3-D model reveals secrets of metastasis
A cancer cell breaks away from a primary tumor and settles in a new location, where it once again divides. Pharmaceutical companies typically use simplistic two-dimensional assays for this process, which is known as metastasis, to evaluate anti-cancer therapeutics. In these assays, cells crawl across the surface of a matrix, traveling in a single plane. But a new study indicates that this approach misses some crucial phenomena.
Working in the labs of Whitehead Member Paul Matsudaira and MIT professor Douglas Lauffenburger, postdoctoral researcher Muhammad Zaman discovered that cells move quite differently in three dimensions. His study, which focused on human prostate tumor cells, appeared this week in the online early edition of Proceedings of the National Academy of Sciences.
"Two-dimensional assays ignore the obstacles that cells face in their natural contexts," explains Zaman, who recently became an assistant professor at the University of Texas at Austin. "In 3D, cells move through a thick jungle of fibers, or "vines"
Cells must either squeeze through or chop up these putative vines to get anywhere. As a result, they move slower in three dimensions.
In an interesting twist, all cells need at least some vines to move, as they latch onto the "branches" with claw-like proteins called integrins and pull themselves forward. When Zaman disabled some of these claws, in a manner analogous to certain anti-cancer drugs, the cells moving across the top of the jungle canopy (in two dimensions) needed a greater number of vines to keep up their pace, while cells plowing through the jungle instead needed vines chopped to maintain the same speed. The complexity of this situation is further increased in that the cells become dramatically sensitive to the stiffness of the vines when the integrins are disabled and consequently tend to squeeze through the vines rather than pushing them aside.
"Our findings help explain why two-dimensional assays for metastasis-inhibiting drugs do not effectively predict their effects in tissue," says Lauffenburger, who is director of MITâ€
But technology must improve before more complicated 3D studies are attempted. For his 3D work Zaman worked with one sample at a time, using a special confocal microscope at the Whitehead-MIT BioImaging Center. The microscope divided each specimen into virtual slices, generating a new stack of images every 15 minutes.
"It took me about a year to get enough data because the microscope wasnâ€
"Muhammad was successful for two reasons," says Matsudaira. "His computational model predicted what would happen in virtual experiments and then he was able to go straight to test the predictions with these complicated 3D experiments. As a result, the sophisticated models of cell movement enhance our understanding of key biological processes, including metastasis."
The research was funded by the National Institutes of Health, the National Science Foundation and the Sokol Foundation for Cancer Research.
Last reviewed: By John M. Grohol, Psy.D. on 30 Apr 2016
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