Brentuximab vedotin (BV) is an antibody-drug conjugate that specifically delivers the potent cytotoxic drug MMAE to CD30-positive cells. BV is FDA-approved for treatment of relapsed/refractory Hodgkin lymphoma (HL) and anaplastic large cell lymphoma (ALCL); however, many patients do not achieve complete remission and develop BV resistant disease. We selected for BV-resistant HL (L428) and ALCL (Karpas-299) cell lines using either constant (ALCL) or pulsatile (HL) exposure to BV. We confirmed drug resistance by MTS assay, and analyzed CD30 expression in resistant cells by flow cytometry, qRT-PCR, and Western blotting. We also measured drug exporter expression, MMAE resistance, and intracellular MMAE concentrations in BV-resistant cells. Additionally, tissue biopsy samples from 10 HL and 5 ALCL patients who had relapsed or progressed after BV treatment were analyzed by immunohistocytochemistry for CD30 expression. The resistant ALCL cell line, but not the HL cell line, demonstrated downregulated CD30 expression compared to the parental cell line. In contrast, the HL cell line, but not the ALCL cell line, exhibited MMAE resistance and increased expression of the MDR1 drug exporter compared to the parental line. For both HL and ALCL, samples from patients relapsed/resistant on BV persistently expressed CD30 by immunohistocytochemistry. One HL patient sample expressed MDR1 by immunohistocytochemistry. Although loss of CD30 expression is a possible mode of BV resistance in ALCL in vitro models, this has not been confirmed in patients. MMAE resistance and MDR1 expression are possible modes of BV resistance for HL both in vitro and in patients.
Purpose: In classical Hodgkin lymphoma, the malignant Reed-Sternberg cells express the cell surface marker CD30. Brentuximab vedotin is an antibody-drug conjugate (ADC) that selectively delivers a potent cytotoxic agent, monomethyl auristatin E (MMAE), to CD30-positive cells. Although brentuximab vedotin elicits a high response rate (75%) in relapsed/refractory Hodgkin lymphoma, most patients who respond to brentuximab vedotin eventually develop resistance.Patients and Methods: We developed two brentuximab vedotin-resistant Hodgkin lymphoma cell line models using a pulsatile approach and observed that resistance to brentuximab vedotin is associated with an upregulation of multidrug resistance-1 (MDR1). We then conducted a phase I trial combining brentuximab vedotin and cyclosporine A (CsA) in patients with relapsed/refractory Hodgkin lymphoma.Results: Here, we show that competitive inhibition of MDR1 restored sensitivity to brentuximab vedotin in our brentuximab vedotin-resistant cell lines by increasing intracellular MMAE levels, and potentiated brentuximab vedotin activity in brentuximab vedotin-resistant Hodgkin lymphoma tumors in a human xenograft mouse model. In our phase I trial, the combination of brentuximab vedotin and CsA was tolerable and produced an overall and complete response rate of 75% and 42% in a population of patients who were nearly all refractory to brentuximab vedotin.Conclusions: This study may provide a new therapeutic strategy to combat brentuximab vedotin resistance in Hodgkin lymphoma. This is the first study reporting an effect of multidrug resistance modulation on the therapeutic activity of an ADC in humans. The expansion phase of the trial is ongoing and enrolling patients who are refractory to brentuximab vedotin to confirm clinical activity in this population with unmet need.
Purpose Inhibitors of DNA (cytosine-5)-methyltransferases (DNMT) are active antineoplastic agents. We conducted the first-in-human phase I trial of 5-fluoro-2′-deoxycytidine (FdCyd), a DNMT inhibitor stable in aqueous solution, in patients with advanced solid tumors. Objectives were to establish the safety, maximum tolerated dose (MTD), pharmacokinetics, and pharmacodynamics of FdCyd + tetrahydrouridine (THU). Methods FdCyd + THU were administered by 3 h IV infusion on days 1–5 every 3 weeks, or days 1–5 and 8–12 every 4 weeks. FdCyd was administered IV with a fixed 350 mg/m2/day dose of THU to inhibit deamination of FdCyd. Pharmacokinetics of FdCyd, downstream metabolites and THU were assessed by LC–MS/MS. RBC γ-globin expression was evaluated as a pharmacodynamics biomarker. Results Patients were enrolled on the 3-week schedule at doses up to 80 mg/m2/day without dose-limiting toxicity (DLT) prior to transitioning to the 4-week schedule, which resulted in an MTD of 134 mg/m2/day; one of six patients had a first-cycle DLT (grade 3 colitis). FdCyd ≥40 mg/m2/day produced peak plasma concentrations >1 μM. Although there was inter-patient variability, γ-globin mRNA increased during the first two treatment cycles. One refractory breast cancer patient experienced a partial response (PR) of >90 % decrease in tumor size, lasting over a year. Conclusions The MTD was established at 134 mg/m2 FdCyd + 350 mg/m2 THU days 1–5 and 8–12 every 4 weeks. Based on toxicities observed over multiple cycles, good plasma exposures, and the sustained PR observed at 67 mg/m2/day, the phase II dose for our ongoing multi-histology trial is 100 mg/m2/day FdCyd with 350 mg/m2/day THU.
Background: Both Hodgkin lymphoma (HL) and anaplastic large cell lymphoma (ALCL) express surface CD30. Brentuximab vedotin (BV) is an antibody-drug conjugate that delivers a potent cytotoxic agent, monomethyl auristatin E (MMAE), specifically to cells expressing surface CD30. Although BV elicits a high response rate (75% in HL and 86% in ALCL), the majority of patients who do not attain complete response (CR) will eventually develop resistance to BV. It is not known whether resistance to BV is through a) CD 30 alterations b) resistance to cytotoxic agent MMAE or c) overexpression of drug exporters. We developed 2 BV-resistant cell models and obtained primary lymphoma samples from patients with relapsed/progressive disease post BV therapy. We examined CD30 expression, MMAE resistance, drug exporter expression, and gene expression profiles in vitro and in vivo to determine mechanisms of resistance to BV. Methods: HL cell line(L428) and ALCL cell line (KARPAS 299) were used for in vitro experiments. The selection of BV resistant cell model (L428R and KARPAS 299R) used two different approaches (pulsatile or constant exposure). Both BV resistance and MMAE resistance were confirmed by MTS assays. CD30 expression was measured by flow cytometry,qRT-PCR, and Western blotting. Drug exporter expression was measured using qRT-PCR to MDR1, MRP1, and MRP3. In vivo experiments utilized primary tumor samples from 15 HL and 4 ALCL patients who had developed relapsed/progressive disease post BV treatment. CD30 expression was assessed by immunohistocytochemistry (IHC). Gene expression profiling was performed in both parental and resistant HL and ALCL cells, and in 4 ALCL primary tumor samples using Affymetrix whole genome GeneChip® Human Genome U133 2.0 Plus. Results: MTS assay showed the IC50 of KARPAS 299R to BV shifted from 24 +/- 10 ng/ml to 28 +/- 9 ug/ml, an 1183-fold increase. MTS assay also showed the IC50 of KARPAS 299R to MMAE only increased 2-fold when compared to KARPAS 299. Flow cytometry showed downregulation of surface CD30 expression in KARPAS 299R as compared to KARPAS 299 parental (59% vs. 96%, median intensity 78 +/- 17 vs. 591 +/- 51). This downregulation was confirmed by qRT-PCR and Western blotting for CD30. As KARPAS 299R is a mixed cell population, we sorted them into CD30+ and CD30- subpopulations. We then analyzed for BV sensitivity based on CD 30 expression status in KARPAS 299R. MTS assay showed that KARPAS 299R CD30+ cells were equally as resistant to BV as KARPAS 299R CD30- cells (figure 1A). IHC performed in 4 ALCL primary tumor samples showed persistent CD 30 expression in relapsed/progressive tumor specimens post BV treatment. Gene expression profiling on KARPAS 299R showed downregulation of CD30 as compared to KARPAS 299. Gene expression profiling on pre- and post-treatment ALCL samples (8) did not show significant differences in CD30 expression. The top four upregulated genes in relapsed/progressive samples as compared to pretreatment samples were LCE3D, WNT3, TNNT, CITED2. The top four downregulated genes in relapsed/progressive samples as compared to pretreatment samples were CXCL13, C4orf7, MS4A1, and IGJ. MTS assay showed that the IC50 of L428R to BV has shifted from 32 +/- 11 ug/ml to 391 +/- 92 ug/ml, a 12-fold increase. MTS assays showed the IC50 of L428R to MMAE has increased 99-folds when compared to L428 (figure 1B). No difference was seen in CD 30 expression by flow cytometry, qRT-PCR, or western blotting between L428R vs. L428. IHC performed in 15 HL primary tumors show persistent CD30 expression in relapsed/progressive tumor specimen post-BV treatment. qRT-PCR showed upregulation of MDR1mRNA in L428R as compared to L428. Gene expression profiling on L428R showed upregulation of MDR1 as compared to L428. Conclusion: Downregulation of CD30 is seen in BV-resistant ALCL cell model. However, sensitivity to BV did not depend solely on the level of CD30 expression as CD30+ cell subpopulations still exhibited resistance to BV in vitro. Upregulation of MDR-1 and resistance to MMAE were seen in BV-resistant HL cells, rather than downregluation of CD30. Downregulation of CD30 was not seen in HL or ALCL primary tumors. Further work is ongoing to explore/validate potential targets derived from gene expression profiling in ALCL primary tumors. Figure 1A Sensitivity to BV is not related to CD30 expression Figure 1A. Sensitivity to BV is not related to CD30 expression Figure 1B. Figure 1B. Viability of L-428 parental versus BV-resistant cells Disclosures Chen: Seattle Genetics, Inc.: Consultancy, Research Funding, Speakers Bureau, Travel expenses Other.
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