Multifunctional Toxins in Snake Venoms and Therapeutic Implications: From Pain to Hemorrhage and Necrosis

Ferraz, Camila R.; Arrahman, Arif; Xie, Cuicui; Casewell, Nicholas R.; Lewis, Richard J.; Kool, Jeroen; Cardoso, Fernanda C.

doi:10.3389/fevo.2019.00218

Cited by 148 publications

(112 citation statements)

References 195 publications

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“…The SVSP identified (“Thrombin-like enzyme ancrod-2”; SC, 53%) has previously been shown to be fibrinogenolytic (51), while the literature relating to the SVMPs detected (“Snake venom metalloproteinase kistomin” and “Zinc metalloproteinase/disintegrin” SC, 33% and 27%, respectively) suggests they predominately exert anticoagulant activities, including interfering with platelet aggregation and promoting haemorrhage (52, 53). It is therefore possible that these toxins are co-eluting with procoagulant components, although given that many SVMPs are multi-functional proteins that can exert procoagulant bioactivities (54), they may be contributing to the functional effect observed here despite these activities not previously being reported.…”

Section: Resultsmentioning

confidence: 88%

“…weakly procoagulant toxins being masked via co-eluting in the anticoagulant areas), it is worth noting that one of the strengths of our approach is the deconvolution of coagulopathic toxin activities from the complex venom mixture, and specifically the identification of anticoagulant venom activity from these ‘net’ procoagulant venoms. Prior studies using crude venom have demonstrated that the majority of the venoms tested here are procoagulant and potently clot plasma (7, 29, 31, 32, 54, 79–82). Despite these observations, our nanofractionation approach clearly reveals that many of these venoms also contain anticoagulant bioactives (e.g.…”

Section: Summary Of Toxin Identificationsmentioning

confidence: 95%

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High throughput screening and identification of coagulopathic snake venom proteins and peptides using nanofractionation and proteomics approaches

Slagboom

Mladic

Xie³

et al. 2019

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17Snakebite is a neglected tropical disease that results in a variety of systemic and local pathologies in 18 envenomed victims and is responsible for around 138,000 deaths every year. Many snake venoms cause 19 severe coagulopathy that makes victims vulnerable to suffering life-threating haemorrhage. The 20 mechanisms of action of coagulopathic snake venom toxins are diverse and can result in both anticoagulant 21 and procoagulant effects. However, because snake venoms consist of a mixture of numerous protein and 22 peptide components, high throughput characterizations of specific target bioactives is challenging. In this 23 study, we applied a combination of analytical and pharmacological methods to identify snake venom toxins 24 from a wide diversity of snake species that perturb coagulation. To do so, we used a high-throughput 25 screening approach consisting of a miniaturised plasma coagulation assay in combination with a venom 26 nanofractionation approach. Twenty snake venoms were first separated using reversed-phase liquid 27 chromatography, and a post-column split allowed a small fraction to be analyzed with mass spectrometry, 28 while the larger fraction was collected and dispensed onto 384-well plates before direct analysis using a 29 plasma coagulation assay. Our results demonstrate that many snake venoms simultaneously contain both 30 procoagulant and anticoagulant bioactives that contribute to coagulopathy. In-depth identification analysis 31 from seven medically-important venoms, via mass spectrometry and nanoLC-MS/MS, revealed that 32 phospholipase A 2 toxins are frequently identified in anticoagulant venom fractions, while serine protease 33 and metalloproteinase toxins are often associated with procoagulant bioactivities. The nanofractionation 34 and proteomics approach applied herein seems likely to be a valuable tool for the rational development of 35 next-generation snakebite treatments by facilitating the rapid identification and fractionation of 36 coagulopathic toxins, thereby enabling specific targeting of these toxins by new therapeutics such as 37 monoclonal antibodies and small molecule inhibitors. Classified Personnel Information 39Author summary 40 Snakebite is a neglected tropical disease that results in more than 100,000 deaths every year. 41Haemotoxicity is one of the most common signs of systemic envenoming observed after snakebite, and 42 many snake venoms cause severe impairment of the blood coagulation that makes victims vulnerable to 43 suffering life-threating hemorrhage. In this study, we applied a combination of analytical and 44 pharmacological methods to identify snake venom toxins from a wide diversity of snake species that 45 interfere with blood coagulation. Twenty snake venoms were screened for their effects on the blood 46 coagulation cascade and based on the initial results and the medical relevance of the species, seven 47 venoms were selected for in-depth analysis of the responsible toxins using advanced identification 48 techniques. Our findings reveal a number ...

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Section: Resultsmentioning

confidence: 88%

Section: Summary Of Toxin Identificationsmentioning

confidence: 95%

High throughput screening and identification of coagulopathic snake venom proteins and peptides using nanofractionation and proteomics approaches

Slagboom

Mladic

Xie³

et al. 2019

Preprint

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“…Treatments for systemic viper envenoming need to neutralize a number of major classes of hemotoxins, which are found in varying abundances across medically important snake species, and typically include the Zn 2+ -dependent snake venom metalloproteinases (SVMPs), phospholipase A 2 (PLA 2 s) and snake venom serine proteases (SVSPs) 17 . Collectively, these three enzymatic families typically comprise >60% of all toxins found in viper venom proteomes 5 and, in combination, are responsible for: (i) the destruction of local tissue, often resulting in necrosis, (ii) the degradation of the basement and cellular membranes resulting in extravasation, and (iii) the onset of coagulopathy via the activation and breakdown of clotting factors -with the latter two effects often culminating in life-threatening systemic hemorrhage [17][18][19][20] .…”

Section: Introductionmentioning

confidence: 99%

A therapeutic combination of two small molecule toxin inhibitors provides pancontinental preclinical efficacy against viper snakebite

Albulescu

Xie²,

Ainsworth³

et al. 2020

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Snakebite is a medical emergency causing high mortality and morbidity in rural tropical communities that typically experience delayed access to unaffordable therapeutics. Viperid snakes are responsible for the majority of envenomings, but extensive interspecific variation in venom composition dictates that different antivenom treatments are used in different parts of the world, resulting in clinical and fiscal snakebite management challenges. Here, we show that a number of repurposed Phase 2-approved small molecules are capable of broadly neutralizing distinct viper venom bioactivities in vitro by inhibiting different enzymatic toxin families. Furthermore, using multiple in vivo models of envenoming, we demonstrate that a single dose of a rationally-selected dual inhibitor combination consisting of marimastat and varespladib prevents lethality caused by venom from the most medically-important vipers of Africa, South Asia and Central America. Our findings strongly support the translation of

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“…Snake venom PLA 2 s (svPLA 2 s) can be major toxin components -they often comprise 30-71% of the total venom proteins, and they can also be diverse in terms of amino acid composition, as evidenced by the UniProtKB database containing over 400 unique svPLA 2 s. [6] In addition to catalyzing the production of lysophospholipids and fatty acid pro-inflammatory mediators, svPLA 2 s are multifunctional enzymes and cause a wide variety of toxic effects ranging from neurotoxicity, myotoxicity, anticoagulant effects, cytotoxicity, cardiotoxicity, to edema. [7] Because of the pathological consequences of these toxins to prey and snakebite victims, svPLA 2 s have been extensively investigated. [7,8] Since May 2018, snake envenoming has been categorized as one of the most neglected tropical diseases.…”

Section: Introductionmentioning

confidence: 99%

“…[7] Because of the pathological consequences of these toxins to prey and snakebite victims, svPLA 2 s have been extensively investigated. [7,8] Since May 2018, snake envenoming has been categorized as one of the most neglected tropical diseases. [9] The annual number of human snakebites is estimated to be between 1.8 and 2.7 million worldwide, resulting in 81,000-138,000 deaths and around three times more cases of permanent morbidity cases.…”

Section: Introductionmentioning

confidence: 99%

Development of high-throughput screening assays for profiling snake venom Phospholipase A₂activity after high-resolution chromatographic fractionation

Slagboom

Kidwai

et al. 2020

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Many organisms, ranging from plants to mammals, contain phospholipase A 2 enzymes (PLA 2 s), which catalyze the production of lysophospholipids and fatty acid proinflammatory mediators. PLA 2 s are also common constituents of animal venoms, including bees, scorpions and snakes, and they cause a wide variety of toxic effects including neuro-, myo-, cyto-, and cardio-toxicity, anticoagulation and edema. The aim of this study was to develop a generic method for profiling enzymatically active PLA 2 s in snake venoms after chromatographic separation. For this, low-volume high-throughput assays for assessment of enzymatic PLA 2 activity were evaluated and optimized. Subsequently, the assays were incorporated into a nanofractionation platform that combines high-resolution fractionation of crude venoms by liquid chromatography (LC) with bioassaying in 384-well plate format, and parallel mass spectrometric (MS) detection for toxin identification. The miniaturized assays developed are based on absorbance or fluorescence detection (respectively, using cresol red or fluorescein as pH indicators) to monitor the pH drop associated with free fatty acid formation by enzymatically active PLA 2 s. The methodology was demonstrated for assessment of PLA 2 activity profiles of venoms from the snake species Bothrops asper, Echis carinatus, Echis coloratus, Echis ocellatus, Oxyuranus scutellatus and Daboia russelii russelii.

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Multifunctional Toxins in Snake Venoms and Therapeutic Implications: From Pain to Hemorrhage and Necrosis

Cited by 148 publications

References 195 publications

High throughput screening and identification of coagulopathic snake venom proteins and peptides using nanofractionation and proteomics approaches

High throughput screening and identification of coagulopathic snake venom proteins and peptides using nanofractionation and proteomics approaches

A therapeutic combination of two small molecule toxin inhibitors provides pancontinental preclinical efficacy against viper snakebite

Development of high-throughput screening assays for profiling snake venom Phospholipase A₂activity after high-resolution chromatographic fractionation

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Multifunctional Toxins in Snake Venoms and Therapeutic Implications: From Pain to Hemorrhage and Necrosis

Cited by 148 publications

References 195 publications

High throughput screening and identification of coagulopathic snake venom proteins and peptides using nanofractionation and proteomics approaches

High throughput screening and identification of coagulopathic snake venom proteins and peptides using nanofractionation and proteomics approaches

A therapeutic combination of two small molecule toxin inhibitors provides pancontinental preclinical efficacy against viper snakebite

Development of high-throughput screening assays for profiling snake venom Phospholipase A2activity after high-resolution chromatographic fractionation

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Product

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Development of high-throughput screening assays for profiling snake venom Phospholipase A₂activity after high-resolution chromatographic fractionation