The Phosphatase PTPL1 Is Required for PTEN-Mediated Regulation of Apical Membrane Size.

PTEN is a tumor suppressor that is frequently lost in epithelial malignancies. A part of the tumor-suppressive properties of PTEN is attributed to its function in cell polarization and consequently its role in maintaining epithelial tissue integrity. However, surprisingly little is known about the function and regulation of PTEN during epithelial cell polarization. We used clustered regularly interspaced short palindromic repeat (CRISPR)/Cas9-mediated gene disruption to delete PTEN in intestinal epithelial Ls174T:W4 cells, which upon differentiation form a microvillus-covered apical membrane (brush border) on a part of the cell cortex, independent of cell-cell junctions. We show that loss of PTEN results in the formation of a larger brush border that, in a fraction of the cells, even spans the entire plasma membrane, revealing that PTEN functions in the regulation of apical membrane size. Depletion of the phosphatase PTPL1 resulted in a similar defect. PTPL1 interacts with PTEN, and this interaction is necessary for apical membrane enrichment of PTEN. Importantly, phosphatase activity of PTPL1 is not required, indicating that PTPL1 functions as an anchor protein in this process. Our work thus demonstrates a novel function for PTEN during cell polarization in controlling apical membrane size and identifies PTPL1 as a critical apical membrane anchor for PTEN in this process.

Rap1 signaling in endothelial barrier control.

The small G-protein Rap1 plays an important role in the regulation of endothelial barrier function, a process controlled largely by cellâ€"cell adhesions and their connection to the actin cytoskeleton. During the various stages of barrier dynamics, different guanine nucleotide exchange factors (GEFs) control Rap1 activity, indicating that Rap1 integrates multiple input signals. Once activated, Rap1 induces numerous signaling cascades, together responsible for the increased endothelial barrier function. Most notably, Rap1 activation results in the inhibition of Rho to decrease radial stress fibers and the activation of Cdc42 to increase junctional actin. This implies that Rap regulates endothelial barrier function by dual control of cytoskeletal tension. The molecular details of the signaling pathways are becoming to be elucidated.

Rasip1 mediates Rap1 regulation of Rho in endothelial barrier function through ArhGAP29.

Rap1 is a small GTPase regulating cell-cell adhesion, cell-matrix adhesion, and actin rearrangements, all processes dynamically coordinated during cell spreading and endothelial barrier function. Here, we identify the adaptor protein ras-interacting protein 1 (Rasip1) as a Rap1-effector involved in cell spreading and endothelial barrier function. Using Förster resonance energy transfer, we show that Rasip1 interacts with active Rap1 in a cellular context. Rasip1 mediates Rap1-induced cell spreading through its interaction partner Rho GTPase-activating protein 29 (ArhGAP29), a GTPase activating protein for Rho proteins. Accordingly, the Rap1-Rasip1 complex induces cell spreading by inhibiting Rho signaling. The Rasip1-ArhGAP29 pathway also functions in Rap1-mediated regulation of endothelial junctions, which controls endothelial barrier function. In this process, Rasip1 cooperates with its close relative ras-association and dilute domain-containing protein (Radil) to inhibit Rho-mediated stress fiber formation and induces junctional tightening. These results reveal an effector pathway for Rap1 in the modulation of Rho signaling and actin dynamics, through which Rap1 modulates endothelial barrier function.

Rap1 can bypass the FAK-Src-Paxillin cascade to induce cell spreading and focal adhesion formation.

We developed new image analysis tools to analyse quantitatively the extracellular-matrix-dependent cell spreading process imaged by live-cell epifluorescence microscopy. Using these tools, we investigated cell spreading induced by activation of the small GTPase, Rap1. After replating and initial adhesion, unstimulated cells exhibited extensive protrusion and retraction as their spread area increased, and displayed an angular shape that was remodelled over time. In contrast, activation of endogenous Rap1, via 007-mediated stimulation of Epac1, induced protrusion along the entire cell periphery, resulting in a rounder spread surface, an accelerated spreading rate and an increased spread area compared to control cells. Whereas basal, anisotropic, spreading was completely dependent on Src activity, Rap1-induced spreading was refractory to Src inhibition. Under Src inhibited conditions, the characteristic Src-induced tyrosine phosphorylations of FAK and paxillin did not occur, but Rap1 could induce the formation of actomyosin-connected adhesions, which contained vinculin at levels comparable to that found in unperturbed focal adhesions. From these results, we conclude that Rap1 can induce cell adhesion and stimulate an accelerated rate of cell spreading through mechanisms that bypass the canonical FAK-Src-Paxillin signalling cascade.

Ezrin is required for efficient Rap1-induced cell spreading.

The Rap family of small GTPases regulate the adhesion of cells to extracellular matrices. Several Rap-binding proteins have been shown to function as effectors that mediate Rap-induced adhesion. However, little is known regarding the relationships between these effectors, or about other proteins that are downstream of or act in parallel to the effectors. To establish whether an array of effectors was required for Rap-induced cell adhesion and spreading, and to find new components involved in Rap-signal transduction, we performed a small-scale siRNA screen in A549 lung epithelial cells. Of the Rap effectors tested, only Radil blocked Rap-induced spreading. Additionally, we identified a novel role for Ezrin downstream of Rap1. Ezrin was necessary for Rap-induced cell spreading, but not Rap-induced cell adhesion or basal adhesion processes. Furthermore, Ezrin depletion inhibited Rap-induced cell spreading in several cell lines, including primary human umbilical vein endothelial cells. Interestingly, Radixin and Moesin, two proteins with high homology to Ezrin, are not required for Rap-induced cell spreading and cannot compensate for loss of Ezrin to rescue Rap-induced cell spreading. Here, we present a novel function for Ezrin in Rap1-induced cell spreading and evidence of a non-redundant role of an ERM family member.

Validation of triage criteria for deciding which apparently inebriated persons require emergency department care.

OBJECTIVES: The sensitivity and specificity of consensus triage criteria for identifying which apparently inebriated patients could be triaged to care in a sobering centre were determined. Sensitivity and specificity for modifications to these criteria were also investigated. METHODS: Paramedics prospectively collected data on apparently inebriated persons en route to the emergency department (ED). 99 of these patients' ED charts were retrospectively reviewed to assess who actually required ED care. RESULTS: Of 99 subjects with both paramedic and ED chart data available, most were male (89%), homeless (57%) and found on the street (81%). Five were admitted and 13 others appeared to require ED care. Per consensus criteria, only 40 were eligible for triage to a sobering centre, but among those were five who appeared to require ED care (sensitivity 72%, 95% CI 47% to 90%; specificity 43%, 95% CI 32% to 55%). Paramedic opinion alone was specific (80%) but not very sensitive (39%). Lowering the pulse exclusion threshold from 130 to 83 would increase sensitivity to 100%, but decrease specificity to 22%. A simple post hoc rule excluding those with age >55 or pulse >83 from non-ED care had high sensitivity (94%) and fair specificity (61%). The consensus criteria's sensitivity and specificity varied (65-83% and 44-49%, respectively) depending on which ED services were considered optional (eg, psychiatric consultation, ECG, intravenous fluids, etc.). CONCLUSION: Most apparently inebriated individuals in this study did not require ED care, but prospective identification of these persons is difficult. A low exclusion cut-off for tachycardia may improve sensitivity.

Imaging cell death with radiolabeled annexin V in an experimental model of rheumatoid arthritis.

UNLABELLED: Rheumatoid arthritis is associated with chronic synovial inflammation due to the abnormal accumulation of macrophages and autoreactive T lymphocytes in joints. The autoreactive cells cause an inflammatory proapoptotic response to self-antigens resulting in eventual bone, cartilage, and soft-tissue loss and destruction. The goal of our study was to determine the timing and intensity of apoptosis in joints using 99mTc-labeled annexin V, an in vivo marker of apoptosis, in a murine model of immune arthritis. METHODS: We used 99mTc-annexin V and autoradiography to study the extent and severity of apoptosis in the front and rear paws of DBA/1 mice with type II collagen-induced rheumatoid arthritis. RESULTS: Compared with control values (n = 10), there was a significant (P < 0.002) nearly 3-fold increase in uptake of 99mTc-annexin V in the front foot pads, rear toes, rear foot pads, and heels at the time of maximal extremity swelling as determined by serial caliper measurements at 4 wk after inoculation with type II bovine collagen (n = 9). The front toes had a 5- to 6-fold increase in uptake compared with control values (P < 0.001). Histologic analysis revealed only scattered rare lymphocytes in the periarticular soft tissues, without joint destruction. Dual autoradiography with 125I-bovine serum albumin as a control showed that 99mTc-annexin V localization was specific. Treatment with methylprednisolone for 1 wk (n = 8) at 4 wk after immunization with type II collagen decreased 99mTc-annexin V uptake by 3- to 6-fold compared with control values (P < 0.002). CONCLUSION: 99mTc-annexin V can detect collagen-induced immune arthritis and its response to steroid therapy before joint destruction.