Introduction Improvement in the ability to target underlying drivers and vulnerabilities of high-grade serous ovarian cancer (HG-SOC) requires the development of molecularly annotated pre-clinical models reflective of clinical responses. Methods We generated patient-derived xenografts (PDXs) from consecutive, chemotherapy-naïve, human HG-SOC by transplanting fresh human HG-SOC fragments into subcutaneous and intra-ovarian bursal sites of NOD/SCID IL2Rγnull recipient mice, completed molecular annotation and assessed platinum sensitivity. Results The success rate of xenografting was 83%. Of ten HG-SOC PDXs, all contained mutations in TP53, two were mutated for BRCA1, three for BRCA2, and in two, BRCA1 was methylated. In vivo cisplatin response, determined as platinum sensitive (progression-free interval ≥100 d, n=4), resistant (progression-free interval <100 d, n=3) or refractory (n=3), was largely consistent with patient outcome. Three of four platinum sensitive HG-SOC PDXs contained DNA repair gene mutations, and the fourth was methylated for BRCA1. In contrast, all three platinum refractory PDXs overexpressed dominant oncogenes (CCNE1, LIN28B and/or BCL2). Conclusions Because PDX platinum response reflected clinical outcome, these annotated PDXs will provide a unique model system for preclinical testing of novel therapies for HG-SOC.
Accurately identifying patients with high-grade serous ovarian carcinoma (HGSOC) who respond to poly(ADP-ribose) polymerase inhibitor (PARPi) therapy is of great clinical importance. Here we show that quantitative BRCA1 methylation analysis provides new insight into PARPi response in preclinical models and ovarian cancer patients. The response of 12 HGSOC patient-derived xenografts (PDX) to the PARPi rucaparib was assessed, with variable dose-dependent responses observed in chemo-naive BRCA1/2-mutated PDX, and no responses in PDX lacking DNA repair pathway defects. Among BRCA1-methylated PDX, silencing of all BRCA1 copies predicts rucaparib response, whilst heterozygous methylation is associated with resistance. Analysis of 21 BRCA1-methylated platinum-sensitive recurrent HGSOC (ARIEL2 Part 1 trial) confirmed that homozygous or hemizygous BRCA1 methylation predicts rucaparib clinical response, and that methylation loss can occur after exposure to chemotherapy. Accordingly, quantitative BRCA1 methylation analysis in a pre-treatment biopsy could allow identification of patients most likely to benefit, and facilitate tailoring of PARPi therapy.
From July 1986 to July 1989, 40 patients (92% pretreated) with deep-seated, advanced soft tissue sarcomas (STS, 25 patients), Ewing's sarcomas (ES, eight patients), osteosarcomas (OS, three patients) and chondrosarcomas (ChS, four patients) were treated at the University of Munich in a protocol involving regional hyperthermia (RHT) combined with ifosfamide plus etoposide. A total of 265 RHT treatments (mean, 6.6 RHT per patient) were applied including 33 pelvic, four extremity, and three abdominal sites. The mean tumor volume was 537 cc (range, 50 to 2,980 cc). For systemic chemotherapy, all patients received ifosfamide (1.5 g/m2, days 1 to 5), etoposide (100 mg/m2, days 1, 3, and 5), and mesna (300 mg/m2 x 4, days 1 to 5) with RHT given only on days 1 and 5 in repeated cycles every 4 weeks. Acute toxicity consisted primarily of pain (57%) combined with local discomfort within the annular phased array applicator (AA) of the BSD hyperthermia system (BSD Medical Corp, Salt Lake City, UT). The average maximum systemic temperature was 37.4 +/- 0.5 degrees C, and there was no indication of enhanced bone marrow toxicity due to the addition of RHT to the systemic chemotherapy. Detailed thermal mapping by invasive thermometry was performed in all patients. In 38 assessable patients, the overall objective response rate was 37%: six complete responses (CRs), four partial responses (PRs), and four favorable histologic responses (FHRs) (95% confidence limits, 22% to 54%). Complete responders are alive and disease-free at 40, 35, 23, 19, 19, and 8 months. Of patients with PR and FHR, two died from metastatic disease after 4 and 17 months and one died from other disease after 27 months. The remaining five patients are stable at 37, 25, 21, 13, and 8 months. Eleven patients showed no change (NC), and 13 patients showed local tumor progression (PD). The mean observation time for all patients was 11.6 months. The time-averaged temperatures (Ts) of all RHT treatments calculated as 20% (T20), 50% (T50), or 90% (T90) of measured tumor sites differed significantly between responders and nonresponders (T20, P = .003; T50, P = .006; and T90, P = .004; respectively). These data support activity for ifosfamide-etoposide combined with RHT in pretreated patients with advanced sarcomas.
Hypervitaminosis D as a cause of hypercalcemia may be due to vitamin D intoxication, granulomatous diseases, or abnormalities of vitamin D metabolism. The CYP24A1 gene encodes for the 24‐hydroxylase enzyme, which is responsible for the catabolism of 25‐hydroxyvitamin D (25(OH)D) and 1,25‐dihydroxyvitamin D (1,25(OH)2D). Mutations in CYP24A1 can result in elevated 1,25(OH)2D causing parathyroid hormone (PTH)‐independent hypercalcemia, hypercalciuria, nephrolithiasis, and nephrocalcinosis. We present the cases of two siblings exhibiting hypercalcemia secondary to a CYP24A1 loss‐of‐function mutation. Case 1 presented initially with PTH‐dependent hypercalcemia, with localization of a left upper parathyroid adenoma on parathyroid technetium sestamibi (99mTc‐MIBI) uptake study. Despite parathyroidectomy (180 mg adenoma), hypercalcemia, hypercalciuria, and low normal PTH levels persisted. A repeat parathyroid 99mTc‐MIBI uptake study localized a second adenoma and a right inferior parathyroidectomy was performed (170 mg adenoma). PTH subsequently became undetectable, however hypercalcemia and hypercalciuria persisted. A new presentation of PTH‐independent hypercalcemia found to be secondary to a CYP24A1 loss‐of‐function mutation in his sibling, Case 2, signaled the underlying cause. Cascade testing confirmed both siblings were homozygous for the pathogenic variant c.1186C>T, p.Arg396Trp (R396W) of CYP24A1 (NM_000782.5). In clinical practice CYP24A1 loss‐of‐function mutations should be considered in patients presenting with PTH‐independent hypercalcemia, hypercalciuria, and 1,25(OH)2D levels in the upper normal or elevated range. Although in our case assays of 24,25(OH)2D were not available, calculation of the 25(OH)D:24,25(OH)2D ratio can assist in the diagnostic process. Possible treatments to manage the risk of hypercalcemia in patients with a CYP24A1 loss‐of‐function mutation include avoidance of vitamin D oversupplementation and excessive sun exposure. Hydration and bisphosphonate therapy can be useful in managing the hypercalcemia. Although not utilized in our cases, treatment with ketoconazole, fluconazole, and rifampicin have been described as potential therapeutic options. © 2023 The Authors. JBMR Plus published by Wiley Periodicals LLC on behalf of American Society for Bone and Mineral Research.
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