Abstract
Germline aberrations in critical DNA-repair and DNA damage–response (DDR) genes cause cancer predisposition, whereas various tumors harbor somatic mutations causing defective DDR/DNA repair. The concept of synthetic lethality can be exploited in such malignancies, as exemplified by approval of poly(ADP-ribose) polymerase inhibitors for treating BRCA1/2-mutated ovarian cancers. Herein, we detail how cellular DDR processes engage various proteins that sense DNA damage, initiate signaling pathways to promote cell-cycle checkpoint activation, trigger apoptosis, and coordinate DNA repair. We focus on novel therapeutic strategies targeting promising DDR targets and discuss challenges of patient selection and the development of rational drug combinations.
Significance: Various inhibitors of DDR components are in preclinical and clinical development. A thorough understanding of DDR pathway complexities must now be combined with strategies and lessons learned from the successful registration of PARP inhibitors in order to fully exploit the potential of DDR inhibitors and to ensure their long-term clinical success. Cancer Discov; 7(1); 20–37. ©2016 AACR.
Introduction
Failure to accurately repair damaged DNA in cells manifests in various clinical phenotypes, including neurodegeneration, infertility, immunodeficiencies, and cancer susceptibility (1, 2). Furthermore, the production of DNA damage in cells following exposure to carcinogens increases cancer risk (3). Germline mutations in genes encoding key players in the DNA-damage response (DDR), including BRCA1, BRCA2, BLM, FANCA, TP53, RAD51C, and MSH2, result in cancer susceptibility syndromes (1), in part because failure to adequately protect the genome against endogenous and exogenous sources of DNA damage results in the accumulation of oncogenic mutations. Genomic instability is therefore a recognized hallmark of cancer (3).
Cancer cells often harbor a reduced repertoire of DNA-repair and DNA-damage signaling capabilities compared with normal cells, and in some cases cancers also upregulate mutagenic repair pathways that drive oncogenesis (4). Consequently, cancer cells are often more reliant on a subset of repair pathways and are therefore more susceptible to DDR inhibition than are normal cells that maintain full DNA-repair/DDR capacity. Faulty cell-cycle checkpoint activation and suboptimal DNA-repair capability in cancer cells also result in replication stress and subsequent accumulation of DNA damage in tumors. In addition, cancer cells often have dysfunctional redox homeostasis and therefore rely heavily on mechanisms that repair oxidative DNA damage, as well as on enzymes that counteract the incorporation of oxidized DNA precursors into genomic DNA (5, 6). Both replication and oxidative stress, as well as other processes such as telomere attrition, provide a background of ongoing DNA damage in cancer cells that can provide potential therapeutic windows for compounds that exacerbate these processes. Such compounds may achieve this by stressing replication further, impairing the ability of cancer cells to handle high levels of replicative or oxidative pressures, or potentially inhibiting DNA repair and associated processes (5–7). Such issues have led to intense interest in the therapeutic development of specific inhibitors of a range of components of the DDR network, several of which are now in clinical testing (8).
A well-recognized sensor of DNA damage is the protein poly(ADP-ribose) polymerase (PARP), which is best known for its role in DNA base excision repair (BER) and repair of DNA single-strand breaks (SSB; Table 1 and Fig. 1; ref. 9), although it also has a less well-defined role in DNA double-strand break (DSB) repair by alternative nonhomologous end-joining (alt-NHEJ; Table 1 and Fig. 1; ref. 10). The clinical development of PARP inhibitors in patients with germline BRCA1/2 mutations stemmed from the robust preclinical data that demonstrated exquisite sensitivity of BRCA1/2-mutant cells and tumors to PARP inhibition (11, 12). It was correctly hypothesized that in these patients, the cancer cells (in which both alleles of either BRCA1 or BRCA2 have been mutated or deleted) would depend on PARP activity for survival, whereas normal cells (that maintain a fully functional copy of BRCA1 or BRCA2) would not. Although these findings were initially thought to be due to a reliance of BRCA1/2-mutant cells on SSB repair for survival, it has since become well recognized that PARP trapping and the subsequent generation of replication-dependent DSBs also contributes significantly to the synthetic lethal relationship between PARP and BRCA. In addition, the PARP family of enzymes plays key roles in multiple cellular processes beyond DNA repair, including cellular differentiation, gene transcription, inflammation, mitosis, cell death, and metabolism, which may contribute to the antitumor activity of PARP inhibitors (13, 14). Synthetic lethality between repair pathways has provided a paradigm for many current clinical strategies targeting DNA repair/DDR. Detailed reviews of the underlying mechanisms-of-action and clinical applications of PARP inhibitors have previously been published and are beyond the scope of this article (15–19).
Predominant DNA repair pathways
Double-strand break repair pathways | |
Classic (c)-NHEJ |
|
Homology-directed repair | |
Homologous recombination (HR) |
|
Alternative (Alt)-NHEJ or MMEJ |
|
Single-strand annealing (SSA) |
|
Other repair pathways | |
Interstrand cross-link (ICL) repair |
|
SSB repair |
|
BER |
|
Translesion synthesis (TLS) |
|
Nucleotide excision repair (NER) |
|
Mismatch repair (MMR) |
|
Double-strand break repair pathways | |
Classic (c)-NHEJ |
|
Homology-directed repair | |
Homologous recombination (HR) |
|
Alternative (Alt)-NHEJ or MMEJ |
|
Single-strand annealing (SSA) |
|
Other repair pathways | |
Interstrand cross-link (ICL) repair |
|
SSB repair |
|
BER |
|
Translesion synthesis (TLS) |
|
Nucleotide excision repair (NER) |
|
Mismatch repair (MMR) |
|
Table showing predominant sensors, signaling, and effector proteins for major DNA repair pathways. Pathways of DSB repair are in blue-shaded area; pathways of SSB repair are in red-shaded area. Main targets of drug development are in red (see the text for details).
Table showing predominant sensors, signaling, and effector proteins for major DNA repair pathways. Pathways of DSB repair are in blue-shaded area; pathways of SSB repair are in red-shaded area. Main targets of drug development are in red (see the text for details).
In this review, we summarize the current status of PARP inhibitors and then look beyond these, focusing on other protein components of the cellular DDR, which include proteins that sense DNA damage, initiate signaling pathways that promote cell-cycle checkpoint activation, and coordinate the repair of damaged DNA with various other cellular processes. We highlight how such DDR enzymes represent rational targets for the discovery of novel therapeutics (Fig. 1) and detail the development and future potential of such compounds. We also discuss the numerous challenges of discovering predictive biomarkers of response for optimal patient selection and the development of promising DDR combinations, including molecularly targeted agents, compounds inhibiting epigenetic targets, and immune checkpoint inhibitors.
Targeting of DNA-Damage Sensor Proteins
DDR sensor proteins detect the region of damaged DNA and direct ensuing cellular responses that include activation of one or more repair pathways. For DSBs, Ku (comprising the Ku70/Ku80 protein heterodimer) and the MRE11–RAD50–NBS1 complex (MRN) are the predominant sensor protein complexes. Ku binds DNA DSBs within seconds of their being generated and serves as a platform for the subsequent recruitment of classic (c)-NHEJ proteins. The MRN complex plays key roles in triggering activation of the DNA-damage signaling kinase ataxia telangiectasia mutated (ATM), initiation of DNA end resection, and promotion of repair by homologous recombination (HR). Chromatin context, transcriptional status, cell-cycle stage, and extent of end resection are all factors that contribute to the selection of DNA repair, either by HR or by NHEJ, and the mechanisms determining the choice of DNA-repair pathway are an intense area of active research (20, 21). Other DNA-damage sensors include components of the Fanconi anemia core complex (FANCA, B, C, E, F, G, L, and M), mismatch-repair proteins (MSH2, MSH3, MSH6, MLH1, and PMS2), and nucleotide excision repair proteins (XPC, DDB2, and CSA), which are sensors of DNA interstrand cross-links, base–base mismatches, or insertion–deletion loops and UV-induced photo-lesions (in particular cyclobutane pyrimidine dimers and pyrimidine 6–4 pyrimidone photoproducts), respectively (Table 1).
There are 17 PARP family members, of which PARP1 has the predominant role in DNA repair, with PARP2 and to a lesser extent PARP3 functioning in fewer, but overlapping, DNA-repair processes (22). Through binding to single-stranded DNA breaks, DNA nicks, or DSBs, PARP catalytic function is activated to generate extensive poly(ADP-ribose) chains (PAR chains) on itself and proteins in the vicinity of DNA damage. These PAR chains and PARP itself then promote the recruitment of critical SSB repair proteins, such as XRCC1, to SSBs and modify chromatin structure to facilitate DNA repair (9). PARP auto-PARylation is also required for the dissociation of PARP from DNA-damage sites (23, 24). Enzymatic inhibition by PARP inhibitors therefore results in both the suppression of SSB repair and BER, which molecularly converges with SSB repair in its downstream stages. Inhibition also results in the trapping of PARP to SSBs, causing the stalling and subsequent collapse of DNA replication forks, resulting in replication-dependent DNA DSBs (23, 24). Such DSBs would normally be repaired by HR; however, in HR-deficient cells, such as BRCA1/2-mutant tumors, less effective and lower-fidelity methods of repair are utilized, which result in unsustainable levels of damage, chromosomal fusions/translocations, and ultimately cell death (20, 25).
Following strong preclinical findings predicting a therapeutic rationale, early clinical trials assessing the PARP inhibitor olaparib (Lynparza; AstraZeneca) demonstrated multiple durable antitumor responses in patients with advanced germline BRCA1/2-mutated ovarian, breast, or castration-resistant prostate cancer (CRPC; refs. 26, 27). This patient benefit was confirmed in later-phase clinical trials (28–31), eventually leading to clinical registration. Olaparib is now approved by the European Medicines Agency (EMA) as maintenance therapy for responding patients with BRCA1/2-mutant ovarian cancer following platinum-based chemotherapy. It was also granted accelerated approval by the FDA for use in patients with advanced BRCA1/2-mutant ovarian cancers, while confirmatory trials are being completed. Most recently, olaparib was given breakthrough therapy designation for treatment of BRCA1/2 or ATM mutated metastatic CRPC in patients who have received a prior taxane-based chemotherapy and at least one newer hormonal agent. Another potent PARP inhibitor, rucaparib (Clovis), has also recently been granted breakthrough therapy status by the FDA following the results of the phase II ARIEL2 trial (32) for use as monotherapy in patients with BRCA1/2-mutant (germline or somatic) advanced ovarian cancer after at least two prior lines of platinum-containing therapies (33). There are additional potent and selective PARP inhibitors in late-phase monotherapy and combination clinical trial development, including niraparib (MK4827; Tesaro), talazoparib (BMN673; Medivation), and veliparib (ABT-888; AbbVie).
Although PARP inhibition is undeniably an effective treatment for BRCA1/2-mutated cancers, with response rates in the region of 50% for platinum-sensitive ovarian cancers (33), the overwhelming majority of patients will ultimately develop tumor resistance. Genetic reversion events that restore BRCA1/2 gene function have been identified in PARP inhibitor–resistant cell lines, platinum-resistant patient-derived cell lines, and tumors from patients who have developed clinical resistance to PARP inhibitors (34). In addition, in Brca1-null mouse embryonic stem cells, loss of DDR factors such as 53BP1 at least partially rescues HR by removing a barrier to DNA end resection (35, 36), although this has yet to be rigorously identified as a resistance mechanism in the clinic. A number of critical challenges therefore remain to optimize the clinical efficacy and widen the utility of PARP inhibitors. Identifying mechanisms of PARP inhibitor resistance remains a critical challenge; others include the development of promising PARP inhibitor combination regimens and the analytic validation of clinically meaningful predictive biomarker assays to identify HR-deficient tumors caused by BRCA1/2 mutations or by other mechanisms (33).
Targeting of DNA-Damage Signaling Proteins
By triggering various protein posttranslational modifications and promoting the assembly of protein complexes, DDR signaling proteins amplify and diversify the damage signal within a cell and coordinate the most appropriate cellular responses, including transcriptional changes, cell-cycle checkpoint activation, alternative splicing, engagement of DNA repair processes, or, in the context of overwhelming damage, activation of cell senescence or apoptotic pathways (1). DNA DSB signaling events are largely coordinated by the apical phosphatidylinositol 3-kinase-related kinases (PIKK) DNA-PKcs (DNA-dependent serine/threonine protein kinase catalytic subunit), ATM, and ATR (ataxia telangiectasia and RAD3-related protein; Fig. 2).
DNA DSB repair signaling pathways through the apical DDR kinases. A, DNA-PK: Ku binds to DNA DSBs and recruits DNA-PKcs. Upon DNA binding, autophosphorylation of DNA-PKcs induces a conformational change that destabilizes the NHEJ core complex, causing sliding of Ku inward on the DNA and enabling access of end-processing and ligation enzymes to DNA ends and facilitation of repair. B, ATM: following DSBs ATM is predominantly activated through interactions with NBS1 of the MRN complex. ATM is the principal kinase responsible for phosphorylation of histone H2AX on serine 139 (known as γH2AX). MDC1 (mediator of DNA-damage checkpoint protein 1) directly binds γH2AX and potentiates DNA-damage signaling leading to spreading of γH2AX to over a megabase from its initial lesion. This in turn promotes recruitment and retention of DNA-damage mediator proteins such as 53BP1. CHK2 is a well-studied ATM substrate. C, ATR: ATR is activated by replication protein A (RPA) bound to ssDNA. The ATR–CHK1 signaling cascade activates the G2–M checkpoint, promotes replication fork stabilization, and slows DNA replication by suppressing origin firing.
DNA DSB repair signaling pathways through the apical DDR kinases. A, DNA-PK: Ku binds to DNA DSBs and recruits DNA-PKcs. Upon DNA binding, autophosphorylation of DNA-PKcs induces a conformational change that destabilizes the NHEJ core complex, causing sliding of Ku inward on the DNA and enabling access of end-processing and ligation enzymes to DNA ends and facilitation of repair. B, ATM: following DSBs ATM is predominantly activated through interactions with NBS1 of the MRN complex. ATM is the principal kinase responsible for phosphorylation of histone H2AX on serine 139 (known as γH2AX). MDC1 (mediator of DNA-damage checkpoint protein 1) directly binds γH2AX and potentiates DNA-damage signaling leading to spreading of γH2AX to over a megabase from its initial lesion. This in turn promotes recruitment and retention of DNA-damage mediator proteins such as 53BP1. CHK2 is a well-studied ATM substrate. C, ATR: ATR is activated by replication protein A (RPA) bound to ssDNA. The ATR–CHK1 signaling cascade activates the G2–M checkpoint, promotes replication fork stabilization, and slows DNA replication by suppressing origin firing.
DNA-PK
DNA-PKcs activity is essential for effective repair by classic NHEJ, which is the predominant DNA repair pathway of DSBs in human cells, occurring through all phases of the cell cycle (Fig. 2A). DNA-PK is composed of Ku plus a ∼460-kDa catalytic subunit (DNA-PKcs), the activity of which is dependent on Ku-mediated DNA DSB binding (37). Ku binds to DNA DSBs and serves as a platform for the recruitment of other core NHEJ proteins, including DNA-PKcs, XRCC4, LIG4, XLF, and PAXX, among others (38, 39). Upon DNA binding, autophosphorylation of DNA-PKcs induces a conformational change that destabilizes the NHEJ core complex, causing inward sliding of Ku on the DNA and enabling access of end-processing and ligation enzymes to DNA ends to facilitate repair (37). Autophosphorylation also stimulates the dissociation of DNA-PKcs from DNA and Ku and inactivates the kinase activity of DNA-PK (38). The best described substrate for DNA-PK is DNA-PK itself, with autophosphorylation occurring at multiple sites (37).
In addition to being important for the repair of exogenous DNA DSBs, classic NHEJ also plays crucial roles in the repair of endogenous DSBs arising during physiologic processes, such as V(D)J and class-switch recombination (40). Mice with a disrupted Prkdc gene have severe combined immunodeficiency, as well as radiosensitivity (40). In addition, DNA-PK has an established role in innate immunity and proinflammatory signaling, which are important issues to consider with respect to long-term treatment with DNA-PK inhibitors, as well as the potential for combination approaches with immune-modulating agents (37). Interestingly, DNA-PK has also long been known to have links to transcription (41), and studies are currently ongoing to investigate the mechanisms by which transcriptional regulation by DNA-PK affects DNA repair (42).
DNA-PK mutants lacking kinase activity, or treatment of cells with small-molecule inhibitors of DNA-PK kinase activity, cause the latter to be stabilized on DNA ends, impeding NHEJ and also likely interfering with other repair processes, including HR, by obstructing DNA end resection (38). As it plays key roles in repair by NHEJ, DNA-PK inhibition profoundly hypersensitizes cells and tumor xenografts to replication-independent DSB-inducing agents, such as radiotherapy and topoisomerase 2 inhibitors (43). In contrast, DNA-PK inhibition alone has very little effect on cancer cell or tumor viability (43), perhaps because most endogenous DSBs arise in the context of DNA replication, where the preferred repair pathway is HR. These compounds are therefore predicted to be associated with modest antitumor activity as monotherapy, whereas there is potential for antitumor synergy in combination with DNA-damaging agents, albeit with a potentially narrow therapeutic index because of associated effects on normal cells in the patient.
The clinical development of DNA-PK inhibitors with high potency and selectivity in vitro has been complicated by inadequate pharmacokinetic (PK) properties. However, a number of novel DNA-PK inhibitors have recently entered clinical development (Table 2). For instance, MSC2490484A (Merck KGaA; NCT02316197) is being evaluated in phase I trials as monotherapy and in combination with radiotherapy, and a phase I trial of VX-984 (Vertex Pharmaceuticals) in combination with liposomal doxorubicin has recently started recruitment (NCT02644278). A dual inhibitor of DNA-PK and TOR kinase (a downstream effector of PI3K–AKT pathway signaling and another member of the PIKK family) is CC-115 (Celgene), which was developed through lead optimization of existing mTOR inhibitors (44). In preclinical studies, CC-115 inhibits proliferation and induces caspase-dependent cell death in chronic lymphoid leukemia (CLL) cells and also leads to death of CLL cells resistant to the PI3Kδ inhibitor idelalisib (45). The relative importance of DNA-PK versus TOR inhibition in this setting has however not been fully elucidated. In a recently reported phase I trial involving patients with advanced solid and hematologic malignancies, CC-115 was well tolerated, with preliminary antitumor activity observed (46). There has been some suggestion that CC-115 may have greater activity in patients with CLL harboring biallelic ATM loss, although the mechanism for this has yet to be established (45).
Monotherapy and combination trials involving DDR inhibitors that have completed or are currently recruiting (www.clinicaltrials.gov)
Target . | Agent . | Phase . | Intervention . | Cancer(s) enrolled . | Status/results . | Trial identifier . | Ref. . |
---|---|---|---|---|---|---|---|
DNA-PK | MSC2490484A | I | MSC2490484A | Solid tumors, CLL | Recruiting | NCT02316197 | — |
MSC2490484A | I | MSC2490484A ± RT | Solid tumors | Recruiting | NCT02516813 | — | |
VX-984 | I | VX-984 ± PLD | Solid tumors | Recruiting | NCT02644278 | — | |
CC-115a | I | CC-115 | GBM, HNSCC, prostate, ES, CLL | 37% (3/8) PR in relapsed ATM-mutant CLL | NCT01353625 | (45, 46) | |
ATM | AZD0156 | I | AZD0156 ± olaparib | Solid tumors | Recruiting | NCT02588105 | — |
ATR | VX-970 ± chemotherapy | I | VX-970 ± carboplatin | Solid tumors | Recruiting | EudraCT: 2013-005100-34 | (67, 68) |
I | VX-970 ± gemcitabine, etoposide, cisplatin or carboplatin | Solid tumors | Recruiting | NCT02157792 | (69, 70) | ||
II | Gemcitabine ± VX-970 (randomized) | Ovarian, primary peritoneal or Fallopian tube | Recruiting | NCT02595892 | — | ||
I | VX-970 + irinotecan | Solid tumors | Recruiting | NCT02595931 | — | ||
II | Carboplatin + gemcitabine ± VX-970 (randomized) | Advanced gynecologic cancers | Not yet recruiting | NCT02627443 | — | ||
I/II | VX-970 + topotecan | Advanced NSCLC, SCLC, Gynae or neuroendocrine | Recruiting | NCT02487095 | — | ||
II | Cisplatin + gemcitabine ± VX-970 (randomized) | Advanced urothelial | Recruiting | NCT02567409 | — | ||
VX-970 ± RT | I | Cisplatin + RT ± VX-970 | Locally advanced HNSCC | Recruiting | NCT02567422 | — | |
I | Whole brain RT + VX-970 | NSCLC brain metastases | Recruiting | NCT02589522 | — | ||
VX-970 + targeted therapy | I | VX-970 + veliparib + cisplatin | Solid tumors | Recruiting | NCT02723864 | — | |
AZD6738 | I | AZD6738 | Relapsed CLL, PLL, B-cell lymphomas | Complete, full results awaited | NCT01955668 | — | |
AZD6738 ± chemotherapy | I | AZD6738 ± carboplatin, olaparib or MEDI4736 | Solid tumors, HNSCC, ATMloss NSCLC, gastric or GOJ carcinoma | Recruiting | NCT02264678 | — | |
I | AZD6738 + paclitaxel | Solid tumors | Recruiting | NCT02630199 | — | ||
AZD6738 + RT | I | AZD6738 + palliative RT | Solid tumors | Recruiting | NCT02223923 | — | |
CHK1 | MK8776 (SCH 900776) | II | Cytarabine ± MK8776 (randomized) | Relapsed AML | Complete, full results awaited | NCT01870596 | — |
I | Gemcitabine + MK8776 | Relapsed lymphoma | Complete, full results awaited | NCT00779584 | (72) | ||
I | Cytarabine + MK8776 | Relapsed AML | 33% (8/24) CR | NCT00907517 | (158) | ||
LY2603618 | I/II | Cisplatin/pemetrexed ± LY2603618 | NSCLC | 14% (2/14) PR | NCT01139775 | (159) | |
I/II | Gemcitabine ± LY2603618 | Pancreatic carcinoma | Complete, full results awaited | NCT00839332 | — | ||
II | Pemetrexed + LY2603618 | NSCLC | Complete, full results awaited | NCT00988858 | — | ||
I | LY2603618 + pemetrexed or gemcitabine | Solid tumors | Complete, full results awaited | NCT01296568 | — | ||
I | LY2603618 + gemcitabine | Solid tumors | Complete, full results awaited | NCT01341457 | (73) | ||
I | LY2603618 + pemetrexed | Solid tumors | Complete, full results awaited | NCT00415636 | — | ||
CCT245737 | I | CCT245737 | Solid tumors | Recruiting | NCT02797964 | — | |
I | CCT245737 + cisplatin and/or gemcitabine | Solid tumors | Recruiting | NCT02797977 | — | ||
GDC-0575 ± chemotherapy | I | GDC-0575 ± gemcitabine | Solid tumors, relapsed lymphoma | Complete, full results awaited | NCT01564251 | — | |
CHK1/2 | LY2606368 | II | LY2606368 | Refractory SCLC | Recruiting | NCT02735980 | — |
II | LY2606368 | Ovarian, breast, prostate | Recruiting | NCT02203513 | — | ||
II | LY2606368 | Solid tumors | Recruiting | NCT02873975 | — | ||
I | LY2606368 | Solid tumors | 4% (2/45) PR—anal SCC, HNSCC | NCT01115790 | (76) | ||
I | LY2606368 | Solid tumors | Recruiting | NCT02778126 | — | ||
I | LY2606368 | Solid tumors | Recruiting | NCT02514603 | — | ||
I | LY2606368 | Pediatric solid tumors | Recruiting | NCT02808650 | — | ||
LY2606368 + chemotherapy | I | LY2606368 + fludarabine + cytarabine | Relapsed AML, high risk MDS | Recruiting | NCT02649764 | — | |
I | LY2606368 + cisplatin, cetuximab, pemetrexed, fluorouracil and/or leucovorin | Solid tumors | Recruiting | NCT02124148 | — | ||
LY2606368 + targeted therapy | I | LY2606368 + ralimetinib (MAPK inhibitor) | Solid tumors | Recruiting | NCT02860780 | — | |
LY2606368 + RT | I | LY2606368 + RT + cisplatin or cetuximab | Locally advanced HNSCC | Recruiting | NCT02555644 | — | |
WEE1 | AZD1775 | II | AZD1775 | SCLC | Recruiting | NCT02593019 | — |
I | AZD1775 | Solid tumors | 8% (2/25) PR: BRCA-mutant ovarian, BRCA-mutant HNSCC | NCT01748825 | (82) | ||
I | AZD1775 | Solid tumors | Recruiting | NCT02482311 | (160) | ||
I | AZD1775 | Solid tumors | Recruiting | NCT02610075 | — | ||
AZD1775 + chemotherapy | II | Carboplatin/paclitaxel ± AZD1775 | Ovarian, TP53mut | Complete, full results awaited | NCT01357161 | (85) | |
II | Carboplatin + AZD1775 | Ovarian, TP53mut, or platinum resistant |
| NCT01164995 | (84) | ||
II | Gemcitabine ± AZD1775 | Ovarian, primary peritoneal, or fallopian | Recruiting | NCT02101775 | — | ||
II | Carboplatin/pemetrexed ± AZD1775 | NSCLC, 1st line | Complete, full results awaited | NCT02087241 | — | ||
II | Docetaxel + AZD1775 | NSCLC, 2nd line | Closed | NCT02087176 | — | ||
II | Carboplatin/paclitaxel + AZD1775 | NSCLC | Recruiting | NCT02513563 | — | ||
II | Paclitaxel weekly + AZD1775 | Gastric carcinoma | Recruiting | NCT02448329 | — | ||
II | Cisplatin ± AZD1775 | HNSCC | Complete, full results awaited | NCT02196168 | — | ||
I/II | Gemcitabine/nab-paclitaxel ± AZD1775 | Pancreatic | Recruiting | NCT02194829 | — | ||
I/II | Irinotecan + AZD1775 | Pediatric solid tumors | Recruiting | NCT02095132 | — | ||
I | Cisplatin/docetaxel + AZD1775 | Locally advanced HNSCC | Recruiting | NCT02508246 | — | ||
I | Gemcitabine, cisplatin or carboplatin + AZD1775 | Solid tumors | PR in 17/176 (10%). RR higher in TP53-mutated vs. wild-type patients: 21% (n = 19) vs. 12% (n = 33) | NCT00648648 | (83) | ||
AZD1775 + targeted therapy | I | AZD1775 + olaparib (PARP inhibitor) | Solid tumors | Complete, full results awaited | NCT02511795 | (161) | |
AZD1775 + Belinostat (HDAC inhibitor) | AML, other myeloid malignancies | Recruiting | NCT02381548 | — | |||
AZD1775 + RT | I/II | Radiation + gemcitabine + AZD1775 | Pancreatic | Recruiting | NCT02037230 | — | |
I | Radiation + cisplatin + AZD1775 | HNSCC | Recruiting | NCT02585973 | (162) | ||
I | RT + cisplatin + AZD1775 | Locally advanced cervical cancer | Recruiting | NCT01958658 | — | ||
I | Radiation + temozolomide + AZD1775 | GBM | Recruiting | NCT01849146 | — | ||
I | Radiation + AZD1775 | Pediatric DIPG | Recruiting | NCT01922076 | — | ||
AZD1775 + immune checkpoint inhibitor | I | MEDI4736 + AD1775 | Solid tumors | Recruiting | NCT02617277 | — | |
BER | TRC102 | I | TRC102 | Solid tumors, lymphoma | Complete, full results awaited | NCT01851369 | (90) |
TRC102 + chemotherapy | II | TRC102 + temozolomide | GBM | Recruiting | NCT02395692 | — | |
I/II | TRC102 + cisplatin and/or pemetrexed | Solid tumors | Recruiting | NCT02535312 | — | ||
I | TRC102 + pemetrexed | Solid tumors | 4% (1/28) PR: HNSCC | NCT00692159 | (89) | ||
I | TRC102 + fludarabine | Hematologic malignancies | Complete, full results awaited | NCT01658319 | — | ||
TRC102 + RT | I | TRC + RT + cisplatin ± pemetrexed | NSCLC | Recruiting | NCT02535325 | — |
Target . | Agent . | Phase . | Intervention . | Cancer(s) enrolled . | Status/results . | Trial identifier . | Ref. . |
---|---|---|---|---|---|---|---|
DNA-PK | MSC2490484A | I | MSC2490484A | Solid tumors, CLL | Recruiting | NCT02316197 | — |
MSC2490484A | I | MSC2490484A ± RT | Solid tumors | Recruiting | NCT02516813 | — | |
VX-984 | I | VX-984 ± PLD | Solid tumors | Recruiting | NCT02644278 | — | |
CC-115a | I | CC-115 | GBM, HNSCC, prostate, ES, CLL | 37% (3/8) PR in relapsed ATM-mutant CLL | NCT01353625 | (45, 46) | |
ATM | AZD0156 | I | AZD0156 ± olaparib | Solid tumors | Recruiting | NCT02588105 | — |
ATR | VX-970 ± chemotherapy | I | VX-970 ± carboplatin | Solid tumors | Recruiting | EudraCT: 2013-005100-34 | (67, 68) |
I | VX-970 ± gemcitabine, etoposide, cisplatin or carboplatin | Solid tumors | Recruiting | NCT02157792 | (69, 70) | ||
II | Gemcitabine ± VX-970 (randomized) | Ovarian, primary peritoneal or Fallopian tube | Recruiting | NCT02595892 | — | ||
I | VX-970 + irinotecan | Solid tumors | Recruiting | NCT02595931 | — | ||
II | Carboplatin + gemcitabine ± VX-970 (randomized) | Advanced gynecologic cancers | Not yet recruiting | NCT02627443 | — | ||
I/II | VX-970 + topotecan | Advanced NSCLC, SCLC, Gynae or neuroendocrine | Recruiting | NCT02487095 | — | ||
II | Cisplatin + gemcitabine ± VX-970 (randomized) | Advanced urothelial | Recruiting | NCT02567409 | — | ||
VX-970 ± RT | I | Cisplatin + RT ± VX-970 | Locally advanced HNSCC | Recruiting | NCT02567422 | — | |
I | Whole brain RT + VX-970 | NSCLC brain metastases | Recruiting | NCT02589522 | — | ||
VX-970 + targeted therapy | I | VX-970 + veliparib + cisplatin | Solid tumors | Recruiting | NCT02723864 | — | |
AZD6738 | I | AZD6738 | Relapsed CLL, PLL, B-cell lymphomas | Complete, full results awaited | NCT01955668 | — | |
AZD6738 ± chemotherapy | I | AZD6738 ± carboplatin, olaparib or MEDI4736 | Solid tumors, HNSCC, ATMloss NSCLC, gastric or GOJ carcinoma | Recruiting | NCT02264678 | — | |
I | AZD6738 + paclitaxel | Solid tumors | Recruiting | NCT02630199 | — | ||
AZD6738 + RT | I | AZD6738 + palliative RT | Solid tumors | Recruiting | NCT02223923 | — | |
CHK1 | MK8776 (SCH 900776) | II | Cytarabine ± MK8776 (randomized) | Relapsed AML | Complete, full results awaited | NCT01870596 | — |
I | Gemcitabine + MK8776 | Relapsed lymphoma | Complete, full results awaited | NCT00779584 | (72) | ||
I | Cytarabine + MK8776 | Relapsed AML | 33% (8/24) CR | NCT00907517 | (158) | ||
LY2603618 | I/II | Cisplatin/pemetrexed ± LY2603618 | NSCLC | 14% (2/14) PR | NCT01139775 | (159) | |
I/II | Gemcitabine ± LY2603618 | Pancreatic carcinoma | Complete, full results awaited | NCT00839332 | — | ||
II | Pemetrexed + LY2603618 | NSCLC | Complete, full results awaited | NCT00988858 | — | ||
I | LY2603618 + pemetrexed or gemcitabine | Solid tumors | Complete, full results awaited | NCT01296568 | — | ||
I | LY2603618 + gemcitabine | Solid tumors | Complete, full results awaited | NCT01341457 | (73) | ||
I | LY2603618 + pemetrexed | Solid tumors | Complete, full results awaited | NCT00415636 | — | ||
CCT245737 | I | CCT245737 | Solid tumors | Recruiting | NCT02797964 | — | |
I | CCT245737 + cisplatin and/or gemcitabine | Solid tumors | Recruiting | NCT02797977 | — | ||
GDC-0575 ± chemotherapy | I | GDC-0575 ± gemcitabine | Solid tumors, relapsed lymphoma | Complete, full results awaited | NCT01564251 | — | |
CHK1/2 | LY2606368 | II | LY2606368 | Refractory SCLC | Recruiting | NCT02735980 | — |
II | LY2606368 | Ovarian, breast, prostate | Recruiting | NCT02203513 | — | ||
II | LY2606368 | Solid tumors | Recruiting | NCT02873975 | — | ||
I | LY2606368 | Solid tumors | 4% (2/45) PR—anal SCC, HNSCC | NCT01115790 | (76) | ||
I | LY2606368 | Solid tumors | Recruiting | NCT02778126 | — | ||
I | LY2606368 | Solid tumors | Recruiting | NCT02514603 | — | ||
I | LY2606368 | Pediatric solid tumors | Recruiting | NCT02808650 | — | ||
LY2606368 + chemotherapy | I | LY2606368 + fludarabine + cytarabine | Relapsed AML, high risk MDS | Recruiting | NCT02649764 | — | |
I | LY2606368 + cisplatin, cetuximab, pemetrexed, fluorouracil and/or leucovorin | Solid tumors | Recruiting | NCT02124148 | — | ||
LY2606368 + targeted therapy | I | LY2606368 + ralimetinib (MAPK inhibitor) | Solid tumors | Recruiting | NCT02860780 | — | |
LY2606368 + RT | I | LY2606368 + RT + cisplatin or cetuximab | Locally advanced HNSCC | Recruiting | NCT02555644 | — | |
WEE1 | AZD1775 | II | AZD1775 | SCLC | Recruiting | NCT02593019 | — |
I | AZD1775 | Solid tumors | 8% (2/25) PR: BRCA-mutant ovarian, BRCA-mutant HNSCC | NCT01748825 | (82) | ||
I | AZD1775 | Solid tumors | Recruiting | NCT02482311 | (160) | ||
I | AZD1775 | Solid tumors | Recruiting | NCT02610075 | — | ||
AZD1775 + chemotherapy | II | Carboplatin/paclitaxel ± AZD1775 | Ovarian, TP53mut | Complete, full results awaited | NCT01357161 | (85) | |
II | Carboplatin + AZD1775 | Ovarian, TP53mut, or platinum resistant |
| NCT01164995 | (84) | ||
II | Gemcitabine ± AZD1775 | Ovarian, primary peritoneal, or fallopian | Recruiting | NCT02101775 | — | ||
II | Carboplatin/pemetrexed ± AZD1775 | NSCLC, 1st line | Complete, full results awaited | NCT02087241 | — | ||
II | Docetaxel + AZD1775 | NSCLC, 2nd line | Closed | NCT02087176 | — | ||
II | Carboplatin/paclitaxel + AZD1775 | NSCLC | Recruiting | NCT02513563 | — | ||
II | Paclitaxel weekly + AZD1775 | Gastric carcinoma | Recruiting | NCT02448329 | — | ||
II | Cisplatin ± AZD1775 | HNSCC | Complete, full results awaited | NCT02196168 | — | ||
I/II | Gemcitabine/nab-paclitaxel ± AZD1775 | Pancreatic | Recruiting | NCT02194829 | — | ||
I/II | Irinotecan + AZD1775 | Pediatric solid tumors | Recruiting | NCT02095132 | — | ||
I | Cisplatin/docetaxel + AZD1775 | Locally advanced HNSCC | Recruiting | NCT02508246 | — | ||
I | Gemcitabine, cisplatin or carboplatin + AZD1775 | Solid tumors | PR in 17/176 (10%). RR higher in TP53-mutated vs. wild-type patients: 21% (n = 19) vs. 12% (n = 33) | NCT00648648 | (83) | ||
AZD1775 + targeted therapy | I | AZD1775 + olaparib (PARP inhibitor) | Solid tumors | Complete, full results awaited | NCT02511795 | (161) | |
AZD1775 + Belinostat (HDAC inhibitor) | AML, other myeloid malignancies | Recruiting | NCT02381548 | — | |||
AZD1775 + RT | I/II | Radiation + gemcitabine + AZD1775 | Pancreatic | Recruiting | NCT02037230 | — | |
I | Radiation + cisplatin + AZD1775 | HNSCC | Recruiting | NCT02585973 | (162) | ||
I | RT + cisplatin + AZD1775 | Locally advanced cervical cancer | Recruiting | NCT01958658 | — | ||
I | Radiation + temozolomide + AZD1775 | GBM | Recruiting | NCT01849146 | — | ||
I | Radiation + AZD1775 | Pediatric DIPG | Recruiting | NCT01922076 | — | ||
AZD1775 + immune checkpoint inhibitor | I | MEDI4736 + AD1775 | Solid tumors | Recruiting | NCT02617277 | — | |
BER | TRC102 | I | TRC102 | Solid tumors, lymphoma | Complete, full results awaited | NCT01851369 | (90) |
TRC102 + chemotherapy | II | TRC102 + temozolomide | GBM | Recruiting | NCT02395692 | — | |
I/II | TRC102 + cisplatin and/or pemetrexed | Solid tumors | Recruiting | NCT02535312 | — | ||
I | TRC102 + pemetrexed | Solid tumors | 4% (1/28) PR: HNSCC | NCT00692159 | (89) | ||
I | TRC102 + fludarabine | Hematologic malignancies | Complete, full results awaited | NCT01658319 | — | ||
TRC102 + RT | I | TRC + RT + cisplatin ± pemetrexed | NSCLC | Recruiting | NCT02535325 | — |
Abbreviations: AML, acute myeloid leukemia; CLL, chronic lymphocytic leukemia; CR, complete response; CRUK, Cancer Research UK; DIPG, diffuse intrinsic pontine gliomas; ES, Ewing sarcoma; GBM, glioblastoma multiforme; GOJ, gastro-oesphageal carcinoma; HDAC, histone deacetylase; HGSOC, high-grade serous ovarian carcinoma; HNSCC, head and neck squamous cell carcinoma; mAb, monoclonal antibody; MDS, myelodysplastic syndrome; NCI, National Cancer Institute; NSCLC, non–small cell lung carcinoma; ORR, objective response rate; PFS, progression-free survival; PLD, pegylated liposomal doxorubicin; PLL, prolymphocytic leukemia; PR, partial response; RT, radiotherapy; SCLC, small cell lung carcinoma.
aDual DNA-PK and mTOR inhibitor.
ATM
Similar to DNA-PK, ATM promotes DNA DSB repair in cells and responds to DSBs generated throughout the cell cycle. Inherited mutations in the ATM gene result in the autosomal recessive condition ataxia telangiectasia, a syndrome characterized by progressive cerebellar ataxia, oculocutaneous telangiectasia, radiosensitivity, predisposition to lymphoid malignancies, and immunodeficiency, with defects in both cellular and humoral immunity (47). A number of different factors have now been identified that promote ATM activation; however, following DNA DSBs, ATM is predominantly activated through interactions with NBS1 of the MRN complex (Fig. 2B; refs. 48, 49). ATM is the principal kinase responsible for the phosphorylation of histone H2AX on serine 139 (known as γH2AX; ref. 50), although some functional redundancy exists with ATR and DNA-PK. MDC1 (mediator of DNA damage checkpoint protein-1) binds directly to γH2AX (51) and potentiates the DNA-damage signal, leading to the spreading of γH2AX to over a megabase from its initial lesion (52). This amplification is thought to help sustain the DDR signal to enable sufficient recruitment and retention of DNA-damage mediator proteins such as 53BP1 at sites of DNA damage, which can be visualized as foci in DNA-damaged cells.
Phospho-proteomic studies have identified hundreds of ATM substrates (53), although the physiologic relevance of many of these proteins is currently unknown. A well-recognized substrate of ATM is CHK2, the activity of which is predominantly, but not exclusively, important for G1–S phase checkpoint activation (54). ATM is also important for the stabilization of p53 through the phosphorylation and subsequent inhibition of proteosomal degradation by MDM2 (54).
ATM inhibition has been demonstrated to hypersensitize cells to ionizing radiation and the DNA DSB-inducing agents etoposide, camptothecin, and doxorubicin (55). A phase I trial of the ATM inhibitor AZD0156 (AstraZeneca) is currently under way as monotherapy and in combination with olaparib and other cytotoxic or molecularly targeted agents (NCT02588105; Table 2). Although there are likely to be other ATM inhibitors in development, to our knowledge none have reached clinical studies.
ATR
Although also important for DSB repair, the context for ATR activation is different from ATM and DNA-PK. ATR is activated by replication protein A (RPA)–bound ssDNA, which can arise as a result of stalled replication forks and also occurs following DNA end resection during the early stages of HR (Fig. 2C; ref. 56). ATR is recruited to RPA–ssDNA by its obligate binding partner ATR-interacting protein (ATRIP) and is activated by topoisomerase binding partner 1 (TOPBP1) in complex with the RAD17-RFC2-5 clamp loader, the 9-1-1 complex (RAD9–RAD1–HUS1), Claspin, and RHINO (57). CHK1 is the best described substrate of ATR, and once activated by ATR, CHK1 serves to inhibit cyclin-dependent kinase (CDK) activity through the phosphorylation of CDC25A. As such, CHK1 is a critical regulator of the G2–M and intra-S cell-cycle checkpoints (Fig. 2C; ref. 58). Interestingly, recent preclinical studies have demonstrated that both ATR and CHK1 have distinct roles in the regulation of the intra-S checkpoint. ATR appears particularly important for the suppression of replication catastrophe in early S-phase cells through the promotion of ribonucleotide reductase accumulation and by limiting origin firing (59). In contrast, other S-phase cells are capable of recovering from replication insults through a CHK1-mediated backup mechanism (59). A synthetic lethal relationship has now been established between ATR and CHK1 inhibition, with combination blockade leading to replication fork arrest, single-stranded DNA accumulation, replication collapse, and synergistic cell death in cancer cells in vitro and in vivo (60).
In addition, a third checkpoint kinase has now been identified (MK2; MAPKAP-K2), which functions independently of CHK1, downstream of ATM and ATR to maintain G2–M and intra-S phase arrest (61–63). To our knowledge, there are currently no MK2 inhibitors in clinical development, although preclinical work has demonstrated interesting synergy between MK2 and CHK1 inhibitors, particularly in KRAS-mutant tumors (64).
VX-970 (Vertex Pharmaceuticals) is a first-in-class ATR inhibitor, with preclinical data demonstrating chemosensitization of lung cancer cells predominantly to chemotherapeutics that result in replication fork collapse, such as cisplatin and gemcitabine in vitro, and increased antitumor activity in combination with cisplatin in vivo (65, 66). Preliminary phase I trial data have shown that VX-970 is well tolerated as monotherapy with no dose-limiting toxicities or grade 3–4 adverse events demonstrated up to weekly intravenous doses of 480 mg/m2 (67). A durable response evaluation criteria in solid tumors (RECIST) complete response was observed in a patient with metastatic ATM-deficient colorectal cancer, who remained on single-agent VX-970 for more than 20 months. When VX-970 was combined with carboplatin, although the maximum tolerated dose was not established because there was no more than one dose-limiting toxicity at each dose level, the recommended phase II dose (RP2D) was VX-970 90 mg/m2 + carboplatin AUC 5 based on carboplatin dose delays observed at higher dose levels. Crucially, paired tumor biopsy studies undertaken at this RP2D showed significant inhibition of ATR-targeted phosphorylation of Ser345 on CHK1, confirming target modulation. At the RP2D, a patient with platinum-refractory, PARP inhibitor–resistant, germline BRCA1- and TP53-mutant advanced high-grade serous ovarian cancer achieved a RECIST partial response and gynecologic cancer intergroup (GCIG) CA125 tumor marker response lasting 6 months. As expected from the predicted mechanism-based toxicity profile of an ATR inhibitor and platinum chemotherapy, myelosuppression (neutropenia and thrombocytopenia) was the most commonly observed treatment-related toxicity (68). Combination trials with VX-970 and a number of other chemotherapeutics, including cisplatin and gemcitabine, are ongoing, with promising antitumor responses observed in chemotherapy-resistant patients with advanced solid cancers (refs. 69, 70; Table 2). AZD6738 (AstraZeneca) is an oral ATR inhibitor currently being assessed in phase I clinical trials as monotherapy or in combination regimens with olaparib, carboplatin, radiotherapy, or the immune-checkpoint inhibitor durvalumab (MEDI4736; AstraZeneca). The optimal scheduling and sequencing of these agents with their respective partners, in order to balance the tradeoff between antitumor activity and bone-marrow toxicity, is not yet clear, and full results of these trials are awaited with interest.
CHK1
Preclinically, CHK1 inhibitors have demonstrated the most synergy with drugs that generate replication-dependent DNA damage such as antimetabolites, and therefore clinical development has focused on their use in combination with such drugs (71). MK8776 (Merck & Co.) is a potent and selective CHK1 inhibitor that is well tolerated as a monotherapy, as well as in combination with gemcitabine (Table 2; ref. 72). Results from a recently published phase I trial of MK8776 as monotherapy or in combination with gemcitabine have shown preliminary evidence of clinical efficacy, with 2 of 30 patients (7%) having a partial response and 13 of 30 (43%) demonstrating stable disease (72). As expected, toxicity was more frequent in combination, and included fatigue, nausea, anorexia, thrombocytopenia, neutropenia, and transient dose-related electrocardiogram (ECG) abnormalities, specifically QTc prolongation. The recommended phase II dose of MK8776 is 200 mg, with gemcitabine administered at 1,000 mg/m2 on days 1 and 8 of a 21-day cycle. LY2603618 (Eli Lilly) is a selective CHK1 inhibitor being evaluated at both 170 mg and 230 mg in combination with gemcitabine (Table 2; ref. 73). Preliminary results reported RECIST partial responses in 4 of 17 patients, with mainly hematologic toxicities observed, and 3 patients discontinuing treatment because of adverse events. A phase I trial of the CHK1 inhibitor CCT245737 (Sareum Holdings Plc.) as monotherapy and in combination with cisplatin and gemcitabine has recently started accrual (NCT02797977 and NCT02797964; Table 2).
CHK2
There is some uncertainty as to whether the inhibition of CHK2 will be beneficial in the clinical setting, and at present there are no selective CHK2 inhibitors in clinical development (71). Genetic deletion of the mouse Chek2 gene alleviates p53-dependent cell death following irradiation, and although the mechanisms for this protection have not been fully defined, there is a hypothetical risk that inhibition of CHK2 may be radioprotective in a clinical setting (74). Further studies are required to determine the appropriate clinical context in which CHK2 inhibition may lead to antitumor activity (75). Several of the early cell-cycle checkpoint inhibitors, such as LY2606368 (Prexasertib; Eli Lilly), are dual inhibitors of CHK1 and CHK2, and many of these have now discontinued clinical development due to lack of efficacy. LY2606368 has undergone evaluation in a phase I trial, defining a RP2D of 105 mg/m2 every 14 days, with a predominant toxicity of myelosuppression (Table 2; ref. 76). Evidence of single-agent activity was observed, with 2 of 45 patients achieving a RECIST partial response (one with anal cancer and one with head and neck squamous cell carcinoma), whereas 15 of 45 (33.3%) patients obtained clinical benefit with radiologic stable disease. The trial is expanding, preferentially in patients with squamous histology tumors, and several combination strategies are currently ongoing.
WEE1
Working in parallel with CHK1, the WEE1 protein kinase also plays a critical role in the activation of the G2–M checkpoint through the regulation of cyclin-dependent kinases (77, 78). Unlike CHK1, however, WEE1 is not directly regulated by DNA damage, but is required for physiologic cell-cycle progression. CDK1 Tyr15 phosphorylation by WEE1 inhibits CDK1 activity, resulting in inactivation of the CDK1/CCNB1 complex and G2–M checkpoint activation (79). The predominant mechanism-of-action of WEE1 inhibitors was initially believed to be failure of the G2–M checkpoint due to inappropriate CDK1/CCNB1 activation, resulting in mitotic catastrophe (79). More recently, however, it has become clear that WEE1 inhibition also generates replication-dependent DNA damage in cells, due to aberrant DNA replication through CDK2 inhibition (80, 81). The first-in-class WEE1 kinase inhibitor AZD1775 (MK1775; AstraZeneca) has been shown to potentiate the cytotoxic effects of a range of DNA-damaging agents and demonstrate single-agent activity in preclinical models (77). AZD1775 has been evaluated in a single-agent phase I clinical trial (82), where a maximum tolerated dose of 225 mg twice daily for 2.5 days per week for two weeks in three-week cycles was established (Table 2). Dose-limiting toxicities reported were reversible supraventricular tachycardia and myelosuppression, with common toxicities including myelosuppression and diarrhea. The study noted evidence of single-agent activity with RECIST partial responses in two germline BRCA1-mutant patients (papillary serous ovarian and squamous cell carcinoma of the head and neck). Proof-of-mechanism target modulation was demonstrated in paired tumor biopsies demonstrating reduced CDK1 Tyr15 phosphorylation levels and increased γH2AX levels after treatment.
Recently published data from a phase I trial of AZD1775 in combination with gemcitabine, cisplatin, or carboplatin demonstrated that chemotherapy combinations with AZD1775 were safely tolerated, with superior response rates in TP53-mutated (21%) compared with TP53 wild-type patients (12%; ref. 83). Interestingly, there is also evidence that WEE1 inhibition may reverse platinum resistance, as the combination of AZD1775 and carboplatin has shown antitumor activity in patients with TP53-mutant, platinum-resistant/refractory ovarian cancer, with a published RECIST partial response rate of 38% (n = 8) and complete response rate of 5% (n = 1; Table 2; ref. 84). Preliminary data from a phase II trial of AZD1775 in combination with carboplatin and paclitaxel versus chemotherapy alone in patients with platinum-sensitive TP53-mutant ovarian cancer demonstrated a superior progression-free survival (PFS) benefit (hazard ratio 0.55, CI, 0.32–0.95, P = 0.030), with common toxicities, including nausea, diarrhea, alopecia, and fatigue (Table 2; ref. 85). There is now a need to better define the patient populations predicted to respond to AZD1775 monotherapy and novel combination regimens, and numerous biomarker-driven clinical trials with AZD1775 are currently ongoing to address such questions (Table 2).
Targeting of DDR Effector Proteins and Repair Pathways
DDR events converge on one or more repair pathways that are dedicated to specific types of DNA damage (Fig. 1 and Table 1). Some established antitumor agents result in a single type of DNA lesion (e.g., topoisomerase inhibitors), whereas others generate a heterogeneous mixture of DNA damage types, engaging multiple repair pathways simultaneously (e.g., radiotherapy). Although NHEJ and HR remain the predominant DSB repair pathways, the importance of alternative homology-directed repair mechanisms is also now recognized (20). These are mutagenic pathways that are able to “backup” standard repair processes, which have been either genetically or chemically compromised. Although there are multiple attractive DNA-repair and DDR effector protein targets, there are still only a limited number of drugs currently in clinical development that target such proteins.
AP endonuclease-1 (APE1) recognizes abasic (AP) sites generated following the removal of damaged bases by DNA glycosylases, and its endonuclease activity is essential for BER (86). In addition, APE1 harbors exonuclease activity important for the removal of 3′ obstructive lesions in DNA, including chain-terminating nucleoside analogues (87). TRC102 (Methoxyamine; TRACON Pharmaceuticals) reacts with abasic sites to cause an AP adduct that is resistant to APE1 action (88), exacerbating the cytotoxicity of alkylating agents and antimetabolites in cells. Hematologic toxicities were dose-limiting for TRC102 in combination with pemetrexed or temozolomide (89, 90), and other early-phase combination trials are ongoing (Table 2).
Recent studies have demonstrated that HR-deficient cells rely on error-prone microhomology-mediated end-joining (MMEJ; also known as alt-NHEJ) for survival (25, 91). The polymerase activity of POLQ (DNA polymerase theta) is required for gap-filling during MMEJ, and POLQ also prevents hyper-recombination by limiting RAD51 accumulation at resected DNA ends (25, 91). POLQ is therefore an attractive drug target, particularly in the context of HR-deficient tumors. The development of small-molecule inhibitors that target protein–protein interactions of the RAD51 recombinase family is also ongoing (92). Targeting protein–protein interactions is challenging and has had limited success, although compounds have been identified that disrupt the self-association of RAD51 and successfully inhibit the interaction between RAD51 and BRCA1 (92). These compounds have the potential to inhibit RAD51-dependent HR in cells, and the demonstration of such effects in functional cellular assays is awaited.
Fine-Tuning the DDR
Each step of the DDR is tightly regulated by reversible posttranslational modifications (PTM), including phosphorylation, ADP-ribosylation, methylation, acetylation, ubiquitylation, sumoylation, and neddylation (93–96). Although DDR-specific kinase and ADP-ribosylation inhibitors are already in clinical development/use, given the essential role of ubiquitylation and deubiquitylation in the DDR, modulating DNA repair through the use of specific inhibitors of ubiquitylation, deubiquitylation, or the ubiquitin–proteasome system is an active area of research (96, 97). HR is particularly sensitive to proteasome inhibition (98), and proteasome inhibitors such as bortezomib (Velcade; Takeda Pharmaceutical Company Ltd.) have been shown to block global ubiquitylation in cells and disrupt protein turnover of several DDR proteins, such as MDC1, BRCA1, and RPA (99–101). Inhibiting a subset of ubiquitin ligases, namely the cullin-ring-ligases (CRL), through inhibition of neddylation (the covalent attachment of the ubiquitin-like protein NEDD8 to target proteins) in cells also affects the DDR (93, 102). Pevonedistat (MLN4924; Takeda Pharmaceutical Company Ltd.) inhibits the NEDD8 E1, blocking NEDD8 conjugation and CRL activity in cells (103). A phase I study of pevonedistat showed that an intermittent dosing schedule was generally well tolerated, with hepatotoxicity being dose-limiting (104). In preclinical studies, pevonedistat exhibited particular synergy with DNA cross-linking agents (105, 106), and phase I combination studies are currently ongoing.
PTMs are reversible, with such turnover being important for various cellular processes. It is perhaps unsurprising therefore that deubiquitylating enzymes (DUB) also play key roles in promoting DNA repair in cells. Indeed, various DUBs are attractive drug targets (96), with several DUB inhibitors currently in preclinical development. Analogously, poly(ADP-ribose) glycohydrolase (PARG) catalyzes the hydrolysis of poly(ADP-ribose) and therefore reverses the effects of PARP. Inhibition of PARG, in a similar fashion to PARP inhibition, leads to DNA damage that depends on HR for repair (107), and efforts are ongoing to generate specific PARG inhibitors for clinical use (108).
Several other classes of compounds have demonstrated inhibitory effects on the DDR, which may potentially be exploited in a clinical setting. Chromatin compaction significantly affects DNA repair (21), and the chromatin modifying inhibitors vorinostat (Zolonza; Merck) and romidepsin (Istodax; Celgene) are both approved for the treatment of cutaneous T-cell lymphoma (109). As well as relieving chromatin compaction, these histone deactylase (HDAC) inhibitors also transcriptionally downregulate a number of DSB repair proteins, thereby hypersensitizing cells to DSB-inducing agents and providing a strong rationale for combination treatment with DNA-damaging compounds (110, 111). There are numerous other compounds in preclinical and clinical development that have inhibitory effects on DNA repair through targeting epigenetic modifier enzymes, such as EZH2 (H3K27 methyltransferase; ref. 112), HDACs (111), and G9A (histone lysine N-methyl-transferase; ref. 113).
Patient Selection
PARP inhibitors are selectively toxic to tumor cells with biallelic mutations/loss of BRCA1 or BRCA2 (BRCA1/2; refs. 11, 12), and olaparib is the first oncology drug to be licensed with a companion genetic diagnostic (BRCAnalysis CDx). Such a level of “synthetic lethality” has yet to be reproduced with any other DDR inhibitor. The effectiveness of PARP inhibitors is not restricted to patients with germline or somatic BRCA1/2 mutations, however, and significant efforts are under way to determine tumors that are essentially HR deficient through other mechanisms (15). Genomic approaches to achieve this include studies undertaken to identify mutations in single HR and/or other genes that predict for PARP inhibitor sensitivity (114, 115). In addition, DNA-repair dysfunction has the potential to lead to global DNA aberrations; the presence of a genome-wide mutational signature (or genomic scar) that occurs in the context of chronic HR deficiency may thus also be a useful biomarker that is predictive of PARP inhibitor sensitivity (116). Scoring systems that measure genomic defects reflective of HR deficiency are also being utilized, including those that quantify loss of heterozygosity (LOH), telomeric allelic imbalance, and large-scale state transitions (defined as a chromosomal break between adjacent segments of DNA of at least 10 Mb) within tumors (117).
The hypermethylation of genes and other epigenetic effects means that focusing entirely on genomics will ultimately fail to identify all patients who are likely to benefit from a molecularly targeted cancer therapy. To address this issue, functional assays of HR deficiency have been pursued and have included the detection of RAD51 foci at DNA-damage sites in breast cancer biopsies following neoadjuvant chemotherapy, where a failure to generate RAD51 foci in cells was strongly predictive of a pathologic complete response (P = 0.011; ref. 118). To date, however, there is no robust strategy to clinically determine which patients will benefit from PARP inhibitors outside of the BRCA1/2-mutant population, and it may be that a combination of functional and genomic approaches is required.
Beyond PARP inhibitors, preclinical data have demonstrated synergy between ATR inhibition and impaired ATM signaling, particularly in the context of exogenous DNA damage (119). The mechanism for this synergy has yet to be defined; however, clinical studies exploring ATR inhibition in the context of ATM loss are ongoing (68). Certainly, a number of studies suggest that high levels of replication stress and, consequently, increased endogenous DNA damage in tumors may be required for hypersensitivity to ATR inhibitor monotherapy. Overexpression of oncogenes such as CCNE1, CCND2, and MYC, adversely affects DNA replication by disrupting origin firing and replication progression, resulting in oncogene-induced replication stress (7). In keeping with this, CCNE1 amplification exaggerates the hypersensitivity of TP53-deficient cells to ATR inhibition (120), and both ATR and CHK1 inhibitors are particularly toxic for Myc-driven lymphomas in mice (121). In addition, oncogenic stress as a result of activating KRAS mutations has been shown to hypersensitize cells to ATR inhibition (122), and selecting tumors with oncogene-induced replication stress has the potential to provide a much-needed therapeutic window for ATR inhibitor/chemotherapy combination strategies.
The physical ends of linear chromosomes, telomere ends, are naturally occurring DNA DSBs in cells that are protected by the Shelterin protein complex in order to prevent DDR activation (123). Maintaining telomere length is essential for the genomic stability of replicating cells and involves the concerted actions of several key DDR players, including ATM, ATR, DNA-PK, and Ku (124, 125). Telomere maintenance is achieved through telomerase activation in 85% of cancers, and telomerase recruitment to telomeres is dependent on ATM and ATR activity in human cells (125). ATR activity has also been shown to be important for alternative lengthening of telomeres (ALT; ref. 126), a mechanism that relies on recombination events to maintain telomere length. In keeping with this, preclinical data have been published demonstrating hypersensitivity of ALT tumor cells to ATR inhibition (126). Given the role of the DDR PIKKs in telomere maintenance, DNA-PK, ATM, and ATR inhibitors all have the potential to negatively affect telomere length in cells. Although this may potentially contribute to their antitumor effects, it may also result in detrimental genomic instability in replicating non-cancer cell populations.
It is currently too preliminary to establish if TP53 deficiency, ATM loss/mutation, ALT reliance, or CCNE1, CCND2, or MYC oncogene activation will predict for sensitivity to ATR inhibitors in the clinic, but it is likely that this will be a far-from-exhaustive list of putative genomic predictive biomarkers, and having a functional marker of replication stress in tumors will be helpful. Surrogate markers of replication stress might include phosphorylation of ATR substrates (e.g., CHK1pS345 and RPApS33) or levels of single-stranded DNA (59). How these markers might change over time and with treatment is, of course, currently unknown, and the usefulness of measuring these biomarkers in archival tumor specimens has yet to be tested.
Combination Strategies
Combining DDR inhibitors with DNA-damaging agents has been the natural first step in the clinical development of combination strategies for DDR inhibitors (Table 2). A thorough understanding of the DNA lesions induced by different chemotherapies and inhibition of the respective pathways required for repair will ultimately maximize the odds of synergistic antitumor efficacy. Nevertheless, toxicities will in many cases limit drug doses used in such combinations. Indeed, combining olaparib with carboplatin and paclitaxel chemotherapies in the clinic has been challenging because of myelosuppression, and reductions in the full single-agent doses of all drugs had to be undertaken to enable the combination to be administered safely (127, 128). Although olaparib showed promising data in a phase II trial of patients with advanced gastric cancer harboring ATM loss when combined with paclitaxel chemotherapy (129), there was no statistically significant survival benefit in the phase III GOLD trial (according to a May 18th, 2016, AstraZeneca press release). Optimizing drug scheduling may enable potential differences in repair kinetics of normal versus cancer cells to be exploited and may, therefore, increase damage in tumors while sparing normal tissue. Careful consideration of the sequence of combination drug administration is required to optimize synergistic effects. Equally, selecting patients with tumors of specific genotypes or phenotypes may produce a therapeutic window for such combinations.
Combining DDR inhibitors with small-molecule inhibitors of other cellular signaling pathways also shows promise, and PARP inhibition has been tested in combination with a number of agents. For example, an EGFR inhibitor combination has been explored following clinical data from the EURTAC trial showing that low BRCA1 mRNA levels were associated with longer PFS to erlotinib (Tarceva; Genentech; ref. 130). A phase I trial of olaparib with gefitinib (Iressa; AstraZeneca) demonstrated safety and tolerability, as well as promising signals of antitumor activity (131); a phase II trial is now accruing (132). Recent preclinical data also suggest that inhibition of the receptor tyrosine kinase c-MET hypersensitizes cells to PARP inhibition, and the clinical evaluation of this finding is likely to follow (133). Preclinical evidence of PI3K inhibition impairing BRCA1/2 expression and sensitizing tumor cells to PARP inhibition in both BRCA1/2-mutant and BRCA1/2–wild-type breast cancers (134, 135) has led to phase I combination trials of olaparib with the PI3K inhibitor buparlisib (BKM120; Novartis; ref. 136) and the AKT inhibitor AZD5363 (AstraZeneca; ref. 137), respectively. Preliminary data suggest that these combinations are tolerable and effective; final results are awaited with interest.
Preclinical evidence suggests that hypoxia results in impaired HR through the downregulation of HR-related genes (138–140). This provided the rationale for a phase I/II trial of the pan–VEGF1–3 inhibitor cediranib (AZD2171; AstraZeneca) with olaparib in patients with platinum-sensitive ovarian cancer (141). A PFS benefit of 8.7 months (hazard ratio 0.42; 95% CI, 0.23–0.76; P = 0.005) was demonstrated with the combination versus olaparib alone in the overall patient population, with predominant toxicities of fatigue, diarrhea, and hypertension observed in the combination arm. Interestingly, however, no PFS difference was observed between the two treatment arms in patients with BRCA1/2-mutated ovarian cancer.
Apart from molecularly targeted agents, we are also beginning to appreciate the considerable cross-talk between DNA repair and endocrine signaling (142). Steroid hormone signaling has been shown to promote NHEJ through transcriptional regulation of NHEJ components such as PRKDC, and has been demonstrated to have both positive and negative effects on HR depending on tumor model and context (142). In prostate cancer models, PARP1 has been demonstrated to support androgen transcriptional function and is required for transcriptional activation of the oncogenic fusion TMPRSS2–ERG protein found in >50% of prostate cancers. Dual blockade of PARP activity and androgen receptor signaling delays tumor growth compared with either as monotherapy in mouse xenograft prostate cancer models (143). This has led to trials combining PARP inhibitors with hormonal manipulation, such as olaparib with the CYP17 inhibitor abiraterone (Zytiga; Janssen Biotech; ref. 144).
There are also now multiple combination studies involving immune checkpoint inhibitors with DDR inhibitors, such as PARP and ATR inhibitors (Table 2). There is preclinical evidence to suggest that immune checkpoint inhibition synergizes with PARP inhibitor treatment in BRCA1-deficient tumors, and clinical trials investigating this hypothesis are ongoing (145). In addition, the success of anti–programmed cell death protein 1/programmed death-ligand 1 therapeutics in mismatch repair–deficient tumors (146) raises the intriguing question as to whether increasing mutational load with DDR inhibitors might increase the immunogenicity of cancers and subsequent responses to immunotherapy. Further studies are required to substantiate this hypothesis, and although high levels of microsatellite instability might prove to be a useful biomarker of response to immune checkpoint inhibitors, alternative mechanisms that might be driving sensitivity should not be discounted (147). Equally, we must be mindful that an intact DDR plays an important role in innate immunity (148). DDR signaling is important for the activation of inflammatory cytokines and induces the expression of immune-receptor ligands on damaged cells. As such, inhibitors of DDR signaling may in fact attenuate the immune response following DNA damage, and therefore immunotherapy–DDR inhibitor combination studies need to be carefully considered.
Future Perspectives and Conclusions
With multiple DDR inhibitors now in preclinical and clinical pipelines, careful consideration of their mechanisms-of-action is required in order to maximize their potential. DDR-deficient tumors should not be grouped indiscriminately into a class of tumors that may respond to any DDR inhibitor. Through closer collaborations between scientists and clinicians, we must insist on a rational rather than empirical approach to the clinical development of DDR inhibitors. A number of factors will be critical to ensure clinical success, including the development of analytically validated pharmacodynamic assays and predictive biomarkers of response and resistance. As we have observed with PARP inhibitors, managing the toxicities of DDR inhibitor/DNA-damaging agent combinations is likely to be challenging, and so clinicians should not shy away from aiming for a single-agent synthetic lethal approach that has already led to some success in the clinic. Much attention has focused on genetic alterations to key DDR drivers, but the relative contribution of somatic epigenetic loss of such DDR players has not been extensively explored. For example, the silencing of the BRCA1 gene through promoter hypermethylation has been demonstrated in breast and ovarian cancers (149), which highlights the importance of also considering functional biomarker assays, rather than relying on genomics in isolation.
Modern clinical trial designs will need to incorporate translational studies, which may be used to guide patient selection, drug scheduling, and treatment response (150). Early-phase trials should aim to consolidate preclinical understandings of drug mechanisms-of-action. Notably, understanding how many successful drugs function, including the PARP inhibitors, has changed over time, meaning that compounds showing preclinical promise should not be discounted on the basis of hypotheses that later appear to be incorrect. It is likely that combination regimens, with drugs given either together or sequentially to overcome resistance, will be required for the optimal application of these DDR inhibitors in the clinic. The use of longitudinal genomic profiling of circulating free DNA to support adaptive drug administration will also be important.
The long-term effects of inhibiting the DDR in patients are still not known and need further study. One recognized risk of DNA damage to normal tissue is the emergence of secondary cancers, particularly hematologic malignancies, following chemotherapy treatment and the potential mutagenic effects of inhibiting DNA repair. We will need to increase our clinical experience of DDR inhibitors before the long-term effects of these compounds are realized. Nevertheless, as PARP inhibitors move into the neoadjuvant and adjuvant settings, the malignant potential of these drugs must be monitored.
Precision medicine has heralded the advent of sophisticated modern technologies, which have permitted genomic profiling of both normal and tumor tissue at greater speeds and at lower costs than before. This has enabled the “real-time” identification of germline and somatic DNA repair gene aberrations, which has critical implications both for identifying families at risk of cancer predisposition and for predicting therapeutic responses to DDR inhibitors. Now that olaparib has been approved for clinical use and others will hopefully soon follow, we must not forget the lessons learned from the successful development of PARP inhibitors, nor ignore the multitude of opportunities that still exist within the DDR network, which now need to be exploited to have a positive impact on cancer medicine.
Disclosure of Potential Conflicts of Interest
T.A. Yap reports receiving commercial research grants and other commercial research support from AstraZeneca and Vertex; has served on advisory boards for Clovis and Pfizer; and has engaged in travel for AstraZeneca and Vertex. No potential conflicts of interest were disclosed by the other authors.
Grant Support
J.S. Brown, B. O'Carrigan, and T.A. Yap acknowledge support from the Experimental Cancer Medicine Centre (to The Institute of Cancer Research) and the National Institute for Health Research Biomedical Research Centre (jointly to the Royal Marsden NHS Foundation Trust and The Institute of Cancer Research). Research in The Jackson laboratory is funded by Cancer Research UK (CRUK) program grant number C6/A18796. Core funding is provided by CRUK (C6946/A14492) and the Wellcome Trust (WT092096). S.P. Jackson receives his salary from the University of Cambridge, UK, supplemented by CRUK.