posted on 2013-12-11, 00:00authored byJong-Cheol Choi, Hong-Ryul Jung, Junsang Doh
Dynamics of small-sized multicellular
clusters is important for
many biological processes including embryonic development and cancer
metastasis. Previous methods to fabricate multicellular clusters depended
on stochastic adhesion and proliferation of cells on defined areas
of cell-adhering islands. This made precise control over the number
of cells within multicellular clusters impossible. Variation in numbers
may have minimal effects on the behavior of multicellular clusters
composed of tens of cells but would have profound effects on groups
with fewer than ten cells. Herein, we report a new dynamic cell micropatterning
method using a cell-friendly photoresist film by multistep microscope
projection photolithography. We first fabricated single cell arrays
of partially spread cells. Then, by merging neighboring cells, we
successfully fabricated multicellular clusters with precisely controlled
number, composition, and geometry. Using this method, we generated
multicellular clusters of Madin–Darby canine kidney cells with
various numbers and initial geometries. Then, we systematically investigated
the effect of multicellular cluster sizes and geometries on their
motility behaviors. We found that the behavior of small-sized multicellular
clusters was not sensitive to initial configurations but instead was
determined by dynamic force balances among the cells. Initially, the
multicellular clusters exhibited a rounded morphology and minimal
translocation, probably due to contractility at the periphery of the
clusters. For 2-cell and 4-cell clusters, single leaders emerged over
time and entire groups aligned and comigrated as single supercells.
Such coherent behavior did not occur in 8-cell clusters, indicating
a critical group size led by a single leader may exist. The method
developed in the study will be useful for the study of collective
migration and multicellular dynamics.