Early experience modifies the postnatal assembly of autonomic emotional motor circuits in rats.

Rat pups that are repeatedly handled and separated from their dam exhibit altered adult behavioral, endocrine, and autonomic responses to stress, but the extent to which early handling and/or maternal separation (H/S) alters the development of circuits that underlie these responses is unknown. The present study tested the hypothesis that early H/S alters the postnatal assembly of synapses within preautonomic emotional motor circuits. Circuit development was traced by synapse-dependent retrograde transneuronal transport of pseudorabies virus (PRV) from the stomach wall. Control and H/S rats were analyzed between postnatal day 6 (P6) and P10, a period of rapid synaptic assembly among preautonomic circuit components. Pups in H/S groups were removed from their dam daily for either 15 min or 3 h beginning on P1, and were injected with virus on P8 and perfused on P10. Quantitative analyses of primary and transsynaptic PRV immunolabeling confirmed an age-dependent assembly of hypothalamic, limbic, and cortical inputs to autonomic nuclei. Circuit assembly was significantly altered in H/S pups, in which fewer neurons in the central amygdala, the bed nucleus of the stria terminalis, and visceral cortices were infected compared with age-matched controls. In contrast, H/S did not alter the assembly of paraventricular hypothalamic inputs to gastric autonomic neurons. H/S-related reductions in limbic and cortical transneuronal infection were similar in pups exposed daily to 15 min or 3 h maternal separation. These findings support the view that environmental events during early postnatal life can influence the formation of neural circuits that provide limbic and cortical control over autonomic emotional motor output.

Plastic reorganization of hippocampal and neocortical circuitry in experimental traumatic brain injury in the immature rat.

The reorganization of circuitry in the immature forebrain resulting from controlled cortical impact was examined with viral transneuronal tracing. Animals injured on postnatal day (PND) 17 and sham controls from the same litters received an intracerebral injection of a recombinant strain of pseudorabies virus (PRV) into the entorhinal cortex on PND 45. Fifty hours following injection of virus the animals were perfused and infected neurons were localized immunohistochemically with antisera specific for PRV. Prior studies have demonstrated that the PRV recombinant used in this analysis moves exclusively in the retrograde direction through synaptically linked neurons. CCI induced a necrotic loss of cortex at the site of impact and variable damage to the underlying corpus callosum and rostral (dorsal) hippocampus that was not present in sham controls. Analysis of viral transport in sham controls revealed retrograde transport of virus through hippocampal and neocortical circuitry in a pattern consistent with established patterns of connectivity and topography. Injured animals exhibited preservation of topographically organized connections in both the hippocampus and neocortex. However, the magnitude of labeling in the injured hemisphere was significantly increased relative to control animals and correlated with the magnitude of the injury. The distribution of infected neurons in the contralateral uninjured hemisphere also conformed to known connections. However differences in the involvement of the corpus callosum in the injury resulted in greater variability in the number of infected neurons among cases. These data provide novel insights into trauma induced reorganization of the developing brain and add to the experimental tools that can be used to assess the basis for functional recovery in animal models of developmental traumatic brain injury.