Engineering potent and selective analogues of GpTx-1, a tarantula venom peptide antagonist of the Na(V)1.7 sodium channel.

NaV1.7 is a voltage-gated sodium ion channel implicated by human genetic evidence as a therapeutic target for the treatment of pain. Screening fractionated venom from the tarantula Grammostola porteri led to the identification of a 34-residue peptide, termed GpTx-1, with potent activity on NaV1.7 (IC50 = 10 nM) and promising selectivity against key NaV subtypes (20× and 1000× over NaV1.4 and NaV1.5, respectively). NMR structural analysis of the chemically synthesized three disulfide peptide was consistent with an inhibitory cystine knot motif. Alanine scanning of GpTx-1 revealed that residues Trp(29), Lys(31), and Phe(34) near the C-terminus are critical for potent NaV1.7 antagonist activity. Substitution of Ala for Phe at position 5 conferred 300-fold selectivity against NaV1.4. A structure-guided campaign afforded additive improvements in potency and NaV subtype selectivity, culminating in the design of [Ala5,Phe6,Leu26,Arg28]GpTx-1 with a NaV1.7 IC50 value of 1.6 nM and >1000× selectivity against NaV1.4 and NaV1.5.

[1]  Jordan A. Wagner,et al.  From foe to friend: using animal toxins to investigate ion channel function. , 2015, Journal of molecular biology.

[2]  A. Malmberg,et al.  Global Nav1.7 Knockout Mice Recapitulate the Phenotype of Human Congenital Indifference to Pain , 2014, PloS one.

[3]  S. Waxman,et al.  Paroxysmal itch caused by gain-of-function Nav1.7 mutation , 2014, PAIN®.

[4]  Sharan K Bagal,et al.  Recent progress in sodium channel modulators for pain. , 2014, Bioorganic & medicinal chemistry letters.

[5]  K. Carlin,et al.  Studies examining the relationship between the chemical structure of protoxin II and its activity on voltage gated sodium channels. , 2014, Journal of medicinal chemistry.

[6]  J. Wood,et al.  Pain without Nociceptors? Nav1.7-Independent Pain Mechanisms , 2014, Cell reports.

[7]  G. King,et al.  Discovery of a selective NaV1.7 inhibitor from centipede venom with analgesic efficacy exceeding morphine in rodent pain models , 2013, Proceedings of the National Academy of Sciences.

[8]  A. Gibbs,et al.  Analysis of the Structural and Molecular Basis of Voltage-sensitive Sodium Channel Inhibition by the Spider Toxin Huwentoxin-IV (μ-TRTX-Hh2a) , 2013, The Journal of Biological Chemistry.

[9]  M. Bednarek,et al.  Potency optimization of Huwentoxin-IV on hNav 1.7: A neurotoxin TTX-S sodium-channel antagonist from the venom of the Chinese bird-eating spider Selenocosmia huwena , 2013, Peptides.

[10]  D. Yoshikami,et al.  Distinct disulfide isomers of μ-conotoxins KIIIA and KIIIB block voltage-gated sodium channels. , 2012, Biochemistry.

[11]  R. Stöcklin,et al.  Large-scale discovery of conopeptides and conoproteins in the injectable venom of a fish-hunting cone snail using a combined proteomic and transcriptomic approach. , 2012, Journal of proteomics.

[12]  G. King,et al.  Spider-venom peptides that target voltage-gated sodium channels: pharmacological tools and potential therapeutic leads. , 2012, Toxicon : official journal of the International Society on Toxinology.

[13]  K. Carlin,et al.  Cysteine racemization during the Fmoc solid phase peptide synthesis of the Nav1.7‐selective peptide – protoxin II , 2012, Journal of peptide science : an official publication of the European Peptide Society.

[14]  L. Poppe,et al.  PADLOC: a powerful tool to assign disulfide bond connectivities in peptides and proteins by NMR spectroscopy. , 2012, Analytical chemistry.

[15]  A. Dickenson,et al.  Distinct Nav1.7-dependent pain sensations require different sets of sensory and sympathetic neurons , 2012, Nature Communications.

[16]  Tadashi Kimura,et al.  Characterization of voltage-dependent calcium channel blocking peptides from the venom of the tarantula Grammostola rosea. , 2011, Toxicon : official journal of the International Society on Toxinology.

[17]  Xiao Mei Zheng,et al.  Identification of a potent, state-dependent inhibitor of Nav1.7 with oral efficacy in the formalin model of persistent pain. , 2011, Journal of medicinal chemistry.

[18]  A. Steiner,et al.  Optimization of oxidative folding methods for cysteine‐rich peptides: a study of conotoxins containing three disulfide bridges , 2011, Journal of peptide science : an official publication of the European Peptide Society.

[19]  K. Blumenthal,et al.  Inhibition of the activation pathway of the T-type calcium channel Ca(V)3.1 by ProTxII. , 2010, Toxicon : official journal of the International Society on Toxinology.

[20]  S. Waxman,et al.  Familial pain syndromes from mutations of the Nav1.7 sodium channel , 2010, Annals of the New York Academy of Sciences.

[21]  P. Ruben,et al.  Interaction between voltage-gated sodium channels and the neurotoxin, tetrodotoxin , 2008, Channels.

[22]  Martin Koltzenburg,et al.  ProTx-II, a Selective Inhibitor of NaV1.7 Sodium Channels, Blocks Action Potential Propagation in Nociceptors , 2008, Molecular Pharmacology.

[23]  S. Dib-Hajj,et al.  NaV1.7 Gain-of-Function Mutations as a Continuum: A1632E Displays Physiological Changes Associated with Erythromelalgia and Paroxysmal Extreme Pain Disorder Mutations and Produces Symptoms of Both Disorders , 2008, The Journal of Neuroscience.

[24]  E. Moczydlowski,et al.  Tarantula Huwentoxin-IV Inhibits Neuronal Sodium Channels by Binding to Receptor Site 4 and Trapping the Domain II Voltage Sensor in the Closed Configuration* , 2008, Journal of Biological Chemistry.

[25]  D. Macintyre,et al.  Benzazepinone Nav1.7 blockers: potential treatments for neuropathic pain. , 2007, Bioorganic & medicinal chemistry letters.

[26]  P. Lund,et al.  A stop codon mutation in SCN9A causes lack of pain sensation. , 2007, Human molecular genetics.

[27]  Brian J. Smith,et al.  Structure/Function Characterization of μ-Conotoxin KIIIA, an Analgesic, Nearly Irreversible Blocker of Mammalian Neuronal Sodium Channels* , 2007, Journal of Biological Chemistry.

[28]  D. Macintyre,et al.  Discovery of a novel class of benzazepinone Na(v)1.7 blockers: potential treatments for neuropathic pain. , 2007, Bioorganic & medicinal chemistry letters.

[29]  K. Blumenthal,et al.  Molecular interactions of the gating modifier toxin ProTx-II with NaV 1.5: implied existence of a novel toxin binding site coupled to activation. , 2007, The Journal of biological chemistry.

[30]  M. Dubé,et al.  Loss‐of‐function mutations in the Nav1.7 gene underlie congenital indifference to pain in multiple human populations , 2007, Clinical genetics.

[31]  O. Cheneval,et al.  The venom of the snake genus Atheris contains a new class of peptides with clusters of histidine and glycine residues. , 2007, Rapid Communications in Mass Spectrometry.

[32]  K. Blumenthal,et al.  ProTx-I and ProTx-II: gating modifiers of voltage-gated sodium channels. , 2007, Toxicon : official journal of the International Society on Toxinology.

[33]  Hussain Jafri,et al.  An SCN9A channelopathy causes congenital inability to experience pain , 2006, Nature.

[34]  Rachael K. Blackman,et al.  Nav1.7 Mutant A863P in Erythromelalgia: Effects of Altered Activation and Steady-State Inactivation on Excitability of Nociceptive Dorsal Root Ganglion Neurons , 2006, The Journal of Neuroscience.

[35]  O. Cheneval,et al.  Mass spectrometry strategies for venom mapping and peptide sequencing from crude venoms: case applications with single arthropod specimen. , 2006, Toxicon : official journal of the International Society on Toxinology.

[36]  M. Lazdunski,et al.  Four Novel Tarantula Toxins as Selective Modulators of Voltage-Gated Sodium Channel Subtypes , 2006, Molecular Pharmacology.

[37]  W. Catterall,et al.  Overview of Molecular Relationships in the Voltage-Gated Ion Channel Superfamily , 2005, Pharmacological Reviews.

[38]  Brian J. Smith,et al.  Novel conotoxins from Conus striatus and Conus kinoshitai selectively block TTX-resistant sodium channels. , 2005, Biochemistry.

[39]  S. Levinson,et al.  Decrease in inflammatory hyperalgesia by herpes vector-mediated knockdown of Nav1.7 sodium channels in primary afferents. , 2005, Human gene therapy.

[40]  R. French,et al.  Sodium channel toxins--receptor targeting and therapeutic potential. , 2004, Current medicinal chemistry.

[41]  G. Forlani,et al.  Nociceptor-specific gene deletion reveals a major role for Nav1.7 (PN1) in acute and inflammatory pain. , 2004, Proceedings of the National Academy of Sciences of the United States of America.

[42]  B. Ding,et al.  Mutations in SCN9A, encoding a sodium channel alpha subunit, in patients with primary erythermalgia , 2004, Journal of Medical Genetics.

[43]  S. Liang,et al.  Function and Solution Structure of Huwentoxin-IV, a Potent Neuronal Tetrodotoxin (TTX)-sensitive Sodium Channel Antagonist from Chinese Bird Spider Selenocosmia huwena * , 2002, The Journal of Biological Chemistry.

[44]  V. Garsky,et al.  Two tarantula peptides inhibit activation of multiple sodium channels. , 2002, Biochemistry.

[45]  M. Backonja Use of anticonvulsants for treatment of neuropathic pain , 2002, Neurology.

[46]  T. Jensen Anticonvulsants in neuropathic pain: rationale and clinical evidence , 2002, European journal of pain.

[47]  T. Rozen Antiepileptic Drugs in the Management of Cluster Headache and Trigeminal Neuralgia , 2001, Headache.

[48]  J. Mao,et al.  Systemic lidocaine for neuropathic pain relief , 2000, Pain.

[49]  Gordon M. Crippen,et al.  Prediction of Physicochemical Parameters by Atomic Contributions , 1999, J. Chem. Inf. Comput. Sci..

[50]  R. Norton,et al.  The cystine knot structure of ion channel toxins and related polypeptides. , 1998, Toxicon : official journal of the International Society on Toxinology.

[51]  D. Craik,et al.  A common structural motif incorporating a cystine knot and a triple‐stranded β‐sheet in toxic and inhibitory polypeptides , 1994, Protein science : a publication of the Protein Society.

[52]  T Sun,et al.  Pulsed field gradient stimulated echo methods for improved NMR diffusion measurements in heterogeneous systems , 1989 .

[53]  P. Edman,et al.  A method for the determination of amino acid sequence in peptides. , 1949, Archives of biochemistry.

[54]  A. Meir,et al.  Two tarantula venom peptides as potent and differential Na(V) channels blockers. , 2014, Toxicon : official journal of the International Society on Toxinology.

[55]  Miriam Góngora-Benítez,et al.  Optimized Fmoc solid‐phase synthesis of the cysteine‐rich peptide linaclotide , 2011, Biopolymers.

[56]  R. Stöcklin,et al.  Venom Composition and Strategies in Spiders: Is Everything Possible? , 2011 .

[57]  A. L. Goldin,et al.  Resurgence of sodium channel research. , 2001, Annual review of physiology.

[58]  Pavel A. Pevzner,et al.  De Novo Peptide Sequencing via Tandem Mass Spectrometry , 1999, J. Comput. Biol..

[59]  M. Noda,et al.  Structure and function of sodium channel. , 1987, Journal of receptor research.

[60]  H. Takeshima,et al.  Expression of functional sodium channels from cloned cDNA , 1986, Nature.

[61]  H. Niall [36] Automated edman degradation: The protein sequenator , 1973 .