MEF2 proteins, including MEF2A, are expressed in both muscle and non-muscle cells.

The MEF2 proteins are involved in regulation of many muscle specific genes. Although MEF2 RNAs encoding the MEF2A and MEF2D isoforms are ubiquitously expressed, the presence of MEF2 proteins in non-muscle cell types has been controversial. Here we use a well-characterised antibody in conjunction with DNA binding studies to provide evidence that members of the MEF2 family are widely expressed in the nuclei of cultured cells and are competent to bind DNA. The data show that non-muscle MEF2 complexes contain MEF2A, and that another MEF2 protein, probably MEF2D, is also present. These results suggest that MEF2 proteins fulfil functions in addition to muscle-specific gene expression.     

Predation and the evolution of gregariousness. II. An economic model for predator-prey interaction

An earlier paper presented models which allow the relative advantages of different prey dispersions to be assessed for two cases: when the prey's main defence is concealment, and when prey may evade the predator (Treisman 1975). With these as a basis, an economic model for predator-prey interaction is developed which takes explicit account of the conflicts between the need to maintain watch for a predator and the prey's other needs. The model embodies arguments based on statistical decision theory which allow factors such as the degree of predation threat, the watchfulness of the prey and the number of watchers to be related to the expected value of the prey's performance. The model provides a basis for predicting the optimal number of watchers or optimal group size under various conditions. The advantages of different group configurations are compared, and it is shown that animals which aggregate (and maintain a high sensory decision criterion) will have an advantage over solitary animals under certain conditions.     

Electrical and adaptive properties of rod photoreceptors in bufo marinus. I. Effects of altered extracellular Ca(2+) levels

The effects of altering extracellular Ca(2+) levels on the electrical and adaptive properties of toad rods have been examined. The retina was continually superfused in control (1.6 mM Ca(2+)) or test ringer’s solutions, and rod electrical activity was recorded intracellularly. Low-calcium ringer’s (10(-9)M Ca(2+)) superfused for up to 6 min caused a substantial depolarization of the resting membrane potential, an increase in light-evoked response amplitudes, and a change in the waveform of the light-evoked responses. High Ca(2+) ringer’s (3.2 mM) hyperpolarized the cell membrane and decreased response amplitudes. However, under conditions of either low or high Ca(2+) superfusion for up to 6 min, in both dark-adapted and partially light-adapted states, receptor sensitivity was virtually unaffected; i.e., the V-log I curve for the receptor potential was always located on the intensity scale at a position predicted by the prevailing light level, not by Ca(2+) concentration. Thus, we speculate that cytosol Ca(2+) concentration is capable of regulating membrane potential levels and light-evoked response amplitudes, but not the major component of rod sensitivity. Low Ca(2+) ringer’s also shortened the period of receptor response saturation after a bright but nonbleaching light flash, hence accelerating the onset of both membrane potential and sensitivity recovery during dark adaptation.

Exposure of the retina to low Ca(2+) (10(-9)M) ringer’s for long periods (7-15 min) caused dark-adapted rods to lose responsiveness. Response amplitudes gradually decreased, and the rods became desensitized. These severe conditions of low Ca(2+) caused changes in the dark-adapted rod that mimic those observed in rods during light adaptation. We suggest that loss of receptor sensitivity during prolonged exposure to low Ca(2+) ringer’s results from a decrease of intracellular (intradisk) stores of Ca(2+); i.e., less Ca(2+) is thereby released per quantum catch.

     

Plant- and stimulus-specific variations in remote-controlled sieve-tube occlusion

Phloem injury triggers local sieve-plate occlusion including callose-mediated constriction and protein plugging of sieve pores. In intact plants, reversible sieve-plate occlusion is induced by electric potential waves (EPWs)—accompanied by Ca²⁺-influx—as result of distant burning. Here, we present additional results which pertain to (a) the variability of EPW-profiles in relation to forisome conformation in intact Vicia faba plants and (b) the differential occlusion reactions to burning and cutting in various plant species. A correlation between stimulus perception and mode of phloem loading is discussed.Key words: callose, electrical potential waves, forisome, membrane potential, phloem transport, sieve-element occlusion, wound potentials