The Effects of Sodium-Transport Inhibitors and Cooling on Membrane Potentials in Cockroach Central Nervous Connectives

Cold-acclimation improves chill tolerance in the migratory locust through preservation of ion balance and membrane potential

Most insects have the ability to alter their cold tolerance in response to temporal temperature fluctuations, and recent studies have shown that insect cold tolerance is closely tied to the ability to maintain transmembrane ion-gradients that are important for the maintenance of cell membrane potential (Vm). Accordingly, several studies have suggested a link between preservation of Vm and cellular survival after cold stress, but none have measured Vm in this context. We tested this hypothesis by acclimating locusts (Locusta migratoria) to high (31°C) and low temperature (11°C) for four days before exposing them to cold stress (0°C) for up to 48 hours and subsequently measuring ion balance, cell survival, muscle Vm, and whole animal performance. Cold stress caused gradual muscle cell death which coincided with a loss of ion balance and depolarisation of muscle Vm. The loss of ion-balance and cell polarisation were, however, dampened markedly in cold-acclimated locusts such that the development of chill injury was reduced. To further examine the association between cellular injury and Vm we exposed in vitro muscle preparations to cold buffers with low, intermediate, or high [K+]. These experiments revealed that cellular injury during cold exposure occurs when Vm becomes severely depolarised. Interestingly we found that cellular sensitivity to hypothermic hyperkalaemia was lower in cold-acclimated locusts that were better able to defend Vm whilst exposed to high extracellular [K+]. Together these results demonstrate a mechanism of cold-acclimation in locusts that improves survival after cold stress: Increased cold tolerance is accomplished by preservation of Vm through maintenance of ion homeostasis and decreased K+-sensitivity.

Alkaloid neurotoxins-dependent sodium transport in insect synaptic nerve-ending particles

1. Sodium uptake associated with the activation of voltage-sensitive sodium channels by alkaloid activators, batrachotoxin, veratridine, and aconitine in presynaptic nerve terminals isolated from the central nervous system of cockroach (Periplaneta americana) was investigated. 2. Batrachotoxin (K0.5, 0.2 microM) was full agonist as for most effective activator of Na+ uptake; veratridine (K0.5, 2.5 microM) and aconitine (K0.5, 7.6 microM) produced a maximal stimulation of 22Na+ uptake that were 71% and 43% respectively of that produced by batrachotoxin. 3. Veratridine-dependent 22Na+ uptake was completely inhibited by tetrodotoxin (I0.5, 11 nM), a specific inhibitor of the nerve membrane sodium channels. 4. The present study describes appropriate conditions for measuring neurotoxins--stimulated sodium transport in insect central nervous system synaptosomes. The data show that voltage-sensitive sodium channels as defined by specific activation by the alkaloid neurotoxins are qualitatively distinct in insect synaptosomes than those previously described for vertebrate brain synaptosomes, cultured neuronal cell, nerve membrane vesicles and neuroblastoma cells.

Physiological and ultrastructural evidence for an extracellular anion matrix in the central nervous system of an insect (Periplaneta americana)

The efflux of radiocations (22Na, 2K and 45Ca) and of radiochloride occur as two-stage processes from intact cockroach nerve cords. It is suggested that the initial, fast fraction of efflux comes mainly from the superficial connective tissue layer, the neural lamella, and the clefts between the underlying layer of neuroglia, the perineurium. This is deduced from the lack of effect of a metabolic inhibitor and sodium-transport inhibitors on the fast component of 22Na efflux (which contrast with their effects both on the size an the half-time of the slow component) and from the typically extracellular ratios between the fast components of substantial increase in the fast fractions of 22Na and 45Ca efflux but only a small increase in 36Cl efflux: effects which would be expected if the addition to the fast fraction consisted of ions maintained in Donnan equilibrium with fixed anionic sites within the extracellular system. The presence of such anionic sites is also indicated by lanthanum-binding in the extracellular matrix and by the previous histochemical demonstration of hyaluronic acid in the matrix by Ashhurst and Costin. It is suggested that the anionic glycosaminoglycans provide an extracellular cation reservoir which could serve a role in short-term ionic homeostasis of the brain microenvironment.

Effects of palytoxin on sodium and potassium permeabilities in unmyelinated axons

Palytoxin (PTX) is a very potent marine toxin isolated from the Zoanthid Palythoa. Its effects on the nerve membrane have been studied on two different preparations: the giant axon of the Cockroach, Periplaneta americana and the giant axon of the Squids, Loligo pealei and Loligo forbesi. In both preparations, PTX at concentrations ranging from 0.03 to 10 microM depolarized the axonal membrane through a selective increase in the resting sodium conductance. This increase was never reversible and was only temporarily and partly antagonized by tetrodotoxin (TTX) at concentrations which block completely the voltage-dependent sodium conductance. A voltage-clamp analysis of these effects showed that, besides this increase, PTX induced complex modifications of the voltage-dependent ionic conductances and increased the leak conductance. The selectivity of the PTX induced sodium channels seemed to decrease with time. Altogether, the results indicate that PTX induces strong and irreversible modifications of the membrane structure.