Do sires and juvenile male mice (C57BL/6) contribute to the rearing of the offspring?

Copulation and/or cohabitation with a pregnant female facilitate paternal behavior in male mice. However, their contribution to the rearing of the offspring is still not well understood. Our aims were to investigate the behavior of sires toward own or alien pups; the immediate consequences of the presence of fathers on the offspring and the behavior of the mother; and whether the exposure of juvenile males to newborn siblings, in an overlapping litters context, facilitates paternal behavior in C57BL/6 mice. We found that sires behaved paternally toward alien pups at both postpartum days 3 and 7; did not affect the behavior of the mother (e.g., licking and grooming, retrieval behavior, time in the nest, and crouching postures); and reduced the time offspring stayed alone in the nest. The exposure to newborn siblings did not promote paternal behavior in juvenile males. Therefore, sires are more paternal than usually described in the literature for laboratory mice, suggesting a facultative role in the rearing of the offspring. However, juvenile male mice, in contrast to juvenile females, could be adapted to leave the nest earlier without major contribution to the offspring.     

Comparative Study of Six Strains of Naegleria with Special Reference to Nonpathogenic Variants of Naegleria fowleri*

SYNOPSIS. Naegleria fowleri strains HB-1 and KUL, pathogenic for humans, Naegleria gruberi strain 1518/1e, and 3 strains (Vm1, LvH₁, and LvH₂) of Naegleria isolated from a body of water polluted with thermal effluents were compared in an attempt at specific identifications of the latter strains. The 3 environmental isolates were morphologically almost identical with N. fowleri and had almost the same temperature tolerance, although at 37 and 42 C the growth rates of LvH₁ and LvH₂ were higher than those of the human pathogen, N. fowleri, and of isolate Vm1, which was pathogenic for mice. Serologic examinations by indirect fluorescent antibody method revealed a very close relationship of the new isolates with the human pathogens. While Vm1 was indistinguishable from N. fowleri, LvH₁ and LvH₂ were not, when cross-absorbed antisera were used. Of all the strains examined, only the 2 LvH isolates were not inhibited by amphotericin B, while only N. gruberi was not inhibited by fumagillin. The cytopathic effect in Vero cell cultures suggested that the LvH strains could have a certain degree of virulence, although this was not confirmed by intranasal and intracerebral inoculations of mice. The cytopathic effects of the human pathogens and of the isolate pathogenic for mice were related to their virulence for mice. It is concluded that there exists an intermediate form between N. gruberi and N. fowleri, with a strong relationship to the latter species. We refer to such strains as nonpathogenic variants of N. fowleri. Further research is needed to reveal their place in the taxonomy.     

Modeling a Neural Oscillator that Paces Heartbeat in the Medicinal Leech

SYNOPSIS. Heartbeat in the medicinal leech is paced by a neuraloscillator comprising two elemental oscillators whose activityis coordinated intersegmental coordinating fibers. The elementaloscillators each consist of a bilateral pair of heart interneuronslinked by reciprocal inhibitory synapses. The activity cycleof each elemental oscillator consists of alternating burstsof action potentials (plateau/burst phase) and periods inhibition(inactive phase). Oscillation ensues in the reciprocally inhibitorypairs because each neuron is able to escape from the inhibitionits contralateral partner and thus move on to the plateau/burstphase. We have identified and described membrane currents thatcontribute to oscillation and studied graded synaptic transmissionbetween the neurons, using discontinuous current clamp and switchingsingle electrode voltage clamp techniques. A hyperpolarization-activatedinward current, Ih, plays a major role in escape from inhibition,and Ca²⁺ currents produce plateau potentials that support burstformation and mediate graded synaptic transmission. To consolidate our knowledge and guide future research, we haveconstructed a first generation computer model of a neural oscillatorbased on reciprocal inhibition, using Hodgkin-Huxley equationsand a synaptic transfer model, derived from our biophysicalstudies, with Nodus software (De Schutter, 1989). This modelhas confirmed an important role for I_h in sustaining oscillationand has implicated a similarly important role for outward currents(particularly I_A), which remain to be studied. Neural oscillatorsbased on reciprocal inhibition appear to be ubiquitous, andour studies, biophysical and computational, provide insightsinto how they may operate.