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Integrins are Mechanosensors that Modulate Human Eosinophil ActivationAhmadzai, Mohammad Mustafa 11 1900 (has links)
Eosinophils are end-point effectors of inflammation that contribute to the clinical severity of asthma. Eosinophil homing to the asthmatic lung is primarily guided by eotaxin-1, which is an eosinophil-selective chemokine. The mechanism by which eotaxin-1 augments intracellular calcium during cell migration is incompletely understood but is integral to the extravasation of eosinophils at sites of inflammation. We consequently report here that fluid shear stress, like eotaxin-1, unexpectedly activates human eosinophils in a calcium-dependent manner. We used confocal fluorescence microscopy to study calcium-handling in purified human eosinophils. Application of eotaxin-1 augmented the [Ca2+]i in a concentration-dependent manner. Pre-treatment of cells with ryanodine (10 μM) completely abolished the eotaxin-mediated calcium response, indicating that this phenomenon is dependent on Ca2+-release from the ER. Several SOCC blockers (2-APB, 100 μM; Gd3+, 10 μM; SKF-96365, 100 μM) attenuated SOCE, suggesting that these channels may directly contribute towards the eotaxin-1 calcium response in human eosinophils. In the presence of fluid-perfusion, eosinophils displayed a robust perfusion-induced calcium response (PICR) demonstrating that eosinophils are mechanically sensitive. The PICR rapidly induced adhesion and non-directional migration in eosinophils, suggesting that some hitherto unknown molecular mechanosensor permits these cells to detect and respond to changes in shear-stress. Pre-treatment of eosinophils with the non-selective tripeptide integrin receptor blocker, Arg-Gly-Asp (RGD), abrogated the PICR. The highly selective, dual α4β7/α4β1 integrin receptor blocker, CDP-323, was used to ascertain whether these highly expressed integrin subtypes mediate the PICR in eosinophils. Pre-treatment of cells with CDP-323 completely abolished the PICR, in addition to the eotaxin-mediated calcium response in a shear-dependent manner. Taken together, our results support a novel role for the α4β7/α4β1 integrin receptors as mechanosensors that directly modulate [Ca2+]i, adhesion and migration in human eosinophils. On-going experiments will seek to quantify the shear-response thresholds at which eosinophils activate and the time-course of the associated calcium response. This study suggests that the recruitment and activation of eosinophils are regulated by chemical and mechanical stimuli via overlapping, calcium-dependent signal transduction cascades. Given that the PICR is mediated by the eosinophil-specific α4β7/α4β1 integrin receptors, we conclude that integrin receptors are molecular mechanosensors that may facilitate eosinophil activation, adhesion and non-directional migration independently of, or in conjunction with, chemokine signaling. / Thesis / Master of Science in Medical Sciences (MSMS)
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Neuroinflammatory conditions upregulate Piezo1 mechanosensitive ion channel in astrocytesJayasi, Jazmine 01 December 2021 (has links)
Neuroinflammation is prevalent in neurodegenerative diseases and plays a significant role in the central nervous system (CNS) innate immunity, which is the body’s first line of defense mechanisms against invading pathogens and injuries to maintain homeostasis. However, in neurodegenerative diseases, neuroinflammation becomes persistent alongside the subsequent damage to nearby neurons and affects CNS-resident immune glial cells, such as microglia and astrocytes. Accumulating evidence suggests that neuroinflammation is mainly characterized by the excessive activation of glial cells, thus causing abnormal changes in their microenvironment and release soluble factors that can promote or inhibit neuroinflammation. Currently, there is no effective treatment to cure these progressive neurological disorders. Therefore, it is critical to understand how neuroinflammation affects astroglia cell function and their biomechanical properties that change their behavior throughout disease progression. Astrocytes are the most predominant glial cell in the CNS and are critical in the development and maintenance of neuroinflammatory disorders. To date, very little is known regarding the role and specific function of Piezo1 mechanosensitive ion channel (MSC) in the CNS. Recently, Piezo1 expression was found to be upregulated in Lipopolysaccharide (LPS)-induced neuroinflammation in mouse astrocyte cultures. However, it is unknown whether the aberrant mechanical environment in astrocytes interplay with the mechanosensory function of Piezo1 and its current activity in neuroinflammatory conditions. In this study, we investigated Piezo1 mechanosensitive ionic currents by performing in vitro patch-clamp electrophysiology and calcium imaging. Our preliminary studies revealed that astrocytes derived from the mouse cerebellum stimulated with LPS or Piezo1 agonist, Yoda1, increased Ca2+ influx and further augmented when treated concurrently. We also found that electrophysiology recordings showed changes in mechanosensitive ionic currents and were comparable with our calcium imaging data indicating that MSCs are involved in neuroinflammation. Therefore, we postulated that Piezo1, a non-selective cation MSC that opens in response to mechanical force is a key mechanosensor involved in neuroinflammation by altered mechanical signals in C8-S astrocytes. Using an in vitro system of Mouse C8-S (Astrocyte type II clone), the goal of this study was to investigate if neuroinflammatory conditions upregulate Piezo1 calcium influx and current activity. We show that astrocytic Piezo1 regulates mechanotransducive release of ATP by controlling the mechanically induced calcium influx and current activation in LPS-induced astrocytes. Additionally, Piezo1 antagonist, GsMTx4 and Piezo1 siRNA significantly reduced the LPS-induced current, indicating that Piezo1 is involved in neuroinflammation. Our findings demonstrate that the activity of Piezo1 stimulated by neuroinflammatory conditions may be significant for the development of therapeutics to prevent or treat neuroinflammatory disorders and diseases.
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Droplet Interface Bilayers for Mechano-Electrical Transduction Featuring Bacterial MscL ChannelsNajem, Joseph Samih 02 December 2015 (has links)
This dissertation investigates the behavior of the Escherichia Coli mechanosensitive (MS) channel MscL, when incorporated within a droplet interface bilayer (DIB). The activity of MscL channels in an artificial DIB system is demonstrated for the first time in this document. The DIB represents a building block whose repetition can form the basis to a new class of smart materials. The corresponding stimuli-responsive properties can be controlled by the type of biomolecule incorporated into the lipid bilayer, which is in the heart of this material. In the past decade, many research groups have proven the capability of the DIB to host a wide collection of natural and engineered functional biomolecules. However, very little is known about the mechano-electrical transduction capabilities of the DIB. The research present herein specifically seeks to achieve three direct goals: 1) exploring the capabilities of the DIB to serve as a platform for mechano-electrical transduction through the incorporation of bacterial MscL channels, 2) understanding the physics of mechano-electrical transduction in the DIB through the development of theoretical models, and 3) using the developed science to regulate the response of the DIB to a mechanical stimulus.
MscL channels, widely known as osmolyte release valves and fundamental elements of the bacterial cytoplasmic membrane, react to increased tension in the membrane. In the event of hypo-osmotic shocks, several channels residing in the membrane of a small cell can generate a massive permeability response to quickly release ions and small molecules, saving bacteria from lysis. Biophysically, MscL is well studied and characterized primarily through the prominent patch clamp technique. Reliable structural models explaining MscL's gating mechanism are proposed based on its homolog's crystal structure modeling, which lead to extensive experimentation. Under an applied tension of ~10 mN/m, the closed channel which consists of a tight bundle of transmembrane helices, transforms into a ring of greatly tilted helices forming an ~8 A water-filled conductive pore. It has also been established that the hydrophobicity of the tight gate, positioned at the intersection of the inner TM1 domains, determines the activation threshold of the channel. Correspondingly, it was found that by decreasing the hydrophobicity of the gate, the tension threshold could be lowered. This property of MscL made possible the design of various controllable valves, primarily for drug delivery purposes. For all the aforementioned properties and based on its fundamental role of translating cell membrane excessive tensions into electrophysiological activities, MscL makes a great fit as a mechanoelectrical transducer in DIBs.
The approach presented in this document consists of increasing the tension in the lipid bilayer interface through the application of a dynamic mechanical stimulus. Therefore, a novel and simple experimental apparatus is assembled on an inverted microscope, consisting of two micropipettes (filled with PEG-DMA hydrogel) containing Ag/AgCl wires, a cylindrical oil reservoir glued on top of a thin acrylic sheet, and a piezoelectric oscillator actuator. By using this technique, dynamic tension can be applied by oscillating one droplet, producing deformation of both droplets and area changes of the DIB interface. The tension in the artificial membrane will cause the MS channels to gate, resulting in an increase in the conductance levels of the membrane. The increase in bilayer tension is found to be equal to the sum of increase in tensions in both contributing monolayers. Tension increase in the monolayers occurs due to an increase in surface area of the constant volume aqueous droplets supporting the bilayer.
The results show that MS channels are able to gate under an applied dynamic tension. Interestingly, this work has demonstrated that both electrical potential and surface tension need to be controlled to initiate mechanoelectric coupling, a property previously not known for ion channels of this type. Gating events occur consistently at the peak compression, where the tension in the bilayer is maximal. In addition, the experiments show that no activity occurred at low amplitude oscillations (< 62.5um). These two findings basically present an initial proof that gating is occurring and is due to the mechanical excitation, not just a random artifact. The role of the applied potential is also highlighted in this study, where the results show that no gating happens at potentials lower that 80 mV. The third important observation is that the frequency of oscillation has an important impact of the gating probability, where no gating is seen at frequencies higher than 1 Hz or lower than 0.1 Hz.
Each of the previous observations is addressed separately in this research. It was found that the range of frequencies to which MscL would respond to in a DIB could be widened by using asymmetrical sinusoidal signals to stimulate the droplets. By increasing the relaxation time and shorting the compression time, a change in the monolayer's surface area is achieved, thus higher tension increase in the bilayer. It was also found that a high membrane potential assists in the opening of MscL as the droplets are stimulated. This is due to the sensitivity of MscL to the polarity of the signal. By using the right polarity the channel could be regulated to become more susceptible to opening, even at tensions lower than the threshold.
Finally, it was demonstrated, for the first time, that MscL would gate in asymmetric bilayers without the need to apply a high external potential. Asymmetric bilayers, which are usually composed from different lipids in each leaflet, generate an asymmetric potential at the membrane. This asymmetric potential is proven to be enough to cause MscL to gate in DIBs upon stimulation. / Ph. D.
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The pharmacology of the mechanosensitive channels of Escherichia coliNguyen, Thom Ngoc Minh January 2007 (has links)
Mechanosensitive (MS) channels are a class of ion channels which are gated by membrane stretch. The mechanosensitive channel of large conductance (MscL) of the bacterium E.coli has become a prototype MS channel for studying structure-function relationships in this class of ion channels. MscL homologues have commonly been found in Gram-negative and Gram-positive bacterial strains forming a sub-family of a larger family of MS class of ion channels encompassing prokaryotes (bacteria and archaea) as well as cell-walled eukaryotes (fungi and plants). MscL and its homologues have been found to play an important role in osmoregulation of bacterial cells. Though the MS channels of bacteria have been thoroughly studied, little is known about the pharmacology of these channels. This thesis has one general aim, that is, to identify compounds which are able to gate and/or alter the gating of the MS channels of bacteria in particular, the MscL of E. coli. Using the patch-clamp technique, potential compounds mostly identified via in-silico techniques were examined to observe the effects on MscL reconstituted in artificial lipid membranes and MscS in giant bacterial spheroplasts. The compounds were tested for the ability to spontaneously gate the MscL and MscS and/or alter the Boltzmann distribution parameters of the MscL, indicative of an effect on the gating of MscL. Compounds showing potential as MscL activators were then examined for in-vivo effects using different growth assays. The effects of parabens, gallates, eriochrome cyanine R, brilliant green, deoxycholic acid are reported. Of these compounds, parabens and eriochrome cyanine R showed the most encouraging results. Identification of MS channel gate ligands not only benefits structural studies as tetrodotoxin has for the voltage-sensitive sodium channel, these compounds could also V potentially serve as base compounds for novel antibiotics which would target the MS channels of bacteria. Since the MS channels of bacteria serve as safety valves for the bacterium, gating during exposure to a hypo-osmotic challenge such as rain to release excessive cellular turgor, a pharmacological agent that could impair the gating of the MS channels releasing essential cytoplasmic osmolytes, would cause the growth impairment or death of the bacterium. With the rise in multi-drug resistant bacteria, continual development of novel antibiotics is crucial.
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The role of mechanosensitve ion channels during zebrafish heart regeneration / Le rôle des canaux ioniques mécanosensibles dans la régénartion cardiovasculaire chez le poisson zèbreNasr, Nathalie 23 February 2018 (has links)
Chez l'Homme, la plupart des maladies cardio-vasculaires provoquent une destruction du tissu cardiaque. Ce dernier est remplacé par de la fibrose conduisant à une diminution de la fonction contractile et une augmentation de la charge ventriculaire avec des risques d’arythmie. Pour maintenir un débit cardiaque constant, les cardiomyocytes vont alors s’hypertrophier, induisant sur le long terme le développement une insuffisance cardiaque. L’augmentation de la charge ventriculaire pourrait être perçue par des mécanosenseurs tels que les canaux ioniques mecanosensibles TREK-1. Contrairement aux mammifères adultes, le cœur du poisson zèbre se régénère suite à une destruction massive du ventricule. Cette régénération se fait par un mécanisme de dédifférenciation, suivie d'une étape de prolifération des cardiomyocytes. Chez les mammifères adultes, la prolifération des cardiomyocytes pourrait être bloquée / inhibée empêchant ainsi la régénération. L’hypothèse que les gènes responsables de l’hypertrophie pathologique chez les mammifères adultes suite à l’augmentation de la charge ventriculaire, soient également responsables la prolifération des cardiomyocytes au cours de la régénération cardiaque chez le poisson zèbre est ainsi consistante. Cette étude, a montré que les canaux TREK-1a et TREK-1b du poisson zèbre possèdent des propriétés biophysiques et pharmacologiques, similaires à ceux du canal TREK-1 de mammifères, et qu’ils jouent un rôle fondamental dans la régénération cardiaque. / In humans, most cardiovascular disorders lead to the destruction of cardiac tissue which will be replaced by fibrosis, leading to arrhythmia and reduced contractile function, resulting in an increase in ventricular load. In order to maintain an overall cardiac output, cardiomyocytes undergo hypertrophic response, leading to pathological hypertrophy and heart failure. This increase in ventricular load, have to be sensed by mechanosensors such as the mechanosensitive ion channels such as TREK-1. Unlike mammals, adult zebrafish (zf) can fully regenerate their heart after an extensive insult through cardiomyocyte dedifferentiation followed by proliferation. We believe that in adult mammals, cardiomyocyte proliferation has been blocked/inhibited. Therefore it’s likely that genes which respond to increased ventricular load in mammals and trigger pathological hypertrophy will trigger cardiomyocyte proliferation during heart regeneration in zf. In this study we show that zTREK1a and zTREK1b have similar biophysical and pharmacological properties to mammalian TREK1 and they are important for successful zebrafish heart regeneration.
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Novel Extrinsic and Intrinsic Factors Mediating OsteoarthritisKara A Negrini (8102609) 08 May 2020 (has links)
<p>Osteoarthritis (OA) is a leading
cause of disability globally, with higher incidence in older people and lower
socioeconomic status populations. The challenges health care systems face with
management of the disease highlights the importance of OA research. Many
studies examine possible risk factors of knee and hip OA including obesity,
smoking, and alcohol consumption. Findings support that while obesity increases
risk of knee OA, smoking is not a major risk factor. These extrinsic factors are,
however, associated with lower socioeconomic status, and also with anxiety and
depression disorders. Up to 30% of patients with chronic knee OA have described
psychological stress and decreased quality of life due to debilitating pain,
but the effects of psychological stress on development of knee OA has not been
described.</p><p><br></p><p>At the cellular level, mechanosensitive cation channels in
cartilage and bone, are involved with OA, but studies looking specifically at
synovium and joint capsule are limited. Transient receptor potential (TRP)
channels are upregulated in joint capsule in end-stage primary shoulder OA. We
were unable to identify any previous studies evaluating Piezo channel
expression in musculoskeletal soft tissues, but Piezo channel antagonism reduces
chondrocyte death after mechanical injury. These findings suggest channels may
help regulate joint responses to repetitive loading during training or work
while also contributing to protective mechanisms within the musculoskeletal
system. The overall objective of this research was to investigate factors that impact
OA development or the disease phenotype. Two studies evaluated the following
aims: 1) demonstrate the influence of chronic psychological stress on knee OA
and overall systemic health, and 2) characterize the role of mechanosensitive
channels in the joint capsule in OA. The first study used a mouse chronic
social defeat model paired with destabilization of the medial meniscus (DMM)
surgery to create a social stress scenario during OA development. We
hypothesized chronic social defeat would exacerbate knee OA structural changes
and systemic inflammation. The second study aimed to explore the role of
mechanosensitive channels in joint capsule during OA development in the equine.
Immunohistochemistry was performed on forelimb fetlock joint capsule from
horses with varying degrees of lameness to first identify TRP and Piezo channel
expression. Next, fibroblasts were isolated from the tissue to determine
channel activity. We hypothesized that TRP and Piezo channels are required for
normal homeostasis, but are dysregulated in OA and dysregulation contributes to
fibrosis of the joint capsule. Joint capsule fibrosis leads to joint stiffening
and reduced range of motion, two of the cardinal signs of OA.</p><p><br></p><p>The results of the first study showed OA was induced to a
similar extent in both groups of mice that underwent DMM surgery. While
anxiety- and depressive-like behaviors were exhibited by mice that underwent
chronic social defeat episodes, unexpectedly, the majority of systemic
inflammatory markers were not worse in mice with DMM and chronic social defeat
compared to DMM alone. We were also able to show TRP and Piezo channel expression
in one normal dorsal and palmar fetlock joint capsule sample, however, COVID-19
prevented further investigation. With our results we were able to conclude that
while chronic social stress influences development of OA, in the current
experiments, neither systemic inflammation nor structural signs of knee OA were
worse with chronic social stress. We hope that exploration of OA through these
two studies will help us understand how the disease contributes to overall
systemic dysfunction while also providing a baseline for future development of TRP
and Piezo channel modulators to prevent joint pathologies.</p>
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Mechanosensitive Ion Channels as Biophysical Sensors of Muscle Satellite Cells / 筋衛星細胞における機械受容イオンチャネルに関する研究Hirano, Kotaro 23 March 2023 (has links)
京都大学 / 新制・課程博士 / 博士(工学) / 甲第24637号 / 工博第5143号 / 新制||工||1982(附属図書館) / 京都大学大学院工学研究科合成・生物化学専攻 / (主査)教授 森 泰生, 教授 浜地 格, 教授 跡見 晴幸 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DGAM
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ROLE OF THE MECHANOSENSITIVE ION CHANNEL TRPV4 IN ANGIOGENESISThoppil, Roslin Joseph 24 April 2015 (has links)
No description available.
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Mécanotransduction dans les neurones sensoriels de mammifèresHao, Jizhe 08 December 2011 (has links)
La mécanotransduction correspond à un processus dans lequel la force physique est convertie en signal chimique ou électrique. Ce processus est à la base de nombreuses fonctions physiologiques, y compris le sens du toucher, l’audition, la proprioception et la nociception. Nous ne connaissons pas à ce jour les mécanismes moléculaires à l’origine de la diversité fonctionnelle des mécanorécepteurs. L’objectif de thèse était de fournir 1 caractérisation des canaux mécanosensibles des neurones sensoriels afin d’identifier les mécanismes responsables des propriétés des mécanorécepteurs. 4 types de courants excitateurs ont été identifiés et classés sur la base de leurs cinétiques de relaxation: des courants à relaxation rapide, intermédiaire, lente ou ultra-lente. La relaxation résulte de l’adaptation et de l’inactivation. Nous montrons également que ces courants mécanosensibles possèdent des propriétés spécifiques permettant le codage des différents paramètres du stimulus mécanique. Tous s’activent graduellement en fonction de l’intensité du stimulus mécanique, mais seuls les courants à relaxation lente et ultralente informent sur la persistance du stimulus. A contrario, les courants à relaxation rapide et intermédiaire sont mis en jeu essentiellement par des stimulations rapides, ils traduisent donc la rapidité d’installation du stimulus. Nous avons ensuite identifié un nouveau courant mécanosensible potassique (IKmech) exerçant un effet inhibiteur sur la décharge des mécanorécepteurs. Le profil pharmacologique et les travaux menés sur des souris KO et transgéniques montrent que le courant IKmech est porté par la sous-unité Kv1.1 qui est mécano-susceptible via un mécanisme par lequel la pression altère la sensibilité au potentiel des canaux. En s’opposant aux courants excitateurs, le courant IKmech régule le seuil de décharge des mécano-nocicepteurs et la fréquence de décharge des mécanorécepteurs non nociceptifs. / The somatosensory system mediates fundamental physiological functions, including the senses of touch, pain and proprioception. The aim of my thesis was to understand molecular mechanism of mechanotransduction in mammalian sensory neurons.We identified 4 types of mechanotransducer currents that distribute differentially in cutaneous nociceptors and mechanoreceptors and that differ in desensitization rates. Desensitization of mechanotransducer channels in mechanoreceptors was fast and mediated by channel inactivation and adaptation, which reduces the mechanical force sensed by the transduction channel. Both processes were promoted by negative voltage. These properties of mechanotransducer channels suited them to encode the dynamic parameters of the stimulus. In contrast, inactivation and adaptation of mechanotransducer channels in nociceptors had slow time courses and were suited to encode duration of the stimulus. Thus, desensitization properties of mechanotransducer currents relate to their functions as sensors of phasic and tonic stimuli and enable sensory neurons to achieve efficient stimulus representation.In the second work, we explored the molecular determinants of threshold differences and temporal adaptation among mammalian mechanoreceptors. We identified a novel mechanosensitive K+ current (IKmech) in different classes of mechanosensory neurons from mouse and rat DRGs. IKmech activates slowly in response to mechanical stimulation and is carried by Kv1.1 subunit-containing K+ channels. By antagonizing depolarizing drive induced by excitatory MS currents, IKMech regulates threshold for noxious mechano-perception and temporal adaptation in non-painful mechanosensation. Our work has identified Kv1.1 as an essential molecular element in defining the threshold range of mechanical sensitivity and temporal responses of fibers associated with mechanical perception.
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To Hear Without and Ear: Mechanosensation in PlantsParet, Taylor York January 2017 (has links)
No description available.
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