Orisa J. Igwe scite author profile

We recently demonstrated that conditioned media (CM) from osteocytes enhances myogenic differentiation of myoblasts, suggesting that signaling from bone may be important for skeletal muscle myogenesis. The effect of CM was closely mimicked by prostaglandin E 2 (PGE 2 ), a bioactive lipid mediator in various physiological or pathological conditions. PGE 2 is secreted at high levels by osteocytes and such secretion is further enhanced under loading conditions. Although four types of receptors, EP1 to EP4, mediate PGE 2 signaling, it is unknown whether these receptors play a role in myogenesis. Therefore, in this study, the expression of EPs in mouse primary myoblasts was characterized, followed by examination of their roles in myoblast proliferation by treating myoblasts with PGE 2 or specific agonists. All four PGE 2 receptor mRNAs were detectable by quantitative real-time PCR (qPCR), but only PGE 2 and EP4 agonist CAY 10598 significantly enhance myoblast proliferation. EP1/EP3 agonist 17-phenyl trinor PGE 2 (17-PT PGE 2 ) and EP2 agonist butaprost did not have any significant effects. Moreover, treatment with EP4 antagonist L161,982 dose-dependently inhibited myoblast proliferation. These results were confirmed by cell cycle analysis and the gene expression of cell cycle regulators. Concomitant with the inhibition of myoblast proliferation, treatment with L161,982 significantly increased intracellular reactive oxygen species (ROS) levels. Cotreatment with antioxidant Nacetyl cysteine (NAC) or sodium ascorbate (SA) successfully reversed the inhibition of myoblast proliferation and ROS overproduction caused by L161,982. Therefore, PGE 2 signaling via the EP4 receptor regulates myogenesis by promoting myoblast proliferation and blocking this receptor results in increased ROS production in myoblasts.

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Toll-Like Receptor 4–Mediated Nuclear Factor Kappa B Activation Is Essential for Sensing Exogenous Oxidants to Propagate and Maintain Oxidative/Nitrosative Cellular Stress

Karki

Igwe

2013

PLoS ONE

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The mechanism(s) by which cells can sense exogenous oxidants that may contribute to intracellular oxidative/nitrosative stress is not clear. The objective of this study was to determine how cells might respond to exogenous oxidants to potentially initiate, propagate and/or maintain inflammation associated with many human diseases through NF-κB activation. First, we used HEK-Blue cells that are stably transfected with mouse toll-like receptor 4 (mTLR4) or mouse TLR2. These cells also express optimized secreted embryonic alkaline phosphatase (SEAP) reporter gene under the control of a promoter inducible by NF-κB transcription factor. These cells were challenged with their respective receptor-specific ligands, different pro-oxidants and/or inhibitors that act at different levels of the receptor signaling pathways. A neutralizing antibody directed against TLR4 inhibited responses to both TLR4-specific agonist and a prooxidant, which confirmed that both agents act through TLR4. We used the level of SEAP released into the culture media due to NF-κB activation as a measure of TLR4 or TLR2 stimulation. Pro-oxidants evoked increased release of SEAP from HEK-Blue mTLR4 cells at a much lower concentration compared with release from the HEK-Blue mTLR2 cells. Specific TLR4 signaling pathway inhibitors and oxidant scavengers (anti-oxidants) significantly attenuated oxidant-induced SEAP release by TLR4 stimulation. Furthermore, a novel pro-oxidant that decays to produce the same reactants as activated phagocytes induced inflammatory pain responses in the mouse orofacial region with increased TLR4 expression, and IL-1β and TNFα tissue levels. EUK-134, a synthetic serum-stable scavenger of oxidative species decreased these effects. Our data provide in vitro and related in vivo evidence that exogenous oxidants can induce and maintain inflammation by acting mainly through a TLR4-dependent pathway, with implications in many chronic human ailments.

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Hyperalgesia induced by peripheral inflammation is mediated by protein kinase C βII isozyme in the rat spinal cord

Igwe¹,

Chronwall²

2001

Neuroscience

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Toll-like receptor 4 signaling: A common pathway for interactions between prooxidants and extracellular disulfide high mobility group box 1 (HMGB1) protein-coupled activation

Zhang

Karki

Igwe

2015

Biochemical Pharmacology

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Necrotic cells passively release HMGB1, which can stimulate TLR4 in an autocrine fashion to potentially initiate “sterile” inflammation that maintains different disease states. We have shown that prooxidants can induce NF-κB activation through TLR4 stimulation. We examined whether prooxidants enhance HMGB1-induced TLR4 signaling through NF-κB activation. We used LPS-EK as a specific agonist for TLR4, and PPC and SIN-1 as in situ sources for ROS. As model systems, we used HEK-Blue cells (stably transfected with mouse TLR4), RAW-Blue™ cells (derived from murine RAW 264.7 macrophages) and primary murine macrophages from TLR4-KO mice. Both HEK-Blue and RAW-Blue 264.7 cells express optimized secreted embryonic alkaline phosphatase (SEAP) reporter under the control of a promoter inducible by NF-κB. We treated cells with HMGB1 alone and/or in conjunction with prooxidants and/or inhibitors using SEAP release as a measure of TLR4 stimulation. HMGB1 alone and/or in conjunction with prooxidants increased TNFα and IL-6 released from TLR4-WT, but not from TLR4-KO macrophages. Pro-oxidants increased HMGB1 release, which we quantified by ELISA. We used both fluorescence microscopy imaging and flow cytometry to quantify the expression of intracellular ROS. TLR4-neutralizing antibody decreased prooxidant-induced HMGB1 release. Prooxidants promoted HMGB1-induced NF-κB activation as determined by increased release of SEAP and TNF-α, and accumulation of iROS. HMGB1 (Box A), anti-HMGB1 and anti-TLR4-neutralizing pAbs inhibited HMGB1-induced NF-κB activation, but HMGB1 (Box A) and anti-HMGB1 pAb had no effect on prooxidant-induced SEAP release. The present results confirm that prooxidants enhance proinflammatory effects of HMGB1 by activating NF-κB through TLR4 signaling.

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Specific binding of substance P aminoterminal heptapeptide [SP(1-7)] to mouse brain and spinal cord membranes

et al. 1990

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Aminoterminal fragments of substance P (SP) have been previously shown to produce effects distinct, and often opposite, from those produced by the C-terminal of SP. The present investigation was initiated to determine whether N-terminal fragments interact at binding sites distinct from the neurokinin-1 (NK-1) receptor where the C-terminal sequence of SP binds with high affinity, and distinct from mu-opiate receptors, where we have previously shown the N-terminal sequence of SP to interact. A tritium-labeled aminoterminal heptapeptide of SP, 3H-SP(1-7), was synthesized, purified, and used to characterize the binding of a variety of fragments of SP and opioids in the mouse brain and spinal cord membranes. Using the reduction of SP-induced caudally directed biting and scratching behaviors as an index of biological activity, 3H-SP(1-7) was shown to be equipotent to unlabeled SP(1-7). 3H-SP(1-7) was found to bind reversibly to a saturable population of sites. Scatchard analyses of concentration-dependent saturation of binding in the brain indicated a single population of noninteracting sites with a high affinity (Kd = 2.5 nM) and a low capacity (Bmax = 29.2 fmol/mg protein). Kinetic analyses indicated an apparent dissociation equilibrium constant of 2.1 nM. Two populations of binding sites were observed in the spinal cord, one with a very high affinity (Kd = 0.03 nM) and low capacity (Bmax = 0.87 fmol/mg protein), and the other with lower affinity (Kd = 5.4 nM) and intermediate capacity (Bmax = 19.6 fmol/mg protein). Specific agonists for NK-1, NK-2, and NK-3 and delta opioid receptors, carboxyterminal fragments of SP, and a variety of other peptides did not compete at the 3H-SP(1-7) binding sites, but structurally related N-terminal peptides and (D-Ala2, NMe-Phe4, Gly-ol)-enkephalin (DAMGO) were active in displacing the ligand. The binding site for 3H-SP(1-7) appeared to be a membrane-bound complex whose specific binding was dependent on the integrity of both proteins and phospholipids. These studies are the first to characterize the binding sites for the SP N-terminal partial sequence of SP that can be generated by metabolism in vivo. The expanding body of evidence for distinct biological activities of N-terminal metabolites of SP, together with the current characterization of N-terminal binding, strongly support the existence of an N-terminal-directed SP receptor. The characteristics of SP(1-7) binding sites are consistent with those expected for an SP N-terminal receptor.

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Orisa J. Igwe

Prostaglandin E₂ promotes proliferation of skeletal muscle myoblasts via EP4 receptor activation

Toll-Like Receptor 4–Mediated Nuclear Factor Kappa B Activation Is Essential for Sensing Exogenous Oxidants to Propagate and Maintain Oxidative/Nitrosative Cellular Stress

Hyperalgesia induced by peripheral inflammation is mediated by protein kinase C βII isozyme in the rat spinal cord

Toll-like receptor 4 signaling: A common pathway for interactions between prooxidants and extracellular disulfide high mobility group box 1 (HMGB1) protein-coupled activation

Specific binding of substance P aminoterminal heptapeptide [SP(1-7)] to mouse brain and spinal cord membranes

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Orisa J. Igwe

Prostaglandin E2 promotes proliferation of skeletal muscle myoblasts via EP4 receptor activation

Toll-Like Receptor 4–Mediated Nuclear Factor Kappa B Activation Is Essential for Sensing Exogenous Oxidants to Propagate and Maintain Oxidative/Nitrosative Cellular Stress

Hyperalgesia induced by peripheral inflammation is mediated by protein kinase C βII isozyme in the rat spinal cord

Toll-like receptor 4 signaling: A common pathway for interactions between prooxidants and extracellular disulfide high mobility group box 1 (HMGB1) protein-coupled activation

Specific binding of substance P aminoterminal heptapeptide [SP(1-7)] to mouse brain and spinal cord membranes

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Prostaglandin E₂ promotes proliferation of skeletal muscle myoblasts via EP4 receptor activation