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EXPERT OPINION ON DRUG DISCOVERY
INVITED REVIEW
Induced degradation of protein kinases by bifunctional small molecules:
a next-generation strategy
Sole author:
Jay C. Groppe, PhD
Associate Professor
Department of Biomedical Sciences
Texas A&M University College of Dentistry
Dallas, TX 75246
mobile (210) 332-8059
office (214) 370-7203
fax (214) 874-4538
https://dentistry.tamhsc.edu/bms/facultystaffstudents/faculty/groppe.html
ARTICLE HISTORY
Received 2 January 2019
Accepted 23 August 2019
https://doi.org/10.1080/17460441.2019.1660641
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REVIEW
Induced degradation of protein kinases by bifunctional small molecules:
a next-generation strategy
ABSTRACT
Introduction: Protein kinases are a major target for small-molecule drug development.
However, relatively few compounds are free of off-target toxicity and reach the clinic. Because
the 500-plus kinases share conserved ATP-binding clefts, the site targeted by competitive
inhibitors, generation of specific therapeutics remains a nearly intractable challenge.
Areas covered: Inducing degradation, instead of inhibition by occupancy-driven drugs, is an
emerging strategy that offers the long-sought specificity, as well as mechanistic benefits.
Currently approved inhibitors require steady-state binding and leave proteins intact for
interactions in multi-protein complexes. After a general background about induced protein
degradation, perspectives on protein kinases are provided.
Expert opinion: Induced degradation by state-of-the-art compounds (proteolysis-targeting
chimeras, PROTACs) has been shown for protein kinases, albeit in early pre-clinical stages.
Further work is required to expand the number of enzymes that could be exploited to direct
proteins for degradation by ubiquitylation. In addition, despite the simple modularity of the
chimeras, generation of hits will require empirical approaches due to the role of protein-protein
interactions and distribution of tagging sites. However, given the advantages of degradation,
drug discovery efforts targeting protein kinases should increasingly shift toward generation and
screening of inducers of degradation and away from occupancy-based inhibitors of old.
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KEYWORDS
ALK2, BMP signaling inhibition, cereblon, E3 ubiquitin ligase, H-SAAD/D, HyT, PROTAC,
induced protein degradation, protein kinase inhibition, von Hippel-Lindau VHL
Article highlights
1. Induced degradation of proteins by novel small molecules is an unconventional approach for
down-regulation of targets offering significant advantages over occupancy-driven inhibition.
2. Arising from initial unanticipated effects two decades ago, the field has evolved to current
structure-based, rational designs of modular small-molecule degraders of specific targets.
3. Proteolysis-targeting chimeras, or PROTACs, are optimized hetero-bifunctional inducers of
protein degradation that are rapidly emerging as a next-generation strategy or drug modality.
4. Examples are given of PROTACs that have been produced to target protein kinases; the first
bona fide composition was developed by the Crews laboratory at Yale and published in 2015.
5. Because protein kinases, in particular those involved in signaling, form complexes, a case is
made for PROTACs directed to a Ser-Thr receptor kinase (Activin receptor-like kinase 2)
that forms a hetero-tetrameric complex, which affords manifold opportunities for quenching
dysregulated signaling by mutant ALK2, an aim of at least six pharmaceutical companies.
6. Though proof-of-concept has been established for application of the PROTACs methodology
to protein kinase targets, technological hurdles remain to be surmounted, and each case
appears to require a systematic, empirical design approach, hence possibly labor-intensive.
7. Nevertheless, given that the field has only recently come of age and shown such significant
promise, and that the large and important family of protein kinases has remained relatively
untapped with respect to drugs reaching the clinic, induced degradation by novel chimeras is
expected to become a next-generation approach to be vigorously pursued in drug discovery.
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1. Introduction
Induced protein degradation by small molecules, an alternative to occupancy-driven inhibition,
has steadily grown as an attractive, promising drug discovery avenue over the last two decades.
Perturbation of homeostasis and turnover of specific proteins by means of induced degradation is
an event-driven strategy (Table 1), thus comparable to other down-regulation methods such as
gene silencing and editing [1, 2]. Rather than simply inhibiting phosphotransferase activity
through steady-state occupancy of binding sites (active or allosteric), the small molecules serve
as non-stoichiometric cofactors in cycles of catalytic degradation of the targeted proteins, an
irreversible process. Thus, small molecule inducers of protein degradation would be anticipated
to show dramatically different activities relative to their traditional counterparts on both the
molecular and cellular levels.
Mechanisms of inhibition for therapeutic intervention
Occupancy-driven Event-driven
Protein-binding Molecular-genetic modification of
nucleic acids Inhibitors of activity Inducers of degradation
Non-covalent active site inhibitors (competitive)
Covalent active site inhibitors
(suicide)
Allosteric destabilizers
e.g. H-SAAD/Ds
Gene editing:
e.g. CRISPR-Cas9
Non-covalent allosteric site inhibitors
Covalent allosteric site inhibitors
(suicide)
Active- or ligand-binding site destabilizers
and/or degraders e.g. PROTACs
Gene-silencing RNAs:
anti-sense
micro
small-interfering
Protein-Protein Interaction (PPI)
Table 1. Mechanisms of action underlying inhibition of cellular processes in drug discovery,
comparing occupancy-driven with event-driven methods, protein-binding inhibitors with
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nucleic acid targeting techniques, covalent with non-covalent inhibitors of enzyme activity or
protein-protein interactions and two disparate types of inducers of protein degradation. See
Expert Opinion section for further comparison and discussion.
Though not a new concept (cf. 2.1 – 2.3), during just the last several years, the field has
undergone a renaissance, due in large part to the innovation of hetero-bifunctional inducers of
protein degradation, particularly proteolysis-targeting chimeras (PROTACs). Therapeutics that
inhibit through degradation of proteins implicated in the pathology of diseases and disorders are
already FDA-approved, including lenalidomide, which serendipitously targets a protein kinase
(casein kinase 1) along with two lymphoid transcription factors (see below) [3]. Many others
are in drug development pipelines as representatives of a cutting-edge approach in the
pharmaceutical industry [4]. To date, most inducers of protein degradation are arising from
small start-up companies that are invested in or acquired by the larger pharmaceutical concerns.
For example, in July 2014 in an agreement worth up to $1.725 billion, Genentech acquired
Seragon Pharmaceuticals, a developer of selective estrogen receptor degraders (SERDs, cf. 2.2),
to diversify the portfolio of the parent company Roche of hormone-receptor positive breast
cancer drugs. In announcements, Genentech has metaphorically described the mechanism of
action of the degraders as “designed to work by throwing the key driver of disease into what is
essentially a cellular garbage can” (the proteasome complex).
The more recently developed and far more widely applicable inducers of degradation, the
above-mentioned PROTACs, originated in academic laboratories (Craig Crews, Yale; Raymond
Deshaies, Cal Tech; Jay Bradner, Dana-Farber; Alessio Ciulli, Dundee; Nathanael Gray,
Harvard; and others) and now are undergoing preclinical advancement at recently launched
spinout companies such as Arvinas (New Haven, CT in 2013), C4 Therapeutics (Cambridge, MA
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in 2016), Kymera Therapeutics, Cambridge, MA 2017) and Captor Therapeutics (Wroclaw,
Poland and Allschwil, Switzerland in 2017) [5]. As a reflection of burgeoning interest in the
promising therapeutic avenue by industry, in just the last three years, three major pharmaceutical
companies have poured large capital into Arvinas alone: (1) Merck, up to $434 million (2015),
(2) Genentech/Roche, more than $300 million (2015) and (3) Pfizer, up to more than $830
million (2018) [6]. Both C4 and Kymera Therapeutics have also announced similar partnerships
in the short time since inception of these academic spinoffs.
Big pharma, which could usher inducers of protein degradation through clinical trials, has
good reason to be optimistic, as evidenced by the success of lenalidomide. Marketed as an IMiD
or immunomodulatory drug by Celgene, the drug is a blockbuster that was not found through
design but by chance. The IMiD lenalidomide, an analog of the banned drug thalidomide, binds
the specificity-imparting recognition interface of an E3 ubiquitin ligase complex (RING-type,
EC 2.3.2.27, as opposed to HECT-type, EC 2.3.2.26) [7], antagonizing the ubiquitylation of
endogenous substrates. In addition, however, the IMiD acts as a “molecular glue” that
unexpectedly redirects the E3 ligase by forming cryptic interfaces which promote recruitment of
clinically important targets [two lymphoid transcription factors, Ikaros (IKZF1) and Aiolos
(IKZF3), as well as the a protein kinase (casein kinase 1)]. Thus due to this serendipitous
neofunction, lenalidomide can act as a cofactor, rather than an inhibitor, in ubiquitylation and
targeted degradation of the proteins [8, 9]. With indications for multiple hematological disorders
(myelodysplastic syndromes MDS), the lenalidomide topped the list of ten best-selling cancer
drugs of Q1 – Q3 of 2017 [10]. Note that only two of the top ten were conventional small
molecule kinase inhibitors. Monoclonal antibodies (biologics) made up half the list. Another
was also a biologic, a growth factor for a blood cell disorder, neutropenia. The tenth was an
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inhibitor of protein degradation (proteasomal), meaning that of the top-ten cancer drugs, two
were regulators of protein turnover (one positive, one negative).
Because Crews et al. and a host of others worldwide have authored numerous in-depth
reviews focused on the chimeric degraders specifically and on induced protein degradation in
general [2, 9, 11-16], in addition to seminal publications marking milestones in the development
of PROTACs, this expert opinion will aim to draw attention to a specific promising application.
Hence following presentation of a concise history of the topic to provide background and
context, the review will focus on a subset of pharmacological targets, the protein kinase family,
with perspectives on early efforts, current advances and the challenges and opportunities going
forward with development of efficacious inducers of kinase degradation.
2. Induced protein degradation by small molecules mediated by chaperones
2.1 Human epidermal growth factor receptor 2 (HER2) and EGFR: HSP90 chaperone-based
mechanisms
Twenty years ago, a new class of inhibitor targeting tyrosine kinase receptors (EC 2.7.10.1) for
growth factors was identified. Some irreversible inhibitors of HER2/Erb-2 [17] were found to
increase both ubiquitylation and endocytosis of the receptor kinase, leading to intracellular
destruction of the proteins. Increased antitumor effects were observed in animals that appeared
to stem from degradation rather than simple inactivation [18-20]. Though the degradative
pathway was mediated by chaperones such as heat shock protein 90 (HSP90; EC 3.6.4.10),
inhibition by small molecules (17AAG, related to geldanamycin, and PU24FC1, a purine-
scaffold synthetic derivative) [21, 22] at two sites within the chaperone was shown to also block
the activity of HER2 [23, 24] and another transmembrane kinase, EGFR (epidermal growth
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factor receptor; Erb-1), as well as other proteins involved in signal transduction such as steroid
receptors and the RAF1 kinase (EC 2.7.11.1) [25-27]. HER2 degradation was also achieved with
a depsipeptide which acetylated HSP90, along with downregulation of ERB1, RAF1and p53
[28].
All of the above-mentioned mechanisms of degradation are based on the indispensable role
of the molecular chaperone HSP90 in folding, stability and function of “client” proteins or
substrates. Many client proteins sensitive to the activity of HSP90 are implicated in the
pathogenesis of breast cancers (steroid hormone receptors ER and PR, receptor tyrosine kinases
HER2 and EGFR, and components of oncogenic signal transduction cascades, AKT and RAF1).
Inhibition of HSP90 activity causes the sensitive client proteins to misfold or destabilize,
adopting aberrant conformations that induce polyubiquitylation and subsequent proteasomal
degradation [29-31].In summary, small molecules have long been identified that regulated
protein activity through degradation involving the chaperone HSP90, however none were
apparently sufficiently specific or efficacious to enter or emerge from the clinic [32, 33].
2.2 Selective estrogen receptor modulators and degraders: ligand-binding alters conformation
Selective estrogen receptor modulators (SERMs) are small molecules with a history of acting as
agonists or antagonists, at times differentially depending on tissue type. Selective estrogen
receptor degraders (SERDs) are also targeted at the hormone binding site of the nuclear
receptors, however they induce destruction of the protein [34, 35]. Fulvestrant, a first-in-class
SERD breast cancer therapeutic developed by AstraZeneca and in use since 2002, induces
degradation by one of two ways: (1) a ubiquitin-mediated mechanism due to recruitment of a
specific E3 ligase by the SERD-estrogen receptor complex, or (2) through exposure of
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hydrophobic residues due to destabilization by the SERD at the hormone binding site, and
recruitment of chaperones, which escort the partially unfolded receptor to the proteasome [9].
The latter mechanism is derived from a co-crystal structure of estrogen receptor bound by a
SERM, which interacts with the main chain through a carboxylate warhead, inducing a
hydrophobic bulge, which mimics endogenous misfolding that recruits chaperones [36].
Interestingly, though the results of recent extensive, sophisticated analyses by a large team
predominantly from Genentech did not provide further insight into the underlying structural-
functional mechanism of action of fulvestrant, an unanticipated cellular basis for induced
degradation by the therapeutic antagonist was revealed: increased ER turnover is a consequence
of intranuclear ER immobilization in the nuclear matrix, with low chromatin accessibility [37],
2.3 HyT: hydrophobic tags, mimicking misfolded protein, acting as bait for chaperones
Based on earlier observations that the recruitment of chaperones, which typically recognize and
assist in the refolding of misfolded proteins, could also lead to intracellular degradation, a
method was developed that is referred to as hydrophobic tagging, or HyT [38-40]. A
bifunctional or chimeric molecule, with a site-specific ligand on one end and a bulky
hydrophobic moiety on the other, recruits chaperones that fail to refold the baited protein, which
is either escorted directly to the proteasome, or indirectly as a result of forming a ternary
complex with an E3 ubiquitin ligase and undergoing covalent modification for targeting to the
proteasome [9]. As an example of the latter case, a HyT hydrophobic-tag (TX1-85-1) developed
for the HER3 (human epidermal growth factor receptor 3, also known as ERB3) pseudokinase is
a covalent bifunctional ligand that targets a cysteine residue (Cys781 in the ATP-binding site of
HER3), resulting in the direct binding of chaperones followed by indirect recruitment of E3
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ligases [41]. The TX1-85-1 hydrophobic tag represented the first selective HER ligand. In the
case of HER3 HyTs and for SARDs (selective androgen receptor degraders) [39], inhibition of
HSP90 accentuates targeted degradation, just as for HER2 irreversible inhibitors and SERDs.
2.4 H-SAAD/Ds: allosteric destabilizers of native state targeting the key hub of protein kinases
Recently, an in silico screen aiming to identify small molecule stabilizers, or pharmacological
chaperones, of a dysregulated bone morphogenetic protein receptor kinase (cf. 5.1, below) was
performed by targeting a shallow surface site formed in part by the C-4 loop, the key hub
responsible for allosteric regulation of activity of protein kinases. No stabilizing compounds
were found, however destabilizing hits were identified that shared warhead groups with sp2
nitrogen atoms in heterocyclic rings. They were hypothesized to serve as hydrogen-bond
acceptors, triggering instability of the loop through interaction with the multi-valent guanidino
group of an arginine residue (Arg 258) within the segment (Figure 1). Deemed hypoxia-
selective (H-S) Activin receptor-like kinase Allosteric Destabilizers and Degraders due to the
requisite participation of an ionizable histidine (His 318) within the hub, the set of commercially
available compounds have thus far been studied exclusively in vitro [42].
Thus cell-based studies will be required to establish whether the destabilizers also act as
inducers of degradation. Nonetheless, the chaperone-mediated turnover of other
conformationally perturbed or HyT-tagged proteins provides solid precedent for the likelihood of
inducing degradation in the cell. Moreover, given that the destabilizing activities of H-
SAAD/Ds were not only markedly sensitive to changes in pH within the physiological range (pH
6.5 > 7.25), but also to changes in temperature (37°C > 30°C), the efficacies of the allosterically
acting compounds and thus the potential for degradation of the target activin receptor-like kinase
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would be enhanced under hypoxic conditions in mammalian cell-based assays, in mouse models
and in patients (cf. 5.1).
Figure 1. A hypoxia-selective allosteric destabilizer and degrader (C28, green) with sp2 nitrogen
hydrogen-bond acceptor warhead, docked on a ring-like, surface pocket of a bone morphogenetic
protein (BMP) receptor kinase that is comprised in part by the C-4 loop (red), the key
allosteric hub responsible for conformational plasticity and instability of protein kinases.
3. Induced protein degradation by small molecules mediated by polyubiquitin-tagging
3.1 Bifunctional target-specific, E3 ubiquitin ligase-baiting inducers of degradation
In addition to HyT-tagging, a second method which arose earlier has been continuously
developed in parallel that is based on tagging with ubiquitin chains, which mark the targets for
direct degradation by the proteasome instead of through an indirect chaperone-mediated process.
Proteolysis-targeting chimeras (PROTACs), like the hydrophobic tags, are hetero-bifunctional
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molecules, yet functionally more refined. Rather than chaperone-baiting hydrophobic moieties,
E3 ubiquitin ligase-baiting ligands are employed, again fused to a target-specific ligand, such as
a competitive inhibitor [2, 11-16, 43-48]. A pair of related examples are depicted in Figure 2
[49]. PROTAC 3 and PROTAC 7 share von Hippel-Lindau E3 ligase-recruiting moieties to
direct polyubiquitylation of the target proteins, yet differ with respect to the target-specific
ligands. The former, with a gefitinib-based warhead, binds specifically to the EGFR kinase,
whereas the latter, with a foretinib counterpart, binds c-Met.
An additional difference, under-appreciated in two-dimensions, is the length and composition
of the polyethylene glycol linkers connecting the E3 ligase- and kinase-binding ligands. As
shown below in a model of a crystal structure of a PROTAC-mediated complex [50], the proper
parameters could prove crucial for providing for an extensive and stable protein-protein interface
(Figure 3). Specifically, Ciulli and co-workers deduced that rational design of a bifunctional
molecule that “folds on itself” is of key importance, resulting in recruitment of E3 ligase and
target protein into close proximity and formation of a stable ternary complex. Though burial of
extensive surface area, formation of specific protein-protein interactions and reduction in
entropic cost were all cited as potential beneficial effects of optimal linker length, composition
and attachment positions and vectors, the degree of cooperative complexation was found to be
dictated by the extent of surface complementarity between E3 ligase and target protein, that in
turn was determined by the relative orientation of the two macromolecules directed by a modular
hetero-bifunctional ligand.
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3.2 PROTACs provide major advantages over HyT-tagging and occupancy-based inhibitors
As anticipated, a chief advantage of the PROTACS method has been experimentally confirmed:
the extent and duration of signal inhibition resulting from degradation is significantly greater
than for steady-state competition by a simple active site, occupancy-based inhibitor [49]. Less
anticipated was the finding that the relative orientations or positions of the components of the
ternary complex of target protein, PROTAC and specific E3 ligase could dramatically alter
degradative activity. A broad-spectrum inhibitor conjugate was found to result in degradation of
Figure 3. Crystal structure of a chromatin-binding bromodomain protein targeted for degradation
bound to a von Hippel-Lindau:ElonginC:ElonginB substrate-recognition (E3 ubiquitin ligase)
complex recruited by the heterobifunctional (BET inhibitor-VHL ligand) PROTAC MZ1.
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a limited subset of protein kinases that bound the inhibitor alone (cf. 4.11) [1, 9, 47, 49]. On the
one hand, the substantial additional level of specificity that could be achieved is a major plus,
however, on the other, despite the simplistic modularity of the approach in principle, in practice,
empirical testing and optimization would likely be necessary for each specific protein targeted.
In addition to the aspect of enhanced selectivity, another significant benefit of PROTACs
methodology has been brought to the fore by two independent groups within the last year:
potential for poly-pharmacological mechanisms to accentuate the therapeutic effect of targeted
degradation. Mikihiko Naito and co-workers at the National Institute of Health Sciences (Japan)
have successfully combined target protein knockdown with cytocidal activities by also degrading
cellular inhibitor of apoptosis protein 1 (cIAP1) or X-linked inhibitor of apoptosis protein
(XIAP) [51-53] The chimeric dual-degraders are referred to by the acronym, SNIPERs: Specific
and Nongenetic IAP-dependent Protein ERasers. Craig Crews and co-workers have succeeded
in constructing a chimera that degrades a target protein (BRD4, bromodomain-containing protein
4, an epigenetic regulator that recognizes acetylated lysine residues) while also stabilizing p53,
producing a synergistic antiproliferative effect of multiple cancer cell lines. The nutlin-based
PROTAC, one of few, hijacks the E3 ligase MDM2, knocking down BRD4 and upregulating the
tumor-suppressor protein. As a result of the poly-pharmacological mechanism, proliferation is
inhibited more effectively than a corresponding VHL-utilizing PROTAC with similar BRD4-
degrading activity [54].
3.3 Future applications of PROTACs for a broad spectrum of protein targets in drug discovery
Arvinas, in agreements with Pfizer, has developed PROTACs for estrogen (ARV-471) and
androgen receptors (ARV-110) for oral delivery with improved pharmacodynamics and
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pharmacokinetic properties [55]. The AR-degrading chimera is the first PROTAC drug to enter
the clinic, currently in Phase 1 to evaluate safety and tolerability in patients with metastatic
castration-resistant prostate cancer who have progressed on standard care therapies. According
to Arvinas, in contrast to traditional antagonism through a competitive- and occupancy-driven
process, degradation is iterative and hence less susceptible to increases in expression and
mutations in the hormone receptors, enabling PROTACs to overcome known mechanisms of
resistance to current standards of care.
Other targets of interest include the so-called “undruggable” proteins that lack biologically
relevant binding sites (substrate or ligand), but might possess clefts or pockets that could afford
modest affinity for specific or selective small molecules identified in screens of compound
libraries (chemical or in silico) or by rational design. As will be advocated below, protein kinase
targets should be revisited or explored with the cutting-edge method. First though, for proof-of-
concept, published preclinical successes will be briefly summarized.
4. Protein kinases targeted for proteolysis by PROTACS: preclinical proof-of-concept
For historical perspective and to provide supporting experimental evidence for applicability of
PROTAC-induced degradation to protein kinases, a roster of examples is presented below. For
more in depth background, see two recent excellent reviews by Tan and Gray [56] and by
Ferguson and Gray [57]. In addition to a typical modular pair depicted above (Fig. 2, PROTAC
3 and PROTAC 7), the chemical structures of hetero-bifunctional molecules targeting protein
kinases are available in the primary references cited in each subsection, or can be viewed and
compared in the representative collection compiled by Tan and Gray [56].
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4.1 Receptor-interacting serine-threonine kinase 2 (RIPK2): first application of VHL ligands
In 2015, the first applications of a VHL E3 ligase ligand as a component of modular PROTAC
designs was reported, including one for degradation of a protein kinase, RIPK2 (EC 2.7.10.2)
[58]. As a central mediator of the innate immune response triggering cytokine release, aberrant
RIPK2 signaling is implicated in inflammatory bowel disease and sarcoidosis, which could thus
be potentially treated by RIPK2-selective PROTACs [45]. Previous constructs suffered from
multiple undesirable properties due to their reliance on an inferior HIF1 peptide fragment as
bait for E3 ligase. The synthetic VHL ligand was actually a tert-butyl-hydroxyproline derivative
(ligand 7; N-acetyl-3-methyl-L-valyl-(4R)-4-hydroxy-N-[4-(4-methyl-1,3-thiazol-5-yl)benzyl]-
L-prolinamide) of the first compound (ligand 1; methyl 4-(((2S,4R)-4-hydroxy-1-(2-(3-
methylisoxazol-5-yl)acetyl)pyrrolidine-2-carboxamido)methyl)benzoate) that had been identified
through in silico and fragment-based screens announced three years earlier [59, 60]., Through
structure-activity relationship studies conducted by Ciulli and coworkers in Dundee, ligand 7
was imparted with a significantly lower KD (185 nM) than the parent molecule [61].
Consistent with the high affinity for of the synthetic derivative for the VHL E3 ligase,
RIPK2_PROTAC was shown to act catalytically and reduce endogenous protein levels by 90%
at nanomolar concentrations. Furthermore, of the approximately 7,000 proteins quantitatively
analyzed, only one other, MAPKAPK3 (MAP kinase-activated protein kinase 3), was
significantly degraded, hence RIPK2_PROTAC proved to be highly selective as well as active.
Interestingly, in keeping with the high selectivity afforded by the hetero-bifunctional compound,
other kinases in the screen were bound by RIPK2_PROTAC but not degraded (RIPK3, ABL and
TESK), at least under the conditions of the assay [58].
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4.2 TANK-binding kinase 1 (TBK1): specifically degraded despite non-specifically inhibited
TANK-Binding Kinase 1 [TBK1; tumor necrosis factor receptor-associated factor or TRAF-
family member-associated NF-B activator (encoded by the TANK gene) kinase 1; EC
2.7.11.10] is an IB (IKK)-related kinase that can activate NF-B in a kinase-dependent manner
[62, 63]. PROTACs targeting TBK1 were synthesized with VHL-binding ligand to recruit the
E3 ligase. Intriguingly, despite the kinase-binding moiety inhibiting two related kinases
(TBK1/IKK), only one was degraded (TBK1) and not the other (IKK).
4.3 Human epidermal growth factor receptor 2 (Her2) and EGFR: first PROTACs for RTKs
Her2 and EGFR are validated targets for a subtype of non-small cell lung cancers (NSCLCs) and
other tumors as well as one type of breast cancer, with FDA-approved inhibitors in the clinic. In
the first demonstration of the applicability of the strategy to the receptor tyrosine kinase (RTK)
family, PROTACs for the two have been produced with the specific inhibitors linked to a VHL-
binding ligand [49].
4.4 Mesenchymal-to-epithelial transition RTK (c-MET): degradation versus simple inhibition
In a seminal paper from Crews and co-workers, the c-MET proto-oncogene, a receptor tyrosine
kinase is targeted by PROTACs, along with two others, the EGFR and HER2 as well as multiple
mutants of EGFR and c-MET (mesenchymal-epithelial transition factor, the receptor for
hepatocyte growth factor/scatter factor or HGF/SF ligand). [49]. Fully functional, target-
degrading PROTACs were compared with target-inhibiting variants that contain an inactivated
E3 ligase-recruiting ligand (rather than the parent tyrosine kinase inhibitor warheads alone). The
results of the studies show significant advantages of degradation versus simple inhibition: (1)
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degradation provides a more sustained down-regulation of signaling even after washout, (2)
activity-independent, protein-protein interaction scaffolding functions are eliminated and (3)
mutated kinases that might otherwise switch off as a result of treatments are disposed of. The
findings provide a major proof-of-concept for the broader application of PROTACs to target
transmembrane receptor kinases and the efficacy of recruitment of the VHL E3 ligases for down-
regulation of the signaling proteins from the plasma membrane.
4.5 ABL: first clinical small molecule kinase inhibitors employed as warheads in PROTACs
Derivatives of imatinib, the first small molecule kinase inhibitor (SMKI) to reach the clinic, were
synthesized by Takeda (Japan) to induce to degradation of BCR-ABL, a fusion of the breakpoint
cluster region protein (BCR) and the Abelson murine leukemia viral oncogene homolog 1
(ABL1) tyrosine kinase (EC 2.7.10.2) often found in chronic myelogenous leukemia (CML) and
acute lymphocytic leukemia [64, 65]. Hetero-bifunctional compounds of imatinib, dasatinib and
two other ABL inhibitors were conjugated to three different E3 ligase baits via PEG linkers of
varying length. Similarly, Crews and co-workers synthesized dasatinib-based PROTACs
targeting the ABL kinase [66]. Inhibitor specificity, linker lengths and the specific type of E3-
interacting bait were all found to be important, empirically determined parameters. Recently,
Takeda and academic partners dissected the degrader and inhibitor functions of dasatinib-based
PROTACs, demonstrating that a BCR-ABL degrader provides more sustained inhibition of
CML cell growth than the ABL kinase inhibitor counterpart [67].
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4.6 Cyclin-dependent kinase 9 (CDK9): Unanticipated gain or loss of selectivity of PROTACs
Cyclin-dependent kinases (EC 2.7.11.22) are perhaps best known for their role in cell cycle
control, however a second major functional group is involved in control of transcription. For
example, CDK9 is the catalytic subunit of transcription elongation factor b (P-TEFb), which
phosphorylates the C-terminal domain of RNA polymerase II (EC 2.7.7.6), stimulating
transcription [68, 69]. Because P-TEFb phosphorylates other components (transcription factors)
that regulate elongation of transcription in an array of cellular and physiological processes,
CDK9 has been deemed an appealing candidate for therapeutic intervention [70].
In order to specifically target the multifunctional cyclin-dependent kinase, Gray and co-
workers recently reported the development of a PROTAC for CDK9 (Thal-SNS-032) based on a
selective CDK2/7/9 inhibitor (SNS-032) [71]. In eleven leukemia cell lines, the PROTAC
induced significant degradation of CDK9, and importantly, enhanced anti-proliferative effects
compared to the inhibitor alone. Because the PROTAC only degraded CDK9, rather than other
targets of the inhibitor as well, and because chimeras based on a more selective and potent
CDK9 inhibitor (NVP-2) proved less efficient, two key aspects of the approach were brought to
light: (1) PROTACs can exhibit more selectivity than the parental inhibitors, which however (2)
do not necessarily translate their efficacies as modular components of hetero-bifunctional
degraders.
4.7 Bruton’s tyrosine kinase (BTK): cooperative protein-protein interactions not required
BTK is a non-specific, non-receptor tyrosine kinase (EC 2.7.10.2) required for B cell maturation
and a therapeutic target for cancers of the blood. Pfizer has investigated the applicability of the
PROTACs methodology for BTK with an eleven-compound library with ligand to recruit the E3
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ligase cereblon (CRBN) and linkers of different lengths. Beyond simply determining whether
ternary complexes of BTK, CRBN and PROTAC formed, cooperativity of binding was also
assessed. In contrast to a key role for cooperativity proposed for other protein complexes
assembled by the hetero-bifunctional ligands, none was observed nor was found necessary for
efficient degradation of the POI. However, consistent with most if not all other studies with
small libraries of PROTACs, linker length was crucial for alleviating steric clashes between the
two protein components brought together by the chimeric small molecule [72].
4.8 Focal-adhesion kinase (FAK): elimination of protein scaffold function, not simply activity
FAK is another non-specific, non-receptor tyrosine kinase (EC 2.7.10.2), which is required in
tumor invasion and metastasis, functions as more than a phosphotransferase enzyme, but also as
a scaffold for protein complex formation. Perhaps not surprisingly then, in preclinical studies,
FAK inhibitors combined with other therapeutics are significantly more efficacious than either
unaided agent[73]. To determine whether degradation of the FAK scaffold and the concerted
abolishment of kinase activity would improve the performance of FAK inhibitors alone , a
selective and potent FAK degrader (PROTAC-3; Figure 2) was compared with the parent
compound, defactinib [74]. Indeed, the inducer of degradation outperformed the inhibitor as
judged by measurement of activation of the FAK enzyme and cellular processes mediated by
FAK(cell migration and tissue invasion), providing evidence of the potential for PROTACs to
control dysregulation stemming from protein kinases with enzymatic and scaffolding functions.
21
4.9 Extracellular signal-related kinases 1 and 2 (ERK1/2): a permeable pro-drug PROTAC
ERK1 and ERK2 (mitogen-activated protein kinases; EC 2.7.11.24) regulate a broad array of
cytosolic and nuclear proteins as substrates of phosphorylation and are part of an activation
cascade (Ras-Raf-MEK-ERK) responsible for approximately one-third of all cancers [75]. The
highly mutated RAS small monomeric GTPase (EC 3.6.5.2) has been recalcitrant to efficacious
inhibitor development to date, thus attention has been focused on other components of the signal
transduction cascade.
Toward that end, ERK1 and ERK2 have been targeted by two small prodrug precursors with
good permeability that can combine intracellularly via bio-orthogonal click chemistry (inverse
electron demand Diels-Alder or IEDDA cycloaddition) to form an active, whole PROTAC or
Figure 2. Modular composition of proteolysis-targeting chimeras for protein kinase degradation
[45]. 2D structures: PROTAC 3- Pubchem CID 135156947, PROTAC 7- Pubchem CID
13810841.
22
CLIPTAC (Astex Pharmaceuticals, Cambridge, UK) [76]. Performing the click chemistry prior
to addition to cultured cells (human melanoma cell line) resulted in undetectable levels of
targeted degradation in western blot assays. In marked contrast, step-wise addition of the two
prodrugs at 1 M each produced complete degradation of ERK2 and near-so for ERK1 after 16 h
co-incubation. Given the relatively high molecular weights inherent to linked, bifunctional
compounds, synthesis of PROTACs as self-assembling prodrug pairs (CLIPTACs) is an
attractive option for future design strategies for drugs entering the clinic.
4.10 Promiscuous, multi-kinase inhibitors as modules of PROTACs: additional selectivity
Two seminal papers with respect to development of PROTACs for degradation of proteins-of-
interest (POIs) in general, but focusing on protein kinases specifically, were published as a suite
along with that of the RTK-targeting studies of Crews and co-workers (cf. 4.4) in Cell Chemical
Biology in January of 2018 and highlighted with a preview article [1]. In one of the two, Crews
and co-workers also synthesized PROTACs composed of the promiscuous protein kinase
inhibitor foretinib (cf. 3.1: for structure, cf. Fig. 2, warhead component of PROTAC 7),
polyethylene glycol linkers and VHL or cereblon ligands (VHL PROTAC 1 and CRBN
PROTAC 2) [47]. Similarly, in the other seminal paper, Nathanael Gray and co-workers
surveyed the degradable kinome with a promiscuous kinase-directed hetero-bifunctional
degrader synthesized from a versatile diaminopyrimidine scaffold directed at the ATP-binding
site (TL12-186), polyethylene glycol linkers and the cereblon-recruiting IMiD analog,
pomalidomide [43].
Both studies demonstrated that additional selectivity arises such that only small subsets of the
kinases tested were effectively or even detectably degraded [43, 47]. The structural and
23
functional origins of the additional layers of selectivity were hypothesized to include
complementary protein-protein interactions between the POIs and E3 ligase recruited by the bait
moiety of the PROTACs, as well as possible low affinity but cooperative interactions in the
ternary complex composed of the hetero-bifunctional ligand, POI and E3 ligase. Orientation of
the E3 complex with respect to target lysine residues (cf. 6.5, below) might also be one of
multiple factors responsible for high specificity and low off-target toxicity that has been long-
sought after for small molecule protein kinase therapeutics.
Indeed, while this article was under review, Crews and coworkers had further reported that
one isoform of a protein family could be selectively targeted over others simply by varying the
linker length and orientation of a single E3 ligase. Moreover, stable ternary complex formation
was found to be necessary but not sufficient for robust degradation, consistent with the
hypothesis above [77].
5. Protein kinases in multi-protein complexes offer enhanced potential for quenching
dysregulated signaling: mutant ALK2 BMP receptor kinase as a putative case
5.1 Targeting dysregulated BMP signaling that leads to severely debilitating bone deposition
Though rare, the heterozygous mutation (R206H) in a type I (ligand-activated) bone
morphogenetic protein (BMP) receptor kinase (ACVR1/ALK2; activin receptor-like kinase 2;
receptor protein serine/threonine kinase, EC 2.7.11.30) is linked to a severe musculoskeletal
disorder (FOP; Fibrodysplasia Ossificans Progressiva; OMIM 135100) causes metamorphosis of
soft tissues into extra-skeletal or heterotopic bone, restricting mobility throughout the body in a
stepwise, cumulative manner. At present, at least six pharmaceutical companies (BioCryst,
Blueprint, Clementia/Ipsen, Keros, La Jolla, Regeneron) have made efforts to develop a
24
therapeutic for FOP, which cannot currently be effectively managed much less prevented or even
diminished in frequency or extent. All but two are developing ATP-competitive, selective
inhibitors of ALK2 receptor kinase. Regeneron has entered phase 1 clinical trials with a
monoclonal antibody that neutralizes the non-canonical ligand (activin) with a specific
neofunction of activating the R206H mutant but not wildtype ALK2 receptor kinase in the
heterozygous FOP patients. Clementia/Ipsen has ushered a retinoic acid receptor- agonist
(orphan drug designation, initially developed by Roche), palovarotene, through ongoing phase 2
and phase 3 trials, that broadly dampens BMP signaling by reducing SMAD1/5/8
phosphorylation [78]. Unfortunately, palovarotene showed severely adverse effects on skeletal
maturation in a mouse model, perhaps due to the dampening of all BMP signaling and/or the
chronic administration required to retard or restrain HO [79], Interestingly, proteasome-
mediated degradation of the phosphorylated downstream effectors is the proposed mechanism of
action, based on the promotion of degradation of phosphorylated SMAD1 by all-trans-retinoic
acid [80].
Because heterotopic bone formation also arises without mutation yet due solely to soft-tissue
trauma from high-velocity gunshot wounds and explosive injuries (IEDs), extensive burns, brain
and spinal cord injuries and from complications of elective arthroplasties (hip and knee
replacements), inhibition of aberrant BMP signaling has applications in additional larger patient
populations, both military and civilian [81, 82]. In mouse models without the gain-of-function
mutation in ALK2, trauma triggers upregulation of transcription of genes encoding BMP ligands,
which in turn then are hypothesized to increase signaling aberrantly through any or all of the
three activin receptor-like kinases (ALK2, ALK3, ALK6) that transduce BMP signals.
25
Of note, Levi and co-workers showed that knockdown of any one of the three ALK-encoding
genes did not inhibit trauma-induced HO (tHO), however combined ablation of ALK2 and
ALK3 produced near total elimination [81]. Thus, for treatment of non-genetic tHO patients,
broadly selective therapeutics targeting two or all three of the redundantly acting type I BMP
receptors, or an ALK2-selective in combination with an ALK3- and/or ALK6-selective
compound, would be necessary. Such a therapeutic might be tolerated for treatment of acute
cases, whereas for FOP, which is a life-long, chronic affliction, a highly selective ALK2-
targeting drug would almost certainly be required. Ideally, the drug could be administered as a
prophylactic against the stepwise accumulation of mobility-arresting heterotopic bone.
5.2 Promiscuous PROTAC does not induce degradation of ALK2
Intriguingly, although in non-pathological contexts, ligand-activated ALK2 receptor kinase is
degraded by an endogenous negative feedback mechanism involving a specific E3 ubiquitin
ligase in a ternary complex with a negative regulatory protein [83-86] (cf. 5.3),.induced
degradation of the protein was not observed with the putatively promiscuous PROTACs (VHL
PROTAC 1, CRBN PROTAC 2) described above (4.10) [47]. Though the promiscuous parent
inhibitor (foretinib, 10 M) was detectably diminished phage-displayed ALK2 receptor kinase
activity in a KinomeScan assay (70%), inhibition by VHL PROTAC 1 was negligible (6%) and
inhibition by CRBN PROTAC 2 abolished (both at 10 M). Hence ALK2 receptor kinase
apparently must be targeted by a modified PROTAC with different linker length, composition or
site of attachment, or with a ligand bait for a different E3 ligase.
In addition to a systematic, modular screening approach, consideration of the structure and
mechanism of assembly of the multi-protein signaling complex containing ALK2 could enhance
26
and streamline the development of an efficacious drug for the diverse, debilitating bone-forming
musculoskeletal pathologies (cf. 5.4, below). In support of the proposed drug discovery
approach, two proteins interacting with the cytoplasmic kinase of ALKs, a downstream-effector
substrate (R-Smad3) [87] and a dampening protein (FK-506 binding protein 12 kDa, FKBP12;
peptidylprolyl isomerase, EC 5.2.1.8) [88], can be degraded with hetero-bifunctional small
molecules. In the case of the signaling-dampening binding protein, induced degradation should
be avoided, since competitive inhibition of type I BMP receptor binding of FKBP12 by the
FK506 ligand leads to receptor activation and promotes osteogenic differentiation [89].
In the case of the downstream effector SMADs, the therapeutic effect of targeted degradation
would be anticipated to be commensurate with that of the ALK2 receptor kinase itself [90-93],
however, since the effect would be broad, quenching all BMP signaling, the result for
chronically dosed FOP patients would be highly undesirable. That said, for acute treatment of
non-genetic tHO, non-selective quenching of BMP signaling from the pool of type I receptor
kinases could prove adventitious, offering an alternative avenue from ATP-competitive
inhibitors that have undesirable off-target effects [81].
Since type II receptor kinases (activin type II receptors ActRIIA, IIB and the bone
morphogenetic protein type II receptor, BMPRII, EC 2.7.11.30) serve dual roles as upstream
phosphorylating enzymes and as scaffolds that form heterodimers with ALK2 [94], targeting this
component of the signaling complex for destruction might also prove efficacious. Unlike
directed degradation of BMP-specific SMADs (1/5/8) recruited to the signaling complex,
directed degradation of type II receptors including ActRIIA and IIB, which are required for
signaling by activin ligands through SMADs 2/3, the effects would be therefore be overly broad.
Hence just as for PROTACs composed of ALK2-selective warheads that might induce the
27
degradation of signaling-dampening FKBP12, those that lead to or allowed for degradation of
type II receptors would be undesirable.
Note that an overarching conclusion from consideration of the effects of degradation of the
proximal components in the signaling complex directed by a PROTAC composed of an ALK2-
selective warhead is the importance and necessity for determining the effects on stability of not
just the type I receptor kinase but all of the components in the ligand-induced signaling complex.
5.3 Activated ALKs are degraded by an endogenous negative feedback mechanism in complex
In the canonical pathway, signals are transduced by BMP/TGF-β superfamily ligands solely by
downstream effector substrates (receptor-regulated or R-SMADs) of activated endocytic receptor
complexes that, upon phosphorylation and hetero-trimerization, translocate into nuclei of the
receiving cells to turn on and off target genes [95]. To perhaps compensate for the simplicity of
the transduction mechanism, two negative feedback loops down-regulate signaling through
proteasomal degradation of pathway components. In one case that is independent of signaling,
pools of R-SMADs are maintained at basal levels to set the sensitivity to signal input, while in a
distinct, signaling-dependent process the activated receptor kinases in complex with inhibitory I-
SMA6 or 7 are targeted for destruction [83-86].
In the latter case, binding of inhibitory I-Smad to activated type I receptors (ALKs), which
form stable complexes, leads to association with and modification by specific E3 ubiquitin
ligases (SMURFs1/2; SMAD ubiquitin regulatory factors). Thus, I-SMADs act as adaptors for
composite interactions with an E3 ligase and activated ALK receptor kinase. In a pathological
context, after pharmacological (AMPK activators metformin or aspirin) upregulation of
inhibitory SMAD6 and SMURF1 E3 ligase in fibroblasts and induced pluripotent stem (iPS)
28
cells from a FOP patient, activated ALK2 mutant receptor was shown to be degraded by the
ubiquitin-proteasome system, presumably as a result of enhanced formation of a receptor
kinase:I-SMAD:E3 ligase complex [96].
In summary, activated wildtype and mutant ALK2 receptor kinases are downregulated by
endogenous or pharmacologically induced degradation by the ubiquitin-proteasome pathway,
respectively, yet PROTACs derived from a promiscuous protein kinase inhibitor (cf. 5.2), fail to
bind much less induce the degradation of the susceptible protein. Therefore, toward design and
synthesis of ALK2-targeted PROTACs, rather than by trial-and-error , a more rational approach
is called for.
5.4 Model for ALK2-containing heterotetramer with R-Smad effector substrate recruited
The serine-threonine receptor kinase (Activin receptor-like kinase 2 or ALK2), is a component of
a ligand-assembled, heterotetrameric-receptor complex, which due to multiple binding sites and
interacting partners, affords manifold opportunities for quenching the dysregulated signaling of a
pathology-triggering, gain-of-function mutant (R206H). To date, only the crystal structures of
the extracellular assemblages of BMP/TGF-β signaling complexes have been determined [97-
100]. Interactions between the cytoplasmic kinases of the receptors and the substrate R-SMADs
have been thoroughly characterized [101, 102], however no binary or ternary complex structures
crystallized, save for FKBP12-bound ALKs.
In order to guide the rational, modular design of PROTACs as therapeutics for dysregulated
ALK2 signaling , a stepwise in silico-docked model of the cytoplasmic components of the BMP
signaling complex was generated that serves as a paradigm for targeting other protein kinase
complexes (Figure 4). Since the two types of receptor kinases (EC 2.7.11.30) associate as
29
heteromeric dimers in the absence of ligand [94, 103], in the first step crystal structures of
cytoplasmic constructs of ALK2 (PDB ID 3H9R) and BMPRII (PDB ID 3G2F) kinases were
docked in silico with state-of-the-art routines via the ClusPro web server [104]. In the next step,
after partial truncation (autoinhibitory -helix 1) of ALK2 kinase in the docked heterodimer, the
crystal structure (1KHUA) of the protein-interacting (MH2; phosphopeptide-recognition or
forkhead-associated (FHA) domain of a BMP R-Smad was then docked to form a ternary
complex of the preformed kinase heterodimer and effector substrate.
In the final step, two ternary complexes were in turn docked to generate the ligand-induced,
cooperatively assembled cytoplasmic signal transduction complex of two kinase heterodimers
Figure 4. Stepwise in silico-docked model of homodimeric bone morphogenetic protein (BMP)
ligand-induced, heterotetrameric signaling complex that would provide expansive surface area,
including six unique composite protein:protein interfaces, for recruitment of substrate-
recognition E3 ligases, which, in addition to those of the PROTAC warhead-binding protein
kinase itself (type I), could potentially modify an even broader assortment of lysine residues.
30
with two R-Smad substrates recruited for phosphorylation. In addition to the requisite and
pronounced complementarity of the manifold surfaces within the six-chain complex, several
structural elements are juxtaposed to provide for specificity of the interactions and site-specific
phosphorylations, hence the in silico model generated by the ClusPro routines appears reliable,
suggesting that other signaling complexes might be investigated via a similar step-wise process.
Consideration of the structure of a multi-protein signaling complex in the modular design of
PROTACs provides several potential benefits. First, the position of the linker extending from
the kinase inhibitor might require relocation, in order to prevent steric clashes or to render to the
other moiety, the E3 ligase ligand, greater potential for protein-protein interactions within the
complex. Second, determination of the length and composition of the linker itself might be
facilitated by rational design, rather than blind, systematic syntheses and functional tests, or at
minimum by iterations of tests of small sets followed by rational design. Third, as demonstrated
in the BMP heterotetrameric receptor assembly, a second kinase active site (type II receptor)
could be targeted by a competitive inhibitor linked to an E3 ligand. Fourth, visualization of a
model of a multi-component complex reveals the necessity of analyzing all of the proteins with
respect to degradation, rather than simply that bound by the inhibitor module of the PROTAC.
Finally, in silico screening of virtual libraries of small molecules that target pockets or clefts
created at protein-protein interfaces within the complex could provide not only new leads, but
ones which would limit degradation to components actively involved in signaling, rather than the
total cellular pool in the absence of activation. Along those lines, the PROTAC for the
downstream-effector substrate (R-Smad3) [87] referred to above (cf. 5.2) was developed through
in silico docking and rational design. However, since the R-SMAD was targeted as a free
effector, rather than as a component of an activated signaling complex, the low efficacy and
31
toxicity of the designed compound might be overcome by investigating second-generation
derivatives based on an in silico-docked model for the related TGF- receptor assemblage.
5.5 Degradation of BMP signaling complexes in other contexts underscores feasibility for
therapeutic intervention with rationally designed PROTACs
Note that, in addition to the SMURF1/2 and SMAD6/7 negative feedback loops discussed above
(cf. 5.3), BMP signaling complexes have been shown to be subject to degradation by the
ubiquitin-proteasome system in other cellular contexts. For example, the Drosophila BMP
receptor kinase ortholog, TKV, is degraded by the proteasome downstream of an S6 serine-
threonine kinase family member (S6KL), inhibiting the growth of neuromuscular junctions and
stimulating endocytosis at the synapse [105]. In another case, activated BMP receptor-regulated
SMAD was shown to be degraded following interaction with and polyubiquitylation by an E3
ligase, NEDD4 (neural precursor cell expressed, developmentally down-regulated 4) [106].
Such examples of degradation of receptors and effectors underscore the feasibility for therapeutic
intervention by application – ostensibly through rational design – of PROTAC methodology in
human diseases and disorders caused by dysregulated BMP/TGF-β signaling.
5.6 Another potential application of rational design of PROTACs for protein kinase complexes
Of course, the model of a complex of signaling proteins focused on above is only one example.
If available, crystal structures of complexes of protein isoforms to be selectively targeted would
be preferable and provide three-dimensional templates for rational design of PROTACs that
stabilize ternary complexes in a productive fashion (cf. 4.10) [77]. One such candidate would be
complexes of CDKs and cyclins, which are well-represented in the Protein Data Bank (e.g. 1FIN,
32
CDK2-Cyclin A; 3G33, CDK4-Cyclin D3; 1G3N, CDK6-Cyclin D; 5HQ0, CDK1-Cyclin B;
5L2W, CDK2-Cyclin E; 3TN8, CDK9-Cyclin T; 3RGF, CDK8-Cyclin C; 4YC3, CDK1-Cyclin
B1). Superposition of the complexes (PyMOL) reveals a deep cleft between the chains proximal
to the ATP/competitive inhibitor-binding site that is structurally highly variable, primarily due to
dramatic differences in the conformation of the activation segment or A-loop. Hence structure-
based design might impart specificity to otherwise only marginally selective or even
promiscuous inhibitors of CDKs if rationally coupled to E3 ligases.
5.7 Considerations and concerns inherent to protein kinases composed of catalytic and
regulatory subunits or proteins
Similar to the concerns raised about the misdirected degradation of the type I BMP receptor
dampening protein FKBP12 by a PROTAC composed of an ATP-competitive inhibitor as
warhead targeting the cytoplasmic kinase (cf. 5.2), rational design and subsequent analyses of the
activities of PROTACs targeting CDK-Cyclin complexes should bear in mind the potential for
misdirected degradation of the cyclin regulatory proteins rather than specific CDKs. Such
concerns should actually be extended to any protein kinase composed of catalytic and regulatory
subunits or proteins, and would be expected to vary in effect depending on the nature of the
protein pair, e.g. whether or not the regulatory subunits interact with more than one kinase. If so,
off-target effects might arise indirectly through degradation of the regulatory subunit pool,
altering stoichiometries and concomitantly the activities of other kinases or binding partners.
33
6. Non-degradative effects: further considerations and caveats of protein ubiquitylation
As will be reiterated amongst the conclusions, because the focus of this review has thus far been
on the degradative effects of polyubiquitylation, the caveat should be voiced that modification
with ubiquitin protein moieties can also have a multitude of non-degradative effects that
newcomers to the field should become mindful of and keep under consideration, such as
inhibition of degradation and activation of protein kinases. In addition, enzyme-catalyzed
deubiquitination is also a burgeoning field of study that is currently commonly included in
conferences focusing on PROTAC-mediated degradation. The specific examples given below of
non-degradative effects by different linkages and E3 ligase, as well as removal of ubiquitin
modifications, are meant to draw attention to potential obstacles and opportunities in continued
development of PROTACs as therapeutics targeting protein kinases.
6.1 E3 ligase binding can inhibit, rather than promote, polyubiquitylation and degradation
The E3 ligase SMURF1, a component of a negative feedback loop that leads to degradation of
ALK receptor kinases (cf. 5.3), conversely facilitates estrogen receptor alpha signaling by
increasing the stability of ER alpha, hypothetically due to inhibition of K48-specific poly-
ubiquitylation [107]. Conceivably therefore, endogenous downregulation of kinases could be
blocked by exogenous recruitment of E3 ligases into unproductive complexes by candidate
PROTAC compounds. For a promiscuously binding inhibitor moiety, a linked E3 ligase could
simultaneously degrade a targeted protein while blocking the endogenous negative regulation of
another, representing a new category of off-target toxicity unique to PROTAC inhibitors.
34
6.2 Non-degradative regulation of the TGF-β signaling pathway: positive and negative
The transforming growth factor- (TGF-β) signaling pathway, which utilizes a separate subset of
downstream effectors (SMADs 2 and 3) than the BMP counterpart (SMADs 1, 5 and 8), is both
positively and negatively regulated by non-degradative mechanisms through modulation of the
regulated (TβRI/ALK5, TGF- type I/activin receptor-like kinase 5) receptor (EC 2.7.11.30), the
regulated effectors (R-SMADs) and the inhibitory effectors (I-SMADs) [108-110]. Itch (or
Itchy), an E3 ubiquitin ligase involved in the modulation of immune responses, catalyzes non-
degradative, TGF-β-induced ubiquitylation of SMAD2, which in turn enhances protein-protein
interactions between TβRI receptor kinase and the SMAD substrate, and concomitantly, TGF-β-
induced transcription. Conversely, in keeping with the caveat posed above about non-productive
binding of E3 ligases and differential effects, the Itch protein inhibits TGF-β signaling by
binding SMAD7 and enhancing the association of the I-SMAD with activated TβRI receptor
kinase [111]. Though similar with respect to down-regulation of the signaling pathway as for the
Smurf1/2 E3 ligases discussed above (cf. 5.3), inhibition by Itch was not dependent on any form
of ubiquitylation, simply binding, whereas the SMURF1/2 E3 ligase induced the degradation of
activated ALK receptor kinase by polyubiquitylation.
6.3 Ubiquitylation appears to allosterically alter structure and dynamics of protein kinases
Because covalently linking proteins with ubiquitin was observed to be non-degradative in
different contexts, the post-translational modifications were hypothesized to perhaps alter the
structure and function of proteins much like phosphorylation or glycosylation [112]. With
proteomic methods, Jacobsen and co-workers identified ubiquitin-tagged protein kinases in a
human cell down to the sites of ubiquitylation, which were commonly in structured regions
35
involved in regulation and activity. Subsequent molecular dynamics simulations focused on one
enzyme, ZAP-70 (70 kDa zeta-chain associated protein; a non-specific protein-tyrosine kinase,
EC 2.7.10.2), indicated that ubiquitin modifications affect the structure of the protein and have
site-specific effects. For example, at K377, modification induced structural changes that
resembled the inactive state, whereas at K476, a site on the opposite side of the protein had the
inverse effect. Thus, non-degradative ubiquitylation of protein kinases, similar to site-specific
phosphorylation, might allosterically alter structure and dynamics and therefore activity and
function of the conformationally regulated family of enzymes.
6.4 Polyubiquitylation through linkages on Ub K63 can induce activation of protein kinases
The polymeric structure of the polyubiquitin chain dictates whether or not the tagged protein is
targeted for proteasomal degradation. Linkages from the sidechain -amino of ubiquitin K48
typically promote proteasomal degradation. In contrast, K63-linked polyubiquitylation does not
trigger proteasomal inhibition but in fact, like mono-ubiquitylation, has been found to contribute
to protein-protein interfaces to enhance associations and formations of complexes. Activation of
protein kinases and trafficking of proteins are two cellular processes regulated by K63-linked
non-degradative polyubiquitylation, which can influence cell survival and cancer development
[113].
TANK-binding kinase (TBK1), successfully targeted by a PROTAC for proteasomal
degradation (cf. 4.2), becomes modified by non-degradative K63-linkages at two sites, one in the
kinase domain (KD, Lys30) and the other in the scaffold/dimerization domain (SDD, Lys401).
These post-translational modifications are required for formation of dimers, which are necessary
for activation of TBK1, hence serve crucial roles [114].
36
A specific E3 ubiquitin ligase, TRAF6 (tumor necrosis factor-associated protein 6), has been
shown to regulate several protein kinases via polyubiquitylation with K63 linkages. TβRI, the
type I TGF-β receptor kinase interacts with TRAF6, which polyubiquitylates TAK1
(transforming growth factor- kinase 1 or mitogen-activated protein kinases kinase kinase,
MAP3K7) leading to activation, thus without the receptor kinase acting directly on TAK1 [115].
The structural basis for the activating effects of the K63-polyubiquitin chain could be due to
alteration of protein-protein interactions with components of the pathway, and/or as a result of
changes in structure and dynamics.
In addition to TAK1, the E3 ligase TRAF6 also has been shown to promote the activation of
AKT/PKB (protein kinase B) through polyubiquitylation with K63 linkages [116]. In this case,
the mechanism is clearer, though indirect. Following growth factor stimulation, AKT/PKB,
primarily localized in the cytosol, is actively recruited to the plasma membrane as a result of
K63-chain polyubiquitylation by TRAF6. Interestingly, a mutation of AKT that leads to an
increase in polyubiquitylation, membrane localization and phosphorylation was found to be
associated with a human cancers (breast, ovarian, colon and bladder carcinomas, malignant
melanoma), demonstrating an important role for the K63-linked polymer in oncogenic AKT
activation [113, 117].
Recently, adding to the complexity of the so-called ubiquitin code of multiple types, sites and
mixtures of polymers, proteomic studies revealed that branched forms are common in
mammalian cells. The E3 ligases TRAF6 and HUWE1 (HECT-type ubiquitin ligase HECT,
UBA and WWE Domain Containing 1) work in concert to create branches at K48 and K63, and
importantly, though K48 linkages are sufficient for proteasomal degradation, K48 branching in
37
K63 chains serves to enhance NF-kB signaling by stabilizing the downstream cascade of the
pathway [118, 119].
6.5 Different ubiquitylation modes and protein fates dictated by specific E2:E3 ligase pairs
Although this review has necessarily focused on the E3 ubiquitin ligases, which are recruited to
targets of degradation by PROTACs, the role and influence of E2 ligases (EC 2.3.2.23) should
not be ignored. Tethering of a ubiquitin-conjugating E2 enzyme to a substrate in the absence of
an E3 is sufficient for transfer of the activated ubiquitin protein [120]. However, specific sites of
ubiquitylation are determined by an E3 ligase in complex with the E2 and substrate protein by
positioning the E2 active site near the long flexible sidechain of a lysine residue. From a
catalytic standpoint, ubiquitylation results from nucleophilic attack of the terminal -amino
group of the lysine on the thioester bond linking the activated ubiquitin group to the E2 catalytic
cysteine. Consequently, a particular E3 ligase will dictate which lysine is covalently tagged and
the type (mono- or polyubiquitinylated, branched or unbranched) but must act in complex with a
specific E2 for catalytic transfer. Thus E3 ligases recruited by PROTACs for degradation of
target proteins should be considered more as specific E2:E3 ligase pairs, rather than autonomous
actors in the ubiquitin-proteasomal system [121].
6.6 Ubiquitylation of proteins is reversible in vivo: de-ubiquitinating enzymes (DUBs)
As a final consideration or caveat, along with the focus on PROTAC-induced degradation
through polyubiquitylation of target proteins, a counter-acting cellular process should be kept in
mind, i.e. de-ubiquitination of proteins by a family of de-ubiquitinating enzymes or DUBs
(ubiquitinyl hydrolases or thiolesterases, EC 3.4.19.12). Much like the albeit relatively smaller
38
family of phosphatases employed by the cell to reverse effects of protein kinase phosphorylation
of regulated proteins, the DUBs are a smaller family relative to the E3 ligases and serve a similar
function, i.e. reverse the effects of covalent modification with a small protein or polymers
thereof. In fact, TGF- family signaling pathways have been shown to be controlled by de-
ubiquitination by DUBs.[109, 122]
7. Conclusion
Induced protein degradation is an event-driven means of elimination of targets, in contrast to
simple and conventional inhibition through occupancy-driven mechanisms. The clinical
potential of induced protein degradation mediated by small molecules has been clearly
established by two drugs (fulvestrant, a SERD and lenalidomide, an IMiD) that were not
designed as such but subsequently found to act through degradative mechanisms (cf.
Introduction). Two inductive avenues have been observed to lead to proteasomal degradation of
target proteins: chaperone-mediated (cf. 2.1 – 2.4) and by enzyme-catalyzed polyubiquitylation.
The latter has been the focus of drug discovery in recent years, in particular the modular design
of PROTACs, which hijack E3 ubiquitin ligases to modify specific targets and induce
proteasomal degradation (cf. 3.1 – 3.3). A roster of examples presented within (cf. 4.1 – 4.10)
demonstrate the applicability of the chimeric inducers for targeting the large and clinically
important family of protein kinases. Beyond these paradigms, a case was made for seeing
protein kinases not as isolated entities, but as components of multi-protein complexes which
offer additional sites for E3 ligase binding and modification of lysine residues (cf. 5.1 – 5.4).
Finally, because this review has focused on degradation of proteins mediated by
polyubiquitylation, a caveat was made that modification with ubiquitin protein moieties can have
39
a multitude of non-degradative effects which should be kept in mind, such as inhibition of
degradation and activation of protein kinases (cf. 6.1 – 6.6).
8. Expert opinion
In marked contrast to conventional occupancy-based inhibitors, therapeutics that act through an
event-driven mechanism offer significant advantages, primarily with respect to dynamics, since
steady-state levels of inhibitors need not be maintained. Of the avenues identified to date (cf.
Table 1), inducers of protein degradation appear to be the most desirable and have already been
proven in the clinic, albeit in a limited number of cases reflecting the relative infancy of the field.
Molecular-genetic modification of nucleic acids, though powerful, is only recently showing true
promise and might reach the clinic well into the future, if at all. That is to say, gene-silencing of
RNAs has only recently emerged as efficacious due to barriers to introduction, despite the initial
promise and excitement following the award of a Nobel prize for the ground-breaking studies. In
a similar vein, gene-editing methods such as CRISPR-Cas9 (Cas9: CRISPR-associated nuclease
9, a translocase of a new class of EC 7 hydrolases) remain plagued by off-target effects, which
though likely to be resolved, might be much less a concern than the ethical barriers which
ultimately could keep the method out of clinics and restricted to a laboratory research tool. With
respect to protein targets, covalent inhibitors (active and allosteric site) offer the benefits of
event-driven therapeutics, are surprisingly non-toxic and commercially successful (aspirin,
penicillin). The major barrier to the widespread application of this class is the requirement for a
specific nucleophilic group at the binding site to react with an electrophilic warhead on the drug.
Thus, small molecule inducers of protein degradation, in particular PROTACs, have emerged as
the leading candidates from the wide repertoire of event-driven therapeutics currently on hand.
40
In the case of protein kinases, targeting with PROTACs offers even more than the
pharmacodynamic benefits, in that an additional, often times much-needed layer of specificity
can be imparted by the E3 ligase interactions with the substrate protein or complex. Moreover,
substantially less effort might be needed to generate preclinical leads for further development.
That is, even target-selective inhibitors with modest affinity and specificity would suffice when
paired with E3 ligase interactions and limited lysine substrate accessibility. As a result, drug
discovery might prove dramatically less computationally intensive for rational design avenues, or
require less extensive screening of compound libraries. Since both require a great deal of
expertise and resources, typically limited to well-staffed and well-funded groups in industry or
academia, with the growing implementation of PROTAC design and synthesis, the entry level
into drug development would likely be lowered, allowing more and more laboratories to
productively engage in translational projects that can contribute to the volume of the flow of
candidates in or into commercial pipelines and/or clinical trials. In keeping with the expected
growth in adoption of the methodology by laboratories with modest resources, modular
components for synthesis of PROTACs as well as promiscuous test compounds have recently
become commercially available (Tocris, R&D Systems; Life Sensors).
Though much remains to be explored and many hurdles need to be overcome such as
enhanced permeability of the relatively large chimeras, characterization of other E3 ligases and
screening for corresponding bait ligands [1], development of occupancy-based protein kinase
inhibitors is anticipated to continue to shift toward protein degraders over the next five years, as
evidenced by the last. With the substantial investments by major pharmaceutical companies in
inducers of protein degradation in general (cf. Introduction), due to the long-standing interest in
protein kinases throughout the industry and the encouraging proofs-of-concept presented above
41
(cf. 4.1 – 4.10), a dramatic increase in safe and efficacious therapeutics targeting this large and
clinically important family of enzymes is expected to reach the clinic to treat a wide range of
pathologies, not the least of which are the many protein kinase-linked cancers.
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