RNA Detection

the highest available pressure applied, position the stage such

that the tip only slightly reaches trough the edge of the glass

slide or coverslip. Slowly lower the needle until the tip bends

and snaps onto the other side of the glass. Now, slowly raise the

tip till it bends and snaps back to focus. Usually, this maneuver

opens the tip without affecting the final diameter and thus the

piercing ability. However, if it fails repeatedly or the tip gets

broken, replace the needle and start over fromstep 3of Sub-

heading3.7.

12. Exposing the tip to open air for prolonged periods will cause
    clogging, so keep it under the oil also when preparing or
    imaging the specimen.


13. Assessing the axial position of the tip relative to the specimen is
    difficult. As a rule of thumb look for indications of physical
    interaction, e.g., movement, rotation and distortion of the
    specimen and bending of the tip. Movement of the specimen
    indicates too large tip diameter and a consequent inappropriate
    piercing pressure, whereas rotation of the egg chambers sig-
    nifies too lateral hit which usually stems from a too shallow
    angle of the needle. Ideally, this angle is between 30 and 45
    relative to the glass plane holding the specimen.


14. It may happen that the tip gets stuck in the perivitelline space
    between the oocyte and the follicular epithelium. In such cases,
    formation of a liquid bubble can be observed after injection,
    accompanied by an immensely bright fluorescent signal of the
    probe around and within the oocyte due that it gets endocy-
    tosed by the oocyte into yolk granules. Due to the intensity of
    this aspecific fluorescence, the affected oocyte cannot be used
    for mRNP imaging even after reinjection.


15. TO and QB labeled probes can be simply combined with simul-
    taneous imaging of red (e.g., mCherry) or green fluorescent
    proteins (e.g., EGFP), respectively due to the differences in
    the emission and absorption spectra of these fluorescent mole-
    cules. Using microscopes equipped with a supercontinuum
    based light source (e.g., a white-light laser) TO can be combined
    with EGFP with minimal cross-talk using the following sequen-
    tial scan setup: 470 nm laser line and 480–520 nm detection
    window to image GFP and 525 nm laser line and 535–575 nm
    detection window to image TO (Fig.2).


16. We found no decline inoskarmRNP motility within the first
    hour after dissection. Very little or no RNP motility and a
    subsequent formation of larger RNP aggregates over the
    course of an hour are indicative of either inefficient insulin
    signaling or probable interference of the probe with normal
    mRNP biogenesis. To distinguish between the two scenarios,
    repeat the microinjection and imaging using cultivation
    medium made with a fresh aliquot of human insulin.

286 Jasmine Chamiolo et al.