Snake Venom Peptides: Tools of Biodiscovery

Munawar, Aisha; Ali, Syed Abid; Akrem, Ahmed; Betzel, Christian

doi:10.3390/toxins10110474

Cited by 113 publications

(86 citation statements)

References 206 publications

(224 reference statements)

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“…These features optimize their pharmacokinetics and extend their elimination half-life so that they resist enzymatic degradation. The APD contains 3156 AMPs, 98% of which were discovered in nature [13]: many, in fact, were extracted from the skin secretions of frogs [44,[113][114][115] or are toxins from other species, e.g., bees, snakes, and wasps [86,116,117]. In contrast, all the FDA-approved AMPs were discovered in or derived from Gram-positive bacteria commonly found in the soil: Brevibacillus brevis (gramicidin), Streptomyces roseosporus (daptomycin), Amycolatopsis orientalis (vancomycin, which is the prototype of oritavancin, dalbavancin, and telavancin), and Paenibacillus polymyxa (colistin) [118].…”

Section: Conclusion and Future Perspectivesmentioning

confidence: 99%

Development and Challenges of Antimicrobial Peptides for Therapeutic Applications

2020

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More than 3000 antimicrobial peptides (AMPs) have been discovered, seven of which have been approved by the U.S. Food and Drug Administration (FDA). Now commercialized, these seven peptides have mostly been utilized for topical medications, though some have been injected into the body to treat severe bacterial infections. To understand the translational potential for AMPs, we analyzed FDA-approved drugs in the FDA drug database. We examined their physicochemical properties, secondary structures, and mechanisms of action, and compared them with the peptides in the AMP database. All FDA-approved AMPs were discovered in Gram-positive soil bacteria, and 98% of known AMPs also come from natural sources (skin secretions of frogs and toxins from different species). However, AMPs can have undesirable properties as drugs, including instability and toxicity. Thus, the design and construction of effective AMPs require an understanding of the mechanisms of known peptides and their effects on the human body. This review provides an overview to guide the development of AMPs that can potentially be used as antimicrobial drugs.

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Section: Conclusion and Future Perspectivesmentioning

confidence: 99%

Development and Challenges of Antimicrobial Peptides for Therapeutic Applications

2020

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“…These venoms comprise 50-200 components distributed in dominant and secondary families which can be presented in multiple proteins and peptides isoforms (Vonk et al, 2011;Slagboom et al, 2017;Tasoulis and Isbister, 2017). The dominant families are secreted phospholipases A 2 (PLA2s), snake venom metalloproteinases (SVMP), snake venom serine proteases (SVSP), and three-finger peptides (3FTX), while the secondary families comprise cysteine-rich secretory proteins, Lamino acid oxidases, kunitz peptides, C-type lectins, disintegrins, and natriuretic peptides (Slagboom et al, 2017;Tasoulis and Isbister, 2017;Munawar et al, 2018). Interestingly, snake venom composition varies interspecifically (Fry et al, 2008;Tasoulis and Isbister, 2017), as well as intraspecifically, with many factors influencing this diversity including age (Dias et al, 2013), gender (Menezes et al, 2006;Zelanis et al, 2016), location (Durban et al, 2011;Goncalves-Machado et al, 2016), diet (Barlow et al, 2009), and season (Gubensek et al, 1974).…”

Section: Introductionmentioning

confidence: 99%

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

et al. 2019

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Animal venoms have evolved over millions of years for prey capture and defense from predators and rivals. Snake venoms, in particular, have evolved a wide diversity of peptides and proteins that induce harmful inflammatory and neurotoxic effects including severe pain and paralysis, hemotoxic effects, such as hemorrhage and coagulopathy, and cytotoxic/myotoxic effects, such as inflammation and necrosis. If untreated, many envenomings result in death or severe morbidity in humans and, despite advances in management, snakebite remains a major public health problem, particularly in developing countries. Consequently, the World Health Organization recently recognized snakebite as a neglected tropical disease that affects ∼2.7 million p.a. The major protein classes found in snake venoms are phospholipases, metalloproteases, serine proteases, and three-finger peptides. The mechanisms of action and pharmacological properties of many snake venom toxins have been elucidated, revealing a complex multifunctional cocktail that can act synergistically to rapidly immobilize prey and deter predators. However, despite these advances many snake toxins remain to be structurally and pharmacologically characterized. In this review, the multifunctional features of the peptides and proteins found in snake venoms, as well as their evolutionary histories, are discussed with the view to identifying novel modes of action and improving snakebite treatments.

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“…The non-reduced intact mass signal of fraction 11 shows a mass of 6,630.1 Da, which is an indicator for a Kunitz-type serine protease inhibitor ( Figure 3A ). 68, 69 The comparison with the reduced intact mass (6,636.2 Da) reveals a mass shift of Δ6.1 Da (corresponding to three disulfide bridges), which confirms the Kunitz-type architecture. Furthermore we were able to identify several PLA 2 proteoforms in fractions 14 and 15 by disulfide bond mapping ( Figure 3B ).…”

Section: Resultsmentioning

confidence: 55%

Extended snake venomics by top-down in-source decay: Investigating the newly discovered Anatolian Meadow viper subspecies,Vipera anatolica senliki

Hempel

Damm

Mrinalini

et al. 2019

Preprint

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13Herein we report on the venom proteome of Vipera anatolica senliki, a recently discovered and 14 hitherto unexplored subspecies of the critically endangered Anatolian Meadow viper endemic to the 15 Antalya Province of Turkey. Integrative venomics, including venom gland transcriptomics as well as 16 complementary bottom-up and top-down proteomic analyses, were applied to fully characterize the 17 venom of V. a. senliki. Furthermore, the classical top-down venomics approach was extended to 18 elucidate the venom proteome by an alternative in-source decay (ISD) proteomics workflow using the 19 reducing matrix 1,5-diaminonaphthalene (1,5-DAN). Top-down ISD proteomics allows for disulfide 20 bond mapping as well as effective de novo identification of high molecular weight venom constituents, 21 both of which are difficult to achieve by commonly established top-down approaches. Venom gland 22 transcriptome analysis identified 42 venom transcript annotations from 13 venom toxin families. 23 Relative quantitative snake venomics revealed snake venom metalloproteinases (svMP, 42.9%) as 24 the most abundant protein family, followed by several less dominant toxin families. Online mass 25 profiling and top-down venomics provide a detailed insight into the venom proteome of V. a. senliki 26 and facilitates a comparative analysis of venom variability for the closely related subspecies, V. a. 27 anatolica.28

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Snake Venom Peptides: Tools of Biodiscovery

Cited by 113 publications

References 206 publications

Development and Challenges of Antimicrobial Peptides for Therapeutic Applications

Development and Challenges of Antimicrobial Peptides for Therapeutic Applications

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

Extended snake venomics by top-down in-source decay: Investigating the newly discovered Anatolian Meadow viper subspecies,Vipera anatolica senliki

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