Vittoria Zoppi1,2, Scott J Hughes1, Chiara Maniaci1,3, Andrea Testa1, Teresa Gmaschitz4, Corinna Wieshofer4, Manfred Koegl4, Kristin M Riching5, Danette L Daniels5, Andrea Spallarossa2, Alessio Ciulli1. 1. Division of Biological Chemistry and Drug Discovery, School of Life Sciences, James Black Centre , University of Dundee , Dow Street , DD1 5EH , Dundee , Scotland , United Kingdom. 2. Dipartimento di Farmacia, Sezione di Chimica del Farmaco e del Prodotto Cosmetico , Università degli Studi di Genova , Viale Benedetto XV 3 , 16132 Genova , Italy. 3. Medical Research Council Protein Phosphorylation and Ubiquitylation Unit, School of Life Sciences, James Black Centre , University of Dundee , Dow Street , DD1 5EH , Dundee , Scotland , United Kingdom. 4. Boehringer Ingelheim RCV GmbH & Co. KG , 1221 Vienna , Austria. 5. Promega Corporation , 2800 Woods Hollow Road , Madison , Wisconsin 53711 , United States.
Abstract
Developing PROTACs to redirect the ubiquitination activity of E3 ligases and potently degrade a target protein within cells can be a lengthy and unpredictable process, and it remains unclear whether any combination of E3 and target might be productive for degradation. We describe a probe-quality degrader for a ligase-target pair deemed unsuitable: the von Hippel-Lindau (VHL) and BRD9, a bromodomain-containing subunit of the SWI/SNF chromatin remodeling complex BAF. VHL-based degraders could be optimized from suboptimal compounds in two rounds by systematically varying conjugation patterns and linkers and monitoring cellular degradation activities, kinetic profiles, and ubiquitination, as well as ternary complex formation thermodynamics. The emerged structure-activity relationships guided the discovery of VZ185, a potent, fast, and selective degrader of BRD9 and of its close homolog BRD7. Our findings qualify a new chemical tool for BRD7/9 knockdown and provide a roadmap for PROTAC development against seemingly incompatible target-ligase combinations.
Developing PROTACs to redirect the ubiquitination activity of E3 ligases and potently degrade a target protein within cells can be a lengthy and unpredictable process, and it remains unclear whether any combination of E3 and target might be productive for degradation. We describe a probe-quality degrader for a ligase-target pair deemed unsuitable: the von Hippel-Lindau (VHL) and BRD9, a bromodomain-containing subunit of the SWI/SNF chromatin remodeling complex BAF. VHL-based degraders could be optimized from suboptimal compounds in two rounds by systematically varying conjugation patterns and linkers and monitoring cellular degradation activities, kinetic profiles, and ubiquitination, as well as ternary complex formation thermodynamics. The emerged structure-activity relationships guided the discovery of VZ185, a potent, fast, and selective degrader of BRD9 and of its close homolog BRD7. Our findings qualify a new chemical tool for BRD7/9 knockdown and provide a roadmap for PROTAC development against seemingly incompatible target-ligase combinations.
Targeted
protein degradation is an emerging strategy to use small
molecules to knock down a protein by hijacking the ubiquitin–proteasome
system.[1,2] PROTACs (proteolysis targeting chimeras)
are bifunctional degrader molecules composed of a ligand for the target
protein and a ligand for E3 ligase recruitment, connected by a linker.[3,4] Upon formation of a ternary complex target:degrader:E3,[5−7] the protein of interest is ubiquitinated and degraded by the proteasome.
Compared to target blockade, post-translational protein degradation
more closely phenocopies genetic approaches to target validation and
can lead to a more sustained cellular effect with more extended duration
of action. An attractive feature of PROTACs is their catalytic mode
of action, as any one molecule may perform multiple rounds of target
ubiquitination and degradation.[8] A consequence
of this feature is that degraders can function at substoichiometric
receptor occupancies, meaning they exhibit degradation activities
at concentrations that can be orders of magnitude lower than their
binary dissociation constants (Kd) from
the target, alleviating the requirement for full target engagement.[9] Moreover, PROTAC molecules can add a layer of
target selectivity beyond that expected from the constitutive binding
ligands, thus providing highly selective degraders with reduced off-target
effect.[5,10−12] The mounting interest
in PROTAC drug discovery is also motivated by the promise to target
proteins considered “undruggable” via conventional medicinal
chemistry approaches.[13] To date, different
target classes have been successfully degraded, including epigenetic
targets such as bromodomain-containing proteins BRD2, BRD3, and BRD4,[5,10,11,14−17] BRD9,[18] TRIM24,[19] SIRT2,[20] PCAF/GNC5,[21] protein kinases,[8,12,22−26] nuclear receptors,[27,28] and E3 ubiquitin ligases to self-degrade.[29,30]To fulfill the potential of targeted protein degradation,
a general
methodology for an efficient PROTAC design would be desirable. However,
the development of active PROTAC degraders is often a laborious and
unguided process. The choice of E3 ligase and the selection of target
ligands and their conjugation are all potential optimization variables
that expand the chemical space to be exploited by medicinal chemists.
Properties of the linker, such as length, composition, and site of
attachment, are known to be important but often their impact on activity
vary in a target- and context-dependent fashion.[11,24,29,31,32] Moreover, small-molecule binders for both the protein
of interest and the E3 ligase are required. Despite the large number
of human E3 ubiquitin ligases postulated to function in cells, only
a few have good-quality ligands[33] that
have been successfully used for PROTACs.[34] The most common ligases recruited are the von Hippel–Lindau
(VHL) protein complex CRL2VHL and the cereblon (CRBN) complex
CRL4CRBN. Studies have shown that PROTACs made of the same
target ligand but either VHL or CRBN ligands can exhibit different
degradation selectivity and efficacy.[11,14,18,22] In some systems, CRBN-based
degraders show a more active profile than VHL-based molecules. Potential
greater flexibility of the Cullin4 based CRL4CRBN compared
to CRL2VHL has been invoked to suggest more productive
ubiquitination of the accessible lysine residues on the target protein.[1,32,35] These observations would suggest
that the development of VHL-based degraders might require more exploration
in the PROTAC design than those based on CRBN. Even if degradation
of a given target protein can be readily obtained by recruiting one
E3 ligase, emerging evidence suggests that it could be beneficial
to develop a parallel chemical series hijacking other E3 ligases.
For example, chemical liabilities on a particular ligase ligand could
be readily circumvented by switching to a different compound. The
hijacked E3 ligase expression and intrinsic activity may be context-dependent,
and vary widely among different cells and tissue types.[36] Furthermore, resistance mechanisms could potentially
arise from the loss of the hijacked E3 ligase, as demonstrated by
the correlation between level of CRBN and response to CRBN-recruiting
drugs in multiple myeloma.[37] Switching
the hijacked ligase can thus aid targeted protein degradation. It
however remains unclear whether optimal target–E3 pairs exist
or indeed whether any combination of E3 ligase and target protein
might be tractable.Here, we demonstrate the development of
probe-quality PROTACs for
a ligase–target pair previously considered incompatible: VHL
and the protein BRD9.[18] BRD9 and its close
homolog BRD7 (85% sequence identity[38])
are bromodomain-containing subunits of the BAF (BRG-/BRM-associated
factor) and PBAF (polybromo-associated BAF) complexes, respectively.[39,40] BAF and PBAF represent two variants of the SWI/SNF complex, one
of the four mammalian ATP-dependent chromatin remodeling complexes.
The SWI/SNF complexes control gene expression, DNA replication, and
DNA repair by modulating access to promoters and coding regions of
DNA through modification of the degree of compactness of chromatin.[41−43] Mounting evidence from genetics and sequencing of cancer-associated
mutations have spurred efforts to unravel yet largely elusive physiological
roles of BAF/PBAF subunits and to develop targeted therapeutics in
cancer and other human diseases.[39] In particular,
BRD9 is overexpressed in several malignancies, such as cervical cancer
and in non-small-cell lung cancer (NSCLC).[44,45] In contrast, BRD7 gene has been proposed as candidate tumor suppressor
gene,[46−49] as it regulates breast cancer cell metabolism[50] and acts as negative regulator of aerobic glycolysis essential
for tumor progression.[51] BRD7 also promotes
X-box binding protein 1 (XBP1) nuclear translocation, which prevents
the development of insulin-resistance disorders.[52] In contrast to these roles, it has been recently shown
that inactivation of the BRD7 gene sensitizes tumor cells to T cell-mediated
killing, suggesting that knockdown of BRD7 could be an attractive
target for cancer immunotherapy.[53] Potent
and selective inhibitors that bind to the BRD7/9 bromodomains have
recently emerged from structure-guided medicinal chemistry campaigns,
including compounds I-BRD9,[38] LP99,[54] ketone “compound 28”,[55] BI-7273 and BI-9564[56] (1a,b, Figure ), and GNE-375.[57] These BRD7/9 inhibitors have been used in cells to help clarify
the roles of the BRD7/9 bromodomains in oncogenesis and other disease
states. For example, pharmacological studies of inhibitors 1a and 1b in combination with domain-swap protein engineering
revealed that an active bromodomain of BRD9 is required to sustain
MYC transcription and proliferation of leukemic cells.[56,58] These findings and availability of bromodomain ligands prompted
us to initiate a PROTAC medicinal chemistry campaign to target BRD7
and BRD9 proteins for degradation.
Figure 1
Chemical structures of parent (1a, 1b, 2–4) and modified
(1c, 2a–4a) BRD7/9 and
E3 ligase ligands.
Functional groups selected for conjugation are shown in blue on parent
ligands and in red on modified ligands.
Chemical structures of parent (1a, 1b, 2–4) and modified
(1c, 2a–4a) BRD7/9 and
E3 ligase ligands.
Functional groups selected for conjugation are shown in blue on parent
ligands and in red on modified ligands.
Results and Discussion
First Generation of BRD7 and BRD9 Degraders
We began
our investigation by designing a small set of PROTACs aimed to induce
BRD7/9 degradation by recruiting three different E3 ubiquitin ligases:
VHL, CRBN, and DCAF15.[59,60] We aimed to leverage available
E3 ligase ligands and to maximize the opportunity for complementary
surfaces between the bromodomain and the ligase within the ternary
complex. As BRD7/9 bromodomain ligands, we selected compounds 1a,b (Figure ),[56] on the basis of their
high binding affinity[56] and of their superiority
as BRD9 chemical probes over other ligands.[58] To design the first generation of degraders, we inspected the crystal
structure of 1a bound to BRD9 (PDB code 5EU1)[56] to identify suitable attachment points and vectors for
linker conjugation, important considerations for PROTAC design as
known to greatly influence degradation activities.[11,29] The dimethylamine group of the molecule was identified as a solvent-exposed
group not involved in interactions with the protein. For synthetic
reasons, the dimethylamine group of compound 1a was replaced
by a piperazine group (BrdL1 (1c), Figure and Supporting Information Figure S1), providing a convenient isosteric handle. As E3
ligase recruiting moieties, VH032 (2, VHL ligand, Figure )[61−63] and pomalidomide
(3, CRBN ligand, Figure )[64] were selected and modified
to afford compounds VHL1 (2a) and 3a (Figure and Supporting Information Figure S1). The amino
terminal groups of 2a and 3a were conjugated
via amide bond to the linker without perturbing the interaction with
the E3 ligases, as previously demonstrated.[8,10,15,22] To expand
the arsenal of E3 ligase ligands being explored, we designed conjugates
containing indisulam (4, Figure ), a small molecule recently reported to
bind to the E3 ligase DCAF15 and to redirect the activity of the CRL4DCAF15 complex toward the neosubstrate CAPERα (also known
as RBM39).[59,60] As the binding mode of 4 is not known, we leveraged information on the activity of
a biotinylated photoactive analogue probe to guide our conjugation
strategy.[60] Accordingly, a para-benzylamine analogue of 4 (derivative 4a, Figure and Supporting Information Figure S1) was designed
as conjugatable ligase ligand. To generate a first set of compounds,
we decided to use PEG linkers composed of two or four PEG units to
connect the two warheads (compounds 5–10, Scheme ).
Scheme 2
Synthesis of the
First Generation of Degraders
Reagents and conditions:
(a)
oxalyl chloride, DMSO, DCM, then TEA, −78 °C to rt, 2
h; (b) 1c, NaBH(OAc)3, TEA, DMF, rt, overnight;
(c) TFA, DCM, rt, 2 h; (d) E3 ligand (2a, 3a, or 4a), HATU, HOAt, DIPEA, DMF, rt, 2 h.
Compounds 5–10 were obtained as
reported in Schemes and 2. Briefly,
reductive amination between the commercially available 4-bromo-2,6-dimethoxybenzaldehyde
(11) and boc-piperazine led to the formation of compound 12 which was then cross-coupled with 14 (obtained
by methylation of 13) under the Myaura–Suzuki
condition (one-pot two steps); the cleavage of tert-butyloxycarbonyl protecting group in acidic conditions afforded 1c in quantitative yield (Scheme ). The primary alcohol functionality of the
linkers (15 and 16) was oxidized to aldehyde
group using a Swern reaction and condensed with the terminal secondary
amine of 1c to afford the tert-butyl
ester intermediates 17 and 18 that were
converted into the corresponding acids by trifluoroacetic acid (TFA)
treatment (Scheme ). Compounds 19 and 20 were then conjugated
with the conjugatable E3 ligands (2a and 3a prepared as previously described,[61,65] and 4a synthesis in Supporting Information Synthetic Procedures) using HATU as coupling reagent yielding
final compounds 5–10.
Scheme 1
Synthesis
of the BRD7/9 Ligand 1c
Reagents
and conditions: (a)
1-Boc-piperazine, NaBH(OAc)3, THF, rt, overnight, yield
97%; (b) NaH, CH3I, DMF, 0 °C, 5 h, yield 95%. (c)
Step 1: 12, B2pin2, KOAc, Pd(dppf)Cl2, 1,4 dioxane, microwave, 140 °C, 40 min. Step 2: 14 and K2CO3 (aq) are added to step
1; microwave, 120 °C, 30 min, yield 55%. (d) HCl 4 M in dioxane,
DCM, rt, 1 h, quantitative yield.
Synthesis
of the BRD7/9 Ligand 1c
Reagents
and conditions: (a)
1-Boc-piperazine, NaBH(OAc)3, THF, rt, overnight, yield
97%; (b) NaH, CH3I, DMF, 0 °C, 5 h, yield 95%. (c)
Step 1: 12, B2pin2, KOAc, Pd(dppf)Cl2, 1,4 dioxane, microwave, 140 °C, 40 min. Step 2: 14 and K2CO3 (aq) are added to step
1; microwave, 120 °C, 30 min, yield 55%. (d) HCl 4 M in dioxane,
DCM, rt, 1 h, quantitative yield.
Synthesis of the
First Generation of Degraders
Reagents and conditions:
(a)
oxalyl chloride, DMSO, DCM, then TEA, −78 °C to rt, 2
h; (b) 1c, NaBH(OAc)3, TEA, DMF, rt, overnight;
(c) TFA, DCM, rt, 2 h; (d) E3 ligand (2a, 3a, or 4a), HATU, HOAt, DIPEA, DMF, rt, 2 h.To assess the degradation activity of the first generation
of PROTACs,
HeLa cells were treated with compounds 5–10 at fixed concentration of 1 μM, for 4 and 16 h before
harvesting (Figure A). CRBN-based PROTACs 7 and 8 demonstrated
strong degradation of BRD9 already after 4 h of treatment, whereas
no BRD7 degradation was observed (Figure A). In contrast, VHL-based degraders 5 and 6 showed weak activity against both BRD7
and BRD9, inducing at most 20% degradation after 4 h and 30% after
16 h, and even weaker activity was observed with the indisulam-based
PROTACs 9 and 10 (Figure A). siRNA knockdown experiments (Figure B) validated the
specificity of the bands observed by Western blot.
Figure 2
Screening of first generation
of degraders. (A) Western blot analysis
of BRD9 and BRD7 levels after treatment of HeLa cells with 1 μM
compounds for 4 and 16 h before harvesting. Degradation activity is
reported below each lane as % of protein abundance relative to 0.1%
DMSO vehicle. (B) Western blot analysis of BRD9 and BRD7 levels after
48 h transfection with 1.25 nM siRNA targeting respectively BRD7,
BRD9, or negative control (N.C.) siRNA. Intensity values are quantified
as described in the Experimental Section.
Screening of first generation
of degraders. (A) Western blot analysis
of BRD9 and BRD7 levels after treatment of HeLa cells with 1 μM
compounds for 4 and 16 h before harvesting. Degradation activity is
reported below each lane as % of protein abundance relative to 0.1%
DMSO vehicle. (B) Western blot analysis of BRD9 and BRD7 levels after
48 h transfection with 1.25 nM siRNA targeting respectively BRD7,
BRD9, or negative control (N.C.) siRNA. Intensity values are quantified
as described in the Experimental Section.While this research was underway,
Remillard et al.[18] disclosed the BRD9 degrader
dBRD9 (21, Figure ) confirming the
strong degradation activity of our CRBN-recruiting PROTACs. Compounds 7 and 21 share the same target and E3 ligands,
which, however, were differently modified to attach two distinct linkers
(Figure ). CRBN-based
PROTACs, however, can exhibit off-target degradation of non-PROTAC-targets
such as IKZF1/3 and GSPT1 due to the neomorphic activity of the CRBN
ligand alone.[18,66]
Figure 3
Structures of compounds 7 and 21.[18]
Structures of compounds 7 and 21.[18]We therefore turned our attention to VHL-based
PROTACs. Encouraged
by the degradation, albeit partial, of both BRD7 and BRD9 induced
by our initial VHL-based PROTACs, we decided to characterize the binding
of 5 biophysically and structurally. To determine the
binding mode of the conjugated bromodomain ligand, compound 5 was cocrystallized with the BRD9 bromodomain (BRD9-BD).
In the BRD9-BD:5 complex, the bromodomain ligand was
clearly observed within its binding pocket, and its binding mode closely
recapitulates that of 1a (rmsd = 0.569 Å) (Figure A,B). The alkylated
piperazine is favorably accommodated within the binding site, with
the linker directed toward solvent, as desired (Figure A,B).
Figure 4
Ternary complex formation and analysis
of binding mode for compound 5. (A) Cocrystal structure
of BRD9-BD and compound 5. The warhead component of the
degrader (purple and cyan; one from
each protomer in the ASU) recapitulates the binding of inhibitor 1a (magenta, PDB code 5EUI),[56] whereas
the alkylated piperazine used to attach the linker is solvent-exposed
and does not form any unfavorable interactions with the protein. (B) Fo – Fc omit
map of compound 5 (contoured at 2.5σ) showing electron
density for the alkylated piperazine ring. (C) BRD9-BD titrated into 5 alone. (D) VCB titrated into 5 alone. (E) VCB
titrated into BRD9-BD:5 binary complex. VCB binds more
weakly to the binary complex BRD9-BD:5 (Kd = 73 nM) compared to compound 5 alone (Kd = 33 nM), indicating negative cooperativity.
Ternary complex formation and analysis
of binding mode for compound 5. (A) Cocrystal structure
of BRD9-BD and compound 5. The warhead component of the
degrader (purple and cyan; one from
each protomer in the ASU) recapitulates the binding of inhibitor 1a (magenta, PDB code 5EUI),[56] whereas
the alkylated piperazine used to attach the linker is solvent-exposed
and does not form any unfavorable interactions with the protein. (B) Fo – Fc omit
map of compound 5 (contoured at 2.5σ) showing electron
density for the alkylated piperazine ring. (C) BRD9-BD titrated into 5 alone. (D) VCB titrated into 5 alone. (E) VCB
titrated into BRD9-BD:5 binary complex. VCB binds more
weakly to the binary complex BRD9-BD:5 (Kd = 73 nM) compared to compound 5 alone (Kd = 33 nM), indicating negative cooperativity.To characterize biophysically
the interplay between VCB (VHL-ElonginC-ElonginB
complex), compound 5, and the BRD9 bromodomain, we applied
our previously developed ITC assay[5,11] that measures
the thermodynamics and cooperativities of ternary complex formation.
Previous work has demonstrated that VHL is capable of forming highly
stable and cooperative ternary complexes, as seen with MZ1-Brd4BD2
(ref (5)) and with
the homo-PROTAC dimerizer CM11 (ref (29)). Titrations of protein into PROTAC alone revealed
a binary binding affinity for VCB (Kd =
33 ± 2 nM, Figure D and Table ) within
2-fold of that measured on previously characterized VHL-based BET
degrader MZ1 (Kd = 70 nM, refs (5) and (11)). Similarly, the binary
affinity (Kd = 15 ± 3 nM) and binding
enthalpy (ΔH = −12 kcal/mol) for BRD9-BD
(Figure C and Table ) were comparable
to that of inhibitor 1a,[56] consistent with the conserved binding modes of 5 and
inhibitor 1a observed crystallographically (Figure A). The titrations
of VCB into BRD9-BD:5 complex (Figure E) showed that VCB binds more weakly to the
binary complex BRD9-BD:5 (Kd = 73 nM) than to compound 5 alone (Kd = 33 nM), indicating negative cooperativity (α
< 1, Table ). Negative
cooperativity has previously been observed with tetrahydroquinoline-based
BET PROTACs, where it was demonstrated that linker length and exit
vector can significantly influence ternary complex formation.[11] On the basis of these considerations, we reasoned
to explore variations on the linker as well as the point of derivatization.
Table 1
Thermodynamic Parameters of Formation
of Binary and Ternary Complexes between VCB, BRD9 Bromodomain, and
Compound 5 Measured by Isothermal Titration Calorimetry
(ITC)a
syringe
cell
Kd (nM)
ΔH (kcal/mol)
ΔG (kcal/mol)
–TΔS (kcal/mol)
N
α
BRD9-BD
5
15 ± 3
–12.5 ± 0.4
–10.7 ± 0.1
1.8 ± 0.5
0.753 ± 0.004
VCB
5
33 ± 2
–15.2 ± 0.1
–10.2 ± 0.1
4.9 ± 0.1
0.60 ± 0.01
BRD9-BD:5
73 ± 2
–6.4 ± 0.1
–9.7 ± 0.1
–3.3 ± 0.1
0.75 ± 0.05
0.45
All ITC titrations were performed
at 25 °C. Values reported are the mean ± SEM from at least
three independent measurements (n ≥ 3).
All ITC titrations were performed
at 25 °C. Values reported are the mean ± SEM from at least
three independent measurements (n ≥ 3).
Second Generation of BRD7 and BRD9 Degraders
To improve
ternary complex formation and degradation activity of PROTACs 5 and 6, we explored the impact of varying their
derivatization point, linker length, and composition (compounds 22–31, Table ). First, to expand the conjugation pattern
between VHL1 and BrdL1 (Figure ), the number of PEG units was modified (3 units for 24; 5 units for 22), a more lipophilic 11-atoms
chain was inserted (compound 23), and a different attachment
to BrdL1 moiety via amide conjugation was explored (compound 25) (Table ). Furthermore, we explored a conjugation vector via a phenolic position
(VHL2 (2b), compounds 28 and 31, Table and Supporting Information Figure S1), as previously
described.[29,67] To improve binary binding affinities
to VHL and potentially fine-tune intermolecular interactions in the
ternary complex,[5] we replaced the VHL2
acetyl group with either a cyanocyclopropyl group (VHL3 (2c), derivatives 27 and 30, Table and Supporting Information Figure S1)[29,62] or a fluorocyclopropyl
group (VHL4 (2d), derivatives 26 and 29, Table and Supporting Information Figure S1).[63] As assessed by crystallographic studies (for 2c, PDB code 5LLI; for 2d, PDB code 5NVX), these modifications accommodate snugly
on the VHL protein surface and enhance binding affinity.[62,63] To allow direct comparison with the compounds from the first series,
compounds 26–28 and 29–31 were designed to contain PEG2 and PEG4 linkers,
respectively.
Table 2
SAR of Second Generation of PROTACsa
Footnote: *Degradation
activity
reported as % of total protein remaining after 1 μM compound
treatment relative to 0.1% DMSO vehicle as quantified by Western blotting
of HeLa cell lysates.
Footnote: *Degradation
activity
reported as % of total protein remaining after 1 μM compound
treatment relative to 0.1% DMSO vehicle as quantified by Western blotting
of HeLa cell lysates.Compounds 22 and 24 were obtained via
the same synthetic route used for the first generation (synthesis
of compounds 22, 24, and 25 detailed in the Supporting Information). The synthesis of 23 (Scheme ) involved nucleophilic attack of diethylene
glycol (PEG2) to 6-bromo-1-hexene to afford derivative 33 that was oxidized to carboxylic acid 34 by treatment
with TEMPO and bis-acetoxyiodobenzene (BAIB). After coupling
with 2a, Lemieux–Johnson oxidation of the double
bond yielded the aldehyde intermediate that was reacted with amine 1c to yield compound 23 in 54% yield. A similar
synthetic strategy was applied for the synthesis of degraders 26–31 (Scheme ). Briefly, after nucleophilic substitution
of polyethylene glycol (PEG2 and PEG4) with allyl bromide, the alcoholic
group of 38 and 39 was activated as mesylate
and reacted with the phenolic group present in the VHL ligand scaffold
affording derivatives 40–45. The
alkene moiety was then oxidized, and the resulting aldehyde derivative
was directly used for the final reductive amination step with 1c to afford the final products 26–31.
Reagents and conditions: (a)
NaOH, allyl bromide, dioxane, rt, overnight; (b) MsCl, TEA, DCM, rt,
3 h; (c) VHL ligands 2b–d, K2CO3, DMF, 70 °C, overnight; (d) OsO4, NaIO4, pyridine, dioxane/H2O, rt; (e) 1c, NaBH(OAc)3, TEA, DMF, rt, overnight.All second-generation compounds were profiled for
BRD9 and BRD7
degradation after treatment for 4 and 16 h (Figure A and Supporting Information Figures S2 and S3). The two VHL-based PROTACs 5 and 6 were included as reference compounds. Derivative 26 (Figure B) demonstrated marked and selective (around 90%) depletion of BRD9
over BRD7 already after 4 h treatment in HeLa cells (Figure A, Table ). By comparing and contrasting the degradation
profiles of related compounds, structure–activity relationships
began to emerge (Table ). As expected, the length of linkers influenced degradation profiles,
with more pronounced BRD9 degradation observed with shorter linkers
for given matched pairs (compare 26 and 29; 27 and 30; 5 with 24, 6, and 22). We also observed
that for a given linker length, replacement of an oxygen atom with
a methylene group was beneficial to degradation activity (compare 23 vs 24). Among conjugates derivatized at the
phenolic position of the VHL ligand, the nature of the terminal capping
group also influenced degradation potency. Within each series of conjugates
of fixed linker, compounds bearing the fluorocyclopropyl moiety (VHL4)
were more potent degraders than those containing cyanocyclopropyl
(VHL3) and even more so than acetyl group (VHL2) (26 vs 27 and 28; and 29 vs 30 and 31, respectively) (Table ). These trends are consistent with the binary
binding affinity values measured for the corresponding VHL ligands.[63] To account for potential different protein expression
levels, compounds 22–31 were tested
across a panel of different cancer cell lines (Supporting Information Figures S2 and S3). From these degradation
screens, 26 was confirmed as the most active compound,
consistently across all assays and cell lines.
Figure 5
Compound 26 induces rapid and profound depletion of
BRD9 in cells. (A) Western blot analysis of BRD9, BRD7, and β-actin
after treatment of HeLa cells with 1 μM compounds for 4 h before
harvesting (data reported in Table ). (B) Chemical structure of 26. (C) Quantification
of BRD9 protein levels after treatment of HeLa with six different
concentrations of 26 at 30 min and 4 h before harvesting.
(D) Quantification of BRD9 protein levels after treatment with 1 μM 26 in HeLa at the desired time points. Intensity values, DC50, and half-lives were quantified as described in the Experimental Section.
Compound 26 induces rapid and profound depletion of
BRD9 in cells. (A) Western blot analysis of BRD9, BRD7, and β-actin
after treatment of HeLa cells with 1 μM compounds for 4 h before
harvesting (data reported in Table ). (B) Chemical structure of 26. (C) Quantification
of BRD9 protein levels after treatment of HeLa with six different
concentrations of 26 at 30 min and 4 h before harvesting.
(D) Quantification of BRD9 protein levels after treatment with 1 μM 26 in HeLa at the desired time points. Intensity values, DC50, and half-lives were quantified as described in the Experimental Section.Compound 26 was further characterized by profiling
its concentration-dependent activity at early time points (30 min
and 4 h before harvesting; Figure C and Supporting Information Figure S4). PROTAC 26 induced preferential degradation
of BRD9 over BRD7, resulting in a half-degrading concentration (DC50) of 560 nM against BRD9 (Figure C and Supporting Information Figure S4). More than 60% of degradation of BRD9 was observed
at 1 μM after 4 h, while maximal degradation (Dmax around 80%) was reached at 10 μM. At higher
doses, the characteristic “hook effect” was observed,
consistent with 26 acting preferentially as inhibitor
over degrader at high concentrations. Rapid and selective target degradation
was confirmed by profiling cellular activities over time (Figure D and Supporting Information Figure S4). Treatments
of HeLa cells at fixed concentration (1 μM) of 26 at varying time points revealed rapid degradation of BRD9 with an
apparent half-life of 3.5 h, resulting in more than 50% degradation
already after 4 h treatment and achieving the highest level of depletion
after 8 h (Figure D).To determine to what extent a correlation could be seen
between
ternary complex formation and the improved degradation properties
of 26, we turned to measurements of thermodynamic parameters
and cooperativity by ITC (Figure A and Supporting Information Figure S5). Titrating VCB into 26 alone or BRD9-BD:26 complex indicated a cooperativity α = 1, an over
2-fold improvement over 5. At the binary level compared
to 5, we observed negligible difference between 26 and 5 in binding affinity for BRD9-BD, but
a slight loss in affinity for VCB (Kd =
87 ± 5 nM for 26 compared to 33 ± 2 nM for 5) (Supporting Information Table S1).
Figure 6
Improved ternary complex formation by series-2 degraders. (A) Overlay
of compound 26 titrations shows no difference between
binary (VCB into 26 alone; black) and ternary (VCB into
BRD9-BD:26 binary complex; green) titrations. (B) Fluorescence
polarization measurements for compound 5 in the presence
(red) and absence (black) of BRD9-BD. The rightward shift in the presence
of BRD9-BD indicates negative cooperativity. Each point is the mean
± SEM of at least two individual experiments performed in triplicate.
(C) Fluorescence polarization measurements for compound 26 in the presence (green) and absence (black) of BRD9-BD. Each point
is the mean ± SEM of at least two individual experiments performed
in triplicate. (D) AlphaLISA assay showing increased ternary complex
formation for 26 (green) compared to 5 (red).
Each point is the mean ± SEM of at least one experiment performed
in quadruplicate.
Improved ternary complex formation by series-2 degraders. (A) Overlay
of compound 26 titrations shows no difference between
binary (VCB into 26 alone; black) and ternary (VCB into
BRD9-BD:26 binary complex; green) titrations. (B) Fluorescence
polarization measurements for compound 5 in the presence
(red) and absence (black) of BRD9-BD. The rightward shift in the presence
of BRD9-BD indicates negative cooperativity. Each point is the mean
± SEM of at least two individual experiments performed in triplicate.
(C) Fluorescence polarization measurements for compound 26 in the presence (green) and absence (black) of BRD9-BD. Each point
is the mean ± SEM of at least two individual experiments performed
in triplicate. (D) AlphaLISA assay showing increased ternary complex
formation for 26 (green) compared to 5 (red).
Each point is the mean ± SEM of at least one experiment performed
in quadruplicate.To confirm these findings,
we repurposed an existing fluorescence
polarization (FP) assay that involves the competitive displacement
of a FAM-labeled HIF-1α peptide.[68] By comparing PROTAC-induced peptide displacement in the presence
and absence of BRD9-BD, it is possible to determine the cooperativity
(Figure B,C). FP measurements
for compound 5 showed a rightward shift in the IC50 curve in the presence of BRD9-BD, indicating negative cooperativity,
whereas compound 26 showed no shift. Back-calculation
of Kd values[63] produced affinity values that were comparable to those obtained
by ITC (Supporting Information Table S1 and Figure S5).Previous studies with VCB and BET bromodomains have
demonstrated
that the amount of ternary complex formed is well correlated to the
cooperativity of the system.[5] Therefore,
we employed an AlphaLISA proximity assay to determine the effect of
increasing cooperativity on ternary complex formation (Figure D). Indeed, there was a 50%
increase in the maximum α intensity measured for VCB:26:BRD9-BD compared to VCB:5:BRD9-BD, suggesting that
the increased cooperativity of 26 compared to 5 resulted in increased population of ternary complex.
Third Generation
of BRD7 and BRD9 Degraders
The pronounced
degradation of BRD9 observed with 26 motivated us to
design a third generation of PROTACs with the goal to further optimize
our degrader. On the basis of the SAR previously acquired, the design
strategy was to keep VHL4 moiety fixed and to focus on systematically
varying the linker length and composition, as well as the substitution
and conjugation chemistry at the BRD7/9 warhead. The focus on the
linker concentrated on exploring varying ratios between hydrophilic
and lipophilic portions within the context of three different lengths:
5, 8, and 11 atoms (Table ). We reasoned that varying the balance between hydrophilicity
and lipophilicity might influence the conformational equilibria and
intrinsic folding propensity of the linker, with direct impact on
the process of ternary complex formation as well as potentially cell
permeability. Linkers were connected to four different analogues of
BRD7/9 ligands. Guided by the structure–activity relationships
of BRD7/9 bromodomain inhibitors developed by Martin et al.,[56] we introduced two structural variations, single
or in combination. First, we arranged the methoxy groups on the phenyl
ring in either meta (BrdL1, 1c) or para (BrdL2, 1d) (Table and Supporting Information Figure S1)
relative to each other. Second, we replaced the piperazine moiety
with an azetidine group (BrdL3, 1e and BrdL4, 1f, Table and Supporting Information Figure S1). For conjugation
between the bromodomain ligand and the linker, either tertiary amines
(via reductive amination reactions) or amide bonds were contemplated.
This design yielded a set of 19 new PROTACs (Table ).
Table 3
SAR of Third Generation
of PROTACsa
Footnote: *Degradation activity
reported as % of total protein remaining after 1 μM compound
treatment relative to 0.1% DMSO vehicle as quantified by Western blotting
of HeLa and RI-1 cell lysates.
Footnote: *Degradation activity
reported as % of total protein remaining after 1 μM compound
treatment relative to 0.1% DMSO vehicle as quantified by Western blotting
of HeLa and RI-1 cell lysates.To circumvent the need to use the hazardous reagent osmium tetroxide
previously applied in the Lemieux–Johnson reaction, some key
modifications and optimization to the synthesis were made (Scheme and Supporting Information Synthetic Procedures).
Mesylation of the free hydroxy group of the linkers allowed nucleophilic
attack by the phenolic group of 2d (Scheme ). The lipophilic compound 66, instead, was conjugated to 2d via alkylation
(Scheme ). Then, the
diacetal functional group on the linker was hydrolyzed to aldehyde
under acidic conditions to allow reductive amination with 1c,d (synthesis of 1d is described in the Supporting Information) warheads, leading to
the formation of compounds 46–54.
To conjugate the linker to 1e,f via amide
bond, VHL-linker aldehyde intermediates were oxidized to acid through
a Pinnick reaction. Then, HATU-mediated coupling with 1e,f (synthesis described in the Supporting Information) was applied to obtain the final compounds 55–64 (Scheme and Supporting Information Synthetic Procedures).
Scheme 5
General Synthetic Routes for Third-Generation
Compounds
Reagents and conditions: (a)
MsCl, TEA, DCM, rt, 3 h; (b) 2d, K2CO3, DMF, 70 °C, overnight; (c) K2CO3, DMF, 70 °C, overnight; (d) HCl 1 N, THF (1:1), 50 °C,
2 h; (e) 1c,d, NaBH(OAc)3, TEA,
DMF, rt, overnight; (f) Na2HPO4, NaClO2, 2-methyl-2-butene, t-BuOH, H2O, rt,
4 h ; (g) 1e,f, HATU, HOAt, DIPEA, DMF,
rt, 2 h.
General Synthetic Routes for Third-Generation
Compounds
Reagents and conditions: (a)
MsCl, TEA, DCM, rt, 3 h; (b) 2d, K2CO3, DMF, 70 °C, overnight; (c) K2CO3, DMF, 70 °C, overnight; (d) HCl 1 N, THF (1:1), 50 °C,
2 h; (e) 1c,d, NaBH(OAc)3, TEA,
DMF, rt, overnight; (f) Na2HPO4, NaClO2, 2-methyl-2-butene, t-BuOH, H2O, rt,
4 h ; (g) 1e,f, HATU, HOAt, DIPEA, DMF,
rt, 2 h.Degraders 46–64 were screened
at 1 μM in HeLa cells following 4 and 16 h of treatment (Table , Figure A and Supporting Information Figure S6). A large proportion of compounds induced
efficient degradation of both BRD7 and BRD9 in HeLa cells, with less
than 10% total protein remaining after 4 h treatment (Table , Figure A). Overall, within matched pairs, greater
degradation activity was observed for compounds containing meta (BrdL1 and BrdL3) over para (BrdL2
and BrdL4) dimethoxy substituents (as representative examples: 46 vs 47, 26 vs 48, 51 vs 52, Figure A). To assess consistency of cellular activity, compound
screening was repeated in RI-1 (DLBCL) cells after 2 h of treatment
(Table , Figure B). This cell line
was chosen because it is sensitive to BRD9 inhibition,[58] it is of clinical relevance, and it also expresses
both VHL and CRBN ligases (Supporting Information Figure S7). The compounds that induced greatest protein degradation
activity after 2 h were 46 and 52 (on BRD9),
and 51 (on BRD7) (Figure B). Compounds 46 and 51 differ
only by one atom in the center of the linker, which is oxygen or carbon,
respectively (Table ). Compound 52 is the analogue of 51 but
with BrdL2 instead of BrdL1 (Table ). 46 and 51 showed enhanced
degradation of BRD9 compared to 26, and similar levels
of degradation compared to CRBN-based degrader 7 in RI-1
cells after 8 h treatment. In addition, 46 and 51 achieved PROTAC-induced degradation of BRD7 in addition
to BRD9 (Figure C).
Figure 7
Screening
of third generation of degraders. (A) Western-blot analysis
of BRD9 and BRD7 levels after treatment of HeLa cells with 1 μM
compounds for 4 h before harvesting. (B) Western blot analysis of
BRD9 and BRD7 levels after treatment of RI-1 cells with 1 μM
compounds for 2 h before harvesting. (C) Western blot analysis of
BRD9 and BRD7 levels after treatment of RI-1 cells with 1 μM 7, 26, 46, and 51 for
2 and 8 h before harvesting. Intensity values were quantified as described
in the Experimental Section.
Screening
of third generation of degraders. (A) Western-blot analysis
of BRD9 and BRD7 levels after treatment of HeLa cells with 1 μM
compounds for 4 h before harvesting. (B) Western blot analysis of
BRD9 and BRD7 levels after treatment of RI-1 cells with 1 μM
compounds for 2 h before harvesting. (C) Western blot analysis of
BRD9 and BRD7 levels after treatment of RI-1 cells with 1 μM 7, 26, 46, and 51 for
2 and 8 h before harvesting. Intensity values were quantified as described
in the Experimental Section.We next decided to assess the concentration-dependent
activity
of 46 and 51 in RI-1 cells at two time points
(2 and 8 h) after treatments at different concentrations (Figure A,C). This experiment
revealed 51 to be the most potent of the two, achieving
maximal protein degradation of BRD9 in the 10–100 nM window,
and of BRD7 between 0.1–1 μM, with the hook effect observed
at higher concentrations with both proteins (Figure A). In contrast, 46 required
concentrations of about 10-fold higher than 51 to achieve
its Dmax, and consequently longer treatment
times to achieve similar degradation levels of both BRD9 and BRD7
(Figure A). Dose-dependent
degradation profiles of 51 at the 8 h time-point gave
half-degrading concentrations (DC50) of 1.76 nM and 4.5
nM against BRD9 and BRD7, respectively (Figure C). The pronounced hook effect observed on
BRD9 protein levels upon treatment with 1 μM of 51 (Figure A,C) explains
its apparent weaker degradation activity in the initial screening
(Figure B). The potent
and rapid protein degradation induced by 51 was confirmed
by assessing its activity in RI-1 cells treated with 10 nM or 100
nM of compound at varying time points (Figure D). Levels of both BRD7 and BRD9 decreased
by more than 50% already after 30 min of treatment at 100 nM, reaching
more than 90% of degradation after 4 h. No protein recovery was observed
through 48 h of treatment. At the lower concentration used (10 nM) 51 was seen to degrade preferentially BRD9 over BRD7, consistent
with the lower DC50 value for BRD9 versus BRD7. Together,
the results of the stepwise design and optimization of VHL-based degraders
allowed us to identify 51 as our most potent degrader,
with DC50 in the single-digit nanomolar range and profound Dmax greater than 90% (Figure ). These data qualified PROTAC 51 as a potent dual BRD9 and BRD7 degrader, hence afterward referred
to as VZ185.
Figure 8
VZ185 induces strong and rapid degradation in a time-
and dose-dependent
manner. (A) Western blot analysis of BRD9, BRD7, and β-actin
after treatment of RI-1 cells with six different concentrations of
compounds 46 and 51 for 2 and 8 h before
harvesting. (B) Chemical structures of 51 (VZ185) and 46. (C) Quantification of protein levels relative to DMSO
control after treatment with different concentration of VZ185 and
DC50 values. (D) Time-dependent experiment in RI-1 cells
after treatment with 10 nM and 100 nM 51 at the desired
time points. Intensity values and DC50 were quantified
as described in the Experimental Section.
VZ185 induces strong and rapid degradation in a time-
and dose-dependent
manner. (A) Western blot analysis of BRD9, BRD7, and β-actin
after treatment of RI-1 cells with six different concentrations of
compounds 46 and 51 for 2 and 8 h before
harvesting. (B) Chemical structures of 51 (VZ185) and 46. (C) Quantification of protein levels relative to DMSO
control after treatment with different concentration of VZ185 and
DC50 values. (D) Time-dependent experiment in RI-1 cells
after treatment with 10 nM and 100 nM 51 at the desired
time points. Intensity values and DC50 were quantified
as described in the Experimental Section.To confirm the potent and rapid
degradation activity of VZ185 and
its superiority over close analogues, we employed orthogonal kinetic
degradation studies using live cell luminescent monitoring of BRD7
and BRD9 endogenously tagged with HiBiT in HEK293 cells using CRISPR/Cas9.[69] Degradation profile experiments carried out
over 24 h confirmed the superior degradation activity of VZ185 over
compounds 26 and 46 at a fixed concentration
of 1 μM (Supporting Information Figure S8). Treatment across a range of concentrations of VZ185 of both HiBiT-BRD7
and HiBiT-BRD9 revealed differential degradation profiles (Figure A) and allowed the
calculation of Dmax, DC50 values,
and initial rates of degradation (Figure B,C). Indeed, rapid degradation was observed
within a few hours by VZ185 showing preference for BRD9 as compared
to BRD7 (BRD9-DC50 = 4 nM; BRD7-DC50 = 34 nM)
(Figure B). Degradation
rate was directly proportional to the concentration of VZ185 except
at high concentration for BRD9 where the curve reaches a plateau (Figure C). This trend was
in line with the strong “hook effect” previously observed
with VZ185. Degradation activity was also confirmed within matched-pairs 26–48 and VZ185-52 with CRISPR/Cas9-mediated
HiBiT endogenous tagging of BRD9 and BRD7 in HEK293 cells (Supporting Information Figure S8). In addition,
degradation analysis in a panel of other human cancer cell lines (EOL-1,
A-204) confirmed the potency of VZ185, showing a DC50 between
2 and 8 nM for BRD9 (Supporting Information Figure S9).
Figure 9
Quantitative live-cell kinetics of VZ185 induced degradation of
BRD7 and BRD9. Degradation profile (A), calculation of DC50 values (B), and initial degradation rate (C) across concentration
series indicated of VZ185 using continual luminescent reading of CRISPR/Cas9
endogenously tagged HiBiT-BRD7 or HiBiT-BRD9 in HEK293 cells. Error
bars are expressed as SEM taken from n = 3 experiments.
Quantitative live-cell kinetics of VZ185 induced degradation of
BRD7 and BRD9. Degradation profile (A), calculation of DC50 values (B), and initial degradation rate (C) across concentration
series indicated of VZ185 using continual luminescent reading of CRISPR/Cas9
endogenously tagged HiBiT-BRD7 or HiBiT-BRD9 in HEK293 cells. Error
bars are expressed as SEM taken from n = 3 experiments.Following its identification as
the best degrader, we subjected
VZ185 to a thorough biophysical characterization in order to dissect
the molecular basis underpinning its potent degradation activity.
Both the ITC and FP data indicated that the PROTAC was not more cooperative
than 26 (Table and Supporting Information Figures S5 and S10). Consistent with this, the amount of ternary complex
estimated by AlphaLISA was also not significantly different from that
measured for 26 (Table and Supporting Information Figure S10). However, the binary affinity for both VCB (Kd = 26 ± 9 nM) and the BRD9 bromodomain (Kd = 5.1 ± 0.6 nM) was significantly greater
than 26. The pronounced binary affinity for each respective
protein provides some basis for the strong “hook effect”
observed in the degradation assays, consistent with previous reports
that a high binary affinity can direct PROTACs to function preferentially
as inhibitors at higher concentrations and exhibit strong hook effects.[11] Despite the absence of a significant boost in
cooperativity over 26, the total ΔG° for ternary complex formation increased to −21.7 kcal/mol,
which is greater compared to those of 26 (−20.7
kcal/mol) and 5 (−20.4 kcal/mol) (Table ) and in line with that of our
potent Brd4 degrader MZ1 (−22.2 kcal/mol).[5] VZ185 and its analogues 26 and 46 all showed low cell permeability in PAMPA assay, suggesting that
permeability is unlikely to be the main driver of the enhanced degradation
activity of VZ185 (Table S3). The data
together suggest that the thermodynamically more stable ternary complex
formed by VZ185 helps to drive its more potent and rapid degradation
activity, in spite of its low cell permeability.
Table 4
Biophysical Comparison between BRD9
Degraders from Three Generations
ITCa
FPb
AlphaLISA
compd
binary Kd (nM)
ternary Kd (nM)
α
total ΔG (kcal/mol)
binary Kd (nM)
ternary Kd (nM)
α
max intensity
5
33 ± 2
73 ± 2
0.45
–20.4
24 ± 6
98 ± 2
0.24
1.0 × 106
26
87 ± 5
83 ± 2
1.05
–20.7
70 ± 14
60 ± 5
1.17
1.56 × 106
VZ185
26 ± 9
27 ± 3
0.96
–21.7
35 ± 5
35 ± 6
1.00
1.47 × 106
All ITC titrations
were performed
at 25 °C. Values reported are the mean ± SEM from at least
two independent measurements (n ≥ 2).
Kd values
are reported as the mean ± SEM of at least two individual experiments
performed in triplicate.
All ITC titrations
were performed
at 25 °C. Values reported are the mean ± SEM from at least
two independent measurements (n ≥ 2).Kd values
are reported as the mean ± SEM of at least two individual experiments
performed in triplicate.We next studied the functional mechanism of VZ185 by confirming
proteasome and CRL2VHL involvement and ubiquitination of
BRD7 and BRD9 (Figure ). Combined treatment of the active degrader with the proteasome
inhibitor MG132 and the neddylation inhibitor MLN4924, which blocks
the activity of CRL2VHL,[70] suppressed
the degradation of BRD7 and BRD9, clearly indicating that the degradation
is proteasome- and CRL2VHL-dependent (Figure A). Moreover, to investigate
levels of target ubiquitination, NanoBRET experiments were performed
using the endogenously tagged HiBiT-BRD7 and BRD9 as energy donors
and a polyclonal-Ub primary in conjunction with a fluorescently labeled
secondary antibody as an energy acceptor (Figure B). Increases in BRET can be observed over
time after treatment with VZ185 for both proteins, indicating PROTAC-induced
target ubiquitination. The observed signal was stronger for BRD9 as
compared to BRD7, consistent with the trends observed for VZ185 inducing
preferential degradation of BRD9 compared to BRD7 (Figure B). Additionally, to confirm
the involvement of VHL in the mechanism of action of VZ185, a competition
assay with VHL inhibitor VH298 (ref (62)) was carried out. RI-1 cells were treated with
100 μM VH298 30 min before adding VZ185 (100 nM), and the cells
were incubated for 4 h before cell lysis (Figure A). As anticipated, pretreatment with VHL
inhibitor blocked the degradation activity of VZ185. Moreover, since
the trans stereochemistry of the hydroxyl group of
the hydroxyproline moiety on VHL is essential for the binding to VHL,[62,71] RI-1 cells were treated with cisVZ185 (100 nM)
as inactive negative control (synthesis detailed in the Supporting Information) for 4 h before harvesting.
As expected, no degradation of BRD7 or BDR9 was observed with cisVZ185 (Figure A).
Figure 10
Mechanistic characterization of VZ185 mode of action.
(A) VZ185
activity is proteasome and CRL2VHL-dependent. RI-1 cells
were treated in two replicates with MG132, MLN4924, VH298, and cisVZ185 in the presence of absence of VZ185 (100 nM) at
desired time points before harvesting. (B) NanoBRET experiments in
HEK293 cells to monitor ubiquitination of HiBiT endogenously tagged
BRD9 (purple) or BRD7 (green) using monoclonal-Ub primary and Alexa594
secondary antibodies at times indicated after treatment with 1 μM
VZ185. Error bars expressed as SEM of n = 3 experiments.
Mechanistic characterization of VZ185 mode of action.
(A) VZ185
activity is proteasome and CRL2VHL-dependent. RI-1 cells
were treated in two replicates with MG132, MLN4924, VH298, and cisVZ185 in the presence of absence of VZ185 (100 nM) at
desired time points before harvesting. (B) NanoBRET experiments in
HEK293 cells to monitor ubiquitination of HiBiT endogenously tagged
BRD9 (purple) or BRD7 (green) using monoclonal-Ub primary and Alexa594
secondary antibodies at times indicated after treatment with 1 μM
VZ185. Error bars expressed as SEM of n = 3 experiments.We next assessed the impact of
compound-induced BRD7/9 degradation
on the viability of cancer cell lines. EOL-1 (acute myeloid eosinophilic
leukemia) and A-204 (malignant rhabdoid tumor) cell lines were chosen
because they are sensitive to BRD9 inhibition/degradation[18,56] and dependent on an active BAF complex,[72] respectively. Cellular ATP presence was quantified as signal of
metabolically active cells (Figure ). VZ185 was cytotoxic in both cell lines, with EC50 of 3 nM (EOL-1) and 40 nM (A-402), and proved to be equipotent
to CRBN-based degrader 21 (dBRD9, EC50 of
5 and 90 nM, respectively) (Figure ). Differential cytotoxicity of BRD7/9 degradation
by VZ185 over and above BRD7/9 bromodomain inhibition was clearly
observed (EC50 of 90–340 nM and 370–3550
nM for compounds 1a and 1b, respectively).
The activity in A-204 cells is of particular relevance as malignant
rhabdoid tumors are rare, chemoresistant cancers with poor survival
rate (<25%) that are distinctly characterized by biallelic inactivation
of SMARCB1, a core subunit of the BAF complex, suggesting specific
vulnerabilities.[86]
Figure 11
Effect of BRD7/9 degradation
on viability of BRD9-sensitive cancer
cell lines. Cell proliferation activity assessed in EOL-1 (A) and
A-204 (B) cell lines after treatment with 1a, 1b, VZ185, 7, 21 (dBRD9), and doxorubicin
for 7 days.
Effect of BRD7/9 degradation
on viability of BRD9-sensitive cancer
cell lines. Cell proliferation activity assessed in EOL-1 (A) and
A-204 (B) cell lines after treatment with 1a, 1b, VZ185, 7, 21 (dBRD9), and doxorubicin
for 7 days.Finally, to assess the
cellular selectivity of VZ185 for BRD7/9
degradation and identify potential degradation off-targets, multiplexed
isobaric tagging mass spectrometry proteomic experiments were performed
to monitor protein levels in a quantitative and unbiased manner. RI-1
cells were treated in triplicate with DMSO, 100 nM VZ185, or 100 nM cisVZ185 for 4 h. Among 6273 proteins quantified in this
analysis, of those that met the criteria for a statistically significant
change in abundance (p-value y <
0.001; fold change {x < −20% U, x > 20%}, Figure and Supporting Information Figures S11 and S12), markedly selective degradation of BRD7 and BRD9
was observed. As expected, BRD7/9 proteins were not depleted by treatment
with negative control cisVZ185 (Supporting Information Figures S11 and S12). Protein levels
of other bromodomain-containing proteins or other BAF/PBAF subunits
remained unaffected. To confirm selectivity over key potential off-target
proteins within the bromodomain protein family, live cell kinetic
analyses of endogenously tagged BRD2/3/4 and SMARCA4 proteins expressing
LgBiT were performed (Supporting Information Figure S13). These results together with the proteomic data confirmed
VZ185 as an effective and highly selective degrader of BRD7/9 proteins
in cells. In vitro PK data further showed high stabilities of VZ185
in both plasma and microsomes from both human and mouse species, as
well as high aqueous kinetic solubility (up to ∼100 μM, Table S3). Together, the data qualify VZ185 as
a novel high-quality degrader probe for cellular and potentially in
vivo investigations.
Figure 12
Impact of VZ185 on the cellular proteome after treatment
of RI-1
cells with 100 nM compound for 4 h before harvesting. Data are plotted
as fold change (%) versus −log10 of p-value (t test) for a total of 6273 proteins, expressed
as the mean of the replicates. For quantification, see Experimental Section.
Impact of VZ185 on the cellular proteome after treatment
of RI-1
cells with 100 nM compound for 4 h before harvesting. Data are plotted
as fold change (%) versus −log10 of p-value (t test) for a total of 6273 proteins, expressed
as the mean of the replicates. For quantification, see Experimental Section.
Conclusion
We describe the development of a new series
of PROTACs against
BRD9, a target thought as not degradable through recruitment of the
E3 ligase VHL. In spite of starting from unimpressive degradation
profiles of initial compounds, VHL-based degraders could be optimized
by systematically varying the conjugation patterns and monitoring
cellular degradation activities and formation of ternary complexes.
Throughout the campaign, we revealed important structure–activity
relationships that proved invaluable to guide the optimization search
space and led to significant improvements in degradation activities.
We thoroughly characterize VZ185 as a highly selective, potent, and
rapid dual degrader with a slight preference for BRD9 over BRD7. Our
findings thus qualify VZ185 as a new high-quality chemical probe that
will be valuable to explore the biology and therapeutic potential
of degrading these two proteins.Biophysical and mechanistic
studies suggest that increased ternary
complex stability correlates with improved degradation profiles. The
absence of positive cooperativity in VZ185 allows much scope for optimizing
the thermodynamics of ternary complex formation, which in turn should
warrant enhanced degradation activities of future compounds.[5,11,32] Further investigation of the
contributing factors of single-target selectivity would be important
and could also allow rational design of single-target selective degraders,
for example, for BRD7 over BRD9. More generally, this successful campaign
exemplifies a broadly applicable approach to arrive at degraders that
are effective for any target–ligase pairs, even those that
might have been considered unproductive based on negative studies
with initial compounds. It is thus tempting to speculate that there
may not exist a preferred E3 ligase for “PROTACing”
a given target protein. Any E3 ligase might, in principle, be hijacked
for productive target ubiquitination and degradation, provided the
combinatorial chemical space is adequately explored.
Experimental Section
Chemistry. Synthesis
Chemicals,
commercially available,
were purchased from Apollo Scientific, Sigma-Aldrich, Fluorochem,
or Manchester Organics and used without any further purification.
All reactions were carried out using anhydrous solvents. Analytical
thin-layer chromatography (TLC) was performed on precoated TLC plates
(layer 0.20 mm silica gel 60 with fluorescent indicator (UV 254: Merck)).
The TLC plates were air-dried and revealed under UV lamp (254/365
nm). Flash column chromatography was performed using prepacked silica
gel cartridges (230–400 mesh, 40–63 mm; SiliCycle) using
a Teledyne ISCO Combiflash Companion or Combiflash Retrieve using
the solvent mixtures stated for each synthesis as mobile phase. Liquid
chromatography–mass spectrometry (LC–MS) analyses were
performed with either an Agilent HPLC 1100 series connected to a Bruker
Daltonics MicroTOF or an Agilent Technologies 1200 series HPLC connected
to an Agilent Technologies 6130 quadrupole spectrometer or a Waters
2795 connected to a Waters ZQ Micromass spectrometer; all instruments
were connected to a diode array detector. All of the final compounds
used in all of the experiments were evaluated after preparative LC–MS
separations with a Waters X-bridge C18 column (50 mm × 2.1 mm
× 3.5 mm particle size); flow rate, 0.5 mL/min with a mobile
phase of water/MeCN + 0.1% NH4OH or water/MeCN + 0.1% CHOOH;
95/5 water/MeCN was initially held for 0.5 min followed by a linear
gradient from 95/5 to 5/95 water/MeCN over 3.5 min which was then
held for 2 min. The purity of all the compounds was evaluated using
the analytical LC–MS system described before, and purity was
>95%. 1H NMR and 13C NMR spectra were recorded
on a Bruker Avance II 500 spectrometer (1H at 500.1 MHz, 13C at 125.8 MHz) or on a Bruker DPX-400 spectrometer (1H at 400.1 MHz, 13C at 101 MHz). Chemical shifts
(δ) are expressed in ppm reported using residual solvent as
the internal reference in all cases. Signal splitting patterns are
described as singlet (s), doublet (d), triplet (t), multiplet (m),
or a combination thereof. Coupling constants (J)
are quoted to the nearest 0.1 Hz.
General Method A
To a mixture of aryl bromide (1 equiv)
in dioxane (0.2 M), Pd(dppf)Cl2 (0.1 equiv), bis(pinacolato)diboron
(1.2 equiv), and KOAc (3 equiv) were added. The mixture was heated
under microwave conditions at 140 °C for 40 min. Then aryl iodide 14 (1 equiv) and a degassed solution of K2CO3 2 M (2 equiv) were added. The reaction mixture was heated
in microwave at 120 °C for 30 min. The resulting mixture was
filtered through Celite and washed several times with DCM. The organic
phase was washed with H2O and brine, dried over MgSO4, filtered, and evaporated in vacuum. The crude was purified
by flash column chromatography using a gradient from 0% to 20% of
MeOH in DCM to obtain the desired compound. Then the intermediate
was taken up in a mixture 1:1 HCl 4 N in dioxane/DCM and stirred at
rt for 3 h. The solvents were evaporated to dryness to obtain the
desired compound as hydrochloride salt.
General Method B
To a solution of acid (1 equiv) in
DMF (0.2 M), HATU (1 equiv), HOAt (1 equiv), amine (1 equiv), and
DIPEA (5 equiv) were added. The reaction mixture was stirred at rt
for 2 h. The solvent was evaporated under reduced pressure to give
the corresponding crude, which was chromatographically purified to
yield the final compound.
General Method C
A mixture of aldehyde (1 equiv), amine
(HCl salt, 1.1 equiv), and TEA (1.1 equiv) in DMF (0.2 M) was stirred
at rt. After 15 min, NaBH(OAc)3 (1.5 equiv) was added,
and the reaction was stirred overnight at rt under nitrogen. The solvent
was evaporated under reduced pressure to give the corresponding crude,
which was purified accordingly to yield the desired compound.
General
Method D
To a stirred solution of oxalyl chloride
(1.5 equiv) in DCM (0.3 M), DMSO (2 equiv) was added dropwise at −78
°C. After 10 min at −78 °C, the alcohol starting
material (1 equiv) in DCM (0.3 M) was added. The reaction was stirred
at −78 °C for 1 h, TEA (10 equiv) was added dropwise,
and temperature was increased to rt. After 1 h, the reaction mixture
was diluted with DCM, washed with a saturated solution of ammonium
chloride. The organic phases were combined, washed with brine, dried
over MgSO4, filtered, and evaporated to dryness. Then the
crude was dissolved in DMF (0.05 M); 1c (1 equiv) and
TEA (1.1 equiv) were added. After 15 min, NaBH(OAc)3 was
added and the reaction mixture was stirred overnight at rt under nitrogen.
The solvent was evaporated under reduced pressure to give the corresponding
crude, which was purified by preparative HPLC to yield the desired
compound.
General Method E
To a solution of
the alcohol starting
material (1 equiv) and trimethylamine (1.5 equiv) in DCM (0.2 M),
methansulfonyl chloride (1.2 equiv) was added at 0 °C. The reaction
mixture was stirred at 0 °C for 3 h. The reaction was quenched
with a saturated solution of ammonium chloride and extracted with
DCM. The organic phases were combined, dried over MgSO4, filtered, and evaporated to dryness. The crude (1.5 equiv) was
suspended in DMF (0.2 M), and 2b–d inhibitor derivative (1 equiv) and K2CO3 (3
equiv) were added. The mixture was heated overnight at 70 °C.
The reaction mixture was diluted with water and extracted with DCM.
The organic phases were combined, dried over MgSO4, filtered,
and evaporated to dryness. The crude was purified by flash column
chromatography using a gradient from 0% to 20% of MeOH in DCM to yield
the desired compound.
General Method F
A 1 M aqueous solution
of HCl (1 mL)
was added to the VHL-acetal linker (0.06 mmol) in THF (1 mL). The
reaction mixture was heated at 50 °C for 2 h. The solvent was
evaporated under reduced pressure, and the product was extracted with
DCM/MeOH (9:1). The organic phases were combined, dried over MgSO4, filtered, and evaporated to dryness. The crude was used
directly without any further purification.
General method G
Aldehyde (1 equiv) was taken up in t-BuOH and water
(4:1) (0.3 M). Then 2-methyl-2-butene 2
M in THF (4 equiv) was added, followed by sodium phosphate dibasic
(1 equiv) and sodium chlorite (2 equiv). The reaction mixture was
stirred at rt for 4 h. A 1 M aqueous solution of HCl was added. The
product was extracted with DCM. The organic phases were combined,
dried over MgSO4, filtered, and evaporated to dryness.
The crude was used directly without any further purification.
Following general method C, compound 12 was obtained from 4-bromo-2,6-dimethoxybenzaldehyde
(11) and boc-piperazine (both commercially available).
The reaction was quenched with saturated solution of NaHCO3, extracted with DCM, washed with water and brine. The organic phases
were combined, dried over MgSO4, filtered, and evaporated
to dryness to give the desired compound without any further purification
as sticky oil. Yield: 495 mg, 97%. 1H NMR (500 MHz, CDCl3) δ: 6.69 (s, 2H), 3.78 (s, 6H), 3.62 (s, 2H), 3.38
(t, J = 5.0 Hz, 4H), 2.41 (t, J =
4.4 Hz, 4H), 1.43 (s, 9H). 13C NMR (125 MHz, CDCl3) δ: 159.9, 154.7, 122.8, 107.7, 79.8, 56.1, 51.8, 48.5, 31.0,
28.5. MS m/z calcd for C18H27BrN2O4 414.12, found 415.2 [M
+ H+].
4-Iodo-2-methyl-2,7-naphthyridin-1(2H)-one
(14)
A mixture of 4-iodo-2,7-naphthyridin-1(2H)-one 13 (synthesized accordingly to literature[74]) (1 equiv) and NaH (2 equiv) was stirred 30
min at 0 °C in DMF (0.2 M). Then CH3I (1.6 equiv)
was added and the reaction mixture was stirred at 0 °C for 5
h. Water was added, and the precipitate formed was filtered and dried
in vacuum. Yield: 300 mg, 95%. 1H NMR (400 MHz, DMSO) δ:
9.27 (s, 1H), 8.82 (d, J = 5.6 Hz, 1H), 8.26 (s,
1H), 7.47 (d, J = 5.5 Hz, 1H), 3.52 (s,3H). 13C NMR (101 MHz, DMSO) δ: 160.3, 152.0, 150.3, 144.8,
143.0, 122.4, 120.7, 67.9, 36.2. MS m/z calcd for C9H7IN2O 285.96, found
287.1 [M + H+].
A mixture of compound 17 (0.015 mmol), TFA (0.5 mL), and DCM (0.5 mL) was stirred at rt for
3 h. Then the solvent was evaporated; the crude was dried under high
pressure overnight and used directly in the next step without any
further purification. Quantitative yield. MS m/z calcd for C28H36N4O7 540.26, found 541.4 [M + H+].
A mixture of compound 18 (0.034 mmol), TFA (0.5 mL), and DCM (0.5 mL) was stirred at rt for
3 h. Then the solvent was evaporated; the crude was dried under high
pressure overnight and used directly without any further purification.
Quantitative yield. MS m/z calcd
for C34H48N4O10 672.34,
found 673.36 [M + H+].
A mixture of 35 (1 equiv),
osmium tetroxide 4% in H2O (0.2 equiv), sodium periodate
(4 equiv), pyridine (2 equiv) in dioxane/H2O (3:1) was
stirred at rt for 48 h. Then H2O was added to the reaction
and the product was extracted with DCM. The organic phases were combined,
dried over MgSO4, filtered, and evaporated to dryness.
The crude was dissolved in DCE, and a mixture of 1c (1
equiv) and TEA (1.1 equiv) in DCE (0.02 M) was added. After 15 min,
NaBH(OAc)3 was added and the reaction mixture was stirred
at rt for 4 h under nitrogen. The solvent was evaporated under reduced
pressure to give the corresponding crude, which was purified by HPLC
using a gradient of 5% to 95% v/v acetonitrile in 0.1% aqueous solution
of ammonia. Compound 23 was obtained as a white powder.
Yield: 6.9 mg, 54%. 1H NMR (400 MHz, CDCl3)
δ: 9.68 (s, 1H), 8.69 (d, J = 5.6 Hz, 1H),
8.66 (s, 1H), 7.41 (dd, J = 0.6, 5.6 Hz, 1H), 7.37–7.32
(m, 4H), 7.27 (s, 1H), 6.53 (s, 2H), 4.72 (t, J =
8.0 Hz, 1H), 4.59–4.49 (m, 3H), 4.35–4.29 (m, 1H), 4.07–3.95
(m, 3H), 3.85–3.80 (m, 8H), 3.67–3.55 (m, 8H), 3.43
(t, J = 6.4 Hz, 2H), 2.74–2.37 (m, 14H), 2.15–2.09
(m, 1H), 1.60–1.47 (m, 4H), 1.36–1.27 (m, 2H), 0.94
(s, 9H). 13C NMR (101 MHz, CDCl3) δ: 171.5,
170.9, 170.5, 168.6, 161.6, 159.8, 151.8, 151.1, 150.4, 148.6, 141.9,
138.3, 136.0, 131.7, 131.1, 129.6, 128.3, 120.6, 118.1, 117.6, 105.5,
71.4, 71.3, 70.6, 70.1, 58.6, 58.2, 57.2, 56.9, 56.1, 52.5, 51.7,
48.6, 43.4, 37.3, 36.1, 35.2, 29.4, 26.6, 26.0, 24.2, 16.2. HRMS m/z calcd for C53H70N8O9S 994.50, found 995.5178 [M + H+].
A mixture of 45 (1 equiv),
osmium tetroxide 4% in H2O (0.2 equiv), sodium periodate
(4 equiv), pyridine (2 equiv) in dioxane/H2O (3:1) was
stirred at rt for 48 h. Then H2O was added to the reaction
and the product was extracted with DCM. The organic phases were combined,
dried over MgSO4, filtered, and evaporated to dryness.
Then, following general method A, from the aldehyde derivative and 1c compound 31 was obtained after purification
by HPLC using a gradient of 5% to 95% v/v acetonitrile in 0.1% aqueous
solution of formic acid as white powder. Yield: 3.7 mg, 17%. 1H NMR (400 MHz, MeOD) δ: 9.55 (d, J = 0.7 Hz, 1H), 8.90 (s, 1H), 8.70 (d, J = 5.8 Hz,
1H), 7.76 (s, 1H), 7.64 (dd, J = 0.6, 5.8 Hz, 1H),
7.52 (d, J = 7.7 Hz, 1H), 7.08–7.01 (m, 2H),
6.81 (s, 2H), 4.65–4.60 (m, 2H), 4.53–4.41 (m, 3H),
4.27–4.25 (m, 2H), 4.02–3.61 (m, 29H), 2.96–2.76
(m, 10H), 2.51 (s, 3H), 2.27–2.21 (m, 1H), 2.15–2.08
(m, 1H), 2.04 (s, 3H), 1.06 (s, 9H). 13C NMR (101 MHz,
MeOD) δ: 174.4, 173.1, 172.3, 163.0, 161.0, 158.0, 152.8, 151.8,
151.3, 151.2, 149.1, 143.5, 139.0, 133.5, 132.8, 130.0, 128.4, 122.8,
121.7, 119.2, 119.1, 113.7, 106.6, 71.9, 71.6, 71.5, 71.4, 71.1, 70.9,
69.4, 60.7, 59.2, 58.1, 58.0, 56.6, 52.8, 49.8, 39.4, 38.9, 37.4,
36.5, 27.0, 22.3, 16.0. HRMS m/z calcd for C56H76N8O12S 1084.53, found 1085.5658 [M + H+].
2-(2-(Hex-5-en-1-yloxy)ethoxy)ethan-1-ol
(33)
To a suspension of NaH (2.5 equiv) in DMF
(1 M) and THF (1 M),
diethylene glycol (5 equiv) was added at 0 °C under nitrogen.
After 45 min 6-bromo-1-hexene (1 equiv) was added dropwise at 0 °C.
Then the ice bath was removed, and the reaction mixture was stirred
overnight at rt under nitrogen. Distillate water was added, and the
reaction mixture was acidified with HCl 1 M up to pH 2. The product
was extracted with CHCl3. The organic phases were combined,
dried over MgSO4, filtered, and evaporated to dryness.
The resulting oil was purified by flash column chromatography using
a gradient from 50% to 100% of ethyl acetate in heptane to obtain
the desired compound 33 as an oil. Yield: 552 mg, 49%. 1H NMR (400 MHz, CDCl3) δ: 5.85–5.74
(m, 1H), 5.03–4.96 (m, 1H), 4.96–4.91 (m, 1H), 3.75–3.56
(m, 8H), 3.46 (t, J = 6.7 Hz, 2H), 2.09–2.03
(m, 2H), 1.65–1.56 (m, 2H), 1.48–1.39 (m, 2H). 13C NMR (101 MHz, CDCl3) δ: 138.8, 114.7,
72.6, 71.5, 70.6, 70.3, 62.0, 33.6, 29.2, 25.5.
2-(2-(Hex-5-en-1-yloxy)ethoxy)acetic
Acid (34)
A mixture of 30 (1 equiv), BAIB (2.2
equiv), TEMPO (0.22 equiv)
in ACN/H2O (1:1) (0.5 M) was stirred overnight at rt. The
day after the solvent was evaporated, the crude was resuspended in
DCM and washed with H2O. The organic phases were combined,
dried over MgSO4, filtered, and evaporated to dryness.
The resulting product was purified by flash column chromatography
using a gradient from 0% to 20% of MeOH in DCM to obtain compound 34 as an oil. Yield: 472 mg, 81%. 1H NMR (400 MHz,
CDCl3) δ: 5.84–5.73 (m, 1H), 5.03–4.97
(m, 1H), 4.96–4.92 (m, 1H), 4.15 (s, 2H), 3.76–3.73
(m, 2H), 3.63–3.59 (m, 2H), 3.52 (t, J = 6.6
Hz, 2H), 2.10–2.03 (m, 2H), 1.65–1.57 (m, 2H), 1.49–1.40
(m, 2H). 13C NMR (101 MHz, CDCl3) δ: 173.2,
138.7, 114.8, 71.7, 71.6, 69.7, 69.1, 33.6, 28.9, 25.4.
Following general method B, compound 35 was obtained from compounds 34 and 2a (synthesized accordingly to literature[61]). The crude was purified by HPLC using a gradient of 5% to 95% v/v
acetonitrile in 0.1% aqueous solution of formic acid to obtain 35 as white powder. Yield: 14.7 mg, 30%. 1H NMR
(400 MHz, CDCl3) δ: 8.64 (s, 1H), 7.28–7.23
(m, 4H), 5.74–5.63 (m, 1H), 4.93–4.82 (m, 2H), 4.65
(t, J = 7.9 Hz, 1H), 4.49–4.21 (m, 4H), 4.03–3.85
(m, 3H), 3.59–3.47 (m, 5H), 3.40–3.34 (m, 2H), 2.47–2.39
(m, 4H), 2.06–1.91 (m, 3H), 1.54–1.45 (m, 2H), 1.37–1.29
(m, 2H), 0.87 (s, 9H). 13C NMR (101 MHz, CDCl3) δ: 171.6, 170.8, 150.7, 148.1, 138.7, 138.4, 132.0, 130.7,
129.6, 128.3, 114.8, 71.5, 71.4, 70.4, 70.3, 69.8, 58.6, 57.5, 56.7,
43.3, 36.0, 34.9, 33.6, 29.1, 26.5, 25.4, 16.0. MS m/z calcd for C32H46N4O6S 614.31, found 615.4 [M + H+].
2-(2-(Allyloxy)ethoxy)ethan-1-ol
(38)
To a mixture of NaOH (1 equiv) in dioxane
(0.3 M), diethylene glycol
(2 equiv) and allyl bromide (1 equiv) were added dropwise. The mixture
was heated overnight at 55 °C. Then the reaction mixture was
dried over MgSO4, filtered, and evaporated in vacuum. The
crude was purified by flash column chromatography using a gradient
from 50% to 100% of ethyl acetate in heptane to obtain compound 38 as an oil. Yield: 329 mg, 54%. 1H NMR (400 MHz,
CDCl3) δ: 5.90–5.80 (m, 1H), 5.21 (qd, J = 1.6, 17.2 Hz, 1H), 5.14–5.10 (m, 1H), 3.96 (td, J = 1.4, 5.7 Hz, 2H), 3.68–3.59 (m, 4H), 3.56–3.52
(m, 4H). 13C NMR (101 MHz, CDCl3) δ: 134.5,
117.3, 72.6, 72.2, 70.4, 69.4, 61.7.
3,6,9,12-Tetraoxapentadec-14-en-1-ol
(39)
Following the same procedure applied for
compound 38, from tetraethylene glycol and allyl bromide
compound 39 was obtained as oil. Yield: 3.29 g, 68%.
Analytical data matched
those previously reported.[75]
Following general method F, compound 69 was obtained from 67 (0.066 mmol) and directly
used in the next step without any further purification. MS m/z calcd for C30H39FN4O7S 618.15, found 619.3 [M + H+].
Following general method F, compound 70 was obtained from 68 (0.04 mmol) and directly
used in the next step without any further purification. MS m/z calcd for C31H41FN4O6S 616.27, found 617.3 [M + H+].
Following general method G, compound 71 was obtained from compound 69 (0.04 mmol)
and was used in the next step without any further purification. Quantitative
yield. MS m/z calcd for C30H39FN4O8S 634.25, found 635.3 [M
+ H+].
Following general method G, compound 72 was obtained from compound 70 (0.05 mmol)
and was used in the next step without any further purification. Quantitative
yield. MS m/z calcd for C31H41FN4O7S 632.27, found 633.3 [M
+ H+].
Biology. Cell Culture
Human cell
lines HeLa and Hek293
were purchased from ATCC and propagated in DMEM medium (Gibco), supplemented
with 10% fetal bovine serum (FBS) (Gibco), l-glutamine (Gibco),
100 μg mL–1 of penicillin/streptomycin. RI-1
cells, purchased from DSMZ, were propagated in RPMI medium (Gibco),
supplemented with 10% fetal bovine serum (FBS) (Gibco), l-glutamine, 100 μg mL–1 of penicillin/streptomycin.
Cells were kept at 37 °C and 5% of CO2. EOL-1 and
A-204 cell lines were purchased from ATCC and DSMZ. EOL-1 cells were
grown in RPMI supplemented with 10% fetal calf serum. A-204 cells
were grown in McCoy’s medium supplemented with 10% fetal calf
serum. All cell lines were routinely tested for mycoplasma contamination
using MycoAlert kit from Lonza.
Testing Compounds in Cells
HeLa and Hek293 cells were
seeded at either 0.3 × 106 or 0.5 × 106 cells per well in 6-well plate in 2 mL of medium. At 80% confluency,
cells were treated with compounds at the desired concentration, with
final DMSO concentration of 0.1% v/v. Cells were incubated at 37 °C
and 5% of CO2 for the desired time before harvesting. For
protein extraction from adherent cells, cells were washed twice with
DPBS (Gibco) and lysed with RIPA buffer (Sigma-Aldrich), supplemented
with cOmplete Mini EDTA-free protease inhibitor cocktail (Roche).
Insoluble material was removed by centrifugation at 14 000
rpm for 15 min at 4 °C. Supernatant was collected and protein
concentration was quantified by Bradford assay (Thermo Scientific
no. 23200, mean of two replicates). For RI-1 cells, (1–1.5)
× 106 cells/mL were seeded in 6-well plate in 2 mL
of medium. The day after, cells were treated with compounds at the
desired concentration, with final DMSO concentration of 0.1% v/v.
Before harvesting, cells were incubated at 37 °C and 5% CO2 for the desired time. Cells were washed twice with DPBS (Gibco)
and lysed with RIPA buffer (Sigma-Aldrich), supplemented with cOmplete
Mini EDTA-free protease inhibitor cocktail (Roche). Lysates were sonicated
(10 s) and centrifuged at 14 000 rpm for 20 min at 4 °C.
Supernatant was collected, and protein concentration was quantified
by Bradford assay (mean of two replicates). For EOL-1 and A-204 cell
line, 20 000 cells were seeded in 300 μL per well in
a 24-well plate and incubated at 37 °C overnight. Compounds were
added from DMSO stock solution using a digital dispenser D300 (Tecan),
normalizing for added DMSO, and cells were incubated at 37 °C
for 18 h. Medium was removed, and cells were washed with PBS and lysed
in 80 μL of lysis buffer (1% Triton, 350 mM KCl, 10 mM Tris,
pH 7,4, phosphatase-protease inhibitor cocktail (Thermo Scientific
no. 1861281), 10 mM DTT, Benzonase 0.5 μL/ml (Novagen no. 70746
10KU, 25 U/μL)) for 30 min on ice before insoluble debris was
pelleted by centrifugation.
Small Interfering RNA
HeLa cells were seeded at 0.3
× 106 cells per well in 6-well plates in 2 mL of medium,
with a goal to achieve 70% of confluence on the day of transfection.
BRD7, BRD9, and CRBN targeting siRNA (L-020297-00-0005 ON-TARGETplus
human BRD7, L-014250-02-0005 ON-TARGETplus human BRD9, and L-021086-00-0005
ON-TARGETplus human CRBN SMARTpool, 5 nmol, Dharmacon) were prepared
as a 20 μM solution in RNase-free 1× siRNA buffer (Dharmacon).
Nontargeting siRNA (On-TARGETplus control pool, nontargeting pool
D-001810-10-05, 5 nmol, Dharmacon) was used as negative control. Medium
was replaced on the day of transfection. siRNA solution (5 μL)
of BRD7, BRD9, or CRBN targeting siRNA, negative control, and vehicle
control (1× siRNA buffer) were added to 250 μL of Opti-mem
(Gibco), prepared in duplicate. Lipofectamine RNAiMax (5 μL,
Thermo Fisher Scientific) was added to 250 μL of Opti-mem in
another tube, also in duplicate. The two solutions were combined,
incubated for 20 min at rt, and added to the wells. Plates were incubated
at 37 °C and 5% CO2 for 48 h before harvesting as
described above.
Mechanistic Evaluation
Cells were
seeded in 6-well
plates with 5 × 105 cells per well in 2 mL of complete
medium to aim for 80% confluence on the day of treatment. At time
zero, ML4924 was added at final concentration of 3 μM with 0.1%
v/v of DMSO. DMSO was added to the remaining wells in order to match
concentration of vehicle in all wells. After 3 h, MG132 (50 μM)
or VH298 (100 μM) was added to the designated wells at a final
concentration of 0.1% v/v of DMSO. Again, DMSO was added to the remaining
wells to match vehicle concentration. At t = 3.5
h, VZ185 or cisVZ185 was added at 100 nM and 0.1%
v/v of DMSO, matching the DMSO concentration in the remaining wells
(final concentration 0.3% v/v). Plates were incubated for an additional
4 h at 37 °C and 5% CO2 before harvesting as described
before. The experiment was performed in duplicate.
Immunoblotting
Proteins were resolved by SDS–PAGE
on NuPage 4–12% Bis-Tris Midi Gel (Invitrogen) and transferred
to Amersham Protran 0.45 NC nitrocellulose membrane (GE Healthcare)
using wet transfer. The membrane was blocked with 5% w/v milk in Tris-buffered
saline (TBS) with 0.1% w/v Tween-20. The following primary antibodies
at the given concentration were used: anti β-actin (Cell Signaling
Technology, 4970S, 13E5) 1:2000, anti-Brd9 (Bethyl A303-781A) 1:1000,
anti-Brd7 (Bethyl A302-304A) 1:1000, VHL rabbit Ab (Cell Signaling
Technology, no. 68547S) 1:1000, anti-CRBN (Novus Bio, NBP 1-9-1810)
1:1000, anti-actin hFAB rhodamine antibody, Bio-Rad, no. 12004164.
Following incubation with horseradish peroxidase-conjugated secondary
antibody (Cell Signaling Technology) or IRDye secondary antibody (Licor),
bands were developed using Amersham ECL Prime Western blotting detection
kit on Amersham Hyperfilm ECL film (Amersham) or ChemiDoc imaging
system (Bio-Rad). ImageJ software was used for band quantification,
and the last was reported as relative amount as ratio of each protein
band relative to the lane’s loading control. Then the values
obtained were normalized to 0.1% DMSO vehicle control. Alternatively,
protein levels were determined on a WES capillary electrophoresis
instrument (Proteinsimple) using a BRD9 antibody (Bethyl A303-781A)
and a GAPDH antibody (Abcam no. ab9485) for normalization. DC50 and half-lives were determined by assuming a linear model
between the two data points across 50% protein level mark.
Proliferation
Assays
A-204 cells (1 × 103) were seeded
per well of 384-well plates. After overnight incubation,
compounds were added to the cells at logarithmic dose series using
the HP digital dispenser D300 (Tecan), normalizing for added DMSO.
1 day and 8 days after seeding cellular ATP content was measured using
CellTiterGlo (Promega). Measurements after 8 days were divided by
the measurement after 1 day (i.e., the T0 plate) to derive fold proliferation. Data were analyzed with GraphPad
Prism software to obtain EC50 values.
MS Proteomics
Sample
Preparation
RI-1 cells were seeded at 2 ×
106 cells/mL in a 10 cm plate 12 h before treatment. Cells
were treated with 0.1% DMSO as vehicle control and with 100 nM VZ185
and 100 nM cisVZ185 as negative control. Cells were
incubated at 37 °C and 5% CO2 for 4 h before harvesting.
Cells were washed twice with DPBS (Gibco) and lysed with 0.5 mL of
100 mM Tris, pH 8.0, 4% (w/v) SDS, supplemented with cOmplete Mini
EDTA-free protease inhibitor cocktail (Roche). Lysates were sonicated
(2 × 10 s) and centrifuged at 14 000 rpm for 20 min at
4 °C. The supernatant fraction of the cell extract was collected,
and protein concentration was quantified by BCA assay (Thermo Fisher
Scientific). Further sample processing, digestion, desalting, TMT
10-plex isobaric labeling were performed as previously described.[5] After labeling, the peptides from the 9 samples
were pooled together in equal proportion. The pooled sample was fractionated
into 20 discrete fractions using high pH reverse-phase chromatography
on an XBridge peptide BEH column (130 Å, 3.5 μm, 2.1 mm
× 150 mm, Waters) on an Ultimate 3000 HPLC system (Thermo Scientific/Dionex).
A mixture of buffer A (10 mM ammonium formate in water, pH 9) and
B (10 mM ammonium formate in 90% CH3CN, pH 9) was used
over a linear gradient of 5% to 60% buffer B over 60 min at a flow
rate of 200 μL/min. The peptides eluted from the column were
collected in 80 fractions before concatenation into 20 fractions based
on the UV signal of each fraction. All the fractions were dried in
a Genevac EZ-2 concentrator and resuspended in 1% formic acid for
MS analysis.
nLC–MS/MS Analysis
The fractions
were analyzed
sequentially on a Q Exactive HF hybrid quadrupole-Orbitrap mass spectrometer
(Thermo Scientific) coupled to an UltiMate 3000 RSLCnano UHPLC system
(Thermo Scientific) and EasySpray column (75 μm × 50 cm,
PepMap RSLC C18 column, 2 μm, 100 Å, Thermo Scientific).
A mix of buffer A (0.1% formic acid in H2O) and B (0.08%
formic acid in 80% CH3CN) was used over a linear gradient
from 5% to 35% buffer B over 125 min using a flow rate of 300 nL/min.
Column temperature was set at 50 °C. The Q Exactive HF hybrid
quadrupole-Orbitrap mass spectrometer was operated in data dependent
mode with a single MS survey scan from 335 to 1600 m/z followed by 15 sequential m/z dependent MS2 scans. The 15 most intense precursor ions
were sequentially fragmented by higher energy collision dissociation
(HCD). The MS1 isolation window was set to 0.7 Da and the resolution
set at 120 000. MS2 resolution was set at 60 000. The
AGC targets for MS1 and MS2 were set at 3e6 ions and 1e5 ions, respectively.
The normalized collision energy was set at 32%. The maximum ion injection
times for MS1 and MS2 were set at 50 and 200 ms, respectively.
Peptide
and Protein Identification and Quantification
The raw MS
data files for all 20 fractions were merged and searched
against the Uniprot-sprot-Human-Canonical database by Maxquant software
1.6.0.16 for protein identification and TMT reporter ion quantitation.
The identifications were based on the following criteria: enzyme used
trypsin/P; maximum number of missed cleavages equal to 2; precursor
mass tolerance equal to 10 ppm; fragment mass tolerance equal
to 20 ppm. Variable modifications: oxidation (M), acetyl (N-term),
deamidation (NQ), Gln → pyro-Glu (Q N-term). Fixed modifications:
carbamidomethyl (C). The data were filtered by applying a 1% false
discovery rate followed by exclusion of proteins with less than two
unique peptides. Quantified proteins were filtered if the absolute
fold-change difference between the three DMSO replicates was
≥1.5.
Protein Expression and Purification
Human proteins
VHL (UniProt accession number P40337), ElonginC (Q15369), and ElonginB
(Q15370) and the bromodomain (residues 134–239) for BRD9 (Q9H8M2)
were used for all protein expression. His6-tagged constructs
were transformed into Escherichia coli BL21(DE3),
and expression was induced by the addition of isopropyl β-d-1-thiogalactopyranoside (IPTG). E. coli cells
were lysed using a pressure cell homogenizer (Stansted Fluid Power);
lysates were clarified by centrifuge and loaded onto a HisTrap FF
affinity column (GE Healthcare). Following elution, His-tags were
removed with TEV protease and samples were loaded onto a second Ni
affinity column to obtain tag-free protein. Following dialysis in
a low-salt buffer, BRD9 bromodomain and VCB complex proteins were
further purified using cation exchange (Resource S; GE Healthcare)
or anion exchange (Resource Q; GE Healthcare) chromatography, respectively.
This was followed by a final polish by size-exclusion chromatography
using a Superdex-75 16/600 column (GE Healthcare) equilibrated with
20 mM HEPES, pH 7.5, 100 mM sodium chloride, and 1 mM
TCEP.
Crystallization and Structure Solution of BRD9 Bromodomain Binary
Complex
The binary complex of Brd9-BD:5 was
generated by incubating 500 μM Brd9 bromodomain with 750 μM
compound 5 (from a 100 mM stock in DMSO). Crystals were
grown using the hanging-drop vapor diffusion method by mixing equal
volumes of binary complex solution and a crystallization solution
containing 24% PEG 3350 and 0.2 M NH4F. Small needle crystals
appeared within 48 h but took approximately 2 weeks to reach a suitable
size for harvesting. Crystals were flash-frozen in liquid nitrogen
using 20% ethylene glycol in liquor solution as a cryoprotectant.
Diffraction data were collected at Diamond Light Source beamline I24
using a Pilatus 6M-F detector at a wavelength of 0.98962 Å. Data
were indexed and integrated using XDS,[78] and scaling and merging were performed with AIMLESS[79] in CCP4i.[80] The structure was
solved by molecular replacement using MOLREP[81] and a search model derived from a BRD9 bromodomain structure (PDB
entry 5I40).
The initial model underwent iterative rounds of model building and
refinement with COOT[82] and REFMAC5,[83] respectively. Compound 5 geometry
restraints for refinement were prepared with the PRODRG[84] server. Model geometry and steric clashes were
validated using the MOLPROBITY server;[85] Ramachandran plots indicate that 97.7% of backbone torsion angles
are in the favored region and there are no outliers. The structure
has been deposited in the Protein Data Bank (PDB) with accession code 6HM0; data collection
and refinement statistics are presented in Supporting Information Table S1.
AlphaLISA Proximity Assay
All assays were performed
at room temperature in 384-well plates with a final assay volume of
25 μL per well, as described previously.[5] All reagents were prepared as 5× stocks diluted in
50 mM HEPES, pH 7.5, 100 mM NaCl, 0.1% (w/v) bovine
serum albumin, and 0.02% (w/v) 3-[(cholamidopropyl)dimethylammonio]-1-propanesulfonate
(CHAPS). Plates were sealed by transparent film and briefly centrifuged
at 100g between additions of reagents. Biotinylated
VCB (100 nM final) and His6-BRD9-bromodomain (100 nM
final) were incubated with a range of PROTAC concentrations (0.5–2000 nM;
two-in-one serial dilution) for 1 h. Streptavidin-coated donor
beads and nickel chelate acceptor beads (PerkinElmer) were added to
a final concentration of 10 μg mL–1, and plates were incubated for another hour. Plates were read on
a PHERAstar FS (BMG Labtech) using an optic module with an excitation
wavelength of 680 nm and emission wavelength of 615 nm.
Intensity values were plotted against PROTAC concentration on a log10 scale using GraphPad Prism, version 7. To obtain biotinylated-VCB,
protein was mixed with EZ-link NHS-PEG4-biotin (Thermo
Scientific) in a 1:1 molar ratio and incubated at room temperature
for 1 h. The reaction was quenched using 1 M Tris-HCl, pH 7.5,
and unreacted NHS-biotin was removed with a PD-10 MiniTrap desalting
column (GE Healthcare) equilibrated with 20 mM HEPES, pH 7.5,
150 mM NaCl, and 1 mM DTT.
Fluorescence Polarization
All measurements were taken
using a PHERAstar FS (BMG LABTECH) with fluorescence excitation and
emission wavelengths (λ) of 485 and 520 nm, respectively. FP
competitive binding assays were run in triplicate in 384-well plates
(Corning 3575) using a total well volume of 15 μL (ref (63)). Each well solution contained
15 nM VCB protein, 10 nM FAM-labeled HIF-1α peptide (FAM-DEALAHypYIPMDDDFQLRSF, Kd = 3 nM as measured by a direct FP titration),
and decreasing concentrations of PROTAC (14-point serial 2-fold dilutions
starting from 50 μM PROTAC) or PROTAC:bromodomain (14-point
serial 2-fold dilutions starting from 50 μM PROTAC:100 μM
bromodomain into wells containing an additional 1 μM bromodomain)
in 100 mM Bis-Tris propane, 100 mM NaCl, 1 mM TCEP, pH 7, with a final
DMSO concentration of 1%. Control wells containing VCB and peptide
with no compound (zero displacement), or peptide in the absence of
protein (maximum displacement), were also included. Control values
were used to obtain the percentage of displacement which was graphed
against log[PROTAC]. Average IC50 values and the standard
error of the mean (SEM) were determined for each titration using Prism
7. Dissociation constants Kd were back-calculated
from the measured IC50 values using a displacement binding
model, as described previously.[68]
Isothermal
Titration Calorimetry
ITC experiments were
performed in an ITC200 microcalorimeter (GE Healthcare) as described
previously.[5] Titrations were carried out
at 25 °C while stirring at 750 rpm and were performed as reverse
mode (protein in the syringe and the ligand in the cell). Compounds
were diluted in ITC buffer (20 mM Bis-Tris propane, 100 mM NaCl, 1
mM tris(2-carboxyethyl)phosphine (TCEP), pH 7.5) from 10 mM
DMSO stock solutions to a final concentration of 20 μM (0.2%
DMSO). Each run consisted of 19 injections of 2 μL of protein
solution (ITC buffer with 0.2% DMSO) at a rate of 0.5 μL/s at
120 s time intervals. An initial injection of 0.4 μL was made
and discarded during data analysis. BRD9 bromodomain (200 μM,
in the syringe) was first titrated into the PROTAC (20 μM, in
the cell); at the end of the titration, the excess of solution was
removed from the cell and the syringe was washed and dried. VCB complex
(168 μM, in the same buffer) was loaded in the syringe and titrated
into the complex PROTAC-bromodomain. The concentration of the complex
in the cell (C) after the first titration (16.8 μM),
was calculated as follows:where C0 is the
initial concentration of the PROTAC in the cell (20 μM), Vcell is the volume of the sample cell (200.12
μL), and Vinj is the volume of titrant
injected during the first titration (38.4 μL). Titrations for
the binary complex PROTAC-VCB were performed by first adding buffer
(38.4 μL) to the solution of PROTAC (20 μM, in the cell)
by a single ITC injection. After removal of the excess solution from
the cell, VCB complex (168 μM, in the same buffer) was loaded
into the (washed and dried) syringe and titrated into the diluted
PROTAC solution. The data were fitted to a single binding-site model
using the MicroCal PEAQ-ITC analysis software provided by the manufacturer
to obtain the stoichiometry n, the dissociation constant Kd, and the enthalpy of binding ΔH.
Live Cell Kinetic Analysis of BRD7 and BRD9
Degradation
HEK293 cells stably expressing LgBiT protein
cultured in DMEM (Gibco)
supplemented with 10% fetal bovine serum (Seradigm) and maintained
at 37 °C and 5% CO2 were genome-edited using CRISPR/Cas9
to generate endogenous HiBiT-BRD7 or HiBiT-BRD9 fusions. Clonal populations
were isolated, and cells were plated in 96-well tissue culture plates
at a density of 2 × 104 cells per well in 100 μL
of growth medium. Following overnight incubation at 37 °C and
5% CO2 medium was replaced with CO2-independent
medium (Gibco) containing 20 μM Endurazine, an extended time-released
substrate (Promega), and plates were incubated at 37 °C, 5% CO2, for 2.5 h before addition of a 3-fold serial dilution of
1 μM final concentration VZ185 compound. Plates retaining the
plate lids were then read every 5 min for a period of 24 h on a GloMax
Discover (Promega) set to 37 °C. Degradation traces for each
concentration were plotted in GraphPad Prism, and the degradation
portion of each curve was fitted to a one-component exponential decay
model to obtain degradation parameters, rate, and Dmax, as previously described.[69]
NanoBRET Ubiquitination of BRD7 and BRD9
Clonal populations
of edited HEK293 cells expressing HiBiT-BRD7 or HiBiT-BRD9 were plated
in tissue 96-well tissue culture plates at a density of 2 × 104 cells per well in 100 μL of growth medium and incubated
overnight at 37 °C, 5% CO2. Following treatment with
1 μM VZ185 for the indicated time frames, medium was replaced
with Opti-MEM (Gibco) containing 200 μg/mL digitonin, 1:200
dilution of primary anti-Ub antibody (Enzo Life Sciences, BML-PW8810),
1:500 dilution of secondary anti-mouse Alexa 594 antibody (Cell Signaling
Technologies, 8890), and 20 μM NanoGlo (Promega) substrate.
Additional control wells received no antibodies (control for background
NanoBRET) or no primary antibody (control for specificity). Plates
were placed on an orbital shaker for 10 min, and NanoBRET measurements
were collected on a CLARIOstar (BMG Labtech). Background subtracted
NanoBRET ratios were generated by calculating the ratios of acceptor
signal to donor signal in both the presence and absence of the Alexa594
antibody and computing the difference. Background subtracted BRET
ratios were expressed in milliBRET units by multiplying by 1000.
Authors: Deng Pan; Aya Kobayashi; Peng Jiang; Lucas Ferrari de Andrade; Rong En Tay; Adrienne M Luoma; Daphne Tsoucas; Xintao Qiu; Klothilda Lim; Prakash Rao; Henry W Long; Guo-Cheng Yuan; John Doench; Myles Brown; X Shirley Liu; Kai W Wucherpfennig Journal: Science Date: 2018-01-04 Impact factor: 47.728
Authors: Jing Lu; Yimin Qian; Martha Altieri; Hanqing Dong; Jing Wang; Kanak Raina; John Hines; James D Winkler; Andrew P Crew; Kevin Coleman; Craig M Crews Journal: Chem Biol Date: 2015-06-04
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Authors: Christian Steinebach; Stefanie Lindner; Namrata D Udeshi; Deepak C Mani; Hannes Kehm; Simon Köpff; Steven A Carr; Michael Gütschow; Jan Krönke Journal: ACS Chem Biol Date: 2018-09-05 Impact factor: 5.100
Authors: Terry D Crawford; Steffan Vartanian; Alexandre Côté; Steve Bellon; Martin Duplessis; E Megan Flynn; Michael Hewitt; Hon-Ren Huang; James R Kiefer; Jeremy Murray; Christopher G Nasveschuk; Eneida Pardo; F Anthony Romero; Peter Sandy; Yong Tang; Alexander M Taylor; Vickie Tsui; Jian Wang; Shumei Wang; Laura Zawadzke; Brian K Albrecht; Steven R Magnuson; Andrea G Cochran; David Stokoe Journal: Bioorg Med Chem Lett Date: 2017-06-03 Impact factor: 2.823
Authors: Martyn D Winn; Charles C Ballard; Kevin D Cowtan; Eleanor J Dodson; Paul Emsley; Phil R Evans; Ronan M Keegan; Eugene B Krissinel; Andrew G W Leslie; Airlie McCoy; Stuart J McNicholas; Garib N Murshudov; Navraj S Pannu; Elizabeth A Potterton; Harold R Powell; Randy J Read; Alexei Vagin; Keith S Wilson Journal: Acta Crystallogr D Biol Crystallogr Date: 2011-03-18
Authors: Lara N Gechijian; Dennis L Buckley; Matthew A Lawlor; Jaime M Reyes; Joshiawa Paulk; Christopher J Ott; Georg E Winter; Michael A Erb; Thomas G Scott; Mousheng Xu; Hyuk-Soo Seo; Sirano Dhe-Paganon; Nicholas P Kwiatkowski; Jennifer A Perry; Jun Qi; Nathanael S Gray; James E Bradner Journal: Nat Chem Biol Date: 2018-03-05 Impact factor: 15.040
Authors: Christian Steinebach; Izidor Sosič; Stefanie Lindner; Aleša Bricelj; Franziska Kohl; Yuen Lam Dora Ng; Marius Monschke; Karl G Wagner; Jan Krönke; Michael Gütschow Journal: Medchemcomm Date: 2019-05-28 Impact factor: 3.597
Authors: James Schiemer; Reto Horst; Yilin Meng; Justin I Montgomery; Yingrong Xu; Xidong Feng; Kris Borzilleri; Daniel P Uccello; Carolyn Leverett; Stephen Brown; Ye Che; Matthew F Brown; Matthew M Hayward; Adam M Gilbert; Mark C Noe; Matthew F Calabrese Journal: Nat Chem Biol Date: 2020-11-16 Impact factor: 15.040
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