Metabolic modulation of transcription: The role of one-carbon metabolism.

While it is well known that expression levels of metabolic enzymes regulate the metabolic state of the cell, there is mounting evidence that the converse is also true, that metabolite levels themselves can modulate gene expression via epigenetic modifications and transcriptional regulation. Here we focus on the one-carbon metabolic pathway, which provides the essential building blocks of many classes of biomolecules, including purine nucleotides, thymidylate, serine, and methionine. We review the epigenetic roles of one-carbon metabolic enzymes and their associated metabolites and introduce an interactive computational resource that places enzyme essentiality in the context of metabolic pathway topology. Therefore, we briefly discuss examples of metabolic condensates and higher-order complexes of metabolic enzymes downstream of one-carbon metabolism. We speculate that they may be required to the formation of transcriptional condensates and gene expression control. Finally, we discuss new ways to exploit metabolic pathway compartmentalization to selectively target these enzymes in cancer.

Implementation of a basement membrane invasion assay using mesenteric tissue.

Metastasis accounts for nearly 90% of all cancer associated mortalities. A hallmark of metastasis in malignancies of epithelial origin such as in the pancreas and breast, is invasion of the basement membrane (BM). While various in vitro assays have been developed to address questions regarding the invasiveness of tumors with relation to the BM, most fail to recapitulate a physiologically accurate cell-membrane interface. Here, we introduce a new 3D in vitro assay that uses the mouse mesenteric tissue as a mimic for the epithelial BM. We describe a simple, cost-effective protocol for extraction and setup of the assay, and show that the mesentery is a physiologically accurate model of the BM in its key components-type IV collagen, laminin-1 and perlecan. Furthermore, we introduce a user-friendly quantification tool, Q-Pi, which allows the 3D reconstruction, visualization and quantification of invasion at a cellular level. Overall, we demonstrate that this invasion assay provides a physiologically accurate tool to investigate BM invasion.

GPER Activation Inhibits Cancer Cell Mechanotransduction and Basement Membrane Invasion via RhoA.

The invasive properties of cancer cells are intimately linked to their mechanical phenotype, which can be regulated by intracellular biochemical signalling. Cell contractility, induced by mechanotransduction of a stiff fibrotic matrix, and the epithelial-mesenchymal transition (EMT) promote invasion. Metastasis involves cells pushing through the basement membrane into the stroma-both of which are altered in composition with cancer progression. Agonists of the G protein-coupled oestrogen receptor (GPER), such as tamoxifen, have been largely used in the clinic, and interest in GPER, which is abundantly expressed in tissues, has greatly increased despite a lack of understanding regarding the mechanisms which promote its multiple effects. Here, we show that specific activation of GPER inhibits EMT, mechanotransduction and cell contractility in cancer cells via the GTPase Ras homolog family member A (RhoA). We further show that GPER activation inhibits invasion through an in vitro basement membrane mimic, similar in structure to the pancreatic basement membrane that we reveal as an asymmetric bilayer, which differs in composition between healthy and cancer patients.