The identification and characterisation of the target proteins of the anti-epileptic drug R-lacosamide

Reamtong, Onrapak

January 2010

(2R)-N-Benzyl-2-acetamido-3-methoxypropionamide (lacosamide) is an anticonvulsant (Choi et al., 1996); under the brand name "Vimpat" this small molecule has recently been approved by the European Medicines Agency and the U.S. Food and Drug Administration for the treatment of epilepsy. The purpose of the research reported here is to develop and apply mass spectrometry approaches to the determination of protein targets of this novel therapeutic. The general strategy involves selecting potential target proteins using lacosamide analogues incorporating an 'affinity bait' to enable covalent modification binding to target proteins, and a 'chemical reporter' for the selective recovery of modified proteins. Lacosamide analogues are incubated with biological samples (primarily mouse brain extracts) and the modified proteins are recovered by introduction of a biotin tag (via the chemical reporter group). Streptavidin affinity chromatography is then used to enrich for bound molecules. The enriched proteins are subjected to tryptic digestion and the resultant peptides analysed by reversed phase liquid chromatography coupled with tandem MS, enabling recognition of proteins via database searching. Firstly, mass spectrometric characterisation of the biotinyl (R)-lacosamide analogue bound to model compounds was performed. Adducts with protected lysine, neurotensin and enolase were analysed. The data showed that ESI was more suitable for ionisation of modified peptides and proteins than MALDI. The biotin enrichment strategy was applied to mouse brain lysate to identify putative candidate target proteins. Twenty-eight candidate target proteins were identified. Moreover, the 14-3-3 protein family, CRMP2 and the sodium/potassium-transporting ATPase family showed preference for the biologically active(R)- isomer over the (S)- lacosamide analogue using a fluorescence tag. Three more biotinyl lacosamide analogues containing different affinity baits were used to enrich candidate target proteins of lacosamide. Most of the identified target proteins supported the findings of the analogue A. To indicate the binding sites, a method was developed for enriching peptides modified by the biotinyl (R)-lacosamide analogue, using streptavidin beads and subsequently analysed these biotinylated peptides using CID and ETD fragmentation methods. Neither fragmentation technique was optimal for elucidation of the sequence or site of modification of unknown target peptides. Purified recombinant proteins were therefore adducted with an AB-(R)-lacosamide analogue lacking the biotinprobe. This smaller (R)-lacosamide analogue underwent less fragmentation than the biotin analogue during CID and could be used for sequence and site identification of the modified peptides. In summary, the studies illustrated the power of MS to study drug mechanisms via the discovery of candidate protein targets.

615

Mass spectrometry ; lacosamide

Electrophysiological studies on the mechanism of action of the novel antiepileptic drug lacosamide

Errington, Adam C, n/a

January 2007

Lacosamide (LCM) is a new antiepileptic drug with a previously unknown mode of action. Using electrophysiological recording techniques in a range of in vitro preparations I have determined a mechanism of action of the new drug. In a 4-aminopyridine model of tonic-clonic seizures in rat visual cortex in vitro, LCM stereoselectively reduced maximal frequency and duration of tonic activity with EC[50�s] of 71 and 41 [mu]M respectively. LCM (100 [mu]M) significantly reduced excitability in whole cell patch clamped neurons producing non-selective reduction in the incidence of excitatory/inhibitory postsynaptic currents (EPSCs; LCM: 46.1 � 15.5 %, P <0.01, n = 4, IPSCs; LCM: 24.9 � 9.6 %, P <0.01, n = 4) and block of spontaneous action potentials (EC₅₀ 61 [mu]M). The inhibitory effects of LCM did not result from changes in passive membrane properties (including resting membrane potential or input resistance) as assessed by application of voltage ramps between -70 to +20 mV. LCM did not mimic the effects of diazepam as an allosteric modulator of GABA[A] receptor currents, nor did it inhibit evoked excitatory currents mediated by AMPA or NMDA receptors. Unlike phenytoin (DPH), carbamazepine (CBZ) or lamotrigine (LTG) that blocked sustained action potential firing evoked by brief depolarising steps (750 ms) or ramps (-70 to 20 mV, 90 mV.sec⁻�), LCM could weakly reduce the frequency of action potentials evoked by brief depolarisation suggesting a potential interaction with VGSCs. In accordance with this, the effect of LCM upon neurotransmission was negated in the presence of tetrodotoxin (200 nM, TTX). The frequency of miniature EPSCs was not altered by the drug (100 [mu]M). These results discounted some crucial potential anticonvulsant targets for LCM but implied a potential interaction with electrogenic VGSCs. When SRF duration was prolonged (10 s) LCM produced significant (P <0.01, n = 4-10, EC₅₀: 48 [mu]M) inhibition, but not within the first second of the burst EC₅₀: 640 [mu]M). Evoked TTX sensitive sodium currents in N1E-115 neuroblastoma cells were significantly reduced by LCM, CBZ, LTG and DPH when V[h]: -60 mV. Hyperpolarizing pulses (500 ms) to -100 mV could reverse block by CBZ, LTG and DPH but not LCM. The V₅₀ for steady state fast inactivation was more hyperpolarized by CBZ (-79.45 � 2.64 mV, n = 5, P < 0.001), LTG (-72.30 � 1.70 mV, n = 6, P <0.05) and DPH (-77.17 � 2.32 mV, n = 6, P <0.05) but not by LCM (-65.02 � 1.75 mV, n = 6, CONTROL: -65.84 � 0.86 mV). In contrast to CBZ, LCM did not slow recovery from fast inactivation or produce frequency dependent facilitation of block of a 3 s, 10 Hz pulse train. LCM (100 [mu]M) did produce a (V₅₀: CONTROL ~64 mV, LCM -57.47 � 4.53 mV, P <0.001, n = 4-8) hyperpolarizing shift in the voltage dependence of slow sodium channel inactivation and promoted channel entry into the slow inactivated state (P <0.001, n = 6) but did not alter the rate of recovery. I therefore conclude that LCM produces inhibition of epileptiform cellular activity, at least in part, via enhancement of voltage gated sodium channel slow inactivation and represents a molecule possessing a unique anticonvulsant mechanism of action.

anticonvulsants

mechanism of action

epilepsy

chemotherapy

Lacosamide

Electrophysiological studies on the mechanism of action of the novel antiepileptic drug lacosamide

Errington, Adam C, n/a

January 2007

Lacosamide (LCM) is a new antiepileptic drug with a previously unknown mode of action. Using electrophysiological recording techniques in a range of in vitro preparations I have determined a mechanism of action of the new drug. In a 4-aminopyridine model of tonic-clonic seizures in rat visual cortex in vitro, LCM stereoselectively reduced maximal frequency and duration of tonic activity with EC[50�s] of 71 and 41 [mu]M respectively. LCM (100 [mu]M) significantly reduced excitability in whole cell patch clamped neurons producing non-selective reduction in the incidence of excitatory/inhibitory postsynaptic currents (EPSCs; LCM: 46.1 � 15.5 %, P <0.01, n = 4, IPSCs; LCM: 24.9 � 9.6 %, P <0.01, n = 4) and block of spontaneous action potentials (EC₅₀ 61 [mu]M). The inhibitory effects of LCM did not result from changes in passive membrane properties (including resting membrane potential or input resistance) as assessed by application of voltage ramps between -70 to +20 mV. LCM did not mimic the effects of diazepam as an allosteric modulator of GABA[A] receptor currents, nor did it inhibit evoked excitatory currents mediated by AMPA or NMDA receptors. Unlike phenytoin (DPH), carbamazepine (CBZ) or lamotrigine (LTG) that blocked sustained action potential firing evoked by brief depolarising steps (750 ms) or ramps (-70 to 20 mV, 90 mV.sec⁻�), LCM could weakly reduce the frequency of action potentials evoked by brief depolarisation suggesting a potential interaction with VGSCs. In accordance with this, the effect of LCM upon neurotransmission was negated in the presence of tetrodotoxin (200 nM, TTX). The frequency of miniature EPSCs was not altered by the drug (100 [mu]M). These results discounted some crucial potential anticonvulsant targets for LCM but implied a potential interaction with electrogenic VGSCs. When SRF duration was prolonged (10 s) LCM produced significant (P <0.01, n = 4-10, EC₅₀: 48 [mu]M) inhibition, but not within the first second of the burst EC₅₀: 640 [mu]M). Evoked TTX sensitive sodium currents in N1E-115 neuroblastoma cells were significantly reduced by LCM, CBZ, LTG and DPH when V[h]: -60 mV. Hyperpolarizing pulses (500 ms) to -100 mV could reverse block by CBZ, LTG and DPH but not LCM. The V₅₀ for steady state fast inactivation was more hyperpolarized by CBZ (-79.45 � 2.64 mV, n = 5, P < 0.001), LTG (-72.30 � 1.70 mV, n = 6, P <0.05) and DPH (-77.17 � 2.32 mV, n = 6, P <0.05) but not by LCM (-65.02 � 1.75 mV, n = 6, CONTROL: -65.84 � 0.86 mV). In contrast to CBZ, LCM did not slow recovery from fast inactivation or produce frequency dependent facilitation of block of a 3 s, 10 Hz pulse train. LCM (100 [mu]M) did produce a (V₅₀: CONTROL ~64 mV, LCM -57.47 � 4.53 mV, P <0.001, n = 4-8) hyperpolarizing shift in the voltage dependence of slow sodium channel inactivation and promoted channel entry into the slow inactivated state (P <0.001, n = 6) but did not alter the rate of recovery. I therefore conclude that LCM produces inhibition of epileptiform cellular activity, at least in part, via enhancement of voltage gated sodium channel slow inactivation and represents a molecule possessing a unique anticonvulsant mechanism of action.

anticonvulsants

mechanism of action

epilepsy

chemotherapy

Lacosamide

(S)-lacosamide inhibition of CRMP2 phosphorylation reduces postoperative and neuropathic pain behaviors through distinct classes of sensory neurons identified by constellation pharmacology.

Moutal, Aubin, Chew, Lindsey A, Yang, Xiaofang, Wang, Yue, Yeon, Seul Ki, Telemi, Edwin, Meroueh, Seeneen, Park, Ki Duk, Shrinivasan, Raghuraman, Gilbraith, Kerry B, Qu, Chaoling, Xie, Jennifer Y, Patwardhan, Amol, Vanderah, Todd W, Khanna, May, Porreca, Frank, Khanna, Rajesh

07 1900

Chronic pain affects the life of millions of people. Current treatments have deleterious side effects. We have advanced a strategy for targeting protein interactions which regulate the N-type voltage-gated calcium (CaV2.2) channel as an alternative to direct channel block. Peptides uncoupling CaV2.2 interactions with the axonal collapsin response mediator protein 2 (CRMP2) were antinociceptive without effects on memory, depression, and reward/addiction. A search for small molecules that could recapitulate uncoupling of the CaV2.2-CRMP2 interaction identified (S)-lacosamide [(S)-LCM], the inactive enantiomer of the Food and Drug Administration-approved antiepileptic drug (R)-lacosamide [(R)-LCM, Vimpat]. We show that (S)-LCM, but not (R)-LCM, inhibits CRMP2 phosphorylation by cyclin dependent kinase 5, a step necessary for driving CaV2.2 activity, in sensory neurons. (S)-lacosamide inhibited depolarization-induced Ca influx with a low micromolar IC50. Voltage-clamp electrophysiology experiments demonstrated a commensurate reduction in Ca currents in sensory neurons after an acute application of (S)-LCM. Using constellation pharmacology, a recently described high content phenotypic screening platform for functional fingerprinting of neurons that uses subtype-selective pharmacological agents to elucidate cell-specific combinations (constellations) of key signaling proteins that define specific cell types, we investigated if (S)-LCM preferentially acts on certain types of neurons. (S)-lacosamide decreased the dorsal root ganglion neurons responding to mustard oil, and increased the number of cells responding to menthol. Finally, (S)-LCM reversed thermal hypersensitivity and mechanical allodynia in a model of postoperative pain, and 2 models of neuropathic pain. Thus, using (S)-LCM to inhibit CRMP2 phosphorylation is a novel and efficient strategy to treat pain, which works by targeting specific sensory neuron populations.

CaV2.2

CRMP2

(S)-lacosamide

Constellation pharmacology

Calcium imaging

Postoperative pain

Neuropathic pain

Involvement of Collapsin Response Mediator Protein 2 in Posttraumatic Sprouting in Acquired Epilepsy

Wilson, Sarah Marie

January 2014

Indiana University-Purdue University Indianapolis (IUPUI) / Posttraumatic epilepsy, the development of temporal lobe epilepsy (TLE) following traumatic brain injury, accounts for 20% of symptomatic epilepsy. Reorganization of mossy fibers within the hippocampus is a common pathological finding of TLE. Normal mossy fibers project into the CA3 region of the hippocampus where they form synapses with pyramidal cells. During TLE, mossy fibers are observed to innervate the inner molecular layer where they synapse onto the dendrites of other dentate granule cells, leading to the formation of recurrent excitatory circuits. To date, the molecular mechanisms contributing to mossy fiber sprouting are relatively unknown. Recent focus has centered on the involvement of tropomycin-related kinase receptor B (TrkB), which culminates in glycogen synthase kinase 3β (GSK3β) inactivation. As the neurite outgrowth promoting collapsin response mediator protein 2 (CRMP2) is rendered inactive by GSK3β phosphorylation, events leading to inactivation of GSK3β should therefore increase CRMP2 activity. To determine the involvement of CRMP2 in mossy fiber sprouting, I developed a novel tool ((S)-LCM) for selectively targeting the ability of CRMP2 to enhance tubulin polymerization. Using (S)-LCM, it was demonstrated that increased neurite outgrowth following GSK3β inactivation is CRMP2 dependent. Importantly, TBI led to a decrease in GSK3β-phosphorylated CRMP2 within 24 hours which was secondary to the inactivation of GSK3β. The loss of GSK3β-phosphorylated CRMP2 was maintained even at 4 weeks post-injury, despite the transience of GSK3β-inactivation. Based on previous work, it was hypothesized that activity-dependent mechanisms may be responsible for the sustained loss of CRMP2 phosphorylation. Activity-dependent regulation of GSK3β-phosphorylated CRMP2 levels was observed that was attributed to a loss of priming by cyclin dependent kinase 5 (CDK5), which is required for subsequent phosphorylation by GSK3β. It was confirmed that the loss of GSK3β-phosphorylated CRMP2 at 4 weeks post-injury was likely due to decreased phosphorylation by CDK5. As TBI resulted in a sustained increase in CRMP2 activity, I attempted to prevent mossy fiber sprouting by targeting CRMP2 in vivo following TBI. While (S)-LCM treatment dramatically reduced mossy fiber sprouting following TBI, it did not differ significantly from vehicle-treated animals. Therefore, the necessity of CRMP2 in mossy fiber sprouting following TBI remains unknown.

Epilepsy

CRMP2

Posttraumatic Sprouting

GSK3beta

CDK5

Lacosamide

Epilepsy -- Research -- Analysis

Brain -- Wounds and injuries

Temporal lobe epilepsy -- Animal models

Neural transmission -- Regulation

Neural circuitry -- Adaptation

Anticonvulsants

Glycogen synthase kinase-3

Nerve tissue proteins

Brain damage

Axons -- Research

Polymerization

Cyclin-dependent kinases

Synapses

Nervous system -- Pathophysiology

Protein kinases