Biased migration of confined neutrophil-like cells in asymmetric hydraulic environments

Prentice-Mott, Harrison; Chang, Chi-Han; Mahadevan, L.; Mitchison, Timothy J.; Irimia, Daniel; Shah, Jagesh V.

doi:10.1073/pnas.1317441110

Cited by 93 publications

(112 citation statements)

References 28 publications

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“…S1A) (5,8). Cells enter microchannels that connect two external reservoirs that Significance Cells orient their motility along chemical gradients using sensitive measurements of the external environment, a process termed chemotaxis.…”

Section: Resultsmentioning

confidence: 99%

“…Operation of the microfluidic devices was carried out as previously described (5,8) with details available in the SI Experimental Procedures. To expose cells to dynamic changes in concentration, cells were loaded and allowed to enter the microchannels in a uniform concentration of 10 nM fMLP by clamping off the 0 nM reservoir.…”

Section: Methodsmentioning

confidence: 99%

“…The local cues for cellular orientation are chemical, either in the form of soluble gradients or substrate-bound moieties (2,3), or physical, in the form of pressure, substrate adhesion, etc. (4,5). In particular, chemical cues activate signaling at the cell surface and are integrated within the cell cytoplasm to give rise to a polarization in the direction of the local gradient.…”

mentioning

confidence: 99%

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Directional memory arises from long-lived cytoskeletal asymmetries in polarized chemotactic cells

Prentice-Mott

Meroz

Carlson

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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Chemotaxis, the directional migration of cells in a chemical gradient, is robust to fluctuations associated with low chemical concentrations and dynamically changing gradients as well as high saturating chemical concentrations. Although a number of reports have identified cellular behavior consistent with a directional memory that could account for behavior in these complex environments, the quantitative and molecular details of such a memory process remain unknown. Using microfluidics to confine cellular motion to a 1D channel and control chemoattractant exposure, we observed directional memory in chemotactic neutrophil-like cells. We modeled this directional memory as a long-lived intracellular asymmetry that decays slower than observed membrane phospholipid signaling. Measurements of intracellular dynamics revealed that moesin at the cell rear is a longlived element that when inhibited, results in a reduction of memory. Inhibition of ROCK (Rho-associated protein kinase), downstream of RhoA (Ras homolog gene family, member A), stabilized moesin and directional memory while depolymerization of microtubules (MTs) disoriented moesin deposition and also reduced directional memory. Our study reveals that long-lived polarized cytoskeletal structures, specifically moesin, actomyosin, and MTs, provide a directional memory in neutrophil-like cells even as they respond on short time scales to external chemical cues. . In particular, chemical cues activate signaling at the cell surface and are integrated within the cell cytoplasm to give rise to a polarization in the direction of the local gradient. Although these processes have been the subject of detailed experimental study and theoretical and computational modeling, the mechanisms by which this orientation is achieved and maintained in the face of environmental noise remains incomplete.Although migration might be thought of as being very sensitive to the variations in the external environment, instead, we see robust migration in a variety of fluctuating environments. These observations all point to the existence of a directional memory in chemotactic cells-a biochemical pathway that stores information about cellular orientation and prevents the loss of orientation in the face of fluctuations, transient loss of polarization, or saturation of the receptors. For example, recent work has demonstrated memory-based behavior in Dictyostelium amoebae under fluctuating waves of chemoattractant (6, 7), although the authors do not identify potential molecular elements that store this information.Here, we use microchannel-based microfluidic devices to observe cell polarization and movement in confined mammalian neutrophil-like cells. Cells in this environment exhibit a strong bias to repolarize in the previous direction of motion after a period of depolarization. This memory is time-dependent and decays when the cell is unstimulated. To describe these results, we construct a minimal phenomenological model coupling membrane and cytoskeletal polarization lifetimes and show that thi...

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Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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confidence: 99%

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Directional memory arises from long-lived cytoskeletal asymmetries in polarized chemotactic cells

Prentice-Mott

Meroz

Carlson

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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“…Biological systems respond to average signal levels, as well as to gradients in chemical concentration 120,121 , material stiffness 122 and pressure 123 . The precise flow control in microfluidic devices forms rapid, stable, linear gradients (for more than 12 hours) 124 .…”

Section: Tailored Contextsmentioning

confidence: 99%

Microfluidics: reframing biological enquiry

Duncombe

Tentori

Herr

2015

Nat Rev Mol Cell Biol

292

202

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The underlying physical properties of microfluidic tools have led to new biological insights through the development of microsystems that can manipulate, mimic and measure biology at a resolution that has not been possible with macroscale tools. Microsystems readily handle sub-microlitre volumes, precisely route predictable laminar fluid flows and match both perturbations and measurements to the length scales and timescales of biological systems. The advent of fabrication techniques that do not require highly specialized engineering facilities is fuelling the broad dissemination of microfluidic systems and their adaptation to specific biological questions. We describe how our understanding of molecular and cell biology is being and will continue to be advanced by precision microfluidic approaches and posit that microfluidic tools — in conjunction with advanced imaging, bioinformatics and molecular biology approaches — will transform biology into a precision science.

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“…Laminar flow can be controlled to study cell-flow interaction. Hence, the use of a microfluidic chip with controllable laminar flows allows the study of cell aggregation, (37) cardiac tissue formation, (38) as well as differentiation. (39) Microfabrication techniques also allow the fabrication of porous membranes to mimic the vascular endothelium and parenchymal tissues by culturing two different kinds of cells on both sides of the porous PDMS substrate.…”

Section: Principles Of Microfabricationmentioning

confidence: 99%

Organ-on-a-Chip Platforms for Drug Delivery and Cell Characterization: A Review

2015

Sensors and Materials

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Biased migration of confined neutrophil-like cells in asymmetric hydraulic environments

Cited by 93 publications

References 28 publications

Directional memory arises from long-lived cytoskeletal asymmetries in polarized chemotactic cells

Directional memory arises from long-lived cytoskeletal asymmetries in polarized chemotactic cells

Microfluidics: reframing biological enquiry

Organ-on-a-Chip Platforms for Drug Delivery and Cell Characterization: A Review

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