Abstract
Venom peptides found in terebrid snails expand the toolbox of active compounds that can be applied to investigate cellular physiology and can be further developed as future therapeutics. However, unlike other predatory organisms, such as snakes, terebrids produce very small quantities of venom, making it difficult to obtain sufficient amounts for biochemical characterization. Here, we describe the first recombinant expression and characterization of terebrid peptide, teretoxin Tgu6.1, from Terebra guttata. Tgu6.1 is a novel forty-four amino acid teretoxin peptide with a VI/VII cysteine framework (C–C–CC–C–C) similar to O, M and I conotoxin superfamilies. A ligation-independent cloning strategy with an ompT protease deficient strain of E. coli was employed to recombinantly produce Tgu6.1. Thioredoxin was introduced in the plasmid to combat disulfide folding and solubility issues. Specifically Histidine-6 tag and Ni-NTA affinity chromatography were applied as a purification method, and enterokinase was used as a specific cleavage protease to effectively produce high yields of folded Tgu6.1 without extra residues to the primary sequence. The recombinantly-expressed Tgu6.1 peptide was bioactive, displaying a paralytic effect when injected into a Nereis virens polychaete bioassay. The recombinant strategy described to express Tgu6.1 can be applied to produce high yields of other disulfide-rich peptides.
Highlights
Venom peptides are a resource for investigating evolution, cellular communication and therapeutic development [1,2,3]
Mature teretoxins from Terebra subulata and Hastula hectica synthesis (SPPS) and recombinant expression are often applied to produce synthetic versions of the were identified with cysteine frameworks similar to those found in conotoxins, but without signal peptides for investigation [21,22,23]
Small cysteine-rich peptides are difficult to overexpress in Escherichia coli due to the formation of insoluble protein aggregates or inclusion bodies, proteolytic degradation and reducing conditions in the E. coli cytoplasm that hinder the formation of disulfide bonds [14]
Summary
Venom peptides are a resource for investigating evolution, cellular communication and therapeutic development [1,2,3]. Toxins 2016, 8, 63; doi:10.3390/toxins8030063 www.mdpi.com/journal/toxins same degree of scientific attention In large part, this is because terebrids are smaller and produce venom on the nanogram scale. With technological advances, such as DNA and RNA sequencing, PCR and molecular biology, it is possible to investigate the primary sequences of terebrid venom peptides, teretoxins, using an integrated venomics strategy that combines phylogenetics, of Toxins. Recent molecular biology, it is possible to investigate the primary sequences terebrididentified venom peptides, isolation and structural characterization of teretoxin. Tv1 as teretoxins, using an integrated venomics strategy that combines phylogenetics, transcriptomics and similar to M‐superfamily conotoxins; Tv1 has a unique fold and disulfide‐bonding pattern proteomics [8,9,17,18].
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