Summary

Перенос генов в разработке мыши Внутреннее ухо по<em> В Vivo</em> Электропорация

Published: June 30, 2012
doi:

Summary

Мышь внутреннее ухо плакоды производных органа чувств чье развитие программа разработана во время беременности. Мы определяем<em> Внутриутробно</em> Перенос генов техника, состоящая из трех этапов: мышь вентральной лапаротомия, transuterine микроинъекции, и<em> В естественных условиях</em> Электропорации. Мы используем цифровой микроскопии видео, чтобы продемонстрировать критической экспериментальных эмбриологических методов.

Abstract

The mammalian inner ear has 6 distinct sensory epithelia: 3 cristae in the ampullae of the semicircular canals; maculae in the utricle and saccule; and the organ of Corti in the coiled cochlea. The cristae and maculae contain vestibular hair cells that transduce mechanical stimuli to subserve the special sense of balance, while auditory hair cells in the organ of Corti are the primary transducers for hearing 1. Cell fate specification in these sensory epithelia and morphogenesis of the semicircular canals and cochlea take place during the second week of gestation in the mouse and are largely completed before birth 2,3. Developmental studies of the mouse inner ear are routinely conducted by harvesting transgenic embryos at different embryonic or postnatal stages to gain insight into the molecular basis of cellular and/or morphological phenotypes 4,5. We hypothesize that gene transfer to the developing mouse inner ear in utero in the context of gain- and loss-of-function studies represents a complimentary approach to traditional mouse transgenesis for the interrogation of the genetic mechanisms underlying mammalian inner ear development6.

The experimental paradigm to conduct gene misexpression studies in the developing mouse inner ear demonstrated here resolves into three general steps: 1) ventral laparotomy; 2) transuterine microinjection; and 3) in vivo electroporation. Ventral laparotomy is a mouse survival surgical technique that permits externalization of the uterus to gain experimental access to the implanted embryos7. Transuterine microinjection is the use of beveled, glass capillary micropipettes to introduce expression plasmid into the lumen of the otic vesicle or otocyst. In vivo electroporation is the application of square wave, direct current pulses to drive expression plasmid into progenitor cells8-10.

We previously described this electroporation-based gene transfer technique and included detailed notes on each step of the protocol11. Mouse experimental embryological techniques can be difficult to learn from prose and still images alone. In the present work, we demonstrate the 3 steps in the gene transfer procedure. Most critically, we deploy digital video microscopy to show precisely how to: 1) identify embryo orientation in utero; 2) reorient embryos for targeting injections to the otocyst; 3) microinject DNA mixed with tracer dye solution into the otocyst at embryonic days 11.5 and 12.5; 4) electroporate the injected otocyst; and 5) label electroporated embryos for postnatal selection at birth. We provide representative examples of successfully transfected inner ears; a pictorial guide to the most common causes of otocyst mistargeting; discuss how to avoid common methodological errors; and present guidelines for writing an in utero gene transfer animal care protocol.

Protocol

1. Брюшной Лапаротомия Обезболить плотины, эмбрионы которых находятся в эмбриональном день 11.5 (E11.5; полдень в день вагинальным вилка обнаруженного день 0,5 эмбрионального развития) путем внутрибрюшинного введения пентобарбитала натрия раствор анестетика (7,5 мкл на грамм массы тел?…

Discussion

Перенос генов в развивающихся мыши внутреннего уха: мышь внутреннее ухо развивается из слуховой плакоды в течение первой недели постимплантационных развитии 12,13. В эмбриональном день 9,5 (E9.5), плакоды был инвагинировать и превратился в заполненных жидкостью пузырьков на?…

Disclosures

The authors have nothing to disclose.

Acknowledgements

We thank Humana Press for permission to publish the microinjection pipette fabrication figure which originally appeared on page 130 of reference 11; Larry Dlugas and Steven Wong, OHSU Department of Educational Communications, for videography; Larry Dlugas for video design and editing; Adam M. O’Quinn, Senior Designer, Trion/Envirco for designing our custom horizontal laminar flow hood and Les Goldsmith for providing the technical schematic; Victor Monterroso, MV, MS, PhD and Tom Chatkupt, DVM, OHSU Department of Comparative Medicine, for guidance with our animal care protocol, surgical techniques, and prophylactic analgesia regimen; Marcel Perret-Gentil, DVM, MS, for sharing his handout on veterinary suturing techniques; Edward Porsov, MS, for designing our Adobe Premiere Pro video microscopy computer workstation; and Leah White and Jonas Hinckley of LNS Captioning (Portland, OR). This work was supported by grants from the National Institute on Deafness and other Communication Disorders: DC R01 008595 and DC R01 008595-04S2 (to JB) and P30 DC005983 (Oregon Hearing Research Center Core Grant, Peter Gillespie, Principal Investigator).

Materials

Name of the reagent Company Catalogue number Comments
Micro Sterilizing Case ROBOZ RS-9900a 8X8.5X1.25 inches
Ball-tipped scissors Fine Science Tools 14109-09  
Ring forceps Fine Science Tools 11106-09 4.8mm ID/6mm OD
Adson Tissue Forceps Fine Science Tools 11027-12  
Needle driver Fine Science Tools 12502-12  
Allergy Syringe Tray Becton Dickison 305536  
Suture 6-0 Syneture GL-889 0.7 metric gastrointestinal suture
Lactated Ringer’s Injection USP Baxter 2B2323  
Fast green Sigma Aldrich F7258  
Borosilicate glass capillary Harvard Apparatus 30-0053  
Nembutal Sodium Solution OVATION Pharmaceuticals Inc. NDC 67386-501-52  
MgSO4.7H2O Fisher Scientific M63-500  
Propylene glycol Fisher Scientific P355-1  
Ethanol Sigma Aldrich E7023-500  
Meloxicam Boehringer Ingeheim NADA 141-219  
Micropipette Puller Sutter Instruments P-97 FB255B box filament; consult Pipette Cookbook from Sutter instruments
Microelectrode Beveler Sutter Instruments BV-10 104C beveling disk for large pipettes; consult owner’s manual for beveling theory
Micropipette holder Warner Instruments MP-S15T For 1.5mm outer diameter pipette and female pressure port for Picospritzer tubing.
Tweezers-style electrode Protech International Inc. CUY650P5 5 mm outer diameter
Square Wave Electroporator Protech International Inc. CUY21EDIT Footpedal recommended
PICOSPRITZER III Parker Hannifin 051-0500-900 Footpedal recommended
Manual Control Micromanipulator Harvard Apparatus 640056  
Horizontal laminar flow clean bench Envirco   Custom modifications to LF 630-10554. See supplementary information for hood schematic.
Leica stereofluorescence dissecting microcope with Lumencor SOLA light engine Bartels and Stout and Lumencor MZ10F with Lumencor SOLA light engine Footpedals to focus the MZ10F and to trigger the SOLA light engine are recommended
Alexa Fluor 594 Dextran Invitrogen D22913 10mg/ml, aqueous
Alexa Fluor 488 Dextran Invitrogen D22910 10mg/ml, aqueous
Enviro-dri Shepherd Specialty Papers   www.ssponline.com

References

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Cite This Article
Wang, L., Jiang, H., Brigande, J. V. Gene Transfer to the Developing Mouse Inner Ear by In Vivo Electroporation. J. Vis. Exp. (64), e3653, doi:10.3791/3653 (2012).

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