Choosing the right drug to fight cancer

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Canadian researchers have discovered a molecular indicator of a mechanism that drives cancer progression, giving doctors the possibility of using precision medicine, that is, choosing which patients will respond to a particular anticancer drug.

In a study published in Cancer Research, a team of biochemists at Université de Montreal found that a group of enzymes called SRC kinases chemically modify a tumour-suppressing protein called SOCS1.

“SOCS1 is part of a gene-regulation circuit centered around the master cell proliferation regulator p53, often called the guardian of the genome,” said senior author Gerardo Ferbeyre, an UdeM biochemistry professor and researcher at its hospital research centre, the CRCHUM.

“If p53 or another protein in its network is mutated or becomes chemically modified in some abnormal way, a pattern of gene activation occurs that programs cells to proliferate without control, as occurs in cancers.”

In their research — led by UdeM PhD student Emmanuelle Saint-Germain, with UdeM biochemist Frédéric Lessard and Université de Sherbrooke biochemist Subburaj Ilangumaran — Ferbeyre’s team uncovered a new mechanism by which the p53 circuit becomes unbalanced.

Normally, the SRC kinases add phosphates to proteins in a cell in a highly regulated manner. But in cancer cells the regulation of these enzymes can break down. As a consequence, SOCS1 is abnormally targeted by these enzymes, leading to an effective inhibition of its ability to regulate p53 and stop the proliferation of cancer cells.

The therapeutic implications of UdeM’s cientists discovery could be multiple, they believe.

Since effective anticancer drugs that target SRC kinases already exist, detection of modified SOCS1 in a tumour could be used to predict whether these drugs would be an effective treatment for the tumour.

“We were able to detect phosphorylated SOCS1 in patients’ samples with an antibody that we developed,” said Saint-Germain. “The same antibody could be used to detect phosphorylated SOCS1 in a clinical setting, providing a way to decide whether SRC kinase inhibitors would be an effective treatment.”

Added Ilangumaran, who has been studying SOCS1 in immune cells and cancers for many years: “This new mechanism for SOCS1 inactivation may actually represent a regulatory control that is hijacked by cancer cells. On a more fundamental level, our group’s discovery — that phosphorylation of SOCS1 acquires a new physical form — opens the door to hitherto unknown ways of regulating SOCS1 functions.

“And this has implications for the treatment of autoimmune diseases and for anticancer immunity.”

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Materials provided by University of Montreal. Note: Content may be edited for style and length.