Lactate promotes glutamine uptake and metabolism in oxidative cancer cells.

Oxygenated cancer cells have a high metabolic plasticity as they can use glucose, glutamine and lactate as main substrates to support their bioenergetic and biosynthetic activities. Metabolic optimization requires integration. While glycolysis and glutaminolysis can cooperate to support cellular proliferation, oxidative lactate metabolism opposes glycolysis in oxidative cancer cells engaged in a symbiotic relation with their hypoxic/glycolytic neighbors.

Paclitaxel-loaded micelles enhance transvascular permeability and retention of nanomedicines in tumors.

Paclitaxel (PTX)-loaded polymeric micelles (M-PTX) have been shown to enhance the blood flow and oxygenation of tumors 24h after treatment. We hypothesized that these changes in the tumor microenvironment could lead to an enhancement of the EPR (enhanced permeability and retention) effect. M-PTX, administered 24h before analysis, increased the accumulation of macromolecules, nanoparticles and polymeric micelles in tumors.

A mitochondrial switch promotes tumor metastasis.

Metastatic progression of cancer is associated with poor outcome, and here we examine metabolic changes underlying this process. Although aerobic glycolysis is known to promote metastasis, we have now identified a different switch primarily affecting mitochondria. The switch involves overload of the electron transport chain (ETC) with preserved mitochondrial functions but increased mitochondrial superoxide production.

Optimization of tumor radiotherapy with modulators of cell metabolism: toward clinical applications.

Most solid tumors are characterized by unstable perfusion patterns, creating regions of hypoxia that are detrimental to radiotherapy treatment response. Because postsurgical radiotherapy, alone or in combination with other interventions, is a first-line treatment for many malignancies, strategies aimed at homogeneously increasing tumor pO2 have been the focus of intense research over the past decades. Among other approaches of demonstrable clinical and preclinical utility, this review focuses on those directly targeting oxygen consumption to redirect oxygen from a metabolic fate to the stabilization of radiation-induced DNA damage, more particularly drugs targeting glucose and lactate metabolism, nitric oxide donors or inducers, and mitogen-activated protein kinase pathway inhibitors.

Lactate activates HIF-1 in oxidative but not in Warburg-phenotype human tumor cells.

Cancer can be envisioned as a metabolic disease driven by pressure selection and intercellular cooperativeness. Together with anaerobic glycolysis, the Warburg effect, formally corresponding to uncoupling glycolysis from oxidative phosphorylation, directly participates in cancer aggressiveness, supporting both tumor progression and dissemination. The transcription factor hypoxia-inducible factor-1 (HIF-1) is a key contributor to glycolysis.

Lactate stimulates angiogenesis and accelerates the healing of superficial and ischemic wounds in mice.

Wounds notoriously accumulate lactate as a consequence of both anaerobic and aerobic glycolysis following microcirculation disruption, immune activation, and increased cell proliferation. Several pieces of evidence suggest that lactate actively participates in the healing process through the activation of several molecular pathways that collectively promote angiogenesis. Lactate indeed stimulates endothelial cell migration and tube formation in vitro, as well as the recruitment of circulating vascular progenitor cells and vascular morphogenesis in vivo.

Targeting the lactate transporter MCT1 in endothelial cells inhibits lactate-induced HIF-1 activation and tumor angiogenesis.

Switching to a glycolytic metabolism is a rapid adaptation of tumor cells to hypoxia. Although this metabolic conversion may primarily represent a rescue pathway to meet the bioenergetic and biosynthetic demands of proliferating tumor cells, it also creates a gradient of lactate that mirrors the gradient of oxygen in tumors. More than a metabolic waste, the lactate anion is known to participate to cancer aggressiveness, in part through activation of the hypoxia-inducible factor-1 (HIF-1) pathway in tumor cells.

Targeting lactate-fueled respiration selectively kills hypoxic tumor cells in mice.

Tumors contain oxygenated and hypoxic regions, so the tumor cell population is heterogeneous. Hypoxic tumor cells primarily use glucose for glycolytic energy production and release lactic acid, creating a lactate gradient that mirrors the oxygen gradient in the tumor. By contrast, oxygenated tumor cells have been thought to primarily use glucose for oxidative energy production.