Roles of syndecan-4 and relative kinases in dorsal root ganglion neuron adhesion and mechanotransduction
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Mechanotransduction
Neurite
Dorsal root ganglion
Syndecan 1
Abstract Caldendrin is a Ca 2+ binding protein that interacts with multiple effectors, such as the Ca v 1 L-type Ca 2+ channel, which play a prominent role in regulating the outgrowth of dendrites and axons ( i.e ., neurites) during development and in response to injury. Here, we investigated the role of caldendrin in Ca v 1-dependent pathways that impinge upon neurite growth in dorsal root ganglion neurons (DRGNs). By immunofluorescence, caldendrin was localized in medium- and large- diameter DRGNs. Compared to DRGNs cultured from WT mice, DRGNs of caldendrin knockout (KO) mice exhibited enhanced neurite regeneration and outgrowth. Strong depolarization, which normally represses neurite growth through activation of Ca v 1 channels, had no effect on neurite growth in DRGN cultures from female caldendrin KO mice. Remarkably, DRGNs from caldendrin KO males were no different from those of WT males in terms of depolarization-dependent neurite growth repression. We conclude that caldendrin opposes neurite regeneration and growth, and this involves coupling of Ca v 1 channels to growth-inhibitory pathways in DRGNs of females but not males.
Neurite
Dorsal root ganglion
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Abstract Cellular FAs (focal adhesions) respond to internal and external mechanical stresses which make them prime candidates for mechanotransduction. Recent observations showed that the FA proteins including vinculin, FAK (FA kinase) and p130Cas are crucial for the ability of cells to transmit forces and to generate cytoskeletal tension. When mechanically stimulated, cells respond by modulating the spreading area, remodel the actin cytoskeleton, activate actomyosin interactions, recruit integrins and reinforce FAs and cytoskeletal structures. These complex cellular responses are orchestrated such that mechanical stresses within the FA complex remained within a narrow range.
Mechanotransduction
Vinculin
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What is the central question of this study? Although the factors secreted from Schwann cells that promote axonal growth in the peripheral nervous system have been well studied, the effect of cell-contact factors on Schwann cells remains to be determined. What is the main finding and its importance? This study demonstrates that Schwann cells stimulate neurite outgrowth by direct contact with neurites and by secreting factors. Notably, the effect of cell-contact factors in neurite outgrowth is comparable to that of secreted factors, indicating that the identification of cell surface molecules on Schwann cells that promote neurite outgrowth could lead to development of a new therapy for peripheral nervous system injury.Schwann cells (SCs) play a variety of roles in the regeneration process after injury to the peripheral nervous system. The factors secreted from SCs that promote axonal growth have been well studied. However, the involvement of cell-contact factors on SCs remains to be determined. Here, we demonstrate a significant contribution of a cell-contact mechanism in the effect of SCs on promotion of neuronal outgrowth. Neurite outgrowth of adult sensory neurons from dorsal root ganglia was quantified during co-culture with adult SCs. Direct contact of SCs with neurons was eliminated by culturing SCs on an insert placed in the same well; this resulted in a 51% reduction in the length of neurite outgrowth. In addition, when dorsal root ganglion neurons were cultured on sparsely seeded SCs, neurons that made contact with SCs on their neurites had 118% longer neurites than neurons that lacked contacts with SCs. Collectively, these findings provide evidence that SCs stimulate neurite outgrowth via direct contact with neurites in addition to secreting factors. The identification of cell surface molecules on SCs that promote neurite outgrowth could lead to development of a new therapy for peripheral nervous system injury.
Dorsal root ganglion
Neurite
Schwann cell
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To explore effect of srGAP3 promotes neurite outgrowth of dorsal root ganglion neurons.In this study, expression of Slit1 was observed predominantly in the glia, while expression of Robo2 and srGAP3 was detected in sensory neurons of postnatal rat cultured dorsal root ganglion (DRG). Furthermore, upregulation of srGAP3 following sciatic nerve transection was detected by immunohistochemistry and Western blotting.It was observed that inhibition of neurite outgrowth in cultured adult DRG neurons following treatment with anti-srGAP3 or anti-Robo2 was more effectively (1.5-fold higher) than that following treatment with an anti-BDNF positive control antibody. It demonstrated that srGAP3 interacted with Robo2 and Slit1 protein to decrease Rac1-GTP activity in cultured adult rat DRG neurons and the opposite effect on Rac1-GTP activity was detected by co-immunoprecipitation and immunoblotting analyses following treatment with anti-Robo2 or anti-srGAP3. These data demonstrated a role for srGAP3 in neurite outgrowth of DRG sensory neurons.Our observations suggest that srGAP3 promotes neurite outgrowth and filopodial growth cones by interacting with Robo2 to inactivate Rac1 in mammalian DRG neurons.
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Abstract Mechanotransduction at focal adhesion complexes is key for various cellular events. Theoretical analyses were performed to predict a potential role of lipid membranes in modulating mechanotransduction at focal adhesions. Calculations suggest that the nanoscale geometric changes and mechanical pulling applied on lipid membranes affect the generation of cellular traction forces and signaling transduction at focal adhesions. This work provides predictions on how lipid membranes contribute to mechanotransduction at cellular focal adhesions. Significance statement Focal adhesion machinery formed across cell membranes orchestrates a variety of signaling and adhesive molecules to function for important cellular physiologies. Although there are evidences that lipid membranes are involved in mechanical transduction at focal adhesions, how the detailed mechanical response of membranes contributes to the process is not identified yet. With numerous data previously identified, predictions made by theoretical modeling suggest that the nonlinear pulling response of lipid membranes serves as a key factor to interpret mechanotransduction at focal adhesions.
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Focal Adhesion Kinase Is Important for Fluid Shear Stress-Induced Mechanotransduction in Osteoblasts
Mechanical loading of bone is important for maintenance of bone mass and structural stability of the skeleton. When bone is mechanically loaded, movement of fluid within the spaces surrounding bone cells generates fluid shear stress (FSS) that stimulates osteoblasts, resulting in enhanced anabolic activity. The mechanisms by which osteoblasts convert the external stimulation of FSS into biochemical changes, a process known as mechanotransduction, remain poorly understood. Focal adhesions are prime candidates for transducing external stimuli. Focal adhesion kinase (FAK), a nonreceptor tyrosine kinase found in focal adhesions, may play a key role in mechanotransduction, although its function has not been directly examined in osteoblasts. We examined the role of FAK in osteoblast mechanotransduction using short interfering RNA (siRNA), overexpression of a dominant negative FAK, and FAK(-/-) osteoblasts to disrupt FAK function in calvarial osteoblasts. Osteoblasts were subjected to varying periods oscillatory fluid flow (OFF) from 5 min to 4 h, and several physiologically important readouts of mechanotransduction were analyzed including: extracellular signal-related kinase 1/2 phosphorylation, upregulation of c-fos, cyclooxygenase-2, and osteopontin, and release of prostaglandin E(2). Osteoblasts with disrupted FAK signaling exhibited severely impaired mechanical responses in all endpoints examined. These data indicate the importance of FAK for both short and long periods of FSS-induced mechanotransduction in osteoblasts.
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PTK2
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The purpose of this investigation was to re-evaluate the neurotrophic effect of GPI-1046 on neurite outgrowth in vitro. GPI-1046 was synthesized and identified with mass spectrometry, nuclear magnetic resonance and elemental analysis. Chicken dorsal root ganglions (DRGs) were removed and divided into three groups: (1) The DRGs were cultured in DMEM containing different concentrations of GPI-1046; (2) The DRGs were cultured in DMEM containing nerve growth factor (NGF) alone at 0.8 and 8 ng/mL, respectively; (3) The DRGs were cultured in DMEM containing both different concentrations of GPI-1046 and NGF at 0.8 ng/mL. The results showed that GPI-1046 alone could not stimulate chicken DRG neurite outgrowth; however, GPI-1046 stimulated DRG neurite outgrowth only in the presence of NGF at low concentration in the culture medium.
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Dorsal root ganglion
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Hemodynamic forces induced by blood flow are potent regulators of vascular homeostasis and arterial structure. While previous work has focused on the role of integrin receptors in mechanotransduction, little is known about the role of cell surface proteoglycans in these processes. This work focuses specifically on the role of the cell surface heparan sulfate proteoglycan syndecan‐1 in vascular cell mechanotransduction. We isolated vascular smooth muscle cells from syndecan‐1 knockout mice and tranfected them with wild‐type and mutated forms of syndecan‐1 using lentiviral vectors. Wild‐type, syndecan‐1 knockout and mutated syndecan‐1 overexpressing mouse vascular smooth muscle cells were cultured in plates with collagen coated silicone membranes. The cells were then subjected to 10% strain at 1 Hz biaxial or uniaxial loads for up to two hours. We found that syndecan‐1 knockout or deletion of the cytoplasmic region of syndecan‐1 caused an increase in actin stress fibers and focal adhesion sites in response to mechanical strain. Further, knockout of syndecan‐1 led to enhanced ERK and Src phosphorylation in response to mechanical strain. These findings support that syndecan‐1 is an important mediator of mechanotransduction in vascular cells.
Syndecan 1
Mechanotransduction
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Neurite outgrowth in culture provides an easy way to determine the effects of a particular substrate or exogenous factor on neuron behavior. Dissociated neurons can be plated on a variety of substrates and the length of the longest neurite outgrowth can be compared. Here, we describe how to isolate and dissociate dorsal root ganglion (DRG) neurons, culture them on coverslips, and measure longest neurite outgrowth.
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Dorsal root ganglion
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Mechanotransduction at focal adhesion complexes is key for various cellular events. Theoretical analyses were performed to predict a potential role of lipid membranes in modulating mechanotransduction at focal adhesions. Calculations suggested that the size of nanostructural constraints and mechanical pulling applied on lipid membranes affect the generation of cellular traction forces and signaling transduction at focal adhesions. This work provides predictions on how lipid membranes contribute to mechanotransduction at cellular focal adhesions.
Mechanotransduction
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