Interdependence of Laminin-mediated Clustering of Lipid Rafts and the Dystrophin Complex in Astrocytes

Astrocyte endfeet surrounding blood vessels are active domains involved in water and potassium ion transport crucial to the maintenance of water and potassium ion homeostasis in brain. A growing body of evidence points to a role for dystroglycan and its interaction with perivascular laminin in the targeting of the dystrophin complex and the water-permeable channel, aquaporin 4 (AQP4), at astrocyte endfeet. However, the mechanisms underlying such compartmentalization remain poorly understood. In the present study we found that AQP4 resided in Triton X-100-insoluble fraction, whereas dystroglycan was recovered in the soluble fraction in astrocytes. Cholesterol depletion resulted in the translocation of a pool of AQP4 to the soluble fraction indicating that its distribution is indeed associated with cholesterol-rich membrane domains. Upon laminin treatment AQP4 and the dystrophin complex, including dystroglycan, reorganized into laminin-associated clusters enriched for the lipid raft markers GM1 and flotillin-1 but not caveolin-1. Reduced diffusion rates of GM1 in the laminin-induced clusters were indicative of the reorganization of raft components in these domains. In addition, both cholesterol depletion and dystroglycan silencing reduced the number and area of laminin-induced clusters of GM1, AQP4, and dystroglycan. These findings demonstrate the interdependence between laminin binding to dystroglycan and GM1-containing lipid raft reorganization and provide novel insight into the dystrophin complex regulation of AQP4 polarization in astrocytes.The basement membrane is a specialized extracellular matrix (ECM)² composed of collagen, fibronectin, perlecan, agrin, and laminin. Several studies have focused on the involvement of these ECM molecules in the formation and maturation of neuromuscular junctions (1–4) and interneuronal synapses (5). More recently, much effort has been made by our group and others to understand the role of these molecules at the interface of astroglia and blood vessels (6–8). Laminin is highly expressed at the perivascular ECM, and the laminin receptor, dystroglycan (α-DG), together with many other components of the dystrophin-associated protein (DAP) complex, is particularly enriched at astrocyte endfeet abutting the blood vessels (9–11). The binding of laminin to α-DG at these specialized astrocyte domains in brain plays a key role in the polarized distribution of components of the DAP complex (6, 12).Multiple lines of evidence indicate that the DAP complex is crucial for the functional distribution both of the water-permeable channel, AQP4, and the inwardly rectifying potassium channel, Kir4.1, at astrocyte endfeet. Indeed, mutations in the dystrophin gene, deletion of α-syntrophin, or loss of laminin binding to α-DG caused by a mutation in the Large1 glycosyltransferase result in a dramatic reduction of the expression of AQP4 and Kir4.1 at perivascular astrocyte endfeet (6, 7, 12–15). The mislocalization of AQP4 in the dystrophin mutant and α-syntrophin null mice results in delayed onset of brain edema and K⁺ clearance (16–18). Collectively, these studies highlight a cooperative role of the ECM and both the extracellular and cytoplasmic components of the DAP complex in the proper targeting of proteins to functional domains of astrocytes leading to the regulation of electrolyte balance and fluid movement.Although the role of DG in targeting other members of the DAP complex (6) as well as AQP4 and Kir4.1 to astrocyte endfeet has been well established (12), the mechanisms underlying this highly organized distribution remain poorly understood. In C2C12 myotubes, agrin triggers AChR clustering, a DG-dependent process, through the coalescence of lipid rafts, which is necessary for proper AChR gating functions (19–21). In oligodendrocytes, laminin induces the relocalization of α6β1 integrin to lipid rafts containing PDGFαR, thereby providing a potential mechanism for the incorporation of cell survival signals (22). Lipid rafts are defined as small (10–200 nm), heterogeneous, highly dynamic, sterol- and sphingolipid-enriched domains that compartmentalize cellular processes. These small rafts can sometimes be stabilized to form larger platforms through protein-protein and protein-lipid interactions (23). Indeed, the immunological synapse is a good example where rafts are brought together to form large functional membrane domains (24). At the immunological synapse, agrin induces the clustering of lipid rafts and their colocalization with CD3 and CD28 complex surface antigens as well as with Lck tyrosine kinase leading to T cell activation (24). Together, these studies provide evidence for a functional role of ligand-induced clustering of lipid rafts.We have previously shown that laminin induces the coclustering of the DAP complex with Kir4.1 and AQP4 in glial cell cultures (8, 25). Moreover, in vivo studies have shown that the perivascular localization of these channels and several components of the DAP complex at astrocyte endfeet require the interaction of laminin with α-DG (6, 12). In light of these data we asked whether lipid rafts contribute to the laminin-DG-dependent compartmentalization of the DAP complex and AQP4 to key active domains of astrocytes. We show here using fluorescently labeled cholera toxin subunit B (CtxB), a common marker for GM1-containing lipid rafts, that laminin induces a dramatic reorganization of GM1 into large clusters or macrodomains that colocalize extensively with components of the DAP complex in cortical astrocyte cultures. Laminin-mediated clustering of AQP4 is dependent both on cholesterol-sensitive lipid rafts and the DAP complex bringing novel insight into ECM-dependent membrane domain organization and the mechanisms underlying the polarized distribution of these proteins in astrocytes.     

Entrapment of intracytosolic bacteria by septin cage-like structures

Actin-based motility is used by various pathogens for dissemination within and between cells. Yet host factors restricting this process have not been identified. Septins are GTP-binding proteins that assemble as filaments and are essential for cell division. However, their role during interphase has remained elusive. Here, we report that septin assemblies are recruited to different bacteria that polymerize actin. We observed that intracytosolic Shigella either become compartmentalized in septin cage-like structures or form actin tails. Inactivation of septin caging increases the number of Shigella with actin tails and enhances cell-to-cell spread. TNF-α, a host cytokine produced upon Shigella infection, stimulates septin caging and restricts actin tail formation and cell-to-cell spread. Finally, we show that septin cages entrap bacteria targeted to autophagy. Together, these results reveal an unsuspected mechanism of host defense that restricts dissemination of invasive pathogens.     

Different Types of Door-Opening Motions as Contributing Factors to Containment Failures in Hospital Isolation Rooms

Hospital isolation rooms are vital for the containment (when under negative pressure) of patients with, or the protection (when under positive pressure) of patients, from airborne infectious agents. Such facilities were essential for the management of highly contagious patients during the 2003 severe acute respiratory syndrome (SARS) outbreaks and the more recent 2009 A/H1N1 influenza pandemic. Many different types of door designs are used in the construction of such isolation rooms, which may be related to the space available and affordability. Using colored food dye as a tracer, the qualitative effects of door-opening motions on the dissemination of potentially contaminated air into and out of a single isolation room were visualized and filmed using Reynolds-number-equivalent, small-scale, water-tank models fitted with programmable door-opening and moving human figure motions. Careful scaling considerations involved in the design and construction of these water-tank models enabled these results to be accurately extrapolated to the full-scale situation. Four simple types of door design were tested: variable speed single and double, sliding and hinged doors, in combination with the moving human figure. The resulting video footage was edited, synchronized and presented in a series of split-screen formats. From these experiments, it is clear that double-hinged doors pose the greatest risk of leakage into or out of the room, followed by (in order of decreasing risk) single-hinged, double-sliding and single-sliding doors. The relative effect of the moving human figure on spreading any potential contamination was greatest with the sliding doors, as the bulk airflows induced were large relative to those resulting from these door-opening motions. However, with the hinged doors, the airflows induced by these door-opening motions were significantly greater. Further experiments involving a simulated ventilated environment are required, but from these findings alone, it appears that sliding-doors are far more effective for hospital isolation room containment.     

Airflow Dynamics of Human Jets: Sneezing and Breathing - Potential Sources of Infectious Aerosols

Natural human exhalation flows such as coughing, sneezing and breathing can be considered as ‘jet-like’ airflows in the sense that they are produced from a single source in a single exhalation effort, with a relatively symmetrical, conical geometry. Although coughing and sneezing have garnered much attention as potential, explosive sources of infectious aerosols, these are relatively rare events during daily life, whereas breathing is necessary for life and is performed continuously. Real-time shadowgraph imaging was used to visualise and capture high-speed images of healthy volunteers sneezing and breathing (through the nose – nasally, and through the mouth - orally). Six volunteers, who were able to respond to the pepper sneeze stimulus, were recruited for the sneezing experiments (2 women: 27.5±6.36 years; 4 men: 29.25±10.53 years). The maximum visible distance over which the sneeze plumes (or puffs) travelled was 0.6 m, the maximum sneeze velocity derived from these measured distances was 4.5 m/s. The maximum 2-dimensional (2-D) area of dissemination of these sneezes was 0.2 m². The corresponding derived parameter, the maximum 2-D area expansion rate of these sneezes was 2 m²/s. For nasal breathing, the maximum propagation distance and derived velocity were 0.6 m and 1.4 m/s, respectively. The maximum 2-D area of dissemination and derived expansion rate were 0.11 m² and 0.16 m²/s, respectively. Similarly, for mouth breathing, the maximum propagation distance and derived velocity were 0.8 m and 1.3 m/s, respectively. The maximum 2-D area of dissemination and derived expansion rate were 0.18 m² and 0.17 m²/s, respectively. Surprisingly, a comparison of the maximum exit velocities of sneezing reported here with those obtained from coughing (published previously) demonstrated that they are relatively similar, and not extremely high. This is in contrast with some earlier estimates of sneeze velocities, and some reasons for this difference are discussed.     

Monophosphothreonyl extracellular signal-regulated kinases 1 and 2 (ERK1/2) are formed endogenously in intact cardiac myocytes and are enzymically active

ERK1 and ERK2 (ERK1/2) are central to the regulation of cell division, growth and survival. They are activated by phosphorylation of the Thr- and the Tyr- residues in their Thr-Glu-Tyr activation loops. The dogma is that dually-phosphorylated ERK1/2 constitute the principal activities in intact cells. We previously showed that, in neonatal rat cardiac myocytes, endothelin-1 and phorbol 12-myristate 13-acetate (PMA) powerfully and rapidly (maximal at ~ 5 min) activate ERK1/2. Here, we show that dually-phosphorylated ERK1/2 rapidly (< 2 min) appear in the nucleus following stimulation with endothelin-1. We characterized the active ERK1/2 species in myocytes exposed to endothelin-1 or PMA using MonoQ FPLC. Unexpectedly, two peaks of ERK1 and two peaks of ERK2 activity were resolved using in vitro kinase assays. One of each of these represented the dually-phosphorylated species. The other two represented activities for ERK1 or ERK2 which were phosphorylated solely on the Thr- residue. Monophosphothreonyl ERK1/2 represented maximally ~ 30% of total ERK1/2 activity after stimulation with endothelin-1 or PMA, and their k_cat values were estimated to be minimally ~ 30% of the dually-phosphorylated species. Appearance of monophosphothreonyl ERK1/2 was rapid but delayed in comparison with dually-phosphorylated ERK1/2. Of 10 agonists studied, endothelin-1 and PMA were most effective in terms of ERK1/2 activation and in stimulating the appearance of monophosphothreonyl and dually-phosphorylated ERK1/2. Thus, enzymically active monophosphothreonyl ERK1/2 are formed endogenously following activation of the ERK1/2 cascade and we suggest that monophosphothreonyl ERK1/2 arise by protein tyrosine phosphatase-mediated dephosphorylation of dually-phosphorylated ERK1/2.