A multicenter phase III trial comparing irinotecan-gemcitabine (IG) with gemcitabine (G) monotherapy as first-line treatment in patients with locally advanced or metastatic pancreatic cancer

Our purpose was to determine the response rate and median and overall survival of gemcitabine as monotherapy versus gemcitabine plus irinotecan in advanced or metastatic pancreatic cancer. Patients with histologically or cytologically confirmed adenocarcinoma who were chemotherapy and radiotherapy naive were enrolled. Patients were centrally randomised at a one-to-one ratio to receive either gemcitabine monotherapy (900 mg m−2 on days 1, 8 and 15 every 4 weeks (arm G), or gemcitabine (days 1 and 8) plus irinotecan (300 mg m−2 on day 8) (arm IG), repeated every 3 weeks. The total number of cycles administered was 255 in the IG arm and 245 in the G arm; the median number of cycles was 3. In all, 145 patients (71 in arm IG and 74 in arm G) were enrolled; 60 and 70 patients from arms IG and G, respectively, were evaluable. A complete clinical response was achieved in three (4.3%) arm G patients; nine (15%) patients in arm IG and four (5.7%) in arm G achieved a partial response. The overall response rate was: arm IG 15% and arm G 10% (95% CI 5.96–24.04 and 95% CI 2.97–17.03, respectively; P=0.387). The median time to tumour progression was 2.8 months and 2.9 months and median survival time was 6.4 and 6.5 months for the IG and G arms, respectively. One-year survival was 24.3% for the IG arm and 21.8% for the G arm. No statistically significant difference was observed comparing gemcitabine monotherapy versus gemcitabine plus irinotecan in the treatment of advanced pancreatic cancer, with respect to overall and 1-year survival

Organometallic indolo[3,2-c]quinolines versus indolo[3,2-d]benzazepines: synthesis, structural and spectroscopic characterization, and biological efficacy

The synthesis of ruthenium(II) and osmium(II) arene complexes with the closely related indolo[3,2-c]quinolines N-(11H-indolo[3,2-c]quinolin-6-yl)-ethane-1,2-diamine (L1) and N′-(11H-indolo[3,2-c]quinolin-6-yl)-N,N-dimethylethane-1,2-diamine (L2) and indolo[3,2-d]benzazepines N-(7,12-dihydroindolo-[3,2-d][1]benzazepin-6-yl)-ethane-1,2-diamine (L3) and N′-(7,12-dihydroindolo-[3,2-d][1]benzazepin-6-yl)-N,N-dimethylethane-1,2-diamine (L4) of the general formulas [(η6-p-cymene)MII(L1)Cl]Cl, where M is Ru (4) and Os (6), [(η6-p-cymene)MII(L2)Cl]Cl, where M is Ru (5) and Os (7), [(η6-p-cymene)MII(L3)Cl]Cl, where M is Ru (8) and Os (10), and [(η6-p-cymene)MII(L4)Cl]Cl, where M is Ru (9) and Os (11), is reported. The compounds have been comprehensively characterized by elemental analysis, electrospray ionization mass spectrometry, spectroscopy (IR, UV–vis, and NMR), and X-ray crystallography (L1·HCl, 4·H2O, 5, and 9·2.5H2O). Structure–activity relationships with regard to cytotoxicity and cell cycle effects in human cancer cells as well as cyclin-dependent kinase (cdk) inhibition and DNA intercalation in cell-free settings have been established. The metal-free indolo[3,2-c]quinolines inhibit cancer cell growth in vitro, with IC50 values in the high nanomolar range, whereas those of the related indolo[3,2-d]benzazepines are in the low micromolar range. In cell-free experiments, these classes of compounds inhibit the activity of cdk2/cyclin E, but the much higher cytotoxicity and stronger cell cycle effects of indoloquinolines L1 and 7 are not paralleled by a substantially higher kinase inhibition compared with indolobenzazepines L4 and 11, arguing for additional targets and molecular effects, such as intercalation into DNA

Implications of TP53 allelic state for genome stability, clinical presentation and outcomes in myelodysplastic syndromes

Tumor protein p53 (TP53) is the most frequently mutated gene in cancer1,2. In patients with myelodysplastic syndromes (MDS), TP53 mutations are associated with high-risk disease3,4, rapid transformation to acute myeloid leukemia (AML)5, resistance to conventional therapies6–8 and dismal outcomes9. Consistent with the tumor-suppressive role of TP53, patients harbor both mono- and biallelic mutations10. However, the biological and clinical implications of TP53 allelic state have not been fully investigated in MDS or any other cancer type. We analyzed 3,324 patients with MDS for TP53 mutations and allelic imbalances and delineated two subsets of patients with distinct phenotypes and outcomes. One-third of TP53-mutated patients had monoallelic mutations whereas two-thirds had multiple hits (multi-hit) consistent with biallelic targeting. Established associations with complex karyotype, few co-occurring mutations, high-risk presentation and poor outcomes were specific to multi-hit patients only. TP53 multi-hit state predicted risk of death and leukemic transformation independently of the Revised International Prognostic Scoring System (IPSS-R)11. Surprisingly, monoallelic patients did not differ from TP53 wild-type patients in outcomes and response to therapy. This study shows that consideration of TP53 allelic state is critical for diagnostic and prognostic precision in MDS as well as in future correlative studies of treatment response

Comprehensive molecular characterization of the hippo signaling pathway in cancer

Hippo signaling has been recognized as a key tumor suppressor pathway. Here, we perform a comprehensive molecular characterization of 19 Hippo core genes in 9,125 tumor samples across 33 cancer types using multidimensional “omic” data from The Cancer Genome Atlas. We identify somatic drivers among Hippo genes and the related microRNA (miRNA) regulators, and using functional genomic approaches, we experimentally characterize YAP and TAZ mutation effects and miR-590 and miR-200a regulation for TAZ. Hippo pathway activity is best characterized by a YAP/TAZ transcriptional target signature of 22 genes, which shows robust prognostic power across cancer types. Our elastic-net integrated modeling further reveals cancer-type-specific pathway regulators and associated cancer drivers. Our results highlight the importance of Hippo signaling in squamous cell cancers, characterized by frequent amplification of YAP/TAZ, high expression heterogeneity, and significant prognostic patterns. This study represents a systems-biology approach to characterizing key cancer signaling pathways in the post-genomic era

Correlation of drug-perturbed marrow cell growth kinetics and intracellular 1-B-D-arabinofuranosylcytosine metabolism with clinical response in adult acute myelogenous leukemia

Abstract To define the relationship between leukemic cell growth, intracellular metabolism of 1-B-D-arabinofuranosylcytosine (ara-C), and the clinical response to timed sequential induction therapy with ara-C in adult acute myelogenous leukemia (AML), growth kinetic and biochemical pharmacologic determinants were examined in AML bone marrow populations. Leukemic blasts from 45 previously untreated patients obtained prior to therapy were cultured in vitro in autologous pretreatment serum (APS) and in serum containing drug-induced humoral stimulatory activity (HSA). Cell populations cultured in HSA demonstrated both increased proliferation, as measured by both [3H]dThd incorporation into DNA and [3H]dThd leukemic blast labeling index, and greater [3H] ara-C leukemic blast labeling index relative to cells maintained in APS. HSA-cultured marrow cells from the 31 patients who achieved complete remission with ara-C-containing therapy demonstrated enhanced intracellular formation of ara-C 5′-triphosphate over three hours and retention of this active form during one subsequent hour in drug-free medium relative to cells maintained in APS. In contrast, cells from the 14 nonresponsive patients demonstrated no such HSA- induced increases in intracellular ara-C metabolism. These studies of human AML marrow cells identify behavior patterns of ara-C activation and net metabolism in the kinetically perturbed, proliferative state that may discriminate clinical sensitivity from clinical resistance to ara-C-based timed sequential therapy. Sensitive AML populations behave similarly to normal hematopoietic cohorts, with direct linkage of HSA- perturbed growth and pharmacologic parameters, while refractory cells demonstrate uncoupling of these determinants in the growth-stimulated state. These in vitro measurements may further serve as a template for prediction of clinical outcome to timed sequential therapy with ara-C, where both pharmacologic and cytokinetic determinants of response are intrinsic to the success of the designed drug scheduling.</jats:p

Correlation of drug-perturbed marrow cell growth kinetics and intracellular 1-B-D-arabinofuranosylcytosine metabolism with clinical response in adult acute myelogenous leukemia

To define the relationship between leukemic cell growth, intracellular metabolism of 1-B-D-arabinofuranosylcytosine (ara-C), and the clinical response to timed sequential induction therapy with ara-C in adult acute myelogenous leukemia (AML), growth kinetic and biochemical pharmacologic determinants were examined in AML bone marrow populations. Leukemic blasts from 45 previously untreated patients obtained prior to therapy were cultured in vitro in autologous pretreatment serum (APS) and in serum containing drug-induced humoral stimulatory activity (HSA). Cell populations cultured in HSA demonstrated both increased proliferation, as measured by both [3H]dThd incorporation into DNA and [3H]dThd leukemic blast labeling index, and greater [3H] ara-C leukemic blast labeling index relative to cells maintained in APS. HSA-cultured marrow cells from the 31 patients who achieved complete remission with ara-C-containing therapy demonstrated enhanced intracellular formation of ara-C 5′-triphosphate over three hours and retention of this active form during one subsequent hour in drug-free medium relative to cells maintained in APS. In contrast, cells from the 14 nonresponsive patients demonstrated no such HSA- induced increases in intracellular ara-C metabolism. These studies of human AML marrow cells identify behavior patterns of ara-C activation and net metabolism in the kinetically perturbed, proliferative state that may discriminate clinical sensitivity from clinical resistance to ara-C-based timed sequential therapy. Sensitive AML populations behave similarly to normal hematopoietic cohorts, with direct linkage of HSA- perturbed growth and pharmacologic parameters, while refractory cells demonstrate uncoupling of these determinants in the growth-stimulated state. These in vitro measurements may further serve as a template for prediction of clinical outcome to timed sequential therapy with ara-C, where both pharmacologic and cytokinetic determinants of response are intrinsic to the success of the designed drug scheduling.</jats:p