Migration of dendritic cells within 3-D collagen lattices is dependent on tissue origin, state of maturation, and matrix structure and is maintained by proinflammatory cytokines.

The function of dendritic cells (DC) depends on active migration through three-dimensional (3-D) extracellular matrices. We have analyzed the migration of murine DC from different tissue origins within 3-D collagen lattices through the use of time-lapse videomicroscopy and single-cell tracking. Directly after incorporation, 50-90% of DC from the spleen (spDC) and Langerhans cells freshly isolated from the epidermis (fLC) displayed active motility in these matrices. Whereas mature spDC showed multilateral pseudopod dynamics as well as fast and heterogeneous migration, immature fLC displayed a spherical shape with faint membrane processes and very homogenous, slow migration characteristics. In the absence of external stimuli, migration of both, spDC and fLC, vanished after >36 h due to cell death. Maintaining fLC viability by external granulocyte-macrophage colony-stimulating factor or tumor necrosis factor alpha prolonged migration up to 5 days. During this period fLC transformed into mature cells with large dendrites, thereby developing a heterogeneous migration pattern more similar to spDC. In randomly polymerized collagen matrices cell paths were without preferential orientation. In contrast, in artificially aligned lattices directional paths in accordance with the forced fiber orientation were observed. Thus, migration is an inherent property of DC, largely influenced by tissue origin, degree of maturity, and the 3-D structure of the environment.