T cells, neutrophils, and protista Dictyostelium undergo amoeboid durotaxis which involves soft end polarized NMIIA.

Ciliated zooplankton larvae sense pressure by ciliary photoreceptor cells, which increase the beating of locomotor cilia via a serotonergic motor circuit leading to rapid upward swimming during barotaxis.

Molecular and genetics approaches reveal a dual regulatory role of neuronal G-protein-coupled receptor NPR-15 in both immunity and avoidance behavior, independent of aerotaxis, mediated by amphid sensory neurons, ASJ.

Nuclear export inhibition reveals concurrent epithelial and mesenchymal phenotypes that cause mechanosensitive disorder in collectively migrating epithelia.

Horizontal cell undergoes amoeboid-like migration in the developing vertebrate retina, a not previously reported migration mode in the central nervous system, that allows them to move within a densely packed tissue without predetermined paths.

Coordinated actions of two opposite flagella control speed and change direction of plant pathogen Phytophthora zoospores, in which the anterior flagellum is the main motor to generate thrust and spontaneously switch from reciprocal beating to breaststrokes to reorient its body.

Collectively migrating cells control their stiffness by Fascin-dependent control of Myosin activity, and this migratory cell stiffness regulates Myosin activity and stiffness within the cellular substrate to ultimately promote migration.

Neutrophils use dorsal membrane protrusions of endothelial cells to cross the vascular wall.