Calcium imaging of vomeronasal organ response using slice preparations from transgenic mice expressing G-CaMP2.

The vomeronasal organ (VNO) in vertebrate animals detects pheromones and interspecies chemical signals. We describe in this chapter a Ca(2+) imaging approach using transgenic mice that express the genetically encoded Ca(2+) sensor G-CaMP2 in VNO tissue. This approach allows us to analyze the complex patterns of the vomeronasal neuron response to large number of chemosensory stimuli.

Imaging neuronal responses in slice preparations of vomeronasal organ expressing a genetically encoded calcium sensor.

The vomeronasal organ (VNO) detects chemosensory signals that carry information about the social, sexual and reproductive status of the individuals within the same species. These intraspecies signals, the pheromones, as well as signals from some predators, activate the vomeronasal sensory neurons (VSNs) with high levels of specificity and sensitivity. At least three distinct families of G-protein coupled receptors, V1R, V2R and FPR, are expressed in VNO neurons to mediate the detection of the chemosensory cues. To understand how pheromone information is encoded by the VNO, it is critical to analyze the response profiles of individual VSNs to various stimuli and identify the specific receptors that mediate these responses. The neuroepithelia of VNO are enclosed in a pair of vomer bones. The semi-blind tubular structure of VNO has one open end (the vomeronasal duct) connecting to the nasal cavity. VSNs extend their dendrites to the lumen part of the VNO, where the pheromone cues are in contact with the receptors expressed at the dendritic knobs. The cell bodies of the VSNs form pseudo-stratified layers with V1R and V2R expressed in the apical and basal layers respectively. Several techniques have been utilized to monitor responses of VSNs to sensory stimuli. Among these techniques, acute slice preparation offers several advantages. First, compared to dissociated VSNs, slice preparations maintain the neurons in their native morphology and the dendrites of the cells stay relatively intact. Second, the cell bodies of the VSNs are easily accessible in coronal slice of the VNO to allow electrophysiology studies and imaging experiments as compared to whole epithelium and whole-mount preparations. Third, this method can be combined with molecular cloning techniques to allow receptor identification. Sensory stimulation elicits strong Ca2+ influx in VSNs that is indicative of receptor activation. We thus develop transgenic mice that express G-CaMP2 in the olfactory sensory neurons, including the VSNs. The sensitivity and the genetic nature of the probe greatly facilitate Ca2+ imaging experiments. This method has eliminated the dye loading process used in previous studies. We also employ a ligand delivery system that enables application of various stimuli to the VNO slices. The combination of the two techniques allows us to monitor multiple neurons simultaneously in response to large numbers of stimuli. Finally, we have established a semi-automated analysis pipeline to assist image processing.

Visualizing calcium responses to acetylcholine convection along endothelium of arteriolar networks in Cx40BAC-GCaMP2 transgenic mice.

Acetylcholine evokes endothelium-dependent vasodilation subsequent to a rise in intracellular calcium. Despite widespread application in human and animal studies, calcium responses to intravascular ACh have not been visualized in vivo. Microiontophoresis of ACh in tissue adjacent to an arteriole activates abluminal muscarinic receptors on endothelial cells within a "local" region of diffusion, but it is unknown whether ACh released in such fashion gains access to the flow stream resulting in further actions downstream. To test this hypothesis and provide new insight into calcium signaling in vivo, we studied the cremaster muscle microcirculation of anesthetized male Cx40(BAC)-GCaMP2 transgenic mice (n = 22; 5-9 mo; 33 ± 1 g) expressing the fluorescent calcium sensor GCaMP2 selectively in arteriolar endothelial cells. Submaximal ACh stimuli were delivered using microiontophoresis (1-µm pipette tip, 500 nA). With stimulus duration <500 ms or with the micropipette positioned within one vessel diameter (∼30 µm) away from an arteriole, endothelial cell calcium fluorescence was restricted to the region of ACh diffusion (<200 µm). In contrast, with the micropipette tip positioned immediately adjacent to an arteriole or within its lumen, calcium fluorescence encompassed entire networks downstream. The velocity of downstream calcium signaling in response to ACh increased with centerline velocity of fluorescent tracer microbeads (r(2) > 0.99; range: <1 mm/s to >10 mm/s). Diverting arteriolar blood flow into a side branch redirected downstream fluorescence responses to ACh; occluding flow abolished responses. Blocking luminal muscarinic receptors (intravascular glycopyrrolate; 6 µg/kg) inhibited downstream responses reversibly. Through visualizing the actions of a "local" ACh stimulus on endothelial cell calcium fluorescence in vivo, the present findings illustrate that transmural diffusion and convection of an agonist can activate entire networks of arteriolar endothelial cells concomitant with its delivery in the flow stream.