LXH254, a potent and selective ARAF-sparing inhibitor of BRAF and CRAF for the
treatment of MAPK-driven tumors
Kelli-Ann Monaco2, Scott Delach1, Jing Yuan1, Yuji Mishina1, Paul Fordjour1, Emma
Labrot1, Daniel McKay5, Ribo Guo1 , Stacy Rivera1 , Hui Qin Wang1, Jinsheng Liang1,
Karen Bui1, John Green1, Peter Aspesi1, Jessi Ambrose1, Penny Mapa1, Lesley Griner1,
Mariela Jaskelioff3, John Fuller4, Kenneth Crawford6, Gwynn Pardee4, Stephania
Widger4, Peter S. Hammerman1, Jeffrey A. Engelman1, Darrin D. Stuart7, Vesselina
Cooke1, Giordano Caponigro1
1. Novartis Institutes for Biomedical Research, 250 Massachusetts Ave.
Cambridge, MA, 02139 United States
2. Bristol Myers-Squibb, 100 Binney St, Cambridge, MA 02142, United States
3. Skyhawk Therapeutics, 35 Gatehouse Dr. Waltham, MA, 02451 United States
4. Novartis Institutes for Biomedical Research, 5300 Chiron Way, Emeryville, CA,
94608 United States
5. Ventus Therapeutics, 7150 Frederick-Banting, Montreal, Quebec H9S 2A1
Canada
6. AbSci 101 East 6th St. #350 Vancouver WA, 98660, United States
7. Scorpion Therapeutics 888 Boylston St. Suite 1111 Boston MA, 02199, United
States
Running Title: LXH254 a potent and selective BRAF and CRAF inhibitor
Corresponding author: Giordano Caponigro, Novartis Institutes for Biomedical Research, 250 Massachusetts Avenue, Cambridge MA 02139. Phone 617-871-7395, Fax: 671-871-4213; Email: [email protected]
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Translational Relevance
The RAS/RAF/MEK/ERK pathway is activated in greater than 30% of human cancers
primarily via mutations in KRAS, NRAS and BRAF. The development of highly selective
and genetic context-specific RAF inhibitors has led to spectacular improvements in
patients with BRAFV600-mutant disease. Unfortunately, the BRAF V600E selectivity of
these inhibitors prevents their utility in RAS-mutant tumors. Here, we describe an
unexpected paralog-selectivity for the type II RAF inhibitor LXH254 that is currently
undergoing clinical trials in RAS-driven tumors in combination with MEK and ERK
inhibitors. LXH254 is a potent inhibitor of both monomeric and dimeric BRAF and
CRAF, but a comparably poor inhibitor of ARAF. This paralog selectivity permits
robust inhibition of dimeric BRAF and CRAF simultaneous with potentially improved TI.
This tolerability profile has enabled vertical combinations with MEK and ERK inhibitors
for the treatment of RAS–driven tumors in clinic.
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Abstract
Purpose: Targeting RAF for anti-tumor therapy in RAS-mutant tumors holds promise.
Herein we describe in detail novel properties of the type II RAF inhibitor LXH254.
Experimental Design: LXH254 was profiled in biochemical, in vitro, and in vivo assays
including examining the activities of the drug in a large panel of cancer-derived cell
lines, and a comprehensive set of in vivo models. In addition, activity of LXH254 was
assessed in cells where different sets of RAF paralogs were ablated, or that expressed
kinase-impaired and dimer-deficient variants of ARAF.
Results: We describe an unexpected paralog selectivity of LXH254, which is able to
potently inhibit BRAF and CRAF, but has less activity against ARAF. LXH254 was
active in models harboring BRAF alterations, including atypical BRAF alterations co-
expressed with mutant K/NRAS, and NRAS mutants, but had only modest activity in
KRAS mutants. In RAS mutant lines loss of ARAF, but not BRAF or CRAF, sensitized
cells to LXH254. ARAF-mediated resistance to LXH254 required both kinase function
and dimerization. Higher concentrations of LXH254 were required to inhibit signaling in
RAS-mutant cells expressing only ARAF relative to BRAF or CRAF. Moreover,
specifically in cells expressing only ARAF, LXH254 caused paradoxical activation of
MAPK signaling in a manner similar to dabrafenib. Lastly, in vivo, LXH254 drove
complete regressions of isogenic variants of RAS mutant cells lacking ARAF
expression, while parental lines were only modestly sensitive.
Conclusions: LXH254 is a novel RAF-inhibitor able to inhibit dimerized BRAF and
CRAF as well as monomeric BRAF while largely sparing ARAF.
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Introduction
Activation of the RAS/RAF pathway due to oncogenic lesions occurs in more than a
third of human cancers, most commonly via mutations in KRAS, NRAS and BRAF (1,2).
Not surprisingly, significant effort has gone into developing inhibitors targeting different
nodes in this pathway most notably the RAF, MEK and ERK kinases and more recently
the KRAS G12C variant (3-7).
The requirement for RAS/RAF signaling in normal tissues limits the potential therapeutic
index (TI) of RAF/MEK/ERK inhibitors. However, studies in mice and humans indicate
that selective inhibition of RAF paralogs and/or oncogenic variants may enable the
development of inhibitors with favorable TIs. First, in adult mice, combined deletion of
BRAF and CRAF is tolerated, whereas combined removal of either MEK1/MEK2, or
ERK1/ERK2 is lethal (8). Second, RAF inhibitors selective for V600-genetic variants
have been developed, and tellingly these inhibitors have proven far more effective
clinically than have MEK inhibitors which inhibit equally both MEK1 and MEK2 (9-19).
The simplest interpretation of differing clinical results for these two inhibitor classes is
that mutant selectivity of the BRAF inhibitors confers a favorable TI enabling relatively
greater systemic drug exposure and correspondingly improved pathway suppression in
tumors. Thus, agents that selectively target specific RAF isoforms or genetic variants
should have improved TIs relative to agents that inhibit equally all family members of
any given node in the pathway.
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The mutant-selectivity of BRAFV600E/D/K inhibitors precludes their use in KRAS, NRAS
and atypical BRAF mutant tumors. Unfortunately, MEK inhibitors, which effectively
inhibit signaling by mutant RAS in pre-clinical models, have proven largely ineffective in
RAS-mutant tumors clinically (20). This failure likely results from two non-mutually
exclusive sources. First, RAS activates multiple downstream pathways. Thus, although
RAF/MEK/ERK is a major RAS effector pathway, in many tumors additional pathways
may be the major oncogenic driver, or provide redundancy should RAF signaling be
impaired (21). Second, the intricate feedback mechanisms that serve to control RAF
pathway output in normal tissues, while disabled in BRAFV600 mutant disease (22), are
largely intact in RAS-mutant tumors. Thus, RAS-mutant tumors contain evolutionarily
honed mechanisms that can buffer tumor cells against the effects of RAF-pathway
inhibitors (21,23). This feedback effect, coupled with the relatively low systemic
exposures afforded by the narrow TI, likely places severe constraints on potential single
agent activity of such inhibitors. Inhibitors that impair RAF-pathway signaling with at
least some degree of bias for the RAS-mutant context relative to the wild type setting
will be required to test the dependency of mutant RAS on RAF/MEK/ERK signaling in
clinic.
Herein we describe LXH254, a RAF inhibitor with potent activity against both BRAF and
CRAF but 30-50 fold lower activity against ARAF in cells. LXH254 was predominantly
active in tumor models harboring activating variants of BRAF and NRAS, but less so in
KRAS mutants, with the exception of KRAS mutants harboring co-incident mutations in
BRAF. Critically, ablation of ARAF expression combined with LXH254 to elicit profound
anti-proliferative in vitro and anti-tumor activity in vivo. Collectively these data suggest
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that LXH254 exemplifies a novel class of RAF inhibitors with selectivity for specific RAF
paralogs. Reduced inhibitory activity against ARAF may limit LXH254 single agent
activity to either tumors within specific genetic contexts such as BRAF mutant tumors, or
RAS-mutant tumors positive for biomarkers indicative of a lack of ARAF utilization.
However, partial pathway inhibition provided by LXH254 in many tumor cells due to
potent inhibition of BRAF and CRAF, coupled with improved tolerability in normal
tissues due to ARAF avoidance, may enable tolerable combinations with additional
agents targeting downstream effectors such as MEK, ERK, or CDK4/6.
Methods:
Cell culture
HCT 116 RAF single and double knockout lines were generated using parental and
BRAF-/- cells from Horizon Discovery (Cambridge, United Kingdom). All other cells lines
were obtained from the BROAD/Novartis Cell Line Encyclopedia collection (24) and
maintained in Dulbecco's Modified Eagle Medium (MIA PaCa-2, 293T, HEK-293),
McCoy’s 5A (HCT 116), Eagle's minimal essential medium (Calu-6, HeyA8, SK-MEL-2)
or RPMI (all other lines) supplemented with 10% fetal bovine serum (FBS, VWR Life
Sciences Seradigm #1500-500). Lines were confirmed mycoplasma-free by PCR and
cell line identity was confirmed by SNP genotyping. All cell lines were maintained at
37°C in a humidified atmosphere containing 5% carbon dioxide.
RAF in vitro enzyme assays
Biochemical inhibition of ARAF, BRAF and CRAF shown in Fig. 1A was performed as
described for RAF709 in (25). In brief, the catalytically inactive MEK1K97R variant was
used as a substrate for either full-length BRAF, full-length activated CRAF
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(Y340E/Y341E variant), or a full-length N-terminal GST-ARAF fusion. In all cases,
LXH254 was pre-incubated with CRAF/BRAF/ARAF for 30 minutes prior to substrate
addition/reaction initiation.
Biochemical activity of LXH254 in the extended panel of kinases shown in
supplementary table 1 was determined as described in (26).
Generation of knock-out cell lines
To generate RAF knockout lines, clustered regularly interspersed short palindromic
repeat (CRISPR) genome editing (27,28) was used for all lines except HCT 116. Guide
sequences for ARAF (CCTGCCCAACAAGCAACGCA), BRAF
(ATATCAGTGTCCCAACCAAT) and CRAF (TGTTGCAGTAAAGATCCTAA) were
synthesized using standard chemistry and cloned into in-house generated lentiviral
expression vectors. . Lentiviral vectors were packaged in 293T cells with TransIT-293
Transfection Reagent (Mirus #MIR2700) using 5.4 micrograms of plasmid per 10-cm
plate. Virus was harvested after 48 hours and passed through a 0.45 micron filter. Cell
lines stably expressing Cas9 were incubated with lentivirus and 8 µg/ml polybrene
(Millipore #TR-1003-G) for 24 hours, and subsequently cultured in media containing
puromycin. Following selection in puromycin reductions in target protein levels were
assessed via immunoblotting and single clones with complete loss of target protein
expression isolated from pools via serial dilutions. HCT 116 knock out lines were
generated in parental and BRAF-/- lines from Horizon Discovery by transfection with zinc
finger mRNAs against ARAF, BRAF and CRAF purchased from Sigma.
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Generation of cell lines expressing exogenous ARAF constructs
ARAFWT-FLAG, ARAFD447A-FLAG, ARAFK336M-FLAG and ARAFR362H-FLAG cDNA
constructs were synthesized and cloned into in-house generated lentiviral vectors and
expressed from either a constitutive (pXP1704) or doxycycline-inducible (pXP1509A)
EF1-alpha promoter by GeneArt (Thermo Fisher Scientific). Lentivirus was packaged,
harvested and used to infect cells as previously described. Cells were cultured in
media containing G418 MIA PaCa-2 until stable pools were generated. Protein
expression was confirmed by immunoblotting and mutations by MassArray (Agena
Biosciences).
Cell Proliferation Assays
Cells were seeded in 96-well plates (Corning #3903) and 24 hours later compound
dilution series (1:3 starting at 10M) were added to wells in duplicate or triplicate. All
compounds were synthesized at Novartis Pharma AG. Plates were incubated for 72 -
120 hours and then CellTiter-GloTM (CTG) Luminescent Cell Viability Assay (Promega
#G7573) was added to wells to assess ATP levels. All points were normalized to
DMSO control samples when determining IC50 values and calculations performed using
GraphPad PRISM 7.0.
High-throughput profiling of the cell line panel described in supplemental figure 1A was
performed as described in Barretina et al (24).
pMEK1/2 and pERK1/2 MSD Assays
For Meso Scale Discoveries (MSD) assays, cells were incubated with compound for 4
or 24 hrs at 37°C and subsequently lysed for 30 minutes at 4°C. Assays were
performed as described in the manufacturer’s protocol for Phospho/Total ERK1/2 (MSD
#K15107D-1), phospho-protein levels normalized to DMSO-treated parental samples
and fold change calculated based upon percentage phosphoprotein in each sample as
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described in the manufacturer’s protocol. Washout experiments described in Figure 1C
were performed as described in (25).
Protein Immunoblots
Cells were plated in 6-well dishes (Corning #3506) and treated with inhibitors for 4 to 72
hours. Cells were harvested in RIPA Lysis and Extraction Buffer (Thermo Fisher
Scientific # 89900) containing 1X Halt Protease Inhibitor Cocktail (Thermo Fisher
Scientific # 87785) and Halt Phosphatase Inhibitor Cocktail (Thermo Fisher Scientific #
78420). Lysates were used for western blot analysis with antibodies recognizing ARAF
(Cell Signaling #4432), BRAF (Sigma-Aldrich # HPA00132), CRAF (Cell Signaling
#12552), CRAF (BD Biosciences # 610151), FLAG (Cell Signaling #8146), phospho-
MEK1/2 (S217/S221) (Cell Signaling #9154), phospho-ERK1/2 (T202/Y204) (Cell
Signaling #4370) and GAPDH (Millipore #MAB374) diluted 1:1000 or with β-actin
antibody (Life Technologies #AM4302) diluted 1:5000.
Co-immunoprecipitations
For Immunoprecipitations shown in Fig. 1B, Cells were seeded in 15-cm dishes and
incubated with 1M of the indicated compounds for 1 hour. Cell lysates were prepared
in immunoprecipitation buffer (10 mM Tris pH7.4, 50 mM NaCl, 0.5% (v/v) NP-40, 1 mM
EDTA) supplemented with 1× protease and 1× phosphatase inhibitor cocktails. Cleared
lysates were normalized for protein concentration and incubated with BRAF (Sigma #
HPA001328), CRAF (Bethyl Labs (A301-519A) (HCT 116), Millipore # 04-739) or MEK
(Millipore # 07-641) antibodies as indicated overnight at 4°C. Protein A Ultra Link Resin
(Thermo Scientific) was then added to each sample, incubated for 2 hrs at 4°C, washed
with immunoprecipitation lysis buffer and eluted in SDS sample buffer. In all other
immunoprecipitations, cells were treated +/- compound for 2-24 hrs, cells lysed in Pierce
IP Lysis Buffer (Thermo Fisher #87787) containing 1X Protease (Thermo Fisher
Scientific # 87785) and Phosphatase Inhibitor (Thermo Fisher Scientific # 78420)
cocktails, and lysates clarified by centrifugation. For each sample, 1-2 milligrams of
lysate were incubated with antibodies to ARAF (Cell Signaling #4432), BRAF (Sigma-
Aldrich # HPA00132), or FLAG (Sigma-Aldrich # F7425) and Protein G Sepharose
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beads (GE Healthcare #17-0618-01) for 3 hrs at 4°C. Complexes were washed 3x with
IP Lysis Buffer and analyzed by immunoblotting.
Cell-based kinase assays
In-cell kinase selectivity profiling was performed by KiNativ™. Briefly, HCT 116 cells
were treated with LXH254 for 2 hours at 10 µM and then lysates were processed,
probe-labelled and analyzed by LC-MS/MS as previously described (29). For IP-kinase
assays, cells were cultured in compound for 4-24 hrs prior to protein
immunoprecipitation as described above. Immunoprecipitates were washed once with
IP Lysis buffer, twice with 1X Kinase buffer (Cell Signaling #9802) and protein-bound
beads incubated in 2X Kinase buffer with 250 micromolar ATP (Cell Signaling #9804)
and 0.5 micrograms MEK1 (Millipore #14-420) or MEK1-K97M (Proqinase #0785-0000-
1) for 30 minutes at 30°C. Beads were then washed 3X with IP-lysis buffer and
prepared for immunoblotting as described above.
In vivo studies
Mice and statement of welfare:
Outbred athymic (nu/nu) female mice (“HSD: Athymic Nude-nu”) (Charles River) and
SCID beige (Charles River) mice were allowed to acclimate in the Novartis NIBRI
animal facility with access to food and water ad libitum for minimum of 3 days prior to
manipulation. Animals were handled in accordance with Novartis ACUC regulations and
guidelines.
Cell culture and in vivo efficacy
All cell lines were shown to be free of Mycoplasma sp. and murine viruses in the
IMPACT VIII PCR assay panel (IDEXX RADIL, IDEXX Laboratories INC, Westbrook,
ME). In all cases cells were harvested at 80-95% confluence with 0.25% trypsin-EDTA
(Gibco #25200-056), washed with PBS, detached with 0.25% trypsin-EDTA (Gibco
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#25200-056) and neutralized with growth medium. Following centrifugation for 5 min at
1200 rpm, all cells except HEY-A8 cells (PBS) were re-suspended in either cold HBSS
(Gibco #14175-095) (HCT 116, A375) or cold HBSS and an equal volume of Matrigel™
Matrix (Corning #354234, all other cells). Cells were then injected in 100-200 l
volumes into either the right or left flanks of female nude mice with the exception of
MEL-JUSO cells, which were injected into SCID beige mice. Total cell numbers
injected/mouse were 2x106 (HCT 116, HEY-A8), 5x106 (MIA PaCa-2, HPAF-II, A375,
Hs944.T, SK-MEL-30), or 1x107 (MEL JUSO, Calu-6, PC-3). 5-7 mice were used for
each group.
3990HPAX, 2043HPAX, 1290HCOX, 2861HCOX, 1855HCOX, 2094HLUX, and
3486HMEX patient-derived tumor xenograft (PDX) tumors and the WM793 xenograft
were propagated by serial passage of tumor fragments in nude mice. Briefly, 3x3x3 mm
fragments of fresh tumor from a previous passage were implanted subcutaneously into
the mice. Efficacy was carried with n=6-12/group.
Percent change in body weight was calculated as (BWcurrent - BWinitial)/(BWinitial) x 100%.
Data was presented as mean percent body weight change from the day of treatment
initiation ± SEM. Tumor volume was determined as published previously (25). All data
were expressed as mean ± standard error of the mean (SEM). Change in tumor volume
were used for statistical analysis, and between group comparisons were carried out
using a one-way ANOVA. For all statistical evaluations, the level of significance was set
at p < 0.05. Significance compared to the vehicle control group is reported unless
otherwise stated.
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Drug formulation
LXH254 was and dosed p.o. in MEPC4 vehicle (45% Cremophor RH40 + 27% PEG400
+ 18% Corn Oil Glycerides (Maisine CC) + 10% ethanol) for all experiments except
PC3, where LXH254 was formulated in 90% PEG400 + 10% Tween80. MEPC4 stock was
diluted 5x (1:4 with DI Water) prior to dosing. Trametinib was dosed p.o. as a
suspension in 0.5% HPMC and 0.2% Tween80 in distilled water at pH8. Trametinib
was stirred overnight and protected from light at RT prior to dosing.
Xenograft qPCR
Tumors were homogenized and RNA was extracted using the Qiagen RNeasy Mini
Qiacube kit (Qiagen cat# 74116) per the manufacturer’s instructions. For RT-qPCR
reactions, 4ul/well of a 10ng/ul suspension of RNA loaded into 384-well plates along
with 16l of Master Mix (Qiagen cat#204645), containing primers for hDUSP6 (Life
Tech cat# Hs00737962) and hRPLPO (Life Tech cat#4326314E), and reverse
transcriptase. Reactions were run for 20 min at 50°C, 15 min at 95° C, followed by 45
cycles of 45 s at 94°C and 45 s at 60°C.
Gene expression analysis
ARAF RNASeq expression, BRAF, NRAS, KRAS and HRAS mutation data from all
TCGA PanCancer Atlas studies were downloaded from the cBioPortal data viewer
(https://www.cbioportal.org/). RNASeq RSEM values were converted to TPM and log2
transformed. Only samples with ARAF expression were considered. Differential
expression normalization was performed using Limma/VOOM for differential expression
in R (30).
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Structural Modeling
The in-house X-ray structure (PDB entry:6N0P) of LXH254 bound to BRAF was used in
conjunction with an X-ray structure of CRAF (PDB entry: 3OMV) to build a homology
model of ARAF with LXH254 bound in the molecular operating environment (MOE) (31).
This model was extensively refined with explicated solvent molecular dynamics
simulations at 300K, 1atm, AM1BCC/ELF charges, TIP3P water, ff14SB (32) force field
with the PARM@FROSST (33) extension within the AMBER (34) suite of simulation
tools. 10ns simulations for each system were run and time average structures were
extracted.
Results:
LXH254 inhibits both monomeric and dimeric RAF and promotes RAF dimer
formation.
LXH254 is a potent inhibitor of the B-and CRAF kinases, inhibiting their catalytic activity
at picomolar (pM) concentrations in biochemical assays (35). Consistent with LXH254
being a type II inhibitor, LXH254-bound BRAF adopts an inactive DFG out, C-helix in,
conformation, and treatment of cells with LXH254 promotes BRAF/CRAF heterodimer
formation most likely due to antagonism of the auto-inhibited state of the kinase which
enables RAS-mediated dimer formation (35,36). We further extended characterization
of RAF inhibition by LXH254 in several ways. First, we measured the biochemical
inhibition of ARAF, BRAF and CRAF by LXH254 (Fig. 1A). Consistent with previously
reported values (35), LHX254 inhibited BRAF and CRAF with IC50 values of 0.2 nM and
0.07 nM, respectively. Inhibition of ARAF, while robust, occurred with a higher IC50
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value of 6.4 nM. Second, the ability of LXH254 to promote B/CRAF heterodimer
formation of endogenous proteins was examined in three RAS-mutant cell lines via IP-
western analysis (Fig. 1B). In all instances both LXH254, and the type II RAF inhibitor
LY3009120 (37), promoted heterodimer formation as judged by analysis of pull-downs
using either BRAF or CRAF-directed antibodies. MEK1 and MEK2 were not detected in
either BRAF or CRAF immuno-precipitates, however, both BRAF and CRAF were
detected upon compound treatment following immunoprecipitation with MEK1/2 directed
antibodies. Lastly, we compared the relative ability of LXH254 to inhibit monomeric
BRAFV600E in A-375 cells compared to RAS-induced wild-type RAF dimers in HCT 116
KRASG13D cells. For this assessment we used an approach described by Yao et al (22),
in which cells are pre-incubated and subsequently washed following treatment with 1M
encorafenib such that inhibition likely reflects LXH254 binding to the second protomer in
RAF dimers unoccupied by encorafenib. In contrast to the ~ 600-fold greater inhibition
of monomeric BRAFV600 vs wt dimeric RAF by dabrafenib that we reported previously
LXH254 displayed similar inhibition of monomeric BRAFV600 and wt dimeric RAF (IC50
for p-ERK levels of 59 nM and 78 nM in A-375 and HCT 116 cells, respectively, Fig.
1C).
An issue that has potentially limited the efficacy of type II RAF inhibitors in clinic is a
lack of selectivity for RAF versus other kinases (37-39). LXH254 displayed a high
degree of selectivity for BRAF and RAF-1 (CRAF) relative to other kinases as judged by
KINOMEscan (35). We further interrogated the selectivity of LXH254 in two orthogonal
screening formats. First, in biochemical assays using purified proteins LXH254 had IC50
values >10 M against 60/62 non-RAF kinases, with only MAPK14 (p38) and ABL1
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having IC50 values below 10 M (2.1 M, and 4.1 M, respectively, Sup. Table 1).
Second, we profiled LXH254 using the KiNativ platform wherein kinase selectivity is
determined in cells via competition with an ATP-competitive covalent probe followed by
mass spectrometry (29). In HCT 116 cells incubated for 2 hours with 10 M LXH254,
the only kinases where probe binding was inhibited >80% were BRAF (90%) and CRAF
(88%) (Fig. 1D and Sup. Table 2). Beyond BRAF and CRAF, only two, ARAF (58%)
and p38 (66%), of the additional 184 kinases, detected in this cell line demonstrated
>50% inhibition of probe binding. High selectivity for BRAF and CRAF, and to a lesser
extent p38in HCT 116 cells was consistent with results from both the biochemical and
KINOMEscan profiling (35). Moreover, weaker binding of LXH254 to p38 in both
binding assay formats corresponds to relatively poor biochemical inhibition of this
kinase (IC50 = 2.1 M), relative to BRAF (0.0002 M) and CRAF (0.00007 M).
Collectively these data indicate that within the kinome, LXH254 is highly selective for
RAF kinases.
In vitro and in vivo activity of LXH254
We next profiled 291 cell lines for sensitivity to LXH254 in a high-throughput format
(Sup. Table 3). Using IC50 cut-offs ranging from 1-2.5 M, concentrations that
approximate Cavg concentrations in clinic (data not shown), we found that cell lines
harboring BRAFV600E/K as well as activating mutations in NRAS were enriched in the
subset of sensitive cells. KRAS mutants were only weakly enriched, with cells lacking
RAS/RAF mutations being predominantly insensitive (22/146 with an IC50 < 2.0 M,
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Sup. Fig 1A, Sup. Table 3). In the case of WT cell lines, in an insensitive model tested,
LXH254 effectively suppressed RAF signaling suggesting that some insensitivity may
result from a lack of pathway dependence (Sup. Fig 3F). To identify potential marker of
either resistance or sensitivity in MAPK-altered models we performed differential-gene
expression analysis, in both the entire set of cell lines as well as the KRAS, NRAS and
BRAF mutant subsets. Unfortunately, this analysis did not reveal any predictors of
sensitivity beyond melanoma lineage makers in the BRAF subset, which was likely a
consequence of the high fraction of BRAFV600E models derived from this lineage (Sup.
Table 9). Cell line sensitivities to LXH254 were very similar to those previously obtained
for the type II RAF inhibitor RAF709 (Sup. Fig 1B (25)).
We subsequently examined the anti-tumor effects of LXH254 in a set of BRAF, NRAS
and KRAS mutant xenograft models as well as a RAS/RAF wildtype model. In general,
and concordant with cell line sensitivity in vitro, models harboring BRAF mutations
either alone (e.g. BRAFV600E) or co-incident with either activated NRAS (SK-MEL-30) or
KRAS (HEYA8, 1855HCOX) either regressed or demonstrated prolonged stasis
following treatment with LXH254 (Fig. 2 A-C, Sup. Table 7). In contrast to RAF-mutant
models, and similar to in vitro cell line data, the majority of KRAS mutant models, as
well as the RAS/RAF WT model displayed at best modest responses to LXH254
although there were notable outliers (e.g. Calu-6 cells, Fig. 2D, Sup. Table 7). When
examined in a subset of models, pathway inhibition was consistent with anti-tumor
results (Fig. 2 A-D).
Loss of ARAF expression sensitizes RAS-mutant cells to LXH254.
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Based on the dual observations that (1) LXH254 had reduced binding of ARAF relative
to BRAF and CRAF in the Kinativ assay and, (2) that RAS mutants, particularly KRAS,
are largely insensitive to LXH254, we hypothesized that that insensitivity might stem
from poor ARAF inhibition by LXH254. To test this hypothesis we used CRISPR-Cas9
or zinc finger nucleases to functionally delete ARAF, BRAF, or CRAF from a series of
RAS mutant cell lines including two NRAS mutant melanoma cell lines (MEL-JUSO and
SK-MEL-30), and three KRAS mutant cell lines (COR-L23, MIA PaCa-2 and HCT 116,
Sup. Fig. 2). Loss of ARAF expression resulted in 3–11 fold increases in sensitivity to
LXH254 relative to parental cell lines in all models tested (Fig. 3, Sup. Table 3). Loss of
BRAF did not alter sensitivity to LXH254 in the wild-type BRAF cell lines; however, loss
of BRAF expression in NRAS mutant SK-MEL-30 cells which also harbor a kinase
impaired class III variant (BRAFD287H,(40)) greatly reduced sensitivity to LXH254 (14-
fold). Loss of CRAF either did not change (MIA PaCa-2, COR-L23), or only slightly
altered (HCT 116) sensitivity to LXH254 in KRAS mutant models, however CRAF loss in
both NRAS mutant cell lines reduced sensitivity to LXH254 3-9 fold. In contrast, loss of
any of the three RAF paralogs did not consistently alter sensitivity to either the MEK1/2
inhibitor trametinib or ERK1/2 inhibitor ulixertinib (Sup. Tables 4 & 8).
We then examined the effect of loss of the various RAF proteins on pathway
suppression by LXH254. Cells were treated with increasing concentrations of LXH254
for 4 hrs, and in some cases 24, 48 and 72 hrs, and p-ERK levels determined using the
Meso Scale Discovery platform (MSD), and/or western analysis using antibodies (Abs)
that detect phosphorylated ERK1/2. Loss of ARAF improved pathway suppression by
LXH254 relative to parental cells and cells lacking either BRAF or CRAF (Table 1, Sup.
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Fig. 3A). Similarly, reduced pathway inhibition occurred in cases where loss of BRAF
(SK-MEL-30) or CRAF (SK-MEL-30, MEL-JUSO) expression decreased sensitivity to
LXH254 (Table 1). Moreover, in both HCT 116 cells and MIA PaCa-2 cells where p-
ERK levels were monitored beyond 4 hours, the differential in pERK reduction by
LXH254 between cells lacking vs expressing ARAF increased further (Table 1, Sup. Fig.
3A). Thus, increased sensitivity to LXH254 in cells lacking ARAF corresponds to
improved pathway suppression. Reduced, albeit transient pathway inhibition by LXH254
in cells lacking CRAF suggests that in the absence of CRAF, ARAF might play a larger
role in signaling. To test this we immuno-precipitated ARAF and BRAF from parental
and CRAF-deficient MIA PaCa-2 cells following 2 and 24 hours of incubation with 1 M
LXH254. In parental cells increasing amounts of BRAF and CRAF co-purified with
immuno-precipitated ARAF over time after LXH254 treatment (Sup. Fig. 3B). Similarly,
increasing amounts of both ARAF, and more prominently CRAF, co-purified with BRAF.
In cells lacking CRAF expression, similar patterns of increasing levels of co-purified
BRAF following ARAF pull-down, and ARAF following BRAF pull-down were observed.
However, in the absence of CRAF, greater amounts of BRAF/ARAF heterodimers were
present at all times despite similar efficiencies of immuno-precipitation. Moreover,
increased levels of BRAF/ARAF heterodimers in CRAF-deficient cells following the two-
hour LXH254 treatment corresponded to failure of LXH254 to inhibit signaling. These
data are consistent with a model where LXH254 has reduced ability to suppress MAPK
signaling driven by ARAF and further that the contribution of ARAF to MAPK signaling
increases in the absence of CRAF expression.
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ARAF-mediated resistance to LXH254 is dependent on both ARAF kinase activity,
and ability to form dimers.
To determine if ARAF-mediated LXH254 insensitivity depends on ARAF catalytic
function or the ability to form RAF-dimers, we re-introduced either N-terminally FLAG-
tagged wild type ARAF, kinase dead ARAF (K336M or D447A), or dimer-deficient ARAF
(R362H) variants into cells lacking endogenous ARAF. In all models examined, re-
introduction of wild type ARAF reverted sensitivity to LXH254 to levels seen in parental
cells (Figs. 4A & B). In contrast, expression of either kinase dead variants K336M (Fig.
4A&C) and D447A (Fig. 4B&C), or dimer-deficient variant ARAFR362H (Fig. 4B), did not
revert sensitivity to LXH254. Concordant with sensitivity to LXH254, over-expression of
wild type ARAF, but neither kinase dead nor dimer-deficient ARAF, reduced pathway
suppression by LXH254 (Sup. Table 5). Failure of kinase dead and dimer deficient
variants to complement loss of endogenous ARAF did not result from poor transgene
expression, as protein levels of all introduced ARAF variants exceeded the expression
of endogenous ARAF, although it should be noted that kinase dead variants were
consistently expressed at lower levels than either wild type or dimer-deficient versions
of ARAF (Sup. Fig. 2).
To ensure that kinase-dead and dimer-deficient RAF variants lacked kinase activity and
failed to form heterodimers, respectively, we performed IP-kinase assays using material
isolated from RAS mutant cell lines expressing the various FLAG-tagged ARAF
variants. In these experiments, the MEL-JUSO, HCT 116 and MIA PaCa-2, but not
COR-L23, cell lines lacked endogenous ARAF expression due to CRISPR/CAS9
editing. ARAF was immuno-precipitated using Abs directed against the FLAG epitope
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from either untreated cells, or cells treated for 24 hours with LXH254 and RAF kinase
activity assessed using recombinant MEK1 as a substrate for the immuno-precipitated
material and monitoring production of phosphorylated MEK1 (p-MEK1) using a
phospho-MEK specific antibody. IP-kinase assays using precipitates from all ARAFwt
expressing cells produced p-MEK1 (Fig 5A-D). In MEL-JUSO and COR-L23 cells IP-
kinase activity was largely dependent on pre-treatment of cells with LXH254 (Fig. 5A &
C), although examination of IP-kinase from lysates from wild type cells suggest that
stimulation of ARAF kinase activity by LXH254 pre-treatment occurred only in the
context of ARAF overexpression (Sup. Fig 3C). Phosphorylated MEK1 was unlikely to
result from auto-phosphorylation by recombinant MEK1, as IP-kinase assays carried out
in HEK293 cells using recombinant catalytically inert MEK1K97M also generated
phosphorylated MEK1 (Sup. Fig. 3D). Cells expressing ARAFK336M or ARAFD447A either
produced significantly less (COR-L23) or failed to generate detectable p-MEK1 despite
similar efficiencies of ARAF-immunoprecipitation. In all cell lines expressing exogenous
wild type and kinase-dead ARAF variants, treatment with LXH254 promoted
heterodimer formation between ARAF and both BRAF and CRAF, with the exception of
MEL-JUSO cells where only ARAF-CRAF heterodimers were detected. In contrast,
immuno-precipitates from HCT 116 and MEL-JUSO cells expressing ARAFR362H were
largely devoid of both B-and-CRAF and generated very little p-MEK1. These data
indicate that kinase dead and dimer-impaired variants lack catalytic activity and
heterodimer forming capability, respectively. Failure of these variants to restore
LXH254 insensitivity indicates that both catalytic function and the ability to dimerize is
required for ARAF-mediated resistance to LXH254.
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Cells expressing only ARAF are less sensitive to LXH254 than cells expressing
only BRAF or CRAF
To investigate further differential inhibition of RAF paralogs by LXH254, we generated
isogenic cell lines using CRISPR CAS-9 that expressed only one of the three RAF
genes. Clonal isolates expressing only ARAF (BRAF/CRAF or CRAF
(ARAF/BRAFwere generated in HCT 116, MIA PaCa-2 and MEL-JUSO cells.
BRAF-only cells were more difficult to generate, and while MIA PaCa-2
(ARAF/CRAF cells were generated, BRAF only HCT 116 cells maintained a low
level of CRAF (ARAF/CRAF-low) and we were unable to generate BRAF-only MEL-
JUSO cells (Sup. Fig. 2). Consistent with results in cells lacking ARAF (Fig. 4), BRAF-
only and CRAF-only cells were 5-10 fold more sensitive to LXH254 in three-day growth
assays than parental cells (Fig 6A & Sup. Table 6). In contrast, ARAF-only cells were
less (HCT 116, MEL-JUSO) or similarly sensitive (MIA PaCa-2) to LXH254 than
parental cells (Fig. 6A). After four hours of treatment, LXH254 effectively inhibited
signaling in BRAF-and-CRAF-only cells, with IC50 values below 100 nM (Fig. 6B). In
contrast, in ARAF-only cells, signal inhibition required higher drug concentrations with
IC50 values measured at >1500 nM in all cell lines (Fig. 6B, Sup. Table 6). Moreover,
treatment of all ARAF-only cell lines with LXH254 resulted in modestly increased p-ERK
(25 – 50%) at LXH254 concentrations ranging from 10 to 370 nM in a manner
reminiscent of paradoxical activation described for type 1/1.5 RAF inhibitors (41-43). As
described previously for cells lacking ARAF (Fig. 3 and Table 1) pathway re-activation
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over time after LXH254 treatment in BRAF-and-CRAF-only cells was reduced relative to
parental cells (Sup. Fig. 3E).
To compare the effects of LXH254 on signaling to that of a type 1.5 inhibitor we treated
parental and individual RAF paralog-expressing MIA PaCa-2 cells for four hours with
the type 1.5 RAF inhibitor dabrafenib and measured the effects on p-ERK levels by
MSD. Consistent with previous results reported in RAS-mutant models, treatment of
MIA PaCa-2 cells with dabrafenib resulted in increased p-ERK levels to a peak ~ 4-fold
greater than baseline at concentrations up to 3.0 M (Fig. 6C). At concentrations
exceeding 3.0 M p-ERK levels declined, returning to original baseline levels at
dabrafenib concentrations of 10 M. Dabrafenib exerted distinctly different effects on p-
ERK levels in cells expressing only one of each of the three RAF proteins. In CRAF-
only cells, treatment with dabrafenib resulted in a similar pattern of pathway activation to
parental MIA PaCa-2cells, although activation was subtly greater at all concentrations
up to ~ 600 nM. In cells expressing only BRAF or ARAF, increases in p-ERK were also
observed however, increases were modest (~ 50%) relative to what occurred in parental
and CRAF-only cells. These data are consistent with previous reports suggesting that
CRAF activation is the major driver of paradoxical activation (17,41,44). Comparing the
effects of signaling indicated that while both drugs similarly and modestly induce
paradoxical activation in ARAF-only expressing cells, LXH254, but not dabrafenib is
able to inhibit wild type BRAF and CRAF in cells (Fig. 6B & C)
RAS mutants lacking ARAF are more sensitive to LXH254 in vivo.
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We next determined the effect of ARAF ablation on sensitivity to MAPK inhibitors in
vivo. Tumors formed from parental and ARAF-deleted variants of the HCT 116, MIA
PaCa-2 and MEL-JUSO models were treated with vehicle, 0.3 mg/kg Q.D. trametinib, or
50 mg/kg B.I.D LXH254. Doses of trametinib and LXH254 were selected that matched
AUC values for the approved dose of trametinib (2mg Q.D.) or the recommended phase
2 dose (RP2D) of LXH254 (400mg B.I.D). ARAF deleted xenografts either grew with
similar kinetics (HCT 116 cells) or slightly slower (MIA PaCa-2, MEL-JUSO) than their
parental counterparts indicating that ARAF ablation has at most modest effects on the
fitness of these models. In all parental models, LXH254 and trametinib exerted similar
effects on tumor growth, resulting in a slow growth phenotype that was most
pronounced in MEL-JUSO cells (Fig. 7A-C). Treatment with LXH254 in the ARAF
knockouts led to complete regression of HCT 116 and MEL-JUSO and near-complete
regression of MIA PaCa-2 xenografts. Several tumors from each KRAS mutant model
regrew after prolonged treatment, including 3/6 from the HCT 116, and 5/6 of the MIA
PaCa-2 tumors (Sup. Fig. 4 A-C). Initial analysis of these variants by western analysis
suggests that at least two tumors (MIA PaCa-2, M2 and M5) became resistant due to
RAF-pathway re-activation, with reactivation in one case potentially attributable to
restoration of ARAF expression (M5). Lack of clear pathway re-activation in the other
six tumors suggest resistance occurred via a MAPK-bypass mechanism (Sup. Fig. 4D).
Strikingly, 2/3 of the regressed HCT 116 tumors, failed to regrow after cessation of drug
treatment consistent with complete eradication of the tumor (Sup. Fig. 4A). In contrast,
variants lacking ARAF expression had similar sensitivities to trametinib as parental MIA
PaCa-2 cells.
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These data indicate that RAS-driven activation of BRAF and CRAF is inhibited
sufficiently by LXH254 to eradicate tumors, and conversely that poor ARAF inhibition is
a critical contributor to the relative insensitivity of RAS-mutant models to LXH254.
Accordingly, we tested whether co-treatment of tumors with LXH254 and low doses of
trametinib, aimed at inhibiting residual ARAF-driven signaling, improved anti-tumor
effects in MIA-PaC-2 cells. Combining LXH254 with either 50% (0.3 mg/kg Q2D) or
10% (mg/kg QD) doses of trametinib-improved efficacy relative to both LXH254, and a
full dose of trametinib (0.3 mg/kg QD), although efficacy was inferior to that seen for
single agent LXH254 in cells lacking ARAF (Fig. 7D), and tumors regrew over time (data
not shown) . Thus, combining LXH254 with even small amounts of a MEK inhibitor can
result in significant anti-tumor effects.
Discussion
LXH254 is a type II RAF inhibitor with a high degree of selectivity for BRAF and CRAF,
that predominantly binds the inactive, DFG-out kinase configuration, and promotes the
formation of BRAF/CRAF heterodimers ((35) Fig 1, Sup. Tables 1 & 2). LXH254
treatment, also promoted MEK1/2 – B/CRAF interactions in IPs using MEK-directed
Abs, however, this interaction was not reciprocated in IPs using RAF-directed Abs. This
discrepancy may be an artifact due to the choice of RAF Abs used for the IPs.
Alternatively, this may reflect the existence of a substantial pool of dimerized RAF that
is not complexed with MEK1/2.
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Here we describe further an unexpected paralog selectivity of this molecule wherein it is
a relatively poor inhibitor of ARAF. Poor ARAF-inhibitory activity in cells was somewhat
unanticipated based on biochemical analysis that indicated single digit nM inhibition of
the ARAF kinase in cell free assays. However, as has been described for CRAF
inhibition by type 1.5 inhibitors, in vitro inhibition of ARAF by LXH254 did not translate to
robust inhibition in the cellular setting. Ablation of ARAF expression in 5/5 RAS mutant
cell lines resulted in more potent anti-proliferative effects and RAF/MEK/ERK signal
suppression by LXH254 (Fig. 3, Table 1).
The mechanistic basis for the failure of LXH254 to inhibit ARAF is unknown and insights
into a structural explanation is hampered by the lack of a crystal structure for ARAF.
However, as suggested here (Sup. Table 8) and elsewhere (37), failure to inhibit ARAF
may not be a property of all type II RAF inhibitors. Simulations of ARAF structure using
information available for BRAF and CRAF (see methods) suggest a possible
explanation for reduced activity of LXH254 against ARAF (Sup. Fig. 5B). The terminal
hydroxyl group of the alkane chain of LXH254 forms a hydrogen bond with the
backbone carbonyl of F595 in BRAF (and CRAF) in the DFG-out configuration of the
protein (35). Simulations of the ARAF structure place this carbonyl shifted to a position
more proximal to the hydroxyl group on LXH254, which would likely eliminate this
hydrogen bond, instead creating a steric clash. Interestingly RAF709, a similarly poor
inhibitor of ARAF (Sup. Table 8) also forms a hydrogen bond with the same carbonyl on
F595, albeit via a water intermediary, which is also predicted to be lost in ARAF. An
understanding of the basis for the decreased inhibitory activity of LXH254 against ARAF
requires further study.
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Roles for ARAF in promoting signal transduction in a scaffolding rather than catalytic
capacity have been previously described (45). However, we found that ARAF-
mediated insensitivity to LXH254 was dependent on ARAF having both kinase activity
and the ability to form dimers, strongly suggesting that failure of LXH254 to inhibit ARAF
catalytic activity while ensconced as an active member of RAF signaling complexes
underlies this phenotype. In RAS mutant tumors engineered to express only ARAF,
LXH254 paradoxically activated signaling to a similar degree, and with a similar bell-
shaped dose-response curve to the type 1.5-inhibitor dabrafenib (Fig. 6). In contrast, in
RAS-mutant cells expressing only B-or-CRAF LXH254 potently inhibited signaling
whereas dabrafenib caused pathway activation, most notably in cells expressing CRAF.
Collectively these data suggest a model where LXH254 potently inhibits dimeric BRAF
and CRAF, but paradoxically activates ARAF-containing dimers (Sup. Fig. 5A).
In the phase I dose escalation trial of LXH254 very few partial responses to single agent
LXH254 were observed (46). This trial was enriched for KRAS-mutant tumors (~ 30%)
and consistent with preclinical data presented herein, the majority of patients with
KRAS-mutant disease progressed on treatment, although a minority of these patients
displayed stabilization of disease. Based on findings here, LXH254 might have single
agent activity only in RAS mutant tumors with either low expression or utilization of
ARAF. However, no correlation was found between ARAF mRNA expression and
sensitivity to LXH254, either in the entire panel of cell lines profiled, or within specific
RAS/RAF-mutated subgroups in vitro (Sup. Fig. 1C). Moreover, analysis of RAS-
mutant tumors in TCGA did not reveal a clearly identifiable subset of RAS-mutant
tumors with intrinsically low-ARAF expression (Sup. Fig. 1D). Thus, the primary utility of
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LXH254 is likely to be in combination with additional agents targeting the MAPK
pathway.
Consistent with this hypothesis, we found that adding even low doses of trametinib to a
full dose of LXH254 improved anti-tumor activity relative to single agent effects in the
MIA PaCa-2 model (Fig.7D). The observation that adult mice tolerate simultaneous loss
of B-and-CRAF (8) suggests that poor ARAF inhibition may improve LXH254 tolerability
relative to e.g. MEK and ERK inhibitors, thereby facilitating the achievement of drug
exposures where both BRAF and CRAF are strongly inhibited. Such improved
tolerability might also facilitate combinations with additional MAPK inhibitors for the
treatment of RAS-mutant tumors resulting in improved pathway suppression and anti-
tumor effects. In support of this idea, LXH254-anchored MAPK combinations, such as
those described in Fig. 7, display a superior tolerability/efficacy relationship when
compared to single agent treatments in preclinical species (Manuscript in prep).
Moreover, combinations between LXH254 and the MEK inhibitor trametinib and ERK
inhibitor LTT462 are currently in dose expansion in patients with a variety of RAS/RAF-
pathway alterations.
Acknowledgements
We thank David Kodack, Qing Shen, Tina Yuan, Rita Das, Flavio Somanji, Huyen
Nguyen, Huaixiang Hao and Albot Liu for critical reading and comments in the
manuscript. We thank Jodi Meltzer, Qamrul Hassan, Yingyun Wang, and Malika Singh
for technical contributions to the generation of RAF-paralog knockout models, BRAF
and CRAF biochemical assays, and in vivo PC3 experiment.
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Table 1:
Cell Line Variant SK-MEL-30 MEL-JUSO HCT 116 COR-L23 Mia PaCa-2 Mia PaCa-2 (24 hrs)
Wild Type 90 77 12 889 687 >10000
ARAF 60 10 5 43 85 170
BRAF 650 94 18 1072 262 >10000
CRAF 300 531 357 1358 3627 >10000
pERK IC50 (nM)
Figure Legends
Figure1. Characterization of LXH254 in biochemical and cellular assays. (A) Shown
are the calculated IC50 values against purified ARAF, BRAF and CRAF in biochemical
assays and structure of LXH254. (B) Western analysis of whole cell lysates (WCL) and
BRAF, CRAF and MEK immuno-precipitates (IP), from HCT 116, MEL-JUSO and MIA
PaCa-2 cells either untreated, or following 1 hr. treatments with either 1M LXH254 or
1M LY3009120. Proteins detected by immunoblotting are indicated to the right of each
panel. (C) Western analysis (top panels) and quantitation via densitometry (lower panel)
of the indicated proteins in A375 and HCT 116 cells following treatment with increasing
amounts of LXH254. LXH254 concentrations (M) are indicated above each lane and
immunoblotted proteins to the right of each panel. HCT 116 cells were treated for 1hr
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with encorafenib that was subsequently washed-out prior to treatment with LXH254. (D)
Assessment of interactions between LXH254 and kinases in HCT 116 cells. Individual
kinases are depicted as circles along the X-axis and fractional inhibition of kinase
interactions with an ATP-competitive probe by LXH254 are given on the Y-axis.
Figure 2. Representative xenograft models treated with LXH254. Shown on the left of
each panel are changes in tumor volume over time (days) and on the right of each
panel changes in DUSP6 mRNA level after a single administration of LXH254 for the
WM-793 (BRAFV600E, A), SK-MEL-30 (NRASQ61K, BRAFD287H, B), HEYA8 (KRASG12D,
BRAFG464E, C) and 3390HPAX (KRASG12D, D) models. Vehicle (Veh) treated animals
are indicated with ( ) and LXH254 treated animals with ( ). All models were treated
with LXH254 100 mg/kg qd. T/C determinations were made at the time when control
animal were sacrificed due to tumor size (1000 - 1500 mm3) and denoted with an
asterix.
Figure 3. Loss of ARAF expression sensitizes RAS-mutant cell lines to LXH254.
Shown are proliferation curves for five cell lines ( ) and derived variants lacking
expression of ARAF ( ), BRAF ( ) and CRAF ( ). Cell line identity and RAS (or RAF)
mutation status are shown above each graph. Concentrations of LXH254 (nM) and
percentage of cells remaining relative to an untreated control as judged by ATP levels
are given on the X, and Y-axis, respectively. Effects of LXH254 on proliferation were
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determined after either three (MEL-JUSO, SK-MEL-30, HCT 116, MIA PaCa-2) or five
(COR-L23) days of incubation with LXH254.
Figure 4. Expression of either kinase-dead or dimer-deficient ARAF fails to reverse
sensitivity to LXH254 in cells lacking ARAF expression. Shown are proliferation curves
for the COR-L23, MIA PaCa-2, HCT 116 and MEL-JUSO cell lines, both wild type ( )
and variants lacking ARAF expression ( ). Also shown are proliferation curves for cell
lines lacking endogenous ARAF expression, but expressing exogenous wild type ARAF
( ), kinase impaired ARAF ( ), either K336M (A), or D447A (B) or dimer-deficient
R362H ARAF ( ). Effects of LXH254 on proliferation were determined after either three
(MEL-JUSO, SK-MEL-30, HCT 116, MIA PaCa-2) or five (COR-L23) days of incubation
with LXH254. In the case of MIA PaCa-2 cells shown in (A) expression of exogenous
ARAF variants were under the transcriptional control of the doxycycline (dox) –regulated
TET-3G promoter with cells grown in the absence of dox depicted with hashed lines.
IC50 values determined for the curves shown in A&B are provided in (C). Values
denoted with * and ** were determined in the absence of presence of doxycycline,
respectively.
Figure 5. Kinase-impaired and dimer deficient ARAF variants lack in vitro kinase
activity and have reduced interactions with B-and-CRAF, respectively. Shown are
western blots using the indicated antibodies performed on either whole cell lysates
(WCL) or material immuno-precipitated using a FLAG-directed Ab (IP:FLAG) from COR-
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L23 (A), MIA PaCa-2 (B), MEL-JUSO (C) and HCT 116 (D) cell lines. In the cases of
COR-L23 and MIA PaCa-2 cells exogenously expressed ARAF variants were under the
transcriptional control of the doxycycline (dox) –regulated TET-3G promoter.
Concentrations of LXH254 used for cell line pretreatment are shown above each
sample. For the IP-kinase assay purified recombinant HISx6 -tagged MEK1 and ATP
were added to immuno-precipitated material.
Figure 6. RAS-mutant cells expressing only ARAF are resistant to LXH254. Shown
are proliferation (A) and p-ERK (B) inhibition curves for parental ( ) HCT 116, MIA
PaCa-2 and MEL-JUSO cell lines as well as variants lacking B-and-CRAF expression (
), ARAF and BRAF expression ( ) and A-and-CRAF expression ( ) following
treatment with increasing concentrations of LXH254. In all cases, changes in cell
number were determined after 72 hours and p-ERK levels after four hours of incubation
with LXH254. p-ERK levels following four hours of treatment of MIA PaCa-2 cells with
increasing concentrations of either LXH254 or dabrafenib are shown in (C).
Figure 7. RAS-mutant cell lines lacking ARAF are sensitive to LXH254 in vivo. Shown
are changes in tumor volume until the time of T/C determination results for HCT 116
(A), MIA PaCa-2 (B, D) and MEL-JUSO (C) models. Parental model are denoted with
(solid lines) and variants lacking ARAF expression with dashed lines. Vehicle treated
animals are shown in black ( ), 0.3 mg/kg trametinib Q.D. treated in blue ( ) and 50
mg/kg LXH254 B.I.D in red ( ). . Shown in (D) is the MIA PaCa-2 model treated as in
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(B) but with additional combinations of 50 mg/kg LXH254 BID with either 0.3 mg/kg
Q2D ( ) or 0.03 mg/kg ( ) trametinib.
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A
D
B
C %
Inh
ibit
ion
Kinase
ARAF
BRAF CRAF
p38α
Assay IC50 (nM)
ARAF 6.4
BRAF 0.21
CRAF 0.072pERK (T202/Y204)
IERK
pMEK (S217/221)
BRAF
CRAF
GAPDH
WC
L
MEK
BRAF
BR
AF
IP
CRAF
MEK
CR
AF
IP
ME
K IP
BRAF
CRAF
MEK
BRAF
CRAF
MEK
HCT 116 MEL-JUSO Mia PaCa-2
DM
SO
LY
30
09
12
0
LX
H25
4
DM
SO
LY
30
09
12
0
LX
H2
54
DM
SO
LY
30
09
12
0
LX
H2
54
- 9 - 8 - 7 - 6 - 5
0
2 5
5 0
7 5
1 0 0
1 2 5
A 3 7 5
H C T 1 1 6
L o g [ M ]
Re
la
tiv
e p
ER
K
Figure 1
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A B
C D
Figure 2
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1 1 0 1 0 0 1 0 0 0 1 0 0 0 0
0
2 5
5 0
7 5
1 0 0
1 2 5
S K -M E L -3 0 (N R A SQ 6 1 K
, B R A FD 2 8 7 H
)
L X H 2 5 4 (n M )%
Co
ntr
ol
gro
wth
1 1 0 1 0 0 1 0 0 0 1 0 0 0 0
0
2 5
5 0
7 5
1 0 0
1 2 5
M IA P a C a -2 (K R A SG 1 2 C
)
L X H 2 5 4 (n M )
% C
on
tro
l g
row
th
1 1 0 1 0 0 1 0 0 0 1 0 0 0 0
0
2 5
5 0
7 5
1 0 0
1 2 5
C O R -L 2 3 (K R A SG 1 2 V
)
L X H 2 5 4 (n M )
% C
on
tro
l g
row
th
1 1 0 1 0 0 1 0 0 0 1 0 0 0 0
0
2 5
5 0
7 5
1 0 0
1 2 5
H C T 1 1 6 (K R A SG 1 3 D
)
L X H 2 5 4 (n M )
% C
on
tro
l g
row
th
1 1 0 1 0 0 1 0 0 0 1 0 0 0 0
0
2 5
5 0
7 5
1 0 0
1 2 5
M E L -J U S O (N R A SQ 6 1 L
)
L X H 2 5 4 (n M )
% C
on
tro
l g
row
th
CRAF Knockout
BRAF Knockout
ARAF Knockout
Parental
Figure 3
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A.
B. MEL-JUSO (NRASQ61L)
1 0 1 0 0 1 0 0 0 1 0 0 0 0
0
2 5
5 0
7 5
1 0 0
1 2 5
L X H 2 5 4 A c t i v i t y
L X H 2 5 4 ( n M )
% C
on
tro
l g
ro
wth
M I A P a C a 2
M I A A R A F k / o
M I A O E A R A F
M I A O E k d A R A F
M I A O E d d A R A F
1 0 1 0 0 1 0 0 0 1 0 0 0 0
0
2 5
5 0
7 5
1 0 0
1 2 5
L X H 2 5 4 ( n M )
% C
on
tro
l g
ro
wth
H C T 1 1 6
H C T 1 1 6 A K O
H C T 1 1 6 A K O + O E w t A R A F
H C T 1 1 6 A K O + O E d d A R A F
H C T 1 1 6 A K O + O E k d A R A F
HCT 116 (KRASG13D)
COR-L23 (KRASG12V)
1 1 0 1 0 0 1 0 0 0 1 0 0 0 0
0
2 5
5 0
7 5
1 0 0
1 2 5
C O R -L 2 3 (K R A SG 1 2 V
)
L X H 2 5 4 (n M )
% C
on
tro
l g
row
th
P a re n t
A R A F K n o c k o u t
A R A F K n o c k o u t +
A R A F -W T -F L A G
A R A F K n o c k o u t +
A R A F -K 3 6 6 M -F L A G
1 1 0 1 0 0 1 0 0 0 1 0 0 0 0
0
2 5
5 0
7 5
1 0 0
1 2 5
C O R -L 2 3 (K R A SG 1 2 V
)
L X H 2 5 4 (n M )
% C
on
tro
l g
row
th
P a re n ta l
A R A F K n o c k o u t
A R A F K n o c k o u t +
A R A F -W T -F L A G
A R A F K n o c k o u t +
A R A F -K 3 6 6 M -F L A G
1 1 0 1 0 0 1 0 0 0 1 0 0 0 0
0
2 5
5 0
7 5
1 0 0
1 2 5
L X H 2 5 4 (n M )
% C
on
tro
l g
row
th
A R A F K n o c k o u t +
A R A F -R 3 6 2 H -F L A G
P a re n ta l
A R A F K n o c k o u t
A R A F K n o c k o u t +
A R A F -D 4 4 7 A -F L A G
A R A F K n o c k o u t +
A R A F -W T -F L A G
1 10 100 1000 100000
25
50
75
100
125
LXH254 (nM)
% C
ontr
ol gro
wth
MELJUSO
MELJUSO ARAF KO
+ARAF-WT
+ARAF-D447A KD
+ARAF-R362H DD
MIA PaCa-2 (KRASG12C)
MIA PaCa-2 (KRASG12C)
Parental
ARAF Knockout +
ARAF-WT-FLAG (- Dox)
ARAF Knockout +
ARAF-K366M-FLAG (- Dox)
ARAF Knockout +
ARAF-K366M_FLAG (+ Dox)
ARAF Knockout +
ARAF-WT-FLAG (+ Dox)
1 10 100 1000 100000
25
50
75
100
125
LXH254 (nM)
%C
on
tro
lg
row
th
C. Cell Line Variant MEL-JUSO HCT 116 MIA PaCa-2 MIA PaCa-2 (inducible) COR-L23 Wild Type 1015 1796 1560 1278 4274
ARAFD 372 491 565 707* 1349
ARAFD + ARAFWT 2420 1794 1854 1427** 6668
ARAFD + ARAFK362H
442 201 560 N/A N/A
ARAFD + ARAFA447D
453 269 605 N/A N/A
ARAFD + ARAFK336M
N/A N/A N/A 710 1675
Proliferation IC50 (nM)
Figure 4
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A. B. C.
D.
Figure 5
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MIA PaCa-2 (KRASG12C)
HCT 116 (KRASG13D)
1 0 1 0 0 1 0 0 0 1 0 0 0 0
0
2 5
5 0
7 5
1 0 0
1 2 5
L X H 2 5 4 ( n M )
% C
on
tro
l g
ro
wth
P a r e n t a l
A R A F o n ly
C R A F o n ly
B R A F o n ly
A.
1 0 1 0 0 1 0 0 0 1 0 0 0 0
0
2 5
5 0
7 5
1 0 0
1 2 5
L X H 2 5 4 ( n M )
% C
on
tro
l g
ro
wth
M E L J U S O
M E L J U S O A R A F o n ly
M E L J U S O C R A F o n ly
1 0 1 0 0 1 0 0 0 1 0 0 0 0
0
2 5
5 0
7 5
1 0 0
1 2 5
L X H 2 5 4 ( n M )
% C
on
tro
l g
ro
wth
P a r e n t a l
A R A F o n ly
C R A F o n ly
B R A F o n ly
1 0 1 0 0 1 0 0 0 1 0 0 0 0
0
2 5
5 0
7 5
1 0 0
1 2 5
L X H 2 5 4 ( n M )
% C
on
tro
l g
ro
wth
M I A P a C a 2
M I A A R A F o n ly
M I A C R A F o n ly
M I A B R A F o n ly
MIA PaCa-2
B.
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