Vaporization of Inorganic Mercury by Cell-free Extracts of Drug Resistant Escherichia coli

The cDNAs encoding venom phospholipase A₂ (PLA₂) inhibitors (PLIs), named Protobothrops elegans (Pe)γPLI-A, PeγPLI-B, PeαPLI-A, and PeαPLI-B, were cloned from the P. elegans liver cDNA library. They were further divided into several constituents due to nucleotide substitutions in their open reading frames. For PeαPLI-A, two constituents, PeαPLI-A_a and PeαPLI-A_b, were identified due to three nonsynonymous substitutions in exon 3. Far-western blot and mass-spectrometry analysis of the P. elegans serum proteins showed the presence of γPLIs, and αPLIs, which can bind venom PLA₂s. In αPLIs from Protobothrops sera, A or B subtype-specific amino acid substitutions are concentrated only in exon 3. A comparison of γPLIs showed that γPLI-As are conserved and γPLI-Bs diversified. Mathematical analysis of the nucleotide sequences of Protobothrops γPLI-B cDNAs revealed that the particular loops in the three-finger motifs diversified by accelerated evolution. Such evolutionary features should have made serum PLIs acquire their respective inhibitory activities to adapt to venom PLA₂ isozymes.     

Accelerated evolution of Trimeresurus okinavensis venom gland phospholipase A2 isozyme-encoding genes

Three Trimeresurus okinavensis (To; himehabu snake, Crotalinae) venom gland phospholipase A₂ (PLA₂) isozymeencoding genes, gPLA₂-o1, gPLA₂-o2 and gPLA₂-o3, were isolated from its genomic DNA library. The nucleotide (nt) sequence analysis revealed that two of the three genes (gPLA₂-o2) and (gPLA₂-o3) occasionally have been converted to inactivated genes by introduction of one base insertion or substitution. It was confirmed from Southern blot analysis that the To haploid genome contains only three venom gland PLA₂ isozyme genes herein isolated. Comparison of these genes showed that nonsynonymous nt substitutions have occurred more frequently than synonymous nt substitutions in the protein-coding regions, except for the signal-peptide coding domain, implying that To venom gland PLA₂isozyme genes have evolved via accelerated evolution. Such an evolutionary feature of To venom gland PLA₂ isozyme genes proves the general universality of accelerated evolution previously drawn for venom gland PLA₂ isozyme genes of other crotalinae snakes. The variability in the mature protein-coding regions of three To venom gland PLA₂ isozyme genes appears to have been brought about by natural selection for point mutations.     

The molecular cloning of a phospholipase A2 from Bothrops jararacussu snake venom: Evolution of venom group II phospholipase A2's may imply gene duplications

The sequence coding for a snake venom phospholipase A₂ (PLA₂), BJUPLA₂, has been cloned from a Bothrops jararacussu venom gland cDNA library. The cDNA sequence predicts a precursor containing a 16-residue signal peptide followed by a molecule of 122 amino acid residues with a strong sequence similarity to group II snake venom PLA₂'s. A striking feature of the cDNA is the high sequence conservation of the 5 and 3 untranslated regions in cDNAs coding for PLA₂'s from a number of viper species. The greatest sequence variation was observed between the regions coding for the mature proteins, with most substitutions occurring in nonsynonymous sites. The phylogenetic tree constructed by alignment of the amino acid sequence of BJUPLA₂ with group II PLA₂'s in general groups them according to current taxonomical divisions and/or functional activity. It also suggests that gene duplications may have occurred at a number of different points during the evolution of snake venom group II PLA₂'s.The nucleotide sequence reported in this paper has been submitted to the GenBank/EMBL Data Bank with accession number X76289.Correspondence to: A.M. Moura-da-Silva     

Identification and evolution of venom phospholipase A2 inhibitors from Protobothrops elegans serum

The cDNAs encoding venom phospholipase A(2) (PLA(2)) inhibitors (PLIs), named Protobothrops elegans (Pe)γPLI-A, PeγPLI-B, PeαPLI-A, and PeαPLI-B, were cloned from the P. elegans liver cDNA library. They were further divided into several constituents due to nucleotide substitutions in their open reading frames. For PeαPLI-A, two constituents, PeαPLI-A(a) and PeαPLI-A(b), were identified due to three nonsynonymous substitutions in exon 3. Far-western blot and mass-spectrometry analysis of the P. elegans serum proteins showed the presence of γPLIs, and αPLIs, which can bind venom PLA(2)s. In αPLIs from Protobothrops sera, A or B subtype-specific amino acid substitutions are concentrated only in exon 3. A comparison of γPLIs showed that γPLI-As are conserved and γPLI-Bs diversified. Mathematical analysis of the nucleotide sequences of Protobothrops γPLI-B cDNAs revealed that the particular loops in the three-finger motifs diversified by accelerated evolution. Such evolutionary features should have made serum PLIs acquire their respective inhibitory activities to adapt to venom PLA(2) isozymes.     

Interisland Evolution of <Emphasis Type="Italic">Trimeresurus flavoviridis</Emphasis> Venom Phospholipase A<Subscript>2</Subscript> Isozymes

Abstract Trimeresurus flavoviridis snakes inhabit the southwestern islands of Japan. A phospholipase A₂ (PLA₂), named PL-Y, was isolated from Okinawa T. flavoviridis venom and its amino acid sequence was determined from both protein and cDNA. PL-Y was unable to induce edema. In contrast, PLA-B, a PLA₂ from Tokunoshima T. flavoviridis venom, which is different at only three positions from PL-Y, is known to induce edema. A new PLA₂, named PLA-B′, which is similar to PLA-B, was cloned from Amami-Oshima T. flavoviridis venom gland. Three T. flavoviridis venom basic [Asp⁴⁹]PLA₂ isozymes, PL-Y (Okinawa), PLA-B (Tokunoshima), and PLA-B′ (Amami-Oshima), are identical in the N-terminal half but have one to four amino acid substitutions in the β1-sheet and its vicinity. Such interisland sequence diversities among them are due to isolation in the different environments over 1 to 2 million years and appear to have been brought about by natural selection for point mutation in their genes. Otherwise, a major PLA₂, named PLA2, ubiquitously exists in the venoms of T. flavoviridis snakes from the three islands with one to three synonymous substitutions in their cDNAs. It is assumed that the PLA2 gene is a prototype among T. flavoviridis venom PLA₂ isozyme genes and has hardly undergone nonsynonymous mutation as a principal toxic component. Phylogenetic analysis based on the amino acid sequences revealed that T. flavoviridis PLA₂ isozymes are clearly separated into three groups, PLA2 type, basic [Asp⁴⁹]PLA₂ type, and [Lys⁴⁹]PLA₂ type. Basic [Asp⁴⁹]PLA₂-type isozymes may manifest their own particular toxic functions different from those of the isozymes of the PLA2 type and [Lys⁴⁹]PLA₂ type.     

Up-regulation of the expressions of phospholipase A2 inhibitors in the liver of a venomous snake by its own venom phospholipase A2

Venomous snakes such as Gloydius brevicaudus have three distinct types of phospholipase A₂ inhibitors (PLIα, PLIβ, and PLIγ) in their blood so as to protect themselves from their own venom phospholipases A₂ (PLA₂s). Expressions of these PLIs in G. brevicaudus liver were found to be enhanced by the intramuscular injection of its own venom. The enhancement of gene expressions of PLIα and PLIβ in the liver was also found to be induced by acidic PLA₂ contained in this venom. Furthermore, these effects of acidic PLA₂ on gene expression of PLIs were shown to be unrelated to its enzymatic activity. These results suggest that these venomous snakes have developed the self-protective system against their own venom, by which the venom components up-regulate the expression of anti-venom proteins in their liver.     

Molecular cloning and biochemical characterization of a myotoxin inhibitor from Bothrops alternatus snake plasma

Phospholipases A₂ (PLA₂s) are important components of Bothrops snake venoms, that can induce several effects on envenomations such as myotoxicity, inhibition or induction of platelet aggregation and edema. It is known that venomous and non-venomous snakes present PLA₂ inhibitory proteins (PLIs) in their blood plasma. An inhibitory protein that neutralizes the enzymatic and toxic activities of several PLA₂s from Bothrops venoms was isolated from Bothrops alternatus snake plasma by affinity chromatography using the immobilized myotoxin BthTX-I on CNBr-activated Sepharose. Biochemical characterization of this inhibitory protein, denominated αBaltMIP, showed it to be a glycoprotein with Mr of ∼24,000 for the monomeric subunit. CD spectra of the PLA₂/inhibitor complexes are considerably different from those corresponding to the individual proteins and data deconvolution suggests that the complexes had a relative gain of helical structure elements in comparison to the individual protomers, which may indicate a more compact structure upon complexation. Theoretical and experimental structural studies performed in order to obtain insights into the structural features of αBaltMIP indicated that this molecule may potentially trimerize in solution, thus strengthening the hypothesis previously raised by other authors about snake PLIs oligomerization.     

Molecular cloning and characterization of a venom phospholipase A2 from the bumblebee Bombus ignitus

Phospholipase A₂ (PLA₂) is one of the main components of bee venom. Here, we identify a venom PLA₂ from the bumblebee, Bombus ignitus. Bumblebee venom PLA₂ (Bi-PLA₂) cDNA, which was identified by searching B. ignitus venom gland expressed sequence tags, encodes a 180 amino acid protein. Comparison of the genomic sequence with the cDNA sequence revealed the presence of four exons and three introns in the Bi-PLA₂ gene. Bi-PLA₂ is an 18-kDa glycoprotein. It is expressed in the venom gland, cleaved between the residues Arg44 and Ile45, and then stored in the venom sac. Comparative analysis revealed that the mature Bi-PLA₂ (136 amino acids) possesses features consistent with other bee PLA₂s, including ten conserved cysteine residues, as well as a highly conserved Ca²⁺-binding site and active site. Phylogenetic analysis of bee PLA₂s separated the bumblebee and honeybee PLA₂ proteins into two groups. The mature Bi-PLA₂ purified from the venom of B. ignitus worker bees hydrolyzed DBPC, a known substrate of PLA₂. Immunofluorescence staining of Bi-PLA₂-treated insect Sf9 cells revealed that Bi-PLA₂ binds at the cell membrane and induces apoptotic cell death.     

Crystal structure of phospholipase PA2-Vb,a protease-activated receptor agonist from the Trimeresurus stejnegeri snake venom

Phospholipase A₂ (PLA₂) is an important component in snake venoms. Here, an acidic PLA₂, designated PA2-Vb was isolated from the Trimeresurus stejnegeri snake venom. PA2-Vb acts on a protease-activated receptor (PAR-1) to evoke Ca²⁺ release through the inositol 1,4,5-trisphosphate receptor (IP₃R) and induces mouse aorta contraction. PAR-1, phospholipase C and IP₃R inhibitors suppressed PA2-Vb-induced aorta contraction. The crystal structure reveals that PA2-Vb has the typical fold of most snake venom PLA₂. Several PEG molecules bond to a positively charged pocket. The finding offers a novel pharmacological basis of the structure for investigating the PAR-1 receptor and suggests potential applications for PA2-Vb in the vascular system.     

Characterization and Gene Organization of Taiwan Banded Krait (Bungarus multicinctus) γ-Bungarotoxin

γ-Bungarotoxin was isolated from Bungarus multicinctus (Taiwan banded krait) venom using a combination of chromatography on a SP-Sephadex C-25 column and a reverse-phase high-performance liquid chromatography column. Circular dichroism (CD) measurement revealed that its secondary structure was dominant with β-sheet structure as is that of snake venom α-neurotoxins and cardiotoxins. γ-Bungarotoxin exhibits activity on inhibiting the binding of [³H]quinuclidinyl benzilate to the M2 muscarinic acetylcholine receptor subtype, and competes weakly with radioiodinated α-bungarotoxin for binding to the Torpedo nicotinic acetylcholine receptor. Moreover, the toxin inhibits collagen-induced platelet aggregation, with an IC₅₀ of approximately 200 nM. The genomic DNA encoding the γ-bungarotoxin precursor is amplified by polymerase chain reaction (PCR). The gene is organized with three exons separated by two introns, and shares virtually identical overall organization with those reported for α-neurotoxin and cardiotoxin genes, including similar intron insertions. The intron sequences of these genes share sequence identity up to 85%, but the exon sequences are highly variable. These observations suggest that γ-bungarotoxin, α-neurotoxins, and cardiotoxins originate from a common ancestor, and the evolution of these genes shows a tendency to diversify the functions of snake venom proteins.     

Identification and characterization of a phospholipase A2 from the venom of the Saw-scaled viper: Novel bactericidal and membrane damaging activities

Phospholipase A₂ (PLA₂), a common toxic component of snake venom, has been implicated in various pharmacological effects. In this study, a basic myotoxic PLA₂, named EcTx-I was isolated from Echis carinatus snake venom by using gel filtration on Superdex G-75, and reverse phase HPLC on C18 and C8 Sepharose columns. PLA₂, EcTx-I was 13,861.72 molecular weight as estimated by MALDI-TOF (15 kD by SDS-PAGE), and consisted of 121 amino acid residues cross-linked by seven disulfide bonds. The N-terminal sequences revealed significant homology with basic myotoxic PLA₂s from other snake venoms. The purified PLA₂ EcTx-I was evaluated (250 μg/ml) for bactericidal activity of a wide variety of human pathogens against Burkholderia pseudomallei (KHW&TES), Enterobacter aerogenes, Escherichia coli, Proteus vulgaris, Proteus mirabilis, Pseudomonas aeruginosa and Staphylococcus aureus. EcTx-I showed strong antibacterial activity against B. pseudomallei (KHW) and E. aerogenes among the tested bacteria. Other Gram-negative and Gram-positive bacteria showed only a moderate effect. However, the Gram-positive bacterium E. aerogenes failed to show any effect on EcTx-I protein at tested doses. The most significant bacteriostatic and bactericidal effect of EcTx-I was observed at MICs of >15 μg/ml against (B. pseudomallei, KHW) and MICs >30 μg/ml against E. aerogenes. Mechanisms of bactericidal and membrane damaging effects were proved by ultra-structural analysis. EcTx-I was able to induce cytotoxicity on THP-1 cells in vitro as well as lethality in BALB/c mice. EcTx-I also induced mild myotoxic effects on mouse skin, but was devoid of hemolytic effects on human erythrocytes up to 500 μg/ml. It is shown that the toxic effect induced by E. carinatus venom is due to the presence of myotoxic PLA₂ (EcTx-I). The result also corroborates the hypothesis of an association between toxic and enzymatic domains. In conclusion, EcTx-I displays a heparin binding C-terminal region, which is probably responsible for the cytotoxic and bactericidal effects.     

Accelerated Evolution and Molecular Surface of Venom Phospholipase A2 Enzymes

Multiple phospholipase A₂ (PLA₂) isoenzymes found in a single snake venom induce a variety of pharmacological effects. These multiple forms are formed by gene duplication and accelerated evolution of exons. We examined the amino acid sequences of 127 snake venom PLA₂ enzymes and their homologues to study in which location most natural substitutions occur. Our data show that hot spots of amino acid substitutions in this group of proteins occur mostly on the surface. A logistic model correlating the substitution rates of each amino acid residue with their surface accessibility indicates that the probability of natural substitutions occurring in the fully exposed residue is 2.6–3.5 times greater than that of substitutions occurring in buried residues. These surface substitutions play a significant role in the evolution of new PLA₂ isoenzymes by altering the specificity of targeting to various tissues or cells, resulting in distinct pharmacological effects. Thus natural substitutions in PLA₂ enzymes, in contrast to popular belief, are not random substitutions but appear to be directed toward modifying the molecular surface. Received: 11 May 1998 / Accepted: 29 June 1998     

N49 phospholipase A2, a unique subgroup of snake venom group II phospholipase A2

A novel phospholipase A₂ (PLA₂) with Asn at its site 49 was purified from the snake venom of Protobothrops mucrosquamatus by using SP-Sephadex C25, Superdex 75, Heparin-Sepharose (FF) and HPLC reverse-phage C₁₈ chromatography and designated as TM-N49. It showed a molecular mass of 13.875 kDa on MALDI-TOF. TM-N49 does not possess enzymatic, hemolytic and hemorrhagic activities. It fails to induce platelet aggregation by itself, and does not inhibit the platelet aggregation induced by ADP. However, it exhibits potent myotoxic activity causing inflammatory cell infiltration, severe myoedema, myonecrosis and myolysis in the gastrocnemius muscles of BALB/c mice. Phylogenetic analysis found that that TM-N49 combined with two phospholipase A₂s from Trimeresurus stejnegeri, TsR6 and CTs-R6 cluster into one group. Structural and functional analysis indicated that these phospholipase A₂s are distinct from the other subgroups (D49 PLA₂, S49 PLA₂ and K49 PLA₂) and represent a unique subgroup of snake venom group II PLA₂, named N49 PLA₂ subgroup.     

Insights on the structure of native CNF,an endogenous phospholipase A2 inhibitor from Crotalus durissus terrificus, the South American rattlesnake

Several snake species possess endogenous phospholipase A₂ inhibitors (sbPLIs) in their blood plasma, the primary role of which is protection against an eventual presence of toxic phospholipase A₂ (PLA₂) from their venom glands in the circulation. These inhibitors have an oligomeric structure of, at least, three subunits and have been categorized into three classes (α, β and γ) based on their structural features. SbγPLIs have been further subdivided into two subclasses according to their hetero or homomeric nature, respectively. Despite the considerable number of sbγPLIs described, their structures and mechanisms of action are still not fully understood. In the present study, we focused on the native structure of CNF, a homomeric sbγPLI from Crotalus durissus terrificus, the South American rattlesnake. Based on the results of different biochemical and biophysical experiments, we concluded that, while the native inhibitor occurs as a mixture of oligomers, tetrameric arrangement appears to be the predominant quaternary structure. The inhibitory activity of CNF is most likely associated with this oligomeric conformation. In addition, we suggest that the CNF tetramer has a spherical shape and that tyrosinyl residues could play an important role in the oligomerization. The carbohydrate moiety, which is present in most sbγPLIs, is not essential for the inhibitory activity, oligomerization or complex formation of the CNF with the target PLA₂. A minor component, comprising no more than 16% of the sample, was identified in the CNF preparations. The amino-terminal sequence of that component is similar to the B subunits of the heteromeric sbγPLIs; however, the role played by such molecule in the functionality of the CNF, if any, remains to be determined.     

Interisland Mutation of a Novel Phospholipase A<Subscript>2</Subscript> from <Emphasis Type="Italic">Trimeresurus flavoviridis</Emphasis> Venom and Evolution of Crotalinae Group II Phospholipases A<Subscript>2</Subscript>

Trimeresurus flavoviridis (Crotalinae) snakes inhabit the southwestern islands of Japan: Amami-Oshima, Tokunoshima, and Okinawa. Affinity and conventional chromatographies of Amami-Oshima T. flavoviridis venom led to isolation of a novel phospholipase A₂ (PLA₂). This protein was highly homologous (91%) in sequence to trimucrotoxin, a neurotoxic PLA₂, which had been isolated from T. mucrosquamatus (Taiwan) venom, and exhibited weak neurotoxicity. This protein was named PLA-N. Its LD₅₀ for mice was 1.34 µg/g, which is comparable to that of trimucrotoxin. The cDNA encoding PLA-N was isolated from both the Amami-Oshima and the Tokunoshima T. flavoviridis venom-gland cDNA libraries. Screening of the Okinawa T. flavoviridis venom-gland cDNA library with PLA-N cDNA led to isolation of the cDNA encoding one amino acid-substituted PLA-N homologue, named PLA-N(O), suggesting that interisland mutation occurred and that Okinawa island was separated from a former island prior to dissociation of Amami-Oshima and Tokunoshima islands. Construction of a phylogenetic tree of Crotalinae venom group II PLA₂s based on the amino acid sequences revealed that neurotoxic PLA₂s including PLA-N and PLA-N(O) form an independent cluster which is distant from other PLA₂ groups such as PLA₂ type, basic [Asp⁴⁹]PLA₂ type, and [Lys⁴⁹]PLA₂ type. Comparison of the nucleotide sequence of PLA-N cDNA with those of the cDNAs encoding other T. flavoviridis venom PLA₂s showed that they have evolved in an accelerated manner. However, when comparison was made within the cDNAs encoding Crotalinae venom neurotoxic PLA₂s, their evolutionary rates appear to be reduced to a level between accelerated evolution and neutral evolution. It is likely that ancestral genes of neurotoxic PLA₂s evolved in an accelerated manner until they had acquired neurotoxic function and since then they have evolved with less frequent mutation, possibly for functional conservation. The nucleotide sequences reported in this paper are available from the GenBank/EMBL/DDBJ databases under accession numbers AB102728 and AB102729.     

Phospholipases A2 isolated from snake venoms block acetylcholine-elicited currents in identified Lymnaea stagnalis neurons

Phospholipases A₂ (PLA₂s) are the most abundant family of snake venom proteins and play a significant role in prey envenomation. Their content in venoms is rather high. PLA₂s not only have enzyme activity but exhibit other types of biological activities including neurotoxicity. We have earlier shown that a protein bitanarin from the venom of the puff adder Bitis arietans is capable to block the responses of Lymnaea stagnalis neurons to acetylcholine and represents an active PLA₂ at the same time. Further investigation of PLA₂s isolated from the venoms of snakes of two families revealed their capability to interact with nicotinic acetylcholine receptors (nAChRs): PLA₂ from Vipera ursinii (Viperidae family), Naja kaouthia, and Bungarus fasciatus (Elapidae family) suppressed acetylcholine-induced current in identified neurons of L. staganlis. The effect was evident at PLA₂ concentration in the range of tens micromoles. The data obtained suggest the presence in a PLA₂ molecule of a site interacting with nAChR and a possible involvement of nAChR block in toxic action of PLA₂s.