%A Kalil,Katherine %A Li,Li %A Hutchins,B.Ian %D 2011 %J Frontiers in Neuroanatomy %C %F %G English %K Axon branching,axon guidance,Axon outgrowth,Calcium Signaling,CaMKII,Corpus Callosum,Microtubules,Wnt5a %Q %R 10.3389/fnana.2011.00062 %W %L %M %P %7 %8 2011-September-28 %9 Review %+ Prof Katherine Kalil,University of Wisconsin-Madison,Neuroscience Training Program,Madison,WI,United States,kakalil@wisc.edu %+ Prof Katherine Kalil,University of Wisconsin-Madison,Department of Neuroscience,1300 University Avenue,Madison,53706,WI,United States,kakalil@wisc.edu %# %! Cortical axon outgrowth, guidance and branching %* %< %T Signaling Mechanisms in Cortical Axon Growth, Guidance, and Branching %U https://www.frontiersin.org/articles/10.3389/fnana.2011.00062 %V 5 %0 JOURNAL ARTICLE %@ 1662-5129 %X Precise wiring of cortical circuits during development depends upon axon extension, guidance, and branching to appropriate targets. Motile growth cones at axon tips navigate through the nervous system by responding to molecular cues, which modulate signaling pathways within axonal growth cones. Intracellular calcium signaling has emerged as a major transducer of guidance cues but exactly how calcium signaling pathways modify the actin and microtubule cytoskeleton to evoke growth cone behaviors and axon branching is still mysterious. Axons must often pause their extension in tracts while their branches extend into targets. Some evidence suggests a competition between growth of axons and branches but the mechanisms are poorly understood. Since it is difficult to study growing axons deep within the mammalian brain, much of what we know about signaling pathways and cytoskeletal dynamics of growth cones comes from tissue culture studies, in many cases, of non-mammalian species. Consequently it is not well understood how guidance cues relevant to mammalian neural development in vivo signal to the growth cone cytoskeleton during axon outgrowth and guidance. In this review we describe our recent work in dissociated cultures of developing rodent sensorimotor cortex in the context of the current literature on molecular guidance cues, calcium signaling pathways, and cytoskeletal dynamics that regulate growth cone behaviors. A major challenge is to relate findings in tissue culture to mechanisms of cortical development in vivo. Toward this goal, we describe our recent work in cortical slices, which preserve the complex cellular and molecular environment of the mammalian brain but allow direct visualization of growth cone behaviors and calcium signaling. Findings from this work suggest that mechanisms regulating axon growth and guidance in dissociated culture neurons also underlie development of cortical connectivity in vivo.