Testing the role of preBötzinger Complex somatostatin neurons in respiratory and vocal behaviors.

Identifying neurons essential for the generation of breathing and related behaviors such as vocalisation is an important question for human health. The targeted loss of preBötzinger Complex (preBötC) glutamatergic neurons, including those that express high levels of somatostatin protein (SST neurons), eliminates normal breathing in adult rats. Whether preBötC SST neurons represent a functionally specialised population is unknown. We tested the effects on respiratory and vocal behaviors of eliminating SST neuron glutamate release by Cre-Lox-mediated genetic ablation of the vesicular glutamate transporter 2 (VGlut2). We found the targeted loss of VGlut2 in SST neurons had no effect on viability in vivo, or on respiratory period or responses to neurokinin 1 or µ-opioid receptor agonists in vitro. We then compared medullary SST peptide expression in mice with that of two species that share extreme respiratory environments but produce either high or low frequency vocalisations. In the Mexican free-tailed bat, SST peptide-expressing neurons extended beyond the preBötC to the caudal pole of the VII motor nucleus. In the naked mole-rat, however, SST-positive neurons were absent from the ventrolateral medulla. We then analysed isolation vocalisations from SST-Cre;VGlut2(F/F) mice and found a significant prolongation of the pauses between syllables during vocalisation but no change in vocalisation number. These data suggest that glutamate release from preBötC SST neurons is not essential for breathing but play a species- and behavior-dependent role in modulating respiratory networks. They further suggest that the neural network generating respiration is capable of extensive plasticity given sufficient time.

Apoptosis in the adult striatum after transient forebrain ischemia and the effects of ischemic severity.

The mechanisms of neuronal injury after cerebral ischemia have been under active investigation. The medium-size neurons in the dorsal striatum die within 24 h after transient cerebral ischemia. Using electron microscopy, the present study examined the nature of neuronal death in the striatum of adult rats following transient forebrain ischemia and tested the hypothesis that the ischemic severity might influence the nature of cell death. After severe ischemia (approximately 21 min ischemic depolarization), most neurons in the dorsal striatum died with swollen organelles and small irregular chromatin clumps resembling necrosis. The tissue damage in the dorsomedial striatum was less severe than that in the dorsolateral striatum and approximately 5% of the neurons in this region died with large chromatin clumps and relatively intact organelles resembling apoptosis. Some neurons displayed a mixture of necrotic- and apoptotic-like appearance. In contrast, the neurons with large somata only exhibited mild ultrastructural changes. After moderate ischemia (approximately 15 min ischemic depolarization), the tissue damage was less severe and the process of necrosis was temporally prolonged compared with that after severe ischemia. The apoptotic-like neuronal death was observed not only in the dorsomedial (approximately 6%) but also in the dorsolateral striatum (approximately 7%). The neurons in the striatum showed transient reversible changes after mild ischemia (approximately 10 min ischemic depolarization). The present study demonstrates that both apoptosis and necrosis occur in the adult striatum following transient forebrain ischemia and apoptosis occurs in the regions with less severe ischemia. These results suggest that ischemic severity might be one of the contributing factors to necrosis or apoptosis following transient global ischemia.

Atoh1-dependent rhombic lip neurons are required for temporal delay between independent respiratory oscillators in embryonic mice.

All motor behaviors require precise temporal coordination of different muscle groups. Breathing, for example, involves the sequential activation of numerous muscles hypothesized to be driven by a primary respiratory oscillator, the preBötzinger Complex, and at least one other as-yet unidentified rhythmogenic population. We tested the roles of Atoh1-, Phox2b-, and Dbx1-derived neurons (three groups that have known roles in respiration) in the generation and coordination of respiratory output. We found that Dbx1-derived neurons are necessary for all respiratory behaviors, whereas independent but coupled respiratory rhythms persist from at least three different motor pools after eliminating or silencing Phox2b- or Atoh1-expressing hindbrain neurons. Without Atoh1 neurons, however, the motor pools become temporally disorganized and coupling between independent respiratory oscillators decreases. We propose Atoh1 neurons tune the sequential activation of independent oscillators essential for the fine control of different muscles during breathing.DOI: http://dx.doi.org/10.7554/eLife.02265.001.