Click here to close
Hello! We notice that you are using Internet Explorer, which is not supported by Xenbase and may cause the site to display incorrectly.
We suggest using a current version of Chrome,
FireFox, or Safari.
BMC Dev Biol
2007 Sep 27;7:107. doi: 10.1186/1471-213X-7-107.
Show Gene links
Show Anatomy links
Electroporation of cDNA/Morpholinos to targeted areas of embryonic CNS in Xenopus.
Falk J
,
Drinjakovic J
,
Leung KM
,
Dwivedy A
,
Regan AG
,
Piper M
,
Holt CE
.
???displayArticle.abstract???
BACKGROUND: Blastomere injection of mRNA or antisense oligonucleotides has proven effective in analyzing early gene function in Xenopus. However, functional analysis of genes involved in neuronal differentiation and axon pathfinding by this method is often hampered by earlier function of these genes during development. Therefore, fine spatio-temporal control of over-expression or knock-down approaches is required to specifically address the role of a given gene in these processes.
RESULTS: We describe here an electroporation procedure that can be used with high efficiency and low toxicity for targeting DNA and antisense morpholino oligonucleotides (MOs) into spatially restricted regions of the Xenopus CNS at a critical time-window of development (22-50 hour post-fertilization) when axonal tracts are first forming. The approach relies on the design of "electroporation chambers" that enable reproducible positioning of fixed-spaced electrodes coupled with accurate DNA/MO injection. Simple adjustments can be made to the electroporation chamber to suit the shape of different aged embryos and to alter the size and location of the targeted region. This procedure can be used to electroporate separate regions of the CNS in the same embryo allowing separate manipulation of growing axons and their intermediate and final targets in the brain.
CONCLUSION: Our study demonstrates that electroporation can be used as a versatile tool to investigate molecular pathways involved in axon extension during Xenopus embryogenesis. Electroporation enables gain or loss of function studies to be performed with easy monitoring of electroporated cells. Double-targeted transfection provides a unique opportunity to monitor axon-target interaction in vivo. Finally, electroporated embryos represent a valuable source of MO-loaded or DNA transfected cells for in vitro analysis. The technique has broad applications as it can be tailored easily to other developing organ systems and to other organisms by making simple adjustments to the electroporation chamber.
???displayArticle.pubmedLink???
17900342
???displayArticle.pmcLink???PMC2147031 ???displayArticle.link???BMC Dev Biol ???displayArticle.grants???[+]
Figure 1. Efficient DNA transfection of stage 26â28 Xenopus embryos. a: Schematic representation of the experimental setup. Embryos were placed in the main channel of the electroporation chamber, while the electrode tips (0.5 mm wide) were positioned in the transverse channel. A diagram of the setup is presented as an insert with channel (outlines in red). b, c: Representative images of embryos electroporated in 1à MMR and 0.1à MBS. Bright field images (left panel) and GFP fluorescence (right panel) of living embryos 12 h after electroporation. No morphological abnormalities are observed. d: Histograms presenting the relative transfection efficiencies (blue) evaluated from observation of embryos as shown in c and d. The percentage of embryos showing macroscopic damage (red) was recorded for each condition. Different parameters are listed in the following order: Voltage, pulse duration, interpulse space and number of pulses. e, f: Electroporation resulted in a high percentage of transfected cells without affecting brain microanatomy. Nls-GFP signal (e) was observed in many nuclei (f) from the ventricle to the most superficial layer 48 h after electroporation. The transfected hemi-brain was outlined in white. Scale bars: 400 μm in b and c; 100 μm in e.
Figure 2. Cell types and morphology of the transfected cells. a: Membrane-tethered GFP (GAP-GFP) delineated the processes of transfected neurons including the axons (the ventricle and neuropil are outlined in white). The arrow indicates a bundle of axons travelling in the neuropil). b: Radial-glia like morphology of GAP-RFP transfected cells lining the ventricle. c-e: Co-expression of GAP-GFP (c) and acetylated-tubulin (d) in superficial layers (e- merge). f: Wholemount brain preparation from an electroporated embryo showing different axon tracts. The brain outline was drawn based on the corresponding bright field image. Di., diencephalon; OT, optic tectum; Tel., telencephalon; Epi., epiphysis. Scale bars: 100 μm in f; 50 μm in a; 10 μm in b-e.
Figure 3. Electroporation of stage 21â35/36 embryos leads to rapid expression of transgenes. a: Electroporation efficiency decreased with increasing embryonic stage. Percentages of nls-GFP positive cells 12 h after transfection at stage 26, 28 or 32 (n represents the number of sections analyzed from 3 embryos). Similar results were obtained at 48 h post electroporation (data not shown). b-d: Distribution of transfected cells depended on the stage of embryos electroporated. Distribution of nls-GFP transfected cells 48 h afterwards in embryos electroporated at stage 28 (b) and 32 (c). Note that the density of cells (DAPI) is lower laterally. d: Histograms showing decreases in the fraction of cells transfected in the superficial third of the brain when embryos were electroporated at stage 32 as compared to stage 28. e: A cluster of superficially located cells can be selectively transfected by injecting the DNA solution under the skin (the pia and epidermis are outlined in white). f-h: Time course of GFP expression in embryos electroporated at stage 29/30 (20 V/25 ms/1 s/8 x). The fractions as well as mean intensities of GFP positive cells were quantified (h) from sections (examples: f and g) (15 sections from 3 embryos were analyzed for the 6 h and 48 h time points and 39 sections from 3 embryos for the 24 h time-point). Differences between the time points were statistically significant using a Mann-Whitney test; probabilities are indicated together with the standard error (S.E.M). Outlines of the brains are presented (ventricle on the left). Scale bars: 100 μm in e; 50 μm in b, c, f and g.
Figure 4. Using electroporation to study retino-tectal projections in vivo: a-b: Regions of the brain can be differentially targeted by sliding the embryo in the main channel (compare upper and lower panels in a). When the caudal part of the head was exposed, most of the optic pathway was electroporated (b). c-e: The transfected area can be restricted by reducing the amount of embryo area directly facing the electrodes. The modified chamber used to restrict electroporation is depicted in c (note the narrowing of the transverse channel in the inset), and a representative example of GFP expression 12 h post electroporation in a live embryo is shown in d. GFP expression in the tectum is shown on a wholemount dissected brain (e). Axons emanating from these neurons can be clearly observed (arrow). The dashed line delineates the diencephalon/mesencephalon boundary. The transfected area is restricted to the OT (dorsal mesencephalon). f-g: Electrodes can be placed dorsal and ventral to the embryo to target the ventral or dorsal part of the brain. A frontal section through the midbrain (g) demonstrating that ventral populations can be targeted by placing the embryo on its side in the specifically designed chamber represented in f. h-r: Retinas can be electroporated without affecting eye development. 48 h post electroporation, GAP-GFP was detected in all the retinal layers and outlined different retinal cell types with their characteristic morphologies (h-i). Eye microanatomy appeared normal (h). Eye-targeted electroporation can be performed by placing the embryo ventral side up, so that the eye but not the brain faces the electrodes (j). Eye-specific electroporation can be performed with limited brain transfection. Insert: side view of a transfected embryo 24 h after eye-targeted electroporation. GFP signal was detected in the eye and the RGC axons navigating to the tectum (arrow) but not in the brain on frontal sections (k). l-n: Co-electroporation of pCS2GAP-RFP with pEGFP. Most of the GAP-RFP positive cells (m) are also EGFP positive (n). Double positive cells are marked with white dots and the arrows point to axons leaving the retina. Outlines of the retina and lens were drawn from the corresponding DAPI counterstainings. After GAP-GFP electroporation, axons can be monitored using time-lapse microscopy (o-q) and growth cone morphology can be analyzed (r) in wholemount brain preparations. Axons were monitored as they entered the tectum. Initial positions of the two growth cones are indicated (white dot and rectangle). Time is in hours. Epi., epiphysis. Scale bars: 400 μm in a, d and insert j; 200 μm in b and e; 100 μm in k; 50 μm in h, i and l; 25 μm in o-q; 10 μm in m and n; 5 μm in r.
Figure 5. Both retinal projection neurons and their substrate pathway can be manipulated separately in the same embryo. a-d: Eye-targeted electroporation can be combined with brain electroporation. a: A dorsal view of an embryo doubly transfected. Retinal axons (red in b and c) navigate normally to the tectum, passing through a transfected region of the diencephalon (green in c) (dashed line indicates the OT boundary). Eye- and ventral-targeted electroporation can be combined (d). Frontal section showing axons from the transfected retina (red) that have crossed the transfected midline (GFP-transfected) and growing dorsally towards tectum (arrow). e-g: Electroporation can be performed on embryos lipofected in the eyes. e: High magnification of two GFP lipofected axons passing through a cluster of electroporated tectal cells. f and g: Frontal sections of an embryo lipofected in the eye and electroporated in the brain. Retinal axons in the dorsal brain (green: f, g) traversed the transfected cells (red: g). Outlines of brains in wholemounts (b, c, e) and sections (f, g) were drawn based on bright field images and DAPI counterstainings respectively. Epi., epiphysis; Di., diencephalon; OT, optic tectum; Tel, telencephalon. Scale bars: 400 μm in a; 100 μm in b-g.
Figure 6. Introducing Morpholinos into young Xenopus tadpoles by electroporation and in vitro approaches. a-d: Frontal sections of embryos 24 h after electroporation with lissamine-tagged MO. Large numbers of cells can be loaded with MO in both the brain (a) and the eye (c). Microanatomy of both structures appears normal (b and d). e-f: Co-electroporation of pCS2GAP-GFP with lissamine-tagged special delivery MO. e: A higher magnification image of a co-electroporated brain. The MO signal was de-saturated in Photshop in order to facilitate observation of MO and membrane GFP co-expression (arrowhead). f: An image of eye-targeted co-electroporation illustrating the extent of co-electroporation and the sizes of MO and DNA electroporated regions. g: Frontal section of a MO/GFP co-electroporated embryo showing that GFP can be used to trace the axons of electroporated cells (arrowheads indicate axons at different points in their pathway). h and i: Examples of embryos electroporated with pCS2GFP in the presence (i) or absence (h) of anti-GFP MO. Morphology of the eye appeared normal in both conditions (left panel). The GFP signal was sharply reduced in the anti-GFP MO condition when analyzed 12 h after electroporation (central panels). A decrease in electroporation efficiency was not a confounding factor in this experiment as the Special Delivery lissamine-tagged MO control is efficiently loaded in both conditions (far right panel). j: Quantification of results presented in h and i (n indicates the number of embryos analyzed). Anti-GFP MO only affects expression of pCS2GFP but not of pEGFP (Clontech). k: Anti-GFP MO was co-electroporated with GFP and GAP-RFP. 48 h after electroporation, GFP and RFP fluorescence was quantified on sections and the ratio between the two calculated. (n refers to the numbers of sections quantified [3 embryos were analyzed for control and 6 for MO]). Statistical analysis: Mann-Whitney test; probabilities are indicated together with the S.E.M. l-m: Sections through an eye lipofected with GFP (green, l and m) and subsequently loaded with lissamine-tagged MOs (red) using electroporation (merge, m). n-q: Electroporated embryos can be a source of modified cells for in vitro studies. Explants and cells cultured from MO (n and o) or DNA (GFP) (p and q) electroporated embryos. Scale bars: 400 μm in h; 100 μm in a; 50 μm in d, f, and g; in 25 μm e and m; 20 μm in n; 10 μm in o.
Araki,
Engrailed defines the position of dorsal di-mesencephalic boundary by repressing diencephalic fate.
1999, Pubmed
Araki,
Engrailed defines the position of dorsal di-mesencephalic boundary by repressing diencephalic fate.
1999,
Pubmed
Bonnot,
Electroporation loading of calcium-sensitive dyes into the CNS.
2005,
Pubmed
Bosch,
In vivo electroporation for genetic manipulations of whole Hydra polyps.
2002,
Pubmed
Bovolenta,
Morphogen signaling at the vertebrate growth cone: a few cases or a general strategy?
2005,
Pubmed
Boy,
XSEB4R, a novel RNA-binding protein involved in retinal cell differentiation downstream of bHLH proneural genes.
2004,
Pubmed
,
Xenbase
Briscoe,
A homeodomain protein code specifies progenitor cell identity and neuronal fate in the ventral neural tube.
2000,
Pubmed
Canatella,
Tissue electroporation: quantification and analysis of heterogeneous transport in multicellular environments.
2004,
Pubmed
Cao,
A functional study of miR-124 in the developing neural tube.
2007,
Pubmed
Cerda,
Electroporation of DNA, RNA, and morpholinos into zebrafish embryos.
2006,
Pubmed
Coen,
Xenopus Bcl-X(L) selectively protects Rohon-Beard neurons from metamorphic degeneration.
2001,
Pubmed
,
Xenbase
Cornel,
Precocious pathfinding: retinal axons can navigate in an axonless brain.
1992,
Pubmed
,
Xenbase
Das,
In vivo time-lapse imaging of cell divisions during neurogenesis in the developing zebrafish retina.
2003,
Pubmed
Di Gregorio,
Analyzing gene regulation in ascidian embryos: new tools for new perspectives.
2002,
Pubmed
Dityateva,
Rapid and efficient electroporation-based gene transfer into primary dissociated neurons.
2003,
Pubmed
Dwivedy,
Ena/VASP function in retinal axons is required for terminal arborization but not pathway navigation.
2007,
Pubmed
,
Xenbase
Eberhart,
EphA4 constitutes a population-specific guidance cue for motor neurons.
2002,
Pubmed
Eide,
Electroporation-mediated gene transfer in free-swimming embryonic Xenopus laevis.
2000,
Pubmed
,
Xenbase
England,
A dynamic fate map of the forebrain shows how vertebrate eyes form and explains two causes of cyclopia.
2006,
Pubmed
Eroshkin,
Characterization of cis-regulatory elements of the homeobox gene Xanf-1.
2002,
Pubmed
,
Xenbase
Foa,
The scaffold protein, Homer1b/c, regulates axon pathfinding in the central nervous system in vivo.
2001,
Pubmed
,
Xenbase
Geng,
The Xenopus noggin promoter drives roof-plate specific transcription.
2003,
Pubmed
,
Xenbase
Haas,
Single-cell electroporation for gene transfer in vivo.
2001,
Pubmed
,
Xenbase
Haas,
Targeted electroporation in Xenopus tadpoles in vivo--from single cells to the entire brain.
2002,
Pubmed
,
Xenbase
Hammond,
Slit-mediated repulsion is a key regulator of motor axon pathfinding in the hindbrain.
2005,
Pubmed
Harris,
Two cellular inductions involved in photoreceptor determination in the Xenopus retina.
1992,
Pubmed
,
Xenbase
Harris,
Growth cones of developing retinal cells in vivo, on culture surfaces, and in collagen matrices.
1985,
Pubmed
,
Xenbase
Hartenstein,
Early pattern of neuronal differentiation in the Xenopus embryonic brainstem and spinal cord.
1993,
Pubmed
,
Xenbase
Heasman,
Beta-catenin signaling activity dissected in the early Xenopus embryo: a novel antisense approach.
2000,
Pubmed
,
Xenbase
Hendricks,
Electroporation-based methods for in vivo, whole mount and primary culture analysis of zebrafish brain development.
2007,
Pubmed
,
Xenbase
Holt,
Lipofection of cDNAs in the embryonic vertebrate central nervous system.
1990,
Pubmed
,
Xenbase
Itasaki,
'Shocking' developments in chick embryology: electroporation and in ovo gene expression.
1999,
Pubmed
Jacobson,
Neurite outgrowth traced by means of horseradish peroxidase inherited from neuronal ancestral cells in frog embryos.
1985,
Pubmed
,
Xenbase
Kamdar,
Electroporation of Drosophila embryos.
1995,
Pubmed
Kos,
Methods for introducing morpholinos into the chicken embryo.
2003,
Pubmed
Koshiba-Takeuchi,
Tbx5 and the retinotectum projection.
2000,
Pubmed
Leung,
Asymmetrical beta-actin mRNA translation in growth cones mediates attractive turning to netrin-1.
2006,
Pubmed
,
Xenbase
Luo,
Cadherins guide migrating Purkinje cells to specific parasagittal domains during cerebellar development.
2004,
Pubmed
Luo,
Ex ovo electroporation for gene transfer into older chicken embryos.
2005,
Pubmed
Martinez,
Transfection of primary central and peripheral nervous system neurons by electroporation.
2003,
Pubmed
Michiue,
Temporal and spatial manipulation of gene expression in Xenopus embryos by injection of heat shock promoter-containing plasmids.
2005,
Pubmed
,
Xenbase
Miskevich,
RNA interference of Xenopus NMDAR NR1 in vitro and in vivo.
2006,
Pubmed
,
Xenbase
Momose,
Efficient targeting of gene expression in chick embryos by microelectroporation.
1999,
Pubmed
Moody,
Developmental expression of a neuron-specific beta-tubulin in frog (Xenopus laevis): a marker for growing axons during the embryonic period.
1996,
Pubmed
,
Xenbase
Muramatsu,
Comparison of three nonviral transfection methods for foreign gene expression in early chicken embryos in ovo.
1997,
Pubmed
Nakamura,
Introduction of DNA into chick embryos by in ovo electroporation.
2001,
Pubmed
Nutt,
Comparison of morpholino based translational inhibition during the development of Xenopus laevis and Xenopus tropicalis.
2001,
Pubmed
,
Xenbase
Ohnuma,
Lipofection strategy for the study of Xenopus retinal development.
2002,
Pubmed
,
Xenbase
Palmer,
Multiple roles of ephrins in morphogenesis, neuronal networking, and brain function.
2003,
Pubmed
Pekarik,
Screening for gene function in chicken embryo using RNAi and electroporation.
2003,
Pubmed
Poggi,
Influences on neural lineage and mode of division in the zebrafish retina in vivo.
2005,
Pubmed
Rao,
In vivo comparative study of RNAi methodologies by in ovo electroporation in the chick embryo.
2004,
Pubmed
Renzi,
Olfactory sensory axons expressing a dominant-negative semaphorin receptor enter the CNS early and overshoot their target.
2000,
Pubmed
Roberts,
The early development of neurons with GABA immunoreactivity in the CNS of Xenopus laevis embryos.
1987,
Pubmed
,
Xenbase
Rols,
In vivo electrically mediated protein and gene transfer in murine melanoma.
1998,
Pubmed
Sasagawa,
Axes establishment during eye morphogenesis in Xenopus by coordinate and antagonistic actions of BMP4, Shh, and RA.
2002,
Pubmed
,
Xenbase
Sasagawa,
Improved mRNA electroporation method for Xenopus neurula embryos.
2002,
Pubmed
,
Xenbase
Scaal,
In ovo electroporation of avian somites.
2004,
Pubmed
Schmitt,
Wnt-Ryk signalling mediates medial-lateral retinotectal topographic mapping.
2006,
Pubmed
Takahashi,
Manipulating gene expressions by electroporation in the developing brain of mammalian embryos.
2002,
Pubmed
Treubert-Zimmermann,
Targeting axons to specific fiber tracts in vivo by altering cadherin expression.
2002,
Pubmed
Visvanathan,
The microRNA miR-124 antagonizes the anti-neural REST/SCP1 pathway during embryonic CNS development.
2007,
Pubmed
Vize,
Assays for gene function in developing Xenopus embryos.
1991,
Pubmed
,
Xenbase
Walz,
Chondroitin sulfate disrupts axon pathfinding in the optic tract and alters growth cone dynamics.
2002,
Pubmed
,
Xenbase
Webber,
Fibroblast growth factors redirect retinal axons in vitro and in vivo.
2003,
Pubmed
,
Xenbase
Wu,
Infection of frog neurons with vaccinia virus permits in vivo expression of foreign proteins.
1995,
Pubmed
,
Xenbase