A possible primary cause of cancer: deficient cellular interactions in endocrine pancreas

Metabolic therapies inhibit tumor growth in vivo and in silico

In the recent years, cancer research succeeded with sensitive detection methods, targeted drug delivery systems, and the identification of a large set of genes differently expressed. However, although most therapies are still based on antimitotic agents, which are causing wide secondary effects, there is an increasing interest for metabolic therapies that can minimize side effects. In the early 20th century, Otto Warburg revealed that cancer cells rely on the cytoplasmic fermentation of glucose to lactic acid for energy synthesis (called "Warburg effect"). Our investigations aim to reverse this effect in reprogramming cancer cells' metabolism. In this work, we present a metabolic therapy specifically targeting the activity of specific enzymes of central carbon metabolism, combining the METABLOC bi-therapeutic drugs combination (Alpha Lipoic Acid and Hydroxycitrate) to Metformin and Diclofenac, for treating tumors implanted in mice. Furthermore, a dynamic metabolic model describing central carbon metabolism as well as fluxes targeted by the drugs allowed to simulate tumors progression in both treated and non-treated mice, in addition to draw hypotheses on the effects of the drugs on tumor cells metabolism. Our model predicts metabolic therapies-induced reversed Warburg effect on tumor cells.

An alteration of the endocrine pancreas involved in cancer

Tumor cells display hybrid metabolic features: some of their enzymes are phosphorylated as normally observed when catabolic hormones stimulate Gs-coupled receptors, whereas other enzymes adopt a configuration normally found in anabolic situations, mediated via tyrosine kinase receptors. Consequently, tumor cells have to rewire their metabolic pathways differently, whereas differentiated cells seem to respond preferentially to catabolic hormones. This gives mitotic cells a selective advantage since they deplete other cell reserves for their benefit. The pancreatic gamma aminobutyric acid selection switch between anabolism and catabolism explains the process, that is, a deficient release of gamma aminobutyric acid from beta cells leads to a concomitant release of catabolic glucagon and anabolic insulin and to a progressive desensitisation of insulin receptors on differentiated cells. New stem cells, with non-desensitised insulin receptors, respond to the dual anabolic and catabolic signals and rewire their metabolism in cancer mode. The aim of this letter was to discuss the causal pancreatic alteration of the anabolic-catabolic selection switch.