Similarly, AC proteins, capping protein, and Arp2/3 are sufficient to recapitulate Listeria motility in vitro (Loisel et al., 1999). How do AC proteins
help to drive actin retrograde flow and organization? And how does this influence neurite formation (Figures 8F and 8G)? The location of actin polymerization is tightly regulated, occurring nearly exclusively at the leading edge of growth cones (Forscher and Smith, 1988), probably due to the linkage of actin nucleators to the membrane (Pak et al., 2008; Saarikangas et al., 2010). As they grow, actin filaments (Figure 8F, red) undergo molecular aging, so that the original ATP-actin (light red subunits) becomes ADP-actin (dark red subunits) over time and at locations distant from the www.selleckchem.com/products/MK-2206.html membrane. Since AC proteins (yellow spheres) bind preferentially to this older, ADP-actin portion of filaments, actin depolymerization, severing (Pac-Man), turnover and reorganization, is promoted away from the leading edge. Indeed, we found that active AC is positioned at the base of filopodia and lamellipodia, ideally poised for dismantling F-actin. In the absence of AC proteins, Epigenetics Compound Library nmr attenuated actin disassembly
may lead to the congestion of the intracellular space with actin filaments that reorient haphazardly in response to the pressure of polymerization. Hence, AC may regulate actin organization simply by virtue of its primary activity: increasing actin turnover. Consistent with this view, the reintroduction of Cofilin function restored retrograde flow and reorganized actin superstructures. Our data further show that actin retrograde flow is driven by Cofilin’s propensity for F-actin severing.
These data are consistent with current actin turnover modeling, which indicates that the most effective way to achieve accelerated actin retrograde flow would be to enhance actin deconstruction at the minus end of filaments (Roland et al., crotamiton 2008). Filopodia have recently been linked to neuritogenesis as they engorge with microtubules and elongate into nascent neurites (Dent et al., 2007). From this work and our own results, it is plausible that these radial actin bundles are the sites where microtubules can extend into the peripheral zone in the correct, radial orientation, which is necessary for the consolidation and advance of a nascent neurite (Figure 8F). AC knockout neurons displayed a marked decrease in radially oriented actin filaments in lamellipodia and filopodia while concomitantly exhibiting abnormal microtubule growth patterns and looping trajectories. Thus, the lack of this permissive actin platform for microtubules to grow along may underlie the failure of neuritogenesis in AC KO neurons. However, neuritogenesis is also attenuated in situations where filopodia appear normal, such as in ADF monoallele neurons and wild-type neurons treated with low levels of jasplakinolide. Thus, actin dynamics is also important for this process.