Finding magic
Now they had the first domino (SRC) and the last domino (S6K) in the pathway, but they also had a new mystery to solve.
There was no way that SRC could activate S6K by itself. They didn’t physically connect, at least not directly.
Somewhere in the mix was a mystery domino that bridged the gap between SRC and S6K.
They scratched their heads for a long time trying to unmask that go-between domino until they devised a screening technique to tease out even the slightest connection to SRC and discovered magic.
Well, technically they discovered MAGI1, a scaffolding molecule that provides a platform for enzymes to message each other. MAGI1 linked to SRC, and now they had another domino.
Kugel marveled at the technique that plucked MAGI1 out of the bubbling cellular soup.
“It pulled out the same modified protein in every cell we tried. Again, I was struck by the specificity.” Kugel said.
But despite the wizardry its nickname implied, MAGI1 couldn’t turn anything on or off by itself because it lacked enzyme activity.
It couldn’t bridge the gap between SRC and S6K.
“We were still stuck,” Kugel said. “I remember pacing, and trying to think, what exactly this was doing.”
Then they had an insight.
They were thinking that dasatinib turned off an on-switch that triggered the tumors in these mutant cells, and they’d come up empty in their search for that mystery on-switch.
But they wondered if maybe this drug turned on an off-switch instead, which would achieve the same result.
The off-switch they envisioned turned out to be an enzyme called PP2A.
“Dasatinib turned on the off-switch,” said Luk, a post-doctoral research fellow at Fred Hutch.
Somehow in the toppling of dominoes, the drug activated PP2A, which then turned off S6K, which then killed the cells.
They had found all the dominoes in the signaling pathway, starting with SRC and MAGI1 and ending with PP2A, the off-switch that toppled S6K and caused cell death.
But they didn’t know precisely how the dominoes lined up and toppled down.