Kerstein PC , Patel KM , Gomez TM .

F31 NS074732 NINDS NIH HHS , R01 NS099405 NINDS NIH HHS , R21 NS088477 NINDS NIH HHS , T32 GM007507 NIGMS NIH HHS , R56 NS041564 NINDS NIH HHS

	Figure 1. Talin and FAK are cleaved by calpain within the embryonic spinal cord. a, RT-PCR amplification of mRNA transcripts of calpain1 (262 bp), calpain2 (262 bp), calpainSS1 (299 bp), and βII tubulin (251 bp) from stage 22 Xenopus spinal cords. b, c, Schematic domain organization of talin (b) and FAK (c) showing approximate location of protein interaction motifs and calpain cleavage sites. Below are human and Xenopus protein sequences of the calpain cleavage sites, which are highly conserved between species. d, Immunoblots for talin from Xenopus neural tube lysates incubated in control media or media containing a calpain protease inhibitor (1 μm CPI) for 30 min. The full-length talin band is at 230 kDa (arrow), and the cleaved talin is at 190 kDa (arrowhead). An additional calpain-dependent fragment (Vinculin-Actin-Dimerization domain fragment) was found at 120 kDa (not quantified). Note that all bands appear as doublets since the antibody recognizes both talin isoforms. The average talin cleavage in control and CPI (right) was quantified from the large isoform band intensities (190 kDa band/230 kDa) from multiple blots (n = 7). e, Immunoblots for FAK from Xenopus neural tube lysates incubated in control media or media containing a calpain protease inhibitor (1 μm CPI) for 30 min. The full-length FAK band is at 116 kDa (arrow), and cleaved FAK is at 80 kDa (arrowhead). The average FAK cleavage in control and CPI (right) was quantified (80 kDa band/116 kDa) from multiple blots (n = 6). *p < 0.05, Mann–Whitney U test.
	Figure 2. Calpain activity regulates adhesion protein localization and signaling in filopodia. a–i, Immunocytochemistry experiments were performed with cultured Xenopus spinal neurons plated on laminin. The fluorescence intensity within filopodia was quantified in the following three conditions: control, with 1 μm CPI (calpain inhibition), or without AGAs (−AGAs, calpain activation). a–i, Representative images of growth cones (left) and filopodia (right) shown for selected adhesion proteins, as follows: talin (a–c), phospho-tyrosine 397 FAK (FAK Y397; b–h), and phospho-tyrosine 118 paxillin (PXN Y118; c–i). Immunolabeled adhesion proteins are in green, and phallodin-labeled F-actin is in red. Arrows indicate localization to filopodial tips. j, Quantification of filopodial fluorescence intensity of all adhesion markers tested, including vinculin and total phospho-tyrosine (pY99), with inhibition of calpain or Ca2+-dependent activation of calpain by removal of AGAs. k, Quantification of filopodial fluorescence intensity of talin, FAK Y397, and PXN Y118 in growth cones expressing GFP-tagged dominant-negative calpain1 (H272A) normalized to cocultured wild-type neurons. Scale bar, 5 μm. n > 60 growth cones and n > 3 cultures for all conditions. *p < 0.05, Mann–Whitney U test.
	Figure 3. Calpain activity regulates adhesion dynamics in filopodia. a, c, Inverted contrast TIRF images of growth cones expressing paxillin-GFP displayed at 1 min intervals, over 10 min before (a) and after (c) the addition of CPI (calpain inhibition). b, d, Adhesion lifetime heat maps showing adhesion dynamics from the time points in a and c, respectively. The inset pie charts demonstrate the proportion adhesions with the lifetime 0–1 min (blue), 1–2 min (green), and 2–3 min (red). Note that the inhibition of calpain reduces the number of stable adhesions (arrows) and increases the number new adhesions (arrowheads). e, g, Inverted contrast TIRF images of growth cones expressing paxillin-GFP displayed at 1 min intervals (e) before and (g) after the removal of AGAs (calpain activation). f, h, Adhesion lifetime heat maps showing adhesion dynamics from the time points in e and g, respectively. Note that Ca2+-dependent activation of calpain reduces the formation of new adhesions (arrowheads) and stabilizes existing adhesions (arrows). i, j, Quantification of adhesion assembly (i) and duration (j) for calpain inhibition (+CPI), activation (−AGAs), or the combined removal of AGAs with the addition of CPI. Scale bar, 5 μm. n > 100 adhesions and n > 12 growth cones for each condition. *p < 0.05, Mann–Whitney U test.
	Figure 4. Calpain regulates adhesion dynamics through the cleavage of talin and FAK. a–h, Inverted contrast TIRF images of growth cones expressing paxillin-GFP or paxillin-tdTomato displayed every 1 min over a 3 min period in wild-type- (a, b), dominant-negative calpain1 (H272A; c, d), calpain-resistant talin- (L432G; e, f), or calpain-resistant FAK (V744G; g, h)-expressing neurons. Arrowheads denote new adhesions formed. b, d, f, h, Adhesion lifetime heat maps exhibit adhesion dynamics from the corresponding time points. Arrows represent the stable adhesions that have a lifetime between 2 and 3 min. The inset pie charts demonstrate the proportion of adhesions with lifetimes of 0–1 min (blue), 1–2 min (green), and 2–3 min (red). i, j, Quantification of adhesion formation (i) and duration (j) for wild-type-, capn1–H272A-, talin-WT-, talin-L432G-, FAK-WT-, and FAK-V744G-expressing growth cones. Statistical comparisons were made between wild-type- and capn1-H272A-, talin-WT- and talin-L432G-, and FAK-WT- and FAK-V744G-expressing growth cones. Scale bar, 5 μm. n > 100 adhesions and n > 11 growth cones for each condition. *p < 0.05, Mann–Whitney U test or Student's t test.
	Figure 5. The effects of filopodial Ca2+ transients on adhesion dynamics are blocked by inhibition of calpain activity and cleavage of talin and FAK. a, b, Change in growth cone adhesion assembly rate (a) and adhesion duration (b) after disinhibition of filopodial Ca2+ transients by removing AGAs in wild-type-, capn1-H272A-, talin-WT-, talin-L432G-, FAK-WT-, and FAK-V744G-expressing growth cones in vitro. Paired measurements were made from the same growth cones before and after the removal of AGAs, and data were normalized to the rate of adhesion assembly and duration in normal culture conditions. Statistical comparisons were made within the same growth cones before and after the removal of AGAs within each group. For each group, n > 110 individual adhesions and n > 10 growth cones. *p < 0.05, Mann–Whitney U test or Student's t test.
	Figure 6. Stimulation of filopodial Ca2+ transients causes repulsive turning through calpain-mediated cleavage of talin and FAK. a, a′, Two time-point images of a GFP-expressing growth cone loaded with NP-EGTA undergoing repulsive turning from an area exposed to pulsed UV light (dashed circle) at 10 s intervals. b–d, Two time-point images of growth cones loaded with NP-EGTA and expressing GFP-capn1-H272A (b), GFP-talin-L432G (c), or GFP-FAK-V744G (d) show no repulsive turning to pulsed UV light after 45 min of outgrowth. e, Cumulative distribution of all axon turning angles for control (no NP-EGTA, gray), NP-EGTA loaded wild-type-, capn1-H272A-, talin-L432G-, or FAK-V744G-expressing growth cones. The vertical dashed line represents the mean turning angle for the control growth cones. f, g, The mean turning angle (f) and the mean rate of outgrowth (g) for each condition. Scale bar, 5 μm. n > 10 growth cones for each condition. *p < 0.05, Kruskal–Wallis with Dunn's multiple-comparison test.
	Figure 7. Inhibition of calpain activity promotes RB peripheral axon outgrowth in situ. Open-book skin preparations were used to measure axon outgrowth in situ. a, b, GFP, GFP-capn1-H272A, GFP-FAK-V744G, or GFP-talin-L432G was injected in a single dark blastomere at the eight-cell stage (a) driving expression into one side of the dorsal spinal cord (b). NT, neural tube; NC, notochord. c–g, The skin of 26 hpf embryos was removed, and preparations were labeled with NCAM to observe RB peripheral projections in the skin and flat mounted for confocal imaging. c–g, Representative images of HNK-1 labeling in skin expressing GFP (c), GFP-capn1-H272A (d), GFP-talin-L432G (e), GFP-FAK-V744G (f), or coexpressing GFP-talin-L432G and TagRFP-FAK-V744G (only GFP shown; g). Dashed line represents the dorsal midline. h, Quantification of the maximum axon displacement per 100 μm spinal cord segment on the injected side vs control side for each condition. i, Branching was quantified as the number of axon terminals (growth cones) per 100 μm segment of spinal cord. Scale bar, 50 μm. n > 100 segments and n > 10 embryos for all conditions. *p < 0.05, Mann–Whitney U test.
	Figure 8. Ca2+/calpain regulation of adhesion dynamics and growth cone motility. Growth cones exhibit repulsive turning from local Ca2+ elevations in filopodia. Under basal conditions in our experiments, talin and FAK promote integrin-based adhesion formation, while FAK promotes the disassembly of adhesions to maintain consistent adhesion turnover. Local Ca2+ elevations (dashed lines) in response to repulsive axon guidance cues (presumed) or uncaging of Ca2+ in filopodia (this study) activates calpain. Filopodial calpain activity cleaves talin and FAK to prevent adhesion formation and turnover, and tips the balance between formation and duration that results in Ca2+-dependent repulsive turning.

Baudry, Calpain-1 and Calpain-2: The Yin and Yang of Synaptic Plasticity and Neurodegeneration. 2016, Pubmed

Baudry, Calpain-1 and Calpain-2: The Yin and Yang of Synaptic Plasticity and Neurodegeneration. 2016, Pubmed
Bechara, FAK-MAPK-dependent adhesion disassembly downstream of L1 contributes to semaphorin3A-induced collapse. 2008, Pubmed
Calderwood, The Talin head domain binds to integrin beta subunit cytoplasmic tails and regulates integrin activation. 1999, Pubmed
Chan, Regulation of adhesion dynamics by calpain-mediated proteolysis of focal adhesion kinase (FAK). 2010, Pubmed
Charoy, gdnf activates midline repulsion by Semaphorin3B via NCAM during commissural axon guidance. 2012, Pubmed
Cheng, Phosphorylation of E3 ligase Smurf1 switches its substrate preference in support of axon development. 2011, Pubmed
Dent, GAP-43 phosphorylation is dynamically regulated in individual growth cones. 1992, Pubmed
Dent, The growth cone cytoskeleton in axon outgrowth and guidance. 2011, Pubmed
Franco, Regulating cell migration: calpains make the cut. 2005, Pubmed
Franco, Calpain-mediated proteolysis of talin regulates adhesion dynamics. 2004, Pubmed
Goksoy, Structural basis for the autoinhibition of talin in regulating integrin activation. 2008, Pubmed
Gomez, Filopodial calcium transients promote substrate-dependent growth cone turning. 2001, Pubmed , Xenbase
Guan, Long-range Ca2+ signaling from growth cone to soma mediates reversal of neuronal migration induced by slit-2. 2007, Pubmed
Gómez, Working with Xenopus spinal neurons in live cell culture. 2003, Pubmed , Xenbase
Henley, Calcium mediates bidirectional growth cone turning induced by myelin-associated glycoprotein. 2004, Pubmed , Xenbase
Huang, Talin phosphorylation by Cdk5 regulates Smurf1-mediated talin head ubiquitylation and cell migration. 2009, Pubmed
Huttenlocher, Regulation of cell migration by the calcium-dependent protease calpain. 1997, Pubmed
Kerstein, Mechanosensitive TRPC1 channels promote calpain proteolysis of talin to regulate spinal axon outgrowth. 2013, Pubmed , Xenbase
Kerstein, Mechanochemical regulation of growth cone motility. 2015, Pubmed
Kulkarni, Calpain mediates integrin-induced signaling at a point upstream of Rho family members. 1999, Pubmed
Laukaitis, Differential dynamics of alpha 5 integrin, paxillin, and alpha-actinin during formation and disassembly of adhesions in migrating cells. 2001, Pubmed
Li, Activation of FAK and Src are receptor-proximal events required for netrin signaling. 2004, Pubmed , Xenbase
Li, Essential role of TRPC channels in the guidance of nerve growth cones by brain-derived neurotrophic factor. 2005, Pubmed , Xenbase
Liu, Netrin requires focal adhesion kinase and Src family kinases for axon outgrowth and attraction. 2004, Pubmed
Lowery, The trip of the tip: understanding the growth cone machinery. 2009, Pubmed , Xenbase
Mingorance-Le Meur, Neurite consolidation is an active process requiring constant repression of protrusive activity. 2009, Pubmed
Moon, Balanced Vav2 GEF activity regulates neurite outgrowth and branching in vitro and in vivo. 2010, Pubmed , Xenbase
Myers, Focal adhesion kinase promotes integrin adhesion dynamics necessary for chemotropic turning of nerve growth cones. 2011, Pubmed , Xenbase
Myers, Regulation of axonal outgrowth and pathfinding by integrin-ECM interactions. 2011, Pubmed
Myers, Focal adhesion kinase modulates Cdc42 activity downstream of positive and negative axon guidance cues. 2012, Pubmed , Xenbase
Nawabi, A midline switch of receptor processing regulates commissural axon guidance in vertebrates. 2010, Pubmed
Nichol, Guidance of Axons by Local Coupling of Retrograde Flow to Point Contact Adhesions. 2016, Pubmed , Xenbase
Qin, Role of calpain-mediated p53 truncation in semaphorin 3A-induced axonal growth regulation. 2010, Pubmed
Ren, Focal adhesion kinase in netrin-1 signaling. 2004, Pubmed
Rico, Control of axonal branching and synapse formation by focal adhesion kinase. 2004, Pubmed
Robles, Focal adhesion kinase signaling at sites of integrin-mediated adhesion controls axon pathfinding. 2006, Pubmed , Xenbase
Robles, Src-dependent tyrosine phosphorylation at the tips of growth cone filopodia promotes extension. 2005, Pubmed , Xenbase
Robles, Filopodial calcium transients regulate growth cone motility and guidance through local activation of calpain. 2003, Pubmed , Xenbase
Saltel, New PI(4,5)P2- and membrane proximal integrin-binding motifs in the talin head control beta3-integrin clustering. 2009, Pubmed
Santiago-Medina, PAK-PIX interactions regulate adhesion dynamics and membrane protrusion to control neurite outgrowth. 2013, Pubmed , Xenbase
Santiago-Medina, Imaging adhesion and signaling dynamics in Xenopus laevis growth cones. 2012, Pubmed , Xenbase
Shim, XTRPC1-dependent chemotropic guidance of neuronal growth cones. 2005, Pubmed , Xenbase
Shiraha, Activation of m-calpain (calpain II) by epidermal growth factor is limited by protein kinase A phosphorylation of m-calpain. 2002, Pubmed
Song, Conversion of neuronal growth cone responses from repulsion to attraction by cyclic nucleotides. 1998, Pubmed , Xenbase
Tadokoro, Talin binding to integrin beta tails: a final common step in integrin activation. 2003, Pubmed
Thévenaz, User-friendly semiautomated assembly of accurate image mosaics in microscopy. 2007, Pubmed
Tompa, On the sequential determinants of calpain cleavage. 2004, Pubmed
Vitriol, Growth cone travel in space and time: the cellular ensemble of cytoskeleton, adhesion, and membrane. 2012, Pubmed
Wang, Requirement of TRPC channels in netrin-1-induced chemotropic turning of nerve growth cones. 2005, Pubmed , Xenbase
Wang, Journey to the skin: Somatosensory peripheral axon guidance and morphogenesis. 2013, Pubmed
Wei, Calcium flickers steer cell migration. 2009, Pubmed
Wen, A CaMKII/calcineurin switch controls the direction of Ca(2+)-dependent growth cone guidance. 2004, Pubmed , Xenbase
Woo, Retinotopic mapping requires focal adhesion kinase-mediated regulation of growth cone adhesion. 2009, Pubmed , Xenbase
Woo, Rac1 and RhoA promote neurite outgrowth through formation and stabilization of growth cone point contacts. 2006, Pubmed , Xenbase
Yan, Calpain cleavage promotes talin binding to the beta 3 integrin cytoplasmic domain. 2001, Pubmed