Mapping of the excitatory, inhibitory, and modulatory afferent projections to the anatomically defined active expiratory oscillator in adult male rats.

The lateral parafacial region (pFL ; which encompasses the parafacial respiratory group, pFRG) is a conditional oscillator that drives active expiration during periods of high respiratory demand, and increases ventilation through the recruitment of expiratory muscles. The pFL activity is highly modulated, and systematic analysis of its afferent projections is required to understand its connectivity and modulatory control. We combined a viral retrograde tracing approach to map direct brainstem projections to the putative location of pFL , with RNAScope and immunofluorescence to identify the neurochemical phenotype of the projecting neurons. Within the medulla, retrogradely-labeled, glutamatergic, glycinergic and GABAergic neurons were found in the ventral respiratory column (Bötzinger and preBötzinger Complex [preBötC], ventral respiratory group, ventral parafacial region [pFV ] and pFL ), nucleus of the solitary tract (NTS), reticular formation (RF), pontine and midbrain vestibular nuclei, and medullary raphe. In the pons and midbrain, retrogradely-labeled neurons of the same phenotypes were found in the Kölliker-Fuse and parabrachial nuclei, periaqueductal gray, pedunculopontine nucleus (PPT) and laterodorsal tegmentum (LDT). We also identified somatostatin-expressing neurons in the preBötC and PHOX2B immunopositive cells in the pFV , NTS, and part of the RF. Surprisingly, we found no catecholaminergic neurons in the NTS, A5 or Locus Coeruleus, no serotoninergic raphe neurons nor any cholinergic neurons in the PPT and LDT that projected to the pFL . Our results indicate that pFL neurons receive extensive excitatory and inhibitory inputs from several respiratory and nonrespiratory related brainstem regions that could contribute to the complex modulation of the conditional pFL oscillator for active expiration.

Characterization of McDonald's intermediate part of the Central nucleus of the amygdala in the rat.

The actual organization of the central nucleus of the amygdala (CEA) in the rat is mostly based on cytoarchitecture and the distribution of several cell types, as described by McDonald in 1982. Four divisions were identified by this author. However, since this original work, one of these divisions, the intermediate part, has not been consistently recognized based on Nissl-stained material. In the present study, we observed that a compact condensation of retrogradely labeled cells is found in the CEA after fluorogold injection in the anterior region of the tuberal lateral hypothalamic area (LHA) in the rat. We then searched for neurochemical markers of this cell condensation and found that it is quite specifically labeled for calbindin (Cb), but also contains calretinin (Cr), tyrosine hydroxylase (TH) and methionine-enkephalin (Met-Enk) immunohistochemical signals. These neurochemical features are specific to this cell group which, therefore, is distinct from the other parts of the CEA. We then performed cholera toxin injections in the mouse LHA to identify this cell group in this species. We found that neurons exist in the medial and rostral CEAl that project into the LHA but they have a less tight organization than in the rat.

VGLUT1 synapses and P-boutons on regenerating motoneurons after nerve crush.

Stretch-sensitive Ia afferent monosynaptic connections with motoneurons form the stretch reflex circuit. After nerve transection, Ia afferent synapses and stretch reflexes are permanently lost, even after regeneration and reinnervation of muscle by motor and sensory afferents is completed in the periphery. This loss greatly affects full recovery of motor function. However, after nerve crush, reflex muscle forces during stretch do recover after muscle reinnervation and reportedly exceed 140% baseline values. This difference might be explained by structural preservation after crush of Ia afferent synapses on regenerating motoneurons and decreased presynaptic inhibitory control. We tested these possibilities in rats after crushing the tibial nerve (TN), and using Vesicular GLUtamate Transporter 1 (VGLUT1) and the 65 kDa isoform of glutamic acid-decarboxylase (GAD65) as markers of, respectively, Ia afferent synapses and presynaptic inhibition (P-boutons) on retrogradely labeled motoneurons. We analyzed motoneurons during regeneration (21 days post crush) and after they reinnervate muscle (3 months). The results demonstrate a significant loss of VGLUT1 terminals on dendrites and cell bodies at both 21 days and 3 months post-crush. However, in both cellular compartments, the reductions were small compared to those observed after TN full transection. In addition, we found a significant decrease in the number of GAD65 P-boutons per VGLUT1 terminal and their coverage of VGLUT1 boutons. The results support the hypothesis that better preservation of Ia afferent synapses and a change in presynaptic inhibition could contribute to maintain or even increase the stretch reflex after nerve crush and by difference to nerve transection.