scholarly journals Growth cone behavior and production of traction force.

1990 ◽  
Vol 111 (5) ◽  
pp. 1949-1957 ◽  
Author(s):  
S R Heidemann ◽  
P Lamoureux ◽  
R E Buxbaum
Keyword(s):  
Growth Cone ◽  
Contractile Activity ◽  
Glass Fibers ◽  
Force Production ◽  
Traction Force ◽  
Dorsal Surface ◽  
Growth Cones ◽  
Retrograde Flow ◽  
Cortical Actin ◽  
Over The Top

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.

scholarly journals Stress fibers are embedded in a contractile cortical network

2020 ◽  
Author(s):  
Timothée Vignaud ◽  
Calina Copos ◽  
Christophe Leterrier ◽  
Qingzong Tseng ◽  
Laurent Blanchoin ◽  
...  
Keyword(s):  
Cell Fate ◽  
Actin Filaments ◽  
Mechanical Response ◽  
Force Production ◽  
Traction Force ◽  
Cortical Network ◽  
Cortical Actin ◽  
Cell Fate Decisions ◽  
Production And Distribution ◽  
Intracellular Forces

ABSTRACTContractile actomyosin networks generate intracellular forces essential for the regulation of cell shape, migration, and cell-fate decisions, ultimately leading to the remodeling and patterning of tissues. Although actin filaments aligned in bundles represent the main source of traction-force production in adherent cells, there is increasing evidence that these bundles form interconnected and interconvertible structures with the rest of the intracellular actin network. In this study, we explored how these bundles are connected to the surrounding cortical network and the mechanical impact of these interconnected structures on the production and distribution of traction forces on the extracellular matrix and throughout the cell. By using a combination of hydrogel micropatterning, traction-force microscopy and laser photoablation, we measured the relaxation of the cellular traction field in response to local photoablations at various positions within the cell. Our experimental results and modeling of the mechanical response of the network revealed that bundles were fully embedded along their entire length in a continuous and contractile network of cortical filaments. Moreover, the propagation of the contraction of these bundles throughout the entire cell was dependent on this embedding. In addition, these bundles appeared to originate from the alignment and coalescence of thin and unattached cortical actin filaments from the surrounding mesh.

scholarly journals Regulated Actin Cytoskeleton Assembly at Filopodium Tips Controls Their Extension and Retraction

1999 ◽  
Vol 146 (5) ◽  
pp. 1097-1106 ◽  
Author(s):  
Aneil Mallavarapu ◽  
Tim Mitchison
Keyword(s):  
Actin Cytoskeleton ◽  
Growth Cone ◽  
Actin Filaments ◽  
Neuroblastoma Cell ◽  
Initial Step ◽  
Growth Cones ◽  
Neuroblastoma Cell Line ◽  
Dominant Factor ◽  
Retrograde Flow ◽  
Assembly Rate

The extension and retraction of filopodia in response to extracellular cues is thought to be an important initial step that determines the direction of growth cone advance. We sought to understand how the dynamic behavior of the actin cytoskeleton is regulated to produce extension or retraction. By observing the movement of fiduciary marks on actin filaments in growth cones of a neuroblastoma cell line, we found that filopodium extension and retraction are governed by a balance between the rate of actin cytoskeleton assembly at the tip and retrograde flow. Both assembly and flow rate can vary with time in a single filopodium and between filopodia in a single growth cone. Regulation of assembly rate is the dominant factor in controlling filopodia behavior in our system.

scholarly journals L1-dependent neuritogenesis involves ankyrinB that mediates L1-CAM coupling with retrograde actin flow

2003 ◽  
Vol 163 (5) ◽  
pp. 1077-1088 ◽  
Author(s):  
Kazunari Nishimura ◽  
Fumie Yoshihara ◽  
Takuro Tojima ◽  
Noriko Ooashi ◽  
Woohyun Yoon ◽  
...  
Keyword(s):  
Cell Adhesion Molecule ◽  
Traction Force ◽  
Neurite Growth ◽  
Growth Cones ◽  
Retrograde Flow ◽  
Actin Network ◽  
Filamentous Actin ◽  
Neurite Elongation ◽  
Neurite Initiation ◽  
Cell Adhesion Molecule L1

The cell adhesion molecule L1 (L1-CAM) plays critical roles in neurite growth. Its cytoplasmic domain (L1CD) binds to ankyrins that associate with the spectrin–actin network. This paper demonstrates that L1-CAM interactions with ankyrinB (but not with ankyrinG) are involved in the initial formation of neurites. In the membranous protrusions surrounding the soma before neuritogenesis, filamentous actin (F-actin) and ankyrinB continuously move toward the soma (retrograde flow). Bead-tracking experiments show that ankyrinB mediates L1-CAM coupling with retrograde F-actin flow in these perisomatic structures. Ligation of the L1-CAM ectodomain by an immobile substrate induces L1CD–ankyrinB binding and the formation of stationary ankyrinB clusters. Neurite initiation preferentially occurs at the site of these clusters. In contrast, ankyrinB is involved neither in L1-CAM coupling with F-actin flow in growth cones nor in L1-based neurite elongation. Our results indicate that ankyrinB promotes neurite initiation by acting as a component of the clutch module that transmits traction force generated by F-actin flow to the extracellular substrate via L1-CAM.

Subcellular localization of myosin V in nerve growth cones and outgrowth from dilute-lethal neurons

1997 ◽  
Vol 110 (4) ◽  
pp. 439-449 ◽  
Author(s):  
L.L. Evans ◽  
J. Hammer ◽  
P.C. Bridgman
Keyword(s):  
Growth Cone ◽  
Actin Filaments ◽  
Traction Force ◽  
Growth Cones ◽  
Neuronal Function ◽  
Neuronal Structure ◽  
Myosin V ◽  
Cytoskeletal Organization ◽  
Cervical Ganglion ◽  
Nerve Growth Cones

Myosin V-null mice (dilute-lethal mutants) exhibit apparent neurological defects that worsen from birth until death in the third postnatal week. Although myosin V is enriched in brain, the neuronal function of myosin V is unclear and the underlying cause of the neurological defects in these mice is unknown. To aide in understanding myosin V function, we examined the distribution of myosin V in the rodent superior cervical ganglion (SCG) growth cone, a well characterized neuronal structure in which myosin V is concentrated. Using affinity purified, myosin V-specific antibodies in immunofluorescence and immunoelectron microscopy, we observed that myosin V is concentrated in organelle-rich regions of the growth cone. Myosin V is present on a distinct population of small (50–100 nm) organelles, and on actin filaments and the plasma membrane. Myosin V-associated organelles are present on both microtubules and actin filaments. These results indicate that myosin V may be carried as a passenger on organelles that are transported along microtubules, and that these organelles may also be capable of movement along actin filaments. In addition, we found no abnormalities in outgrowth, morphology, or cytoskeletal organization of SCG growth cones from dilute-lethal mice. These results indicate that myosin V is not necessary for the traction force needed for growth cone locomotion, for organization of the actin cytoskeleton, or for filopodial dynamics.

scholarly journals Local Arp2/3-dependent actin assembly modulates applied traction force during apCAM adhesion site maturation

2017 ◽  
Vol 28 (1) ◽  
pp. 98-110 ◽  
Author(s):  
Kenneth B. Buck ◽  
Andrew W. Schaefer ◽  
Vincent T. Schoonderwoert ◽  
Matthew S. Creamer ◽  
Eric R. Dufresne ◽  
...  
Keyword(s):  
Growth Cone ◽  
Network Flow ◽  
Traction Force ◽  
Axon Growth ◽  
Immunoglobulin Superfamily ◽  
Retrograde Flow ◽  
Actin Assembly ◽  
Growth Responses ◽  
Mechanical Restraint ◽  
Adhesion Sites

Homophilic binding of immunoglobulin superfamily molecules such as the Aplysia cell adhesion molecule (apCAM) leads to actin filament assembly near nascent adhesion sites. Such actin assembly can generate significant localized forces that have not been characterized in the larger context of axon growth and guidance. We used apCAM-coated bead substrates applied to the surface of neuronal growth cones to characterize the development of forces evoked by varying stiffness of mechanical restraint. Unrestrained bead propulsion matched or exceeded rates of retrograde network flow and was dependent on Arp2/3 complex activity. Analysis of growth cone forces applied to beads at low stiffness of restraint revealed switching between two states: frictional coupling to retrograde flow and Arp2/3-dependent propulsion. Stiff mechanical restraint led to formation of an extensive actin cup matching the geometric profile of the bead target and forward growth cone translocation; pharmacological inhibition of the Arp2/3 complex or Rac attenuated F-actin assembly near bead binding sites, decreased the efficacy of growth responses, and blocked accumulation of signaling molecules associated with nascent adhesions. These studies introduce a new model for regulation of traction force in which local actin assembly forces buffer nascent adhesion sites from the mechanical effects of retrograde flow.

scholarly journals Xenopus cytoplasmic linker–associated protein 1 (XCLASP1) promotes axon elongation and advance of pioneer microtubules

2013 ◽  
Vol 24 (10) ◽  
pp. 1544-1558 ◽  
Author(s):  
Astrid Marx ◽  
William J. Godinez ◽  
Vasil Tsimashchuk ◽  
Peter Bankhead ◽  
Karl Rohr ◽  
...  
Keyword(s):  
Growth Cone ◽  
Binding Protein ◽  
Leading Edge ◽  
Growth Cones ◽  
Retrograde Flow ◽  
Spinal Cord Neurons ◽  
Actin Organization ◽  
Axon Elongation ◽  
Axon Extension ◽  
Potential Link

Dynamic microtubules (MTs) are required for neuronal guidance, in which axons extend directionally toward their target tissues. We found that depletion of the MT-binding protein Xenopus cytoplasmic linker–associated protein 1 (XCLASP1) or treatment with the MT drug Taxol reduced axon outgrowth in spinal cord neurons. To quantify the dynamic distribution of MTs in axons, we developed an automated algorithm to detect and track MT plus ends that have been fluorescently labeled by end-binding protein 3 (EB3). XCLASP1 depletion reduced MT advance rates in neuronal growth cones, very much like treatment with Taxol, demonstrating a potential link between MT dynamics in the growth cone and axon extension. Automatic tracking of EB3 comets in different compartments revealed that MTs increasingly slowed as they passed from the axon shaft into the growth cone and filopodia. We used speckle microscopy to demonstrate that MTs experience retrograde flow at the leading edge. Microtubule advance in growth cone and filopodia was strongly reduced in XCLASP1-depleted axons as compared with control axons, but actin retrograde flow remained unchanged. Instead, we found that XCLASP1-depleted growth cones lacked lamellipodial actin organization characteristic of protrusion. Lamellipodial architecture depended on XCLASP1 and its capacity to associate with MTs, highlighting the importance of XCLASP1 in actin–microtubule interactions.

scholarly journals Role of Myosin II in Axon Outgrowth

2003 ◽  
Vol 51 (4) ◽  
pp. 421-428 ◽  
Author(s):  
Jacquelyn Brown ◽  
Paul C. Bridgman
Keyword(s):  
Extracellular Matrix ◽  
Cell Adhesion ◽  
Myosin Ii ◽  
Traction Force ◽  
Growth Cones ◽  
Matrix Proteins ◽  
Retrograde Flow ◽  
Complex Interactions ◽  
Cell Adhesion Proteins

The initial stages of nerve outgrowth carried out by growth cones occur in three fundamental cyclic steps. Each of these steps appears to require myosin II activity to variable degrees. The steps include the following: (a) exploration, involving extensions and retractions that are driven and controlled by the interaction of actin retrograde flow and polymerization; (b) adhesion of new extensions to the substrate, which has been shown to be mediated by complex interactions between extracellular matrix proteins, cell adhesion proteins, and the actin cytoskeleton; and (c) traction force generated during forward advance of the growth cone, resulting in the production of tension on the neurite.

scholarly journals Fmn2 regulates growth cone motility by mediating a molecular clutch to generate traction forces

2020 ◽  
Author(s):  
Ketakee Ghate ◽  
Sampada P. Mutalik ◽  
Lakshmi Kavitha Sthanam ◽  
Shamik Sen ◽  
Aurnab Ghose
Keyword(s):  
Growth Cone ◽  
Molecular Mechanisms ◽  
Point Contact ◽  
Traction Force ◽  
Growth Cones ◽  
Traction Forces ◽  
Growth Environment ◽  
Synaptic Targeting ◽  
Contact Stability ◽  
Extracellular Matrix Interactions

ABSTRACTGrowth cone - mediated axonal outgrowth and accurate synaptic targeting are central to brain morphogenesis. Translocation of the growth cone necessitates mechanochemical regulation of cell - extracellular matrix interactions and the generation of propulsive traction forces onto the growth environment. However, the molecular mechanisms subserving force generation by growth cones remain poorly characterized. The formin family member, Fmn2, has been identified earlier as a regulator of growth cone motility. Here, we explore the mechanisms underlying Fmn2 function in the growth cone. Evaluation of multiple components of the adhesion complexes suggests that Fmn2 regulates point contact stability. Analysis of F-actin retrograde flow reveals that Fmn2 functions as a clutch molecule and mediates the coupling of the actin cytoskeleton to the growth substrate, via point contact adhesion complexes. Using traction force microscopy, we show that the Fmn2-mediated clutch function is necessary for the generation of traction stresses by neurons. Our findings suggest that Fmn2, a protein associated with neurodevelopmental and neurodegenerative disorders, is a key regulator of a molecular clutch activity and consequently motility of neuronal growth cones.

scholarly journals Slipping or Gripping? Fluorescent Speckle Microscopy in Fish Keratocytes Reveals Two Different Mechanisms for Generating a Retrograde Flow of Actin

2005 ◽  
Vol 16 (2) ◽  
pp. 507-518 ◽  
Author(s):  
Carlos Jurado ◽  
John R. Haserick ◽  
Juliet Lee
Keyword(s):  
Flow Rate ◽  
Potent Inhibitor ◽  
Myosin Ii ◽  
Force Production ◽  
Traction Force ◽  
The Other ◽  
Force Generation ◽  
Retrograde Flow ◽  
Transfected Cells ◽  
The Relationship

Fish keratocytes can generate rearward directed traction forces within front portions of the lamellipodium, suggesting that a retrograde flow of actin may also occur here but this was not detected by previous photoactivation experiments. To investigate the relationship between retrograde flow and traction force generation, we have transfected keratocytes with GFP-actin and used fluorescent speckle microscopy, to observe speckle flow. We detected a retrograde flow of actin within the leading lamellipodium that is inversely proportional to both protrusion rate and cell speed. To observe the effect of reducing contractility, we treated transfected cells with ML7, a potent inhibitor of myosin II. Surprisingly, ML7 treatment led to an increase in retrograde flow rate, together with a decrease in protrusion and cell speed, but only in rapidly moving cells. In slower moving cells, retrograde flow decreased, whereas protrusion rate and cell speed increased. These results suggest that there are two mechanisms for producing retrograde flow. One involves slippage between the cytoskeleton and adhesions, that decreases traction force production. The other involves slippage between adhesions and the substratum, which increases traction force production. We conclude that a biphasic relationship exists between retrograde actin flow and adhesiveness in moving keratocytes.

scholarly journals Dissipation of contractile forces: the missing piece in cell mechanics

2017 ◽  
Vol 28 (14) ◽  
pp. 1825-1832 ◽  
Author(s):  
Laetitia Kurzawa ◽  
Benoit Vianay ◽  
Fabrice Senger ◽  
Timothée Vignaud ◽  
Laurent Blanchoin ◽  
...  
Keyword(s):  
Cell Mechanics ◽  
Force Production ◽  
Traction Force ◽  
Structural Rearrangements ◽  
Force Transmission ◽  
Traction Forces ◽  
Cell Traction Forces ◽  
Cell Traction ◽  
Contractile Forces ◽  
Fiber Contraction

Mechanical forces are key regulators of cell and tissue physiology. The basic molecular mechanism of fiber contraction by the sliding of actin filament upon myosin leading to conformational change has been known for decades. The regulation of force generation at the level of the cell, however, is still far from elucidated. Indeed, the magnitude of cell traction forces on the underlying extracellular matrix in culture is almost impossible to predict or experimentally control. The considerable variability in measurements of cell-traction forces indicates that they may not be the optimal readout to properly characterize cell contractile state and that a significant part of the contractile energy is not transferred to cell anchorage but instead is involved in actin network dynamics. Here we discuss the experimental, numerical, and biological parameters that may be responsible for the variability in traction force production. We argue that limiting these sources of variability and investigating the dissipation of mechanical work that occurs with structural rearrangements and the disengagement of force transmission is key for further understanding of cell mechanics.

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