Philip Chang scite author profile

To become migratory, cells must reorganize their connections to the substratum, and during locomotion they must break rear attachments. The molecular and biochemical mechanisms underlying these biophysical processes are unknown. Recent studies have implicated both extracellular signal-regulated kinase/mitogen-activated protein (ERK/MAP) kinase and calpain (EC 3.4.22.17) in these processes, but it is uncertain whether these are two distinct pathways acting on different modes of motility. We report that cell deadhesion involved in epidermal growth factor (EGF) receptor-mediated fibroblast motility requires activation of M-calpain downstream of ERK/MAP kinase signaling. NR6 fibroblasts expressing full-length wild type epidermal growth factor receptor required both calpain and ERK activation, as demonstrated by pharmacological inhibitors (calpeptin and calpain inhibitor I and PD98059, respectively) for EGF-induced deadhesion and motility. EGF induced rapid activation of calpain that was preventable by molecular inhibition of the Ras-Raf-MEK but not phospholipase C␥ signaling pathway, and calpain was stimulated by transfection of constitutively active MEK. Enhanced calpain activity was not mirrored by increased calpain protein levels or decreased levels of its endogenous inhibitor calpastatin. The link between ERK/MAP kinase signaling and cell motility required the M-isoform of calpain (calpain II), as determined by specific antisense-mediated down-regulation. These data promote a previously undescribed signaling pathway of ERK/MAP kinases activating calpain to destabilize cell-substratum adhesions in response to EGF stimulation.Cell motility is a central process involved in many physiological events including tumor invasion, embryonic development, and wound healing. Cell motility has been found to be a very complex biophysical process involving multiple factors working together to accomplish concerted movement. To begin to understand the molecular bases of motility, fibroblast cell motility has been deconstructed into four separate events: extension of the lammelipod, formation of new focal adhesions at the leading edge, breaking of adhesions at the trailing edge, and translocation of the cell mass (1). Failure of any one of these steps is sufficient to prevent cell motility (2, 3).These motility events are regulated by both cell intrinsic and extrinsic properties (4, 5). Among the latter are regulatory inputs from growth factor receptors and the strength and nature of cell-substratum interactions. Previously, it had been demonstrated that motility of adherent cells occurs in a biphasic relationship to adhesiveness of the surface (6, 7). Recently, we have shown that this also holds for growth factor-induced motility, in that epidermal growth factor (EGF) 1 receptor-mediated fibroblast motility is noted only at intermediate levels of cell adhesiveness to substrata (8, 9). Thus, signals that regulate adhesiveness to the substratum are of high importance, since the rear deadhesion of the cell from its substrate can be ...

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Deciphering the Structural Basis of Eukaryotic Protein Kinase Regulation

Meharena

et al. 2013

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Epidermal growth factor receptor-mediated motility in fibroblasts

Wells

Gupta

Chang

et al. 1998

Microsc. Res. Tech.

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The Rate of NF-κB Nuclear Translocation Is Regulated by PKA and A Kinase Interacting Protein 1

et al. 2011

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The mechanism of PKAc-dependent NF-κB activation and subsequent translocation into the nucleus is not well defined. Previously, we showed that A kinase interacting protein 1 (AKIP1) was important for binding and retaining PKAc in the nucleus. Since then, other groups have demonstrated that AKIP1 binds the p65 subunit of NF-κB and regulates its transcriptional activity through the phosphorylation at Ser 276 by PKAc. However, little is known about the formation and activation of the PKAc/AKIP1/p65 complex and the rate at which it enters the nucleus. Initially, we found that the AKIP1 isoform (AKIP 1A) simultaneously binds PKAc and p65 in resting and serum starved cells. Using peptide arrays, we refined the region of AKIP 1A binding on PKAc and mapped the non-overlapping regions on AKIP 1A where PKAc and p65 bind. A peptide to the amino-terminus of PKAc (CAT 1-29) was generated to specifically disrupt the interaction between AKIP 1A and PKAc to study nuclear import of the complex. The rate of p65 nuclear translocation was monitored in the presence or absence of overexpressed AKIP 1A and/or (CAT 1-29). Enhanced nuclear translocation of p65 was observed in the presence of overexpressed AKIP1 and/or CAT 1-29 in cells stimulated with TNFα, and this correlated with decreased phosphorylation of serine 276. To determine whether PKAc phosphorylation of p65 in the cytosol regulated nuclear translocation, serine 276 was mutated to alanine or aspartic acid. Accelerated nuclear accumulation of p65 was observed in the alanine mutant, while the aspartic acid mutation displayed slowed nuclear translocation kinetics. In addition, enhanced nuclear translocation of p65 was observed when PKAc was knocked-down by siRNA. Taken together, these results suggest that AKIP 1A acts to scaffold PKAc to NF-κB in the cytosol by protecting the phosphorylation site and thereby regulating the rate of nuclear translocation of p65.

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Philip Chang

Epidermal Growth Factor Receptor Activation of Calpain Is Required for Fibroblast Motility and Occurs via an ERK/MAP Kinase Signaling Pathway

Deciphering the Structural Basis of Eukaryotic Protein Kinase Regulation

Epidermal growth factor receptor-mediated motility in fibroblasts

The Rate of NF-κB Nuclear Translocation Is Regulated by PKA and A Kinase Interacting Protein 1

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