SummaryWe have applied optogenetics and mGRASP, a light microscopy technique that labels synaptic contacts, to map the number and strength of defined corticocollicular (CC) connections. Using mGRASP, we show that CC projections form small, medium, and large synapses, and both the number and the distribution of synapse size vary among the IC regions. Using optogenetics, we show that low-frequency stimulation of CC axons expressing channelrhodopsin produces prolonged elevations of the CC miniature EPSC (mEPSC) rate. Functional analysis of CC mEPSCs reveals small-, medium-, and large-amplitude events that mirror the synaptic distributions observed with mGRASP. Our results reveal that descending ipsilateral projections dominate CC feedback via an increased number of large synaptic contacts, especially onto the soma of IC neurons. This study highlights the feasibility of combining microscopy (i.e., mGRASP) and optogenetics to reveal synaptic weighting of defined projections at the level of single neurons, enabling functional connectomic mapping in diverse neural circuits.
We studied how co-release of histamine/GABA from axons originating from the hypothalamic tuberomammillary nucleus (TMN) and projecting to the prefrontal cortex (PFC) influences circuit processing. We opto-stimulated histamine/GABA co-release from genetically defined TMN axons that express the histidine decarboxylase gene (TMNHDC axons). Whole-cell recordings were used to monitor excitability of visually identified PFC neurons in layer 2/3 of prelimbic (PL), anterior cingulate (AC) and infralimbic (IL) regions before and after opto-stimulated histamine/GABA release. We found that histamine-GABA co-release influences the PFC through actions on distinct neuronal types: histamine stimulates fast-spiking interneurons; and co-released GABA enhances tonic (extrasynaptic) inhibition on pyramidal cells (PyrNs). For fast spiking non-accommodating interneurons, opto-stimulation increased excitability, an effect blocked by histamine H1 and H2 receptor antagonists. The excitability of other interneuron types in the PFC was not altered. In contrast, the combined action of histamine and GABA co-release from TMNHDC axons produced predominantly divisive gain changes in PyrNs, increasing their resting input conductance, and decreasing the slope of the input-output relationship. The direct inhibitory effect of TMNHDC axon activation on PyrNs was not blocked by histamine receptor antagonists but was blocked by GABAA receptor antagonists. Across the adult lifespan (from 3 months to over 2 years of age), stimulation of TMNHDCaxons in the PFC inhibited PyrN excitability significantly more in older mice. For individuals that maintain cognitive performance into later life, increases in TMNHDC modulation of PyrNs could enhance information processing and be an adaptive mechanism to buttress cognition.
We studied how histamine and GABA release from axons originating from the hypothalamic tuberomammillary nucleus (TMN) and projecting to the prefrontal cortex (PFC) influence circuit processing. We optostimulated histamine/GABA from genetically defined TMN axons that express the histidine decarboxylase gene (TMNHDCaxons). Whole-cell recordings from PFC neurons in layer 2/3 of prelimbic, anterior cingulate, and infralimbic regions were used to monitor excitability before and after optostimulated histamine/GABA release in male and female mice. We found that histamine-GABA release influences the PFC through actions on distinct neuronal types: the histamine stimulates fast-spiking interneurons; and the released GABA enhances tonic (extrasynaptic) inhibition on pyramidal cells (PyrNs). For fast-spiking nonaccommodating interneurons, histamine released from TMNHDCaxons induced additive gain changes, which were blocked by histamine H1 and H2 receptor antagonists. The excitability of other fast-spiking interneurons in the PFC was not altered. In contrast, the GABA released from TMNHDCaxons predominantly produced divisive gain changes in PyrNs, increasing their resting input conductance, and decreasing the slope of the input–output relationship. This inhibitory effect on PyrNs was not blocked by histamine receptor antagonists but was blocked by GABAAreceptor antagonists. Across the adult life span (from 3 to 18 months of age), the GABA released from TMNHDCaxons in the PFC inhibited PyrN excitability significantly more in older mice. For individuals who maintain cognitive performance into later life, the increases in TMNHDCGABA modulation of PyrNs during aging could enhance information processing and be an adaptive mechanism to buttress cognition.SIGNIFICANCE STATEMENTThe hypothalamus controls arousal state by releasing chemical neurotransmitters throughout the brain to modulate neuronal excitability. Evidence is emerging that the release of multiple types of neurotransmitters may have opposing actions on neuronal populations in key cortical regions. This study demonstrates for the first time that the neurotransmitters histamine and GABA are released in the prefrontal cortex from axons originating from the tuberomammillary nucleus of the hypothalamus. This work demonstrates how hypothalamic modulation of neuronal excitability is maintained throughout adult life, highlighting an unexpected aspect of the aging process that may help maintain cognitive abilities.
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