Controlled Three-Dimensional Tumor Microenvironments Recapitulate Phenotypic Features and Differential Drug Response in Early vs Advanced Stage Breast Cancer.

Progression to advanced stage metastatic disease, resistance to endocrine therapies, and failure of drug combinations remain major barriers in the breast cancer therapy. Tumor microenvironments play an important role in progression from non-invasive to invasive disease as well as in response to therapies. Development of physiologically relevant, three-dimensional (3D) controlled microenvironments that can reliably recapitulate tumor progression from the early non-invasive to advanced metastatic stage will contribute to our understanding of disease biology and serve as a tool for screening of drug regimens targeting different disease stages. We have recently engineered physicochemical microenvironments by precisely controlling the size of 3D microtumors of non-invasive T47D breast cancer cells. We hypothesized that the precise control over physiochemical microenvironments will generate unique molecular signatures in size-controlled microtumors (small 150 µm vs large 600 µm) leading to differential phenotypic features and drug responses. The results indicated that large (600 µm) T47D microtumors exhibited traits of clinically advanced tumors such as hypoxia, reactive oxygen species, mesenchymal marker upregulation and collective cell migration unlike non-hypoxic, non-migratory small microtumors (150 µm). Interestingly, large microtumors also lost estrogen receptor alpha (ER-α) protein, consequently showing resistance to 4-hydroxytamoxifen (4-OHT). On the other hand, large microtumors showed upregulation of pro-angiogenic marker, vascular endothelial growth factor (VEGF), and hence were more responsive than small microtumors to the growth inhibition by anti-VEGF antibody. Surprisingly, both small and large microtumors exhibited comparable levels of phosphorylated epidermal growth factor receptor (pEGFR) and downstream signaling molecules such as AKT. As a consequence, both small and large microtumors showed comparable growth inhibition in response to gefitinib (inhibitor preferentially targeting EGFR) independent of microtumor size. Thus, precise control over the microenvironmental factors successfully recapitulated molecular characteristics underlying early vs advanced stage disease using the same non-invasive T47D cells. Such unique molecular signatures further resulted in differential response of small and large microtumors to anti-estrogen, and anti-VEGF treatments with comparable response to the EGFR-targeted therapies, underlining the importance of such stage-specific disease progression models in cancer drug discovery.

Human mass balance study of TAS-102 using (14)C analyzed by accelerator mass spectrometry.

BACKGROUND: TAS-102 is an oral fluoropyrimidine prodrug composed of trifluridine (FTD) and tipiracil hydrochloride (TPI) in a 1:0.5 ratio. FTD is a thymidine analog, and it is degraded by thymidine phosphorylase (TP) to the inactive trifluoromethyluracil (FTY) metabolite. TPI inhibits degradation of FTD by TP, increasing systemic exposure to FTD. METHODS: Patients with advanced solid tumors (6 M/2 F; median age 58 years; PS 0-1) were enrolled on this study. Patients in group A (N = 4) received 60 mg TAS-102 with 200 nCi [(14)C]-FTD, while patients in group B (N = 4) received 60 mg TAS-102 with 1000 nCi [(14)C]-TPI orally. Plasma, blood, urine, feces, and expired air (group A only) were collected up to 168 h and were analyzed for (14)C by accelerator mass spectrometry and analytes by LC-MS/MS. RESULTS: FTD: 59.8% of the (14)C dose was recovered: 54.8% in urine mostly as FTY and FTD glucuronide isomers. The extractable radioactivity in the pooled plasma consisted of 52.7% FTD and 33.2% FTY. TPI: 76.8% of the (14)C dose was recovered: 27.0% in urine mostly as TPI and 49.7% in feces. The extractable radioactivity in the pooled plasma consisted of 53.1% TPI and 30.9% 6-HMU, the major metabolite of TPI. CONCLUSION: Absorbed (14)C-FTD was metabolized and mostly excreted in urine. The majority of (14)C-TPI was recovered in feces, and the majority of absorbed TPI was excreted in urine. The current data with the ongoing hepatic and renal dysfunction studies will provide an enhanced understanding of the TAS-102 elimination profile.

Trabectedin (ET-743, Yondelis) is a substrate for P-glycoprotein, but only high expression of P-glycoprotein confers the multidrug resistance phenotype.

Trabectedin (ET-743, Yondelis) is a novel anticancer drug currently undergoing phase II and III investigations. There are various and conflicting reports whether trabectedin is a substrate for P-glycoprotein (P-gp), an important factor in drug disposition and multi-drug resistance (MDR). We have now unambiguously shown that trabectedin is a P-gp substrate by investigating vectorial transport over monolayers of LLC-PK1 pig kidney and Madine-Darby Canine kidney (MDCK) cells and the mdr1a and/or MDR1 transfected subclones. We further characterized the cytotoxic effects and cellular accumulation of trabectedin in these cell lines as well as in a panel of other cell lines with high or moderate expression levels of P-gp. Trabectedin displayed the typical MDR phenotype only in highly P-gp expressing cell lines, but not in cell lines with expression levels more closely conforming to clinical samples, suggesting that P-gp will not confer resistance to trabectedin in cancer patients.

Human metabolism of [(14)C]indisulam following i.v. infusion in cancer patients.

Indisulam is a new anticancer drug with a unique mechanism of action, arresting the cell cycle at the G1/S transition. The major excretory pathway of indisulam is via the urine, accounting for 63% of the radioactive dose ([(14)C]indisulam) administered in a human mass balance study. Radiochromatographic profiling of urine samples resulted in the detection of several radioactive peaks. The purpose of the present investigation was to elucidate the chemical structures of these observed indisulam metabolites. We collected fractions after chromatographic separation of the urine samples. These fractions were analysed using tandem mass spectrometry. We propose the chemical structure of 15 indisulam metabolites in urine. The metabolism of indisulam is very complex, consisting of oxidative dechlorination, hydroxylation, hydrolysis, acetylation, sulphation and glucuronidation. The clinical relevance of the observed indisulam metabolites needs further investigation.

Quantitative determination of the novel anticancer drug E7070 (indisulam) and its metabolite (1,4-benzenedisulphonamide) in human plasma, urine and faeces by high-performance liquid chromatography coupled with electrospray ionization tandem mass spectrometry.

E7070 (indisulam) is a novel anticancer drug currently undergoing clinical investigation. We present a sensitive and specific method for the quantitative determination of E7070 and its metabolite M1 (1,4-benzenedisulphonamide) in human plasma, urine and faeces. The analytes and their tetra-deuterated analogues, which were used as internal standards, were isolated from the biological matrix by solid-phase extraction with OASIS cartridges (0.5 mL plasma or 1 mL urine) and by liquid-liquid extraction with ethyl acetate at pH 5 (1 mL faecal homogenate). The analytes were separated on a C8 reversed-phase chromatographic column and analyzed using electrospray ionization and tandem mass spectrometric detection in the negative ion mode. The validated concentration ranges in plasma were 0.1-20 microg/mL for E7070 and 0.01-2 microg/mL for M1. In urine and faecal homogenate, a concentration range from 0.05-10 microg/mL or microg/g, respectively, was validated for both analytes. Validation of the plasma assay was performed according to the most recent FDA guidelines. The assay fulfilled all generally accepted requirements for linearity (r > 0.99, residuals between -8 and 10%), accuracy (-13.5 to 1.4%) and precision (all less than 11%) in the tested matrices. We investigated recovery, stability (working solutions at -20 degrees C and at room temperature, biological matrices at -20 degrees C, room temperature and after 3 freeze/thaw cycles; final extracts at room temperature) and robustness. All these parameters were found acceptable. This method is suited for mass balance studies or therapeutic drug monitoring, as demonstrated by a case example showing plasma concentrations and cumulative excretion of E7070 and M1 in urine and faeces. Furthermore, we show the presence of E7070 metabolites in patient urine.