Abstract
Basal-like breast cancers (BLBC) are aggressive breast cancers that respond poorly to targeted therapies and chemotherapies. In order to define therapeutically targetable subsets of BLBC we examined two markers: cyclin E1 and BRCA1 loss. In high grade serous ovarian cancer (HGSOC) these markers are mutually exclusive, and define therapeutic subsets. We tested the same hypothesis for BLBC. Using a BLBC cohort enriched for BRCA1 loss, we identified convergence between BRCA1 loss and high cyclin E1 protein expression, in contrast to HGSOC in which CCNE1 amplification drives increased cyclin E1. In cell lines, BRCA1 loss was associated with stabilized cyclin E1 during the cell cycle, and BRCA1 siRNA led to increased cyclin E1 in association with reduced phospho-cyclin E1 T62. Mutation of cyclin E1 T62 to alanine increased cyclin E1 stability. We showed that tumors with high cyclin E1/BRCA1 mutation in the BLBC cohort also had decreased phospho-T62, supporting this hypothesis. Since cyclin E1/CDK2 protects cells from DNA damage and cyclin E1 is elevated in BRCA1 mutant cancers, we hypothesized that CDK2 inhibition would sensitize these cancers to PARP inhibition. CDK2 inhibition induced DNA damage and synergized with PARP inhibitors to reduce cell viability in cell lines with homologous recombination deficiency, including BRCA1 mutated cell lines. Treatment of BRCA1 mutant BLBC patient-derived xenograft models with combination PARP and CDK2 inhibition led to tumor regression and increased survival. We conclude that BRCA1 status and high cyclin E1 have potential as predictive biomarkers to dictate the therapeutic use of combination CDK inhibitors/PARP inhibitors in BLBC.
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Introduction
Breast cancer with BRCA1 mutation most often manifests as basal-like breast cancer (BLBC)1, which presents difficulties for treatment as these cancers present at an earlier age, at a high grade, and with greater tumor burden. With the exception of immunotherapy/chemotherapy combination for PD-L1 positive patients2, there are currently no targeted therapies routinely used to treat BLBC3.
BRCA1 is a central component of the homologous recombination DNA repair pathway, and its loss results in compromised DNA damage repair4. Alterations to BRCA1 are important founder mutations for breast cancer5, and notably, more than 70% of BRCA1 mutation carriers develop early-onset BLBC based on gene expression profiling6. BRCA1 mutation directly drives the basal phenotype, and mice with Tp53 and Brca1 deletion develop mammary tumors with basal-like characteristics7 while intact Brca1 represses the transcription of basal cytokeratins8.
A previous report identified that BLBCs from patients with germline BRCA1 mutation was associated with high cyclin E1 protein expression9. Cyclin E1 is a cell cycle regulatory protein that activates cyclin-dependent kinase 2 (CDK2), and whose gain can promote both increased proliferation and genomic instability in cancer cells, and is frequently elevated in BLBC10. Perplexingly, in high grade serous ovarian cancer (HGSOC) cyclin E1 amplification and BRCA1/2 mutation are mutually exclusive, presumably because both aberrations drive genomic instability and together they precipitate lethal genomic damage11,12,13.
We recently described two subsets of HGSOC, one where cyclin E1 gene amplification and BRCA1 mutation were mutually exclusive, and another where high cyclin E1 protein expression was due to post–transcriptional deregulation rather than gene amplification, and was often concurrent with BRCA1/2 mutation13. Cyclin E1 protein stability is regulated by a multi-step process of specific phosphorylation and ubiquitination, leading to its cyclic expression and turnover14. Key regulators in the turnover of cyclin E1, such as the ubiquitin ligase component FBXW7 and the deubiquitinase USP28, are frequently dysregulated in cancer14,15,16 leading to altered stability of the cyclin E1 protein.
In this study, we examined whether BRCA1 loss and cyclin E1 gain occurred concurrently or independently in breast cancer. We also explored the mechanisms underpinning high cyclin E1 expression in BRCA1 mutated breast cancer including gene amplification and protein stability. Finally, we tested the hypothesis that disruption of cyclin E1/CDK2 function would sensitize BRCA1-mutant cells to PARP inhibition by enhancing synthetic lethality.
Results
BRCA1 inactivation associates with high cyclin E1 expression in breast cancer
We examined the KConFab cohort, which is enriched for familial cancer mutations, for co-occurrence of germline BRCA1 mutation and high cyclin E1 expression. First, we examined cyclin E1 expression by immunohistochemistry (IHC) (Fig. 1a). High cyclin E1 expression was defined as an H score cut-off of ≥45 based on the overall distribution of cyclin E1 expression (Supplementary Fig. 1a), and previous reports10,17. This cut-off was also associated with patient outcomes (minimal P value, Supplementary Table 1). Overall, germline BRCA1 mutated cancers had significantly higher cyclin E1 protein than the BRCA1 wildtype cases, and tumors with other breast cancer associated germline mutations (BRCA2, PALB2, or CHEK2) (Fig. 1b). Moreover, a significantly larger proportion of germline BRCA1 mutant cases (80.6%) had detectable cyclin E1 protein (83/103) compared to only 35.1% of BRCA1 wildtype tumors (47/134) (P < 0.0001, Fisher Exact test).
Notably, seven of the germline BRCA1 wildtype tumors had high cyclin E1. We hypothesized that these may be BRCA1 methylated since our cohort was selected for familial breast cancers where BRCA1 methylation was not infrequent18. Consequently, we examined the relationship between BRCA1 methylation and cyclin E1 protein expression by interrogating the breast cancer dataset of the TCGA. 241 cases had available data for BRCA1 methylation and cyclin E1 protein expression. Using a cut-off of 0.2 for methylation19, we found that BRCA1 methylation had a significant positive correlation with cyclin E1 protein expression (r = 0.647, p = 0.0082) (Fig. 1c).
Next, we examined the association between cyclin E1 expression and overall survival in germline BRCA1 mutated breast cancers in our cohort. High cyclin E1 expression was associated with a significantly reduced overall survival of patients with BRCA1 mutation (233 vs 426 months, P = 0.012, HR 0.39, CI 0.162–0.951) (Fig. 1d).
CCNE1 amplification is not the primary driver of high expression of cyclin E1 in BRCA1 mutated cancers
The CCNE1 gene, located at chromosome position 19q12, is a frequent site of amplification in cancer. We assessed CCNE1 amplification by in situ hybridization (ISH) analysis of tissue sections with a 19q12 probe and chromosome 19 control insulin receptor (INSR) probe to determine the 19q12/INSR ratio. Representative images of 19q12 non-amplified and 19q12 amplified tumors are shown in Fig. 1e. 13.1% (31/237) of tumors in the entire cohort were found to be 19q12 (CCNE1) amplified. The correlation between cyclin E1 protein and CCNE1 gene amplification was poor (r = 0.178, P = 0.006, Fig. 1f).
Next, we assessed whether CCNE1 amplification and BRCA1 mutation co-occurred. In contrast to HGSOC where they do not co-occur13, 22/103 (21.4%) of BRCA1 mutant cases had concurrent 19q12 (CCNE1) amplification (Supplementary Table 2). This was higher than BRCA1 wildtype cases, where only 9/134 (6.7%) had 19q12 (CCNE1) amplification (Fig. 1g). Since 19q12 (CCNE1) amplification is associated with poor survival in other cancer types we examined its relationship with overall survival in BRCA1 mutated breast cancer. Unlike high expression of cyclin E1, which is predictive of poor survival, 19q12 (CCNE1) amplification had no prognostic value for overall survival in BRCA1 mutated breast cancer (Fig. 1h).
The cyclin E1 degradation machinery is disrupted in BRCA1 mutated breast cancers
Since 19q12 status was only poorly predictive of high cyclin E1 expression, we thus investigated other mechanisms that lead to high cyclin E1 expression. One possibility was disruption of the proteasome-mediated degradation of cyclin E1, which occurs frequently in cancer20. Normal cyclin E1 turnover depends upon phosphorylation within two phospho-degrons on the cyclin E1 protein, of which T62 and T380 are crucial phosphorylation sites. The phosphorylated protein is recognized by the FBXW7 module of the SCFFBXW7 complex, and ubiquitinated for degradation14. The deubiquitinase USP28 can remove ubiquitin from cyclin E1 and antagonize FBWX7-mediated degradation15 (Fig. 2a). Disruption of this process, i.e., loss of cyclin E1 phosphorylation, loss of FBXW7 or gain in USP28, would be expected to increase cyclin E1 stabilization and accumulation.
We assessed the cyclin E1 degradation machinery by IHC in our familial breast cancer cohort. We first assessed cyclin E1 T62 phosphorylation in 204 cases (representative images in Fig. 2b). We observed only a moderate positive correlation between cyclin E1 T62 phosphorylation and cyclin E1 expression (r = 0.183, P = 0.009, Spearman), indicating that a proportion of cancers had very low cyclin E1 T62 phosphorylation (Fig. 2c). Consequently, we assessed the ratio of cyclin E1 phosphorylation to its absolute expression to determine if phosphorylation was specifically dysregulated in certain subsets of patients. We found that the BRCA1 and BRCA2 mutant subsets exhibited a significantly lower T62/cyclin E1 ratio (Fig. 2d), indicative of a loss of cyclin E1 phosphorylation in the absence of functional BRCA1 or BRCA2.
There was no correlation between cyclin E1 and FBXW7 found in our cohort (Fig. 2e, f). However, BRCA1 mutated cancers had higher expression compared to the BRCA2 mutant subset (Fig. 2g). In contrast, USP28 expression was moderately correlated with cyclin E1 expression (r = 0.416, P < 0.0001, Spearman) (Fig. 2h, i). USP28 protein expression was significantly higher in the BRCA1 mutated subset (Fig. 2j).
In summary, BRCA1 mutated breast cancers were characterized by reduced cyclin E1 T62 phosphorylation and elevated USP28 expression. Overall, these data implicate increased cyclin E1 protein stability, rather than gene amplification, as the cause for high cyclin E1 levels observed in BRCA1 mutated breast cancer.
BRCA1 loss leads to cell cycle stabilization of cyclin E1
Since the cyclin E1 degradation machinery was deregulated in BRCA1 mutant cancers across our cohort, we investigated whether cyclin E1 turnover is dysregulated in cell lines with mutant BRCA1 or BRCA1 loss. The BLBC cell line HCC1937 has a homozygous BRCA1 5382C* mutation and the triple negative breast cancer (TNBC) cell line MDA-MB-436 has a BRCA1 homozygous deletion. We compared these to 4 cell lines with wildtype BRCA1: BT-20 and MDA-MB-468 (BLBC cell lines), MDA-MB-231 (TNBC), and SkBr3 (HER2 amplified). Cells were analyzed for the expression of cyclin E1 during the cell cycle using flow cytometry. BT-20, MDA-MB-468, SkBr3, and MDA-MB-231 cells showed a typical downregulation of cyclin E1 during S phase (Fig. 3a), which we quantitated by comparing the expression of cyclin E1 during the second half of S phase versus the first half of S phase (Fig. 3b). The BRCA1 defective cell lines showed significantly diminished downregulation of cyclin E1 during S phase: in HCC1937 cells the cyclin E1 levels did not decrease in S phase, but instead marginally increased. There was a small decrease in the absolute expression of cyclin E1 during S phase in MDA-MB-436 cells (Fig. 3a, b).
We next investigated whether knockdown of BRCA1 was able to recapitulate the stabilization of cyclin E1. We treated BRCA1 wildtype MDA-MB-468 cells, with BRCA1 siRNA#11 and a BRCA1 siRNA pool. Both BRCA1 siRNAs treatments led to an increase of cyclin E1 protein (Fig. 3c). We simultaneously observed no increase in cyclin E1 T62 phosphorylation, indicating that there was lower relative phosphorylation of cyclin E1 (Fig. 3d). Thus the increased expression of cyclin E1 following depletion of BRCA1 protein was linked directly to lower phosphorylation on cyclin E1 T62.
Since cyclin E1 protein expression is dysregulated with BRCA1 disruption and we had observed both loss of T62 phosphorylation and gain of USP28 in our cohort, we sought to confirm that BRCA1 loss alters USP28 expression to stabilize cyclin E1. We tested whether BRCA1 knockdown stabilized cyclin E1 via upregulation of USP28. siRNA-mediated knockdown of USP28 in MDA-MB-231 cells led to decreased expression of cyclin E1 (Supplementary Fig. 2a). In contrast BRCA1 siRNA led only to downregulation of BRCA1 but did not change USP28 levels (Supplementary Fig. 2b). Thus while USP28 is elevated in BRCA1 mutant cancers, we could not detect its regulation directly downstream of BRCA1.
Loss of T62 phosphorylation of cyclin E1 increases cyclin E1 stability and contributes to increased cell survival
Since T62 dephosphorylation is associated with increased cyclin E1 protein stability, we analyzed the effect of disrupting the phospho-degrons on cyclin E1 by mutating phospho-sites to alanine to mimic the non-phosphorylated state. We performed site-directed mutagenesis within the two phospho-degrons of cyclin E1 (Fig. 4a). We created an N-terminal mutant (T62A, designated N-term), a C-terminal mutant (T376A/S380A, designated C-term), and a combined mutant (T62A/T376A/S380A, designated Dual) and stably expressed these in MDA-MB-468 BLBC cells (Fig. 4b).
We examined the effect of each mutant on the stability of the cyclin E1 protein by performing flow cytometry for the V5 tag protein during the cell cycle. We measured the fold change in each of the V5 tagged proteins between early and late S phase (Supplementary Fig. 3). All three mutants were significantly more stable than the wildtype cyclin E1 protein (Fig. 4c). Thus the T62A site in the N-terminus stabilizes the cyclin E1 protein, and particularly in combination with mutation of the C-terminal phospho-sites of cyclin E1.
Next, we examined the effect of each mutant on cell proliferation. Overexpression of cyclin E1 wildtype and each of the cyclin E1 mutants led to a significant increase in BrdU incorporation compared to the vector control (Fig. 4d).
Following this we examined whether these mutants were able to alter the survival of cells when treated with paclitaxel, a taxane chemotherapy used to treat BLBC clinically21. We treated vector control and cyclin E1 mutant cells with paclitaxel, and monitored survival by colony forming assay after 3–4 weeks. Only the Dual mutant cells demonstrated increased colony counts in the presence of paclitaxel compared to vector control (Fig. 4e, f).
Overall, BRCA1 loss led to decreased cyclin E1 T62 phosphorylation, which in turn can increase cyclin E1 protein stability and percentage of cells in S phase. Cyclin E1 T62 was also critical in combination with other cyclin E1 phosphorylation sites to increase cell survival in the presence of paclitaxel.
Synergistic targeting of cells with high cyclin E1 and BRCA1 mutation
Our data showing that BRCA1 loss is associated with elevated cyclin E1 protein, supporting the rationale of co-targeting these proteins. It has been demonstrated that BRCA1 deficiency leads to susceptibility to inhibition of poly (ADP-ribose) polymerase (PARP), whereas cyclin E1 activates the therapeutically targetable kinase CDK2. However, CDK2 also has important roles in DNA repair22, leading to increased sensitivity of BRCA1/2 mutant cancers to CDK2 inhibitors23. We thus hypothesized that treating BRCA1 mutant cancers with a combination of CDK2 and PARP inhibitors would be synergistic due to the simultaneous blockade of cyclin E1 dependent proliferation and exacerbated synthetic lethality from PARP inhibitors due to the additional DNA damage resulting from CDK2 inhibition.
First, we tested whether CDK2 inhibition induces DNA damage, by treating BRCA1 mutant HCC1937 cells with two CDK2 inhibitors, fadraciclib (CYC065)24, and CVT31325. We first established dose–response curves for fadraciclib and CVT313 (Supplementary Fig. 4). We then identified induction of DNA damage by both inhibitors using the alkaline Comet assay, which detects both double-strand and single-strand DNA breaks (Fig. 5a, b). While CVT313 is very specific to CDK225, fadraciclib targets CDK2, CDK5, and CDK9, but with the highest specificity to CDK224. CDK5 has negligible expression in HCC1937 cells26. We subsequently confirmed that DNA damage was occurring via CDK2 action following fadraciclib treatment by performing comet assays after treatment with CDK2 and CDK9 siRNA treatment. CDK2 siRNA treatment led to an increase in tail moment detection after 72 h of exposure at all doses (Fig. 5c). In contrast, there was no effect on DNA damage following CDK9 siRNA exposure (Fig. 5d).
Next, we examined the effect of combining CDK2 inhibition with PARP inhibition. We treated two BRCA1 wildtype (BT-20 and MDA-MB-468) and two BRCA1 mutant cell lines (HCC1937 and MDA-MB-436) with fadraciclib and rucaparib (a PARP inhibitor). Dose–response curves were established for each drug (Supplementary Fig. 4) and we then performed BLISS analysis to determine the effect of combining the two drugs. There was a significant synergy demonstrated with BLISS analysis between the two drugs at intersecting dose curves of fadraciclib and rucaparib. We observed additive to synergistic effects in the two BRCA1 mutant cell lines HCC1937 and MDA-MB-436 and in BRCA1 wildtype MDA-MB-468 cells (Fig. 5e, f, h). The BRCA1 wildtype cell line BT-20 displayed mainly additive effects between the two drugs (Fig. 5g).
It was surprising to observe that both BRCA1 wildtype cell lines displayed sensitivity to PARP inhibition, and MDA-MB-468 cells displayed a synergistic anti-proliferative response to combination therapy. However, MDA-MB-468 cells have been recently identified to have a BRCA2 exon 12 deletion that leads to reduced homologous repair function27. When this is considered, it is not unexpected that these cells are sensitive to PARP inhibition and combination therapy. BT-20 cells have been documented to have inefficient homologous recombination pathways, which also offers a rational explanation for its partial sensitivity to PARP inhibition28. We thus conclude that the combination of fadraciclib and rucaparib can lead to synergistic anti-proliferative effects in cell lines with a BRCA1 mutation, but it may also lead to significant reduction in proliferation in cell lines with other homologous recombination defects.
Combination olaparib and fadraciclib treatment leads to tumor regression in vivo
Since we had observed effective reduction in proliferation in BRCA1 mutant cell lines with combination CDK2 and PARP inhibitors, we assessed the use of the combination therapy in PDX models. We tested in vivo efficacy of the combination therapy in two PDXs of BLBC origin with pathogenic BRCA1 alterations: BRCA1 R1443* mutation and truncating BRCA1 2080delA mutation. Following tumor implantation and expansion, each model was treated with daily gavage of 50 mg/kg olaparib (a PARP inhibitor) and 25 mg/kg fadraciclib (sub-optimal doses selected for combination testing) (Fig. 6a). In the BRCA1 R1443* mutant PDX, single agent olaparib led to reduced tumor burden and increased overall survival (Fig. 6b–d). There was no single agent response to fadraciclib. By contrast, all olaparib and fadraciclib combination treated tumors regressed to below the starting tumor volume, and the host mice survived until the experimental endpoint (Fig. 6b–d).
The BRCA1 2080delA model has high expression of cyclin E1, probably driven in part by CCNE1 copy number gain (1.31× from exome sequencing). In this model we found that both single agent olaparib and fadraciclib were effective, leading to a significant reduction in tumor volume. However, by the 60 day endpoint of the experiment, several of the tumors treated with either olaparib or fadraciclib had begun to grow in the presence of therapy. In contrast, the combination therapy was highly effective and resulted in tumor regression at the experimental endpoint (Fig. 6e, f).
We then further compared the effect of combination therapy to olaparib alone across the two BRCA1 mutated models. Olaparib therapy resulted in smaller tumors compared to controls, but they were significantly larger than the starting volume (1.85× larger, P < 0.013, Fig. 6g). In contrast, treatment with the combination therapy led to the reduction in size of all but one tumor across the two cohorts (0.51× smaller, P < 0.0005; Fig. 6g).
We next examined the effect of CDK2 inhibition, PARP inhibition, and the combination therapy in a BRCA1 wildtype model of BLBC. Since we had observed some synergy between CDK2 inhibition and PARP inhibition across in vitro models with other homologous recombination defects (Fig. 5), we chose the HCI-002 model29 which is wildtype for homologous recombination genes BRCA1, BRCA2, PALB2, CHEK2, and BRIP130. We observed that the individual fadraciclib and olaparib therapies had no effect on tumor growth (Fig. 6h, i) or on survival of the animals (Fig. 6j). Moreover, the combination therapy had no effect on tumor growth or survival (Fig. 6h–j).
Finally, since fadraciclib acts via CDK2 and CDK9 inhibition, we examined the specific induction of DNA damage to determine if there was evidence for inhibition of CDK2 in the combination treated tumors. BRCA1 R1443* PDX tumors at endpoint for vehicle showed diffuse H2AX staining across the entire tumor, whereas combination treated tumors showed intense H2AX foci and entire cells positive for H2AX (Fig. 6k), with significantly more intense staining in the combination treated tumors (Fig. 6l). We also examined a canonical marker of inhibition of CDK9, the downregulation of cell survival protein, MCL-1. MCL-1 expression was maintained or higher in fadraciclib, olaparib, and combination treated tumors than in vehicle treated tumors (Fig. 6m). Of note, fadraciclib treatment did not have any effect in the HCI-002 model (Fig. 6h–j), and this model is reported to have CDK9 copy number gain and elevated expression30.
Discussion
The PARP inhibitors olaparib and talazoparib were recently FDA approved for use as monotherapy in patients with metastatic germline BRCA1/2-mutated breast cancer based on significant improvement in progression-free survival compared to chemotherapy31. However, the utility of PARP inhibitors in BLBC is limited as clinical trials did not show an improvement in overall survival, and partial and complete responses were infrequent. Combinations with chemotherapy can be limited by myelosuppression32. Consequently, there is a compelling unmet clinical need to identify targeted therapies that enhance the lethality of PARP inhibitors without precipitating intolerable side-effects.
We here find that BRCA1 loss reduces the turnover of cyclin E1 thereby increasing proliferation and survival, providing a new therapeutic opportunity to enhance the synthetic lethality of PARP inhibitors by co-targeting the cyclin E1/CDK2 axis. We evaluated fadraciclib, a CDK2/CDK5/CDK9 inhibitor which has successfully completed a First-in-Human Phase I clinical trial, and is continuing clinical development in both solid tumors and hematological malignancies. Our studies identify that CDK2 inhibitors work specifically through CDK2 to induce DNA damage in vitro. We found that a combination of CDK2 inhibition and rucaparib was efficacious across a range of in vitro models with different DNA repair deficiencies. We demonstrate high efficacy of combination fadraciclib and olaparib in vivo to induce tumor regression. Olaparib as a single agent was effective in PDX models with BRCA1 mutation, but several individual tumors were shown to escape therapy, and overall tumor burden was increased by the experimental endpoints. In the BRCA1 mutant PDX models, we show no tumors escaped inhibition with combination treatment, and almost all tumors regressed. We note that these in vivo models may also have benefited from the additional inhibition of CDK9 via fadraciclib, although with the conditions used we do not observe the downregulation of MCL-1 which is normally associated with CDK9 inhibition33 (Fig. 6m). Pan-CDK inhibitors that target CDK1 or CDK12 have been demonstrated in pre-clinical TNBC models to result in homologous repair deficiency and induce synthetic lethality in combination with PARP inhibitors34. This has led to the pan-CDK inhibitor dinaciclib being trialed clinically in combination with the PARP inhibitor veliparib in a patient cohort with TNBC (Clinical Trials Gov reference NCT01434316). Our data indicate that these patients may similarly derived benefit from synthetic lethality between CDK2 inhibition and PARP inhibition.
We found that cyclin E1 is stabilized in BRCA1 mutated breast tumors in association with reduced phosphorylation on cyclin E1 Threonine 62, and high cyclin E1 is associated with decreased overall survival for patients with BRCA1 mutation. Cyclin E1 T62 phosphorylation was originally believed to be of lesser importance in the turnover of cyclin E1, but our work here, and that of others35, shows that it could be having strong effects in tumorigenesis. We find that T62A mutation is sufficient to increase cyclin E1 stability and BrdU incorporation, and that T62A mutation contributes to cell survival in combination with mutation of the other major phospho-sites of the protein. Mutation of cyclin E1 T74A and cyclin E1 T393A (equivalent to human cyclin E1 T62 and T395) in a mouse model led to much higher cyclin E1 levels in hematopoietic and epithelial cells compared to T393A mutation alone, as well as hematopoietic neoplasia35. Delayed mammary gland involution after pregnancy was also observed exclusively in the presence of the T74A mutation35, highlighting its likely importance for breast tumorigenesis.
The kinase responsible for T62 phosphorylation has not been identified, though it is hypothesized to be a CDK2 auto-phosphorylation site based on a loose consensus sequence for CDK2 around the T62 site, and the timing of T62 phosphorylation early in G1 phase soon after partnering with CDK236. Consequently, increased T62 auto-phosphorylation may be the result of a direct physical interaction between BRCA1 and cyclin E1/CDK237 or through downstream effectors of BRCA1 action.
In summary, we have found that CDK2 inhibition may sensitize BRCA1 mutant breast cancer cells to PARP inhibitors. BRCA1 mutation most commonly associates with the aggressive BLBC subtype, and thus the presence of BRCA1 mutation in concert with the BLBC phenotype would suggest combination CDK2 and PARP inhibition as an effective therapeutic strategy. As both low levels of BRCA1 and BRCA1 methylation are very common to BLBC38, and our data demonstrate elevated cyclin E1 in the BRCA1 methylated BLBC, a rational ongoing area of investigation is CDK2 inhibition to sensitize BRCA1 methylated or deficient cancers to PARP inhibitors.
Methods
Patient demographics and tumor samples
The Kathleen Cuningham Foundation Consortium for research into Familial Breast cancer (kConFab; http://www.kconfab.org) cohort comprised 308 breast cancer samples used in this analysis39. Ethics board approval is described in Mann et al.39, and was obtained for patients’ recruitment, sample collection, and research studies. Written informed consent was obtained from all participants as described39.
From four tissue microarrays (TMAs), 237 samples had sufficient tumor tissue for IHC. Patient and tumor characteristics are shown in Table 1. Tumors were classified based on estrogen receptor (ER), progesterone receptor (PR), HER2 status, and mutation status of BRCA1, BRCA2, CHEK2, and PALB2. CK5/14 and/or EGFR positive tumors were classified as BLBC, while CK5/14 and EGFR negative tumors were classified as non-basal like breast cancer (NBLBC).
Dual-color in situ hybridization (ISH) assay for detection of the 19q12 locus amplification
A 19q12 DNP ISH probe that covers the coding sequences of the CCNE1 and adjacent URI1 genes and an INSR DIG ISH probe, a surrogate reference located on chromosome 19p13.2, were provided by Ventana Medical Systems (Tucson, AZ), and optimized for use on the Ventana ULTRATM platform as previously described13, and detailed in the Supplementary methods and Supplementary Fig. 5.
Cyclin E1, FBXW7, USP28, and phospho-cyclin E1 (T62) IHC
Previously optimized cyclin E1 mouse monoclonal (1:100 dilution, HE12) (Santa Cruz Biotechnology, CA), FBXW7 rabbit monoclonal (1:25 dilution, SP-237) (Spring Bioscience, CA) and the USP28 rabbit polyclonal (1:50 dilution, HPA006778) (Sigma Aldrich) antibody staining were performed using the Ventana Bench Mark ULTRATM automated staining platform and the OptiviewTM Detection kit13. Optimization of the cyclin E1 T62 antibody is described in the Supplementary methods and Supplementary Fig. 6. All proteins were assessed on nuclear staining using a 0 to 3+ intensity score. Heterogeneous expression was captured using the semi-quantitative H score40. The distribution of H scores for cyclin E1, phospho-cyclin E1 T62, FBXW7 and USP28 is shown in Supplementary Fig. 1, and determination of the assay cut points for each marker is detailed in Supplementary methods.
Survival analysis
Kaplan–Meier curves were used to plot overall survival. Assessment of progression-free survival was not possible as progression coincided with death in many cases.
Cell lines and drug treatment
Cell lines were obtained from ATCC and cultured in RPMI1640, 5–10% fetal calf serum and insulin (10 μg/ml). All cell lines were authenticated by STR profiling (CellBank Australia) and cultured for less than 6 months after authentication. Cyclin E1 was mutated by site-directed mutagenesis as described41. MDA-MB-468 cells expressing the ecotropic receptor42 were infected with pMSCV-IRES-GFP retrovirus expressing cyclin E1 wildtype and mutants as described43. Subpopulations with graded expression of GFP and cyclin proteins were separated by sterile flow cytometry and matched populations selected based on GFP expression. We expanded cell populations expressing a similar intensity of GFP signal from each cell line, and confirmed expression using western blotting.
Cells were treated with the following drugs resuspended in DSMO: rucaparib (Selleck), paclitaxel (Selleck). Fadraciclib (CYC065) was provided by Cyclacel Ltd, Dundee, UK.
Cell proliferation and survival analysis
Survival assays were performed on MDA-MB-468 cells set up at 15,000 per 6 cm dish in 50% conditioned medium. Paclitaxel (0, 2.3, 2.8 nM) was added every 6–7 days for 3 weeks. Colonies were fixed with trichloroacetic acid (16%), and stained with 10% Diff Quik Stain 2 (Lab Aids). Quantification was done with ImageJ and the ColonyArea plugin44.
Metabolic rate was assessed by Alamar Blue (Invitrogen) to determine IC50 doses. Synergy assays were performed on indicated cell lines in 96 well plates. The concentration of each drug was increased linearly along each axis of the plate, creating a drug matrix of the different concentrations. The highest concentration of each drug was IC80, followed by dilutions of 1/2, 1/4, 1/8, 1/16, and no drug. Cell viability was measured after five days using Alamar Blue. Drug synergy was analyzed with Combenefit using the BLISS algorithm45.
siRNA transfection
Gene-specific siRNAs to BRCA1 (On-Target Plus siRNAs J-003461-11-0005 and J-003461-12-0005); CDK2 (J-003236-11, J-003236-12, J-003236-13, J-003236-14); CDK9 (J-003243-9-0002, J-003243-10-0002, J-003243-11-0002, J-003243-12-0002) and controls [On-Target Plus siCONTROLs (D-001810-10, D-001810-1-4)]; siGENOME Nontargeting siRNA #2 (D-001210-02) were purchased from Dharmacon and transfections carried out as described previously46.
Western blot analysis
Cell lysates were extracted and separated on 4–12% Bis-Tris polyacrylamide gels (Invitrogen) as described47. Uncropped western blots are shown in Supplementary Figs. 7 and 8.
Primary antibodies were BRCA1 (1:1000 dilution, #9010, Cell Signaling Technology), USP28 (1:1000 dilution, EPR4249(2), Abcam), CDK2 (1:500 dilution, M2, Santa Cruz), CDK9 (1:1000 dilution, #2316, Cell Signaling Technology), cyclin E1 (1:1000 dilution, HE12, Santa Cruz), cyclin E1 T62 (1:400 dilution, #4136, Cell Signaling Technology), MCL-1 (1:1000 dilution, D35A5, Cell Signaling Technology), β-actin (1:2000 dilution, AC-15; Sigma) and GAPDH (1:5000 dilution, 4300; Ambion).
Flow cytometry
S-phase percentages were measured by flow cytometric analysis of propidium iodide stained, ethanol fixed cells. Cell cycle specific expression of endogenous cyclin E1 and V5-tagged cyclin E1 constructs were assessed by flow cytometry as described48, with further details provided in the Supplementary Data and Supplementary Fig. 9.
Comet assay
The alkaline comet assay was performed using the Trevigen Kit (Maryland, USA) according to the manufacturer’s guidelines. HCC1937 cells were seeded in a 6 well plate and treated with fadraciclib (Cyclacel) or CVT313 (Thermofisher) at the calculated IC5, IC20 or IC50 dose for 5 days, or treated with 10, 20, or 50 nM CDK2 siRNA or CDK9 siRNA, or 50 nM non targeting siRNA for 72 h. Slides were imaged with a fluorescence microscope (Leica DM5500) and analyzed with ImageJ OpenComet software (v1.3.1,49).
TCGA datasets
Breast cancer datasets were downloaded via cBioPortal9 and the BLBC subset identified from PAM50 definitions from TCGA50.
Patient-derived breast cancer xenograft (PDX) models
All in vivo experiments, procedures and endpoints were approved by the Garvan Institute of Medical Research Animal Ethics Committee (protocol 18/26) or the VHIO Animal Ethics Committee (protocol 17/42). PDX BRCA1 R1443* (PDX 11-26) was derived from a metastatic triple negative breast cancer34, and PDX (HCI-002)29 and BRCA1 2080delA (PDX124) are basal on PAM50 classification and ER/PR negative30,51. For PDX (HCI-002) and PDX BRCA1 R1443* (PDX 11-26), 3–4 mm3 sections of tumor tissue were implanted at surgery into the 4th inguinal mammary gland of female NOD-SCID-IL2γR−/− (NSG) mice. PDX BRCA1 2080delA animals were implanted subcutaneously and supplemented with 1 μmol/L estradiol (Sigma) in the drinking water. Tumor growth was assessed twice weekly by caliper measurement and mice were randomized to treatment arms when tumors reached 150–250 mm3 (using the formula: width2 × length × 0.5). Vehicle (4% DMSO, 30% PEG-300), 50 mg/kg olaparib and 25 mg/kg fadraciclib were administered by oral gavage 5 days a week. Mice were treated for 60 days or until tumor volume reached 1000 mm3.
PDX IHC and quantification
Tumor tissue was fixed in 10% neutral buffered formalin and embedded in paraffin, before being sectioned (4 μM thick) and stained using the Bond RX Automated Stainer (Leica Biosystems). Heat induced antigen retrieval was performed at pH 9 (Bond Epitope Retrieval solution 2, Leica Biosystems), 100 °C for 30 min, before Υ-H2AX antibody incubation (1:500 dilution, Cell Signaling, Clone 20E3) for 60 min. Detection was performed with diaminobenzidine (Bond Polymer Refine Detection, Leica Biosystems) and slides were counterstained with haematoxylin. Slides were imaged using a slide scanner (AperioCS2, Leica Biosystems), and data were analyzed using QuPath52 as described53.
Statistical analysis
Statistical analysis was performed using Prism SoftwareTM version 7 as indicated for each dataset. Data with greater than 10 data points are presented as box and whisker plots with error bars of minimum to maximum, where the box extends from the 25th to the 75th percentile, and the line in the middle of the box indicates the median, or as bar plots with ± standard error of the mean (s.e.m.). Treatment arms and patient subgroups with less than 10 data points are presented as scatter plots without bars or with bars that indicate the mean, and error bars indicate ± s.e.m. All experiments were performed in triplicate, except as indicated. Replicates of in vitro and in vivo experiments were performed on independent samples.
Reporting summary
Further information on research design is available in the Nature Research Reporting Summary linked to this article.
Data availability
The data generated and analyzed during this study are described in the following data record: https://doi.org/10.6084/m9.figshare.1499437254. Where possible (and not including sensitive/patient-identifying data), the data underlying the claims of the article have been made openly available in.xlsx spreadsheet format as part of the above data record. The patient dataset is not publicly available in order to protect patient confidentiality. The clinical cohort was collected and managed by kConFab, who will consider applications to access the cohort via www.kConFab.org. Processed patient data (Excel & Prism formats) can be accessed upon reasonable enquiry with the corresponding author. Cell lines and vectors engineered by the authors for this study are available upon reasonable request to the corresponding author. PDX models were provided by A/Prof Alex Swarbrick (HCI-002), E.L. (PDX 11-26) and V.S. (PDX124).
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Acknowledgements
D.A. was a recipient of the Higher Committee of Education of Iraq Scholarship. V.S. is supported by Instituto de Salud Carlos III (ISCIII) funding, an initiative of the Spanish Ministry of Economy and Innovation partially supported by European Regional Development FEDER Funds [CP19/00033] and A.L.-G. by the Asociación Española Contra el Cáncer (AECC) [INVES20095LLOP]. E.L. is a National Breast Cancer Foundation Endowed Chair and supported by Love Your Sister. C.E.C. is supported by a National Breast Cancer Foundation Career Development Fellowship (ECF17-002) and Cancer Institute NSW Fellowship (2020/CDF1071), and is grateful for the support of the Dr. Lee MacCormick Edwards Charitable Foundation. We wish to thank Heather Thorne, Eveline Niedermayr, Sharon Guo, all the kConFab research nurses and staff, the heads and staff of the Family Cancer Clinics, and the Clinical Follow Up Study (which has received funding from the NHMRC, the National Breast Cancer Foundation, Cancer Australia, and the National Institute of Health (USA)) for their contributions to this resource, and the many families who contribute to kConFab. kConFab is supported by a grant from the National Breast Cancer Foundation, and previously by the National Health and Medical Research Council (NHMRC), the Queensland Cancer Fund, the Cancer Councils of New South Wales, Victoria, Tasmania and South Australia, and the Cancer Foundation of Western Australia. We also thank and acknowledge A/Prof Alex Swarbrick and the Tumour Progression Lab at the Garvan Institute for expanding the HCI-002 model, and the BReast Origin CAncer tissue DonatEd after death (BROCADE) program, funded by the National Breast Cancer Foundation of Australia. The authors additionally thank the Experimental Therapeutics and the Breast Cancer Groups from VHIO for providing study materials.
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This study was conceived and designed by C.E.C. and D.A. KConFab collated and provided materials and updated patient data. D.A. collected, analyzed, and interpreted data. N.P. designed experiments, collected, analyzed, and interpreted data. K.J.F., C.L., S.A., A.L.-G., A.Y., A.W., C.M.S., Z.P., and D.F. undertook experimental analyses, and K.J.F. and C.L. interpreted data. D.E. analyzed preliminary datasets. V.S. provided experimental models and interpreted data. D.B., P.W., and E.L. provided intellectual input into the study design and interpretation, and E.L. provided experimental models and interpreted data. D.A. and C.E.C. drafted the manuscript. All authors read and approved the final manuscript.
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Fadraciclib was provided by Cyclacel Ltd, Dundee, UK under a material transfer agreement with C.E.C. and E.L., with no remuneration for research performed. The remaining authors declare no competing interests.
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Aziz, D., Portman, N., Fernandez, K.J. et al. Synergistic targeting of BRCA1 mutated breast cancers with PARP and CDK2 inhibition. npj Breast Cancer 7, 111 (2021). https://doi.org/10.1038/s41523-021-00312-x
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DOI: https://doi.org/10.1038/s41523-021-00312-x
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