Dissezione e Montaggio di<em> Drosophila</em> pupa Dischi Eye
Summary
The goal of this technique is to enable researchers to perform dissection, immunostaining and mounting of pupal eye discs from Drosophila melanogaster of any age.
Abstract
The Drosophila melanogaster eye disc is a powerful system that can be used to study many different biological processes. It contains approximately 800 separate eye units, termed ommatidia1. Each ommatidium contains eight neuronal photoreceptors that develop from undifferentiated cells following the passage of the morphogenetic furrow in the third larval instar2. Following the sequential differentiation of the photoreceptors, non-neuronal cells develop, including cone and pigment cells, along with mechanosensory bristle cells3. Final differentiation processes, including the structured arrangement of all the ommatidial cell types, programmed cell death of undifferentiated cell types and rhodopsin expression, occurs through the pupal phase4-7. This technique focuses on manipulating the pupal eye disc, providing insight and instruction on how to dissect the eye disc during the pupal phase, which is inherently more difficult to perform than the commonly dissected third instar eye disc. This technique also provides details on immunostaining to allow the visualization of various proteins and other cell components.
Introduction
I campi di biologia dello sviluppo e delle cellule sono stati notevolmente influenzati dalla organismo modello: Drosophila melanogaster. All'interno di questo modello, gli studi del disco occhi hanno contribuito una grande quantità di conoscenze in materia di segnalazione, biologia cellulare e in altri settori. Il terzo disco in ritardo stadio larvale occhio è stato ampiamente studiato ed è un potente modello di utilizzare, in quanto dà una fotografia istantanea di una serie di periodi di sviluppo, ciascuno con le proprie molecole e dei processi di segnalazione unica, come il solco morfogenetica progredisce attraverso il disco occhio 8. Tuttavia, vi è la necessità di ampliare ulteriormente la nostra comprensione dei processi di sviluppo nella fase di pupa dello sviluppo. Mentre ci sono stati studi sul disco occhio pupa 3-7, la nostra conoscenza non si avvicina l'ampiezza del lavoro che è stato eseguito il terzo disco instar occhio. Ciò è dovuto, in parte, alla maggiore difficoltà di sezionare il disco dell'occhio pupa. Pertanto, una presentazione delcorretto metodo di dissezione potrebbe espandere notevolmente la ricerca in questo settore.
Mentre ci sono fasi di sviluppo all'interno di pupa disco occhio che sono facilmente sezionati, in particolare intorno alla metà del periodo di pupa, altri periodi di tempo sono molto più difficili da sezionare. Questo protocollo rappresenta un metodo per sezionare i dischi degli occhi pupa che può essere usato universalmente per tutte le pupe tempi di sviluppo. Questo protocollo può essere utilizzato in alternativa a un altro protocollo 9, che mostra un metodo semplice e veloce per sezionare i dischi occhio dai punti temporali midpupal. Questo protocollo è stato originariamente girato e sviluppato per la formazione di studenti universitari avanzati in Undergraduate Research Consortium UCLA in Genomica Funzionale (URCFG) 10,11 nella tecnica di pupa dissezione dell'occhio. Molti studenti universitari sono stati in grado di utilizzare questo video e metodo per imparare questa tecnica impegnativa.
Protocol
Representative Results
Discussion
While it appears that the process is simple and easy to perform, in reality, this technique requires a great deal of practice to master. Routinely, we start students off by learning to dissect and mount third instar eye discs12, which are much easier to work with. This practice helps to develop an appropriate dissection position of the arms, hands and fingers13 so that manipulation of the forceps under the dissecting microscope is stable, easy and experienced. In essence, the practice period shou…
Divulgations
The authors have nothing to disclose.
Acknowledgements
We appreciate and would like to thank the Howard Hughes Medical Institute for the HHMI Professor award to U.B. which made this project possible. We thank the college at the University of California, Los Angeles for providing facilities and teaching infrastructure support for this work. The work was also supported with funding from Midwestern University and a generous donation from the Charity Fidelity Gift Fund. We thank John VandenBrooks for comments on the manuscript and Krista Pearman for her technical assistance.
Materials
| Phosphate-buffered saline (PBS, pH 7.4) | 80g NaCl, 2g KCl, 14.4g Na2HPO4, 2.4g KH2PO4, Bring volume to 1 l, adjust the pH to 7.4, autoclave or filter sterilize, dilute to 1X PBS with autoclaved ddH2O before using. | ||
| Triton X-100 | Promega | H5142 | Caution: Irritant! Wear gloves. |
| 0.3% PBT | 1.5 ml of Triton X-100, 500 ml 1X PBS. | ||
| 37% formaldehyde solution | Fisher Scientific | F75P1GAL | Caution: Toxic, probable human carcinogen! Wear gloves. |
| Fix Solution | (≈4% Formaldehyde in PBS) 50 μl of 37% Formaldehyde, 450 μl 1XPBS, make fresh before use | ||
| Normal goat serum | Rockland antibodies & assays | B304 | Aliquot in 1 ml volumes and store at -80C |
| Block Solution | 10% NGS in PBT. This can be made and stored at 4 °C for a few days prior to use. | ||
| DAPI stock solution | Life Technologies | D3571 | For coutnerstaining nuclei. Prepare a 1 mg/ml solution with ddH2O. |
| VectaShield Mounting Medium | Vector Labs | H-1000 | Mounting medium |
| Glycerol | Sigma | G5516 | For mounting. Prepare 70% dilution with ddH2O. |
| Equipment | |||
| Nutating mixer | VWR | 82007-202 | Used to rock tissue in 3 well glass dish |
| SylGard 182 Silicone Elastomer Kit | Krayden | NC9897184 | Used to make silicone dissection dish |
| Silicone dissecting dish | Mix Sylgard elastomer kit (above) according to directions gently (to avoid bubbles). Pour mixture into Petri dish (any size). Allow SylGard to cure overnight in 37 °C incubator. | ||
| 3 well glass dish | Corning | 7220-85 | The 3 well variety of these are no longer available, this is the 9 well product. |
| 72 well microwell minitray | Nunc | 438733 | |
| Sharp forceps (Dumont #55) | Fine Science Tools | 11255-20 | |
| Vannas-type Micro Scissors, Straight, 5mm blade | Ted Pella | 1346 | |
| 100 mm Borosilicate glass capillaries | World Precision Instruments | 1B100-4 | Pull with needle puller to make fine point tip that allows a small stream of PBS to flow. |
| Disposable Transfer Pipets, Fine Tip | Samco Scientific | 231 | |
| Tubing dimensions given are inner diameter (ID) x outer diameter (OD) x wall thickness in inches | |||
| PVC tubing (1/8 x 3/16 x 1/32) | Nalgene | 8000-0010 | Use these with pulled needle to assemble the blower tube as shown in Figure 2. |
| Tygon Silicone tubing (3/32 x 5/32 x 1/32) | Saint Gobain Performance Plastics | ABW00004 | |
| Tygon Silicone tubing (1/32 x 3/32 x 1/32) | Saint Gobain Performance Plastics | ABW00001 | |
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