Purpose:

To determine the dose limiting toxicities (DLT), maximum tolerated dose (MTD), and recommended phase II dose (RP2D) of veliparib in combination with weekly topotecan in patients with solid tumors. Correlative studies were included to assess the impact of topotecan and veliparib on poly(ADP-ribose) levels in peripheral blood mononuclear cells, serum pharmacokinetics of both agents, and potential association of germline repair gene mutations with outcome.

Experimental Design:

Eligible patients had metastatic nonhematologic malignancies with measurable disease. Using a 3 + 3 design, patients were treated with veliparib orally twice daily on days 1–3, 8–10, and 15–17 and topotecan intravenously on days 2, 9, and 16 every 28 days. Tumor responses were assessed by RECIST.

Results:

Of 58 patients enrolled, 51 were evaluable for the primary endpoint. The MTD and RP2D was veliparib 300 mg twice daily on days 1–3, 8–10, and 15–17 along with topotecan 3 mg/m2 on days 2, 9, and 16 of a 28-day cycle. DLTs were grade 4 neutropenia lasting >5 days. The median number of cycles was 2 (1–26). The objective response rate was 10%, with 1 complete and 4 partial responses. Twenty-two patients (42%) had stable disease ranging from 4 to 26 cycles. Patients with germline BRCA1, BRCA2, or RAD51D mutations remained on study longer than those without homologous recombination repair (HRR) gene mutations (median 4 vs. 2 cycles).

Conclusions:

Weekly topotecan in combination with veliparib has a manageable safety profile and appears to warrant further investigation.

Translational Relevance

There is significant interest in combining PARP inhibitors with DNA damaging agents, especially in cancers with frequent defects in the HRR pathway such as ovarian cancer. Preclinical observations indicate that addition of PARP inhibitors to topoisomerase I-directed agents such as topotecan results in increased antitumor efficacy in vitro and in vivo. When veliparib or olaparib was combined with daily topotecan for 5 days every 3 weeks, however, the regimen was quite myelosuppressive. This phase I study investigated the addition of veliparib to weekly topotecan, a less myelosuppressive but routinely used regimen, in patients with advanced solid malignancies. The results demonstrated a manageable safety profile and early signs of activity as manifested by responses or disease stability for ≥4 months in 37% of patients. A phase II clinical trial in advanced platinum resistant ovarian carcinoma is under way.

Topoisomerase I (topo I) poisons are widely used for the treatment of various cancers (1–4). In particular, irinotecan has regulatory approval for colorectal cancer (5) and exhibits activity in non–small cell lung cancer and breast cancer (6). Nanoliposomal irinotecan used in combination with 5-fluorouracil and folinic acid has extensive activity against advanced pancreatic cancer (7). Topotecan (TPT) is approved for the treatment of ovarian, cervical, and small cell lung cancers (8). Moreover, novel topo I poisons continue to be identified and tested in the clinical setting (9–12).

Despite their widespread clinical use, topo I poisons have limited efficacy. Topotecan, for example, exhibits a 17% overall response rate and a median overall survival of 57 weeks when administered as a daily 1-hour infusion for 5 consecutive days to patients with recurrent, platinum-resistant ovarian cancer (13). Because myelosuppression occurs in up to 75% of women receiving this therapy (14), alternative regimens have been investigated to improve or maintain efficacy while decreasing toxicity (15, 16). A phase II study investigating topotecan administered on days 1, 8, and 15 of a 28-day cycle had a response rate of 18% in platinum refractory/resistant ovarian cancer (17). With this alternative schedule, myelosuppression was mild, with no grade 4 toxicities observed.

Preclinical studies have demonstrated that PARP inhibitors, which exhibit single-agent clinical activity in ovarian cancer, breast and prostate cancer (18–22), sensitize tumor cells to topo I poisons in vitro and in vivo (23–25). Multiple mechanisms appear to contribute to this sensitization. First, inhibition of PARP1 catalytic activity impairs the recruitment of tyrosyl-DNA phosphodiesterase 1 (TDP1), an enzyme that participates in detoxification of trapped topo I-DNA covalent complexes (26). Second, topo I poisons are known to cause replication fork stalling and collapse (27–29); and PARP1 plays a central role in helping stabilize and restart these replication forks (30–32). Finally, genetic analysis has indicated that trapping of PARP1 at sites of DNA damage, which is an intrinsic feature of all PARP inhibitors, including veliparib (33), also contributes to topotecan/PARP inhibitor synergy (34).

In view of this synergy in preclinical models, there has been substantial interest in combining PARP inhibitors with topo I poisons in the clinic (18, 35). However, all of the early phase trials of topo I poison/PARP inhibitor combinations reported to date have been limited in their ability to administer PARP inhibitor because of severe myelosuppression (35–37). In the case of topotecan, Kummar and colleagues administered the orally bioavailable PARP inhibitor veliparib (38) in combination with the 5-day topotecan regimen and found the combination very myelosuppressive, requiring reduction in doses of both agents (39). The maximum tolerated dose (MTD), veliparib 10 mg twice daily combined with topotecan 0.6 mg/m2/day × 5 days (39), represents 1/40th and less than 1/3 of the respective single-agent MTDs, respectively (40, 41).

In view of these results, we sought to determine whether veliparib could be safely combined with the less myelosuppressive weekly topotecan regimen in patients with solid tumors. In addition to identifying the MTD and dose-limiting toxicities (DLT) of this combination, the goals of the present study were to determine whether there was evidence of clinical activity, assess the impact of topotecan and veliparib on poly(ADP-ribose) polymer (PAR) levels in peripheral blood mononuclear cells, characterize the pharmacokinetics of both agents, and the evaluate the impact of germline DNA repair gene mutations on clinical activity of this combination.

Patients

Patients 18 years or older with any histologically confirmed solid tumor with measurable disease (longest diameter ≥2 cm with conventional CT) that was metastatic or unresectable who had relapsed less than a year from their prior platinum treatment were eligible. In addition patients had to have an Eastern Cooperative Oncology Group (ECOG) performance status of 0–2, adequate bone marrow (as defined by an absolute neutrophil count ≥ 1,500/mcL, hemoglobin ≥ 9.0 g/dL, and platelets ≥ 100,00/mcL), renal [Cr ≤ 1.5 × the upper limit of normal (ULN)] and hepatic function (total bilirubin 1.5 × ULN, ALT and AST ≤ 2.5 × ULN in the absence of hepatic metastasis or ALT ≤ 3 × ULN and AST ≤ 5 × ULN in the presence of hepatic metastasis), as well as the ability to swallow and absorb oral medication. Initially there was no limit on the number of prior regimens, but this was amended at dose level 4 due to impact of prior therapies on marrow reserve. For women of child-bearing potential, a negative serum or urine pregnancy test was required. Exclusion criteria included treatment with chemotherapy, radiation, or immunotherapy within 4 weeks prior to receiving treatment (6 weeks if prior treatment was mitomycin C or a nitrosourea); prior treatment with a PARP inhibitor; prior radiation therapy to >25% of the bone marrow; uncontrolled intercurrent illness; immunocompromise (other than related to the use of glucocorticoids); known CNS metastases or seizure disorder; New York Heart Association class II or III heart disease or history of MI within 6 months; and other active malignancy other than nonmelanoma skin cancer and carcinoma in situ of the cervix. All patients provided written informed consent.

Study design

This phase I clinical trial was open at Mayo Clinic in Rochester MN, Jacksonville FL, and Scottsdale, AZ. Patients were enrolled using a standard 3 + 3 study design in order to determine the MTD and recommended phase II dose (RP2D) of the combination of weekly topotecan with veliparib. A secondary objective was to identify any preliminary evidence of antitumor activity as assessed by objective response in patients with advanced solid tumors. Clinical correlates included identification of any pharmacokinetic interactions between veliparib and topotecan and assessment of the impact of topotecan and veliparib on poly(ADP-ribose) (PAR) levels in peripheral blood mononuclear cells (PBMCs). The study was conducted according to the Declaration of Helsinki. It was approved by the Mayo Clinic Institutional Review Board and registered at clinicaltrials.gov as NCT01012817.

Treatment schedule (Supplementary Fig. S1)

Patients were treated with veliparib orally once (dose levels 1–6) or twice (dose levels 7–13) daily on days 1–3, 8–10, and 15–17 and topotecan intravenously (IV) over 30 minutes on days 2, 9, and 16 every 28 days. For cycle 2 only, patients were treated with veliparib orally daily only on days 8–10 and 15–17 and topotecan IV on days 2, 9, and 16. This omission of veliparib on days 1–3 of cycle 2 allowed sampling of PBMCs and serum topotecan clearance in the absence of veliparib. Subsequent cycles were as described for cycle 1. Premedications were not routinely used. Antiemetics were provided when needed as determined by the treating physician. Prophylactic use of 5-HT3 antagonists and other agents such as glucocorticoids, phenothiazines, and benzodiazepines was permitted. Growth factor support was not recommended and not allowed during cycle 1 of therapy, but prophylactic growth factor was allowed in subsequent cycles at physician discretion if a patient developed grade 3 or 4 neutropenia during a previous cycle. Patients were given a pill diary to record and remind patients of when to take the oral veliparib.

Efficacy assessments

Response was assessed every 8 weeks. Modified response evaluation criteria in solid tumors (RECIST v.1.0) were used.

Pharmacokinetic (PK) assessments

PK studies were performed for veliparib and topotecan. For veliparib, blood samples were taken on cycle 1 day 1 and 2 prior to the dose of veliparib as well as 15 minutes, 30 minutes, 1, 2, 4, 6, and 9 hours after administration. For topotecan, samples were drawn on cycle 1 day 2 and cycle 2 day 2 prior to the topotecan infusion as well as 15 and 30 minutes after start of infusion and 15 and 30 minutes, 1, 1.5, 3.5, 5.5, and 8.5 hours after the end of the infusion. These samples were analyzed for both agents using validated high-performance liquid chromatography assays for topotecan (42) and veliparib (39). Plasma concentration-time data were analyzed by standard noncompartmental methods using Phoenix WinNonlin 1.3 (Certara USA, Inc.).

PAR measurements

Whole blood samples for PBMC PAR assessment were obtained on cycle 1 day 1 (0, 2, 4, and 8 hours after veliparib), cycle 1 day 2 (0, 2, 4, and 8 hours after veliparib) and on cycle 2 day 2 (0, 2, 4, and 8 hours after topotecan). PAR levels were analyzed by sandwich ELISA in the National Clinical Target Validation Laboratory of the NCI as previously described (43).

Statistical and analytical methods

The phase I portion of this trial is a single arm phase I study utilizing 3 + 3 design to determine the MTD of the combination of veliparib and weekly topotecan in the treatment of solid tumors. If a patient failed to complete the initial cycle of therapy for reasons other than toxicity, the patient was regarded as unevaluable with respect to the goals of the study and an additional patient was treated at the current dose level; however, all toxicity information was utilized in the analysis. Objective responses, as defined per RECIST (v.1.0), were summarized by simple descriptive summary statistics delineating complete and partial responses (CR and PR, respectively) as well as stable and progressive disease (SD and PD, respectively).

Safety and DLT definitions

All subjects receiving at least 1 dose of veliparib and topotecan were included in the safety analysis. All adverse events (AE) were graded according to the Common Terminology Criteria for Adverse Events (CTCAE; version 4.0) grading system.

A DLT was defined as the occurrence of drug-related AEs during the first treatment cycle, including grade 4 anemia or thrombocytopenia at any time; grade 4 neutropenia persisting 5 days or longer; grade 3 nausea, diarrhea, or vomiting in spite of maximal supportive care and prophylaxis; clinically significant grade 3 or greater nonhematologic toxicity (not including alopecia, anorexia, or fatigue); and serum creatinine ≥2 times baseline or ≥2 times ULN if baseline is less than the ULN.

The MTD was defined as the dose level below the one that caused DLTs in at least 2 of up to 6 patients. The RP2D was to be the MTD dose unless other safety considerations required lowering the dose.

Patient characteristics

Fifty-eight patients were enrolled in the dose escalation phase of this trial of weekly topotecan and veliparib (Supplementary Fig. S1) between November 2009 and February 2015. One patient enrolled but was never treated so was replaced. Six patients were replaced due to AEs unrelated to treatment or refusal of treatment, but toxicity information was included in the data analysis. Fifty-one patients completed at least one cycle of therapy. As shown in Table 1, the majority of evaluable patients enrolled in the study had ovarian, fallopian tube, or primary peritoneal cancer (45 patients), all of whom had platinum-resistant disease. Because of concern for severe myelosupression, which was seen when low doses of veliparib were combined with daily topotecan (39), the starting dose of veliparib in the present trial was significantly lower than single-agent MTD of 400 mg bid. As a result, 13 dose levels were utilized in this trial (Table 2).

Table 1.

Patient demographics and baseline disease characteristics

All evaluable patients (n = 51)
Median age (range) 56 (34–78) 
% Male (n1 (2%) 
% Female (n50 (98%) 
ECOG PS 
 0 36 (70.6%) 
 1 15 (29.4%) 
 2 
Number of prior lines of therapy 
 1 13 (25.5%) 
 2 27 (52.9%) 
 3 6 (11.8%) 
 4 1 (2.0%) 
 5+ 4 (8.0%) 
Germline mutation status by BROCA 
No germline mutation detected 33 (64.6%) 
BRCA1 13 (25.4%) 
BRCA2 1 (2.0%) 
RAD51D 1 (2.0%) 
CHEK2 1 (2.0%) 
FANCL 1 (2.0%) 
MSH6 1 (2.0%) 
Primary diagnosis/histology 
 Cervix/adenocarcinoma 1 (2%) 
 Endometrial 4 (8%) 
  • Endometrioid 2 (4%) 
  • High grade serous 2 (4%) 
 Small cell lung cancer 1 (2%) 
 Ovarian, fallopian, primary peritoneal 45 (88%) 
  • High grade serous 38 (74%) 
  • Endometrioid 3 (6%) 
  • Poorly differentiated adenocarcinoma 1 (2%) 
  • Carcinosarcoma 1 (2%) 
  • Mucinous (1) 1 (2%) 
  • Clear cell (1) 1 (2%) 
Ovarian cancer cohort (n = 45) 
Number of prior regimens 
 1 7 (16%) 
 2 11 (24%) 
 3 9 (20%) 
 4 5 (11%) 
 5+ 13 (29%) 
Germline mutation status by BROCA 
No germline mutation detected 29 (65%) 
BRCA1 13 (29%) 
BRCA2 1 (2%) 
RAD51D 1 (2%) 
CHEK2 1 (2%) 
All evaluable patients (n = 51)
Median age (range) 56 (34–78) 
% Male (n1 (2%) 
% Female (n50 (98%) 
ECOG PS 
 0 36 (70.6%) 
 1 15 (29.4%) 
 2 
Number of prior lines of therapy 
 1 13 (25.5%) 
 2 27 (52.9%) 
 3 6 (11.8%) 
 4 1 (2.0%) 
 5+ 4 (8.0%) 
Germline mutation status by BROCA 
No germline mutation detected 33 (64.6%) 
BRCA1 13 (25.4%) 
BRCA2 1 (2.0%) 
RAD51D 1 (2.0%) 
CHEK2 1 (2.0%) 
FANCL 1 (2.0%) 
MSH6 1 (2.0%) 
Primary diagnosis/histology 
 Cervix/adenocarcinoma 1 (2%) 
 Endometrial 4 (8%) 
  • Endometrioid 2 (4%) 
  • High grade serous 2 (4%) 
 Small cell lung cancer 1 (2%) 
 Ovarian, fallopian, primary peritoneal 45 (88%) 
  • High grade serous 38 (74%) 
  • Endometrioid 3 (6%) 
  • Poorly differentiated adenocarcinoma 1 (2%) 
  • Carcinosarcoma 1 (2%) 
  • Mucinous (1) 1 (2%) 
  • Clear cell (1) 1 (2%) 
Ovarian cancer cohort (n = 45) 
Number of prior regimens 
 1 7 (16%) 
 2 11 (24%) 
 3 9 (20%) 
 4 5 (11%) 
 5+ 13 (29%) 
Germline mutation status by BROCA 
No germline mutation detected 29 (65%) 
BRCA1 13 (29%) 
BRCA2 1 (2%) 
RAD51D 1 (2%) 
CHEK2 1 (2%) 
Table 2.

Dose escalation and response table

Responses
Dose levelVeliparib (mg)aTopotecan (mg/m2)Number of patients treatedMutation statusNumber of DLTsCRPRSDPD
10 qd BRCA1 (1) 
20 qd BRCA2 (1) 
10 qd BRCA1 (1) 
    CHEK2 (1)      
20 qd BRCA1 (2) 
20 qd BRCA1 (2) 
    RAD51D (1)      
    MSH6 (1)      
30 qd BRCA1 (1) 
7b 30 bid BRCA1 (1) 
50 bid BRCA1 (1) 
100 bid BRCA1 (1) 
10 150 bid FANCL (1) 
11 200 bid  
12 (MTD) 300 bid BRCA1 (1) 
13 400 bid BRCA1 (1) 
Responses
Dose levelVeliparib (mg)aTopotecan (mg/m2)Number of patients treatedMutation statusNumber of DLTsCRPRSDPD
10 qd BRCA1 (1) 
20 qd BRCA2 (1) 
10 qd BRCA1 (1) 
    CHEK2 (1)      
20 qd BRCA1 (2) 
20 qd BRCA1 (2) 
    RAD51D (1)      
    MSH6 (1)      
30 qd BRCA1 (1) 
7b 30 bid BRCA1 (1) 
50 bid BRCA1 (1) 
100 bid BRCA1 (1) 
10 150 bid FANCL (1) 
11 200 bid  
12 (MTD) 300 bid BRCA1 (1) 
13 400 bid BRCA1 (1) 

aAbbreviations: qd, one a day; bid, twice a day.

bDose level 7 and higher received twice daily veliparib.

DLT and MTD determination

DLTs in the first cycle, consisting of myelosuppression (grade 4 neutropenia and grade 4 thrombocytopenia), were observed in 2 of 3 patients at dose level 6 and the study accrued 3 additional patients at dose level 5, all of whom experienced the DLT (grade 4 neutropenia and grade 4 thrombocytopenia). The study was temporarily closed while the dose schedule was reevaluated. Based on the premise that veliparib is being administered to enhance the efficacy of topotecan, the study was reopened at a reduced topotecan dose of 3 mg/m2 on days 1, 8, and 15 (3/4 the single-agent MTD) along with veliparib twice daily at dose level 7. At dose level 10, a DLT in one of the first three patients necessitated treating 6 patients with no further DLTs observed. Grade 4 neutropenia lasting >5 days was observed in 2 of 3 patients at dose level 13 and in 1 of 6 patients at dose level 12. Accordingly, the MTD and recommended phase II dose (RP2D) was dose level 12, i.e., veliparib 300 mg twice daily by mouth on days 1–3, 8–10, and 15–17 along with topotecan 3 mg/m2 intravenously on days 2, 9, and 16.

Safety

For cycle 1, the only grade 4 AEs at least possibly related to treatment in the study were cytopenias (neutropenia in 11 patients, thrombocytopenia in 3 patients, and leukopenia in 2 patients) and one febrile neutropenia. For all cycles, the only grade 4 AEs at least possibly related to treatment involved bone marrow suppression, namely neutropenia (13), thrombocytopenia (3), leukopenia (3), and sepsis (1). The most common grade 3–4 AEs at least possibly related to treatment (Table 3) were again hematologic and included neutropenia (23), thrombocytopenia (12), and leukopenia (19) as well as grade 3 fatigue (1), grade 3 nausea (1), and electrolyte derangements (1). One patient received filgrastim while on therapy. Seventeen patients received red blood cell transfusions and one patient received a platelet transfusion for thrombocytopenia while on low-molecular-weight heparin.

Table 3.

Grade 3 and 4 adverse eventsa at least possibly related to therapy in the 51 evaluable patients (all cycles)

ToxicityGrade 3Grade 4
Anemia 16 (31.3%) — 
Leukopenia 16 (31.3%) 3 (5.8%) 
Neutropenia 10 (19.6%) 13 (22.8%) 
Thrombocytopenia 9 (17.6%) 3 (5.8%) 
Febrile neutropenia 1 (2.0%) — 
Sepsis — 1 (2.0%) 
Fatigue 1 (2.0%) — 
Nausea 1 (2.0%) — 
Hypokalemia 1 (2.0%) — 
ToxicityGrade 3Grade 4
Anemia 16 (31.3%) — 
Leukopenia 16 (31.3%) 3 (5.8%) 
Neutropenia 10 (19.6%) 13 (22.8%) 
Thrombocytopenia 9 (17.6%) 3 (5.8%) 
Febrile neutropenia 1 (2.0%) — 
Sepsis — 1 (2.0%) 
Fatigue 1 (2.0%) — 
Nausea 1 (2.0%) — 
Hypokalemia 1 (2.0%) — 

aAs per NCI CTCAE version 4.0.

Assessment of topotecan and veliparib pharmacokinetics

Fifty-four patients participated in pharmacokinetic (PK) studies for veliparib and topotecan, and data are available for 49 patients (Supplementary Table S1). Similar plasma concentration–time profiles were observed for topotecan and veliparib when administered alone or together as illustrated for a patient treated at the MTD in Supplementary Fig. S2. The mean (±SD) half-life for veliparib was 6.1 ± 2.8 hours. Increasing the veliparib dose from 10 to 300 mg resulted in dose-proportional increases in Cmax and AUC0-9h values (Fig. 1A and Supplementary Table S1). Veliparib AUC0-9h increased from 351 ± 69 ng*h/mL (10 mg daily dose) to 15,031 ± 3,094 ng*h/mL (300 mg twice daily dose). In order to determine the effect of topotecan on veliparib pharmacokinetics, we measured veliparib Cmax and AUC0-9h, on day 1 when veliparib was given alone and on day 2 when it was given with topotecan. The mean (±SD) ratio of (veliparib + topotecan)/veliparib alone was 1.10 ± 0.24 and 1.17 ± 0.19 for Cmax and AUC0-9h, respectively, consistent with little if any accumulation of veliparib. In order to determine the effect of veliparib on topotecan pharmacokinetics, we measured topotecan Cmax and AUC0-9h, on cycle 1, day 2 when topotecan was given with veliparib and on cycle 2, day 1 when it was given with alone. When given alone, there was substantial variability in topotecan clearance such that overlapping AUC values were observed for each dose level and a dose proportional increase in AUC was not observed as the dose was increased from 2 to 4 mg/m2 (Supplementary Table S1). The mean (±SD) half-life and plasma clearance values for topotecan administered alone on cycle 2 were 2.7 ± 0.6 hour and 10.1 ± 3.8 L/h/m2, respectively. The mean (±SD) ratios of (veliparib + topotecan)/topotecan alone were 1.06 ± 0.20 for AUC0-9h and 0.97 ± 0.28 for CL, suggesting at most a small effect of veliparib on topotecan clearance (Fig. 1B and Supplementary Table S1).

Figure 1.

Graphs of veliparib AUC0-9h versus dose (A) and topotecan AUC0-∞ versus veliparib dose (B) following administration of escalating doses of 10–400 mg veliparib with 3 mg/m2 topotecan.

Figure 1.

Graphs of veliparib AUC0-9h versus dose (A) and topotecan AUC0-∞ versus veliparib dose (B) following administration of escalating doses of 10–400 mg veliparib with 3 mg/m2 topotecan.

Close modal

PAR measurements

Measurements of PAR after dosing on day 1 of cycle 1 (veliparib alone), day 2 of cycle 2 (topotecan alone), and day 2 of cycle 1 (topotecan + veliparib) allowed assessment of the effects of each drug alone as well as the combination. Of 47 patients who had PBMCs collected for evaluation of PAR levels, 33 had levels above the lower limit of quantitation (LLQ) at baseline (day 1, prior to initiation of therapy).

PAR levels on day 1 decreased in 32 of these 33 patients (Supplementary Fig. S3A, top; P = 1.5 × 10−8 by sign test) at 2 to 8 hours after veliparib administration compared to baseline. The extent of PAR inhibition, which varied from 0 to at least 85%, increased with veliparib dose (Supplementary Fig. S3A) and with veliparib exposure represented by AUC0-9h after the first dose (Fig. 2A). Prior to the day 2 treatment (day 2, 0 h), PAR levels were close to baseline at dose levels 1 to 6, reflecting poor target inhibition at the end of the 24-hour dosing interval (Fig. 2B; Supplementary Fig. S3A, middle, closed circles). In contrast, PAR levels were generally lower and, in many patients below the LLQ, at 12 hours after the last dose in the twice-daily schedule of dose levels 8 to 13 (Fig. 2B and Supplementary Fig. S3A, red circles).

Figure 2.

Effects of treatment on PAR levels. A, Percent decrease in PAR levels at 2–8 hours on day 1 versus veliparib AUC0-9h. Shown is the mean decrease at 2, 4, and 8 hours after veliparib treatment. Values at or below the LLQ were assumed to be at the LLQ. Line shows fit of data to a 3-parameter sigmoidal equation by nonlinear regression using SigmaPlot (version 12.0). R2 = 0.25, P = 0.031. B, Percent decrease in PAR levels at 0 hours on day 2 versus veliparib AUC0-9h on day 1. Samples with values below the LLQ at 0 hour on day 2 were omitted. Line shows fit of data to a 3-parameter sigmoidal equation by nonlinear regression using SigmaPlot (version 12.0). R2 = 0.33, P = 0.007. Closed circles, patients receiving once daily dosing; open circles, twice daily dosing. C, Relationship between mean decrease in PAR levels at hours 2–8 on day 1 relative to day 1 baseline vs. decrease in PAR levels at hours 2–8 on day 2 relative to day 2 baseline. Dashed line indicates equal % inhibition on days 1 and 2.

Figure 2.

Effects of treatment on PAR levels. A, Percent decrease in PAR levels at 2–8 hours on day 1 versus veliparib AUC0-9h. Shown is the mean decrease at 2, 4, and 8 hours after veliparib treatment. Values at or below the LLQ were assumed to be at the LLQ. Line shows fit of data to a 3-parameter sigmoidal equation by nonlinear regression using SigmaPlot (version 12.0). R2 = 0.25, P = 0.031. B, Percent decrease in PAR levels at 0 hours on day 2 versus veliparib AUC0-9h on day 1. Samples with values below the LLQ at 0 hour on day 2 were omitted. Line shows fit of data to a 3-parameter sigmoidal equation by nonlinear regression using SigmaPlot (version 12.0). R2 = 0.33, P = 0.007. Closed circles, patients receiving once daily dosing; open circles, twice daily dosing. C, Relationship between mean decrease in PAR levels at hours 2–8 on day 1 relative to day 1 baseline vs. decrease in PAR levels at hours 2–8 on day 2 relative to day 2 baseline. Dashed line indicates equal % inhibition on days 1 and 2.

Close modal

Baseline PAR levels on day 30 were 130% ± 100% (range, 44%–540%) of baseline PAR levels on day 1 (Supplementary Fig. S3A, bottom, open circles). After treatment with topotecan alone, PAR levels on day 30 increased in 11 of 20 quantifiable pairs of samples, decreased in 7 pairs and remained unchanged in 2 (Supplementary Fig. S3A and S3B). While this weak trend (P = 0.12 by sign test) is suggestive of earlier reports that topo I poisons activate PAR synthesis in tissue culture lines in vitro (30, 34), topo I levels are known to be low in resting PBCs (44), which also have few advancing replication forks to collide with topo I–DNA complexes to produce additional damage that would activate PARP1. Accordingly, changes in PAR did not correlate with topotecan peak concentrations or AUC (Supplementary Fig. S3B).

Finally, after treatment with the combination on day 2, PBMC PAR levels decreased relative to the day 2 baseline in 14 patients, were unchanged in 4 and increased in 6 (P = 0.04 by sign test; Fig. 2C and Supplementary Fig. S3A, bottom). The percentage change from baseline on day 2 was generally smaller than on day 1 (Fig. 2C, P = 3.7 × 10−4 by sign test), reflecting diminished ability to suppress PAR below the lower baseline levels on day 2 and/or the impact of TPT on polymer synthesis.

Antitumor activity

Evaluable patients (n = 51) received 1 to 26 cycles of therapy. The mean number of cycles for all patients enrolled was 4.5 cycles. The median number of cycles was two. One patient with primary peritoneal cancer had a CR and remained on study for 14 cycles before disease progression. Four patients had PRs as their best response. An additional 22 patients had stable disease for at least 4 months as their best response, with 9 patients having stable disease for six or more cycles and three for nine or more cycles.

Because the vast majority of patients on the study had ovarian carcinoma, most responses were seen within this group. Of the 6 patients who did not have ovarian carcinoma, 1 woman with endometrial carcinoma remained on study for 26 cycles with PR as her best response and the other 5 did not have objective responses. Of the ovarian carcinoma patients, 1 had a CR and 3 had a PR (n = 45; 9%), with an additional 21 maintaining stable disease. Ten women with ovarian cancer remained on study for 6 to 18 cycles.

Overall, the objective response rate for the trial was 10%, with an additional 42% achieving SD. The correlation between dose level and response was not significant. Instead, clinical responses (CR, PR, and SD) were seen across multiple dose levels (Table 2). The CR was seen at dose level 5 (20 mg veliparib and 4 mg/m2 topotecan). This dose of topotecan was subsequently reduced due to DLTs at this dose level. However, three of the four PRs were seen at dose level 12, the MTD.

Relationship between germline HRR gene mutations and time on treatment

Fifty-six of the 58 patients underwent germline BROCA mutation analysis (45). Within the group, there were 14 patients with deleterious germline BRCA1 mutations, 2 with BRCA2 mutations, 1 with a RAD51D mutation, and 1 with a CHEK2 mutation as well as 1 patient with an MSH6 mutation (endometrial cancer). Among the 45 evaluable ovarian cancer patients with BROCA testing, those with germline BRCA mutations (n = 14) received a mean of 5.8 cycles and median of 4 cycles, whereas those without germline BRCA mutation (n = 31) received a mean and median of 4.4 and 2.0 cycles, respectively. Within the BRCA-mutated ovarian cancers (n = 14), there were 0 CR, 3 PR, and 7 SD, whereas in the germline BRCA wild-type ovarian cancers (n = 31), there were 1 CR, 1 PR, and 14 SD. One ovarian cancer patient had a RAD51D mutation and maintained stable disease for 14 cycles. Accordingly, in the 15 evaluable patients with BRCA1, BRCA2 or RAD51D mutation, the mean number of cycles was 6 and the median number of cycles was 4. Interestingly, the endometrial cancer patient with a germline MSH6 mutation had stable disease as her best response and also remained on study for 26 cycles before disease progression.

There has been significant interest in combining PARP inhibitors with other agents such as DNA damaging agents, antiangiogenics, and immune checkpoint inhibitors such as anti–PD-1 antibodies and IDO inhibitors. Trials examining the latter combinations are currently under way. PARP inhibitors are currently FDA approved for the third- or fourth line therapy of ovarian cancers with somatic or germline BRCA1 or BRCA2 mutations as well as a maintenance therapy for platinum-responsive recurrent ovarian cancer regardless of BRCA status. Although these are broad indications, the combination of topotecan and veliparib described here could potentially be used for women with platinum-resistant disease and no BRCA mutation.

Starting with the less myelosuppressive weekly schedule of topotecan, the present study identified the MTD and RP2D of the topotecan/veliparib combination. In addition, as discussed in greater detail below, this study also established that inhibition of poly(ADP-ribose) polymer formation in PBMCs was detectable but modest at PARP inhibitor doses administered. Moreover, the regimen was associated with objective responses and disease stabilization in patients with platinum-resistant ovarian cancer whether germline BRCA mutations were present or not. All of these observations have potential implications for the future development of topo I poison/PARP inhibitor combinations.

The combination of weekly topotecan with veliparib administered for 3 days around the time of each topotecan dose was generally well tolerated, with a manageable safety profile in patients with advanced solid malignancies. The MTD of the combination was veliparib 300 mg twice daily by mouth on days 1–3, 8–10, and 15–17 along with topotecan 3 mg/m2 intravenously on days 2, 9, and 16. This represents three-fourths of topotecan MTD in single-agent studies as well as three-fourths of daily dose of veliparib administered at the MTD, albeit on a more contracted schedule.

Several prior clinical trials have evaluated combinations of camptothecins and PARP inhibitors (36, 39, 46, 47). In a trial of veliparib with topotecan administered daily for 5 days (39), the MTDs of veliparib and topotecan were much lower than in the present trial (10 mg BID and 0.6 mg/m2/dose, respectively) and hematologic toxicity precluded dose escalation. When olaparib was combined with the daily × 3 topotecan regimen (36), the MTDs were olaparib 100 bid and topotecan 1 mg/m2—both far below the individual single-agent MTDs—and neutropenia precluded dose escalation. Examination of the olaparib/irinotecan combination on two different schedules (47) established that administration of irinotecan every 2 weeks along with olaparib twice daily on days 1 to 5 was the better tolerated regimen, although only 50 mg of olaparib/dose (1/6 the daily dose of olaparib at the single-agent MTD) could be administered at the RP2D of the combination. Finally, a recently published phase I of the veliparib/irinotecan combination established the MTD as irinotecan 100 mg/m2 on days 1 and 8 with 40 mg of veliparib twice daily for 14 days of every 21-day cycle. In each of these cases, a PARP inhibitor was added to a regimen that already had myelosuppression as one of its prominent toxicities; and the result was dose-limiting marrow toxicity at relatively modest PARP inhibitor concentrations. In contrast, the weekly regimen of topotecan is less myelosuppressive. Although dose limiting toxicity was observed at dose level 5 (20 mg veliparib twice daily on days 1–3, 8–10, and 15–17) when we attempted to administer topotecan at its single-agent MTD of 4 mg/m2 on days 2, 9, and 16, we were able to easily escalate the PARP inhibitor 10-fold higher by fixing the topotecan at three-fourths of its single-agent MTD. The PK of topotecan and veliparib in this study were similar to those found in a previous study of the combination (39). The PK of veliparib were not altered by coadministration with topotecan over the broad range of veliparib doses studied in this trial. While there might be a slight effect of veliparib on topotecan clearance, it is very modest and does not appear to be clinically significant, as the 3-mg/m2 topotecan dose was tolerable over a 10- to 400-mg dose range for veliparib.

In the prior studies of veliparib combined with topotecan or irinotecan (39, 46), reductions in PBMC PAR levels were seen despite the fact that the doses of veliparib were far below the single-agent MTD. In the phase I trial that evaluated veliparib with the 5-day topotecan regimen, paired tumor biopsies from 3 patients, all obtained at doses above the MTD, also demonstrated a >75% decrease in PAR levels at 4 to 6 hours post therapy. In the current study, we likewise observed a reduction in PAR levels in PBMCs after administration of veliparib. In our study, there was also a trend toward an overall decrease in PAR levels at higher veliparib exposures (Fig. 2A). Moreover, as observed in the day 2 pretreatment samples (Fig. 2B), PAR levels had substantially rebounded from their nadir before the end of the 24-hour dosing interval at dose levels 1 to 6. At dose levels 8 to 13, which involved twice daily dosing, suppression at 12 hours after the last dose was somewhat greater, but polymer was readily detected at 20% to 70% of baseline in many samples (Fig. 2B, open circles), suggesting that bulk PAR synthesis was not being effectively suppressed throughout the interval between doses. Whether this would also have been observed in tumor tissue is currently unknown. Nonetheless, the observation that clinical responses (Table 2) as well as dose-limiting marrow suppression (Table 3) occur at veliparib doses that give incomplete suppression of PAR synthesis might be explained by earlier preclinical studies showing that veliparib traps PARP1 and PARP2 on damaged DNA (33) and PARP trapping contributes to topo I poison/PARP inhibitor synergy (34).

The present results also need to be placed in the context of recent PARP inhibitor combinations. Bang and colleagues have reported that olaparib does not increase the response rate to paclitaxel in relapsed gastric cancer (http://oncologypro.esmo.org/Meeting-Resources/ESMO-2016/Olaparib-in-combination-with-paclitaxel-in-patients-with-advanced-gastric-cancer-who-have-progressed-following-first-line-therapy-Phase-III-GOLD-study). It is important to emphasize that olaparib was administered at doses far below the MTD in that study and there was little evidence to suggest that olaparib would synergize with a microtubule inhibitor. Unpublished results also suggest that veliparib fails to enhance the response rate to carboplatin and paclitaxel in non–small cell lung cancer and triple-negative breast cancer (https://news.abbvie.com/news/abbvie-announces-topline-results-from-two-phase-3-studies-investigating-veliparib-in-combination-with-chemotherapy-for-treatment-patients-with-advanced-or-metastatic-squamous-non-small-cell-lung-cancer-and-early-stage-triple-negative-breast-cancer.htm), again mirroring preclinical results that failed to observe synergy between PARP inhibitors and platinum (34, 48). In contrast, a variety of studies in tissue culture and xenograft models have demonstrated synergy between topo I poisons and PARP inhibitors, including veliparib (23–26, 34). These observations, coupled with the safety profile described in the present study, suggest that further study of the topotecan/veliparib combination might be warranted. On the other hand, PARP inhibitors have also been shown to increase death receptor expression, leading to enhanced sensitivity to cytokines such as FAS ligand and TRAIL that are produced by cytotoxic T cells and activated monocytes (49). These latter observations, along with promising results in immunocompetent mouse models and a variety of additional studies, provide a preclinical basis for PARP inhibitor/immunotherapy trials.

The vast majority of the patients enrolled in the present trial had ovarian cancer. At the time the trial started, cells lacking BRCA1, BRCA2, and other homologous recombination repair proteins were known to be hypersensitive to veliparib (50); and deleterious BRCA1 or BRCA2 mutations were known to be frequent in ovarian cancer. Additional data indicated that cells lacking BRCA2 are also hypersensitive to topo I poisons and are sensitized even further by veliparib (34). Although responses were noted in patients without BRCA mutations, the above observations prompted us to examine the relationship between germline mutations in DNA repair genes and response.

In ovarian cancer patients with deleterious germline DNA repair pathway mutations, the objective response rate was 25% on this veliparib/topotecan regimen, even though all patients had platinum-resistant disease. In contrast, there were no responses, only disease stability, in the phase I study combining veliparib with the 5-day schedule of topotecan (39). In the combination of veliparib with irinotecan (46), 9 patients with ovarian cancer enrolled, all with documented BRCA germline mutations. Among these 9 patients, 1 (with platinum sensitive disease) achieved a PR and 6 achieved SD (1 with platinum-sensitive and 5 with platinum-resistant cancer).

In the present study, ovarian cancer patients with germline BRCA1, BRCA2, or RAD51 mutations were also on study somewhat longer (mean 6 cycles, median 4 cycles) than patients without germline mutations (mean 4.4 cycles, median 2). This trend, however, was not statistically significant and was also confounded by the fact that patients received different doses of veliparib and topotecan across 13 dose levels. Likewise, among the 16 patients with germline homologous recombination defects, there was a trend toward increased clinical benefit (3 PR, 8 SD among 15 patients vs. 1 CR + 1 PR + 14 SD among 30 patients). This also did not reach statistical significance (P = 0.21 by Fisher exact test) and must be interpreted in light of the wide variation in doses administered.

In summary, when veliparib is added to the weekly topotecan regimen, hematologic toxicity is dose limiting, but both agents can be administered at three-fourths of their individual agent MTDs. This regimen has a manageable safety profile and exhibits signs suggestive of potential activity, particularly in ovarian cancer patients with deleterious germline repair pathway mutations. Accordingly, a phase II clinical trial is currently under way in platinum-resistant ovarian carcinoma.

P. Haluska reports receiving commercial research grants from Tesaro and Clovis, and holds ownership interest (including patents) in Merck. No potential conflicts of interest were disclosed by the other authors.

Conception and design: A.E. Wahner Hendrickson, M.E. Menefee, L.C. Hartmann, H.J. Long, J.M. Reid, J. Allred, A. Chen, C. Erlichman, P. Haluska, S.H. Kaufmann

Development of methodology: M.E. Menefee, J.M. Reid, G.G. Poirier, A. Chen, J. Ji, P. Haluska

Acquisition of data (provided animals, acquired and managed patients, provided facilities, etc.): A.E. Wahner Hendrickson, M.E. Menefee, L.C. Hartmann, H.J. Long, D.W. Northfelt, J.M. Reid, O. Kayode, K.S. Flatten, M.I. Harrell, E.M. Swisher, J. Allred, J. Ji, P. Haluska

Analysis and interpretation of data (e.g., statistical analysis, biostatistics, computational analysis): A.E. Wahner Hendrickson, M.E. Menefee, D.W. Northfelt, J.M. Reid, F. Boakye-Agyeman, M.I. Harrell, E.M. Swisher, D. Satele, J. Allred, J. Ji, Y. Zang, S.H. Kaufmann

Writing, review, and/or revision of the manuscript: A.E. Wahner Hendrickson, M.E. Menefee, D.W. Northfelt, J.M. Reid, F. Boakye-Agyeman, M.I. Harrell, E.M. Swisher, D. Satele, J. Allred, A. Chen, J. Ji, Y. Zang, C. Erlichman, P. Haluska, S.H. Kaufmann

Administrative, technical, or material support (i.e., reporting or organizing data, constructing databases): L.C. Hartmann, J.M. Reid, J. Ji, C. Erlichman, S.H. Kaufmann

Study supervision: A.E. Wahner Hendrickson, J. Allred, J. Ji, C. Erlichman, P. Haluska

Other (study coordinator): J.L. Lensing

Other (all activities, except for review of manuscript, occurred while the author was employed by Mayo Clinic): P. Haluska

The authors would like to thank all patients and oncology providers for their participation in this study. Special thanks go to the research assistants who helped collect data for this study and Sarah A. Buhrow for assistance with preparation of figures. Supported in part by UM1 CA186686 (C. Erlichman, P. Haluska), 5K12 CA090628 (A. Wahner Hendrickson), and P50 CA136393 (L. Hartmann, H. Long, K. Flatten, P. Haluska, S.H. Kaufmann) from the National Cancer Institute as well as support to A. Wahner Hendrickson, E.M. Swisher, and S.H. Kaufmann from Stand Up To Cancer—Ovarian Cancer Research Fund Alliance—National Ovarian Cancer Coalition Dream Team Translational Research Grant (Grant Number: SU2C-AACR-DT16-15).

The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

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Supplementary data