Ta3a

Ta3a belongs to the aculeatoxin family of peptides, found in the venom of Hymenoptera.^[1] It is a 29-residue peptide, which is predicted to have an alpha-helical structure (amino acid sequence: LAPIFALLLLSGLFSLPALQHYIEKNYIN).^{[1] [2]} Ta3a is similar to poneratoxin, a voltage-gated sodium channel toxin found in the ant species Paraponera clavata, as well as to other uncharacterised peptides from various other ant species.^[1]

Ta3a targets voltage-gated sodium channels such as Na_v1.6, Na_v1.7 and Na_v1.8, which are involved in peripheral pain signaling.^[1][3] The half-maximal effective concentration (EC50) of Ta3a for the human Na_v1.7 channel is 30 ± 9 nM.^[1] Na_v1.6 is similarly sensitive to Ta3a with an EC50 of 25 ± 2 nM, while Na_v1.8 is less sensitive with an EC50 of 331 ± 58 nM.^[1]

Ta3a exerts a significant regulatory effect on voltage-gated sodium channels, particularly through its interaction with the Na_v1.7 subtype. It prolongs the duration that the channel remains active and increases the likelihood of the channel being open. Additionally, Ta3a shifts the activation of Na_v1.7 to more negative (hyperpolarized) potentials, allowing Na_v1.7 channels to remain active for extended periods even in the absence of additional voltage stimuli. These prolonged, non-inactivating currents cause significant changes in the cell's membrane potential, due to the continuous sodium influx. Such prolonged sodium channel activation also permits sodium currents to persist at very low membrane potentials. The mechanism of action of Ta3a is believed to involve the stabilization of the S4 voltage-sensing domain of Na_v1.7 channels in their "activated" conformation, thereby maintaining channel activity. The S4 region contains multiple positively charged amino acid residues that respond to changes in membrane potential.^[4] Thus, Ta3a likely interacts with the S4 region, leading to channel activation at lower voltages. Therefore, the amount of external voltage required for channel activation is reduced.

The hallmark of Ta3a toxicity is acute pain, which is the most immediate and prominent symptom of Ta3a exposure.^[2] This is due to the excessive activation of the Na_v1.7 channel, which plays a crucial role in pain transmission by enhancing the propagation of nerve signals, particularly pain-related signals. While there are no detailed studies on the effects of Ta3a on the cardiovascular or respiratory systems, overactivation of sodium channels could potentially impact cardiac cells, leading to arrhythmias or other cardiovascular complications.^[5] In severe cases, prolonged sodium channel opening may also affect the central nervous system, potentially causing respiratory difficulties or paralysis.^[6][7]

Since Ta3a primarily exerts its toxic effects by overactivating the Na_v1.7 channel, sodium channel blockers represent a potential therapeutic approach. For instance, tetrodotoxin (TTX), a sodium channel blocker, has been shown to effectively inhibit the persistent currents induced by Ta3a in experimental settings^[2]. However, no studies have yet been conducted on specific treatment methods for Ta3a poisoning.