The fixed Ciona larvae on a glass-based dish were observed by fluorescence microscopy with a 3CCD camera. A long-term Ca2+ transient was captured with pSP-CiVAChT:GCaMP6s or pSP-CiVAChT-H2B:GCaMP6s transduced Ciona embryos (N = 10, Figure 2 ; Figure 3 ., Supplementary Table S1 ). The same results can be obtained with either pSP-CiVAChT:GCaMP6s or pSP-CiVAChT-H2B:GCaMP6s (data not shown). An inverted microscope (Nikon Eclipse, IX71) with a 10×, 20×, 60× oil immersion objective lens (LUCPlanFLN) was used for fluorescence imaging with a U-MWBV2 mirror unit (Olympus, Shinjuku, Japan). SOLA LED light (Lumencor, Beaverton, OR) was used as a light source; fluorescence images were acquired with a 3CCD camera (C7800-20, Hamamatsu Photonics, Hamamatsu, Japan) and processed by the AQUACOSMOS software (Hamamatsu Photonics). Room temperature was maintained at 20°C. As a result, Ca2+ transients for both MN2L and MN2R, located at the Ciona motor ganglion region (Figure 1C ), were continuously imaged from St.22 (mid tailbud II) to St.34 (late tail absorption) (N = 10, Supplementary Table S1 ). Ciona developmental staging (Hotta et al., 2007 (link)) was used to estimate the developmental stage from morphology and time after fertilization.
U mwbv2 mirror unit
Manufactured by Olympus
Sourced in Japan
The U-MWBV2 mirror unit is a component designed for Olympus microscopes. Its core function is to reflect and direct the illumination path within the microscope system.
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3 protocols using u mwbv2 mirror unit
1
Fluorescent Ca2+ Imaging of Ciona Larvae
2
Fluorescence Microscopy and Calcium Imaging
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The embryos were observed by fluorescence microscopy with a three–charge-coupled device (3CCD; C7800-20, Hamamatsu Photonics) camera or by confocal laser scanning microscopy (CLSM). A Nikon inverted microscope (Nikon eclipse, IX71) with a 20× or 40× objective lens (LUCPlanFLN) was used for fluorescence imaging with a U-MWBV2 mirror unit (Olympus). A SOLA light-emitting diode light (Lumencor) was used as the light source, and fluorescence images were acquired with a 3CCD camera and the AQUACOSMOS software (Hamamatsu Photonics). For Ca2+ imaging, the time interval was set to 1 to 5 s per frame. For membrane potential imaging, the time interval was set to 20 ms per frame. An Olympus fv1000 microscope was used for CLSM imaging. Excitation was performed at 488-nm to visualize GCaMP6s and Kaede and at 559-nm to visualize mCherry. An Olympus 20× or 40× oil immersion lens was used.
3
Embryonic Calcium and Membrane Imaging
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The embryos were observed by fluorescence microscopy with a 3CCD (C7800-20, Hamamatsu Photonics) camera or by confocal laser-scanning microscopy (CLSM). A Nikon inverted microscope (Nikon eclipse, IX71) with a 20× or 40× objective lens (LUCPlanFLN) was used for fluorescence imaging with a U-MWBV2 mirror unit (Olympus). A SOLA LED light (Lumencor) was used as the light source, and fluorescence images were acquired with a 3CCD camera and the AQUACOSMOS software (Hamamatsu Photonics). For Ca 2+ imaging, the time interval was set to 1-5 sec per frame. For membrane potential imaging, the time interval was set to 20 msec per frame. For CLSM imaging, an Olympus fv1000 microscope was used. Excitation was performed at 488 nm to visualise the signals of GCaMP6s and Kaede, and at 559 nm to visualise the signal of mCherry. An Olympus 20× or 40× oil immersion lens was used.
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