The growth cone must push its substrate rearward via some traction force in order to propel itself forward. To determine which growth cone behaviors produce traction force, we observed chick sensory growth cones under conditions in which force production was accommodated by movement of obstacles in the environment, namely, neurites of other sensory neurons or glass fibers. The movements of these obstacles occurred via three, different, stereotyped growth cone behaviors: (a) filopodial contractions, (b) smooth rearward movement on the dorsal surface of the growth cone, and (c) interactions with ruffling lamellipodia. More than 70% of the obstacle movements were caused by filopodial contractions in which the obstacle attached at the extreme distal end of a filopodium and moved only as the filopodium changed its extension. Filopodial contractions were characterized by frequent changes of obstacle velocity and direction. Contraction of a single filopodium is estimated to exert 50-90 microdyn of force, which can account for the pull exerted by chick sensory growth cones. Importantly, all five cases of growth cones growing over the top of obstacle neurites (i.e., geometry that mimics the usual growth cone/substrate interaction), were of the filopodial contraction type. Some 25% of obstacle movements occurred by a smooth backward movement along the top surface of growth cones. Both the appearance and rate of movements were similar to that reported for retrograde flow of cortical actin near the dorsal growth cone surface. Although these retrograde flow movements also exerted enough force to account for growth cone pulling, we did not observe such movements on ventral growth cone surfaces. Occasionally obstacles were moved by interaction with ruffling lamellipodia. However, we obtained no evidence for attachment of the obstacles to ruffling lamellipodia or for directed obstacle movements by this mechanism. These data suggest that chick sensory growth cones move forward by contractile activity of filopodia, i.e., isometric contraction on a rigid substrate. Our data argue against retrograde flow of actin producing traction force.
Skip Nav Destination
Article navigation
1 November 1990
Article|
November 01 1990
Growth cone behavior and production of traction force.
S R Heidemann,
S R Heidemann
Department of Physiology, Michigan State University, East Lansing 48824-1101.
Search for other works by this author on:
P Lamoureux,
P Lamoureux
Department of Physiology, Michigan State University, East Lansing 48824-1101.
Search for other works by this author on:
R E Buxbaum
R E Buxbaum
Department of Physiology, Michigan State University, East Lansing 48824-1101.
Search for other works by this author on:
S R Heidemann
Department of Physiology, Michigan State University, East Lansing 48824-1101.
P Lamoureux
Department of Physiology, Michigan State University, East Lansing 48824-1101.
R E Buxbaum
Department of Physiology, Michigan State University, East Lansing 48824-1101.
Online ISSN: 1540-8140
Print ISSN: 0021-9525
J Cell Biol (1990) 111 (5): 1949–1957.
Citation
S R Heidemann, P Lamoureux, R E Buxbaum; Growth cone behavior and production of traction force.. J Cell Biol 1 November 1990; 111 (5): 1949–1957. doi: https://doi.org/10.1083/jcb.111.5.1949
Download citation file:
Sign in
Don't already have an account? Register
Client Account
You could not be signed in. Please check your email address / username and password and try again.
Could not validate captcha. Please try again.
Sign in via your Institution
Sign in via your InstitutionEmail alerts
Advertisement
Advertisement