Thermotaxis and protoplasmic oscillations inPhysarum plasmodia analysed in a novel device generating stable linear temperature gradients

Abstract

The application of sublethal temperature gradients offers a simple, non-invasive means for in vivo studies of thermotaxis and other temperature-dependent processes in various organisms. Development, for instance, can be dramatically desynchronized, and the resulting development gradients allow to analyze physiological inter-dependencies between locally separated subsystems. For this purpose a simple device has been developed, by which a stable linear gradient of 8 °C/cm is established on an inert metal sheet with the aid of Peltier elements. The effects of linear temperature gradients on fusion, growth, and migration of plasmodia of the slime moldPhysarum polycephalum was filmed by 16 mm film time-lapse technique, and their local contraction—relaxation cycles analysed by “multistrip kymography”, which represents a graphic documentation of the spatio-temporal pattern of protoplasmic movements that occur along well-defined regions within the giant cell.Physarum plasmodia preferentially fuse, and grow, in the range of 24–26 °C. Different parts of a single macroplasmodium can simultaneously show positive and negative thermotaxis. The contraction—relaxation cycles generating the protoplasmic shuttle streaming within the network of veins essentially depend on local temperatures and are instantaneously desynchronized by the temperature gradient. Thus they cannot be controlled by a central pacemaker or an overall electric signal. However, there is a strong tendency to locally synchronize the various oscillation frequencies present within the giant cell if temperature differences do not exceed 2 °C.