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Hainantoxin

January 01, 1970

Hainantoxins (HNTX) are neurotoxins from the venom of the Chinese bird spider Haplopelma hainanum. Hainantoxins specifically inhibit tetrodotoxin-sensitive Voltage-gated sodium channels, thereby causing blockage of neuromuscular transmission and paralysis.[1][2] Currently, 13 different hainantoxins are known (HNTX-I – HNTX-XIII), but only HNTX-I, -II, -III, -IV and -V have been investigated in detail.[3]

Sources edit

HNTX-I, HNTX-III, HNTX-IV and HNTX-V are made by the Chinese bird spider Haplopelma hainanum (=Ornithoctonus hainana, Selenocosmia hainana).[1][2][4][5][6][7][8][9][10][11]

Chemistry edit

Structure edit

Hainantoxins I, III, IV and V show high homology, including the presence of three disulfide bonds that form an inhibitor cysteine knot (ICK) motif.

HNTX-I edit

The main component of the venom of O. hainana is HNTX-I.[12] It has 33 amino acid residues, with a total molecular weight of 3605-3608 Da. HNTX-I contains a short triple-stranded anti-parallel beta-sheet and four beta-turns.[4] The amino acid residues His28 and Asp26 are needed for the bioactivity of HNTX-I.[13]

HNTX-II edit

HNTX-II has a molecular weight of 4253 Da and contains 37 amino acid residues. The complete amino acid sequence of HNTX-II is NH2-LFECSV SCEIEK EGNKD CKKKK CKGGW KCKFN MCVKV-COOH.[14]

HNTX-III edit

The structure of HNTX-III consists of 33-35 amino acid residues, which form a beta-sheet with connections between Asp7 and Cys9, Tyr21 and Ser23, and Lys27 and Val30.[6][8]

HNTX-IV edit

HNTX-IV has 35 amino acid residues with a total molecular weight of 3989 Da. The first strand consists of an antiparallel beta-sheet.[11] The complete amino acid sequence of HNTX-IV is NH2-ECLGFG KGCNPS NDQCCK SSNLVC SRKHRW CKYEI-CONH2.[11] Lys 27, His28, Arg29 and Lys 32 are the neuroactive amino acid residues.[1][5][10]

HNTX-V edit

HNTX-V consists of 35 amino acid residues.[2] The whole amino acid residue sequence of HNTX-V is NH2-ECLGFG KGCNPS NDQCCK SANLVC SRKHRW CKYEI-COOH. At the active binding site of HNTX-V, Lys27 and Arg 29 are the most important.[2]

Target edit

Channel edit

Hainantoxins selectively inhibit tetrodotoxin-sensitive (TTX-S) voltage-gated sodium channels (VGSCs).[1][5][6][9] Voltage-gated Ca2+ channels (VGCCs), tetrodotoxin-resistant (TTX-R) VGSCs and rectifier-delayed potassium channels are not affected.[8] HNTX-III and HNTX-IV are part of the Huwentoxin-I family.[3][8] Toxins from the Huwentoxin-I family are thought to bind to site 1 on the sodium channels. Other hainantoxins bind at site 3 of the sodium channels. HNTX-I specifically blocks mammalian Nav1.2 and insect para/tipE channels expressed in Xenopus laevis oocytes. HNTX-I is a weak antagonist of the vertebrate TTX-S VGSCs, but is more potent on insect VGSCs.[4][10]

Affinity edit

For the blockage of sodium channels, electrostatic interactions or hydrogen bonds are needed. Important for the electrostatic interaction is the presence of a positively charged region in the toxin, because the receptor site of the sodium channel contains a lot of negatively charged residues.[1][2] In HNTX-I, the positively charged residues and a vicinal hydrophobic patch have most influence on the binding to the sodium channels.[4] HNTX-IV has a positively charged patch containing the amino acids Arg26, Lys27, His28, Arg29 and Lys32, of which Lys27, Arg29 and Lys32 are the most important for interaction with the TTX-S VGSCs.[10][15] HNTX-V also shows an interface of positively charged amino acids that are responsible for the binding with the TTX-S VGSCs, where also Lys27 and Arg29 are the most important. Subtle differences in the positively charged patch can result in altered electrostatic properties, causing altered pharmacological effects.[4]

Table 1: IC50 values of four subgroups of hainantoxins

IC50
HNTX-I 68 μM[4]
HNTX-III 1.1 nM[8]
HNTX-IV 44.6 nM[8]
HNTX-V 42.3 nM[2]

Mode of action edit

HNTX-I, HNTX-III, HNTX-IV, and HNTX-V are thought to bind to site 1 of voltage-dependent sodium channels, similar to TTX, and thereby block the channel pore. They do not alter activation and inactivation kinetics.[1][4] Ion selectivity of the VGSCs is not changed by hainantoxin.[8][9] The mode of action of HNTX-II is unclear, but is unlikely to involve sodium channels.[14]

Toxicity edit

Symptoms edit

Hainantoxins can affect both vertebrates and invertebrates. HNTX-I has no significant effect on insects or rats.[2][12] HNTX-III and HNTX-IV cause spontaneous contractions of the diaphragm muscle and the vas deferens smooth muscle of the rat.[8][9] HNTX-III and HNTX-IV are able to paralyze cockroaches, and HNTX-IV can even paralyze rats.[15]

LD50 edit

Intracerebroventricular injection in mice with HNTX-II shows a LD50 of 1.41 μg/g. The intraperitoneal LD50 value of HNTX-IV in mice is 0.2 mg/kg.[8][9] HNTX-III is 40 times more potent that HNTX-IV.[8]

Therapeutic use edit

HNTX-III and HNTX-IV have an antagonistic effect on the toxin BMK-I, a toxic protein in the venom of the scorpion Buthus martensii.[8]

References edit

  1. ^ a b c d e f Li D et al. Structure--activity relationships of hainantoxin-IV and structure determination of active and inactive sodium channel blockers. J Biol Chem. 2004 Sep 3;279(36):37734-40. Epub 2004 Jun 16.
  2. ^ a b c d e f g Xiao YC, Liang SP. Purification and characterization of Hainantoxin-V, a tetrodotoxin-sensitive sodium channel inhibitor from the venom of the spider Selenocosmia hainana. Toxicon. 2003 May;41(6):643-50.
  3. ^ a b "Family:%22huwentoxin-1 family%22 in UniProtKB".
  4. ^ a b c d e f g Li D, et al. Function and solution structure of hainantoxin-I, a novel insect sodium channel inhibitor from the Chinese bird spider Selenocosmia hainana. FEBS Lett. 2003 Dec 18;555(3):616-22.
  5. ^ a b c Xu X et al. Solid-phase synthesis and biological characterization of S12A-HNTX-IV and R29A-HNTX-IV: two mutants of hainantoxin-IV. Sheng Wu Gong Cheng Xue Bao. 2005 Jan;21(1):92-6.
  6. ^ a b c Zeng XZ et al. Sequence-specific assignment of 1H-NMR resonance and determination of the secondary structure of Jingzhaotoxin-I. Acta Biochim Biophys Sin (Shanghai). 2005 Aug;37(8):567-72.
  7. ^ Honma T et al. Novel peptide toxins from acrorhagi, aggressive organs of the sea anemone Actinia equina. Toxicon. 2005 Dec 1;46(7):768-74. Epub 2005 Sep 23.
  8. ^ a b c d e f g h i j k Xiao Y, Liang S. Inhibition of neuronal tetrodotoxin-sensitive Na+ channels by two spider toxins: hainantoxin-III and hainantoxin-IV. Eur J Pharmacol. 2003 Sep 5;477(1):1-7.
  9. ^ a b c d e Xiao YC, Liang SP. Inhibition of sodium channels in rat dorsal root ganglion neurons by Hainantoxin-IV, a novel spider toxin. Sheng Wu Hua Xue Yu Sheng Wu Wu Li Xue Bao (Shanghai). 2003 Jan;35(1):82-5.
  10. ^ a b c d Liu Y et al. A positively charged surface patch is important for hainantoxin-IV binding to voltage-gated sodium channels. J Pept Sci. 2012 Oct;18(10):643-9. doi: 10.1002/psc.2451. Epub 2012 Aug 27.
  11. ^ a b c XIONG Xia et al. Effects of Arg26 and Lys27 mutation on the bioactivity of HNTX-IV
  12. ^ a b Liu Z et al. Isolation and characterization of hainantoxin-IV, a novel antagonist of tetrodotoxin-sensitive sodium channels from the Chinese bird spider Selenocosmia hainana. Cell Mol Life Sci. 2003 May;60(5):972-8.
  13. ^ Nicholson GM. Insect-selective spider toxins targeting voltage-gated sodium channels. Toxicon. 2007 Mar 15;49(4):490-512. Epub 2006 Dec 5.
  14. ^ a b Pan J-Y, Yu Z-Q. Isolation and characterization of Hainantoxin-II, a new neurotoxic peptide from the Chinese bird spider (Haplopelma hainanum). Zool. Res. 2010 6:570-4.
  15. ^ a b Wang RL et al. Mechanism of action of two insect toxins huwentoxin-III and hainantoxin-VI on voltage-gated sodium channels. J Zhejiang Univ Sci B. 2010 Jun;11(6):451-7.

January 01, 1970
hainantoxin, hntx, neurotoxins, from, venom, chinese, bird, spider, haplopelma, hainanum, specifically, inhibit, tetrodotoxin, sensitive, voltage, gated, sodium, channels, thereby, causing, blockage, neuromuscular, transmission, paralysis, currently, different. Hainantoxins HNTX are neurotoxins from the venom of the Chinese bird spider Haplopelma hainanum Hainantoxins specifically inhibit tetrodotoxin sensitive Voltage gated sodium channels thereby causing blockage of neuromuscular transmission and paralysis 1 2 Currently 13 different hainantoxins are known HNTX I HNTX XIII but only HNTX I II III IV and V have been investigated in detail 3 Contents 1 Sources 2 Chemistry 2 1 Structure 2 1 1 HNTX I 2 1 2 HNTX II 2 1 3 HNTX III 2 1 4 HNTX IV 2 1 5 HNTX V 3 Target 3 1 Channel 3 2 Affinity 4 Mode of action 5 Toxicity 5 1 Symptoms 5 2 LD50 6 Therapeutic use 7 ReferencesSources editHNTX I HNTX III HNTX IV and HNTX V are made by the Chinese bird spider Haplopelma hainanum Ornithoctonus hainana Selenocosmia hainana 1 2 4 5 6 7 8 9 10 11 Chemistry editStructure edit Hainantoxins I III IV and V show high homology including the presence of three disulfide bonds that form an inhibitor cysteine knot ICK motif HNTX I edit The main component of the venom of O hainana is HNTX I 12 It has 33 amino acid residues with a total molecular weight of 3605 3608 Da HNTX I contains a short triple stranded anti parallel beta sheet and four beta turns 4 The amino acid residues His28 and Asp26 are needed for the bioactivity of HNTX I 13 HNTX II edit HNTX II has a molecular weight of 4253 Da and contains 37 amino acid residues The complete amino acid sequence of HNTX II is NH2 LFECSV SCEIEK EGNKD CKKKK CKGGW KCKFN MCVKV COOH 14 HNTX III edit The structure of HNTX III consists of 33 35 amino acid residues which form a beta sheet with connections between Asp7 and Cys9 Tyr21 and Ser23 and Lys27 and Val30 6 8 HNTX IV edit HNTX IV has 35 amino acid residues with a total molecular weight of 3989 Da The first strand consists of an antiparallel beta sheet 11 The complete amino acid sequence of HNTX IV is NH2 ECLGFG KGCNPS NDQCCK SSNLVC SRKHRW CKYEI CONH2 11 Lys 27 His28 Arg29 and Lys 32 are the neuroactive amino acid residues 1 5 10 HNTX V edit HNTX V consists of 35 amino acid residues 2 The whole amino acid residue sequence of HNTX V is NH2 ECLGFG KGCNPS NDQCCK SANLVC SRKHRW CKYEI COOH At the active binding site of HNTX V Lys27 and Arg 29 are the most important 2 Target editChannel edit Hainantoxins selectively inhibit tetrodotoxin sensitive TTX S voltage gated sodium channels VGSCs 1 5 6 9 Voltage gated Ca2 channels VGCCs tetrodotoxin resistant TTX R VGSCs and rectifier delayed potassium channels are not affected 8 HNTX III and HNTX IV are part of the Huwentoxin I family 3 8 Toxins from the Huwentoxin I family are thought to bind to site 1 on the sodium channels Other hainantoxins bind at site 3 of the sodium channels HNTX I specifically blocks mammalian Nav1 2 and insect para tipE channels expressed in Xenopus laevis oocytes HNTX I is a weak antagonist of the vertebrate TTX S VGSCs but is more potent on insect VGSCs 4 10 Affinity edit For the blockage of sodium channels electrostatic interactions or hydrogen bonds are needed Important for the electrostatic interaction is the presence of a positively charged region in the toxin because the receptor site of the sodium channel contains a lot of negatively charged residues 1 2 In HNTX I the positively charged residues and a vicinal hydrophobic patch have most influence on the binding to the sodium channels 4 HNTX IV has a positively charged patch containing the amino acids Arg26 Lys27 His28 Arg29 and Lys32 of which Lys27 Arg29 and Lys32 are the most important for interaction with the TTX S VGSCs 10 15 HNTX V also shows an interface of positively charged amino acids that are responsible for the binding with the TTX S VGSCs where also Lys27 and Arg29 are the most important Subtle differences in the positively charged patch can result in altered electrostatic properties causing altered pharmacological effects 4 Table 1 IC50 values of four subgroups of hainantoxins IC50 HNTX I 68 mM 4 HNTX III 1 1 nM 8 HNTX IV 44 6 nM 8 HNTX V 42 3 nM 2 Mode of action editHNTX I HNTX III HNTX IV and HNTX V are thought to bind to site 1 of voltage dependent sodium channels similar to TTX and thereby block the channel pore They do not alter activation and inactivation kinetics 1 4 Ion selectivity of the VGSCs is not changed by hainantoxin 8 9 The mode of action of HNTX II is unclear but is unlikely to involve sodium channels 14 Toxicity editSymptoms edit Hainantoxins can affect both vertebrates and invertebrates HNTX I has no significant effect on insects or rats 2 12 HNTX III and HNTX IV cause spontaneous contractions of the diaphragm muscle and the vas deferens smooth muscle of the rat 8 9 HNTX III and HNTX IV are able to paralyze cockroaches and HNTX IV can even paralyze rats 15 LD50 edit Intracerebroventricular injection in mice with HNTX II shows a LD50 of 1 41 mg g The intraperitoneal LD50 value of HNTX IV in mice is 0 2 mg kg 8 9 HNTX III is 40 times more potent that HNTX IV 8 Therapeutic use editHNTX III and HNTX IV have an antagonistic effect on the toxin BMK I a toxic protein in the venom of the scorpion Buthus martensii 8 References edit a b c d e f Li D et al Structure activity relationships of hainantoxin IV and structure determination of active and inactive sodium channel blockers J Biol Chem 2004 Sep 3 279 36 37734 40 Epub 2004 Jun 16 a b c d e f g Xiao YC Liang SP Purification and characterization of Hainantoxin V a tetrodotoxin sensitive sodium channel inhibitor from the venom of the spider Selenocosmia hainana Toxicon 2003 May 41 6 643 50 a b Family 22huwentoxin 1 family 22 in UniProtKB a b c d e f g Li D et al Function and solution structure of hainantoxin I a novel insect sodium channel inhibitor from the Chinese bird spider Selenocosmia hainana FEBS Lett 2003 Dec 18 555 3 616 22 a b c Xu X et al Solid phase synthesis and biological characterization of S12A HNTX IV and R29A HNTX IV two mutants of hainantoxin IV Sheng Wu Gong Cheng Xue Bao 2005 Jan 21 1 92 6 a b c Zeng XZ et al Sequence specific assignment of 1H NMR resonance and determination of the secondary structure of Jingzhaotoxin I Acta Biochim Biophys Sin Shanghai 2005 Aug 37 8 567 72 Honma T et al Novel peptide toxins from acrorhagi aggressive organs of the sea anemone Actinia equina Toxicon 2005 Dec 1 46 7 768 74 Epub 2005 Sep 23 a b c d e f g h i j k Xiao Y Liang S Inhibition of neuronal tetrodotoxin sensitive Na channels by two spider toxins hainantoxin III and hainantoxin IV Eur J Pharmacol 2003 Sep 5 477 1 1 7 a b c d e Xiao YC Liang SP Inhibition of sodium channels in rat dorsal root ganglion neurons by Hainantoxin IV a novel spider toxin Sheng Wu Hua Xue Yu Sheng Wu Wu Li Xue Bao Shanghai 2003 Jan 35 1 82 5 a b c d Liu Y et al A positively charged surface patch is important for hainantoxin IV binding to voltage gated sodium channels J Pept Sci 2012 Oct 18 10 643 9 doi 10 1002 psc 2451 Epub 2012 Aug 27 a b c XIONG Xia et al Effects of Arg26 and Lys27 mutation on the bioactivity of HNTX IV a b Liu Z et al Isolation and characterization of hainantoxin IV a novel antagonist of tetrodotoxin sensitive sodium channels from the Chinese bird spider Selenocosmia hainana Cell Mol Life Sci 2003 May 60 5 972 8 Nicholson GM Insect selective spider toxins targeting voltage gated sodium channels Toxicon 2007 Mar 15 49 4 490 512 Epub 2006 Dec 5 a b Pan J Y Yu Z Q Isolation and characterization of Hainantoxin II a new neurotoxic peptide from the Chinese bird spider Haplopelma hainanum Zool Res 2010 6 570 4 a b Wang RL et al Mechanism of action of two insect toxins huwentoxin III and hainantoxin VI on voltage gated sodium channels J Zhejiang Univ Sci B 2010 Jun 11 6 451 7 Retrieved from https en wikipedia org w index php title Hainantoxin amp oldid 1051916319, wikipedia, wiki, book, books, library,

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