TY - JOUR
T1 - Structurally distinct membrane nanotubes between human macrophages support long-distance vesicular traffic or surfing of bacteria
AU - Önfelt, Björn
AU - Nedvetzki, Shlomo
AU - Benninger, Richard K P
AU - Purbhoo, Marco A.
AU - Sowinski, Stefanie
AU - Hume, Alistair N.
AU - Seabra, Miguel C.
AU - Neil, Mark A A
AU - French, Paul M W
AU - Davis, Daniel M.
N1 - , Wellcome Trust, United Kingdom
PY - 2006/12/15
Y1 - 2006/12/15
N2 - We report that two classes of membrane nanotubes between human monocyte-derived macrophages can be distinguished by their cytoskeletal structure and their functional properties. Thin membrane nanotubes contained only F-actin, whereas thicker nanotubes, i.e., those > ∼0.7 μm in diameter, contained both F-actin and microtabules. Bacteria could be trapped and surf along thin, but not thick, membrane nanotubes toward connected macrophage cell bodies. Once at the cell body, bacteria could then be phagocytosed. The movement of bacteria is aided by a constitutive low of the nanotube surface because streptavidin-coated beads were similarly able to trafic along nanotubes between surface-biotinylated macrophages. Mitochondria and intracellular vesicles, including late endosomes and lysosomes, could be detected within thick, but not thin, membrane nanotubes. Analysis from kymographs demonstrated that vesicles moved in a stepwise, bidirectional manner at ∼1 μm/s, consistent with their traffic being mediated by the microtabules found only in thick nanotubes. Vesicular traffic in thick nanotubes and surfing of beads along thin nanotubes were both stopped upon the addition of azide, demonstrating that both processes require ATP. However, microtubule destabilizing agents colchicine or nocodazole abrogated vesicular transport but not the flow of the nanotube surface, confirming that distinct cytoskeletal structures of nanotubes give rise to different functional properties. Thus, membrane nanotubes between macrophages are more complex than unvarying ubiquitous membrane tethers and facilitate several means for distal interactions between immune cells. Copyright © 2006 by The American Association of Immunologists, Inc.
AB - We report that two classes of membrane nanotubes between human monocyte-derived macrophages can be distinguished by their cytoskeletal structure and their functional properties. Thin membrane nanotubes contained only F-actin, whereas thicker nanotubes, i.e., those > ∼0.7 μm in diameter, contained both F-actin and microtabules. Bacteria could be trapped and surf along thin, but not thick, membrane nanotubes toward connected macrophage cell bodies. Once at the cell body, bacteria could then be phagocytosed. The movement of bacteria is aided by a constitutive low of the nanotube surface because streptavidin-coated beads were similarly able to trafic along nanotubes between surface-biotinylated macrophages. Mitochondria and intracellular vesicles, including late endosomes and lysosomes, could be detected within thick, but not thin, membrane nanotubes. Analysis from kymographs demonstrated that vesicles moved in a stepwise, bidirectional manner at ∼1 μm/s, consistent with their traffic being mediated by the microtabules found only in thick nanotubes. Vesicular traffic in thick nanotubes and surfing of beads along thin nanotubes were both stopped upon the addition of azide, demonstrating that both processes require ATP. However, microtubule destabilizing agents colchicine or nocodazole abrogated vesicular transport but not the flow of the nanotube surface, confirming that distinct cytoskeletal structures of nanotubes give rise to different functional properties. Thus, membrane nanotubes between macrophages are more complex than unvarying ubiquitous membrane tethers and facilitate several means for distal interactions between immune cells. Copyright © 2006 by The American Association of Immunologists, Inc.
M3 - Article
C2 - 17142745
SN - 1550-6606
VL - 177
SP - 8476
EP - 8483
JO - Journal of Immunology
JF - Journal of Immunology
IS - 12
ER -