TY  - JOUR
A1  - Moreno, Eduardo
A1  - Großmann, Robert
A1  - Beta, Carsten
A1  - Alonso, Sergio
T1  - From single to collective motion of social amoebae
BT  - a computational study of interacting cells
JF  - Frontiers in physics
N2  - The coupling of the internal mechanisms of cell polarization to cell shape deformations and subsequent cell crawling poses many interdisciplinary scientific challenges. Several mathematical approaches have been proposed to model the coupling of both processes, where one of the most successful methods relies on a phase field that encodes the morphology of the cell, together with the integration of partial differential equations that account for the polarization mechanism inside the cell domain as defined by the phase field. This approach has been previously employed to model the motion of single cells of the social amoeba Dictyostelium discoideum, a widely used model organism to study actin-driven motility and chemotaxis of eukaryotic cells. Besides single cell motility, Dictyostelium discoideum is also well-known for its collective behavior. Here, we extend the previously introduced model for single cell motility to describe the collective motion of large populations of interacting amoebae by including repulsive interactions between the cells. We performed numerical simulations of this model, first characterizing the motion of single cells in terms of their polarity and velocity vectors. We then systematically studied the collisions between two cells that provided the basic interaction scenarios also observed in larger ensembles of interacting amoebae. Finally, the relevance of the cell density was analyzed, revealing a systematic decrease of the motility with density, associated with the formation of transient cell clusters that emerge in this system even though our model does not include any attractive interactions between cells. This model is a prototypical active matter system for the investigation of the emergent collective dynamics of deformable, self-driven cells with a highly complex, nonlinear coupling of cell shape deformations, self-propulsion and repulsive cell-cell interactions. Understanding these self-organization processes of cells like their autonomous aggregation is of high relevance as collective amoeboid motility is part of wound healing, embryonic morphogenesis or pathological processes like the spreading of metastatic cancer cells.
KW  - cell motility
KW  - cell polarity
KW  - reaction-diffusion models
KW  - cell-cell
KW  - interactions
KW  - phase field model
KW  - collective motion
KW  - active matter
Y1  - 2022
U6  - https://doi.org/10.3389/fphy.2021.750187
SN  - 2296-424X
VL  - 9
PB  - Frontiers Media
CY  - Lausanne
ER  - 
TY  - JOUR
A1  - Lange, Dietrich
A1  - Tilmann, Frederik
A1  - Barrientos, Sergio E.
A1  - Contreras-Reyes, Eduardo
A1  - Methe, Pascal
A1  - Moreno, Marcos
A1  - Heit, Ben
A1  - Agurto, Hans
A1  - Bernard, Pascal
A1  - Vilotte, Jean-Pierre
A1  - Beck, Susan
T1  - Aftershock seismicity of the 27 February 2010 Mw 8.8 Maule earthquake rupture zone
JF  - Earth & planetary science letters
N2  - On 27 February 2010 the M-w 8.8 Maule earthquake in Central Chile ruptured a seismic gap where significant strain had accumulated since 1835. Shortly after the mainshock a dense network of temporary seismic stations was installed along the whole rupture zone in order to capture the aftershock activity. Here, we present the aftershock distribution and first motion polarity focal mechanisms based on automatic detection algorithms and picking engines. By processing the seismic data between 15 March and 30 September 2010 from stations from IRIS, IPGP, GFZ and University of Liverpool we determined 20,205 hypocentres with magnitudes M-w between 1 and 5.5. Seismic activity occurs in six groups: 1.) Normal faulting outer rise events 2.) A shallow group of plate interface seismicity apparent at 25-35 km depth and 50-120 km distance to the trench with some variations between profiles. Along strike, the aftershocks occur largely within the zone of coseismic slip but extend similar to 50 km further north, and with predominantly shallowly dipping thrust mechanisms. Along dip, the events are either within the zone of coseismic slip, or downdip from it, depending on the coseismic slip model used. 3.) A third band of seismicity is observed further downdip at 40-50 km depth and further inland at 150-160 km trench perpendicular distance, with mostly shallow dipping (similar to 28 degrees) thrust focal mechanisms indicating rupture of the plate interface significantly downdip of the coseismic rupture, and presumably above the intersection of the continental Moho with the plate interface. 4.) A deep group of intermediate depth events between 80 and 120 km depth is present north of 36 degrees S. Within the Maule segment, a large portion of events during the inter-seismic phase originated from this depth range. 5.) The magmatic arc exhibits a small amount of crustal seismicity but does not appear to show significantly enhanced activity after the M-w 8.8 Maule 2010 earthquake. 6.) Pronounced crustal aftershock activity with mainly normal faulting mechanisms is found in the region of Pichilemu (similar to 34.5 degrees S). These crustal events occur in a similar to 30 km wide region with sharp inclined boundaries and oriented oblique to the trench. The best-located events describe a plane dipping to the southwest, consistent with one of the focal planes of the large normal-faulting aftershock (M-w = 6.9) on 11 March 2010.
KW  - Maule 2010 earthquake
KW  - local seismicity
KW  - aftershock distribution
KW  - subduction zone
KW  - Central Chile
KW  - seismogenic zone
Y1  - 2012
U6  - https://doi.org/10.1016/j.epsl.2011.11.034
SN  - 0012-821X
VL  - 317
IS  - 2
SP  - 413
EP  - 425
PB  - Elsevier
CY  - Amsterdam
ER  - 
TY  - JOUR
A1  - Moldenhawer, Ted
A1  - Moreno, Eduardo
A1  - Schindler, Daniel
A1  - Flemming, Sven
A1  - Holschneider, Matthias
A1  - Huisinga, Wilhelm
A1  - Alonso, Sergio
A1  - Beta, Carsten
T1  - Spontaneous transitions between amoeboid and keratocyte-like modes of migration
JF  - Frontiers in Cell and Developmental Biology
N2  - The motility of adherent eukaryotic cells is driven by the dynamics of the actin cytoskeleton. Despite the common force-generating actin machinery, different cell types often show diverse modes of locomotion that differ in their shape dynamics, speed, and persistence of motion. Recently, experiments in Dictyostelium discoideum have revealed that different motility modes can be induced in this model organism, depending on genetic modifications, developmental conditions, and synthetic changes of intracellular signaling. Here, we report experimental evidence that in a mutated D. discoideum cell line with increased Ras activity, switches between two distinct migratory modes, the amoeboid and fan-shaped type of locomotion, can even spontaneously occur within the same cell. We observed and characterized repeated and reversible switchings between the two modes of locomotion, suggesting that they are distinct behavioral traits that coexist within the same cell. We adapted an established phenomenological motility model that combines a reaction-diffusion system for the intracellular dynamics with a dynamic phase field to account for our experimental findings.
KW  - cell migration
KW  - amoeboid motility
KW  - keratocytle-like motility
KW  - modes of
KW  - migration
KW  - D. discoideum
KW  - actin dynamics
Y1  - 2022
U6  - https://doi.org/10.3389/fcell.2022.898351
SN  - 2296-634X
VL  - 10
PB  - Frontiers Media
CY  - Lausanne
ER  -