE foam liners | Scientific Specialities | B69302 | |
High speed/benchtop centrifuge | Thermo Fischer Scientific | 05-112-114D | capable of up to 4,000 xg |
His6-Tobacco Etch Virus (TEV) protease | Addgene | 92414 | Purified as per Raran-Kurussi et al. (2017) Removal of Affinity Tags with TEV Protease. In: Burgess-Brown N. (eds) Heterologous Gene Expression in E.coli. Methods in Molecular Biology, vol 1586. Humana Press, New York, NY |
Immobilized Metal Affinity Chromatography (IMAC) column | GE Healthcare Life Sciences | 28-9365-51 | HisPrep FF 16/10 |
In-House Water Supply, Arium Advance | Sartorius Stedim | Resistivity of 18 MΩ0-cm | |
Lipid extruder set with holder | AVANTI POLAR LIPIDS | 610023 | |
Liquid nitrogen | Airgas | NI-DEWAR | |
M110-EH microfluidizer | 微小流体力学 | ||
MabPac RP UHPLC Column, 4 um, 3.0 x 50 mm | Thermo Scientific | 088645 | |
MabPac SEC-1 Column, 5 um, 300 Å, 2.1 x 150 mm | Thermo Scientific | 088790 | |
MagTran software | Thermo Scientific | ||
Methanol, HPLC Grade | VWR Chemicals | BDH20864.400 | |
NGC Chromatography System | BioRad | 78880002 | NGC QuestTM 100 Chromatography system |
Protease Inhibitor Cocktail without EDTA or other chelators | Millipore Sigma | P8849 | |
Rubber Caps type 3 | GE Healthcare | BR-1005-02 | |
Series S Sensor Chip L1 | GE Healthcare | 29104993 | |
Spectrophotometer | Thermo Fischer Scientific | 13-400-519 | Absorbace at 280nm |
Ultra-15 Centrifugal Filter Units, 10K NMWL | Millipore Sigma | UFC901008 | PES membrane |
Ultracel 10K MWCO Ultra 0.5 mL Centrifuge Filters | Amicon | UFC501024 | |
Ultracentrifuge | Beckman Coulter | Optima – L80K | capable of 100,000 xg |
Vanquish UHPLC (Pump, Column Hearter, and LC System) | Thermo Scientific | ||
Vortex Genie 2 | Fisher | 12-812 | |
Water, HPLC Grade | Sigma-Aldrich | 270733-1L | May use in-house water source (see below) |
Whatman GD/XP PES 0.45 mm syringe filter | GE Healthcare – Whatman | 6994-2504 | |
Xcalibur QualBrowser | Thermo Scientific | proteomics software |