Integration of Single and Multicellular Wound Responses

Single cells and multicellular tissues rapidly heal wounds. These processes are considered distinct, but one mode of healing—Rho GTPase-dependent formation and closure of a purse string of actin filaments (F-actin) and myosin-2 around wounds—occurs in single cells [1] and [2] and in epithelia [3], [4], [5], [6], [7], [8], [9] and [10]. Here, we show that wounding of one cell in Xenopus embryos elicits Rho GTPase activation around the wound and at the nearest cell-cell junctions in the neighbor cells. F-actin and myosin-2 accumulate at the junctions and around the wound itself, and as the resultant actomyosin array closes over the wound site, junctional F-actin and myosin-2 become mechanically integrated with the actin and myosin-2 around the wound, forming a hybrid purse string. When cells are ablated rather than wounded, Rho GTPase activation and F-actin accumulation occur at cell-cell junctions surrounding the ablated cell, and the purse string closes the hole in the epithelium. Elevation of intracellular free calcium, an essential upstream signal for the single-cell wound response [2] and [11], also occurs at the cell-cell contacts and in neighbor cells. Thus, the single and multicellular purse string wound responses represent points on a signaling and mechanical continuum that are integrated by cell-cell junctions.     

Wound closure in the lamellipodia of single cells: mediation by actin polymerization in the absence of an actomyosin purse string

The actomyosin purse string is an evolutionarily conserved contractile structure that is involved in cytokinesis, morphogenesis, and wound healing. Recent studies suggested that an actomyosin purse string is crucial for the closure of wounds in single cells. In the present study, morphological and pharmacological methods were used to investigate the role of this structure in the closure of wounds in the peripheral cytoplasm of sea urchin coelomocytes. These discoidal shaped cells underwent a dramatic form of actin-based centripetal/retrograde flow and occasionally opened and closed spontaneous wounds in their lamellipodia. Fluorescent phalloidin staining indicated that a well defined fringe of actin filaments assembles from the margin of these holes, and drug studies with cytochalasin D and latrunculin A indicated that actin polymerization is required for wound closure. Additional evidence that actin polymerization is involved in wound closure was provided by the localization of components of the Arp2/3 complex to the wound margin. Significantly, myosin II immunolocalization demonstrated that it is not associated with wound margins despite being present in the perinuclear region. Pharmacological evidence for the lack of myosin II involvement in wound closure comes from experiments in which a microneedle was used to produce wounds in cells in which actomyosin contraction was inhibited by treatment with kinase inhibitors. Wounds produced in kinase inhibitor-treated cells closed in a manner similar to that seen with control cells. Taken together, our results suggest that an actomyosin purse string mechanism is not responsible for the closure of lamellar wounds in coelomocytes. We hypothesize that the wounds heal by means of a combination of the force produced by actin polymerization alone and centripetal flow. Interestingly, these cells did assemble an actomyosin structure around the margin of phagosome-like membrane invaginations, indicating that myosin is not simply excluded from the periphery by some general mechanism. The results indicate that the actomyosin purse string is not the only mechanism that can mediate wound closure in single cells.     

Wound-induced assembly and closure of an actomyosin purse string in Xenopus oocytes.

BACKGROUND: Both single cells and multicellular systems rapidly heal physical insults but are thought to do so by distinctly different mechanisms. Wounds in single cells heal by calcium-dependent membrane fusion, whereas multicellular wounds heal by a variety of different mechanisms, including circumferential contraction of an actomyosin 'purse string' that assembles around wound borders and is dependent upon the small GTPase Rho. RESULTS: We investigated healing of puncture wounds made in Xenopus oocytes, a single-cell system. Oocyte wounds rapidly assumed a circular morphology and constricted circumferentially, coincident with the recruitment of filamentous actin (F-actin) and myosin-II to the wound borders. Surprisingly, recruitment of myosin-II to wound borders occurred before that of F-actin. Further, experimental disruption of F-actin prevented healing but did not prevent myosin-II recruitment. Actomyosin purse-string assembly and closure was dependent on Rho GTPases and extracellular calcium. Wounding resulted in reorganization of microtubules into an array similar to that which forms during cytokinesis in Xenopus embryos. Experimental perturbation of oocyte microtubules before wounding inhibited actomyosin recruitment and wound closure, whereas depolymerization of microtubules after wounding accelerated wound closure. CONCLUSIONS: We conclude the following: actomyosin purse strings can close single-cell wounds; myosin-II is recruited to wound borders independently of F-actin; purse-string assembly is dependent on a Rho GTPase; and purse-string assembly and closure are controlled by microtubules. More generally, the results indicate that actomyosin purse strings have been co-opted through evolution to dispatch a broad variety of single-cell and multicellular processes, including wound healing, cytokinesis and morphogenesis.     

A Highlights from MBoC Selection: Complete canthi removal reveals that forces from the amnioserosa alone are sufficient to drive dorsal closure in Drosophila

Drosophila''s dorsal closure provides an excellent model system with which to analyze biomechanical processes during morphogenesis. During native closure, the amnioserosa, flanked by two lateral epidermal sheets, forms an eye-shaped opening with canthi at each corner. The dynamics of amnioserosa cells and actomyosin purse strings in the leading edges of epidermal cells promote closure, whereas the bulk of the lateral epidermis opposes closure. Canthi maintain purse string curvature (necessary for their dorsalward forces), and zipping at the canthi shortens leading edges, ensuring a continuous epithelium at closure completion. We investigated the requirement for intact canthi during closure with laser dissection approaches. Dissection of one or both canthi resulted in tissue recoil and flattening of each purse string. After recoil and a temporary pause, closure resumed at approximately native rates until slowing near the completion of closure. Thus the amnioserosa alone can drive closure after dissection of one or both canthi, requiring neither substantial purse string curvature nor zipping during the bulk of closure. How the embryo coordinates multiple, large forces (each of which is orders of magnitude greater than the net force) during native closure and is also resilient to multiple perturbations are key extant questions.     

Wound healing and inflammation: embryos reveal the way to perfect repair

Tissue repair in embryos is rapid, efficient and perfect and does not leave a scar, an ability that is lost as development proceeds. Whereas adult wound keratinocytes crawl forwards over the exposed substratum to close the gap, a wound in the embryonic epidermis is closed by contraction of a rapidly assembled actin purse string. Blocking assembly of this cable in chick and mouse embryos, by drugs or by inactivation of the small GTPase Rho, severely hinders the re-epithelialization process. Live studies of epithelial repair in GFP-actin-expressing Drosophila embryos reveal actin-rich filopodia associated with the cable, and although these protrusions from leading edge cells appear to play little role in epithelial migration, they are essential for final zippering of the wound edges together-inactivation of Cdc42 prevents their assembly and blocks the final adhesion step. This wound re-epithelialization machinery appears to recapitulate that used during naturally occurring morphogenetic episodes as typified by Drosophila dorsal closure. One key difference between embryonic and adult repair, which may explain why one heals perfectly and the other scars, is the presence of an inflammatory response at sites of adult repair where there is none in the embryo. Our studies of repair in the PU. 1 null mouse, which is genetically incapable of raising an inflammatory response, show that inflammation may indeed be partly responsible for scarring, and our genetic studies of inflammation in zebrafish (Danio rerio) larvae suggest routes to identifying gene targets for therapeutically modulating the recruitment of inflammatory cells and thus improving adult healing.     

In vivo imaging of epithelial wound healing in the cnidarian <Emphasis Type="Italic">Clytia hemisphaerica</Emphasis> demonstrates early evolution of purse string and cell crawling closure mechanisms

Background

All animals have mechanisms for healing damage to the epithelial sheets that cover the body and line internal cavities. Epithelial wounds heal either by cells crawling over the wound gap, by contraction of a super-cellular actin cable (“purse string”) that surrounds the wound, or some combination of the two mechanisms. Both cell crawling and purse string closure of epithelial wounds are widely observed across vertebrates and invertebrates, suggesting early evolution of these mechanisms. Cnidarians evolved ~600 million years ago and are considered a sister group to the Bilateria. They have been much studied for their tremendous regenerative potential, but epithelial wound healing has not been characterized in detail. Conserved elements of wound healing in bilaterians and cnidarians would suggest an evolutionary origin in a common ancestor. Here we test this idea by characterizing epithelial wound healing in live medusae of Clytia hemisphaerica.

Results

We identified cell crawling and purse string-mediated mechanisms of healing in Clytia epithelium that appear highly analogous of those seen in higher animals, suggesting that these mechanisms may have emerged in a common ancestor. Interestingly, we found that epithelial wound healing in Clytia is 75 to >600 times faster than in cultured cells or embryos of other animals previously studied, suggesting that Clytia may provide valuable clues about optimized healing efficiency. Finally, in Clytia, we show that damage to the basement membrane in a wound gap causes a rapid shift between the cell crawling and purse string mechanisms for wound closure. This is consistent with work in other systems showing that cells marginal to a wound choose between a super-cellular actin cable or lamellipodia formation to close wounds, and suggests a mechanism underlying this decision.

Conclusions

1. Cell crawling and purse string mechanisms of epithelial wound healing likely evolved before the divergence of Cnidaria from the bilaterian lineage ~ 600mya 2. In Clytia, the choice between cell crawling and purse string mechanisms of wound healing depends on interactions between the epithelial cells and the basement membrane.

     

Cell influx and contractile actomyosin force drive mammary bud growth and invagination

The mammary gland develops from the surface ectoderm during embryogenesis and proceeds through morphological phases defined as placode, hillock, bud, and bulb stages followed by branching morphogenesis. During this early morphogenesis, the mammary bud undergoes an invagination process where the thickened bud initially protrudes above the surface epithelium and then transforms to a bulb and sinks into the underlying mesenchyme. The signaling pathways regulating the early morphogenetic steps have been identified to some extent, but the underlying cellular mechanisms remain ill defined. Here, we use 3D and 4D confocal microscopy to show that the early growth of the mammary rudiment is accomplished by migration-driven cell influx, with minor contributions of cell hypertrophy and proliferation. We delineate a hitherto undescribed invagination mechanism driven by thin, elongated keratinocytes—ring cells—that form a contractile rim around the mammary bud and likely exert force via the actomyosin network. Furthermore, we show that conditional deletion of nonmuscle myosin IIA (NMIIA) impairs invagination, resulting in abnormal mammary bud shape.     

Effects of mutant rat dynamin on endocytosis

The process of wound repair in monolayers of the intestinal epithelial cell line, Caco-2BBe, was analyzed by a combination of time-lapse differential interference contrast (DIC) video and immunofluorescence microscopy, and laser scanning confocal immunofluorescence microscopy (LSCIM). DIC video analysis revealed that stab wounds made in Caco-2BBe monolayers healed by two distinct processes: (a) Extension of lamellipodia into the wounds; and (b) Purse string closure of the wound by distinct arcs or rings formed by cells bordering the wound. The arcs and rings which effected purse string closure appeared sharp and sheer in DIC, spanned between two and eight individual cells along the wound border, and contracted in a concerted fashion. Immunofluorescence analysis of the wounds demonstrated that the arcs and rings contained striking accumulations of actin filaments, myosin-II, villin, and tropomyosin. In contrast, arcs and rings contained no apparent enrichment of microtubules, brush border myosin-I immunogens, or myosin- V. LSCIM analysis confirmed the localization of actin filaments, myosin- II, villin, and tropomyosin in arcs and rings at wound borders. ZO-1 (a tight junction protein), also accumulated in arcs and rings around wounds, despite the fact that cell-cell contacts are absent at wound borders. Sucrase-isomaltase, an apically-localized integral membrane protein, maintained an apical localization in cells where arcs or rings were formed, but was found in lamellipodia extending into wounds in cells where arcs failed to form. Time-course, LSCIM quantification of actin, myosin II, and ZO-1 revealed that accumulation of these proteins within arcs and rings at the wound edge began within 5 minutes and peaked within 30-60 minutes of wounding. Actin filaments, myosin-II, and ZO-1 achieved 10-, 3-, and 4-fold enrichments, respectively, relative to cell edges which did not border wounds. The results demonstrate that wounded Caco-2BBe monolayers assemble a novel cytoskeletal structure at the borders of wounds. The results further suggest that this structure plays at least two roles in wound repair; first, mediation of concerted, purse string movement of cells into the area of the wound and second, maintenance of apical/basolateral polarity in cells which border the wound.     

Coordinated waves of actomyosin flow and apical cell constriction immediately after wounding

Epithelial wound healing relies on tissue movements and cell shape changes. Our work shows that, immediately after wounding, there was a dramatic cytoskeleton remodeling consisting of a pulse of actomyosin filaments that assembled in cells around the wound edge and flowed from cell to cell toward the margin of the wound. We show that this actomyosin flow was regulated by Diaphanous and ROCK and that it elicited a wave of apical cell constriction that culminated in the formation of the leading edge actomyosin cable, a structure that is essential for wound closure. Calcium signaling played an important role in this process, as its intracellular concentration increased dramatically immediately after wounding, and down-regulation of transient receptor potential channel M, a stress-activated calcium channel, also impaired the actomyosin flow. Lowering the activity of Gelsolin, a known calcium-activated actin filament–severing protein, also impaired the wound response, indicating that cleaving the existing actin filament network is an important part of the cytoskeleton remodeling process.     

Endocytosis-dependent coordination of multiple actin regulators is required for wound healing

The ability to heal wounds efficiently is essential for life. After wounding of an epithelium, the cells bordering the wound form dynamic actin protrusions and/or a contractile actomyosin cable, and these actin structures drive wound closure. Despite their importance in wound healing, the molecular mechanisms that regulate the assembly of these actin structures at wound edges are not well understood. In this paper, using Drosophila melanogaster embryos, we demonstrate that Diaphanous, SCAR, and WASp play distinct but overlapping roles in regulating actin assembly during wound healing. Moreover, we show that endocytosis is essential for wound edge actin assembly and wound closure. We identify adherens junctions (AJs) as a key target of endocytosis during wound healing and propose that endocytic remodeling of AJs is required to form “signaling centers” along the wound edge that control actin assembly. We conclude that coordination of actin assembly, AJ remodeling, and membrane traffic is required for the construction of a motile leading edge during wound healing.     

Nonmuscle myosin II generates forces that transmit tension and drive contraction in multiple tissues during dorsal closure

BACKGROUND: The morphogenic movements that characterize embryonic development require the precise temporal and spatial control of cell-shape changes. Drosophila dorsal closure is a well-established model for epithelial sheet morphogenesis, and mutations in more than 60 genes cause defects in closure. Closure requires that four forces, derived from distinct tissues, be precisely balanced. The proteins responsible for generating each of the forces have not been determined. RESULTS: We document dorsal closure in living embryos to show that mutations in nonmuscle myosin II (encoded by zipper; zip/MyoII) disrupt the integrity of multiple tissues during closure. We demonstrate that MyoII localization is distinct from, but overlaps, F-actin in the supracellular purse string, whereas in the amnioserosa and lateral epidermis each has similar, cortical distributions. In zip/MyoII mutant embryos, we restore MyoII function either ubiquitously or specifically in the leading edge, amnioserosa, or lateral epidermis and find that zip/MyoII function in any one tissue can rescue closure. Using a novel, transgenic mosaic approach, we establish that contractility of the supracellular purse string in leading-edge cells requires zip/MyoII-generated forces; that zip/MyoII function is responsible for the apical contraction of amnioserosa cells; that zip/MyoII is important for zipping; and that defects in zip/MyoII contractility cause the misalignment of the lateral-epidermal sheets during seam formation. CONCLUSIONS: We establish that zip/MyoII is responsible for generating the forces that drive cell-shape changes in each of the force-generating tissues that contribute to closure. This highly conserved contractile protein likely drives cell-sheet movements throughout phylogeny.     

Knee Adduction Moment and Medial Contact Force – Facts about Their Correlation during Gait

The external knee adduction moment is considered a surrogate measure for the medial tibiofemoral contact force and is commonly used to quantify the load reducing effect of orthopedic interventions. However, only limited and controversial data exist about the correlation between adduction moment and medial force. The objective of this study was to examine whether the adduction moment is indeed a strong predictor for the medial force by determining their correlation during gait. Instrumented knee implants with telemetric data transmission were used to measure tibiofemoral contact forces in nine subjects. Gait analyses were performed simultaneously to the joint load measurements. Skeletal kinematics, as well as the ground reaction forces and inertial parameters, were used as inputs in an inverse dynamics approach to calculate the external knee adduction moment. Linear regression analysis was used to analyze the correlation between adduction moment and medial force for the whole stance phase and separately for the early and late stance phase. Whereas only moderate correlations between adduction moment and medial force were observed throughout the whole stance phase (R² = 0.56) and during the late stance phase (R² = 0.51), a high correlation was observed at the early stance phase (R² = 0.76). Furthermore, the adduction moment was highly correlated to the medial force ratio throughout the whole stance phase (R² = 0.75). These results suggest that the adduction moment is a surrogate measure, well-suited to predicting the medial force ratio throughout the whole stance phase or medial force during the early stance phase. However, particularly during the late stance phase, moderate correlations and high inter-individual variations revealed that the predictive value of the adduction moment is limited. Further analyses are necessary to examine whether a combination of other kinematic, kinetic or neuromuscular factors may lead to a more reliable prediction of the force magnitude.     

Exposure to external environment of low ion concentrations is the trigger for rapid wound closure in Xenopus laevis embryos

Wounds in Xenopus laevis embryos close rapidly, as previously described. In this study, we examined the dependence on extracellular Na(+) and/or Cl(-) ion concentrations of the closure of wounds in Xenopus embryos inflicted by thermal injury. Wound closure did not occur in normal amphibian medium (100% NAM), while wound areas remarkably decreased either in 10-50% NAM or in 100% NAM lacking Na(+) or Cl(-). Similarly, wound areas did not change in a set of Na(+) and Cl(-) ion concentrations equivalent to those of the humoral fluids of intact Xenopus embryos, but rapid wound closure was induced by decreasing the concentration of either of the two ions. A tangential accumulation of actin cytoskeleton along the wound edge was associated with wound closure. However, a similar actin alignment formed even under the 100% NAM condition, in which wounds did not close, as stated above. The epidermis around the wound edge exhibited ellipse-shaped hypertrophy, and the marginal cells centripetally elongated during wound closure. On the other hand, no distinct morphological changes occurred in 100% NAM, although the epidermis was somewhat thickened. Thus, the morphological changes in the epidermis specific to the low ionic environment most likely play active roles in the wound closure of Xenopus laevis embryos, whereas the tangential actin alignment alone may be insufficient. Taken together, we propose that the wound closure in Xenopus embryos is triggered by a decline in either the extracellular Na(+) or Cl(-) ion concentration, and that this process is required for the abovementioned changes in the shape of the marginal cells.     

Modulating RhoA effectors induces transitions to oscillatory and more wavelike RhoA dynamics in Caenorhabditis elegans zygotes

Pulsatile RhoA dynamics underlie a wide range of cell and tissue behaviors. The circuits that produce these dynamics in different cells share common architectures based on fast positive and delayed negative feedback through F-actin, but they can produce very different spatiotemporal patterns of RhoA activity. However, the underlying causes of this variation remain poorly understood. Here we asked how this variation could arise through modulation of actin network dynamics downstream of active RhoA in early Caenorhabditis elegans embryos. We find that perturbing two RhoA effectors—formin and anillin—induce transitions from nonrecurrent focal pulses to either large noisy oscillatory pulses (formin depletion) or noisy oscillatory waves (anillin depletion). In both cases these transitions could be explained by changes in local F-actin levels and depletion dynamics, leading to changes in spatial and temporal patterns of RhoA inhibition. However, the underlying mechanisms for F-actin depletion are distinct, with different dependencies on myosin II activity. Thus, modulating actomyosin network dynamics could shape the spatiotemporal dynamics of RhoA activity for different physiological or morphogenetic functions.     

An endogenous sodium current may mediate wound healing in Xenopus neurulae

We have studied healing of Xenopus neurulae in order to investigate the role of endogenous sodium-carried electric currents in wound closure. Transected embryos healed completely within 7 hr in an artificial pond water medium. Wound closure was biphasic, with a rapid purse string-like contraction that was independent of sodium concentration followed by a slower sodium-dependent phase. The initial contraction was reversibly inhibited by cytochalasin B. Healing was prevented when neurulae were wounded and left to heal in sodium-free medium. Healing was also prevented in the presence of amiloride, benzamil, or ouabain, drugs that inhibit sodium flux through the epithelium. The transepithelial potential measured in intact neurulae fell rapidly and reversibly by 70% in response to 10 microM amiloride. Currents measured leaving the wound also decreased by 70% following amiloride addition. Our results indicate that at least one phase of wound healing in Xenopus neurulae is dependent upon an endogenous sodium-carried electric current. We hypothesize that the current may act by guiding epithelial cells to the wound site.     

Intrinsic connectivity reveals functionally distinct cortico-hippocampal networks in the human brain

Episodic memory depends on interactions between the hippocampus and interconnected neocortical regions. Here, using data-driven analyses of resting-state functional magnetic resonance imaging (fMRI) data, we identified the networks that interact with the hippocampus—the default mode network (DMN) and a “medial temporal network” (MTN) that included regions in the medial temporal lobe (MTL) and precuneus. We observed that the MTN plays a critical role in connecting the visual network to the DMN and hippocampus. The DMN could be further divided into 3 subnetworks: a “posterior medial” (PM) subnetwork comprised of posterior cingulate and lateral parietal cortices; an “anterior temporal” (AT) subnetwork comprised of regions in the temporopolar and dorsomedial prefrontal cortex; and a “medial prefrontal” (MP) subnetwork comprised of regions primarily in the medial prefrontal cortex (mPFC). These networks vary in their functional connectivity (FC) along the hippocampal long axis and represent different kinds of information during memory-guided decision-making. Finally, a Neurosynth meta-analysis of fMRI studies suggests new hypotheses regarding the functions of the MTN and DMN subnetworks, providing a framework to guide future research on the neural architecture of episodic memory.

Episodic memory depends on interactions between the hippocampus and interconnected neocortical regions. This study uses network analyses of intrinsic brain networks at rest to identify and characterize brain networks that interact with the hippocampus and have distinct functions during memory-guided decision making.     

Possible roles of ENaC and Cl(-) channel in wound closure in Xenopus laevis embryos

Our previous report showed that rapid wound closure in Xenopus laevis embryos was associated with a decrease in the extracellular concentration of either Na(+) or Cl(-) ions. In this study, we examined the wound closure in Xenopus embryos when epithelial Na(+) channel (ENaC), Na(+)/K(+) ATPase (Na(+) pump) or CICs (members of Cl(-) channel) were blocked by each specific inhibitor. Blockage of ENaC and CIC restricted the rate of wound closure during the first 30 min PW and during the subsequent period, respectively. In contrast, inhibition of Na(+) pump had no effect on the rate of wound closure. Furthermore, simultaneous administration of both ENaC and CIC inhibitors resulted in the cumulative reduction of wound closure. Thus, it is plausible that these ion channels play active roles in wound closure in Xenopus embryos. NPPB is known to inhibit both CIC-2 and CIC-3. Immunohistochemical experiments showed that CIC-3, but not CIC-2, was expressed in Xenopus embryos, suggesting that the reduced wound closure by NPPB was due to blockage of CIC-3. A local enhancement of CIC-3 expression at the leading edge of the wounded epidermis was found to be specific to closing wounds that were kept in 10% NAM. An in vitro wounding assay also showed a pattern of CIC-3 expression at the margin of the scratch wound comparable to the results in vivo. These findings suggest that intracellular translocation of CIC-3 is involved in wound closure. We propose that the ion channels, including CIC-3, play a crucial role in wound closure in Xenopus embryos.     

Fluctuation Analysis of Centrosomes Reveals a Cortical Function of Kinesin-1

The actin and microtubule networks form the dynamic cytoskeleton. Network dynamics is driven by molecular motors applying force onto the networks and the interactions between the networks. Here we assay the dynamics of centrosomes in the scale of seconds as a proxy for the movement of microtubule asters. With this assay we want to detect the role of specific motors and of network interaction. During interphase of syncytial embryos of Drosophila, cortical actin and the microtubule network depend on each other. Centrosomes induce cortical actin to form caps, whereas F-actin anchors microtubules to the cortex. In addition, lateral interactions between microtubule asters are assumed to be important for regular spatial organization of the syncytial embryo. The functional interaction between the microtubule asters and cortical actin has been largely analyzed in a static manner, so far. We recorded the movement of centrosomes at 1 Hz and analyzed their fluctuations for two processes—pair separation and individual movement. We found that F-actin is required for directional movements during initial centrosome pair separation, because separation proceeds in a diffusive manner in latrunculin-injected embryos. For assaying individual movement, we established a fluctuation parameter as the deviation from temporally and spatially slowly varying drift movements. By analysis of mutant and drug-injected embryos, we found that the fluctuations were suppressed by both cortical actin and microtubules. Surprisingly, the microtubule motor Kinesin-1 also suppressed fluctuations to a similar degree as F-actin. Kinesin-1 may mediate linkage of the microtubule (+)-ends to the actin cortex. Consistent with this model is our finding that Kinesin-1-GFP accumulates at the cortical actin caps.     

Modulation of inflammation by reactive oxygen species: implications for aging and tissue repair

Following tissue injury, adequate inflammatory vascular responses are essential for subsequent tissue repair. The aims of this study were to investigate the role of reactive oxygen species (ROS, generated at the injury site) in modulating the inflammatory response under acute- and chronic-injury conditions. The effect of age and the implications of this modulation for tissue repair was investigated. Using laser Doppler flowmetry, inflammatory vascular responses were monitored in the base of vacuum-induced blisters in the hind footpad of anesthetized rats (65 mg/kg Nembutal). Inflammation was amplified by superfusion of substance P (SP) over the blister base. The inflammatory response was examined in acute blisters induced on either na?ve skin (acute-injury model) or on skin innervated by a chronically injured nerve (chronic-injury model). Furthermore, the acute-injury model was examined during early and late phases, 0 and 5 h after blister induction, respectively. The involvement of ROS was assessed by either combined superfusion of the antioxidants: superoxide dismutase and catalase over the blister base in acute-injury, or intramuscular injection of tirilazad in chronically injured rats. The results showed that antioxidant treatment had no effect on the response during early and late phases of acute inflammation in young rats. However in old rats, the vascular response was significantly attenuated (60%) or significantly increased (40%) during the early and late phases of acute inflammation, respectively. Under chronic-injury conditions, antioxidant treatment significantly enhanced the response in both young and old rats. We then examined the effect of antioxidant, tirilazad, on the healing of a full thickness thermal injury induced in the intrascapular region (using a CO(2) laser) of the rat. Following burn injury, tirilazad was injected around the wound site starting on day 1 (early treatment) or day 6 (late treatment). Tirilazad had opposing actions on wound closure with early and late treatments delaying (24.6 +/- 0.6 d) or accelerating (14.2 +/- 0.3 d) wound closure compared with the group of aged controls (20.3 +/- 0.8 d). The results suggest that ROS have a paradoxical role exerting either a positive or negative effect on the inflammatory response with age. We contend that the role of ROS in modulating inflammation should be considered when designing treatment protocols to accelerate tissue repair.