Fv1200mpe ix83 inverted microscope

The establishment of transgenic mice expressing AKAR3EV (PKAchu mice) was described previously (Kamioka et al., 2012 (link)). Briefly, 8- to 13-week-old female mice were used for the in vivo imaging. The ear hair was removed with a razor 1 d before the experiments. Mice were anesthetized with 1.5% isoflurane (FUJIFILM Wako Pure Chemical Corp.) inhalation and placed in a side-lying position on an electric heater maintained at 37°C. The ear skin was placed on the cover glass. Two-photon excitation microscopy was performed with an FV1200MPE-IX83 inverted microscope (Olympus) equipped with a ×30/1.05 silicon oil-immersion objective lens (XLPLN 25XWMP; Olympus), an InSight DeepSee Ultrafast laser (Spectra Physics), an IR-cut filter (BA685RIF-3), two dichroic mirrors DM505 (Olympus), and two emission filters (BA460-500 for CFP and BA520-560 for YFP) (Olympus). The excitation wavelength was 840 nm.
The animal protocols were approved by the Animal Care and Use Committee of Kyoto University Graduate School of Medicine (approval no. 22063).

For two-photon excitation microscopy (2PM), we used an FV1200MPE-IX83 inverted microscope (Olympus) equipped with a 30×/1.05 NA silicon oil-immersion objective lens (UPLSAPO 30XS; Olympus), an LCV110-MPE incubator microscope (Olympus) equipped with a 25×/1.05 water-immersion objective lens (XLPLN 25XWMP2; Olympus), and an InSight DeepSee Laser (Spectra Physics). The laser power was set to 3–18%. The scan speed was set between 4–12.5 μs per pixel. Z-stack images were acquired at 1–10 μm intervals. In time-lapse analyses, images were recorded every 1–3 min. The excitation wavelength for CFP was 840 nm. We used an IR-cut filter (BA685RIF-3), two dichroic mirrors (DM505 and DM570), and two emission filters (BA460-500 for CFP and BA520-560 for YFP) (Olympus). Confocal images were acquired with an FV1000/IX83 confocal microscope (Olympus) equipped with a 30×/1.05 NA silicon oil-immersion objective lens (UPLSAPO 30XS; Olympus).

For two-photon excitation microscopy (2PM), we used an FV1200MPE-IX83 inverted microscope (Olympus, Tokyo, Japan) equipped with a 30x/1.05 NA silicon oil-immersion objective lens (UPLSAPO 30XS; Olympus) and an FV1200MPE-BX61WI upright microscope equipped with a 25x/1.05 water-immersion objective lens (XLPLN 25XWMP; Olympus) and an InSight DeepSee Laser (Spectra Physics, Santa Clara, CA, USA). The laser power was set to 8–10% and 2–4% for the observation of the intestine and the skin, respectively [33 (link), 38 (link)]. The scan speed was set at 20 μs/pixel. We used 840-nm light to excite CFP. We used an IR-cut filter (BA685RIF-3), two dichroic mirrors (DM505 and DM570), and two emission filters (BA460-500 for CFP and BA520-560 for YFP) (Olympus). Acquired images were analyzed with MetaMorph software (Universal Imaging, West Chester, PA, USA) as described previously [34 (link), 39 (link)].
Confocal images were acquired with an FV1000/IX83 confocal microscope (Olympus) equipped with a 30x/1.05 NA silicon oil-immersion objective lens (UPLSAPO 30XS; Olympus).