E-cadherin suppression directs cytoskeletal rearrangement and intraepithelial tumor cell migration in 3D human skin equivalents.

The link between loss of cell-cell adhesion, the activation of cell migration, and the behavior of intraepithelial (IE) tumor cells during the early stages of skin cancer progression is not well understood. The current study characterized the migratory behavior of a squamous cell carcinoma cell line (HaCaT-II-4) upon E-cadherin suppression in both 2D, monolayer cultures and within human skin equivalents that mimic premalignant disease. The migratory behavior of tumor cells was first analyzed in 3D tissue context by developing a model that mimics transepithelial tumor cell migration. We show that loss of cell adhesion enabled migration of single, IE tumor cells between normal keratinocytes as a prerequisite for stromal invasion. To further understand this migratory behavior, E-cadherin-deficient cells were analyzed in 2D, monolayer cultures and displayed altered cytoarchitecture and enhanced membrane protrusive activity that was associated with circumferential actin organization and induction of the nonmuscle, beta actin isoform. These features were associated with increased motility and random, individual cell migration in response to scrape-wounding. Thus, loss of E-cadherin-mediated adhesion led to the acquisition of phenotypic properties that augmented cell motility and directed the transition from the precancer to cancer in skin-like tissues.

EspFU, a type III-translocated effector of actin assembly, fosters epithelial association and late-stage intestinal colonization by E. coli O157:H7.

Enterohaemorrhagic Escherichia coli (EHEC) O157:H7 induces filamentous actin-rich 'pedestals' on intestinal epithelial cells. Pedestal formation in vitro requires translocation of bacterial effectors into the host cell, including Tir, an EHEC receptor, and EspF(U), which increases the efficiency of actin assembly initiated by Tir. While inactivation of espF(U) does not alter colonization in two reservoir hosts, we utilized two disease models to explore the significance of EspF(U)-promoted actin pedestal formation. EHECDeltaespF(U) efficiently colonized the rabbit intestine during co-infection with wild-type EHEC, but co-infection studies on cultured cells suggested that EspF(U) produced by wild-type bacteria might have rescued the mutant. Significantly, EHECDeltaespF(U) by itself was fully capable of establishing colonization at 2 days post inoculation but unlike wild type, failed to expand in numbers in the caecum and colon by 7 days. In the gnotobiotic piglet model, an espF(U) deletion mutant appeared to generate actin pedestals with lower efficiency than wild type. Furthermore, aggregates of the mutant occupied a significantly smaller area of the intestinal epithelial surface than those of the wild type. Together, these findings suggest that, after initial EHEC colonization of the intestinal surface, EspF(U) may stabilize bacterial association with the epithelial cytoskeleton and promote expansion beyond initial sites of infection.

Arf6 modulates the beta-actin specific capping protein, betacap73.

Recent work from our laboratory has revealed that isoactin cytoskeletal and membrane dynamics are coordinately regulated. In this chapter, we review some of the recent and relevant scientific literature focusing on key aspects of cytoskeletal and membrane-mediated signal transduction. Additionally, we highlight some of the strategic molecular, biochemical, and cell-based methodologies that we have either developed or implemented in our efforts aimed at revealing the pivotal role(s) that the actin isoforms play in controlling cell shape and motility during developmental and/or disease-associated events. Furthermore, we address the central position of beta-actin and its barbed end-specific capping protein, betacap73, in modulating nonmuscle cell membrane dynamics and cell migration. In studying the molecular mechanisms mediating these cytoskeletal protein interactions, we have recently recognized that cell motility and beta-actin dynamics are controlled by the direct association of betacap73 with the plasma membrane- and endosome-associated protein, ADP-ribosylation factor 6 (Arf6).

Collagenase promotes the cellular responses to injury and wound healing in vivo.

OBJECTIVE: This study focuses on the growth-promoting and migration-enhancing role that Clostridial collagenase plays in vitro and in vivo. METHODS: For in vitro studies, biosynthesized extracellular matrices were treated with purified Clostridial collagenase, nonspecific proteases, or buffer controls. Keratinocytes were subsequently plated upon these matrices in the presence or absence of Clostridial collagenase and/or heparin-binding epidermal-like growth factor, and cell proliferation and migration were quantified. To examine the effects of Clostridial collagenase in vivo, we performed a double-blind study of full-thickness wounds on the backs of Yucatan Micropigs, testing the effects of purified Clostridial collagenase, Regranex (PDGF-BB), and Solosite (carboxymethyl cellulose) on wound healing. IN VITRO STUDIES: Matrix pretreatment with Clostridial collagenase stimulates a 2-fold increase in proliferation and postinjury migration; when Clostridial collagenase and/or heparin-binding epidermal-like growth factor are added to the growth media, there is an additional doubling of growth and migration, yielding approximately 5-fold enhancement of keratinocyte proliferation and migration. Papain-urea treatment under similar conditions results in a 50% decrease in cell number over a 1-week time course. In vivo studies: By all parameters measured, including granulation tissue formation, inflammation, re-epithelization, and time to wound closure, purified Clostridial collagenase was superior (analysis of variance, P > .05) to other treatments tested. CONCLUSION: On the basis of these findings, we concluded that Clostridial collagenase stimulates keratinocyte cellular responses to injury in vitro and may represent a novel therapeutic approach for promotion of wound healing in vivo.

FGF-2 antagonizes the TGF-beta1-mediated induction of pericyte alpha-smooth muscle actin expression: a role for myf-5 and Smad-mediated signaling pathways.

PURPOSE: Although the FGF and TGF-beta families are known to play an important role in regulating vascular endothelial and smooth muscle cell behavior, the influence of these matrix-binding growth factors on microvascular pericyte morphogenesis is not well understood. The current study was undertaken to examine the molecular mechanisms that mediate the effects of the endothelium-produced growth regulators FGF-2 and TGF-beta1 on retinal pericyte proliferation and contractile phenotype. METHODS: Using purified retinal pericytes, a series of assays were implemented, including RT-PCR, DNA binding, immunoprecipitation, electrophoretic mobility shift, and indirect immunofluorescence, in an attempt to elucidate the FGF/TGF-beta1 signaling cascades that mediate retinal microvascular cell growth and contractile phenotype. RESULTS: Treatment of retinal pericytes with FGF-2 and heparin stimulated nearly a log order increase in proliferation, whereas removal of FGF-2 or addition of TGF-beta1 caused withdrawal from the growth cycle, inducing a smooth-muscle-like contractile phenotype, as indicated by upregulation of alpha-smooth muscle actin (alpha-SMA). This switch from a growth-potentiated to a growth-arrested state followed induction of the transcriptional regulator myf-5, as well as the nuclear translocation of myf-5 and Smad2. CONCLUSIONS: Several critical features of the endothelial cell-extracellular matrix-pericyte molecular signaling axis were elucidated in the study that are likely to be responsible for regulating retinal microvascular morphogenesis during normal development, as well as the pathologic angiogenesis accompanying several ocular disorders, including diabetic retinopathy and age-related macular degeneration.

Rho GTPase signaling modulates cell shape and contractile phenotype in an isoactin-specific manner.

Rho family small GTPases (Rho, Rac, and Cdc42) play an important role in cell motility, adhesion, and cell division by signaling reorganization of the actin cytoskeleton. Here, we report an isoactin-specific, Rho GTPase-dependent signaling cascade in cells simultaneously expressing smooth muscle and nonmuscle actin isoforms. We transfected primary cultures of microvascular pericytes, cells related to vascular smooth muscle cells, with various Rho-related and Rho-specific expression plasmids. Overexpression of dominant positive Rho resulted in the formation of nonmuscle actin-containing stress fibers. At the same time, alpha-vascular smooth muscle actin (alphaVSMactin) containing stress fibers were disassembled, resulting in a dramatic reduction in cell size. Rho activation also yielded a disassembly of smooth muscle myosin and nonmuscle myosin from stress fibers. Overexpression of wild-type Rho had similar but less dramatic effects. In contrast, dominant negative Rho and C3 exotransferase or dominant positive Rac and Cdc42 expression failed to alter the actin cytoskeleton in an isoform-specific manner. The loss of smooth muscle contractile protein isoforms in pericyte stress fibers, together with a concomitant decrease in cell size, suggests that Rho activation influences "contractile" phenotype in an isoactin-specific manner. This, in turn, should yield significant alteration in microvascular remodeling during developmental and pathologic angiogenesis.

Betacap73-ARF6 interactions modulate cell shape and motility after injury in vitro.

To understand the role that ARF6 plays in regulating isoactin dynamics and cell motility, we transfected endothelial cells (EC) with HA-tagged ARF6: the wild-type form (WT), a constitutively-active form unable to hydrolyze GTP (Q67L), and two dominant-negative forms, which are either unable to release GDP (T27N) or fail to bind nucleotide (N122I). Motility was assessed by digital imaging microscopy before Western blot analysis, coimmunoprecipitation, or colocalization studies using ARF6, beta-actin, or beta-actin-binding protein-specific antibodies. EC expressing ARF6-Q67L spread and close in vitro wounds at twice the control rates. EC expressing dominant-negative ARF6 fail to develop a leading edge, are unable to ruffle their membranes (N122I), and possess arborized processes. Colocalization studies reveal that the Q67L and WT ARF6-HA are enriched at the leading edge with beta-actin; but T27N and N122I ARF6-HA are localized on endosomes together with the beta-actin capping protein, betacap73. Coimmunoprecipitation and Western blot analyses reveal the direct association of ARF6-HA with betacap73, defining a role for ARF6 in signaling cytoskeletal remodeling during motility. Knowledge of the role that ARF6 plays in orchestrating membrane and beta-actin dynamics will help to reveal molecular mechanisms regulating actin-based motility during development and disease.