Animal cells harbor three types of cytoskeletal elements: actin
filaments, intermediate filaments and microtubules. Despite their name,
cytoskeletons are very dynamic structures, which undergo rapid
reorganization in cells and thus contribute to numerous cellular
processes, such as morphogenesis, motility, intracellular transport, and
cell division. Consequently, defects in cytoskeletal structures lead to
various diseases, including cancer and neurological disorders.
Different cytoskeletal systems do not function in isolation, but
collaborate with each other in cells. Post-doctoral researcher Yaming
Jiu working at the Institute of Biotechnology, University of Helsinki
has now revealed that cytoplasmic intermediate filaments interact with
specific contractile actin filament structures called arcs.
"Actin arcs transport intermediate filaments from cell periphery toward the nucleus. Consequently, disruption of actin arcs led to an abnormal spreading of the intermediate filament network toward the cell periphery and associated defects in cell morphogenesis. Intermediate filaments resist the movement of arcs, and their depletion led to abnormalities in the shape of the arc-rich leading edge of motile cells," describes research director Pekka Lappalainen.
"Actin arcs transport intermediate filaments from cell periphery toward the nucleus. Consequently, disruption of actin arcs led to an abnormal spreading of the intermediate filament network toward the cell periphery and associated defects in cell morphogenesis. Intermediate filaments resist the movement of arcs, and their depletion led to abnormalities in the shape of the arc-rich leading edge of motile cells," describes research director Pekka Lappalainen.
This story is taken from Science Daily
No comments:
Post a Comment