To perform live cell imaging of the third instar larval brain, begin by collecting the dissected brains and the isolated fat bodies in the last well of a three well dissection dish containing the dissection and imaging medium. Place a gas permeable membrane on the back of a slide and press the split ring into the center. Using a 200 microliter micro pipette, transfer up to 10 dissected brains with maximum possible fat bodies and 130 to 140 microliters of the medium onto the center of the membrane.
Orient the brains according to the neural stem cell population to be imaged and the microscope type, ensuring the samples are close to the microscope's objective. For example, to image neural stem cells in the central brain lobes, ensure the brain lobes are closest to the objective. Then gently place a glass cover slip over the solution on the membrane to spread the solution with the brain's and fat bodies throughout the membrane.
Hold the laboratory tissue at the cover slip edge to blot excess solution until the brains touch the cover slip without being squashed. Next, immobilize the cover slip by applying molten petroleum jelly along its edges using a paintbrush and allow the jelly to solidify. Add 400 microliters of imaging medium to a well in a multi well micro slide.
Transfer the previously dissected fat bodies to this well. Then, place up to 10 brains in a cluster near the center of the well. Orient the brains according to the neural stem cell population to be imaged and the microscope type.
Allow the brains to settle in the well for two to five minutes. Cover the micro slide with the slide cover before transferring it to the microscope. Start the acquisition process using the lowest laser power and exposure time to minimize photo bleaching.
Imaging of larval brains expressing UAS driven Cherry-Jupiter and androgynously tagged pins GFP using multi-well imaging slides and without fat body supplementation revealed that the pins formed a pronounced apical crescent in dividing neuroblasts to which the mitotic spindles consistently aligned during mitosis. In those samples, the cell cycle length increased with increasing imaging time. Samples that were imaged in a fat body supplemented medium on a membrane-bound slide did not show an increase in cell cycle length.
Furthermore, neuroblasts with four divisions were observed on the 10 hour membrane-bound slide.
