Alan K. Howe

Integrin signaling and cell growth control

Integrins contribute to cell growth by providing a physical linkage between cytoskeletal structures and the extracellular matrix, and also by participating in various signal transduction processes. The interaction of integrins with matrix ligands can generate signals in and of itself, and can also modulate signals instigated by soluble factors such as peptide mitogens. Cellular events affected by integrin-mediated signaling include motility, cell division, differentiation and programmed cell death. Elucidation of how integrin-mediated cell adhesion controls cell growth is likely to be of fundamental importance in understanding complex biological processes, such as tissue morphogenesis and tumor progression.

Cell adhesion molecules, signal transduction and cell growth.

Signals from dynamic cellular interactions between the extracellular matrix and neighboring cells ultimately input into the cellular decision-making process. These interactions form the basis of anchorage-dependent growth. Recent advances have provided the mechanistic details behind the ability of integrins, and other cell adhesion molecules (CAMs), to regulate both early signal transduction events initiated by soluble factors and downstream events more proximally involved in cell cycle progression. These actions appear to depend on the ability of CAMs to initiate the formation of organized structures that permit the efficient flow of information.

Anchorage-dependent ERK signaling - Mechanisms and consequences

Integrin-mediated adhesion to the extracellular matrix regulates the cellular response to mitogens. Anchorage-dependent growth factor activation of the extracellular signal-regulated kinase (ERK) is an intensely studied example of this regulation. Given the central role of ERK in mediating cell migration, division, and survival, it is also an extremely important example. Recent work has demonstrated that cell adhesion can regulate ERK signaling at several checkpoints and has begun to define the mechanism and consequences associated with anchorage-dependent effects on the ERK cascade.

Regulation of anchorage-dependent signal transduction by protein kinase A and p21-activated kinase

Activation of the canonical mitogen-activated protein kinase (MAPK) cascade by soluble mitogens is blocked in non-adherent cells. It is also blocked in cells in which the cAMP-dependent protein kinase (PKA) is activated. Here we show that inhibition of PKA allows anchorage-independent stimulation of the MAPK cascade by growth factors. This effect is transient, and its duration correlates with sustained tyrosine phosphorylation of paxillin and focal-adhesion kinase (FAK) in non-adherent cells. The effect is sensitive to cytochalasin D, implicating the actin cytoskeleton as an important factor in mediating this anchorage-independent signalling. Interestingly, constitutively active p21-activated kinase (PAK) also allows anchorage-independent MAPK signalling. Furthermore, PKA negatively regulates PAK in vivo, and whereas the induction of anchorage-independent signaling resulting from PKA suppression is blocked by dominant negative PAK, it is markedly prolonged by constitutively active PAK. These observations indicate that PKA and PAK are important regulators of anchorage-dependent signal transduction.

Subcutaneous tissue fibroblast cytoskeletal remodeling induced by acupuncture: Evidence for a mechanotransduction‐based mechanism

Acupuncture needle rotation has been previously shown to cause specific mechanical stimulation of subcutaneous connective tissue. This study uses acupuncture to investigate the role of mechanotransduction‐based mechanisms in mechanically‐induced cytoskeletal remodeling. The effect of acupuncture needle rotation was quantified by morphometric analysis of mouse tissue explants imaged with confocal microscopy. Needle rotation induced extensive fibroblast spreading and lamellipodia formation within 30 min, measurable as an increased in cell body cross sectional area. The effect of rotation peaked with two needle revolutions and decreased with further increases in rotation. Significant effects of rotation were present throughout the tissue, indicating the presence of a response extending laterally over several centimeters. The effect of rotation with two needle revolutions was prevented by pharmacological inhibitors of actomyosin contractility (blebbistatin), Rho kinase (Y‐27632 and H‐1152), and Rac signaling. The active cytoskeletal response of fibroblasts demonstrated in this study constitutes an important step in understanding cellular mechanotransduction responses to externally applied mechanical stimuli in whole tissue, and supports a previously proposed model for the mechanism of acupuncture involving connective tissue mechanotransduction. J. Cell. Physiol.

Integrin regulation of cell signalling and motility

Integrins clearly play a key role in regulating both mitogenic signalling and cell migration. Thus integrins modulate the efficiency of the Erk (extracellular-signal-regulated kinase)/MAP kinase (mitogen-activated protein kinase) pathway, acting at several distinct levels. We have shown that both cAMP-dependent protein kinase and PAKs (p21-activated kinases) play a role in integrin regulation of the Erk pathway, acting primarily at the level of Raf-1. Integrins and PAKs also play a role in the control of cell migration. Thus we have discovered a novel protein that links the alpha5beta1 integrin to migration controlled by Rho-family GTPases. This protein, termed Nischarin, is a large cytosolic macromolecule that is not related to well-known protein families. The N-terminus of Nischarin interacts with a short segment of the cytoplasmic domain of the alpha5 integrin subunit. Overexpression of Nischarin alters actin organization and inhibits Rac-driven cell migration and tumour cell invasion. Use of effector domain mutants of Rac suggest that Nischarin acts downstream of Rac, probably at the level of PAK-family kinases. These studies emphasize the intricate connection between integrins and Rho-family GTPases and their effectors in controlling both mitogenesis and migration.

Oxidation state governs structural transitions in peroxiredoxin II that correlate with cell cycle arrest and recovery.

Inactivation of eukaryotic 2-Cys peroxiredoxins (Prxs) by hyperoxidation has been proposed to promote accumulation of hydrogen peroxide (H2O2) for redox-dependent signaling events. We examined the oxidation and oligomeric states of PrxI and -II in epithelial cells during mitogenic signaling and in response to fluxes of H2O2. During normal mitogenic signaling, hyperoxidation of PrxI and -II was not detected. In contrast, H2O2-dependent cell cycle arrest was correlated with hyperoxidation of PrxII, which resulted in quantitative recruitment of ∼66- and ∼140-kD PrxII complexes into large filamentous oligomers. Expression of cyclin D1 and cell proliferation did not resume until PrxII-SO2H was reduced and native PrxII complexes were regenerated. Ectopic expression of PrxI or -II increased Prx-SO2H levels in response to oxidant exposure and failed to protect cells from arrest. We propose a model in which Prxs function as peroxide dosimeters in subcellular processes that involve redox cycling, with hyperoxidation controlling structural transitions that alert cells of perturbations in peroxide homeostasis.

Spatial restriction of α4 integrin phosphorylation regulates lamellipodial stability and α4β1-dependent cell migration

Întegrins coordinate spatial signaling events essential for cell polarity and directed migration. Such signals from α4 integrins regulate cell migration in development and in leukocyte trafficking. Here, we report that efficient α4-mediated migration requires spatial control of α4 phosphorylation by protein kinase A, and hence localized inhibition of binding of the signaling adaptor, paxillin, to the integrin. In migrating cells, phosphorylated α4 accumulated along the leading edge. Blocking α4 phosphorylation by mutagenesis or by inhibition of protein kinase A drastically reduced α4-dependent migration and lamellipodial stability. α4 phosphorylation blocks paxillin binding in vitro; we now find that paxillin and phospho-α4 were in distinct clusters at the leading edge of migrating cells, whereas unphosphorylated α4 and paxillin colocalized along the lateral edges of those cells. Furthermore, enforced paxillin association with α4 inhibits migration and reduced lamellipodial stability. These results show that topographically specific integrin phosphorylation can control cell migration and polarization by spatial segregation of adaptor protein binding.

Distinct mechanisms mediate the initial and sustained phases of integrin-mediated activation of the Raf/MEK/mitogen-activated protein kinase cascade

Integrin-mediated adhesion to the extracellular matrix activates the canonical mitogen-activated protein kinase cascade, although the exact mechanism is not fully resolved. We show that integrin-mediated activation of Raf-1, an upstream regulator of mitogen-activated protein kinase, occurs in two phases. Efficient early activation of Raf required Raf-Ras interaction but was not affected by protein kinase C (PKC) inhibitors, while a lower, sustained level of activity was independent of Raf-Ras interaction but was reduced by PKC inhibitors. The combination of PKC inhibition and lack of Ras binding completely blocked integrin-mediated Raf activity. The activity of a membrane-bound Raf mutant that is deficient in Ras binding (Raf-R89L-CAAX) was also regulated by adhesion. Raf-R89L-CAAX activity was low in nonadherent cells, was rapidly stimulated to wild-type levels by cell adhesion, and remained at nearly maximal levels longer than wild-type activity. The activation of wild-type and mutant Raf proteins was ablated by cytochalasin D, demonstrating that cytoskeletal organization is required for activation of Raf, even when targeted to the membrane. These data suggest distinct initial and sustained phases of integrin-mediated Raf activation that require Raf membrane localization and possibly PKC activity, respectively, and that integrin-mediated adhesion may regulate a cytoskeleton-associated factor(s) responsible for Raf activation.

FIBROBLAST CYTOSKELETAL REMODELING CONTRIBUTES TO CONNECTIVE TISSUE TENSION

The visco‐elastic behavior of connective tissue is generally attributed to the material properties of the extracellular matrix rather than cellular activity. We have previously shown that fibroblasts within areolar connective tissue exhibit dynamic cytoskeletal remodeling within minutes in response to tissue stretch ex vivo and in vivo. Here, we tested the hypothesis that fibroblasts, through this cytoskeletal remodeling, actively contribute to the visco‐elastic behavior of the whole tissue. We measured significantly increased tissue tension when cellular function was broadly inhibited by sodium azide and when cytoskeletal dynamics were compromised by disrupting microtubules (with colchicine) or actomyosin contractility (via Rho kinase inhibition). These treatments led to a decrease in cell body cross‐sectional area and cell field perimeter (obtained by joining the end of all of a fibroblasts processes). Suppressing lamellipodia formation by inhibiting Rac‐1 decreased cell body cross‐sectional area but did not affect cell field perimeter or tissue tension. Thus, by changing shape, fibroblasts can dynamically modulate the visco‐elastic behavior of areolar connective tissue through Rho‐dependent cytoskeletal mechanisms. These results have broad implications for our understanding of the dynamic interplay of forces between fibroblasts and their surrounding matrix, as well as for the neural, vascular, and immune cell populations residing within connective tissue. J. Cell. Physiol. 226: 1166–1175, 2011.