Chemotactically directed redistribution of alpha-actinin precedes morphological polarization and reversal of polarity in human polymorphonuclear leucocytes (PMNs)

We have determined the temporal and spatial relationship between cell polarization and alpha-actinin localization by analysing the redistribution of alpha-actinin and F-actin in spherical PMNs developing polarity and in polarized cells reversing polarity following localized stimulation with chemotactic peptide using micropipettes. Initially spherical PMNs develop a one-sided accumulation of alpha-actinin before lamellipodia enriched in alpha-actinin are formed. In polarized cells, alpha-actinin is concentrated at the leading front. When polarity is reversed, alpha-actinin redistribution to the uropod precedes reversal of morphological polarity and formation of new lamellipodia at the uropod. Later, lamellipodia enriched in F-actin and alpha-actinin develop at the former uropod to form a new front. The data document that redistribution of alpha-actinin is a very early event in the development of polarity, which precedes formation of lamellipodia.     

Effects of the myosin inhibitor 2,3-butanedione monoxime (BDM) on cell shape, locomotion and fluid pinocytosis in human polymorphonuclear leucocytes

We investigated the role of myosin in polymorphonuclear leucocyte (PMN) shape changes, locomotion, and fluid pinocytosis using the myosin inhibitor 2,3 butanedione monoxime (BDM). Treatment of resting spherical PMNs with BDM produced spheroid cells showing small continuous shape changes (IC(50)=15.5 m m BDM) and occasionally small blebs. Cell polarity, as induced by the chemotactic peptide fNLPNTL or by colchicine, and locomotion were completely suppressed (IC(50)=8.4 to 10 m m). Suppression of fNLPNTL- or colchicine-induced cell polarity produced spheroid cells, suppression of PMA-induced shape changes and fluid pinocytosis produced non-motile spherical cells (IC(50)=25 to 30 m m BDM). BDM suppressed formation of lamellipodia but not formation of blebs. Suppression of microvilli by BDM as observed in resting spherical cells was partially antagonized by PMA. The results suggest that myosin is involved in stabilizing the shape of resting spherical cells, including microvilli, and that myosin is required for cell polarity, locomotion, fluid pinocytosis and for formation of lamellipodia, but not for formation of blebs.     

Reinterpreting polarity and cancer: The changing landscape from tumor suppression to tumor promotion

Cell polarity is a fundamental property used to generate asymmetry and structure in all cells. Cancer is associated with loss of cell and tissue structure. While observations made in model system such as Drosophila, identify polarity regulators as tumor suppressors that cause inappropriate cell division, studies in mammalian epithelia do not always support such a causative contribution. Our analysis of published cancer dataset shows that many polarity genes, including PARD6B, SCRIB, PRKCI, DLG1, DLG2, DLG5 and LLGL2, are frequently amplified in multiple cancers raising the possibility that mammalian epithelia may have evolved to use polarity proteins in multiple ways where they may have tumor promoting functions. In this review, we reinterpret the published results and propose a modified perspective for the role of polarity regulators in cancer biology. In addition to the traditional form of cell polarity, which is involved establishment of maintenance of normal cell structure and asymmetry, we propose that some mammalian polarity proteins also regulate subcellular polarity (intracellular asymmetry), which can improve cellular fitness to carry out functions such as proliferation, apoptosis, stress adaptation, stemness and organelle biology. Here, we define subcellular polarity and discuss evidence that supports a role for subcellular polarity in biology.     

PAR polarity: From complexity to design principles

The par-titioning-defective or PAR proteins comprise the core of an essential cell polarity network that underlies polarization in a wide variety of cell types and developmental contexts. The output of this network in nearly every case is the establishment of opposing and complementary membrane domains that define a cell?s polarity axis. Yet, behind this simple pattern is a complex system of interactions, regulation and dynamic behaviors. How these various parts combine to generate polarized patterns of protein localization in cells is only beginning to become clear. This review, part of the Special Issue on Cell Polarity, aims to highlight several emerging themes and design principles that underlie the process of cell polarization by components of the PAR network.     

Biphasic response of human polymorphonuclear leucocytes and keratinocytes (epitheliocytes) fromXenopus laevis to mechanical stimulation

Summary Human polymorphonuclear leucocytes and epitheliocytes isolated from tadpole tails ofXenopus laevis were used to observe the responses of cells to mechanical stimulation with a microneedle. Biphasic responses were observed: a retraction phase lasting 1–3 s was followed by an extension phase lasting 10–40s. Weak stimulation evoked alocal response whilst on strong stimulation the whole cells rounded up. Spreading after induced rounding was at least one order of magnitude faster (it lasted less than 1–2min) than cell spreading after chemical dissociation of cell cultures. Local or extended loss of cell attachment to the substratum (observed with reflection interference contrast microscopy) preceded changes in cell morphology, visible with phase contrast microscopy. Repeated weak stimulation of one cell side induced extension and locomotion of the cell in this direction. The reported biphasic responses of cells to mechanical stimulation highlight the significance of exact timing when following any cell response to external stimuli.     

Spatial regulation of exocytosis and cell polarity: yeast as a model for animal cells

Exocytosis is the major mechanism by which new membrane components are delivered to the cell surface. In most, if not all, eukaryotic cells this is also a highly spatially regulated process that is tightly coordinated with the overall polarity of a cell. The Rho/Cdc42 family of GTPases and the lethal giant larvae/Sro7 family are two highly conserved families of proteins which appear to have dual functions both in cell polarity and exocytosis. Analysis of their functions has begun to unravel the coordination between these processes and propose a model for polarized vesicle docking and fusion at the site of asymmetric cell growth.     

Insect epidermis: disturbance of supracellular tissue polarity does not prevent the expression of cell polarity

Summary The insect integument displays planar tissue polarity in the uniform orientation of polarized cuticular structures. In a body segment, for example, the denticles and bristles produced by the constituent epidermal cells point posteriorly. Colchicine can abolish this uniform orientation while still allowing individual cells to form orientated cuticular structures and thereby to express cell polarity. This suggests that an individual cell in a sheet can establish planar polarity without reference to some kind of covert supracellular cue (such as a morphogen gradient) in the epidermis as a whole. The results also indicate that colchicine interferes — directly or indirectly — with the mechanisms involved in aligning the polarity axes of individual cells into a common orientation, thereby generating supracellular or tissue polarity.     

Cytoskeletal dynamics ofApedinella radians (Pedinellophyceae) II. Cell division and maintenance of cell polarity and symmetry

Summary The dynamics of the cytoskeletal proteins centrin, actin, and tubulin were followed during cell division in the unicellular phytoflagellateApedinella radians (Pedinellophyceae). Three centrin, or centrin-like, components appear to coordinate independent developmental events during cell division. The first component, basal body centrin, maintains a physical link between basal bodies and the anterior nuclear membrane. Basal body centrin divides in two at metaphase, and each portion segregates with two basal bodies at anaphase. As the positioning of basal bodies defines the anterior region of the cell, basal body centrin appears to play a role in maintaining cell polarity throughout the cell cycle. The second centrin component consists of an array of filamentous bundles arranged as a six-pointed star. During cell division, the star undergoes a conformational change resulting in two distinct centrin triangles, one distributed to each daughter cell, suggesting that centrin filamentous bundles are involved in maintaining cell (radial) symmetry. The third centrin component is transient and associates with the spindle poles, emerging prior to mitosis and remaining until late anaphase/early telophase. Spindle pole centrin establishes temporary horizontal bipolarity, thereby establishing the spindle axis. Unlike centrin filamentous bundles, actin filamentous bundles depolymerize prior to mitosis, indicating they do not influence cell symmetry during cell division. Mitosis is described for the first time in a pedinellid and features a closed spindle, the absence of rhizoplasts and a persistent spindle.     

Induced locomotion of human and murine macrophages: A comparative analysis by means of the modified Boyden-chamber system and the agarose migration assay

Summary This study was designed to gain detailed information concerning the kinetic activity of connective tissuederived macrophages from living human specimens. Their kinetic activity in vitro was estimated using the agarosemigration assay and the modified Boyden-chamber, and compared with that of murine peritoneal macrophages. These assays permit the distinction of chemotactic and chemokinetic patterns as well as spontaneous migration. These kinetic activities were stimulated by and calculated for ultrasound-crushed suspensions of Escherichia coli, zymosan-activated human serum, human serum albumin, casein-activated human serum, tripeptide f-Met-Leu-Phe (N--formyl-L-methionyl-L-leucyl-L-phenylalanine), phytohemagglutinine, modified Eagle's medium and phosphate buffer. Investigation of the migratory performance (in m) in the Boyden-chamber and by the agarose migration assay for chemokinetics and chemotaxis by using tripeptides as chemotactically attracting agents revealed a somewhat higher activity in murine than in human macrophages.This article is cordially dedicated to Professor Dr. Helmut Leonhardt, Kiel, in achieving his 70th anniversary     

The polarity protein Pard3 is required for centrosome positioning during neurulation

Microtubules are essential regulators of cell polarity, architecture and motility. The organization of the microtubule network is context-specific. In non-polarized cells, microtubules are anchored to the centrosome and form radial arrays. In most epithelial cells, microtubules are noncentrosomal, align along the apico-basal axis and the centrosome templates a cilium. It follows that cells undergoing mesenchyme-to-epithelium transitions must reorganize their microtubule network extensively, yet little is understood about how this process is orchestrated. In particular, the pathways regulating the apical positioning of the centrosome are unknown, a central question given the role of cilia in fluid propulsion, sensation and signaling. In zebrafish, neural progenitors undergo progressive epithelialization during neurulation, and thus provide a convenient in vivo cellular context in which to address this question. We demonstrate here that the microtubule cytoskeleton gradually transitions from a radial to linear organization during neurulation and that microtubules function in conjunction with the polarity protein Pard3 to mediate centrosome positioning. Pard3 depletion results in hydrocephalus, a defect often associated with abnormal cerebrospinal fluid flow that has been linked to cilia defects. These findings thus bring to focus cellular events occurring during neurulation and reveal novel molecular mechanisms implicated in centrosome positioning.     

Spectrin and protein 4.1 as an actin filament capping complex

Spectrin and protein 4.1, when added to G- or F-actin, cause the formation of short filaments, as judged by the appearance of powerful nucleating activity for G-actin polymerisation. F-Actin filaments are rapidly fragmented under physiological solvent conditions. The effect of cytochalasin E on the polymerisation reaction and the extent of reduction in the critical monomer concentration of actin when spectrin and 4.1 are added suggest that these proteins form a capping system for the more slowly growing, or 'pointed' ends of actin filaments. The interaction is not affected by calcium or by 4.9, the remaining constituent of the purified red cell membrane cytoskeleton.     

Clostridium perfringens invasiveness is enhanced by effects of theta toxin upon PMNL structure and function: The role of leukocytotoxicity and expression of CD11/CD18 adherence glycoprotein

Abstract Clostridium perfringens infections are characterized by the lack of an inflammatory response at the site of infection and rapidly progressive margins of tissue necrosis. Studies presented here investigated the role of theta toxin from C. perfringens in the pathophysiology of these events. Mice passively immunized with neutralizing monoclonal antibody against theta toxin and challenged with an LD₁₀₀ of log phase C. perfringens had significantly less mortality than untreated controls. Intramuscular injection of killed, washed C. perfringens in mice induced a massive time-dependent influx of polymorphonuclear leukocytes (PMNL) into tissue; injection of either viable, washed C. perfringens or killed organisms plus theta toxin dramatically attenuated PMNL influx although PMNL accumulated in adjacent vessels. The anti-inflammatory effects could not be attributed to an absence of chemoattractants since C. perfringens proteins had chemotactic factor activity, and killed bacilli generated serum-derived chemotactic factors. Scanning and transmission electron microscopy demonstrated the dramatic leukocidal effects of high doses of theta toxin on PMNL. In contrast, sublethal concentrations of theta toxin primed PMNL chemiluminescence, disrupted PMNL cytoskeletal actin polymerization/disassembly, and stimulated functional upregulation of CD11b/CD18 adherence glycoprotein. In summary, these results demonstrate that theta toxin is an important virulence factor in C. perfringens infection. In a concentration-dependent fashion, theta toxin contributes to the pathogenesis of clostridial gangrene by direct destruction of host inflammatory cells and tissues, and by promoting dysregulated PMNL/endothelial cell adhesive interactions.     

Changes in the electrical polarity of tobacco cells following the application of weak external currents

Weak externally applied electric currents changed the natural electrical pattern surrounding cells from tobacco (Nicotiana tabacum L.) suspension cultures. The artificial currents were applied transversely to short filaments of cells placed between a microelectrode lose to the filament surface and a large platinum electrode some distance away. The natural current patterns before and after electrical treatment were measured with a vibrating probe. Significant effects were confined to the cell adjacent to the microelectrode. Currents with densities of 100 A · cm^–2 at the cell surface applied for 10 min or 3 A · cm^–2 for several hours caused a localized increase in the natural current entering the part of the cell which had been nearest the positive electrode. There was no corresponding local increase in current leaving from the opposite side of the cell. Instead, the extra current appeared to leave over a relatively large area. The overall effect was a tendency for the cell to repolarize transversely with a greater proportion of its transcellular currents flowing in the direction of the current applied. The effect was measurable for several hours after the external current was discontinued and may be evidence for a natural mechanism by which neighbouring cells entrain one another's polarities during differentiation. The effect of external currents on cells growing in a 2,4-dichlorophenoxyacetic acid (2,4-D) medium (which suppresses differentiation) was qualitatively the same as on cells in an indole-3-acetic acid medium (which promotes differentiation). If anything, the response was greater in 2,4-D, implying that the disruptive effect of 2,4-D on cell and tissue polarization is not a consequence of it preventing cells sensing the transcellular currents of their neighbours.Abbreviation 2,4-D 2,4-dichlorophenoxyacetic acid The authors are indebted to the Agricultural and Food Research Council of the U.K. for financial support and to the Royal Society for the provision of the vibrating probe.     

Role of mechanical cues in shaping neuronal morphology and connectivity

Neuronal circuits, the functional building blocks of the nervous system, assemble during development through a series of dynamic processes including the migration of neurons to their final position, the growth and navigation of axons and their synaptic connection with target cells. While the role of chemical cues in guiding neuronal migration and axonal development has been extensively analysed, the contribution of mechanical inputs, such as forces and stiffness, has received far less attention. In this article, we review the in vitro and more recent in vivo studies supporting the notion that mechanical signals are critical for multiple aspects of neuronal circuit assembly, from the emergence of axons to the formation of functional synapses. By combining live imaging approaches with tools designed to measure and manipulate the mechanical environment of neurons, the emerging field of neuromechanics will add a new paradigm in our understanding of neuronal development and potentially inspire novel regenerative therapies.     

CD2AP contributes to cell migration and adhesion in cultured gastric epithelium

The potential association of CD2AP with the adherens junction protein E-cadherin, co-localization with the actin cytoskeleton, and involvement in cell migration was investigated in cultured rat gastric mucosal cells. In stationary cells, CD2AP was localized perinuclearly while E-cadherin was expressed along cell-cell contacts and F-actin formed a branched network and adhesion belts. In migrating cells, CD2AP appeared as thread-like accumulations in the leading edges, colocalizing with F-actin and occasionally with E-cadherin. Intracellular injection of anti-CD2AP significantly retarded the migration speed of the cells suggesting a crucial role for CD2AP in mucosal cell migration, possibly as a scaffolding protein between cell membrane proteins and actin cytoskeleton. Co-immunoprecipitation assays revealed that CD2AP and E-cadherin are in a complex in HGF stimulated cells. It is concluded that CD2AP interacts with E-cadherin and co-localizes with F-actin in the leading edge of migrating cells, and significantly contributes to cell migration in restituting gastric epithelium.     

Cadherins as regulators of neuronal polarity

A compelling amount of data is accumulating about the polyphonic role of neuronal cadherins during brain development throughout all developmental stages, starting from the involvement of cadherins in the organization of neurulation up to synapse development and plasticity. Recent work has confirmed that specifically N-cadherins play an important role in asymmetrical cellular processes in developing neurons that are at the basis of polarity. In this review we will summarize recent data, which demonstrate how N-cadherin orchestrates distinct processes of polarity establishment in neurons.     

Cadherins as regulators of neuronal polarity

A compelling amount of data is accumulating about the polyphonic role of neuronal cadherins during brain development throughout all developmental stages, starting from the involvement of cadherins in the organization of neurulation up to synapse development and plasticity. Recent work has confirmed that specifically N-cadherins play an important role in asymmetrical cellular processes in developing neurons that are at the basis of polarity. In this review we will summarize recent data, which demonstrate how N-cadherin orchestrates distinct processes of polarity establishment in neurons.     

Resistance of Neisseria gonorrhoeae to non-oxidative killing by adherent human polymorphonuclear leucocytes

Symptomatic infection with Neisseria gonorrhoeae (Gc) is characterized by abundant neutrophil (PMN, polymorphonuclear leucocyte) influx, but PMNs cannot clear initial infection, indicating that Gc possess defences against PMN challenge. In this study, survival of liquid-grown Gc was monitored after synchronous infection of adherent, interleukin 8-treated human PMNs. 40–70% of FA1090 Gc survived 1 h of PMN exposure, after which bacterial numbers increased. Assays with bacterial viability dyes along with soybean lectin to detect extracellular Gc revealed that a subset of both intracellular and extracellular PMN-associated Gc were viable. Gc survival was unaffected in PMNs chemically or genetically deficient for producing reactive oxygen species (ROS). This result held true even for OpaB+ Gc, which stimulate neutrophil ROS production. Catalase- and RecA-deficient Gc, which are more sensitive to ROS in vitro , had no PMN survival defect. recN and ngo1686 mutant Gc also exhibit increased sensitivity to ROS and PMNs, but survival of these mutants was not rescued in ROS-deficient cells. The ngo1686 mutant showed increased sensitivity to extracellular but not intracellular PMN killing. We conclude that Gc are remarkably resistant to PMN killing, killing occurs independently of neutrophil ROS production and Ngo1686 and RecN defend Gc from non-oxidative PMN antimicrobial factors.     

Guiding cell migration through directed extension and stabilization of pseudopodia

Cell migration requires establishment of a single pseudopodium in the direction of movement. Here we highlight recent advances in our understanding of the molecular signaling mechanisms that regulate formation of pseudopodia. We discuss how signal transduction processes are spatially and temporally organized to establish cell polarity through directed extension and stabilization of dominant pseudopodia. We also highlight recent advances in technology that will further the understanding of signaling dynamics specific to pseudopodia extension and cell migration.