A robust platform for recombinant production of animal venom toxin modulators of ion channels
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Background and Purpose
Peptide toxins isolated from animal venom are potent and selective modulators of ion channels, and promising therapeutic leads. Due to intricate disulphide bridge patterns, they are often challenging to produce in standard laboratory settings, which limits engineering approaches to manipulate their structure-function properties. Given the low cost, wide accessibility, and versatility of recombinant expression systems for protein production, we set out to establish a straightforward high-yield strategy across a broad panel of peptide toxins from snakes, spiders and scorpions.
Experimental Approach
13 toxin DNA sequences were genetically fused to the C-terminus of either bivalent or monovalent human IgG1 antibody fragment crystallisable (Fc) domain sequences and expressed recombinantly from mammalian Expi293F cells. Affinity-purified proteins were evaluated by SDS-PAGE and size-exclusion chromatography (SEC). Function was assessed by Ca 2+ flux assays on CN21 cells, or whole-cell electrophysiology on human embryonic kidney (HEK293T) cells, Chinese hamster ovary (CHO) cells, or dorsal root ganglion (DRG) neurons. Immunocytochemistry using HEK293T cells and mouse DRG neurons assessed Fc-toxin fusion binding.
Key Results
Monovalent Fc-toxin fusions consistently yielded 1-6 mg of pure, non-proteolytically cleaved protein from 20-70 ml cultures for several toxin types, including three-finger toxins from snakes, inhibitory cystine knot (ICK) toxins from spiders, and α-toxins from scorpions, substantially surpassing the performance of unfused toxins or bivalent Fc-toxin fusions which gave low or no yield. Snake toxins targeting nicotinic acetylcholine receptors retained high single digit nanomolar inhibitory potency. Spider and scorpion toxins targeting the voltage-gated Na + channel Na v 1.7 retained pharmacological function and selectivity across a panel of five Na v subtypes, albeit with reduced potencies that did not exceed ∼70 nM.
Conclusions and Implications
We present a strategy for straightforward robust production of pure, monodisperse, and functional animal venom-derived toxins. This lowers the barrier to toxin production in a standard laboratory setting for follow-on engineering purposes.
