Project description:Role of vascular normalization in benefit from metronomic chemotherapy. Mpekris F1, Baish JW2, Stylianopoulos T3, Jain RK4. Author information Abstract Metronomic dosing of chemotherapy-defined as frequent administration at lower doses-has been shown to be more efficacious than maximum tolerated dose treatment in preclinical studies, and is currently being tested in the clinic. Although multiple mechanisms of benefit from metronomic chemotherapy have been proposed, how these mechanisms are related to one another and which one is dominant for a given tumor-drug combination is not known. To this end, we have developed a mathematical model that incorporates various proposed mechanisms, and report here that improved function of tumor vessels is a key determinant of benefit from metronomic chemotherapy. In our analysis, we used multiple dosage schedules and incorporated interactions among cancer cells, stem-like cancer cells, immune cells, and the tumor vasculature. We found that metronomic chemotherapy induces functional normalization of tumor blood vessels, resulting in improved tumor perfusion. Improved perfusion alleviates hypoxia, which reprograms the immunosuppressive tumor microenvironment toward immunostimulation and improves drug delivery and therapeutic outcomes. Indeed, in our model, improved vessel function enhanced the delivery of oxygen and drugs, increased the number of effector immune cells, and decreased the number of regulatory T cells, which in turn killed a larger number of cancer cells, including cancer stem-like cells. Vessel function was further improved owing to decompression of intratumoral vessels as a result of increased killing of cancer cells, setting up a positive feedback loop. Our model enables evaluation of the relative importance of these mechanisms, and suggests guidelines for the optimal use of metronomic therapy. KEYWORDS: drug delivery; immune response; oxygenation; thrompospondin-1; tumor perfusion

Project description:We extend our established agent-based multiscale computational model of infection of lung tissue by SARS-CoV-2 to include pharmacokinetic and pharmacodynamic models of remdesivir. We model remdesivir treatment for COVID-19; however, our methods are general to other viral infections and antiviral therapies. We investigate the effects of drug potency, drug dosing frequency, treatment initiation delay, antiviral half-life, and variability in cellular uptake and metabolism of remdesivir and its active metabolite on treatment outcomes in a simulated patch of infected epithelial tissue. Non-spatial deterministic population models which treat all cells of a given class as identical can clarify how treatment dosage and timing influence treatment efficacy. However, they do not reveal how cell-to-cell variability affects treatment outcomes. Our simulations suggest that for a given treatment regime, including cell-to-cell variation in drug uptake, permeability and metabolism increase the likelihood of uncontrolled infection as the cells with the lowest internal levels of antiviral act as super-spreaders within the tissue. The model predicts substantial variability in infection outcomes between similar tissue patches for different treatment options. In models with cellular metabolic variability, antiviral doses have to be increased significantly (>50% depending on simulation parameters) to achieve the same treatment results as with the homogeneous cellular metabolism.

Project description:Mechanism of anti-tumor drug

Project description:: FTY720 (Fingolimod) is an immunosuppressive drug approved by FDA for Multiple Sclerosis (MS), that has gained attention as anti-cancer drug, thanks to its ability to disrupt the binding between the onco-protein SET and the tumor- suppressor phosphatase PP2A. We investigated FTY720 induced phospho-proteomic changes on acute myeloid leukemia cell lines carrying KMT2A-transocations. The phospho-proteomic data indicated that FTY720 treatment resulted in the down-regulation of phospho-sites associated to protein serine/threonine kinase activity, chromatin organisation and transcription. The findings support the hypothesis of a feedback loop between SET, PP2A and MYC, whereby FTY720 re-activates PP2A with an overall inhibitory effect on MYC, resulting in cell cycle arrest and apoptosis.

Project description:Anti-senescent drug screening by deep learning-based morphology senescence scoring

Project description:We report label-free and targeted quantification of xenobiotic metabolizing enzymes (XME) and transporters in 39 human liver microsomal samples. More than 2800 proteins were identified and quantified. These data can be used in physiologically based pharmacokinetic models for dosage regimen design and precision dosing.

Project description:We have established proteome and phosphoproteome landscapes of two brain sections of juvenile rhesus monkeys in response to long-term fluoxetine treatment following discontinuation of drug dosing.

Project description:The recent advances in anti-cancer treatments have led to a steady increase in the number of cancer survivors, paradoxically also enhancing the number of HF patients who suffer from the undesired cardiotoxic side effects of these anti-tumor treatments. Therapeutic options to reduce or reverse chemotherapy-induced HF are not available. Circular RNAs exhibit high druggability due to the high stability of their special closed loop structure. Circ-INSR overexpression prevents doxorubicin-induced cardiac dysfunction in preclinical murine and human models. Circ-INSR mimics produced in vitro also reduced cardiomyocyte death under doxorubicin stress, highlighting the potential of Circ-INSR-based RNA therapy for future clinical applications.

Project description:The licensed drug rapamycin has potential to be repurposed for geroprotection. A key challenge is to avoid the adverse side-effects of clinical dosing regimes. Here we show a profound memory effect of brief rapamycin treatment. Brief, early adult treatment extended lifespan in Drosophila to the same degree as lifelong dosing. Lasting memory of earlier rapamycin treatment was mediated by elevated autophagy in enterocytes of the gut, accompanied by increased intestinal spermidine levels and improved structure and function of the ageing intestine. Brief elevation of autophagy itself induced a long-term increase in autophagy. In mice, short-term, 3-month treatment also induced a full memory effect, with enhanced autophagy in Paneth cells, improved Paneth cell architecture and gut barrier function at levels induced by chronic treatment, even 6 months after rapamycin was withdrawn. Past rapamycin treatment also enhanced the regenerative potential of aged intestine in intestinal organoids. Full geroprotective effects of chronic rapamycin treatment can thus be obtained with a brief pulse of the drug.

Project description:Phosphoinositide 3-kinase δ (PI3Kδ) plays key roles in lymphocytes and inhibitors targeting this PI3K have been approved for hematological malignancies. While preclinical data in hematological and solid tumor models have demonstrated that PI3Kδ inhibitors (PI3Kδi) can induce anti-tumor immunity, the impact of PI3Kδi in human solid tumors remains unknown. Here, we assessed the effects of the PI3Kδi AMG319 in patients with early stage head and neck cancer in a neoadjuvant, double-blind and placebo-controlled randomised phase-II trial. We find that PI3Kδ inhibition decreases tumor-infiltrating TREG cells and causes heightened cytotoxic potential of tumor-infiltrating CD8+ and CD4+ T cells. Loss of intratumoral TREG cells and an increase in the frequency of activated TREG cells in the blood post-treatment are indicative of systemic effects on TREG cell tissue retention and maintenance. At the chosen AMG319 dosing, the occurrence of immune-related adverse events caused treatment discontinuation in 43% of drug-treated patients, further suggestive of systemic effects on TREG cells. Consistent with this notion, in a murine syngeneic tumor model, PI3Kδi caused a decrease in TREG cells in both tumor and non-malignant tissues and affected TREG subtype composition, maintenance and functionality.