Skip to main content
NCBI home page
The Journal of Venomous Animals and Toxins Including Tropical Diseases logoLink to The Journal of Venomous Animals and Toxins Including Tropical Diseases
. 2021 Sep 24;27:e20210024. doi: 10.1590/1678-9199-JVATITD-2021-0024

De novo venom gland transcriptomics of Calliophis bivirgata flaviceps: uncovering the complexity of toxins from the Malayan blue coral snake

Praneetha Palasuberniam 1,2, Kae Yi Tan 3, Choo Hock Tan 1
PMCID: PMC8476087  PMID: 34616441

Abstract

Background:

The Malayan blue coral snake, Calliophis bivirgata flaviceps, is a medically important venomous snake in Southeast Asia. However, the complexity and diversity of its venom genes remain little explored.

Methods:

To address this, we applied high-throughput next-generation sequencing to profile the venom gland cDNA libraries of C. bivirgata flaviceps. The transcriptome was de novo assembled, followed by gene annotation, multiple sequence alignment and analyses of the transcripts.

Results:

A total of 74 non-redundant toxin-encoding genes from 16 protein families were identified, with 31 full-length toxin transcripts. Three-finger toxins (3FTx), primarily delta-neurotoxins and cardiotoxin-like/cytotoxin-like proteins, were the most diverse and abundantly expressed. The major 3FTx (Cb_FTX01 and Cb_FTX02) are highly similar to calliotoxin, a delta-neurotoxin previously reported in the venom of C. bivirgata. This study also revealed a conserved tyrosine residue at position 4 of the cardiotoxin-like/cytotoxin-like protein genes in the species. These variants, proposed as Y-type CTX-like proteins, are similar to the H-type CTX from cobras. The substitution is conservative though, preserving a less toxic form of elapid CTX-like protein, as indicated by the lack of venom cytotoxicity in previous laboratory and clinical findings. The ecological role of these toxins, however, remains unclear. The study also uncovered unique transcripts that belong to phospholipase A2 of Groups IA and IB, and snake venom metalloproteinases of PIII subclass, which show sequence variations from those of Asiatic elapids.

Conclusion:

The venom gland transcriptome of C. bivirgata flaviceps from Malaysia was de novo assembled and annotated. The diversity and expression profile of toxin genes provide insights into the biological and medical importance of the species.

Keywords: Three-finger toxins, Delta-elapitoxin-CB1a, Calliotoxin, Maticotoxin, Snakebite, Envenomation

Background

Snake venoms consist of toxins that are primarily proteins and peptides with diverse pharmacological activities [1]. These toxins are products of venom evolution, representing successful traits critical for the survival of various snake species [2]. The evolvability of venom enables the snakes to adapt to different niches and, in turn, facilitates ecological speciation [3]. Worldwide, approximately 300 venomous snake species are considered medically important as they are implicated in snakebite envenomation, a life-threatening condition caused by the venom inoculated in snakebite victims [4, 5]. It is estimated that 1.8-2.7 million people are affected by snakebite envenomation, resulting in 81,000 to 138,000 deaths annually [5, 6].

In Asia, neurotoxicity is a typical manifestation of envenomation caused by elapid snakes such as cobras, king cobra, kraits and sea snakes. In addition, there is a unique clade of elapids, namely the Asiatic coral snakes, that are often considered less medically important due to their infrequent encounter with human and low fatality rate of envenomation [5]. As such, the venom properties of Asiatic coral snakes are generally less studied in comparison to most other elapids. This limits our understanding of the biological significance and potential application of venoms from these evolutionarily distinct coral snakes in Asia.

The Asiatic (Old World) coral snakes are diverse, comprising three genera, i.e., Calliophis, Hemibungarus and Sinomicrurus [7]. Among these, the blue coral snake (Calliophis bivirgata) is perhaps the most well-known and attractive owing to its unique morphology with striking coloration - its head, tail and underside (ventral surface) are red, and its back is dark blue to black in color flanked by a pair of alluring blue streaks alongside its body [8]. C. bivirgata has a pair of exceptionally long venom glands that extends beyond the jaw distally for one-third the length of the body (Figure 1), and it is ophiophagic (feeding on snakes) [9]. They are often fossorial, hiding beneath rainforest grounds and this makes them very elusive. Although C. bivirgata is often described as reclusive and less aggressive, it can be hostile and ready to bite when provoked. With its extraordinarily long venom glands, an adult C. bivirgata can yield a large amount of venom (~150 mg) in a single milking [10], implying potential medical complications upon severe envenomation [11-13].

Figure 1. Morphology and distribution of Malayan blue coral snake (Calliophis bivirgata). (A) Dorsal view showing red coloration of the head and tail (which is continuous on the ventral surface), with the back in black or dark blue, flanked by a pair of alluring blue streaks alongside the body. (B) Dissection revealing a pair of exceptionally elongated venom glands in the snake. (C) Areas shaded in green depicting the native distribution of Calliophis subspecies in Southeast Asia based on the Reptile Database [16]. Photos by Choo Hock Tan.

Figure 1.

Open in a new tab

C. bivirgata is endemic to Southeast Asia and three subspecies are recognized across different localities: C. bivirgata flaviceps in Thailand, Peninsular Malaysia, and Sumatra; C. bivirgata tetrataenia in Borneo; and C. bivirgata bivirgata in Java [14-16] (Figure 1 depicts the native range of the species in Southeast Asia). Among these subspecies, C. bivirgata flaviceps (found in Thailand and Peninsular Malaysia) has been reported to cause human fatalities [11, 12]. A recent proteomic study showed that Malaysian C. bivirgata flaviceps venom contains high amounts of cytotoxin-like proteins (22.6%) and phospholipases A2 (41.1%) which could be instrumental in the pathophysiology of envenomation [15]. Other studies further detected a sodium channel antagonist, a delta-neurotoxin called calliotoxin in C. bivirgata venom, indicating that C. bivirgata envenomation can potentially result in neurotoxicity [10, 17]. The C. bivirgata venom, however, showed negligible immunological cross-reactivity with various elapid antivenoms that were raised against non-coral snake species in Asia, despite having abundant three-finger toxins and phospholipases A2 as the venoms of most other elapid species [18]. These reports unveiled the real hidden threat in C. bivirgata envenomation: there is no effective antivenom available to treat the envenomation, and an inappropriate antivenom given to a patient may result in fatal hypersensitive reactions.

The proteome and antigenicity of C. bivirgata venom indicate that the toxin genes of this species are evolutionarily divergent from the other elapids. This has implications on the medical importance of this species in terms of pathophysiology and treatment of envenomation. To better understand the diversity and functions of its toxins, this study investigated the de novo venom gland transcriptome of C. bivirgata flaviceps (a subspecies from Peninsular Malaysia) through a high-throughput next-generation sequencing approach and deep data mining. In addition, the findings were compared to a recent study of three-finger toxin evolution in this species which also employed the venom gland transcriptomic method [17]. Uncovering the complexity and the diversity of toxin genes in this unique species enriches our current knowledge base of snake venoms, and provides deeper insights into the clinical, biomedical, and evolutionary significance of the Asiatic coral snakes [19].

Methods

Preparation of snake venom gland tissue

The Malayan blue coral snake, C. bivirgata flaviceps was a male adult specimen from Pahang in the central region of Peninsular Malaysia. The snake was milked four days before venom gland removal to promote maximal transcription [20]. The venom glands were collected following euthanasia and sectioned into dimensions of 5 x 5 mm. The sectioned tissue was immersed in RNAlater Solution (Ambion, TX, USA) at 4 (C overnight followed by −80 (C until further use. The study was carried out in line with protocols approved by the Institutional Animal Use and Care Committee (IACUC) of University of Malaya, Malaysia (Approval code: #2013-11-12/PHAR/R/TCH).

Extraction and purification of total RNA

The venom gland tissue was homogenized in a 1 ml glass homogenizer with TRIzol solution (Invitrogen, CA, USA), followed by adding 20% chloroform to separate the RNA (aqueous state) from the DNA and proteins (interface and organic states) [21]. The sample was centrifuged and treated with RNA-free DNAase I (Thermo Fisher Scientific, MA, USA), and the RNA was precipitated with isopropyl alcohol, followed by washing with 70% ethanol [22]. The quality of the purified total RNA was assessed using Agilent 2100 Bioanalyzer (Agilent RNA 6000 NanoKit) (Agilent Technologies, Waldbronn, Germany). The RNA integrity number of the sample was 8.9 (Grade A), indicating that the quality of RNA was in good condition for further downstream transcriptomic analysis.

Construction of cDNA library

The cDNA library construction was carried out with MGIEasy RNA Library Prep Set (Item No: 1000006383), as per manufacturer’s instructions. In brief, mRNA was purified with Dynabeads® mRNA Purification Kit using magnetic beads. Enriched poly(A)+ mRNA isolated from the total venom gland RNA was adopted for cDNA construction. The isolated mRNA was fragmented into short fragments, which acted as templates for cDNA synthesis. Quantitative validation was conducted using ABI StepOnePlus Real-time PCR system (Applied Biosystem, CA, USA), which quantified adaptor-ligated sequences whereas qualitative validation was done using Agilent 2100 Bioanalyzer (Agilent Technologies, Waldbronn, Germany) for quality control of cDNA. The sample was then sequenced in a single lane on the BGISeq-500 platform (BGI Genomics Co., Ltd., Shenzhen, China) with 100-base-pair, paired-end reads.

Filtration of raw sequenced reads

Sequenced data generated from BGISeq-500 platform were transformed into raw reads in a FASTQ format. Raw reads were filtered as part of the quality control process in the pre-analysis stage [23]. Raw reads with unknown bases of more than 5%, reads containing adaptor sequences and low-quality reads which possessed reads containing more than 20% bases with quality score less than 15 were removed before downstream transcriptome assembly.

Assembly of de novo transcriptome

The de novo ‘shot-gun’ transcriptome assembly was performed using a short-reads assembly program, Trinity version 2.0.6, which includes three software modules, Inchworm, Chrysalis, and Butterfly [24, 25], to reconstruct long scaffolds from single reads. Trinity was the assembly method of choice in this study as this program has been shown to recover good transcripts after passing quality filters while also recovering relatively long transcripts at its highest specificity [26, 27]. The clean read Q20 score, a point of reference for quality control assessment was obtained as a benchmark for successful de novo assembly of the transcriptome.

Clustering of transcripts

Unigenes obtained from Trinity were processed for sequence splicing and removal of redundant reads utilizing TIGR Gene Indices Clustering Tool (TGICL), version 2.0.6, to isolate non-redundant (NR) transcripts at the longest length [28]. Transcripts that shared nucleotide sequence similarity of more than 70% were grouped into clusters (transcript ID with the prefix CL labelled as contigs) whereby those sharing less than 70% similarity were labelled as singletons (transcript ID with a prefix of Unigene).

For functional annotation, all transcripts were subjected to BLASTx (Basic Local Alignment Search Tool-x) applying NCBI non-redundant database (NR), with a cut-off value of E <10-5. The coding regions of transcripts were determined by referencing to the highest-ranked proteins.

Quantifying transcript abundance

Clean reads were aligned to Unigene using Bowtie2, version 2.2.5 [29]. The gene expression levels were then calculated using RNA-seq with expectation maximization (RSEM) tool, version 1.2.12 [30]. Fragments per kilobase of exon model per million reads mapped (FPKM) were used to determine the transcript abundance for identified genes [31]. FPKM is the summation of normalized read counts based on gene length and the total number of mapped reads. The data was obtained using RSEM tool in conjunction with Trinity based on a computational formula:

FPKM of gene A =106BNC1000

FPKM is the expression of gene A; B is the number of fragments/reads which are aligned to gene A; N is the total number of fragments/reads that are aligned to all genes; C is the base number in the coding sequence of gene A.

Categorization of transcripts

The de novo assembled transcripts were subjected to BLASTx search to obtain the closest resembling sequences from the NR protein database for classification based on functional annotations. The transcripts (Unigenes) were then sifted to remove those with an FPKM value of less than 1, followed by categorization into three groups: “toxins”, “non-toxins” and “unidentified” as previously described [32-34] (Additional file 1). “Toxin” transcripts were recruited by toxin-related keywords search against the annotated transcripts [33, 35, 36]. “Non-toxin” and “unidentified” groups contain transcripts of cellular proteins or house-keeping genes, and transcripts that could not be identified, respectively. The redundancy of gene expression was determined by dividing the total FPKM of each group by the total number of transcripts in the respective group of transcripts [34]. In the toxin group, the amino acid sequences were used to further validate the toxin identity through BLASTp suite (Basic Local Alignment Search Tool-Protein) in the UniProtKB (Universal Protein Resource Knowledgebase) database platform. The transcripts were searched against Serpentes database (taxid: 8570) and validated based on the lowest E-score value with the highest percentage of sequence similarity (updated as of March 23, 2020). The transcripts and sequences, clustered into different toxin families, and information of full-length transcripts, were provided in Additional file 2.

Multiple sequence alignment

Multiple sequence alignment was conducted using Jalview software (version 2.11.1.4) [37] and MUSCLE (Multiple Sequence Comparison by Log-Expectation) [38] program on amino acid sequences of toxins. Sequences of related species used in multiple sequence alignment were retrieved from UniProtKB depository (http://www.uniprot.org/). The sequences and species selected for comparison were based on toxinological relevance and purpose to elucidate similarity and variation between comparing sequences.

Selection pressure analysis

Sequences of interest were aligned using Mega X (version 10.0.5). Selection pressure was then analyzed using pairwise distances with amino acid substitution and Maximum Composite Likelihood model. Non-synonymous and synonymous (dN/dS) substitution rates were obtained.

Results and discussion

Sequencing and de novo transcriptome assembly

De novo sequencing of the cDNA library of the Malayan blue coral snake (C. bivirgata flaviceps) venom gland tissue yielded a total of 50,850,478 clean reads. Assembly of the de novo short reads created 79,142 contigs (N50 = 1,640) that were connected to form 52,809 transcripts (N50 = 1,906). Output and quality metrics of RNA sequencing were provided in Additional file 3. The accuracy of sequencing indicative of successful de novo venom gland transcriptome was validated by the base call accuracy of Q20 percentage at 98.53%.

The transcripts were filtered at the FPKM (fragments per kilobase per million mapped reads) of ≥ 1 and yielded 35,766 transcripts. Based on BLASTx search, the transcripts were assigned into three categories: (a) “toxin”; (b) “non-toxin”; and (c) “unidentified” (Table 1; Figure 2A). Transcripts in the “toxin” category encoded known and putative snake toxins, and these dominated the transcriptome by a total FPKM of 44.46%. Transcripts in the “non-toxin” category encoded proteins with no known toxic activities in envenomation, and these constituted 40.09% of the total FPKM. Meanwhile, the “unidentified” category (15.45% of total FPKM) included transcripts with no identifiable hits from the BLASTx search. The high expression of toxin transcripts (dominating virtually half of the venom gland transcriptome) in the venom gland of this species is consistent with observations reported in Micrurus spp. (American coral snakes) whose toxin gene transcription accounted for 46-61% of the venom gland transcriptome [39, 40].

Table 1. Overview of transcript classification and expression in de novo venom gland transcriptome of C. bivirgata flaviceps.

Total number of transcripts at fragments per kilobase of exon model per million mapped reads (FPKM) > 1 35,766
Categories Toxin Non-toxin Unidentified
Number of transcripts 74 19,331 16,360
Relative abundance of transcripts (% of total FPKM) 44.46 40.09 15.45
Redundancy (average FPKM/transcript) 5,627.03 19.42 8.85
Open in a new tab

Figure 2. Venom gland transcriptome of Calliophis bivirgata flaviceps from Malaysia. (A) Abundance (in percentage of total FPKM) and redundancy (average FPKM/transcript) of transcripts according to “toxin”, “non-toxin” and “unidentified” categories. (B) Expression profile of toxin transcripts according to protein families (in percentage of total toxin FPKM). The percentages indicate the relative abundances of transcripts based on expression levels in FPKM, as outlined in the method. FPKM: fragments per kilobase of transcript per million mapped reads; 3FTx: three-finger toxin; NTX: neurotoxin; CTX: cytotoxin; KSPI: Kunitz-type serine protease inhibitor; VES: vespryn; SVMP: snake venom metalloproteinase; svPLA2: snake venom phospholipase A2; CYS: cystatin; PDE: phosphodiesterase; NAP: natriuretic peptide; AP: aminopeptidase; NEP: neprilysin; WAP: waprin; DPP: dipeptidyl peptidase; 5’NUC: 5’nucleotidase; PLB: phospholipase B; SVSP: snake venom serine protease; HYA: hyaluronidase.

Figure 2.

Open in a new tab

Expression of toxin genes in C. bivirgata flaviceps venom gland

A total of 74 distinct transcripts were identified in the “toxin” category. These transcripts were clustered by sequence similarities and relevance of snake venom function into 16 different families of toxin genes (Table 2). Although the total number of all toxin transcripts was only 74, the high expression of all toxins contributed to an exceptionally high redundancy (on average, 5,627.03 FPKM/toxin transcript) in contrast to the much lower levels noted in the non-toxin and unidentified gene groups (19.42 FPKM/transcript and 8.85 FPKM/transcript, respectively) (Figure 2A), consistent with the high activity of toxin gene transcription in the venom gland tissue of the snake.

Table 2. Overview of toxin gene families and subtypes in the venom gland transcriptome of Calliophis bivirgata flaviceps.

Toxin gene families/subtypes Species and annotation based on sequence similarities Transcript abundancea (non-redundant transcript)
Three-finger toxin (3FTx) 94.19 (20)
Short-chain 3FTx 94.16 (18)
Delta-elapitoxin-Cb1a* P0DL82 Calliophis bivirgatus 40.14 (2)
Three-finger toxin MALT0070C F5CPE6 Micrurus altirostris 20.07 (3)
Neurotoxin 3FTx-LI P0C553 Bungarus fasciatus 13.68 (3)
Cytotoxin A5* P62375 Naja atra 7.26 (2)
Neurotoxin 3FTx-RK P0C554 Bungarus fasciatus 5.87 (1)
Three-finger toxin D.L A0A0H4BLZ2 Micrurus diastema 4.63 (2)
Three-finger toxin T.B A0A0H4IS80 Micrurus tener 1.21 (1)
Maticotoxin A* P24742 Calliophis bivirgatus 1.15 (1)
Cytotoxin homolog 3* P01473 Naja melanoleuca 0.07 (1)
Neurotoxin 3FTx-RI P0C555 Bungarus fasciatus 0.04 (1)
Neurotoxin-like protein NTL2 Q9W717 Naja atra 0.03 (1)
Long-chain 3FTx 0.03 (1)
Long neurotoxin LlLong Q7T2I3 Laticauda laticaudata 0.03 (1)
Non-conventional 3FTx < 0.01 (1)
Probable weak neurotoxin 3FTx-Lio1 A7X3M9 Erythrolamprus poecilogyrus < 0.01 (1)
Phospholipase A2 (svPLA2) 0.17 (5)
Phospholipase A2 2* P24645 Calliophis bivirgatus 0.08 (1)
Basic phospholipase A2 PC17* Q8UUH8 Laticauda colubrina 0.07 (2)
Basic phospholipase A2 PC9 Q8UUH9 Laticauda colubrina 0.02 (1)
Group XV phospholipase A2 V8NS07 Ophiophagus hannah < 0.01 (1)
Snake venom metalloproteinase (SVMP) 0.67 (10)
Asrin* A6XJS7 Austrelaps superbus 0.50 (1)
Snake venom metalloproteinase-disintegrin-like mocarhagin Q10749 Naja mossambica 0.10 (1)
Zinc metalloproteinase-disintegrin-like MTP4 F8RKW1 Drysdalia coronoides 0.04 (2)
Zinc metalloproteinase-disintegrin-like ohanin A3R0T9 Ophiophagus hannah 0.01 (1)
Nigrescease-1 B5KFV8 Cryptophis nigrescens 0.01 (2)
Zinc metalloproteinase-disintegrin-like NaMP* A8QL59 Naja atra < 0.01 (1)
Zinc metalloproteinase-disintegrin-like BmMP A8QL49 Bungarus multicinctus < 0.01 (1)
Zinc metalloproteinase-disintegrin-like atragin D3TTC2 Naja atra < 0.01 (1)
Kunitz-type serine protease inhibitor (KSPI) 3.65 (4)
Kunitz-type serine protease inhibitor mulgin-3 Q6ITB9 Pseudechis australis 3.16 (1)
Kunitz-type serine protease inhibitor textilinin-4 Q90W98 Pseudonaja textilis textilis 0.47 (1)
Kunitz-type serine protease inhibitor vestiginin-2 A6MFL2 Demansia vestigiata 0.02 (1)
Kunitz-type protease inhibitor 1* V8N7R6 Ophiophagus hannah 0.01 (1)
Vespryn (VES) 0.87 (1)
Ohanin* P83234 Ophiophagus hannah 0.87 (1)
Cystatin (CYS) 0.15 (6)
Cystatin* E3P6N7 Pseudechis porphyriacus 0.12 (1)
Cystatin-C* V8NX38 Ophiophagus hannah 0.01 (1)
Cystatin-B V8P5H9 Ophiophagus hannah 0.01 (1)
Cystatin 1 A0A2H4N3F5 Bothrops moojeni < 0.01 (2)
Cystatin* E3P6P4 Naja kaouthia < 0.01 (1)
Phosphodiesterase (PDE) 0.09 (2)
Snake venom phosphodiesterase 5GZ4 Naja atra 0.05 (1)
Venom phosphodiesterase 1 J3SEZ3 Crotalus adamanteus 0.04 (1)
Natriuretic peptides (NAP) 0.08 (2)
Natriuretic peptide Na-NP D9IX97 Naja atra 0.08 (1)
C-type natriuretic peptide Q09GK2 Philodryas olfersii < 0.01(1)
Aminopeptidase (AP) 0.04 (9)
Aminopeptidase* B6EWW5 Gloydius brevicaudus 0.03 (2)
Aminopeptidase NPEPL1* A0A2H4N3C8 Bothrops moojeni 0.01 (2)
Aminopeptidase* T2HQN1 Ovophis okinavensis < 0.01 (2)
Aminopeptidase B* V8N861 Ophiophagus hannah < 0.01 (1)
Aminopeptidase O V8NPW5 Ophiophagus hannah < 0.01 (2)
Neprilysin (NEP) 0.03 (1)
Neprilysin* V8NQ76 Ophiophagus hannah 0.03 (1)
Waprin (WAP) 0.02 (2)
Porwaprin-b* B5L5N2 Pseudechis porphyriacus 0.02 (1)
Waprin-Phi3* A7X4M7 Philodryas olfersii < 0.01 (1)
5' nucleotidase (5’NUC) 0.02 (3)
Snake venom 5' nucleotidase* F8S0Z7 Crotalus adamanteus 0.02 (1)
5' nucleotidase* A6MFL8 Demansia vestigiata < 0.01 (1)
5' nucleotidase A0A024AXW5 Micropechis ikaheca < 0.01 (1)
Dipeptidyl peptidase (DPP) 0.02 (5)
Dipeptidyl peptidase 1* V8N9E5 Ophiophagus hannah 0.01 (1)
Dipeptidyl peptidase 2* V8NF35 Ophiophagus hannah 0.01 (1)
Dipeptidyl peptidase 9* V8NC40 Ophiophagus hannah < 0.01 (2)
Dipeptidyl peptidase 8* V8N5Q6 Ophiophagus hannah < 0.01 (1)
Phospholipase B (PLB) 0.01 (2)
Phospholipase-B 81* F8J2D3 Spilotes sulphureus 0.01 (1)
Phospholipase B-like V8NLQ9 Ophiophagus hannah < 0.01 (1)
Snake venom serine protease (SVSP) < 0.01 (1)
Snake venom serine protease P18965 Daboia siamensis < 0.01 (1)
Hyaluronidase (HYA) < 0.01 (1)
Hyaluronan and proteoglycan link protein 3 V8P471 Ophiophagus hannah < 0.01 (1)
Open in a new tab
a

Transcript abundance expression (%) is based on FPKM (fragments per kilobase of exon model per million reads mapped). *Number of full-length toxin transcripts from venom gland of Calliophis bivirgata flaviceps. Determined by the coverage of amino acids of transcripts to amino acids of mature chain of annotated proteins.

Out of the 74 toxin transcripts, 31 transcripts have ≥ 90% sequence coverage based on the annotated protein entries. These toxins were classified under full-length transcripts in the present study (Table 2; sequences available in Additional file 2). The majority of toxin transcripts were annotated based on sequence similarities from various elapid species, while only four transcripts were matched to sequences specific to Calliophisspecies, indicating that the existing toxin database is indeed limited for the Asiatic coral snakes.

Among the 16 toxin gene families, three-finger toxins (3FTx) are the most diversified and abundantly expressed (20 transcripts at 94.19% of total toxin FPKM). Its domination in the venom gland transcriptome suggests that the 3FTxs are critical in the venom evolution of C. bivirgata flaviceps and implicated in its adaptation to specific ophiophagic diet. The diversely expressed 3FTx genes in this species were further categorized by sequence subtypes into long-chain, short-chain and non-conventional groups (Table 2), and elaborated based on their functional attributes in the context of envenomation. Other toxin families were expressed at much lower levels. These include Kunitz-type serine protease inhibitor (KSPI), vespryn (VES), snake venom metalloproteinase (SVMP), snake venom phospholipase A2 (svPLA2), cystatin (CYS), phosphodiesterase (PDE), natriuretic peptide (NAP), aminopeptidase (AP), neprilysin (NEP), waprin (WAP), 5’ nucleotidase (5’NUC), dipeptidyl peptidase (DPP), and phospholipase B (PLB), snake venom serine protease (SVSP) and hyaluronidase (HYA). Figure 2B illustrates the overall venom gland transcriptome of C. bivirgata flaviceps according to the toxin gene families.

Three-finger toxins (3FTxs)

3FTxs are typically the major toxins of elapids, e.g., cobras [41, 42], kraits [43, 44], sea snakes [45], mambas [46, 47] and coral snakes [39, 48, 49]. These are non-enzymatic polypeptides with molecular weights of approximately 6-9 kDa, orientated in three beta-stranded loops that resemble three protruding fingers [50, 51]. Comparison of the venom gland transcriptomic profiles between the current study and a recent report [17] reveals a similar dominating pattern of 3FTx, notwithstanding variation in the relative proportions of many toxin subtypes (Table 3). The variation implies potential inter-individual differences between the specimens, e.g., wild versus captive snakes from different geographical regions, or extensive post-translational modifications [52]. Variations also could be accounted for by methodological differences, in terms of tissue harvesting time [20] and program algorithms used in the study. Although transcriptional events in venom gland was shown to achieve the highest level four days after venom extraction [20], the transcriptome may represent only a snapshot of toxin gene expression as different genes likely have varying transcription rates and mRNA half-lives.

Table 3. Comparison of venom gland transcriptomics of the Malayan blue coral snake (Calliophis bivirgata) between two studies.

Toxin gene families Current studya Dashevsky et al. [17]b
Total transcripts 74 125
Three-finger toxins 20, 94.16% 67, 82%
Neurotoxins 16, 85.70% NS
Cytotoxin-like proteins 4, 8.49% NS
Kunitz-type serine protease inhibitor 4, 3.65% 24, 9%
Phospholipase A2 5, 0.17% 13, 8%
Vespryn 1, 0.87% 1, *
Snake venom metalloproteinase 10, 0.67% 4, *
Cystatin 6, 0.15% 4, *
Phosphodiesterase 2, < 0.1% 1, *
Natriuretic peptide 2, < 0.1% NR
Aminopeptidase 9, < 0.1% NR
Neprilysin 1, < 0.1% 1, *
Waprin 2, < 0.1% 1, *
5’Nucleotidase 3, < 0.1% NR
Dipeptidyl peptidase 5, < 0.1% NR
Phospholipase B 2, < 0.1% 1, *
Snake venom serine protease 1, < 0.01% NR
Hyaluronidase 1, < 0.01% 1, *
Cysteine-rich secretory proteins NR 2, *
Kallikrein NR 1, *
Nerve growth factors NR 4, *
Open in a new tab

Bold indicates the number of transcripts in each toxin gene family and protein subtype. Percentage indicates the relative abundance of transcripts. aRelative abundance of transcripts based on fragments per kilobase per million mapped reads (FPKM). bRelative abundance of transcripts based on transcripts per million (TPM). *One of the 11 toxin gene families with their total abundance reported as < 1% collectively. NS: not specified; NR: not reported.

Based on the protein structure, 3FTx transcripts in C. bivirgata flaviceps venom gland transcriptome were further categorized into short-chain 3FTx (S-3FTx, with four disulfide bridges), long-chain 3FTx (L-3FTx, with an additional fifth disulfide bridge on the second loop) and non-conventional 3FTx (NC-3FTx, with an additional fifth disulfide bridge on the first loop) [51]. Within the 3FTxs family, the most abundantly and diversely expressed transcripts belonged to S-3FTxs (94.16%, 18 transcripts), while L-3FTx and NC-3FTx each consisted of only one lowly expressed transcript (< 0.05% of total toxin FPKM) (Table 2). Of these, the majority of S-3FTx transcripts (40.14% of toxin FPKM, two transcripts) were annotated by sequence similarities to a delta-neurotoxin, called calliotoxin (UniProtKB: P0DL82). Other S-3FTx composed of 12 putative neurotoxins or neurotoxin-like proteins and four cardiotoxin-like/cytotoxin-like proteins. Multiple sequence alignment revealed highly conserved four disulfide bridges (formed by eight conserved cysteine residues) among the 18 S-3FTx, and five disulfide bridges in each of the L-3FTx and NC-3FTx respectively (Figure 3).

Figure 3. Multiple sequence alignments of three-finger toxin (3FTx) transcripts from Calliophis bivirgata flaviceps. Black brackets denote the four disulfide bridges in all 3FTx, while blue and orange brackets represent the fifth disulfide bridges present in L-3FTx (second loop) and NC-3FTx (first loop), respectively.

Figure 3.

Open in a new tab

Short-chain three-finger toxins (S-3FTxs)

Delta-neurotoxins (calliotoxin)

In the venom gland transcriptome, Cb_FTX01 and Cb_FTX02 were the two most abundantly expressed transcripts of S-3FTx. Both transcripts were annotated as calliotoxins (UniProtKB: P0DL82 and Cbivi_3FTx_034 reported by Dashevsky et al. [17]), which is by far the only delta-neurotoxin discovered from snake venoms [10]. To elucidate variation in the genes, sequences of Cb_FTX01 and Cb_FTX02 were further compared with calliotoxins and representative alpha-neurotoxins from common elapid species found in Southeast Asia (Figure 4). Both Cb_FTX01 and Cb_FTX02 exhibited high sequence similarities (88-100%) to calliotoxins (UniProtKB: P0DL82) and Cbivi_3FTx_034 [17], suggesting similar pharmacological properties of these delta-neurotoxins expressed in the venom gland transcriptome. An earlier study showed that calliotoxin binds to the sodium channels of motor neurons, prolonging the action potential and resulting in spastic paralysis [10]. The delta-neurotoxin is presumably the principal toxin that causes neurotoxic death in C. bivirgata envenomation, and this neurotoxic effect has been shown to affect different taxa including mammals and birds [10, 15] but resist neutralization by elapid antivenoms [18].

Figure 4. Multiple sequence alignments of Cb_FTX01 and Cb_FTX02 of Calliophis bivirgata flaviceps compared to functionally matched sequences from (A) serpentes and (B) non-serpentes groups obtained from public database. Percentage indicates the sequence similarities compared to Cb_FTX01(*). Black brackets: disulfide bridges, red regions: critical binding amino acid residues.

Figure 4.

Open in a new tab

On the other hand, the delta-neurotoxins of C. bivirgata flaviceps lack the specific binding sites toward the alpha-subunit of nicotinic acetylcholine receptor (nAChR) (Lys-27, Trp-29 and Asp-31) [53], and have very low sequence similarity (20-45%) to elapid alpha-neurotoxins (Figure 4). The emergence of delta-neurotoxin in C. bivirgata flaviceps venom marks the divergent evolution of its 3FTx from virtually all other elapids, whose neurotoxic 3FTxs are primarily alpha-neurotoxins. Alpha-neurotoxins block the nAChR and cause flaccid paralysis as the mode of kill, as opposed to spastic paralysis induced by delta-neurotoxins. In nature, delta-neurotoxins are typically present in the venoms of invertebrate animals, e.g., scorpions, solitary wasps, cone snails, spiders, and sea anemone [54-58]. In snakes, thus far, delta-neurotoxins were discovered only from this species. The delta-neurotoxins of C. bivirgata flaviceps, nonetheless, are distinct with only 7-21% of sequence similarities to those of the invertebrate animals. Comparing across different taxa, the delta-neurotoxins of C. bivirgata flaviceps are highly divergent from the following invertebrates at their respective critical binding sites: Leiurus hebraeus (UniProtKB: P56678, at Ile-59, Lys-64, His-66) [59]; Anoplius samariensis (UniProtKB: P69391, at Arg1, Lys3 or Lys12) [60]; Conus purpurascens (UniProtKB: P58913, at Phe-60 and Ile-63) [61]; Missulena bradleyi (UniProtKB: P83608, at Lys-3, Lys-4, Arg-5, Glu-6, Trp-7, Lys-10, Glu-12, Tyr-22, Tyr-25) [62]; Anemonia sulcata (UniProtKB: P01535, at Tyr-7, Trp-8, Pro-12, Trp-13 and Tyr-18) [63] (Figure 4). This illustrates a case of functional convergence where C. bivirgata flaviceps and these unrelated species, in their respective biomes, have independently evolved toxins that are functionally similar for the purpose of prey paralyzing.

Cardiotoxin-like/Cytotoxin-like proteins

Within the S-3FTx group, Cb_FTX05, Cb_FTX13, Cb_FTX15 and Cb_FTX16 are four transcripts encoding for cytotoxin-like/cardiotoxin-like proteins, and accounting for 8.49% of the total toxin FPKM (Table 3; Additional file 2). Cb_FTX05 and Cb_FTX15 were annotated as cytotoxin (CTX) homologues from Naja atra (UniProtKB: P62375, with 53-55% similarities), and Cb_FTX16 was annotated as one from Naja melanoleuca (UniProtKB: Q9W716, with 51% similarity) (Figure 5). Although the CTX-like proteins of C. bivirgata flaviceps were annotated as those from cobra (Naja spp.), they were found to have only ~50% sequence similarity, indicating that the CTX-like proteins of C. bivirgata flaviceps are evolutionarily divergent from the cobra CTX, and thus these are purely putative toxins whose activities were hypothesized based on sequence similarities. Significant variations were observed particularly in the loop II region which is critical for CTX binding to the lipid bilayer of membrane [51] (Figure 5), suggesting that the CTX-like proteins of the coral snake are functionally varied from those of cobras.

Figure 5. Multiple sequence alignments of cytotoxin-like transcripts of Calliophis bivirgata flaviceps (Cb_FTX05, -13, -15, -16) aligned and compared to closely related sequences from public database. Highlighted in: red box - His-4/Tyr-4-type; blue box - Ser-28-type, green box - Pro-31-type; black brackets - disulfide bridges.

Figure 5.

Open in a new tab

The other CTX-like transcript, Cb_FTX13, was annotated as maticotoxin (UniProtKB: P24742), a cardiotoxin-like protein reported previously in C. bivirgata venom [15, 64]. Maticotoxin exhibited weak cytotoxicity in vitro but caused hemolysis in synergistic action with phospholipase A2 [15, 64]. Earlier, in the report by Takasaki et al. [64], maticotoxin was only partially sequenced to 41 amino acid residues with the use of Edman degradation method. The present study, together with the recent study by Dashevsky et al. [17], successfully uncovered its full amino acid sequence and the presence of eight conserved cysteine residues (forming four disulfide bridges) that are responsible for its three-fingered structure (Figure 5). Noteworthy, all CTX-like proteins from C. bivirgata flaviceps represent a unique class not conforming to the usual classification of CTX known presently. Chien et al. [65] through studying the binding effect of various cobra CTX to lipids, proposed that CTX could be divided into P-type and S-type based on the presence of Pro-31 or Ser-29 in the sequence. Both amino acid residues are located within the same phospholipid binding sites in the tip of loop 2, but Ser-29 is located in the more hydrophilic region (thus weaker binding to lipid membrane) [65]. A variant H-type, whose 4th amino acid residue is substituted with histidine, was noted in some CTX regardless of P-type or S-type, and these “H-type” CTX variants are generally less toxic due to weak membrane binding activity [66]. The CTX-like sequences of C. bivirgata flaviceps contain no distinguishable conserved amino acid at residue positions 29 and 31 (neither Ser-29 nor Pro-31) but, interestingly, display conserved tyrosine at the 4th residue. The emergence of Tyr4 in these sequences could be probably a result of His substitution by Tyr involving a single nucleotide mutation from C to U at the codon (CAU/CAC to UAU/UAC). The mean dN/dS ratio comparing the H-type CTX cytotoxin A5 and homolog 5V of cobra to the CTX-like proteins of C. bivirgata flaviceps are 0.60 and 0.95, respectively, implying a synonymous substitution, and that the evolution of the Tyr-4-containing CTX variant is near neutral or under constraint. Considering that His and Tyr were both polar, aromatic and having a positive amino acid substitution similarity score (+2 based on BLOSUM 62 scoring matrix), the replacement is likely conservative, thus preserving a less cytotoxic form of maticotoxin in the C. bivirgata flaviceps venom [15, 64] as with the H-type CTX of cobra [66]. The exact ecological role of the Try-4-containing variants, which we propose as the Y-type CTX/CTX-like proteins of elapid snakes, remains to be further investigated.

Other three-finger toxins (3FTxs)

A total of 12 transcripts, constituting 45% of the toxin FPKM, were annotated to various neurotoxin-related genes (Table 4). These transcripts were matched with limited sequence similarities mainly to S-3FTXs reported from coral snakes (Micrurus spp.), cobras (Naja spp.), kraits (Bungarus spp.) and sea krait (Laticauda spp.). Notably, most of these transcripts were only present at the mRNA level (present study) but not detected in the venom proteome reported earlier [15], suggesting a complex regulatory process between gene transcription and protein translation. Some of the transcripts probably undergo rapid degradation, pre-empting meaningful translation as in pseudogenization - a more common fate for a duplicated gene, which would have been anticipated in the course of evolution of the extended 3FTx gene family in this species. Are these representations of pseudogenes conserved among the elapids, evolving free of selective pressure and following random genetic drift? Regardless, these minor proteins if translated in the venom would be toxins that potentially play an integral role in the overall venom function. The biological function and pathophysiological roles of these toxins, nevertheless, deserve further investigation in the future.

Table 4. Other putative neurotoxins in C. bivirgata flaviceps venom gland transcriptome.

Toxin transcripts Toxin subtypes Annotated sequences and species Reference Sequence similarities (%) Toxin FPKM (%)
Short-chain three-finger toxins
Cb_FTX03 Cb_FTX08 Cb_FTX09 Three-finger toxin MALT0070C F5CPE6, Micrurus altirostris [39] 42 20.1
41
41
Cb_FTX04 Cb_FTX07 Cb_FTX14 Neurotoxin 3FTx-LI P0C553, Bungarus fasciatus [67] 41 13.7
43
42
Cb_FTX06 Neurotoxin 3FTx-RK P0C554, Bungarus fasciatus [68] 65 5.9
Cb_FTX10 Cb_FTX11 Three-finger toxin D.L A0A0H4BLZ2, Micrurus diastema Uncharacterized 42 4.6
45
Cb_FTX12 Three-finger toxin T.B AKO63249, Micrurus tener Uncharacterized 55 1.2
Cb_FTX17 Neurotoxin_3FTx-RI P0C555, Bungarus fasciatus [67] 44 <0.1
Cb_FTX18 Neurotoxin-like protein NTL2 Q9W717, Naja atra Uncharacterized 44 <0.1
Long-chain three-finger toxins
Cb_FTX19 Long neurotoxin LlLong Q7T2I3, Laticauda laticaudata [69] 93 <0.1
Non-conventional three-finger toxins
Cb_FTX20 Probable weak neurotoxin 3FTx-Lio1 A7X3M9, Erythrolamprus poecilogyrus Uncharacterized 60 <0.1
Open in a new tab

Snake venom phospholipases A2 (svPLA2)

Snake venom phospholipases A2 are extensively distributed in the venoms of virtually all snake species, although recent studies revealed exceptions in the venoms of African non-spitting cobras (subgenus: Uraeus) [70, 71]. Conventionally, snake venom PLA2 (svPLA2) are classified into the secretory svPLA2 family of Groups IA (cobras and kraits), IIA (most viperids) and IIB (Gaboon vipers) [72]. In the C. bivirgata flaviceps venom gland transcriptome, a total of five svPLA2 transcripts (Cb_PLA01-05, 0.17 % of total toxin FPKM) were identified (Table 2; Additional file 2). Of these, the full-length transcripts of the two main svPLA2 (Cb_PLA01 and Cb_PLA02) were characterized, and categorized as Group IB and Group IA svPLA2, respectively. Conserved amino acid residues His-48, Tyr-52 and Asp-99 in svPLA2 [72] were present in the svPLA2 transcripts of C. bivirgata flaviceps. In addition to these critical amino acid residues, these svPLA2 transcripts contain Asp-49 which is one of the key residues for enzymatic activities [723]. Similarly, Cb_PLA01 and transcripts retrieved from another study (Cbivi_PLA2_00, -03, -07 and -09) [17] contain a surface loop located between residues 62 to 66, termed pancreatic loop, which is a characteristic of Group IB svPLA2 [74] (Figure 6). Group IB svPLA2, mainly found in mammalian pancreas, have been reported in only a few snake venoms from elapids such as Oxyuranus scutellatus [75], Pseudonaja textilis [76] and Micrurus frontalis frontalis [77]. The presence of the hydrophilic pancreatic loop in Group IB svPLA2 has been shown to decrease the substrate-PLA2 enzyme binding activity [74], but the biological significance of this phenomenon and its effect on snakebite envenomation remain unclear. In comparison, Cb_PLA01 exhibited high sequence similarities to Cbivi_PLA2_00, -03, -07 and -09 (86-99% sequence similarities), suggesting they may exhibit similar pharmacological activities. It is also notable that Group IA svPLA2 (Cb_PLA02) was absent in the recently reported study of the same species [17].

Figure 6. Multiple sequence alignment of snake venom phospholipase A2 (svPLA2) transcripts (Cb_PLA01 and Cb_PLA02) of Calliophis bivirgata flaviceps aligned and compared to closely related sequences from public database. Brackets in blue and green: conservative disulfide bonds and residues of pancreatic loop; black: additional disulfide bridges; red box: conserved amino acid residues.

Figure 6.

Open in a new tab

Based on the computation determination of theoretical pI (isoelectrical point) using ExPASy computational tool (SIB Swiss Institute of Bioinformatics), Cb_PLA01, Cbivi_PLA2_IB_00 and Cbivi_PLA2_IB_09 isoforms were found to be acidic (pI: 6.70, 5.88 and 5.88, respectively) whereas Cb_PLA02, Cbivi_PLA2_IB_03 and Cbivi_PLA2_IB07 isoforms were basic (pI: 8.75, 8.19, and 7.53, respectively). On multiple sequence alignment, Cb_PLA01 were annotated as acidic svPLA2 from Ophiophagus hannah (UniProtKB: P80966) and Naja kaouthia (UniProtKB: P00596) with sequence similarities of ~70% (Figure 6). An acidic svPLA2 from king cobra was previously reported to cause myocardial and skeletal muscle degeneration in mice [78], while acidic svPLA2 from other elapids generally lack toxicity [45, 79, 80]. On the other hand, Cb_PLA02 (coding for a basic svPLA2) showed ~90% sequence similarity to two basic svPLA2 isoforms from the sea krait, Laticauda colubrina (UniProtKB: Q8UUH8 and Q8UUH9) (Figure 6). Multiple sequence alignment in Figure 6 further revealed that both svPLA2 transcripts (CB_PLA01 and CB_PLA02) have limited sequence similarity (45−50%) to the pre-synaptic beta-bungarotoxins from Bungarus spp. (kraits), which are also ophiophagic venomous snakes found in Asia. The finding is consistent with transient myotoxicity and the lack of presynaptic neurotoxic activity caused by C. bivirgata flaviceps venom [15, 64].

Snake venom metalloproteinase (SVMP)

Snake venom metalloproteinases (SVMP) are multi-domain proteins with diverse biological activities, e.g., causing hemorrhage, fibrinogenolysis and defibrination, and inhibition of platelet aggregation [81]. These proteins are usually major components in the venoms of vipers and pit vipers, consistent with the pathological phenotypes seen in viper/pit viper envenomation (hemorrhagic syndrome and consumptive coagulopathy) [82]. Most elapid venoms contain little or small amount of SVMP, with the exceptions of king cobra [32] and Asian coral snakes (Calliophisspp.) [15, 17, 49]. The biological and pathological role of SVMP in elapid venoms has not been well elucidated although it could be contributing to inflammatory responses [83]. Interestingly, elapid SVMP are commonly members of PIII class which are more structurally and functionally variable [84]. In the case of C. bivirgata flaviceps venom gland transcriptome, a total of eight transcripts of SVMP, with two of which showing full-length sequences (Cb_SVMP01 and Cb_SVMP07), were identified at a very low abundance (0.7% of total toxin FPKM) (Table 2; Additional file 2).

All the transcripts from the present work and a recent study [17] belong to PIII class of SVMP in which the mature chain of protein consists of the metalloproteinase, disintegrin-like, and cysteine-rich domains, with conserved ECD (glutamic acid, cysteine, aspartic acid) integrin-binding motifs present at the disintegrin domain (Figure 7). In comparison, Cb_SVMP01 showed high sequence similarities (82-94%) to transcripts Cbivi_SVMP02, -06, -07 and -11 (Figure 7) [17]. On BLAST search, the SVMP sequences of C. bivirgata flaviceps matched most closely to those from cobras (Naja spp.) but with limited sequence similarity (56−75%) (Figure 7), suggesting molecular and perhaps functional adaptation in SVMP that is unique to the Asiatic coral snake and divergent from the cobras.

Figure 7. Multiple sequence alignment of snake venom metalloproteinase (SVMP) transcripts (Cb_SVMP01 and Cb_SVMP07) of Calliophis bivirgata flaviceps with other annotated sequences. Brackets in black: metalloproteinase, disintegrin and cysteine-rich domains; red regions: ECD motif.

Figure 7.

Open in a new tab

Other minor toxin transcripts

Other toxin genes with low expression (< 5% of toxin FPKM) include Kunitz-type serine protease inhibitor (KSPI), vespryn (VES), cystatin (CYS), phosphodiesterase (PDE), natriuretic peptide (NAP), aminopeptidase (AP), neprilysin (NEP), waprin (WAP), 5’nucleotidase (NUC), dipeptidyl peptidase (DPP), phospholipase B (PLB), snake venom serine protease (SVSP) and hyaluronidase (HYA). Among these, VES, CYS, PDE, NUC and HYA were previously reported in the venom proteome at low abundances [15]. In contrast, the other toxin families, i.e., KSPI, NAP, AP, NEP, WAP, DPP, PLB and SVSP were not found in the venom proteome, presumably due to their very low protein abundances below the detection limit of the mass spectrometry used. From the venom gland transcriptomics, the findings suggest that the toxin genes are conserved in the Calliophislineage.

Meanwhile, a discrepancy was observed between the transcript expression level (present study) and protein abundance in the venom proteome reported previously [15]. The lack of correlation between toxin gene expression and venom protein abundance has also been reported in several earlier studies [32, 33, 39, 40, 85]. It should be noted that in most venom gland transcriptomic studies, the venom gland transcriptome reflects a “snapshot” of gene expression at a certain time point when the gland tissue was harvested, typically a few days after venom milking. The mRNAs of various toxins could be expressed at different rates, having varying half-lives and subjected to complex regulation processes including post-transcriptional and post-translational modifications [86]. These events in between could have further modulated the maturation and secretion of proteins into the final venom product, thus the lack of correlation between the transcript expression and protein abundance. Furthermore, the use of a single de novo assembly program (Trinity) is a limitation in this study, as ideally a combination of multiple assemblers may have added advantage to fully capture the entirety of the transcripts expressed [26]. Nevertheless, Trinity (assembler program used in this study) is one that has been widely applied in venom-gland transcriptomics, and it has been shown to recover the highest number of good transcripts that passed quality filters [26, 27].

Furthermore, while calliotoxin (a delta-neurotoxin) has been identified in the present transcriptomic study and from the venom of the homologous Malaysian species [10], this unique toxin was not detected in the venom proteomics reported earlier [15]. Previously, the toxin was not detected in the venom proteome presumably due to the lack of the complete sequence back then to support a comprehensive reference search database. The proteomic approach adopted was deriving quantitative information from peptide-centric mass spectrometry data, which has its weakness in protein identification without a model organism to provide a reference database with complete sequence coverage. In regard to this, we propose that the venom proteome can be re-investigated using a more comprehensive database, incorporating the diverse species-specific toxin sequences including the calliotoxin isolated by Yang et al. [10], and de novo sequences from the recent study [17] and current work.

Conclusion

To summarize, this study reported the de novo venom gland transcriptomics of Calliophis bivirgata flaviceps, a unique Asiatic coral snake species from the Peninsula of Malaysia. The findings unveiled the complexity and diversity of venom genes in the species, demonstrating inter-specific and intra-specific variations in the sequences and expressions of toxin genes. Of note, three-finger toxins uncovered from this species show remarkable variability in their sequences and putative functions from those of many Asiatic elapids, as indicated by the presence of delta-neurotoxins (including calliotoxin), Tyr-4-containing CTX-like proteins, svPLA2 of Group IA and IB, and divergent forms of PIII class of SVMP. The findings enriched the toxin knowledge base for the Malayan blue coral snake, and the comprehensive transcriptomic profiling provides deeper insights into the medical and biological significance of the species.

Abbreviations

cDNA: complementary deoxyribonucleic acid; 3FTx: three-finger toxin; CTX: cytotoxin; C. bivirgata: Calliophis bivirgata; C. bivirgata flaviceps: Calliophis bivirgata flaviceps; FPKM: fragments per kilobase per million mapped reads; BLAST: basic local alignment search tool; KSPI: Kunitz-type serine protease inhibitor; VES: vespryn; SVMP: snake venom metalloproteinase; svPLA2: snake venom phospholipase A2; CYS: cystatin; PDE: phosphodiesterase; NAP: natriuretic peptide; AP: aminopeptidase; NEP: neprilysin; WAP: waprin; 5’NUC: 5’ nucleotidase; DPP: dipeptidyl peptidase; PLB: phospholipase B; SVSP: snake venom serine protease; HYA: hyaluronidase; NTX: neurotoxin; TPM: transcript per million; ND: not detected; NS: not specified; S-3FTx: short three-finger toxin; L-3FTx: long three-finger toxin; NC-3FTx: non-conventional three-finger toxin; nAChR: nicotinic acetylcholine receptor; mRNA: messenger ribonucleic acid; spp.: species pluralis; IACUC: Institutional Animal Use and Care Committee; RNA: ribonucleic acid; PCR: polymerase chain reaction; NCBI: National Centre for Biotechnology Information; NR: non-redundant; RSEM: RNA-seq with expectation maximization; BLASTp: Basic Local Alignment Search Tool-Protein; UniProtKB: Universal Protein Resource Knowledgebase; MUSCLE: Multiple Sequence Comparison by Log-Expectation.

Supplementary material

Additional file 1. Venom gland transcriptomic analysis of Calliophis bivirgata flaviceps.
Click here for additional data file. (3.5MB, xlsx)
Additional file 2. Classification and sequences of toxin genes from Calliophis bivirgata flaviceps venom gland transcriptome.
Click here for additional data file. (178.4KB, xlsx)
Additional file 3. Output and quality metrics of RNA sequencing for the de novo assembly of Calliophis bivirgata flaviceps venom gland transcriptome.
Click here for additional data file. (67.5KB, pdf)

Footnotes

Availability of data: Sequencing data from the de novo venom gland transcriptomics of Calliophis bivirgata flaviceps was deposited in National Centre for Biotechnology Information (NCBI) Sequence Read Archive (http://submit.ncbi.nlm.nih.gov) under SRA accession: PRJNA639409.

Availability of data and materials: Not applicable.

Funding: The present study was supported by the University of Malaya (Grant numbers: BKS003-2020 and ST011-2020).

Ethics approval: The study was carried out in accordance with the protocols approved by the Institutional Animal Use and Care Committee (IACUC) of University of Malaya, Malaysia (Approval code: #2013-11-12/PHAR/R/TCH).

Consent for publication: Not applicable.

References

  1. Casewell NR, Wüster W, Vonk FJ, Harrison RA, Fry BG. Complex cocktails: the evolutionary novelty of venoms. Trends Ecol Evol. 2013;28(4):219–229. doi: 10.1016/j.tree.2012.10.020. [DOI] [PubMed] [Google Scholar]
  2. Kordis D, Gubensek F. Adaptive evolution of animal toxin multigene families. Gene. 2000;261(1):43–52. doi: 10.1016/s0378-1119(00)00490-x. [DOI] [PubMed] [Google Scholar]
  3. Wollenberg Valero KC, Marshall JC, Bastiaans E, Caccone A, Camargo A, Morando M, Niemiller ML, Pabijan M, Russello MA, Sinervo B, Werneck FP, Sites JW, Jr, Wiens JJ, Steinfartz S. Patterns, mechanisms and genetics of speciation in reptiles and amphibians. Genes (Basel) 2019;10(9):646. doi: 10.3390/genes10090646. [DOI] [PMC free article] [PubMed] [Google Scholar]
  4. Gutiérrez JM, Calvete JJ, Habib AG, Harrison RA, Williams DJ, Warrell DA. Snakebite envenoming. Nat Rev Dis Primers. 2017;3:17063. doi: 10.1038/nrdp.2017.63. [DOI] [PubMed] [Google Scholar]
  5. World Health Organization . Guidelines for the management of snakebites. 2. 2016. pp. 1–204.https://apps.who.int/iris/handle/10665/249547 WHO Regional Office for South-East Asia. [Google Scholar]
  6. Kasturiratne A, Wickremasinghe AR, de Silva N, Gunawardena NK, Pathmeswaran A, Premaratna R, Savioli L, Lalloo DG, de Silva HJ. The global burden of snakebite: a literature analysis and modelling based on regional estimates of envenoming and deaths. PLoS Med. 2008;5(11):e218. doi: 10.1371/journal.pmed.0050218. [DOI] [PMC free article] [PubMed] [Google Scholar]
  7. Slowinski JB, Boundy J, Lawson R. The phylogenetic relationships of Asian coral snakes (Elapidae: Calliophisand Maticora) based on morphology and molecular characters. Herpetol. 2001;57(2):233–245. [Google Scholar]
  8. Chanhome L, Cox MJ, Vasaruchapong T, Chaiyabutr N, Sitprija V. Characterization of venomous snakes of Thailand. Asian Biomed. 2011;5(3):311–328. [Google Scholar]
  9. Stuebing RB, Inger RF, Lardner B. A field guide to the snakes of Borneo. 2. Borneo: Natural History Publications; 2014. [Google Scholar]
  10. Yang DC, Deuis JR, Dashevsky D, Dobson J, Jackson TNW, Brust A, Xie B, Koludarov I, Debono J, Hendrikx I, Hodgson WC, Josh P, Nouwens A, Baillie GJ, Bruxner TJ, Alewood PF, Lim KKP, Frank N, Vetter I, Fry BG. The snake with the scorpion's sting: novel three-finger toxin sodium channel activators from the venom of the long-glanded blue coral snake (Calliophis bivirgatus) Toxins (Basel) 2016;8(10):303. doi: 10.3390/toxins8100303. [DOI] [PMC free article] [PubMed] [Google Scholar]
  11. Harrison JL. The bite of blue Malaysian coral snake or Ular Matahari (Maticora bivirgata) Malayan Nat J. 1957;11(4):130–132. [Google Scholar]
  12. Lim FLK, Lee MTM. Fascinating snakes in Southeast Asia: an introduction raffles bulletin of zoology. Kuala Lumpur: Tropical Press Sdn. Bhd; 1990. [Google Scholar]
  13. Lim KKP, Lim FLK. A guide to the amphibians and reptiles of Singapore. 1. Singapore: Singapore Science Centre; 1992. [Google Scholar]
  14. Grismer L, Chan-Ard T. Calliophis bivirgata. The IUCN Red List of Threatened Species 2012 Internet. 2012 doi: 10.2305/IUCN.UK.2012-1.RLTS.T191956A2020812.en. [DOI] [Google Scholar]
  15. Tan CH, Fung SY, Yap MKK, Leong PK, Liew JL, Tan NH. Unveiling the elusive and exotic: venomics of the Malayan blue coral snake (Calliophis bivirgata flaviceps) J Proteomics. 2016;132:1–12. doi: 10.1016/j.jprot.2015.11.014. [DOI] [PubMed] [Google Scholar]
  16. The Reptile Database [Internet]. Ostrava (Czech Republic): Reptarium. 1995-. Calliophis bivirgatus (BOIE, 1827) [2021 July 20]. about 3 screens. Available from: https://reptile-database.reptarium.cz/species?genus=Calliophis&species=bivirgatus.
  17. Dashevsky D, Rokyta D, Frank N, Nouwens A, Fry BG. Electric blue: molecular evolution of three-finger toxins in the long-glanded coral snake species Calliophis bivirgatus . Toxins (Basel) 2021;13(2):124. doi: 10.3390/toxins13020124. [DOI] [PMC free article] [PubMed] [Google Scholar]
  18. Tan CH, Liew JL, Tan KY, Tan NH. Genus Calliophisof asiatic coral snakes: a deficiency of venom cross-reactivity and neutralization against seven regional elapid antivenoms. Toxicon. 2016;121:130–133. doi: 10.1016/j.toxicon.2016.09.003. [DOI] [PubMed] [Google Scholar]
  19. Brahma RK, McCleary RJR, Kini RM, Doley R. Venom gland transcriptomics for identifying, cataloging, and characterizing venom proteins in snakes. Toxicon. 2015;93:1–10. doi: 10.1016/j.toxicon.2014.10.022. [DOI] [PubMed] [Google Scholar]
  20. Rotenberg D, Bamberger ES, Kochva E. Studies on ribonucleic acid synthesis in the venom glands of vipera palaestinae (Ophidia, Reptilia) Biochem J. 1971;121(4):609–612. doi: 10.1042/bj1210609. [DOI] [PMC free article] [PubMed] [Google Scholar]
  21. Rio DC, Ares M, Jr, Hannon GJ, Nilsen TW. Purification of RNA using TRIzol (TRI reagent) Cold Spring Harb Protoc. 2010;2010(6):pdb.prot5439. doi: 10.1101/pdb.prot5439. [DOI] [PubMed] [Google Scholar]
  22. Rio DC, Ares M, Jr, Hannon GJ, Nilsen TW. Ethanol precipitation of RNA and the use of carriers. Cold Spring Harb Protoc. 2010;2010(6):pdb.prot5440. doi: 10.1101/pdb.prot5440. [DOI] [PubMed] [Google Scholar]
  23. Conesa A, Madrigal P, Tarazona S, Gomez-Cabrero D, Cervera A, McPherson A, Szcześniak MW, Gaffney DJ, Elo LL, Zhang X, Mortazavi A. A survey of best practices for RNA-seq data analysis. Genome Biol. 2016;17:13. doi: 10.1186/s13059-016-0881-8. [DOI] [PMC free article] [PubMed] [Google Scholar]
  24. Grabherr MG, Haas BJ, Yassour M, Levin JZ, Thompson DA, Amit I, Adiconis X, Fan L, Raychowdhury R, Zeng Q, Chen Z, Mauceli E, Hacohen N, Gnirke A, Rhind N, di Palma F, Birren BW, Nusbaum C, Lindblad-Toh K, Friedman N, Regev A. Full-length transcriptome assembly from RNA-Seq data without a reference genome. Nat Biotechnol. 2011;29(7):644–652. doi: 10.1038/nbt.1883. [DOI] [PMC free article] [PubMed] [Google Scholar]
  25. Haas BJ, Papanicolaou A, Yassour M, Grabherr M, Blood PD, Bowden J, Couger MB, Eccles D, Li B, Lieber M, MacManes MD, Ott M, Orvis J, Pochet N, Strozzi F, Weeks N, Westerman R, William T, Dewey CN, Henschel R, LeDuc RD, Friedman N, Regev A. De novo transcript sequence reconstruction from RNA-seq using the Trinity platform for reference generation and analysis. Nat Protoc. 2013;8(8):1494–1512. doi: 10.1038/nprot.2013.084. [DOI] [PMC free article] [PubMed] [Google Scholar]
  26. Holding ML, Margres MJ, Mason AJ, Parkinson CL, Rokyta DR. Evaluating the performance of De novo assembly methods for venom-gland transcriptomics. Toxins (Basel) 2018;10(6):249. doi: 10.3390/toxins10060249. [DOI] [PMC free article] [PubMed] [Google Scholar]
  27. Sze S-H. In: Computational Methods for Next Generation Sequencing Data Analysis. Mandoiu I, Zelikovsky A, editors. Hoboken, New Jersey: John Wiley & Sons; 2016. Computational Approaches for Studying Alternative Splicing in Nonmodel Organisms from RNA-SEQ Data; pp. 287–299. [Google Scholar]
  28. Pertea G, Huang X, Liang F, Antonescu V, Sultana R, Karamycheva S, Lee Y, White J, Cheung F, Parvizi B, Tsai J, Quackenbush J. TIGR gene indices clustering tools (TGICL): a software system for fast clustering of large EST datasets. Bioinformatics. 2003;19(5):651–652. doi: 10.1093/bioinformatics/btg034. [DOI] [PubMed] [Google Scholar]
  29. Langmead B, Salzberg SL. Fast gapped-read alignment with Bowtie 2. Nat Methods. 2012;9(4):357–359. doi: 10.1038/nmeth.1923. [DOI] [PMC free article] [PubMed] [Google Scholar]
  30. Li B, Dewey CN. RSEM: accurate transcript quantification from RNA-Seq data with or without a reference genome. BMC Bioinformatics. 2011;12:323. doi: 10.1186/1471-2105-12-323. [DOI] [PMC free article] [PubMed] [Google Scholar]
  31. Mortazavi A, Williams BA, McCue K, Schaeffer L, Wold B. Mapping and quantifying mammalian transcriptomes by RNA-Seq. Nat Methods. 2008;5(7):621–628. doi: 10.1038/nmeth.1226. [DOI] [PubMed] [Google Scholar]
  32. Tan CH, Tan KY, Fung SY, Tan NH. Venom-gland transcriptome and venom proteome of the malaysian king cobra (Ophiophagus hannah) BMC Genomics. 2015;16(1):687. doi: 10.1186/s12864-015-1828-2. [DOI] [PMC free article] [PubMed] [Google Scholar]
  33. Tan KY, Tan CH, Chanhome L, Tan NH. Comparative venom gland transcriptomics of Naja kaouthia (monocled cobra) from Malaysia and Thailand: elucidating geographical venom variation and insights into sequence novelty. PeerJ. 2017;5:e3142. doi: 10.7717/peerj.3142. [DOI] [PMC free article] [PubMed] [Google Scholar]
  34. Chong HP, Tan KY, Tan NH, Tan CH. Exploring the diversity and novelty of toxin genes in Naja sumatrana, the equatorial spitting cobra from Malaysia through De Novo venom-gland transcriptomics. Toxins (Basel) 2019;11(2):104. doi: 10.3390/toxins11020104. [DOI] [PMC free article] [PubMed] [Google Scholar]
  35. Rokyta DR, Lemmon AR, Margres MJ, Aronow K. The venom-gland transcriptome of the eastern diamondback rattlesnake (Crotalus adamanteus) BMC Genomics. 2012;13:312. doi: 10.1186/1471-2164-13-312. [DOI] [PMC free article] [PubMed] [Google Scholar]
  36. Tan CH, Tan KY. De Novo venom-gland transcriptomics of spine-bellied sea snake (Hydrophis curtus) from Penang, Malaysia-next-generation sequencing, functional annotation and toxinological correlation. Toxins. 2021;13(2):127. doi: 10.3390/toxins13020127. [DOI] [PMC free article] [PubMed] [Google Scholar]
  37. Waterhouse AM, Procter JB, Martin DMA, Clamp M, Barton GJ. Jalview Version 2--a multiple sequence alignment editor and analysis workbench. Bioinformatics. 2009;25(9):1189–1191. doi: 10.1093/bioinformatics/btp033. [DOI] [PMC free article] [PubMed] [Google Scholar]
  38. Edgar RC. MUSCLE: a multiple sequence alignment method with reduced time and space complexity. BMC Bioinformatics. 2004;5:113. doi: 10.1186/1471-2105-5-113. [DOI] [PMC free article] [PubMed] [Google Scholar]
  39. Corrêa-Netto C, Junqueira-de-Azevedo ILM, Silva DA, Ho PL, Leitao-de-Araujo M, Alves MLM, Sanz L, Foguel D, Zingali RB, Calvete JJ. Snake venomics and venom gland transcriptomic analysis of brazilian coral snakes, Micrurus altirostris and M. corallinus. J Proteomics. 2011;74(9):1795–1809. doi: 10.1016/j.jprot.2011.04.003. [DOI] [PubMed] [Google Scholar]
  40. Margres MJ, Aronow K, Loyacano J, Rokyta DR. The venom-gland transcriptome of the eastern coral snake (Micrurus fulvius) reveals high venom complexity in the intragenomic evolution of venoms. BMC Genomics. 2013;14(1):531. doi: 10.1186/1471-2164-14-531. [DOI] [PMC free article] [PubMed] [Google Scholar]
  41. Wong KY, Tan CH, Tan KY, Quraishi NH, Tan NH. Elucidating the biogeographical variation of the venom of Naja naja (spectacled cobra) from Pakistan through a venom-decomplexing proteomic study. J Proteomics. 2018;175:156–173. doi: 10.1016/j.jprot.2017.12.012. [DOI] [PubMed] [Google Scholar]
  42. Dutta S, Chanda A, Kalita B, Islam T, Patra A, Mukherjee AK. Proteomic analysis to unravel the complex venom proteome of eastern India Naja naja: correlation of venom composition with its biochemical and pharmacological properties. J Proteomics. 2017;156:29–39. doi: 10.1016/j.jprot.2016.12.018. [DOI] [PubMed] [Google Scholar]
  43. Oh AMF, Tan CH, Ariaranee GC, Quraishi N, Tan NH. Venomics of Bungarus caeruleus (Indian krait): comparable venom profiles, variable immunoreactivities among specimens from Sri Lanka, India and Pakistan. J Proteomics. 2017;164:1–18. doi: 10.1016/j.jprot.2017.04.018. [DOI] [PubMed] [Google Scholar]
  44. Oh AMF, Tan CH, Tan KY, Quraishi NH, Tan NH. Venom proteome of Bungarus sindanus (Sind krait) from Pakistan and in vivo cross-neutralization of toxicity using an indian polyvalent antivenom. J Proteomics. 2019;193:243–254. doi: 10.1016/j.jprot.2018.10.016. [DOI] [PubMed] [Google Scholar]
  45. Tan CH, Tan KY, Ng TS, Sim SM, Tan NH. Venom proteome of spine-bellied sea snake (Hydrophis curtus) from Penang, Malaysia: toxicity correlation, immunoprofiling and cross-neutralization by sea snake antivenom. Toxins (Basel) 2018;11(1):3. doi: 10.3390/toxins11010003. [DOI] [PMC free article] [PubMed] [Google Scholar]
  46. Lauridsen LP, Laustsen AH, Lomonte B, Gutiérrez JM. Toxicovenomics and antivenom profiling of the eastern green mamba snake (Dendroaspis angusticeps) J Proteomics. 2016;136:248–261. doi: 10.1016/j.jprot.2016.02.003. [DOI] [PubMed] [Google Scholar]
  47. Laustsen AH, Lomonte B, Lohse B, Fernández J, Gutiérrez JM. Unveiling the nature of black mamba (Dendroaspis polylepis) venom through venomics and antivenom immunoprofiling: identification of key toxin targets for antivenom development. J Proteomics. 2015;119:126–142. doi: 10.1016/j.jprot.2015.02.002. [DOI] [PubMed] [Google Scholar]
  48. Sanz L, Pla D, Pérez A, Rodríguez Y, Zavaleta A, Salas M, Lomonte B, Calvete JJ. Venomic analysis of the poorly studied desert coral snake, Micrurus tschudii tschudii, supports the 3FTx/PLA₂ dichotomy across Micrurus venoms. Toxins (Basel) 2016;8(6):178. doi: 10.3390/toxins8060178. [DOI] [PMC free article] [PubMed] [Google Scholar]
  49. Tan KY, Liew JL, Tan NH, Quah ESH, Ismail AK, Tan CH. Unlocking the secrets of banded coral snake (Calliophis intestinalis, Malaysia): a venom with proteome novelty, low toxicity and distinct antigenicity. J Proteomics. 2019;192:246–257. doi: 10.1016/j.jprot.2018.09.006. [DOI] [PubMed] [Google Scholar]
  50. Tsetlin V. Snake venom alpha-neurotoxins and other 'three-finger' proteins. Eur J Biochem. 1999;264(2):281–286. doi: 10.1046/j.1432-1327.1999.00623.x. [DOI] [PubMed] [Google Scholar]
  51. Kini RM, Doley R. Structure, function and evolution of three-finger toxins: mini proteins with multiple targets. Toxicon. 2010;56(6):855–867. doi: 10.1016/j.toxicon.2010.07.010. [DOI] [PubMed] [Google Scholar]
  52. Fox JW, Serrano SMT. Exploring snake venom proteomes: multifaceted analyses for complex toxin mixtures. Proteomics. 2008;8(4):909–920. doi: 10.1002/pmic.200700777. [DOI] [PubMed] [Google Scholar]
  53. Servent D, Ménez A. In: Handbook of Neurotoxicology. Massaro EJ, editor. Totowa, NJ: Humana Press; 2002. Snake neurotoxins that interact with nicotinic acetylcholine receptors; pp. 385–425. [Google Scholar]
  54. Abbas N, Gaudioso-Tyzra C, Bonnet C, Gabriac M, Amsalem M, Lonigro A, Padilla F, Crest M, Martin-Eauclaire MF, Delmas P. The scorpion toxin Amm VIII induces pain hypersensitivity through gain-of-function of TTX-sensitive Na+ channels. Pain. 2013;154(8):1204–1215. doi: 10.1016/j.pain.2013.03.037. [DOI] [PubMed] [Google Scholar]
  55. Moran Y, Gordon D, Gurevitz M. Sea anemone toxins affecting voltage-gated sodium channels--molecular and evolutionary features. Toxicon. 2009;54(8):1089–1101. doi: 10.1016/j.toxicon.2009.02.028. [DOI] [PMC free article] [PubMed] [Google Scholar]
  56. Eitan M, Fowler E, Herrmann R, Duval A, Pelhate M, Zlotkin E. A scorpion venom neurotoxin paralytic to insects that affects sodium current inactivation: purification, primary structure, and mode of action. Biochemistry. 1990;29(25):5941–5947. doi: 10.1021/bi00477a009. [DOI] [PubMed] [Google Scholar]
  57. Schiavon E, Stevens M, Zaharenko AJ, Konno K, Tytgat J, Wanke E. Voltage-gated sodium channel isoform-specific effects of pompilidotoxins. FEBS J. 2010;277(4):918–930. doi: 10.1111/j.1742-4658.2009.07533.x. [DOI] [PubMed] [Google Scholar]
  58. Fry BG, Vidal N, van der Weerd L, Kochva E, Renjifo C. Evolution and diversification of the Toxicofera reptile venom system. J Proteomics. 2009;72(2):127–136. doi: 10.1016/j.jprot.2009.01.009. [DOI] [PubMed] [Google Scholar]
  59. Karbat I, Kahn R, Cohen L, Ilan N, Gilles N, Corzo G, Froy O, Gur M, Albrecht G, Heinemann SH, Gordon D, Gurevitz M. The unique pharmacology of the scorpion α-like toxin Lqh3 is associated with its flexible C-tail. FEBS J. 2007;274(8):1918–1931. doi: 10.1111/j.1742-4658.2007.05737.x. [DOI] [PubMed] [Google Scholar]
  60. Konno K, Hisada M, Naoki H, Itagaki Y, Yasuhara T, Nakata Y, Miwa A, Kawai N. Molecular determinants of binding of a wasp toxin (PMTXs) and its analogs in the Na+ channels proteins. Neurosci Lett. 2000;285(1):29–32. doi: 10.1016/s0304-3940(00)01017-x. [DOI] [PubMed] [Google Scholar]
  61. Bulaj G, DeLaCruz R, Azimi-Zonooz A, West P, Watkins M, Yoshikami D, Oliveira BM. Delta-conotoxin structure/function through a cladistic analysis. Biochemistry. 2001;40(44):13201–13208. doi: 10.1021/bi010683a. [DOI] [PubMed] [Google Scholar]
  62. Gunning SJ, Chong Y, Khalife AA, Hains PG, Broady KW, Nicholson GM. Isolation of delta-missulenatoxin-Mb1a, the major vertebrate-active spider delta-toxin from the venom of Missulena bradleyi (Actinopodidae) FEBS Lett. 2003;554(1-2):211–218. doi: 10.1016/S0014-5793(03)01175-x. [DOI] [PubMed] [Google Scholar]
  63. Moran Y, Kahn R, Cohen L, Gur M, Karbat I, Gordon D, Gurevitz M. Molecular analysis of the sea anemone toxin Av3 reveals selectivity to insects and demonstrates the heterogeneity of receptor site-3 on voltage-gated Na+ channels. Biochem J. 2007;406(1):41–48. doi: 10.1042/BJ20070233. [DOI] [PMC free article] [PubMed] [Google Scholar]
  64. Takasaki C, Yoshida H, Shimazu T, Teruuchi T, Toriba M, Tamiya N. Studies on the venom components of the long-glanded coral snake, Maticora bivirgata. Toxicon. 1991;29(2):191–200. doi: 10.1016/0041-0101(91)90103-x. [DOI] [PubMed] [Google Scholar]
  65. Chien KY, Chiang CM, Hseu YC, Vyas AA, Rule GS, Wu W. Two distinct types of cardiotoxin as revealed by the structure and activity relationship of their interaction with zwitterionic phospholipid dispersions. J Biol Chem. 1994;269(20):14473–14483. [PubMed] [Google Scholar]
  66. Chiang CM, Chien KY, Lin HJ, Lin JF, Yeh HC, Ho PL, Wu WG. Conformational change and inactivation of membrane phospholipid-related activity of cardiotoxin V from Taiwan cobra venom at acidic pH. Biochemistry. 1996;35(28):9167–9176. doi: 10.1021/bi952823k. [DOI] [PubMed] [Google Scholar]
  67. Tsai IH, Tsai HY, Saha A, Gomes A. Sequences, geographic variations and molecular phylogeny of venom phospholipases and threefinger toxins of eastern India Bungarus fasciatus and kinetic analyses of its Pro31 phospholipases A2. FEBS J. 2007;274(2):512–525. doi: 10.1111/j.1742-4658.2006.05598.x. [DOI] [PubMed] [Google Scholar]
  68. Qian YC, Fan CY, Gong Y, Yang SL. cDNA cloning and sequence analysis of six neurotoxin-like proteins from Chinese continental banded krait. Biochem Mol Biol Int. 1998;46(4):821–828. doi: 10.1080/15216549800204362. [DOI] [PubMed] [Google Scholar]
  69. Fujimi TJ, Nakajyo T, Nishimura E, Ogura E, Tsuchiya T, Tamiya T. Molecular evolution and diversification of snake toxin genes, revealed by analysis of intron sequences. Gene. 2003;313:111–118. doi: 10.1016/s0378-1119(03)00637-1. [DOI] [PubMed] [Google Scholar]
  70. Tan CH, Wong KY, Tan NH, Ng TS, Tan KY. Distinctive distribution of secretory phospholipases A₂ in the venoms of afro-asian cobras (subgenus: Naja, Afronaja, Boulengerina and Uraeus) Toxins (Basel) 2019;11(2):116. doi: 10.3390/toxins11020116. [DOI] [PMC free article] [PubMed] [Google Scholar]
  71. Tan KY, Wong KY, Tan NH, Tan CH. Quantitative proteomics of Naja annulifera (sub-saharan snouted cobra) venom and neutralization activities of two antivenoms in Africa. Int J Biol Macromol. 2020;158:605–616. doi: 10.1016/j.ijbiomac.2020.04.173. [DOI] [PubMed] [Google Scholar]
  72. Doley R, Zhou X, Kini RM. In: Handbook of venoms and toxins of reptiles. 1. Mackessy SP, editor. London, UK: CRC Press Inc; 2009. Snake venom phospholipase A2 enzymes; pp. 173–215. [Google Scholar]
  73. Pereira MF, Novello JC, Cintra ACO, Giglio JR, Landucci ET, Oliveira B, Marangoni S. The amino acid sequence of bothropstoxin-II, an Asp-49 myotoxin from Bothrops jararacussu (Jararacucu) venom with low phospholipase A2 activity. J Protein Chem. 1998;17(4):381–386. doi: 10.1023/a:1022563401413. [DOI] [PubMed] [Google Scholar]
  74. Zhang HL, Xu SJ, Wang QY, Song SY, Shu YY, Lin ZJ. Structure of a cardiotoxic phospholipase A2 from Ophiophagus hannah with the “pancreatic loop”. J Struct Biol. 2002;138(3):207–215. doi: 10.1016/s1047-8477(02)00022-9. [DOI] [PubMed] [Google Scholar]
  75. Fohlman J, Eaker D, Karlsoon E, Thesleff S. Taipoxin, an extremely potent presynaptic neurotoxin from the venom of the australian snake taipan (Oxyuranus s. scutellatus). Isolation, characterization, quaternary structure and pharmacological properties. Eur J Biochem. 1976;68(2):457–469. doi: 10.1111/j.1432-1033.1976.tb10833.x. [DOI] [PubMed] [Google Scholar]
  76. Pearson JA, Tyler MI, Retson KV, Howden MEH. Studies on the subunit structure of textilotoxin, a potent presynaptic neurotoxin from the venom of the Australian common brown snake (Pseudonaja textilis). 3. The complete amino-acid sequences of all the subunits. Biochim Biophys Acta. 1993;1161(2-3):223–229. doi: 10.1016/0167-4838(93)90217-f. [DOI] [PubMed] [Google Scholar]
  77. Francis BR, da Silva NJ, Júnior, Seebart C, Casais e Silva LL, Schmidt JJ, Kaiser II. Toxins isolated from the venom of the brazilian coral snake (Micrurus frontalis frontalis) include hemorrhagic type phospholipases A2 and postsynaptic neurotoxins. Toxicon. 1997;35(8):1193–1203. doi: 10.1016/s0041-0101(97)00031-7. [DOI] [PubMed] [Google Scholar]
  78. Huang MZ, Gopalakrishnakone P. Pathological changes induced by an acidic phospholipase A2 from Ophiophagus hannah venom on heart and skeletal muscle of mice after systemic injection. Toxicon. 1996;34(2):201–211. doi: 10.1016/0041-0101(95)00128-x. [DOI] [PubMed] [Google Scholar]
  79. Wong KY, Tan CH, Tan NH. Venom and purified toxins of the spectacled cobra (Naja naja) from Pakistan: insights into toxicity and antivenom neutralization. Am J Trop Med Hyg. 2016;94(6):1392–1399. doi: 10.4269/ajtmh.15-0871. [DOI] [PMC free article] [PubMed] [Google Scholar]
  80. Tan CH, Wong KY, Tan KY, Tan NH. Venom proteome of the yellow-lipped sea krait, Laticauda colubrina from Bali: insights into subvenomic diversity, venom antigenicity and cross-neutralization by antivenom. J Proteomics. 2017;166:48–58. doi: 10.1016/j.jprot.2017.07.002. [DOI] [PubMed] [Google Scholar]
  81. Fox JW, Serrano SMT. Structural considerations of the snake venom metalloproteinases, key members of the M12 reprolysin family of metalloproteinases. Toxicon. 2005;45(8):969–985. doi: 10.1016/j.toxicon.2005.02.012. [DOI] [PubMed] [Google Scholar]
  82. Gutierrez JM, Ruvacodo A, Escalante T. In: Handbook of venoms and toxins of reptiles. 1. Mackessy SP, editor. London, UK: CRC Press Inc; 2009. Snake venom metalloproteinases Biological roles and participation in the pathophysiology of envenomation; pp. 115–138. [Google Scholar]
  83. Markland FS, Jr, Swenson S. Snake venom metalloproteinases. Toxicon. 2013;62:3–18. doi: 10.1016/j.toxicon.2012.09.004. [DOI] [PubMed] [Google Scholar]
  84. Fox JW, Serrano SMT. Insights into and speculations about snake venom metalloproteinase (SVMP) synthesis, folding and disulfide bond formation and their contribution to venom complexity. FEBS J. 2008;275(12):3016–3030. doi: 10.1111/j.1742-4658.2008.06466.x. [DOI] [PubMed] [Google Scholar]
  85. Rodrigues RS, Boldrini-França J, Fonseca FPP, de la Torre P, Henrique-Silva F, Sanz L, Calvete JJ, Rodrigues VM. Combined snake venomics and venom gland transcriptomic analysis of Bothropoides pauloensis. J Proteomics. 2012;75(9):2707–2720. doi: 10.1016/j.jprot.2012.03.028. [DOI] [PubMed] [Google Scholar]
  86. Vogel C, Marcotte EM. Insights into the regulation of protein abundance from proteomic and transcriptomic analyses. Nat Rev Genet. 2012;13(4):227–232. doi: 10.1038/nrg3185. [DOI] [PMC free article] [PubMed] [Google Scholar]

Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

Additional file 1. Venom gland transcriptomic analysis of Calliophis bivirgata flaviceps.
Click here for additional data file. (3.5MB, xlsx)
Additional file 2. Classification and sequences of toxin genes from Calliophis bivirgata flaviceps venom gland transcriptome.
Click here for additional data file. (178.4KB, xlsx)
Additional file 3. Output and quality metrics of RNA sequencing for the de novo assembly of Calliophis bivirgata flaviceps venom gland transcriptome.
Click here for additional data file. (67.5KB, pdf)

Articles from The Journal of Venomous Animals and Toxins Including Tropical Diseases are provided here courtesy of Centro de Estudos de Venenos e Animais Peçonhentos - CEVAP

RESOURCES