Ilan Davis

In Vivo Imaging of oskar mRNA Transport Reveals the Mechanism of Posterior Localization

Summary oskar mRNA localization to the posterior of the Drosophila oocyte defines where the abdomen and germ cells form in the embryo. Although this localization requires microtubules and the plus end-directed motor, kinesin, its mechanism is controversial and has been proposed to involve active transport to the posterior, diffusion and trapping, or exclusion from the anterior and lateral cortex. By following oskar mRNA particles in living oocytes, we show that the mRNA is actively transported along microtubules in all directions, with a slight bias toward the posterior. This bias is sufficient to localize the mRNA and is reversed in mago, barentsz, and Tropomyosin II mutants, which mislocalize the mRNA anteriorly. Since almost all transport is mediated by kinesin, oskar mRNA localizes by a biased random walk along a weakly polarized cytoskeleton. We also show that each component of the oskar mRNA complex plays a distinct role in particle formation and transport.

Drosophila wingless and Pair-Rule Transcripts Localize Apically by Dynein-Mediated Transport of RNA Particles

Asymmetric mRNA localization targets proteins to their cytoplasmic site of function. We have elucidated the mechanism of apical localization of wingless and pair-rule transcripts in the Drosophila blastoderm embryo by directly visualizing intermediates along the entire path of transcript movement. After release from their site of transcription, mRNAs diffuse within the nucleus and are exported to all parts of the cytoplasm, regardless of their cytoplasmic destinations. Endogenous and injected apical RNAs assemble selectively into cytoplasmic particles that are transported apically along microtubules. Cytoplasmic dynein is required for correct localization of endogenous transcripts and apical movement of injected RNA particles. We propose that dynein-dependent movement of RNA particles is a widely deployed mechanism for mRNA localization.

Intracellular mRNA localization: motors move messages

Intracellular mRNA localization is a common mechanism of post-transcriptional regulation of gene expression. In a wide range of organisms, mRNA localization coupled with translational regulation target the proteins to their site of function. Here, we describe recent exciting evidence that some mRNAs are transported as particles along the cytoskeleton by the molecular motors dynein, kinesin or myosin. We discuss the key questions of how localized mRNAs might be linked to motors and what determines their cytoplasmic destinations.

Drosophila gurken (TGFα) mRNA Localizes as Particles that Move within the Oocyte in Two Dynein-Dependent Steps

In Drosophila oocytes, gurken mRNA localization orientates the TGF-alpha signal to establish the anteroposterior and dorsoventral axes. We have elucidated the path and mechanism of gurken mRNA localization by time-lapse cinematography of injected fluorescent transcripts in living oocytes. gurken RNA assembles into particles that move in two distinct steps, both requiring microtubules and cytoplasmic Dynein. gurken particles first move toward the anterior and then turn and move dorsally toward the oocyte nucleus. We present evidence suggesting that the two steps of gurken RNA transport occur on distinct arrays of microtubules. Such distinct microtubule networks could provide a general mechanism for one motor to transport different cargos to distinct subcellular destinations.

The Salvador-Warts-Hippo Pathway Is Required for Epithelial Proliferation and Axis Specification in Drosophila

In Drosophila, the body axes are specified during oogenesis through interactions between the germline and the overlying somatic follicle cells [1-5]. A Gurken/TGF-alpha signal from the oocyte to the adjacent follicle cells assigns them a posterior identity [6, 7]. These posterior cells then signal back to the oocyte, thereby inducing the repolarization of the microtubule cytoskeleton, the migration of the oocyte nucleus, and the localization of the axis specifying mRNAs [8-10]. However, little is known about the signaling pathways within or from the follicle cells responsible for these patterning events. We show that the Salvador Warts Hippo (SWH) tumor-suppressor pathway is required in the follicle cells in order to induce their Gurken- and Notch-dependent differentiation and to limit their proliferation. The SWH pathway is also required in the follicle cells to induce axis specification in the oocyte, by inducing the migration of the oocyte nucleus, the reorganization of the cytoskeleton, and the localization of the mRNAs that specify the anterior-posterior and dorsal-ventral axes of the embryo. This work highlights a novel connection between cell proliferation, cell growth, and axis specification in egg chambers.

Dynein Anchors Its mRNA Cargo after Apical Transport in the Drosophila Blastoderm Embryo

Molecular motors actively transport many types of cargo along the cytoskeleton in a wide range of organisms. One class of cargo is localized mRNAs, which are transported by myosin on actin filaments or by kinesin and dynein on microtubules. How the cargo is kept at its final intracellular destination and whether the motors are recycled after completion of transport are poorly understood. Here, we use a new RNA anchoring assay in living Drosophila blastoderm embryos to show that apical anchoring of mRNA after completion of dynein transport does not depend on actin or on continuous active transport by the motor. Instead, apical anchoring of RNA requires microtubules and involves dynein as a static anchor that remains with the cargo at its final destination. We propose a general principle that could also apply to other dynein cargo and to some other molecular motors, whereby cargo transport and anchoring reside in the same molecule.

Transcribed genes are localized according to chromosomal position within polarized Drosophila embryonic nuclei

When some genes are silenced, their positions within the nucleus can change dramatically [1] [2]. It is unclear, however, whether genes move to new positions when they are activated [3]. The chromosomes within the polarized nuclei of the fruit fly Drosophila have a well-characterized apical-basal orientation (the Rabl configuration [4]). Using a high-resolution in situ hybridization method [5], we found that each of 15 transcribed genes was localized as predicted by their chromosomal position and by the known polarized organization of the chromosomes. We also found that, within their specific apical-basal plane, most nascent transcript foci could occupy any radial position. There was no correlation between the apical-basal position of the transcribed locus and the final cytoplasmic site of localization of the RNA along the apical-basal axis of the cell. There was also no relationship between the distance of loci from the nuclear periphery and the amount of nascent mRNA decorating the gene. Our results are consistent with the view that effective transcription can occur without major re-localization of the genes themselves.

Changes in bicoid mRNA Anchoring Highlight Conserved Mechanisms during the Oocyte-to-Embryo Transition

Intracellular mRNA localization directs protein synthesis to particular subcellular domains to establish embryonic polarity in a variety of organisms. In Drosophila, bicoid (bcd) mRNA is prelocalized at the oocyte anterior. After fertilization, translation of this RNA produces a Bcd protein gradient that determines anterior cell fates [1] and [2]. Analysis of bcd mRNA during late stages of oogenesis suggested a model for steady-state bcd localization by continual active transport [3]. However, this mechanism cannot explain maintenance of bcd localization throughout the end of oogenesis, when microtubules disassemble in preparation for embryogenesis [4] and [5], or retention of bcd at the anterior in mature oocytes, which can remain dormant for weeks before fertilization [6]. Here, we elucidate the path and mechanism of sustained bcd mRNA transport by direct observation of bcd RNA particle translocation in living oocytes. We show that bcd mRNA shifts from continuous active transport to stable actin-dependent anchoring at the end of oogenesis. Egg activation triggers bcd release from the anterior cortex for proper deployment in the embryo, probably through reorganization of the actin cytoskeleton. These findings uncover a surprising parallel between flies and frogs, as cortically tethered Xenopus Vg1 mRNA undergoes a similar redistribution during oocyte maturation [7]. Our results thus highlight a conserved mechanism for regulating mRNA anchoring and redeployment during the oocyte-to-embryo transition.

Lifting the Fog: Image Restoration by Deconvolution

Publisher Summary Deconvolution is a data processing technique that is very widely used in science and engineering. Any microscope image of a fluorescent specimen can, in principle, be deconvolved after acquisition in order to improve contrast and resolution. The most common application in biology is for deblurring images acquired as three-dimensional (3D) image stacks using a wide-field fluorescence microscope, where each image includes considerable out-of-focus light or blur originating from regions of the specimen. Deconvolution and confocal imaging are by no means mutually exclusive. Confocal imaging can nearly always benefit from the improvements in contrast, signal-to-noise ratio, and resolution afforded by restorative deconvolution methods. Deconvolution, particularly the more advanced approaches, is implemented through a software package where the algorithm is generally assisted by data correction before and noise reduction steps both before and between iterations. With a given deconvolution package, the quality of results obtained will depend foremost upon the quality of raw image data and upon the accuracy of PSF data.

A helicase that gets Oskar's message across

Messenger RNA localization is a common way of targeting proteins to their site of function. This process is dependent on RNA signals that are interpreted by trans-acting factors. A putative RNA helicase and translational initiation factor is now shown to form a conserved complex, important for localization of oskar mRNA in Drosophila melanogaster and RNA surveillance in human cells.