An AMP-activated protein kinase-PGC-1α axis mediates metabolic plasticity in glioblastoma.

Glioblastoma, the most frequent primary malignant brain tumour in adults, is characterised by profound yet dynamic hypoxia and nutrient depletion. To sustain survival and proliferation, tumour cells are compelled to acquire metabolic plasticity with the induction of adaptive metabolic programs. Here, we interrogated the pathways necessary to enable processing of nutrients other than glucose.

Protocol using ex vivo mouse brain slice culture mimicking in vivo conditions to study tumor growth and cell motility of glioblastoma cells.

Herein, we present an ex vivo approach to study glioblastoma (GBM) cell motility in viable mouse brain slice cultures, closely mimicking in vivo features. We detail the preparation and culturing of mouse brain slices followed by tumor cell injection, allowing for the analysis of different aspects of the cellular migration and invasion process. Our assay facilitates testing diverse perturbations including genetic modifications and treatments in a physiological context.

Presenting metabolomics analyses: what's in a number?

Metabolism analysis is complex, accordingly representation and interpretation of metabolomics and fluxomics data is prone to pitfalls, which, if not considered, can lead to misinterpretations. The purpose of this short advice article is to raise awareness for these pitfalls and provide a guideline for biologists on how to best present metabolomics data.

PKM2 diverts glycolytic flux in dependence on mitochondrial one-carbon cycle.

Modeling tumor metabolism in vitro remains challenging. Here, we used galactose as an in vitro tool compound to mimic glycolytic limitation. In contrast to the established idea that high glycolytic flux reduces pyruvate kinase isozyme M2 (PKM2) activity to support anabolic processes, we have discovered that glycolytic limitation also affects PKM2 activity.