Electrophysiological effects of fractions isolated from the venom of Parabuthus granulatus on calcium channels in cardiac myocytes / L.H. du Plessis

Du Plessis, Lissinda Hester

January 2004

Scorpion toxins specific for Na+ and K+ channels, have been studied extensively but relatively little has been done on Ca2+ channel toxins. Toxins in the venom of only two South African scorpions P. transvaalicus and P. granulatus have been found to interact with Ca2+ channels. Kurtoxin isolated from the venom of P. transvaalicus inhibits the T and L-type neuronal Ca2+ channels, whereas KLI and KLII (Kurtoxin-like peptide I and II), isolated from P. granulatus, inhibits T-type Ca2+ channel activity in mouse male germ cells. In this study the effects of fractions isolated from the venom of P. granularus on Cca2+ channels in rat ventricular myocytes were investigated by means of the whole-cell patch clamp technique. Fractions of P. granulatus crude venom were isolated with Sephadex G50 columns (fraction I-IV). Fraction III (PgIII) showed a voltage dependent increase of the inward Ca2+ current and influenced the channel kinetics by shifting the voltage dependence of activation towards more hyperpolarizing membrane potentials and decreased the rate of inactivation and deactivation. The time of the current to reach peak was also delayed. PgIII was further separated by HPLC in an attempt to identify the subfraction/s responsible for the agonistic effect. Subfraction I had an agonistic effect similar to PgIII, whereas subfraction II and III, decreased the Ca2+ current. The observed agonistic effect has not been described in the literature. The identification of new peptide structures with unique functions are important in the field of toxin research. Peptides that target Ca2+ channels can be valuable tools to characterize Ca2+ channels. Ca2+ channels in the heart are implicated in a number of pathological disorders like angina, ischemia, some arrhythmias and hypertension. / Thesis (M.Sc. (Physiology))--North-West University, Potchefstroom Campus, 2005.

Cardiac Ca²+ channel

Agonist

Scorpion toxins

Electrophysiological effects of fractions isolated from the venom of Parabuthus granulatus on calcium channels in cardiac myocytes / L.H. du Plessis

Du Plessis, Lissinda Hester

January 2004

Scorpion toxins specific for Na+ and K+ channels, have been studied extensively but relatively little has been done on Ca2+ channel toxins. Toxins in the venom of only two South African scorpions P. transvaalicus and P. granulatus have been found to interact with Ca2+ channels. Kurtoxin isolated from the venom of P. transvaalicus inhibits the T and L-type neuronal Ca2+ channels, whereas KLI and KLII (Kurtoxin-like peptide I and II), isolated from P. granulatus, inhibits T-type Ca2+ channel activity in mouse male germ cells. In this study the effects of fractions isolated from the venom of P. granularus on Cca2+ channels in rat ventricular myocytes were investigated by means of the whole-cell patch clamp technique. Fractions of P. granulatus crude venom were isolated with Sephadex G50 columns (fraction I-IV). Fraction III (PgIII) showed a voltage dependent increase of the inward Ca2+ current and influenced the channel kinetics by shifting the voltage dependence of activation towards more hyperpolarizing membrane potentials and decreased the rate of inactivation and deactivation. The time of the current to reach peak was also delayed. PgIII was further separated by HPLC in an attempt to identify the subfraction/s responsible for the agonistic effect. Subfraction I had an agonistic effect similar to PgIII, whereas subfraction II and III, decreased the Ca2+ current. The observed agonistic effect has not been described in the literature. The identification of new peptide structures with unique functions are important in the field of toxin research. Peptides that target Ca2+ channels can be valuable tools to characterize Ca2+ channels. Ca2+ channels in the heart are implicated in a number of pathological disorders like angina, ischemia, some arrhythmias and hypertension. / Thesis (M.Sc. (Physiology))--North-West University, Potchefstroom Campus, 2005.

Cardiac Ca²+ channel

Agonist

Scorpion toxins

Ion selectivity and membrane potential effects of two scorpion pore-forming peptides / D. Elgar

Elgar, Dale

January 2005

Parabutoporin (PP) and opistoporin 1 (OP1) are cation, a-helical antimicrobial peptides isolated from the southern African scorpion species, Parabuthus schlechteri and Opistophthalmus carinatus, respectively. Along with their antimicrobial action against bacteria and fungi, these peptides show pore-forming properties in the membranes of mammalian cells. Pore-formation and ion selectivity in cardiac myocytes were investigated by measuring the whole cell leak current by means of the patch clamp technique. Pore-formation was observed as the induction of leak currents. Ion selectivity of the pores was indicated by the shift of the reversal potential (E,,,) upon substitution of intra (K' with CS' and CI- with aspartate) and extracellular (Na' with NMDG') ions. Results were compared with the effect of gramicidin A used as a positive control for monovalent cation selective pores. PP and OP I induced a fluctuating leak current and indicate non-selectivity of PP and OP1-induced pores. An osmotic protection assay to determine estimated pore size was performed on the cardiac myocytes. PP and OP1-induced pores had an estimate pore size of 1.38-1.78 nm in diameter. The effect of PP and OP1 on the membrane potential (MP) of a neuroblastoma cell line and cardiac myocytes was investigated. TMRM was used to mark the MP fluorescently and a confocal microscope used to record the data digitally. The resting membrane potential (RMP) of the neuroblastoma cells was calculated at -38.3 f 1.9 mV. PP (0.5 uM) and OP1 (0.5-1 uM) depolarized the entire cell uniformly to a MP of -1 1.9 k 3.9 mV and -9.4 k 1.9 mV, respectively. This occurred after 20-30 min of peptide exposure. In the case of the cardiac myocytes depolarization was induced to -39.7 f 8.4 mV and -32.6 f 5.2 mV by 0.5-1 uM PP and 1.5-2.5 uM OPl, respectively. / Thesis (M.Sc. (Physiology))--North-West University, Potchefstroom Campus, 2006.

Scorpion toxins

Antimicrobial peptides

Pore-formation

Ion selectivity

Pore size

Membrane potential

Ion selectivity and membrane potential effects of two scorpion pore-forming peptides / D. Elgar

Elgar, Dale

January 2005

Parabutoporin (PP) and opistoporin 1 (OP1) are cation, a-helical antimicrobial peptides isolated from the southern African scorpion species, Parabuthus schlechteri and Opistophthalmus carinatus, respectively. Along with their antimicrobial action against bacteria and fungi, these peptides show pore-forming properties in the membranes of mammalian cells. Pore-formation and ion selectivity in cardiac myocytes were investigated by measuring the whole cell leak current by means of the patch clamp technique. Pore-formation was observed as the induction of leak currents. Ion selectivity of the pores was indicated by the shift of the reversal potential (E,,,) upon substitution of intra (K' with CS' and CI- with aspartate) and extracellular (Na' with NMDG') ions. Results were compared with the effect of gramicidin A used as a positive control for monovalent cation selective pores. PP and OP I induced a fluctuating leak current and indicate non-selectivity of PP and OP1-induced pores. An osmotic protection assay to determine estimated pore size was performed on the cardiac myocytes. PP and OP1-induced pores had an estimate pore size of 1.38-1.78 nm in diameter. The effect of PP and OP1 on the membrane potential (MP) of a neuroblastoma cell line and cardiac myocytes was investigated. TMRM was used to mark the MP fluorescently and a confocal microscope used to record the data digitally. The resting membrane potential (RMP) of the neuroblastoma cells was calculated at -38.3 f 1.9 mV. PP (0.5 uM) and OP1 (0.5-1 uM) depolarized the entire cell uniformly to a MP of -1 1.9 k 3.9 mV and -9.4 k 1.9 mV, respectively. This occurred after 20-30 min of peptide exposure. In the case of the cardiac myocytes depolarization was induced to -39.7 f 8.4 mV and -32.6 f 5.2 mV by 0.5-1 uM PP and 1.5-2.5 uM OPl, respectively. / Thesis (M.Sc. (Physiology))--North-West University, Potchefstroom Campus, 2006.

Scorpion toxins

Antimicrobial peptides

Pore-formation

Ion selectivity

Pore size

Membrane potential

Solution NMR Studies Of Peptide Toxins From Cone Snails And Scorpion

Kumar, G Senthil

10 1900

Major constituents of the venom of various animals are peptidogenic in nature. Marine snails belonging to the species Conus are venomous predators that use small, structurally constrained peptides present in their venom for prey capture and defense. It is known that ~500 Conus species are present in nature and the venom of each of these Conus species is a complex mixture of nearly 100 peptides accounting for > 50,000 peptides with little overlap among the different species. The peptides isolated from the venom of Conus species are commonly known as conotoxins or conopeptides. Some of the common targets of these peptides include the different ion channels like Na+, K+, and Ca2+, and receptor subtypes such as nicotinic acetylcholine and NMDA receptors. The ion channels and receptor subtypes were targeted by conopeptides with high degree of specificity and selectivity. The structural information on the peptides from cone snails can prove to be a valuable starting tool for the understanding of the function of different ion channels and hence in the design of neuropharmacologically active drugs. Conotoxins are disulfide-rich peptides and the number of disulfide generally ranges from two to five. Based on the arrangement of cysteines in their primary sequence, they are classified into different superfamilies. The signal sequences of the precursors belonging to a particular superfamily are highly conserved and hence the members within the same family have, in common, the unique disulfide arrangement and pharmacological activity. Conotoxins are classified into eleven superfamilies till date. In order to understand the underlying the principles involved in the action of these peptides on different ion channels, one needs to know the three-dimensional structures which, in potential, will help in the identification of the pharmacophores responsible for the observed pharmacological activity. With the aim of studying the structure-activity relationships found among the conotoxins, we have initiated a study on the peptides isolated from the marine snails found in the Indian coastal waters. This thesis is focused in the structural studies of the peptide toxins from marine cone snails and a terrestrial scorpion. The tool used for the structural studies of these peptide toxins is Nuclear Magnetic Resonance Spectroscopy. Chapter 1 provides an overview of the peptide toxins found among various animal species with more emphasis on conotoxins and scorpion toxins. In addition, the rationale behind the present study has also been explained. Chapter 2 describes the structure determination of two conopeptides isolated from Conus amadis, δ-Am2766 and Am2735, which are active on mammalian sodium channels. The structural aspects and comparison with other known conopeptides belonging to the same superfamily as that of these two peptides have also been described. Solution NMR studies of Ar1446 and Ar1248, two conopeptides isolated from the species Conus araneosus have also been studied using Homonuclear NMR methods. Ar1446 is a three disulfide-bonded peptide. Our studies have revealed that this peptide has a novel disulfide connectivity not previously observed in the M superfamily or any other superfamily of conotoxins. The structural features of Ar1446 will be described along with the NMR studies on two-disulfide bonded peptide, Ar1248, belonging to the A-superfamily of conotoxins. The main problem faced in the kind of study of peptides isolated from natural sources is the amount that can be isolated and purified to homogeneity. In order to obtain large quantities of peptides, we have successfully used Cytochrome b5 as fusion host to clone, over express and purify these peptides using recombinant methods. The use of recombinant methods has aided in the preparation of isotopically enriched peptides. The use of cyt b5 as fusion host for the large scale production of some of the peptides from Indian marine snails is described in Chapter 4. A novel pharmacologically active linear peptide, Mo1659 isolated from Conus monile, have been studied using Heteronuclear NMR methods. This peptide was cloned, over expressed and purified using Cytochrome b5 as a fusion host. Another linear peptide, Mo1692 (also from Conus monile), has been prepared using the same method and was studied using Homonuclear NMR methods. Both these peptides were liberated from the fusion host using cyanogen bromide cleavage and were subsequently purified using RP-HPLC. The results of the biosynthetic preparation and NMR studies of these two peptides have been described in Chapter 5. Chapter 6 describes the solution structure determination of a novel scorpion toxin characterized in the venom of the Indian red scorpion Buthus tamulus. The cloning, over expression, folding and purification of BTK-2 is described here. The structure and the function of this recombinantly produced BTK-2 will also be described.

Polypeptides

Nuclear Magnetic Resonance

Snails

Scorpions

Peptide Toxins

Conotoxins

Scorpion Toxins

Conopeptides

Mo1659

δ−conotoxin

Am2766

Am2735

Conus amadis

Ar1446

Ar1248

Conus araneosus

BTK-2

Buthus tamulus

Biochemistry

La diversité des toxines de scorpions et leur intérêt dans la recherche biologique et pharmacologique : (purification et caractérisation chimique, pharmacologique et immunologique des toxines de scorpion présentant des problèmes de santé publique au Moyen Orient et leurs implications pharmacologiques) / Scorpion toxins diversity and their interest in biological an pharmacological research : purification and chemical, pharmacological and immunological characterization of toxins from scorpions involved in Public Health problems in Middle-East and their pharmacological applications

Abbas, Najwa

10 December 2010

Les scorpions du genre Androctonus, comme Androctonus australis en Algérie et en Tunisieou Androctonus mauretanicus au Maroc, sont responsables d’environ 100.000 piqûres par ansur l’ensemble du Maghreb, suivies de 1 % de décès. Ils posent un réel problème de santépublique. Les toxines «alpha» modulant les canaux sodium voltage-activés (Nav) sontresponsables de 80 à 90% de l’activité létale des venins d’Androctonus australis etmauretanicus. Cependant, certaines petites molécules sont aussi capables de bloquer lefonctionnement d’autres types de canaux ioniques, en particulier des canaux potassiumvoltage-activés (Kv).Au cours de cette thèse, nous avons isolé et caractérisé les composants du venind’Androctonus amoreuxi, scorpion largement distribué en Afrique du Nord et au Moyen-Orient, mais qui n’avait jusqu’ici fait l’objet d’aucune etude rigoureuse. Nous avons identifiéles constituants impliqués dans la toxicité du venin et précisé leurs propriétéspharmacologiques et immunologiques, ainsi que l’effet qu’elles induisent enélectrophysiologie sur des canaux Nav et Kv clonés exprimés dans l’ovocyte de Xenope.Nous avons recherché de nouveaux membres d’une famille de toxines récemment isolées, lesBirtoxines-like, et interprété leur polymorphisme biologique par la modélisation de leursstructures 3D. Enfin, nous avons mené à bien un programme portant sur les effetsantinociceptifs des toxines de scorpion chez la souris. Cela nous a permis de proposer uneexplication qui fait intervenir le système opiacé et la « contre-irritation ». L’effet des toxinesreconnues « analgésiques » a ensuite été testé en électrophysiologie sur des neuronesnocicepteurs. / The North African scorpion Androctonus australis in Algeria and Tunisia, or Androctonusmauretanicus in Morocco, are responsible of about 100.000 stings each year in Maghreb,followed by 1% of death. Small toxins modulating voltage-gated sodium channels (Nav),named “alpha”, are responsible of 80 to 90% of the total lethal activity from the Androctonusaustralis and mauretanicus venoms. However, smaller molecules are also able to block thefunctioning of another type of ionic channels, in particular, the voltage-gated potassiumchannels (Kv).During this thesis, we have isolated and characterized the compounds of the venom fromAndroctonus amoreuxi, a scorpion widely found in North Africa and Middle East, but neverseriously studied so far. We have identified the constituents implicated in the toxicity anddefined their immunological and pharmacological properties, as well as theirelectrophysiological effects on cloned Nav and Kv channels expressed in Xenopus oocytes.We also have looked for recently characterized new molecules, the Birtoxins-like, and tried toexplain their large biological polymorphism by 3D structural models. At last, we haveevaluated the antinociceptifs effects of scorpion toxins in mice. We have proposed that theantalgic effects observed after administration of scorpion toxins are partly due to a counterirritation phenomenon, which implicates the activation of an endogenous opioid system. The“analgesic” toxins have been further tested in electrophysiology on DRG neurons.

Toxines de scorpions

Canaux sodium voltage-activés

Canaux potassium voltage-activés

Nocicepteurs

Contre-irritation

Scorpion toxins

Nociception

Dnic

Electrophysiology on DRG neurons