Your search keyword '"Adam C. Errington"' showing total 6 results

1. The transcription factor ZEB1 regulates stem cell self-renewal and cell fate in the adult hippocampus

Author

Thomas Brabletz, Florian A. Siebzehnrubl, Adam C. Errington, David Petrik, Ana Jimenez-Pascual, Simone Brabletz, Bhavana Gupta, Marc P. Stemmler, and Vasileios Eftychidis

Subjects

asymmetrical division, Epithelial-Mesenchymal Transition, QH301-705.5, Neurogenesis, Ependymoglial Cells, Symmetric cell division, Cell fate determination, Biology, Hippocampus, Article, General Biochemistry, Genetics and Molecular Biology, astrogliogenesis, Mice, neural stem cell, lineage specification, Animals, Humans, Cell Self Renewal, Biology (General), Transcription factor, Gliogenesis, Neurons, animal model, EMT, Zinc Finger E-box-Binding Homeobox 1, Cell Differentiation, Stem Cell Self-Renewal, Neural stem cell, Cell biology, gliogenesis, Cre-loxP, Stem cell

Abstract

Summary Radial glia-like (RGL) stem cells persist in the adult mammalian hippocampus, where they generate new neurons and astrocytes throughout life. The process of adult neurogenesis is well documented, but cell-autonomous factors regulating neuronal and astroglial differentiation are incompletely understood. Here, we evaluate the functions of the transcription factor zinc-finger E-box binding homeobox 1 (ZEB1) in adult hippocampal RGL cells using a conditional-inducible mouse model. We find that ZEB1 is necessary for self-renewal of active RGL cells. Genetic deletion of Zeb1 causes a shift toward symmetric cell division that consumes the RGL cell and generates pro-neuronal progenies, resulting in an increase of newborn neurons and a decrease of newly generated astrocytes. We identify ZEB1 as positive regulator of the ets-domain transcription factor ETV5 that is critical for asymmetric division., Graphical abstract, Highlights • The stem cell transcription factor, ZEB1, demarcates active from quiescent RGL cells • ZEB1 drives the self-renewal of RGL cells by promoting asymmetric cell division • Loss of Zeb1 causes increased neurogenesis and decreased astrogliogenesis • ZEB1 induces Etv5 expression to regulate asymmetric cell division, Gupta et al. show that the stem cell transcription factor, ZEB1, labels activated hippocampal stem cells and regulates their self-renewal and astroglial fate specification. Mechanistically, ZEB1 promotes asymmetric cell divisions and induces the expression of ETV5, a transcriptional regulator of asymmetric divisions and astroglial lineage commitment.

Published

2021

2. Lacosamide: Novel action mechanisms and emerging targets in epilepsy and pain

Author

George Lees and Adam C. Errington

Subjects

Lacosamide, business.industry, Drug discovery, medicine.medical_treatment, Calcium channel, Critical Care and Intensive Care Medicine, medicine.disease, Slow inactivation, Epilepsy, Anesthesiology and Pain Medicine, Mediator, Anticonvulsant, Anesthesia, Medicine, business, Signalling pathways, Neuroscience, medicine.drug

Abstract

Summary The new anticonvulsant Lacosamide ( ® Vimpat) selectively promotes slow inactivation of VGSCs, has a higher affinity for channels involved in sensory/pain transduction than CNS channels and was discovered in NIH in vivo screens. Click chemistry, the new crystal structure for VGSCs, and the profiling of related signalling pathways may further impact on drug discovery (and reveal the physiological process of slow inactivation). The surrogate binding target collapsin response mediator protein (CRMP-2) enhances lacosamide block at VGSCs. CRMP-2 also enhances N-type calcium channel (CaV2.2) expression and novel blocking peptides can reduce inflammatory pain in disease models. Mechanistic understanding and multi-disciplinary engagement is essential for cost-effective drug discovery in the quest to find safe, curative drugs in epilepsy and pain.

Published

2011

3. Seeking a mechanism of action for the novel anticonvulsant lacosamide

Author

George Lees, Leanne Coyne, Norma Selve, Thomas Stöhr, and Adam C. Errington

Subjects

Patch-Clamp Techniques, Neural Conduction, Action Potentials, Kainate receptor, AMPA receptor, In Vitro Techniques, Neurotransmission, Pharmacology, Inhibitory postsynaptic potential, Rats, Sprague-Dawley, Radioligand Assay, Cellular and Molecular Neuroscience, GABA transaminase, Lacosamide, Acetamides, Excitatory Amino Acid Agonists, Animals, Drug Interactions, Rats, Wistar, Cells, Cultured, gamma-Aminobutyric Acid, Neurons, Dose-Response Relationship, Drug, Chemistry, Brain, Neural Inhibition, Embryo, Mammalian, Rats, Animals, Newborn, Potassium, Excitatory postsynaptic potential, NMDA receptor, Anticonvulsants, Calcium, Neurotransmitter transport, Excitatory Amino Acid Antagonists

Abstract

Lacosamide (LCM) is anticonvulsant in animal models and is in phase 3 assessment for epilepsy and neuropathic pain. Here we seek to identify cellular actions for the new drug and effects on recognised target sites for anticonvulsant drugs. Radioligand binding and electrophysiology were used to study the effects of LCM at well-established mammalian targets for clinical anticonvulsants. 10 microM LCM did not bind with high affinity to a plethora of rodent, guinea pig or human receptor sites including: AMPA; Kainate; NMDA (glycine/PCP/MK801); GABA(A) (muscimol/benzodiazepine); GABA(B); adenosine A1,2,3; alpha1, alpha2; beta1, beta2; M1,2,3,4,5; H1,2,3; CB1,2; D1,2,3,4,5; 5HT1A,1B,2A,2C,3,5A,6,7 and KATP. Weak displacement (25%) was evident at batrachotoxin site 2 on voltage gated Na+ channels. LCM did not inhibit neurotransmitter transport mechanisms for norepinephrine, dopamine, 5-HT or GABA, nor did it inhibit GABA transaminase. LCM at 100 microM produced a significant reduction in the incidence of excitatory postsynaptic currents (EPSC's) and inhibitory postsynaptic currents (IPSC's) in cultured cortical cells and blocked spontaneous action potentials (EC50 61 microM). LCM did not alter resting membrane potential or passive membrane properties following application of voltage ramps between -70 to +20 mV. The voltage-gated sodium channel (VGSC) blocker phenytoin potently blocked sustained repetitive firing (SRF) but, in contrast, 100 microM LCM failed to block SRF. No effect was observed on voltage-clamped Ca2+ channels (T-, L-, N- or P-type). Delayed-rectifier or A-type potassium currents were not modulated by LCM (100 microM). LCM did not mimic the effects of diazepam as an allosteric modulator of GABA(A) receptor currents, nor did it significantly modulate evoked excitatory neurotransmission mediated by NMDA or AMPA receptors (n > or = 5). Evidently LCM perturbs excitability in primary cortical cultures but does not appear to do so via a high-affinity interaction with an acknowledged recognition site on a target for existing antiepileptic drugs.

Published

2006

4. Stereoselective effects of the novel anticonvulsant lacosamide against 4-AP induced epileptiform activity in rat visual cortex in vitro

Author

Thomas Stöhr, Adam C. Errington, and George Lees

Subjects

Male, Pentobarbital, Patch-Clamp Techniques, Lacosamide, medicine.medical_treatment, Convulsants, In Vitro Techniques, Neurotransmission, Pharmacology, Synaptic Transmission, Epileptogenesis, Membrane Potentials, Rats, Sprague-Dawley, Cellular and Molecular Neuroscience, Acetamides, Prohibitins, Potassium Channel Blockers, medicine, Animals, Picrotoxin, Ictal, 4-Aminopyridine, Visual Cortex, 6-Cyano-7-nitroquinoxaline-2,3-dione, Epilepsy, Neocortex, Chemistry, Rats, Electrophysiology, Carbamazepine, Ethosuximide, medicine.anatomical_structure, Anticonvulsant, 2-Amino-5-phosphonovalerate, Phenobarbital, Anticonvulsants, Female, Extracellular Space, Excitatory Amino Acid Antagonists, medicine.drug

Abstract

We examined effects of the novel anticonvulsant lacosamide and its inactive isomer (SPM 6953) in an in vitro model of epileptiform activity. Focal field potential recordings (34+/-0.2 degrees C) were obtained from 17 to 22 day old rat brain slices. Physiological synaptic transmission (fEPSP amplitude and duration) in CA1 of rat hippocampus was not significantly altered (P0.05, n = 4) by lacosamide (1 microM-1 mM). Recording from visual cortex during application of 4-aminopyridine (4-AP; 100 microM) revealed both spontaneous and evoked 'ictal like' discharges. Spontaneous ictal like discharges in the visual cortex were blocked by 100 microM carbamazepine (CBZ), 100 microM pentobarbital and 200 microM phenobarbital (PHB) but were insensitive to the anti-absence drug ethosuximide (750 microM; n = 4, P0.05). Lacosamide reduced tonic duration and maximal firing frequency with EC(50)s of 41 and 71 microM, respectively. In contrast, the S stereoisomer (100-320 microM) produced no significant effect on spontaneous ictal activity (n = 3-4, P0.05). Seizures induced by high frequency (100 Hz, 1s) stimulation were selectively reduced in amplitude by PHB (200 microM) and frequency by CBZ (100 microM; n = 6) and lacosamide (100 microM; n = 4). GABAergic negative going potentials were attenuated by CBZ (irreversible with washing) and lacosamide (reversible) but not by PHB. We conclude that lacosamide blocks 4-AP induced epileptiform activity in the visual cortex. This novel anticonvulsant drug appears to inhibit epileptogenesis (seizure spread) by interacting with a stereoselective, but as yet unidentified, target site in rodent neocortex in the mid-micromolar range.

Published

2006

5. Voltage-gated sodium channels and their roles in drug action

Author

Karen Madison, Amit Kumar, Adam C. Errington, and George Lees

Subjects

Membrane potential, Voltage-gated ion channel, business.industry, Sodium channel, Cardiac action potential, Critical Care and Intensive Care Medicine, Resting potential, Electrophysiology, Anesthesiology and Pain Medicine, Graded potential, Medicine, business, Neuroscience, Ion channel

Abstract

Summary The voltage-gated ion channels (VGICs) represent a superfamily of glycoprotein molecules that are able to form membrane spanning channels that ‘gate' in response to changes in membrane potential. This regulates ion selective fluxes on the microsecond–millisecond timescale. They are crucially involved in regulating activity in excitable cells of the CNS and in skeletal muscle fibres. VGICs are directly involved in control of cellular resting potential, neurotransmitter release, determination of spike firing threshold and initiation, propagation and shaping of action potentials. They represent a major target for local anaesthetic, anti-convulsant/analgesic and anti-arrhythmic drugs. The basic mechanism for communication of information between the cells of the CNS is the firing of action potentials. The action potential is an ‘all or none' cellular response that is highly dependent upon a range of VGICs which are transiently permeable to Na + (cation influx depolarises the cell), K + (efflux for rapid repolarisation and refractoriness) and perhaps to a lesser extent Ca 2+ ions (these are important in regulating action potential duration, contractility, transmitter release etc). In order to encode the large volume of information being processed by the CNS, action potentials are often fired in very complex and high-frequency patterns. The role of VGSCs in the control of cellular excitability and determining the pattern of cellular communication within the CNS makes them potential targets for contribution to the clinical state of anaesthesia (although this is highly controversial). In this review we will endeavour to explain the physiological roles of voltage-gated sodium channels, their molecular classification, structure and modulation by drugs.

Published

2005

6. Sodium channel inhibition by anandamide and synthetic cannabimimetics in brain

Author

Jian Zheng, Chengyong Liao, Laurence S. David, Adam C. Errington, G. Singh, Leanne Coyne, George Lees, and Russell A. Nicholson

Subjects

Male, Patch-Clamp Techniques, Cannabinoid receptor, Hydrocarbons, Fluorinated, medicine.medical_treatment, Sodium Channels, Membrane Potentials, Potassium Chloride, Sodium Channel Agonists, Mice, chemistry.chemical_compound, Drug Interactions, Batrachotoxins, Enzyme Inhibitors, Cells, Cultured, gamma-Aminobutyric Acid, Neurons, Chemistry, General Neuroscience, Brain, Anandamide, Calcium Channel Blockers, Endocannabinoid system, Biochemistry, Sodium Channel Blockers, Polyunsaturated Alkamides, Morpholines, Neurotoxins, Glutamic Acid, Arachidonic Acids, Tetrodotoxin, In Vitro Techniques, Naphthalenes, Neurotransmission, Inhibitory postsynaptic potential, Cannabinoid Receptor Modulators, medicine, Animals, Molecular Biology, Analysis of Variance, Veratridine, Binding Sites, Dose-Response Relationship, Drug, Cannabinoids, Sodium channel, Benzoxazines, Phenylmethylsulfonyl Fluoride, Animals, Newborn, Biophysics, Neurology (clinical), Cannabinoid, Endocannabinoids, Synaptosomes, Developmental Biology

Abstract

Anandamide is a prominent member of the endocannabinoids, a group of diffusible lipid molecules which influences neuronal excitability. In this context, endocannabinoids are known to modulate certain presynaptic Ca(2+) and K(+) channels, either through cannabinoid (CB1) receptor stimulation and second messenger pathway activation or by direct action. We investigated the susceptibility of voltage-sensitive sodium channels to anandamide and other cannibimimetics using both biochemical and electrophysiological approaches. Here we report that anandamide, AM 404 and WIN 55,212-2 inhibit veratridine-dependent depolarization of synaptoneurosomes (IC(50)s, respectively 21.8, 9.3 and 21.1 microM) and veratridine-dependent release of L-glutamic acid and GABA from purified synaptosomes [IC(50)s: 5.1 microM (L-glu) and 16.5 microM (GABA) for anandamide; 1.6 microM (L-glu) and 3.3 microM (GABA) for AM 404, and 12.2 (L-glu) and 14.4 microM (GABA) for WIN 55,212-2]. The binding of [3H]batrachotoxinin A 20-alpha-benzoate to voltage-sensitive sodium channels was also inhibited by low to mid micromolar concentrations of anandamide, AM 404 and WIN 55,212-2. In addition, anandamide (10 microM), AM 404 (10 microM) and WIN 55,212-2 (1 microM) were found to markedly block TTX-sensitive sustained repetitive firing in cortical neurones without altering primary spikes, consistent with a state-dependent mechanism. None of the inhibitory effects we demonstrate on voltage-sensitive sodium channels are attenuated by the potent CB1 antagonist AM 251 (1-2 microM). Anandamide's action is reversible and its effects are enhanced by fatty acid amidohydrolase inhibition. We propose that voltage-sensitive sodium channels may participate in a novel signaling pathway involving anandamide. This mechanism has potential to depress synaptic transmission in brain by damping neuronal capacity to support action potentials and reducing evoked release of both excitatory and inhibitory transmitters.

Published

2003