Biochemistry of the Thrombin-Like Enzyme and Its Purification from Iranian Echis Carinatus Snake Venom: Its Interaction with Platelet Receptors.

Snake venoms are rich in valuable substances that have medical potential in the diagnosis and treatment of hemostatic diseases. The present paper was aimed at the purification and functional characterization basis of a thrombin-like enzyme and its role in the functioning of the coagulation cascade and platelet aggregation pathway. A thrombin-like serine protease was purified from the Iranian Echis carinatus venom (TLIECV), employing a one-step chromatographic procedure. This peptide was collected in high yield and purity by a single chromatographic step using RP-HPLC equipped with a C18 column. This peptide showed a 3000 Da molecular weight in gel-electrophoresis. Evidence in the SDS-PAGE gel has confirmed high recovery of fraction in optimal terms. Subsequently, this peptide was identified via its intact molecular mass and peptide mass fingerprint (PMF) using matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF/MS). Multiple sequence alignments were performed by ClustalW, the Bioedit software. Molegro Data Modeller (MDM) 3.0 software was used to predict the putative tertiary structure of the peptide. The enzyme possessed fibrinogenolytic, procoagulant, and aggregation inducer properties. Moreover, the SDS-PAGE (12%) was applied to examine fibrinogenolytic function. The purified enzyme degraded the Aα chain of fibrinogen while the Bß and γ chains were not digested. According to that, the deficient human plasma in factor X and normal human plasma were also coagulated by TLIECV, it takes part in the common and intrinsic routes of the coagulation cascade. These findings proved that TLIECV is a serine protease identical to procoagulant thrombin-like snake venom proteases; however, it specifically releases the Aα chain of bovine fibrinogen. Because of its function to make up for the deficiency of factor X and its platelet aggregation inducer property, TLIECV could be considered a molecular impact to reveal the hemostasis mechanisms.

The effect of the venom of the yellow Iranian scorpion Odontobuthus doriae on skeletal muscle preparations in vitro.

The yellow Iranian scorpion Odontobuthus doriae can cause fatal envenoming, but its mechanism of action is unclear. One of the reported manifestations of envenoming is moderate to severe involuntary tremor of skeletal muscle. In order to understand better the mechanism of action of this venom on skeletal muscle function, we examined the effects of the venom in vitro on chick biventer cervicis (CBC) and mouse hemidiaphragm (MHD) nerve muscle preparations. O. doriae venom (0.3-10mug/ml) initially increased and then decreased twitch height. The venom also caused contracture in both preparations. In mouse triangularis sterni preparations, used for all intracellular recording techniques, the venom enhanced the release of acetylcholine and induced repetitive firing of nerve action potentials and endplate potentials in response to single-shock stimulation. With extracellular recording techniques, scorpion venom (1mug/ml) was found to cause changes to the perineural waveform associated with nerve terminal action potentials consistent with effects on Na(+) and K(+) currents. The main facilitatory effects of O. doriae venom are likely to be due to toxins that affect Na(+) channels in nerve-muscle preparations similar to most Old World scorpion venoms, but blocking effects on K(+) channels are also possible. Such effects could lead to initial enhancement of transmitter release that could underlie the muscle tremors seen in victims. Toxins acting on Na(+) and K+ currents have been isolated from the venom [Jalali, A., Bosmans, F., Amininasab, M., Clynen, E., Cuypers, E., Zaremirakabadi, A., Sarbolouki, M.N., Schoofs, L., Vatanpour, H., Tytgat, J., 2005. OD1, the first toxin isolated from the venom of the scorpion Odontobuthus doriae active on voltage-gated Na(+) channels. FEBS Lett. 579, 4181-4186; Abdel-Mottaleb, Y., Clynen, E., Jalali, A., Bosmans, F., Vatanpour, H., Schoofs, L., Tytgat, J., 2006. The first potassium channel toxin from the venom of the Iranian scorpion Odontobuthus doriae. FEBS Lett. 580, 6254-6258]; however, the muscle paralysis seen at higher concentrations of venom may be due to additional, as yet uncharacterised, components of the venom.

On the site by which alpha-dendrotoxin binds to voltage-dependent potassium channels: site-directed mutagenesis reveals that the lysine triplet 28-30 is not essential for binding.

We constructed a synthetic gene encoding the published amino acid sequence of DTx from Dendroaspis angusticeps, a ligand of voltage-dependent postassium channels that facilitates neurotransmitter release. We expressed it in Escherichia coli as a fusion protein secreted in the culture medium. The recombinant DTx was generated in vitro by chemical treatment and recovered as two isoforms. One of them (rDTx), like the venom toxin, has an N-terminal pyroglutamate whereas the other (rQDTx) has a free N-terminal glutamine. Chromatographic differences between rDTx and natural DTx led us to re-examine the amino acid sequence of natural DTx. In contrast to what was previously published, position 12 was an Asp and not Asn. Despite this difference, rDTx and DTx had similar toxicity in mice and binding affinity to synaptosomes, suggesting that residue 12 is not important for DTx function. Nor is the N-terminal residue implicated in DTx function since rDTx and rQDTx also had similar biological activities. We also synthesized and expressed a mutant of the DTx gene in which the lysine triplet 28-30 was changed into Ala-Ala-Gly. The two resulting recombinant isoforms exhibited only small decreases in biological activity, excluding the possibility that the positively charged lysine triplet 28-30 of DTx is directly involved in the toxin functional site.

Modulation of acetylcholine release at mouse neuromuscular junctions by interaction of three homologous scorpion toxins with K+ channels.

1. The effects of three scorpion toxins, charybdotoxin (CTX), iberiotoxin (IbTX), and noxiustoxin (NTX) have been studied on acetylcholine release and on K+ channels by means of twitch tension and electrophysiological recording techniques using isolated skeletal muscle preparations and by a radioligand binding assay using 125I-labelled dendrotoxin I (DpI) and rat brain synaptosomal membranes. 2. On chick biventer cervicis preparations, CTX and IbTX (125 nM) augmented the twitch responses to indirect muscle stimulation. Further, the increase (about 70-80% of control twitch height) was fast in onset, reaching a maximum within 25-30 min. NTX at 125 nM produced a slower augmentation of the twitch responses to indirect muscle stimulation, with the maximum response being seen after 40-50 min. 3. On mouse triangularis sterni preparations, CTX (300 nM after 35-40 min) and IbTX (100 nM after 15 min) increased quantal content of the evoked endplate potentials (e.p.p.) by about two fold. However, NTX (300 nM) caused only a small increase in e.p.p. amplitude, which was followed by repetitive e.p.ps in response to single shock nerve stimulation after 40-50 min. 4. Extracellular recording of nerve terminal current waveforms in triangularis sterni preparations revealed that CTX and IbTX (3-100 nM), but not NTX (100 nM), blocked the Ca(2+)-activated K+ current, IK-Ca. However, there was no major change in the portion of the nerve terminal waveform associated with voltage-dependent K+ currents, IKv. 5. In the radioligand binding assay, NTX potently displaced labelled [125I]-DpI, whereas CTX produced only partial displacement. However, IbTX did not displace [125I]-DpI from its binding sites on rat brain synaptosomal membranes.6. We conclude that these three structurally homologous scorpion toxins act on different K+ channels and that this leads to different patterns of facilitation of acetylcholine release. IbTX acts selectively on high conductance Ca2+-activated K+ channels, leading to an increase in the amplitude of e.p.ps without any other changes. NTX acts on voltage-dependent K+ channels that are sensitive to dendrotoxin and causes repetitive e.p.ps. CTX shares amino acid residues that exist in the structures of IbTX and NTX;CTX acts on both Ca2+- and voltage-dependent K+ channels.

Effects of scorpion (Buthus tamulus) venom on neuromuscular transmission in vitro.

The effects of venom from the Indian red scorpion Buthus tamulus (BT) on neuromuscular transmission have been investigated by means of twitch tension and electrophysical recording techniques using isolated skeletal muscle preparations. On chick biventer cervicis preparations, BT (1-3 micrograms/ml) augmented the twitch responses to indirect, but not direct, muscle stimulation. Higher concentrations caused a transient augmentation followed by a large contracture and then a reduction in twitch height. BT at the concentrations tested caused little change in postjunctional sensitivity as assessed by responses to exogenous acetylcholine, carbachol and KCl. Tubocurarine abolished the prolonged contracture induced by BT (10 micrograms/ml) in the presence or absence of nerve stimulation. On mouse hemidiaphragm preparations, BT (3-10 micrograms/ml) increased the twitch responses to indirect stimulation but caused little change in directly stimulated preparations. On mouse triangularis sterni preparations, BT (3-10 micrograms/ml) increased quantal content of the evoked end-plate potentials (epps) by about 70%, without markedly affecting the time course and amplitude of miniature epps. BT also caused repetitive epps in response to single shock nerve stimulation. Extracellular recording of nerve terminal current waveforms in triangularis sterni preparations revealed that BT (10-30 micrograms/ml) slightly reduced the amplitude of the waveform. Subsequently, BT induced repetitive firing of nerve endings in response to single shock stimulation, and eventually markedly prolonged the time course of the nerve terminal waveform. The effects caused by BT were different from those caused by iberiotoxin, the blocker of Ca(2+)-activated K+ currents, isolated from BT. The effects were similar to those caused by ATX-II, a toxin that delays inactivation of Na+ channels. However, BT and ATX-II behaved differently in the presence of K+ channel blockers, 3,4-diaminopyridine (DAP) and tetraethylammonium (TEA). These results confirm that Buthus tamulus venom acts mainly prejunctionally to increase the release of acetylcholine. The effect of BT on the perineural waveforms suggests that some of its actions may be due to effects on Na+ channels at or near the nerve terminals; however, additional effects of K+ channels are likely.

The effects of Indian red scorpion Buthus tamulus venom in vivo and in vitro.

The Indian red scorpion Buthus tamulus (or Mesobuthus tamulus) can cause fatal envenoming, but its mechanism of action is unclear. Venom was tested in vivo in anaesthetized rats and in vitro on isolated cardiac and skeletal muscle preparations. In vivo, the venom caused marked rhythmical fluctuations in blood pressure preceding cardiovascular collapse and death. On sheep Purkinje fibres, venom could induce spontaneous action potentials and cause prolongation of action potential duration. In chick biventer cervicis and mouse triangularis sterni preparations, venom enhanced the release of acetylcholine and induced repetitive firing of nerve action potentials in response to single shock stimulation. High concentrations caused stimulation then block of neuromuscular transmission. The main effects of Buthus tamulus venom are likely to be due to toxins that affect the opening of Na+ channels in nerves and muscles. This will cause an increase in the release of neurotransmitters in the peripheral nervous system, which may produce cardiovascular abnormalities and respiratory paralysis.

Changes to biological activity following acetylation of dendrotoxin I from Dendroaspis polylepis (black mamba).

The potassium channel blocker dendrotoxin I was acetylated with acetic anhydride. Mono-acetyl derivatives of all seven lysine residues (N-terminus blocked) and a di-derivative were isolated by chromatography on the cation-exchanger Bio-Rex 70 and reversed-phase high-performance liquid chromatography. The derivative acetyl-Lys 29 and the di-derivative of Tyr 24 and Lys 28 had more than 1000 times lower affinity than the native toxin as determined by inhibition of the 125I-dendrotoxin binding to synaptosomal membranes from rat brain. Lys 29 is part of the triplet Lys-Lys-Lys (28-30) which also occurs in the homologous alpha-dendrotoxin where the triplet is not in the functional site, as shown by site-directed mutagenesis. Acetylation of Lys 29 may have produced large structural perturbations that inactivated the toxin. Acetylation of Lys 28 alone had little effect, but the toxin became almost inactive when both Lys 28 and Tyr 24 were modified. Ten experiments were conducted under similar conditions, but a derivative of Tyr 24 was obtained only three times. In these cases the toxin apparently had a different structure, with Tyr 24 accessible to the reagent. This may depend on freeze-drying, which can alter the structure of proteins. The third derivative with low activity was acetyl-Lys 5, with affinity decreased 20-fold. Lys 5 has a protruding side-chain that does not interact with any other group in the toxin molecule. Therefore, Lys 5 is probably part of the functional site for dendrotoxin's binding to the voltage-dependent K+ channels.

Neuromuscular effects of some potassium channel blocking toxins from the venom of the scorpion Leiurus quinquestriatus hebreus.

The scorpion venom Leiurus quinquestriatus hebreus was fractionated by chromatography in order to isolate toxins that affected binding of radiolabelled dendrotoxin to K+ channel proteins on synaptosomal membranes and that facilitated acetylcholine release in chick biventer cervicis nerve-muscle preparations. In addition to the previously characterized charybdotoxin, three toxins were isolated: 14-2, 15-1 and 18-2. Toxin 14-2 has a blocked N-terminus and because of low quantities, it has not been sequenced; 15-1 is a newly sequenced toxin of 36 residues with some overall homology to charybdotoxin and noxiustoxin; 18-2 is identical to charybdotoxin-2. The apparent Ki against dendrotoxin binding were: charybdotoxin, 3.8 nM; 14-2, 150 nM; 15-1, 50 nM; and 18-2, 0.25 nM. Toxin 14-2 (75 nM-1.5 microM) had a presynaptic facilitatory effect on neuromuscular preparations. Toxin 15-1 augmented responses to direct muscle stimulation, probably because it blocked Ca(2+)-activated K+ currents in muscle fibres. Toxin 18-2 (charybdotoxin-2) had a potent presynaptic facilitatory action, with less effect on direct muscle stimulation. This contrasts with the relatively weak neuromuscular effects of the highly homologous charybdotoxin. On a Ca(2+)-activated K+ current in mouse motor nerve endings, charybdotoxin and toxin 18-2 produced maximal block at around 100 nM, whereas 15-1 was inactive at 300 nM. Charybdotoxin can increase quantal content, but this is more likely to result from block of voltage-dependent K+ channels than Ca(2+)-activated channels: the increase in transmitter release occurred in conditions in which little IKCa would be present; higher concentration of charybdotoxin and longer exposure times were required to increase transmitter release than those needed to block IKCa, and the facilitatory effects of charybdotoxin and toxin 18-2 correlated more with their effects on dendrotoxin binding than on block of IKCa.

Structure-activity studies on scorpion toxins that block potassium channels.

Scorpion venoms contain toxins that block different types of potassium channels. Some of these toxins have affinity for high conductance Ca(2+)-activated K+ channels and for dendrotoxin-sensitive voltage-dependent K+ channels. The structural features that determine the specificity of binding to different channel types are not known. We investigated this using natural and synthetic scorpion toxins. We have tested the effects of charybdotoxin (CTX) and two homologues (Lqh 15-1 and Lqh 18-2), iberiotoxin (IbTX), and kaliotoxin (KTX) from the scorpions Leiurus quinquestriatus hebreus, Buthus tamulus and Androctonus mauretanicus mauretanicus, respectively, and synthetic variants of CTX, namely CTX2-37, CTX3-37, CTX4-37, and CTX7-37, on a Ca(2+)-activated K+ current (IK-Ca) at a mammalian motor nerve terminal, and on the binding of a radiolabelled dendrotoxin, 125I-DpI, to voltage-dependent K+ channels on rat brain synaptosomal membranes. The native toxins contain 37-38 amino acid residues, they are over 30% identical in sequence (CTX and IbTX are 68% identical), and they have similar three-dimensional conformations. All toxins, except IbTX, displaced 125I-DpI from its synaptosomal binding sites: Lqh 18-2 (Ki = 0.25 nM), KTX (Ki = 2.1 nM), CTX (Ki = 3.8 nM), CTX2-37, (Ki = 30 nM), Lqg 15-1 (Ki = 50 nM), CTX3-37 (Ki = 60 nM), CTX4-37 (Ki = 50 nM), CTX7-37 (Ki = 105 nM). IbTX had no effect at 3 microM. When variants of CTX with deletions at the N-terminal portion were tested for their activity on IK-Ca on motor nerve terminals in mouse triangularis sterni nerve-muscle preparations, CTX3-37 and CTX4-37 were ineffective at 100 nM; and CTX7-37 was ineffective at up to 1 microM. IbTX and CTX (100 nM) completely blocked IK-Ca, but KTX (100 nM) did not affect the nerve terminal IK-Ca. Different residues appear to be important for interactions of the toxins with different K+ channels. IbTX did not displace dendrotoxin binding, but it did block IK-Ca, whereas KTX was as active as CTX against dendrotoxin binding but it did not affect the IK-Ca of the motor nerve terminals. The N-terminal section of the toxins appears to be particularly involved in block of IK-Ca at the motor nerve terminal: it is truncated in the inactive synthetic CTX variants; and it is positively charged at lysine-6 in KTX (which is inactive), but negatively charged in IbTX and neutral in CTX.(ABSTRACT TRUNCATED AT 400 WORDS)

Sensitive high-performance liquid chromatographic method for determination of captopril in plasma.

A rapid, simple and sensitive high-performance liquid chromatographic method for the determination of captopril in plasma has been developed. Captopril is derivatized with a new reagent, 2-bromo-2'-acetonaphthone to form a product that showed ultraviolet-absorbing properties. For plasma samples, the protein was removed with 6% perchloric acid and the derivatized captopril was extracted with diethyl ether. The chromatographic separation was performed on an analytical mu bondapak NH2 column (300 x 3.9 mm, i.d.) with an isocratic mobile phase consisting of n-hexane-2-propanol-methanol-acetic acid (68:15:15:2). Using ultraviolet detection at 246 nm, the quantification limit for captopril in plasma was 10 ng/ml. The calibration curve was linear over the concentration range 12.5-500 ng/ml. The average recovery was 95% for plasma. The inter-day and intra-day assay coefficients of variation were found to be less than 12%.

Synthesis of charybdotoxin and of two N-terminal truncated analogues. Structural and functional characterisation.

Charybdotoxin and two N-terminal truncated peptides, corresponding to the 2-37 and 7-37 sequences, were obtained by stepwise solid-phase synthesis using N alpha-t-butyloxycarbonyl and benzyltype side-chain protection. While this strategy was generally useful, the S-acetamidomethyl protecting group used for the six cysteines was not completely stable under HF treatment and its subsequent removal by mercury(II) treatment was neither complete nor devoid of side reactions. The completely deprotected native and truncated sequences were folded efficiently in the presence of glutathione and were finally purified by high-pressure liquid chromatography with overall yields of 4.0-5.0%. Each protein was characterised chemically, structurally and functionally. 1H-NMR spectroscopy was used and a complete assignment of all the protons of the three synthetic proteins was achieved. NMR data show that synthetic charybdotoxin is indistinguishable from the natural protein. The two truncated proteins contain the same elements of secondary structure and a similar overall three-dimensional structure, in agreement with circular dichroic measurements. The shortest analogue, however, may have local structural perturbations and/or higher flexibility. Biological activity on dog epithelial Ca(2+)-activated K+ channels and on rat brain synaptosomal voltage-dependent K+ channels show that synthetic charybdotoxin was as potent as the natural toxin on both channels. For both channels, deletion of the first amino acid, 5-oxoproline (pyroglutamic acid) decreased only slightly the potency of the inhibitor, while deletion of the entire 1-6 segment reduced potency much more. We conclude that the N-terminal region of charybdotoxin plays a functional role in tuning the toxin's biological activity but is not essential for the folding and stability of the structure. The structure of the shortest analogue represents an interesting example of how a well organised and stable alpha/beta fold can be engineered with only 31 amino acid residues.