Effects of Lys to Glu mutations in GsMTx4 on membrane binding, peptide orientation, and self-association propensity, as analyzed by molecular dynamics simulations

Nishizawa, Kenji; Nishizawa, Manami; Gnanasambandam, Radhakrishnan; Sachs, Frederick; Sukharev, Sergei; Suchyna, Thomas M.

doi:10.1016/j.bbamem.2015.09.003

Cited by 14 publications

(33 citation statements)

References 40 publications

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“…We predicted that this creates a reservoir of mobile surface area on one monolayer which would have the effect of clamping the tension on that monolayer which was further supported by molecular dynamic simulations (Fig. 2 and [75]). A new model of GsMTx4 inhibition is proposed where the critical factors for its inhibitory potential are how deeply it binds to relaxed membranes and its availability to transition to deeper states as tension increases.…”

Section: Gsmtx4 Mechanism Of Inhibition and Modulation Of Piezo Vs K+mentioning

confidence: 63%

Piezo channels and GsMTx4: Two milestones in our understanding of excitatory mechanosensitive channels and their role in pathology

Suchyna

2017

Progress in Biophysics and Molecular Biology

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Discovery of Piezo channels and the reporting of their sensitivity to the inhibitor GsMTx4 were important milestones in the study of non-selective cationic mechanosensitive channels (MSCs) in normal physiology and pathogenesis. GsMTx4 had been used for years to investigate the functional role of cationic MSCs, especially in muscle tissue, but with little understanding of its target or inhibitory mechanism. The sensitivity of Piezo channels to bilayer stress and its robust mechanosensitivity when expressed in heterologous systems were keys to determining GsMTx4’s mechanism of action. However, questions remain regarding Piezo’s role in muscle function due to the non-selective nature of GsMTx4 inhibition toward membrane mechanoenzymes and the implication of MCS channel types by genetic knockdown. Evidence supporting Piezo like activity, at least in the developmental stages of muscle, is presented. While the MSC targets of GsMTx4 in muscle pathology are unclear, its muscle protective effects are clearly demonstrated in two recent in situ studies on normal cardiomyocytes and dystrophic skeletal muscle. The muscle protective function may be due to the combined effect of GsMTx4’s inhibitory action on cationic MSCs like Piezo and TRP, and its potentiation of repolarizing K+ selective MSCs like K2P and SAKCa. Paradoxically, the potent in vitro action of GsMTx4 on many physiological functions seems to conflict with its lack of in situ side-effects on normal animal physiology. Future investigations into cytoskeletal control of sarcolemma mechanics and the suspected inclusion of MSCs in membrane micro/nano sized domains with distinct mechanical properties will aide our understanding of this dichotomy.

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Section: Gsmtx4 Mechanism Of Inhibition and Modulation Of Piezo Vs K+mentioning

confidence: 63%

Piezo channels and GsMTx4: Two milestones in our understanding of excitatory mechanosensitive channels and their role in pathology

Suchyna

2017

Progress in Biophysics and Molecular Biology

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“…We have shown that GsMTx4 associates superficially with membranes under low tension, and inserts deeper when membrane tension increases acting as an area/tension clamp for the outer monolayer [21,22]. Recent electron micrographic studies of the Piezo1 channel structure place the likely mechanosensing domains for these channels on the outer monolayer [59].…”

Section: Discussionmentioning

confidence: 99%

“…In vitro measures of MSC activity in cardiac tissue, single cells and patch assays, show GsMTx4 activity in the range of 0.1–5 μM [15,19,20]. GsMTx4 is a gating modifier that inhibits MSCs by clamping the membrane tension of the outer monolayer where its penetration depth, and thus its surface area contribution, is tension dependent [21,22]. …”

Section: Introductionmentioning

confidence: 99%

GsMTx4-D is a cardioprotectant against myocardial infarction during ischemia and reperfusion

Wang

Sachs

et al. 2016

Journal of Molecular and Cellular Cardiology

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GsMTx4 is a selective inhibitor of cationic mechanosensitive ion channels (MSCs) and has helped establish the role of MSCs in cardiac physiology. Inhomogeneous local mechanical stresses due to hypercontracture and swelling during ischemic reperfusion injury (IRI) likely induce elevated MSC activity that can contribute to cation imbalance. The aim of this study was to determine if the D enantiomer of GsMTx4 can act as a cardioprotectant in a mouse IRI model. Ischemia and reperfusion involved ligating a coronary artery followed by release of the ligature. GsMTx4-D was tested by either acute intravenous injection during the ischemic event or by two day pretreatment by intraperitoneal injection, both methods achieving similar results. Based on pharmacokinetic studies, GsMTx4-D dosage was set to achieve expected plasma concentrations between 50 and 5000 nM and heart tissue concentrations between 1 and 200 nM by intravenous injection. Relative to vehicle injected animals, GsMTx4-D reduced infarct area by ~40% for acute and pretreated animals for both 20 and 45 min ischemic challenges. Many indicators of cardiac output were indistinguishable from sham-treated control hearts after GsMTx4-D treatment showing improvement at both 4 and 48 h post ischemia, and premature ventricular beats immediately following reperfusion were also significantly reduced. To determine if GsMTx4-D cardioprotection could act directly at the level of cardiomyocytes, we tested its effects in vitro on indicators of IRI damage like cation influx and activation of inflammatory kinases in isolated myocytes cultured under hypoxic conditions. Hypoxia challenged cardiomyocytes treated with 10 μM GsMTx4-D showed improved contractility and near normal contraction-related Ca2+ influx. GsMTx4-D inhibited indicators of ischemic damage such as the apoptotic signaling system JNK/c-Jun, but also inhibited the energy response signaling system Akt kinase. We conclude that GsMTx4-D is a potent cardioprotectant in vivo that may act directly on cardiomyocytes and potentially be useful in multidrug strategies to treat IRI.

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“…Independent of resolution of the force field used, classical (i.e., unbiased) MD simulation are used to address questions including, but not limited to, the spontaneous binding of the peptide to the membrane surface, including conformational changes in the peptide, the penetration‐depth and orientation of the peptide at the water–lipid interface, the identification of peptide residues that control lipid binding, the effect of peptide binding on the local structure of the membrane, and the effect of lipid composition or mutations in the peptide on these properties. For pore‐forming peptides, classical MD simulations are also used to study the structure and stability of preformed pores or the first steps in pore formation …”

Section: Computational Approaches To Study Venom Peptide—membrane Intmentioning

confidence: 99%

“…Like GMs, MSC‐directed peptides are mostly disulfide‐rich peptides with a well‐defined secondary structure. Examples include the spider venom peptides GasFII, GsMTx‐2, and GsMTx‐4 . The third group are pore‐forming peptides that irreversibly damage cell membranes by a pore‐forming mechanism (Figure ).…”

Section: Introductionmentioning

confidence: 99%

Molecular simulations of venom peptide‐membrane interactions: Progress and challenges

Deplazes

2018

Peptide Science

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Because of their wide range of biological activities venom peptides are a valuable source of lead molecules for the development of pharmaceuticals, pharmacological tools and insecticides. Many venom peptides work by modulating the activity of ion channels and receptors or by irreversibly damaging cell membranes. In many cases, the mechanism of action is intrinsically linked to the ability of the peptide to bind to or partition into membranes. Thus, understanding the biological activity of these venom peptides requires characterizing their membrane binding properties. This review presents an overview of the recent developments and challenges in using biomolecular simulations to study venom peptide‐membrane interactions. The review is focused on (i) gating modifier peptides that target voltage‐gated ion channels, (ii) venom peptides that inhibit mechanosensitive ion channels, and (iii) pore‐forming venom peptides. The methods and approaches used to study venom peptide‐membrane interactions are discussed with a particular focus on the challenges specific to these systems and the type of questions that can (and cannot) be addressed using state‐of‐the‐art simulation techniques. The review concludes with an outlook on future aims and directions in the field.

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Effects of Lys to Glu mutations in GsMTx4 on membrane binding, peptide orientation, and self-association propensity, as analyzed by molecular dynamics simulations

Cited by 14 publications

References 40 publications

Piezo channels and GsMTx4: Two milestones in our understanding of excitatory mechanosensitive channels and their role in pathology

Piezo channels and GsMTx4: Two milestones in our understanding of excitatory mechanosensitive channels and their role in pathology

GsMTx4-D is a cardioprotectant against myocardial infarction during ischemia and reperfusion

Molecular simulations of venom peptide‐membrane interactions: Progress and challenges

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