Abstract Oxytocinergic actions within the hippocampal CA2 are important for neuromodulation, memory processing and social recognition. However, the source of the OTergic innervation, the cellular targets expressing the OT receptors (OTRs) and whether the PVN-to-CA2 OTergic system is altered during heart failure (HF), a condition recently associated with cognitive and mood decline, remains unknown. Using immunohistochemistry along with retrograde monosynaptic tracing, RNAscope and a novel OTR-Cre rat line, we show that the PVN (but not the supraoptic nucleus) is an important source of OTergic innervation to the CA2. These OTergic fibers were found in many instances in close apposition to OTR expressing cells within the CA2. Interestingly, while only a small proportion of neurons were found to express OTRs (∼15%), this expression was much more abundant in CA2 astrocytes (∼40%), an even higher proportion that was recently reported for astrocytes in the central amygdala. Using an established ischemic rat heart failure (HF) model, we found that HF resulted in robust changes in the PVN-to-CA2 OTergic system, both at the source and target levels. Within the PVN, we found an increased OT immunoreactivity, along with a diminished OTR expression in PVN neurons. Within the CA2 of HF rats, we observed a blunted OTergic innervation, along with a diminished OTR expression, which appeared to be restricted to CA2 astrocytes. Taken together, our studies highlight astrocytes as key cellular targets mediating OTergic PVN inputs to the CA2 hippocampal region. Moreover, provides the first evidence for an altered PVN-to-CA2 OTergic system in HF rats, which could potentially contribute to previously reported cognitive and mood impairments in this animal model.
For over half a century, it has been postulated that the internal excitatory circuit in the hippocampus consists of three relay stations. Excitation arrives from the entorhinal cortex to the DG granule cells, is transmitted through the mossy fibers to CA3 pyramidal cells, and is then transmitted through Schaffer collaterals to CA1 pyramidal neurons. In all three structures (DG, CA3 and CA1), the activity of the excitatory neurons involved in the synaptic transmission of excitation are under the control of inhibitory basket neurons that are recruited into network activity via feed-forward and feed-back excitation. However, in the late 90s “stratum radiatum giant cells” were described as a novel type of neuron with the anatomical features of excitatory cells. Since then, the role of these cells in the hippocampal circuitry has not been well understood. Here, using optogenetic and electrophysiological techniques we characterized the functional location of these neurons within the hippocampal network. We show that: (i) the main excitatory drive to giant excitatory neurons in stratum radiatum (ExN R ) comes via Schaffer collaterals; (ii) within the CA1 field, ExN R are not directly connected with local pyramidal cells, but provide massive and efficient excitatory input to parvalbumin positive (PV+) interneurons; (iii) ExN R are reciprocally innervated by bistratified cells, but not inhibited by backet interneurons; (iv) the efficiency of ExN R excitation to PV+ interneurons is sufficient for a single ExN R action potential to trigger massive inhibition of downstream CA1 pyramidal cells. Taken together, our data shows that ExN R constitute an alternative pathway of excitation for CA1 interneurons that avoids the burden of perisomatic inhibition.
In the developing telencephalon, NMDA receptors (NMDARs) are composed of GluN1 and GluN2B subunits. These “young” NMDARs set a brake on synapse recruitment in neurons of the neonatal cortex. The functional role of GluN2B for synapse maturation of adult-born granule cells (GCs) in the olfactory bulb has not been established and may differ from that of differentiating neurons in immature brain circuits with sparse activity. We genetically targeted GCs by sparse retroviral delivery in mouse subventricular zone that allows functional analysis of single genetically modified cells in an otherwise intact environment. GluN2B-deficient GCs did not exhibit impairment with respect to the first developmental milestones such as synaptogenesis, dendrite formation, and maturation of inhibitory synaptic inputs. However, GluN2B deletion prevented maturation of glutamatergic synaptic input. This severe impairment in synaptic development was associated with a decreased response to novel odors and eventually led to the demise of adult-born GCs. The effect of GluN2B on GC survival is subunit specific, since it cannot be rescued by GluN2A, the subunit dominating mature NMDAR function. Our observations indicate that, GluN2B-containing NMDARs promote synapse activation in adult-born GCs that integrate in circuits with high and correlated synaptic activity. The function of GluN2B-containing NMDARs on synapse maturation can thus be bidirectional depending on the environment.
Das Neuroeptid Oxytocin (OT) wird ausschließlich im Hypothalamus von magnozellulären Oxytocin-Neuronen (magnOT) und parvozellulären Oxytocin-Neuronen (parvOT) gebildet. Bisher war es v. a. dafür bekannt, dass es als Kuschelhormon im Körper z. B. bei der Entstehung der Mutter-Kind-Bindung eine Rolle spielt oder als Neurotransmitter die Stimmung und das Sozialverhalten positiv beeinflusst. Nun gibt es Hinweise darauf, dass OT auch einen Einfluss auf die Schmerzwahrnehmung hat.
Neuropeptides, such as neuropeptide S (NPS) and oxytocin (OXT), represent potential options for the treatment of anxiety disorders due to their potent anxiolytic profile. In this study, we aimed to reveal the mechanisms underlying the behavioral action of NPS, and present a chain of evidence that the effects of NPS within the hypothalamic paraventricular nucleus (PVN) are mediated via actions on local OXT neurons in male Wistar rats. First, retrograde studies identified NPS fibers originating in the brainstem locus coeruleus, and projecting to the PVN. FACS identified prominent NPS receptor expression in PVN-OXT neurons. Using genetically encoded calcium indicators, we further demonstrated that NPS reliably induces a transient increase in intracellular Ca
For over half a century, it has been postulated that the internal excitatory circuit in the hippocampus consists of three relay stations. Excitation arrives from the entorhinal cortex to the DG granule cells, is transmitted through the mossy fibers to CA3 pyramidal cells, and is then transmitted through Schaffer collaterals to CA1 pyramidal neurons. In all three structures (DG, CA3 and CA1), the activity of the excitatory neurons involved in the synaptic transmission of excitation are under the control of inhibitory basket neurons that are recruited into network activity via feed-forward and feed-back excitation. However, in the late 90s “stratum radiatum giant cells” were described as a novel type of neuron with the anatomical features of excitatory cells. Since then, the role of these cells in the hippocampal circuitry has not been well understood. Here, using optogenetic and electrophysiological techniques we characterized the functional location of these neurons within the hippocampal network. We show that: (i) the main excitatory drive to giant excitatory neurons in stratum radiatum (ExN R ) comes via Schaffer collaterals; (ii) within the CA1 field, ExN R are not directly connected with local pyramidal cells, but provide massive and efficient excitatory input to parvalbumin positive (PV+) interneurons; (iii) ExN R are reciprocally innervated by bistratified cells, but not inhibited by backet interneurons; (iv) the efficiency of ExN R excitation to PV+ interneurons is sufficient for a single ExN R action potential to trigger massive inhibition of downstream CA1 pyramidal cells. Taken together, our data shows that ExN R constitute an alternative pathway of excitation for CA1 interneurons that avoids the burden of perisomatic inhibition.
