Amy Hong scite author profile

Animal oocytes undergo a highly conserved developmental arrest in prophase of meiosis I. Often this marks a period of rapid growth for the oocyte and is necessary to coordinate meiotic progression with the developmental events of oogenesis. In Drosophila, the oocyte develops within a 16-cell germline cyst. Throughout much of oogenesis, the oocyte remains in prophase of meiosis I. By contrast, its 15 mitotic sisters enter the endocycle and become polyploid in preparation for their role as nurse cells. How germline cysts establish and maintain these two independent cell cycles is unknown. We demonstrate a role for the p21 CIP /p27 Kip1 /p57 Kip2 -like cyclin-dependent kinase inhibitor (cki) dacapo in the maintenance of the meiotic cycle in Drosophila oocytes. Our data indicate that it is through the differential regulation of the cki Dacapo that two modes of cell-cycle regulation are independently maintained within the common cytoplasm of ovarian cysts.

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Two-photon excitation improves multifocal structured illumination microscopy in thick scattering tissue

Ingaramo

York

Wawrzusin

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

112

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Multifocal structured illumination microscopy (MSIM) provides a twofold resolution enhancement beyond the diffraction limit at sample depths up to 50 μm, but scattered and out-of-focus light in thick samples degrades MSIM performance. Here we implement MSIM with a microlens array to enable efficient two-photon excitation. Two-photon MSIM gives resolution-doubled images with better sectioning and contrast in thick scattering samples such as Caenorhabditis elegans embryos, Drosophila melanogaster larval salivary glands, and mouse liver tissue.multiphoton | superresolution F luorescence microscopy is an invaluable tool for biologists.Protein distributions in cells have an interesting structure down to the nanometer scale, but features smaller than 200-300 nm are blurred by diffraction in widefield and confocal fluorescence microscopes. Superresolution techniques like photoactivated localization microscopy (1), stochastic optical reconstruction microscopy (2), or stimulated emission depletion (STED) (3) microscopy allow the imaging of details beyond the limit imposed by diffraction, but usually trade acquisition speed or straightforward sample preparation. And although STED can provide resolution down to 40 nm, STED-specific fluorophores are recommended and it often requires light intensities that are orders of magnitude above widefield and confocal microscopy. On the other hand, structured illumination microscopy (SIM) (4) gives twice the resolution of a conventional fluorescence microscope with light intensities on the order of widefield microscopes and can be used with most common fluorophores. SIM uses contributions from both the excitation and emission point spread functions (PSFs) to substantially improve the transverse resolution and is generally performed by illuminating the sample with a set of sharp light patterns and collecting fluorescence on a multipixel detector, followed by image processing to recover superresolution detail from the interaction of the light pattern with the sample. A related technique, image scanning microscopy (ISM), uses a scanned diffraction-limited spot as the light pattern (5, 6). Multifocal SIM (MSIM) parallelizes ISM by using many excitation spots (7), and has been shown to produce optically sectioned images with ∼145-nm lateral and ∼400-nm axial resolution at depths up to ∼50 μm and at ∼1 Hz imaging frequency. In MSIM, images are excited with a multifocal excitation pattern, and the resulting fluorescence in the multiple foci are pinholed, locally scaled, and summed to generate an image [multifocal-excited, pinholed, scaled, and summed (MPSS)] with root 2-improved resolution relative to widefield microscopy, and improved sectioning compared with SIM due to confocal-like pinholing. Deconvolution is applied to recover the final MSIM image which has a full factor of 2 resolution improvement over the diffraction limit.

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The cyclin-dependent kinase inhibitor Dacapo promotes replication licensing during Drosophila endocycles

Hong

Narbonne-Reveau

Riesgo-Escovar

et al. 2007

EMBO J

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The endocycle is a developmentally programmed variant cell cycle in which cells undergo repeated rounds of DNA replication with no intervening mitosis. In Drosophila, the endocycle is driven by the oscillations of Cyclin E/Cdk2 activity. How the periodicity of Cyclin E/Cdk2 activity is achieved during endocycles is poorly understood. Here, we demonstrate that the p21(cip1)/p27(kip1)/p57(kip2)-like cyclin-dependent kinase inhibitor (CKI), Dacapo (Dap), promotes replication licensing during Drosophila endocycles by reinforcing low Cdk activity during the endocycle Gap-phase. In dap mutants, cells in the endocycle have reduced levels of the licensing factor Double Parked/Cdt1 (Dup/Cdt1), as well as decreased levels of chromatin-bound minichromosome maintenance (MCM2-7) complex. Moreover, mutations in dup/cdt1 dominantly enhance the dap phenotype in several polyploid cell types. Consistent with a reduced ability to complete genomic replication, dap mutants accumulate increased levels of DNA damage during the endocycle S-phase. Finally, genetic interaction studies suggest that dap functions to promote replication licensing in a subset of Drosophila mitotic cycles.

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Amy Hong

The p27cip/kip orthologdacapomaintains theDrosophilaoocyte in prophase of meiosis I

Two-photon excitation improves multifocal structured illumination microscopy in thick scattering tissue

The cyclin-dependent kinase inhibitor Dacapo promotes replication licensing during Drosophila endocycles

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