A Chromosome-Level Genome Assembly of the Reef Stonefish (Synanceia verrucosa) Provides Novel Insights into Stonustoxin (sntx) Genes.

Reef stonefish (Synanceia verrucosa) is one of the most venomous fishes, but its biomedical study has been restricted to molecular cloning and purification of its toxins, instead of high-throughput genetic research on related toxin genes. In this study, we constructed a chromosome-level haplotypic genome assembly for the reef stonefish. The genome was assembled into 24 pseudo-chromosomes, and the length totaled 689.74 Mb, reaching a contig N50 of 11.97 Mb and containing 97.8% of complete BUSCOs. A total of 24,050 protein-coding genes were annotated, of which metalloproteinases, C-type lectins, and stonustoxins (sntx) were the most abundant putative toxin genes. Multitissue transcriptomic and venom proteomic data showed that sntx genes, especially those clustered within a 50-kb region on the chromosome 2, had higher transcription levels than other types of toxins as well as those sntx genes scatteringly distributed on other chromosomes. Further comparative genomic analysis predicted an expansion of sntx-like genes in the Percomorpha lineage including nonvenomous fishes, but Scorpaenoidei species experienced extra independent sntx duplication events, marking the clear-cut origin of authentic toxic stonustoxins. In summary, this high-quality genome assembly and related comparative analysis of toxin genes highlight valuable genetic differences for potential involvement in the evolution of venoms among Scorpaeniformes fishes.

Comparative transcriptome analyses of venom glands from three scorpionfishes.

Scorpionfishes (Scorpaenidae) are a relatively common cause of human envenomation. They often enter coastal waters and their stings can be quite hazardous, provoking extreme pain and causing the victims to take days to recover. There are few genomic resources available for the scorpionfishes. In this study, we elucidated the transcriptomic profile of the venom glands from three different scorpionfish species, namely Scorpaenopsis cirrosa, S. neglecta and S. possi. This is the first report of scorpionfish transcriptomes. After functional and pathway annotation, we employed toxin annotation to identify many species-specific (18, 13 and 19 respectively) and overlapping putative toxins among the three species. Our study represents a significant improvement in the genetic information about the venoms from these three species. Moreover, this work also provides an archive for future studies on evolution of fish toxins and can be used for comparative studies of other fishes.

A Novel Mutant of rLj-RGD3 (rLj-112) Suppressed the Proliferation and Metastasis of B16 Cells through the EGFR Signaling Pathway.

Lj-RGD3, which contains three Arg⁻Gly⁻Asp (RGD) motifs, was first identified from the buccal glands of Lampetra japonica and has been shown to suppress the tumor progression in the previous studies. Apart from the three RGD motifs, Lj-RGD3 is also characterized by its high content of histidine in its amino acid sequence. In order to clarify whether the histidine-rich characterization of Lj-RGD3 is also associated with its anti-tumor activity, mutants were designed in which the three RGD motifs (Lj-112), or all histidines (Lj-27) or both (Lj-26) were deleted. Furthermore, a mutant (Lj-42) in which all histidines and three RGD motifs were respectively substituted with alanines and three Ala⁻Gly⁻Asp (AGD) motifs, as well as a mutant (Lj-41) in which all histidines were substituted with alanines was synthesized to avoid alterations in structure which might further cause changes in the peptides' functions. After recombination and purification, recombinant Lj-112 (rLj-112), recombinant Lj-27 (rLj-27), recombinant Lj-41 (rLj-41), and recombinant Lj-RGD3 (rLj-RGD3) exhibited anti-proliferative activity in B16 cells, respectively; while recombinant Lj-26 (rLj-26) and recombinant Lj-42 (rLj-42) did not affect the proliferation of B16 cells significantly. In addition, the anti-proliferative activity of rLj-112 in B16 cells was due to apoptosis. Typical apoptosis features were observed, including chromatin condensation, fragmented DNA, and increased levels of cleaved caspase 3/caspase 7/nuclear enzyme poly (ADP-ribose) polymerase (PARP) in B16 cells. Similar to rLj-RGD3, rLj-112 was also capable of suppressing the migration and invasion of B16 cells by disturbing the F-actin arrangement. After labeling with FITC, rLj-112 was found localized in the cytoplasm of B16 cells, which induced the internalization of epidermal growth factor receptor (EGFR), suggesting that rLj-112 might block the EGFR mediated signaling pathway. Actually, the phosphorylation level of EGFR and its downstream signal molecules including Akt, PI3K, p38, and ERK1/2 was reduced in the rLj-112 treated B16 cells. In vivo, rLj-112 also inhibited the growth, weight, and volume of the tumors in B16 xenografted C57BL/6 mice without reducing their body weight, indicating that rLj-112 might be safe and might be used as an effective anti-tumor drug in the near future.

Expression of Recombinant Stonustoxin Alpha Subunit and Preparation of polyclonal antiserum for Stonustoxin Neutralization Studies.

Stonustoxin (SNTX) is a lethal protein found in stonefish venom, responsible for many of the symptoms associated with stonefish envenomation. To counter stonefish venom challenges, antivenom is a well-established and effective solution. In this study, we aimed to produce the recombinant alpha subunit protein of Stonustoxin from Synanceia horrida and prepare antibodies against it The SNTXα gene sequence was optimized for E. coli BL21 (DE3) expression and cloned into the pET17b vector. Following purification, the recombinant protein was subcutaneously injected into rabbits, and antibodies were extracted from rabbit´s serum using a G protein column As a result of codon optimization, the codon adaptation index for the SNTXα cassette increased to 0.94. SDS-PAGE analysis validated the expression of SNTXα, with a band observed at 73.5 kDa with a yield of 60 mg/l. ELISA results demonstrated rabbits antibody titers were detectable up to a 1:256,000 dilution. The isolated antibody from rabbit´s serum exhibited a concentration of 1.5 mg/ml, and its sensitivity allowed the detection of a minimum protein concentration of 9.7 ng. In the neutralization assay the purified antibody against SNTXα protected mice challenged with 2 LD50. In conclusion, our study successfully expressed the alpha subunit of Stonustoxin in a prokaryotic host, enabling the production of antibodies for potential use in developing stonefish antivenom.

Molecular phylogeny and evolution of the proteins encoded by coleoid (cuttlefish, octopus, and squid) posterior venom glands.

In this study, we report for the first time a detailed evaluation of the phylogenetic history and molecular evolution of the major coleoid toxins: CAP, carboxypeptidase, chitinase, metalloprotease GON-domain, hyaluronidase, pacifastin, PLA2, SE-cephalotoxin and serine proteases, with the carboxypeptidase and GON-domain documented for the first time in the coleoid venom arsenal. We show that although a majority of sites in these coleoid venom-encoding genes have evolved under the regime of negative selection, a very small proportion of sites are influenced by the transient selection pressures. Moreover, nearly 70 % of these episodically adapted sites are confined to the molecular surface, highlighting the importance of variation of the toxin surface chemistry. Coleoid venoms were revealed to be as complex as other venoms that have traditionally been the recipient of the bulk of research efforts. The presence of multiple peptide/protein types in coleoids similar to those present in other animal venoms identifies a convergent strategy, revealing new information as to what characteristics make a peptide/protein type amenable for recruitment into chemical arsenals. Coleoid venoms have significant potential not only for understanding fundamental aspects of venom evolution but also as an untapped source of novel toxins for use in drug design and discovery.

The Natterin Proteins Diversity: A Review on Phylogeny, Structure, and Immune Function.

Since the first record of the five founder members of the group of Natterin proteins in the venom of the medically significant fish Thalassophryne nattereri, new sequences have been identified in other species. In this work, we performed a detailed screening using available genome databases across a wide range of species to identify sequence members of the Natterin group, sequence similarities, conserved domains, and evolutionary relationships. The high-throughput tools have enabled us to dramatically expand the number of members within this group of proteins, which has a remote origin (around 400 million years ago) and is spread across Eukarya organisms, even in plants and primitive Agnathans jawless fish. Overall, the survey resulted in 331 species presenting Natterin-like proteins, mainly fish, and 859 putative genes. Besides fish, the groups with more species included in our analysis were insects and birds. The number and variety of annotations increased the knowledge of the obtained sequences in detail, such as the conserved motif AGIP in the pore-forming loop involved in the transmembrane barrel insertion, allowing us to classify them as important constituents of the innate immune defense system as effector molecules activating immune cells by interacting with conserved intracellular signaling mechanisms in the hosts.

Diversity, phylogenetic distribution, and origins of venomous catfishes.

BACKGROUND: The study of venomous fishes is in a state of relative infancy when compared to that of other groups of venomous organisms. Catfishes (Order Siluriformes) are a diverse group of bony fishes that have long been known to include venomous taxa, but the extent and phylogenetic distribution of this venomous species diversity has never been documented, while the nature of the venoms themselves also remains poorly understood. In this study, I used histological preparations from over 100 catfish genera, basic biochemical and toxicological analyses of fin spine extracts from several species, and previous systematic studies of catfishes to examine the distribution of venom glands in this group. These results also offer preliminary insights into the evolutionary history of venom glands in the Siluriformes. RESULTS: Histological examinations of 158 catfish species indicate that approximately 1250-1625+ catfish species should be presumed to be venomous, when viewed in conjunction with several hypotheses of siluriform phylogeny. Maximum parsimony character optimization analyses indicate two to three independent derivations of venom glands within the Siluriformes. A number of putative toxic peptides were identified in the venoms of catfish species from many of the families determined to contain venomous representatives. These peptides elicit a wide array of physiological effects in other fishes, though any one species examined produced no more than three distinct putative toxins in its venom. The molecular weights and effects produced by these putative toxic peptides show strong similarities to previously characterized toxins found in catfish epidermal secretions. CONCLUSION: Venom glands have evolved multiple times in catfishes (Order Siluriformes), and venomous catfishes may outnumber the combined diversity of all other venomous vertebrates. The toxic peptides found in catfish venoms may be derived from epidermal secretions that have been demonstrated to accelerate the healing of wounds, rather than defensive crinotoxins.

Pardaxin, a fish toxin peptide interaction with a biomimetic phospholipid/polydiacetylene membrane assay.

Pardaxin is a fish toxin belonging to the alpha-helical, pore-forming peptide family, used in toxicological and biophysical research to study toxin-cell and -lipid-artificial membranes interactions. We investigated the membrane interaction of two pardaxin analogues using a colorimetric phospholipid/polydiacetylene biomimetic assay. In this assay, polydiacetylene undergoes visible, concentration dependent, blue-red transformation induced through interactions of pardaxins with the vesicle membrane. Pardaxins P4 and P5, are composed of 33 amino acids, but differ in a single amino acid substitution at the carboxy-terminal (G31 to D31, respectively) known to decrease the pore forming activity. Addition of pardaxins in the colorimetric assay induced dose-dependent color transitions with different kinetics. The colorimetric analysis could distinguish between different pardaxins-membrane interaction profiles, suggesting bilayer surface association for P4 and vesicle membrane penetration for P5. The colorimetric assay could distinguish between pardaxins membrane interaction profiles although circular dichroism spectra of vesicle-interacting pardaxins did not indicate a significant difference in the secondary structure between these two toxin analogues. The colorimetric platform utilized in the present report represents a useful assay with general applications for studying membrane interactions of peptides in general and pore-forming toxins in particular, and may become an important tool for evaluating quantitative toxin structure-activity relationship.

Purification, properties and cDNA cloning of neoverrucotoxin (neoVTX), a hemolytic lethal factor from the stonefish Synanceia verrucosa venom.

A proteinaceous toxin with hemolytic and lethal activities, named neoverrucotoxin (neoVTX), was purified from the venom fluid of stonefish Synanceia verrucosa and its primary structure was elucidated by a cDNA cloning technique. NeoVTX is a dimeric 166 kDa protein composed of alpha-subunit (702 amino acid residues) and beta-subunit (699 amino acid residues) and lacks carbohydrate moieties. Its hemolytic activity is inhibited by anionic lipids, especially potently by cardiolipin. These properties are comparable to those of stonustoxin (SNTX) previously purified from S. horrida. Alignment of the amino acid sequences also reveals that the neoVTX alpha- and beta-subunits share as high as 87 and 95% sequence identity with the SNTX alpha- and beta-subunits, respectively. The distinct differences between neoVTX and SNTX are recognized only in the numbers of Cys residues (18 for neoVTX and 15 for SNTX) and free thiol groups (10 for neoVTX and 5 for SNTX). In contrast, neoVTX considerably differs from verrucotoxin (VTX), a tetrameric 322 kDa glycoprotein, previously purified from S. verrucosa. In addition, the sequence identity of the neoVTX beta-subunit with the reported VTX beta-subunit is 90%, being lower than that with the SNTX beta-subunit.

Occurrence of a stonefish toxin-like toxin in the venom of the rabbitfish Siganus fuscescens.

Rabbitfish belonging to the order Perciformes are well-known venomous fish that are frequently involved in human accidents. However little research has been done into either the whole venom toxicities or the structures and properties of their venom toxins. In this study, we first examined biological activities of the crude venom extract prepared from dorsal spines of Siganus fuscescens, a rabbitfish most commonly found along the coasts of Japan. As a result, the crude venom extract was shown to have mouse-lethal activity, hemolytic activity against rabbit erythrocytes, edema-forming activity and nociceptive activity, similar to the known scorpaeniform fish toxins (stonefish toxins and their analogues). Then, the primary structure of the S. fuscescens toxin was successfully elucidated by the same cDNA cloning strategy as previously employed for the toxins of some scorpaeniform fish (lionfish, devil stinger and waspfish). The S. fuscescens toxin is obviously an analogue of stonefish toxins, being composed of two kinds of subunits, an α-subunit of 703 amino acid residues and a ß-subunit of 699 amino acid residues. Furthermore, the genes encoding both subunits were cloned from genomic DNA and shown to have an architecture of three exons and two introns, as reported for those of the scorpaeniform fish toxins. This study is the first to demonstrate the occurrence of stonefish toxin-like toxins in perciform fish.

The anti-tumor effects of the recombinant toxin protein rLj-RGD3 from Lampetra japonica on pancreatic carcinoma Panc-1 cells in nude mice.

Recombinant Lampetra japonica RGD peptide (rLj-RGD3) is a soluble toxin protein with three RGD (Arg-Gly-Asp) motifs and a molecular weight of 13.5kDa. The aim of this study was to investigate the effects and mechanisms of rLj-RGD3 on tumor growth and survival in pancreatic carcinoma Panc-1 cell-bearing mice. A Panc-1 human pancreatic carcinoma-bearing nude mouse model was successfully generated, and the animals were treated with different doses of rLj-RGD3 for 3 weeks. The volume and weight of the subcutaneous tumors, the survival of the nude mice, histopathological changes, the intratumoral MVD, the number of apoptotic Panc-1 cells, and apoptosis-related proteins and gene expressions were determined. rLj-RGD3 significantly decreased the tumor volumes and weights, and the maximum tumor volume and weight IR values were 53.2% (p<0.001) and 55.9% (p<0.001), respectively. The life expectancy of Panc-1-bearing nude mice treated with rLj-RGD3 was increased by 56.3% (p<0.001). Meanwhile, rLj-RGD3 promoted the expression of Bax, caspase-3, and caspase-9 and inhibited Bcl-2 and VEGF expression. In addition, rLj-RGD3 did not change FAK, PI3K and Akt expression, but p-FAK, p-PI3K and p-Akt, levels were down-regulated. These results show that rLj-RGD3 induced potent anti-tumor activity in vivo and suppressed the growth of transplanted Panc-1 cells in a nude mouse model, implying that rLj-RGD3 may serve as a potent clinical therapeutic agent for human pancreatic carcinoma.

Transcriptome analysis of expressed sequence tags from the venom glands of the fish Thalassophryne nattereri.

Thalassophryne nattereri (niquim) is a venomous fish found on the northern and northeastern coasts of Brazil. Every year, hundreds of humans are affected by the poison, which causes excruciating local pain, edema, and necrosis, and can lead to permanent disabilities. In experimental models, T. nattereri venom induces edema and nociception, which are correlated to human symptoms and dependent on venom kininogenase activity; myotoxicity; impairment of blood flow; platelet lysis and cytotoxicity on endothelial cells. These effects were observed with minute amounts of venom. To characterize the primary structure of T. nattereri venom toxins, a list of transcripts within the venom gland was made using the expressed sequence tag (EST) strategy. Here we report the analysis of 775 ESTs that were obtained from a directional cDNA library of T. nattereri venom gland. Of these ESTs, 527 (68%) were related to sequences previously described. These were categorized into 10 groups according to their biological functions. Sequences involved in gene and protein expression accounted for 14.3% of the ESTs, reflecting the important role of protein synthesis in this gland. Other groups included proteins engaged in the assembly of disulfide bonds (0.5%), chaperones involved in the folding of nascent proteins (1.4%), and sequences related to clusterin (1.5%), as well as transcripts related to calcium binding proteins (1.0%). We detected a large cluster (1.3%) related to cocaine- and amphetamine-regulated transcript (CART), a peptide involved in the regulation of food intake. Surprisingly, several retrotransposon-like sequences (1.0%) were found in the library. It may be that their presence accounts for some of the variation in venom toxins. The toxin category (18.8%) included natterins (18%), which are a new group of kininogenases recently described by our group, and a group of C-type lectins (0.8%). In addition, a considerable number of sequences (32%) was not related to sequences in the databases, which indicates that a great number of new toxins and proteins are still to be discovered from this fish venom gland.

Molecular cloning of grammistins, peptide toxins from the soapfish Pogonoperca punctata, by hemolytic screening of a cDNA library.

A novel method, based on the hemolytic screening of a cDNA phage library, was developed to isolate cDNAs encoding grammistins (antibacterial peptide toxins) of the soapfish Pogonoperca punctata. As a result, cDNAs encoding six grammistins were isolated and elucidated for their nucleotide sequences. In common with the grammistins, the precursor protein is composed of a highly conserved signal peptide, a considerably conserved propeptide that is characterized to contain a pair of basic residues (Lys-Arg) at plural positions including the C-terminus and one copy of a mature peptide. This precursor organization is similar to those of dermaseptins, antibacterial peptides from the frog skin.

Complete amino-acid sequence of the beta-subunit of VTX from venom of the stonefish (Synanceia verrucosa) as identified from cDNA cloning experiments.

A cDNA encoding a subunit of the verrucotoxin (VTX) has been identified from a cDNA library derived from stonefish venom glands. It encodes a polypeptide of 708 amino-acid residues, followed by a 3'-untranslated region of 895 bp long. The ORF contains the complete mature sequence of the beta-subunit of the VTX, as inferred from both the presence of an identical N-terminus sequence and 96% homology among the 506 amino terminus residues found in the partial sequence of the beta-subunit of the stonustoxin from Synanceia horrida (Ghadessy, F.J., Jeyaseelan, K., Chung, M.C.M., Khoo, H.E., and Yuen, R. (1994) Toxicon 32, 1684-1688). Upstream the mature sequence, we noticed the presence of an incomplete peptide of a 13 amino acids, whose unusual primary structure supports the idea of the existence of a propeptide and/or of a new secretion signal.

Further isolation and characterization of grammistins from the skin secretion of the soapfish Grammistes sexlineatus.

Soapfishes contain peptide toxins (grammistins) in the skin secretion. Two grammistins (Gs 1 and Gs 2) and six grammistins (Pp 1, Pp 2a, Pp 2b, Pp 3, Pp 4a and Pp 4b) have already been isolated from Grammistes sexlineatus and Pogonoperca punctata, respectively. In this study, five grammistins (Gs A-E), together with grammistins Gs 1 and Gs 2, were further isolated from G. sexlineatus by gel filtration and reverse-phase HPLC. Sequence analyses revealed that grammistins Gs A (28 residues) and Gs C (26 residues) are analogous to grammistin Pp 3 and grammistin Gs B (12 residues) to grammistin Pp 1, while grammistins Gs D (13 residues) and Gs E (13 residues) are identical with grammistins Pp 1 and Pp 2b, respectively. Grammistins Gs A-C exhibited antibacterial activity with a broad spectrum against nine species of bacteria in common with the other grammistins but had no hemolytic activity differing from the other grammistins. Grammistins Gs A-E, Gs 1 and Gs 2 could release carboxyfluorescein entrapped within liposomes made of either phosphatidylcholine or phosphatidylglycerol/phosphatidylcholine (3:1), demonstrating their membrane-lytic activity. However, no clear relationship between the membrane-lytic activity and the biological activity of grammistins was recognized.

Isolation, characterization and synthesis of a novel paradaxin isoform.

We report the isolation of a novel pardaxin isoform from the toxic secretion of the Red Sea Moses sole (Pardachirus marmoratus). Mass spectrometrical analysis of the newly purified peptide revealed a different primary structure compared to the previously known pardaxin isoforms. Sequence analysis disclosed an aspartic acid residue instead of glycine at position 31 of the new isoform. According to the novel sequence, a synthetic Asp-31-peptide was compared with the native compound as well as with synthetic Gly-31-pardaxin. The isolated Asp-31-pardaxin isoform and its synthetic analog exhibited identical elution properties during reverse-phase HPLC, as well as similar dose-dependent lytic effects on human erythrocytes at a concentration of 10(-6) to 10(-5)M. The hemolytic activity of Asp-31-pardaxins was lower than that of Gly-31-pardaxin and no synergistic effect between these peptides was found. The additional negative charge introduced by Asp-31 is likely to affect the selectivity of pardaxin pores towards a variety of ions.

A genomic region encoding stonefish (Synanceja horrida) stonustoxin beta-subunit contains an intron.

The polymerase chain reaction (PCR) has been used to amplify a 1899 base pair fragment from stonefish genomic DNA. A comparison of the translated nucleotide sequence of this product with the separately determined N-terminal amino acid sequence of the beta-subunit reveals the presence of a 416 bp intron at Gly 18. The nucleotide sequence following this intron encodes 476 amino acids whose sequence showed no homology to other known toxins. This region, however, contained amino acid sequences identical to internal peptide sequences determined separately from the toxin's beta-subunit.

Toxin gene determination and evolution in scorpaenoid fish.

In this study, we determine the toxin genes from both cDNA and genomic DNA of four scorpaenoid fish and reconstruct their evolutionary relationship. The deduced protein sequences of the two toxin subunits in Sebastapistes strongia, Scorpaenopsis oxycephala, and Sebastiscus marmoratus are about 700 amino acid, similar to the sizes of the stonefish (Synanceia horrida, and Synanceia verrucosa) and lionfish (Pterois antennata and Pterois volitans) toxins previously published. The intron positions are highly conserved among these species, which indicate the applicability of gene finding by using genomic DNA template. The phylogenetic analysis shows that the two toxin subunits were duplicated prior to the speciation of Scorpaenoidei. The precedence of the gene duplication over speciation indicates that the toxin genes may be common to the whole family of Scorpaeniform. Furthermore, one additional toxin gene has been determined in the genomic DNA of Dendrochirus zebra. The phylogenetic analysis suggests that an additional gene duplication occurred before the speciation of the lionfish (Pteroinae) and a pseudogene may be generally present in the lineage of lionfish.

Novel anticandidal activity of a recombinant Lampetra japonica RGD3 protein.

Lj-RGD3, an RGD (Arg-Gly-Asp) toxin protein from the salivary gland of Lampetra japonica, exhibits antifungal activity against Candida albicans. Lj-RGD3 has three RGD motifs and shows homology to histidine-rich glycoprotein. We synthesised two mutant derivatives of Lj-RGD3: Lj-26, which lacks all three RGD motifs and contains no His residues; and Lj-112, which lacks only the three RGD motifs. We investigated the effects of the wild-type and mutated toxins on a gram-positive bacterium (Escherichia coli), a gram-negative bacterium (Staphylococcus aureus), and a fungus (C. albicans). rLj-RGD3 and its mutants exhibited antifungal but not antibacterial activity, as measured by a radial diffusion assay. The C. albicans inhibition zone induced by rLj-112 was larger than that induced by the other proteins, and its inhibitory effect on C. albicans was dose-dependent. In viable-count assays, the rLj-112 MIC was 7.7 micrometer, whereas the MIC of the positive control (ketoconazole) was 15 micrometer. Time-kill kinetics demonstrated that rLj-112 effectively killed C. albicans at 1× and 2× MIC within 12 and 6 h, respectively. Electron microscopy analysis showed that rLj-RGD3 and rLj-112 induced C. albicans lysis. Our results demonstrate a novel anticandidal activity for rLj-RGD3 and its mutant derivatives.

Some properties and cDNA cloning of proteinaceous toxins from two species of lionfish (Pterois antennata and Pterois volitans).

Lionfish, members of the genera Pterois, Parapterois and Dendrochirus, are well known to be venomous, having venomous glandular tissues in dorsal, pelvic and anal spines. The lionfish toxins have been shown to cross-react with the stonefish toxins by neutralization tests using the commercial stonefish antivenom, although their chemical properties including structures have been little characterized. In this study, an antiserum against neoverrucotoxin, the stonefish Synanceia verrucosa toxin, was first raised in a guinea pig and used in immunoblotting and inhibition immunoblotting to confirm that two species of Pterois lionfish (P. antennata and P. volitans) contain a 75kDa protein (corresponding to the toxin subunit) cross-reacting with neoverrucotoxin. Then, the amino acid sequences of the P. antennata and P. volitans toxins were successfully determined by cDNA cloning using primers designed from the highly conserved sequences of the stonefish toxins. Notably, either α-subunits (699 amino acid residues) or ß-subunits (698 amino acid residues) of the P. antennata and P. volitans toxins share as high as 99% sequence identity with each other. Furthermore, both α- and ß-subunits of the lionfish toxins exhibit high sequence identity (70-80% identity) with each other and also with the ß-subunits of the stonefish toxins. As reported for the stonefish toxins, the lionfish toxins also contain a B30.2/SPRY domain (comprising nearly 200 amino acid residues) in the C-terminal region of each subunit.