Cup is essential for oskar mRNA translational repression during early Drosophila oogenesis.

Study of the timing and location for mRNA translation across model systems has begun to shed light on molecular events fundamental to such processes as intercellular communication, morphogenesis, and body pattern formation. In D. melanogaster, the posterior mRNA determinant, oskar, is transcribed maternally but translated only when properly localized at the oocyte's posterior cortex. Two effector proteins, Bruno1 and Cup, mediate steps of oskar mRNA regulation. The current model in the field identifies Bruno1 as necessary for Cup's recruitment to oskar mRNA and indispensable for oskar's translational repression. We now report that this Bruno1-Cup interaction leads to precise oskar mRNA regulation during early oogenesis and, importantly, the two proteins mutually influence each other's mRNA expression and protein distribution in the egg chamber. We show that these factors stably associate with oskar mRNA in vivo. Cup associates with oskar mRNA without Bruno1, while surprisingly Bruno1's stable association with oskar mRNA depends on Cup. We demonstrate that the essential factor for oskar mRNA repression in early oogenesis is Cup, not Bruno1. Furthermore, we find that Cup is a key P-body component that maintains functional P-body morphology during oogenesis and is necessary for oskar mRNA's association with P-bodies. Therefore, Cup drives the translational repression and stability of oskar mRNA. These experimental results point to a regulatory feedback loop between Bruno 1 and Cup in early oogenesis that appears crucial for oskar mRNA to reach the posterior pole and its expression in the egg chamber for accurate embryo development.

PinMol: Python application for designing molecular beacons for live cell imaging of endogenous mRNAs.

Molecular beacons are nucleic acid oligomers labeled with a fluorophore and a quencher that fold in a hairpin-shaped structure, which fluoresce only when bound to their target RNA. They are used for the visualization of endogenous mRNAs in live cells. Here, we report a Python program (PinMol) that designs molecular beacons best suited for live cell imaging by using structural information from secondary structures of the target RNA, predicted via energy minimization approaches. PinMol takes into account the accessibility of the targeted regions, as well as the inter- and intramolecular interactions of each selected probe. To demonstrate its applicability, we synthesized an oskar mRNA-specific molecular beacon (osk1236), which is selected by PinMol to target a more accessible region than a manually designed oskar-specific molecular beacon (osk2216). We previously demonstrated osk2216 to be efficient in detecting oskar mRNA in in vivo experiments. Here, we show that osk1236 outperformed osk2216 in live cell imaging experiments.

The temporally controlled expression of Drongo, the fruit fly homolog of AGFG1, is achieved in female germline cells via P-bodies and its localization requires functional Rab11.

To achieve proper RNA transport and localization, RNA viruses exploit cellular vesicular trafficking pathways. AGFG1, a host protein essential for HIV-1 and Influenza A replication, has been shown to mediate release of intron-containing viral RNAs from the perinuclear region. It is still unknown what its precise role in this release is, or whether AGFG1 also participates in cytoplasmic transport. We report for the first time the expression patterns during oogenesis for Drongo, the fruit fly homolog of AGFG1. We find that temporally controlled Drongo expression is achieved by translational repression of drongo mRNA within P-bodies. Here we show a first link between the recycling endosome pathway and Drongo, and find that proper Drongo localization at the oocyte's cortex during mid-oogenesis requires functional Rab11.

The role of ER exit sites in maintaining P-body organization and transmitting ER stress response during Drosophila melanogaster oogenesis.

Processing bodies (P-bodies) are cytoplasmic membrane-less organelles which host multiple mRNA processing events. While the fundamental principles of P-body organization are beginning to be elucidated in vitro, a nuanced understanding of how their assembly is regulated in vivo remains elusive. Here, we investigate the potential link between ER exit sites and P-bodies in Drosophila melanogaster egg chambers. Employing a combination of live and super-resolution imaging, we found that P-bodies associated with ER exit sites are larger and less mobile than cytoplasmic P-bodies, indicating that they constitute a distinct class of P-bodies which are more mature than their cytoplasmic counterparts. Moreover, we demonstrate that altering the composition of ER exit sites has differential effects on core P-body proteins (Me31B, Cup, and Trailer Hitch) suggesting a potential role for ER exit sites in P-body organization. We further show that in the absence of ER exit sites, P-body integrity is compromised and the stability and translational repression efficiency of the maternal mRNA, oskar, are reduced. Finally, we show that ER stress is communicated to P-bodies via ER exit sites, highlighting the pivotal role of ER exit sites as a bridge between membrane-bound and membrane-less organelles in ER stress response. Together, our data unveils the significance of ER exit sites not only in governing P-body organization, but also in facilitating inter-organellar communication during stress, potentially bearing implications for a variety of disease pathologies.

Drosophila rasiRNA pathway mutations disrupt embryonic axis specification through activation of an ATR/Chk2 DNA damage response.

Small repeat-associated siRNAs (rasiRNAs) mediate silencing of retrotransposons and the Stellate locus. Mutations in the Drosophila rasiRNA pathway genes armitage and aubergine disrupt embryonic axis specification, triggering defects in microtubule polarization as well as asymmetric localization of mRNA and protein determinants in the developing oocyte. Mutations in the ATR/Chk2 DNA damage signal transduction pathway dramatically suppress these axis specification defects, but do not restore retrotransposon or Stellate silencing. Furthermore, rasiRNA pathway mutations lead to germline-specific accumulation of gamma-H2Av foci characteristic of DNA damage. We conclude that rasiRNA-based gene silencing is not required for axis specification, and that the critical developmental function for this pathway is to suppress DNA damage signaling in the germline.

Visualizing and Tracking Endogenous mRNAs in Live Drosophila melanogaster Egg Chambers.

Fluorescence-based imaging techniques, in combination with developments in light microscopy, have revolutionized how cell biologists conduct live cell imaging studies. Methods for detecting RNAs have expanded greatly since seminal studies linked site-specific mRNA localization to gene expression regulation. Dynamic mRNA processes can now be visualized via approaches that detect mRNAs, coupled with microscopy set-ups that are fast enough to capture the dynamic range of molecular behavior. The molecular beacon technology is a hybridization-based approach capable of direct detection of endogenous transcripts in living cells. Molecular beacons are hairpin-shaped, internally quenched, single-nucleotide discriminating nucleic acid probes, which fluoresce only upon hybridization to a unique target sequence. When coupled with advanced fluorescence microscopy and high-resolution imaging, they enable one to perform spatial and temporal tracking of intracellular movement of mRNAs. Although this technology is the only method capable of detecting endogenous transcripts, cell biologists have not yet fully embraced this technology due to difficulties in designing such probes for live cell imaging. A new software application, PinMol, allows for enhanced and rapid design of probes best suited to efficiently hybridize to mRNA target regions within a living cell. In addition, high-resolution, real-time image acquisition and current, open source image analysis software allow for a refined data output, leading to a finer evaluation of the complexity underlying the dynamic processes involved in the mRNA's life cycle. Here we present a comprehensive protocol for designing and delivering molecular beacons into Drosophila melanogaster egg chambers. Direct and highly specific detection and visualization of endogenous maternal mRNAs is performed via spinning disc confocal microscopy. Imaging data is processed and analyzed using object detection and tracking in Icy software to obtain details about the dynamic movement of mRNAs, which are transported and localized to specialized regions within the oocyte.

Normal microRNA maturation and germ-line stem cell maintenance requires Loquacious, a double-stranded RNA-binding domain protein.

microRNAs (miRNAs) are single-stranded, 21- to 23-nucleotide cellular RNAs that control the expression of cognate target genes. Primary miRNA (pri-miRNA) transcripts are transformed to mature miRNA by the successive actions of two RNase III endonucleases. Drosha converts pri-miRNA transcripts to precursor miRNA (pre-miRNA); Dicer, in turn, converts pre-miRNA to mature miRNA. Here, we show that normal processing of Drosophila pre-miRNAs by Dicer-1 requires the double-stranded RNA-binding domain (dsRBD) protein Loquacious (Loqs), a homolog of human TRBP, a protein first identified as binding the HIV trans-activator RNA (TAR). Efficient miRNA-directed silencing of a reporter transgene, complete repression of white by a dsRNA trigger, and silencing of the endogenous Stellate locus by Suppressor of Stellate, all require Loqs. In loqs(f00791) mutant ovaries, germ-line stem cells are not appropriately maintained. Loqs associates with Dcr-1, the Drosophila RNase III enzyme that processes pre-miRNA into mature miRNA. Thus, every known Drosophila RNase-III endonuclease is paired with a dsRBD protein that facilitates its function in small RNA biogenesis.

Molecular beacons: Fluorescent probes for detection of endogenous mRNAs in living cells.

A novel approach for detecting nucleic acid in solution has been adopted for real-time imaging of native mRNAs in living cells. This method utilizes hybridization probes, called "molecular beacons", that generate fluorescent signals only when they are hybridized to a complementary target sequence. Nuclease-resistant molecular beacons are designed to efficiently hybridize to accessible regions within RNAs and then be detected via fluorescence microscopy. The target regions chosen for probe binding are selected using two computer algorithms, mfold and OligoWalk, that predict the secondary structure of RNAs and help narrow down sequence stretches to which the probes should bind with high affinity in vivo. As an example, molecular beacons were designed against regions of oskar mRNA, microinjected into living Drosophila melanogaster oocytes and imaged via confocal microscopy.

Drosophila melanogaster Oogenesis: An Overview.

The Drosophila melanogaster ovary has served as a popular and successful model for understanding a wide range of biological processes: stem cell function, germ cell development, meiosis, cell migration, morphogenesis, cell death, intercellular signaling, mRNA localization, and translational control. This review provides a brief introduction to Drosophila oogenesis, along with a survey of its diverse biological topics and the advanced genetic tools that continue to make this a popular developmental model system.

Single-Molecule RNA In Situ Hybridization (smFISH) and Immunofluorescence (IF) in the Drosophila Egg Chamber.

Detection of nucleic acids in whole tissues has become key in our understanding of gene expression during development. In situ hybridization (ISH) has been an invaluable technique in the making of numerous discoveries. Most recently, the technical advance of using short, fluorescently labeled probes has allowed for the detection of single-mRNA molecules. Thus, quantification of RNA levels in single cells or even within subcellular regions is now possible without RNA isolation. In combination with the immunofluorescence (IF) technique, visualization of nucleic acids and associating proteins is achieved with higher resolution than ever before using light microscopy. Here we describe the steps implemented to achieve the visualization of individual messenger RNAs (mRNA) using single-molecule FISH (smFISH) probes, as well as detection of mRNA/protein (mRNP) complexes via smFISH in combination with IF.

Tiny molecular beacons: LNA/2'-O-methyl RNA chimeric probes for imaging dynamic mRNA processes in living cells.

New approaches for imaging dynamic processes involving RNAs in living cells are continuously being developed and optimized. The use of molecular beacons synthesized from 2'-O-methylribonucleotides (which are resistant to cellular nucleases) is an established approach for visualizing native mRNAs in real time. In order to spatially and temporally resolve dynamic steps involving RNA in cells, molecular beacons need to efficiently hybridize to their RNA targets. To expand the repertoire of target sites accessible to molecular beacons, we decreased the length of their probe sequences and altered their backbone by the inclusion of LNA (locked nucleic acid) nucleotides. We named these new LNA/2'-O-methyl RNA chimera oligonucleotides "tiny molecular beacons". We analyzed these tiny molecular beacons and found that the incorporation of just a few LNA nucleotides enables these shorter probes to stably anneal to more structured regions of the RNA than is possible with conventional molecular beacons. The ease of synthesis of tiny molecular beacons and the flexibility to couple them to a large variety of fluorophores and quenchers render them optimal for the detection of less abundant and/or highly structured RNAs. To determine their efficiency to detect endogenous mRNAs in live specimens, we designed tiny molecular beacons that were specific for oskar mRNA and microinjected them into living Drosophila melanogaster oocytes. We then imaged the live oocytes via spinning disk confocal microscopy. The results demonstrate that tiny molecular beacons hybridize to target mRNA at faster rates than classically designed molecular beacons and are able to access previously inaccessible target regions.

Tiny molecular beacons for in vivo mRNA detection.

The molecular beacon technology is an established approach for visualizing native mRNAs in living cells. These probes need to efficiently hybridize to accessible RNA regions in order to spatially and temporally resolve the dynamic steps of the RNA life cycle. A refined method using two computer algorithms, mfold and RNAstructure, is described for choosing shorter, more abundant target regions for molecular beacon binding. The probes are redesigned as small hairpins and are synthesized from 2'-O-methyl RNA/LNA chimeric nucleic acids. These tiny molecular beacons are stable in the cellular environment and have a high affinity for binding to target RNAs. The user-friendly synthesis protocol and ability to couple to a variety of fluorophores make tiny molecular beacons the optimal technology to detect less abundant, highly structured RNAs, as well as small RNAs, such as microRNAs. As an example, tiny chimeric molecular beacons were designed to target regions of oskar mRNA, microinjected into living Drosophila melanogaster oocytes and imaged via spinning disc confocal microscopy.

In vivo colocalisation of oskar mRNA and trans-acting proteins revealed by quantitative imaging of the Drosophila oocyte.

Efficient mRNA transport in eukaryotes requires highly orchestrated relationships between nuclear and cytoplasmic proteins. For oskar mRNA, the Drosophila posterior determinant, these spatio-temporal requirements remain opaque during its multi-step transport process. By in vivo covisualization of oskar mRNA with Staufen, its putative trafficking protein, we find oskar mRNA to be present in particles distinct from Staufen for part of its transport. oskar mRNA stably associated with Staufen near the posterior pole. We observe oskar mRNA to oligomerize as hundreds of copies forming large particles which are necessary for its long range transport and localization. We show the formation of these particles occurs in the nurse cell nucleus in an Hrp48-dependent manner. We present a more refined model of oskar mRNA transport in the Drosophila oocyte.

Molecular beacons light the way: Imaging native mRNAs in living cells.

Extract: In vivo techniques to investigate the pathways that mRNAs undergo from maturation to localization at specific regions within a cell have thus far been the exclusive domain of protein biology as our ability to probe for nucleic acids in vivo have been hindered. In vivo imaging of synthetic transcripts helped dissect such a fundamental cellular process. Yet, in order to fully grasp the diverse organization and behavior of mRNAs in living cells, it is important to visualize the distribution and dynamics of RNA molecules in their living context, much like green fluorescent protein and its variants that fluoresce in diverse colors, have allowed us to image the dynamics of proteins. In 1996, our laboratory described a novel approach for detecting nucleic acids in solution. We have proceeded to make significant adaptations to this technique to facilitate visualization of the distribution and trafficking of mRNAs in living cells. This technique utilizes hybridization probes, called "molecular beacons," that generate fluorescent signals only when hybridized to a complementary nucleic acid target sequence. Molecular beacons are single-stranded oligonucleotides that form a stem-and-loop structure, where the loop portion of the molecule is a probe sequence complementary to a target RNA sequence, and the stem is formed by the annealing of complementary arm sequences which envelope the probe sequence. A fluorophore and a quencher moiety are covalently linked to the end of each arm, respectively.

Visualizing the distribution and transport of mRNAs in living cells.

We have visualized the movements of native mRNAs in living cells. Using nuclease-resistant molecular beacons, we imaged the transport and localization of oskar mRNA in Drosophila melanogaster oocytes. When the localization pattern was altered by genetic manipulation of the mRNA's 3' untranslated region, or by chemical perturbation of the intracellular tubulin network, the distribution of the fluorescence signals changed accordingly. We tracked the migration of oskar mRNA in real time, from the nurse cells where it is produced to the posterior cortex of the oocyte where it is localized. Our observations reveal the presence of a transient, and heretofore elusive, stage in the transport of oskar mRNA. Direct visualization of specific mRNAs in living cells with molecular beacons will accelerate studies of intracellular RNA trafficking and localization, just as the use of green fluorescent protein has stimulated the study of specific proteins in vivo.