Name: optical clearing of the mouse central nervous system using passive clarity
Uploaded: 2016-06-30T13:00:00
Description: Watch this Scientific Journal Video about Optical Clearing of the Mouse Central Nervous System Using Passive CLARITY at JoVE.com

This work was generously supported by the National Institutes of Health/National Institute of Neurological Disorders and Stroke (NIH/NINDS) grant 1R01NS086981 and the Conrad N. Hilton Foundation. We thank Dr. Laurent Bentolila and Dr. Matthew Schibler for their invaluable assistance with confocal microscopy. We thank those that have contributed to the CLARITY forum (http://forum.claritytechniques.org). We especially thank Dr. Karl Deisseroth for opening up his lab to teach this fascinating technique. The authors are grateful for the generous support from the Brain Mapping Medical Research Organization, Brain Mapping Support Foundation, Pierson-Lovelace Foundation, The Ahmanson Foundation, Capital Group Companies Charitable Foundation, William M. and Linda R. Dietel Philanthropic Fund, and Northstar Fund. Research reported in this publication was also partially supported by the National Center for Research Resources and by the Office of the Director of the National Institutes of Health under award numbers C06RR012169, C06RR015431, and S10OD011939. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health.

All experiments were performed in accordance with Institutional Animal Care and Use Committee (IACUC) guidelines. THY1-YFP, PLP-EGFP and PV-TdTomato mice were used for these experiments, but any mice expressing fluorescent proteins can be successfully cleared and imaged.
1. Tissue Preparation
Caution: Paraformaldehyde (PFA) and acrylamide are toxic and irritants. Perform experiments utilizing these reagents in a fume hood and with appropriate personal protective equip...

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Passive clearing of hydrogel embedded tissues (passive CLARITY) is a simple and inexpensive method for clearing large pieces of tissue. This approach does not require dedicated equipment and can easily be performed in a temperature-controlled shaker. Over the span of a few weeks, even large, highly myelinated tissues, such as an entire brain or spinal cord, will become transparent and suitable for microscopy. Even though this report has focused on the clearing of CNS tissues, passive CLARITY can be applied to any tissue....

The ability to image complete neuroanatomical structures is immensely valuable for understanding the brain in health and disease. Traditionally, 3D imaging has required tissue sectioning to provide the axial resolution and to visualize deep anatomical structures. This approach can produce high-resolution data sets, but requires sophisticated image reconstruction techniques and is very labor intensive. As a result, it has been limited to the imaging of small volumes of tissue1-3. Optical sectioning, on the other hand, is well suited for the creation of high-resolution 3D images of fluorescently labeled tissues. Since optical sectioning is inherently three dimensional, it does not require extensive computation to produce a 3D image volume. However, light scattering and tissue opacity limit the depth at which tissues can be optically sectioned. The depth of imaging is limited to about 150 &#181;m in laser scanning confocal microscopy and to less than 800 &#181;m using two-photon excitation microscopy4-8.
In order to overcome these limitations, several optical clearing techniques have been recently developed and then further refined to permit the deep microscopic imaging of intact tissues. The use of benzyl alcohol and benzyl benzoate (BABB) to render fixed tissues transparent was among one of the earliest approaches9. However, this approach was limited by the quenching of fluorescence in the samples and incomplete clearing of highly myelinated structures10. Refinements of this technique, such as 3D Imaging of Solvent Cleared Organs (3DISCO), have led to very rapid and complete tissue clearing, but still suffer from rapid loss of fluorescent signals, especially yellow fluorescent protein (YFP)10. Water-based clearing solutions, such as Sca/e11 and SeeDB12, preserve fluorescent signals, but do not completely clear highly myelinated tissues. Clear, Unobstructed Brain Imaging Cocktails and Computational analysis (CUBIC) is a promising new optical clearing technology that appears to overcome the limitations of previously developed water-based clearing solutions13. In contrast with other optical clearing techniques, Clear Lipid-exchanged Acrylamide-hybridized Rigid Imaging-compatible Tissue-hYdrogel (CLARITY)14 embeds the brain in a porous matrix that provides structural integrity to proteins, nucleic acids and small molecules, while leaving lipids unbound. The lipids are then removed electrophoretically, culminating in an optically cleared brain that can be easily visualized and equally easily probed using commonly available techniques.
Electrophoretic tissue clearing (ETC) is used to remove lipids from hydrogel embedded tissues in CLARITY, however, ETC can be difficult to implement consistently and tissues subject to electrophoresis can exhibit tissue distortion, browning, loss of fluorescence and antibody reactivity. Passive lipid clearing avoids these limitations, but requires increased clearing times15-17. Passive clearing also permits the clearing of large numbers of samples in parallel, since it is not limited by the number of ETC apparatuses available. Decreasing the concentration of paraformaldehyde and excluding bis-acrylamide from the hydrogel have led to great increases in the speed of clearing at the expense of greater tissue expansion16. Less expensive alternatives to the refractive index matching solution used in the original CLARITY technique have been developed17-19. 2,2'-thiodiethanol (TDE) is an inexpensive and rapid brain clearing agent that reverses some of the tissue expansion that occurs during lipid removal18. This report incorporates passive clearing of hydrogel embedded tissue and the use of TDE as a refractive index matching solution to the original CLARITY technique to produce a highly reproducible and inexpensive protocol for the optical clearing of the mouse central nervous system.

<table border="0" cellpadding="0" cellspacing="0" width="750">
	<tbody>
		<tr height="42">
			<td height="42" style="height:42px;width:216px;">10X phosphate buffered saline (PBS)</td>
			<td style="width:212px;">Fisher</td>
			<td style="width:119px;">BP399-1</td>
			<td style="width:203px;">buffers</td>
		</tr>
		<tr height="21">
			<td height="21" style="height:21px;width:216px;">32% paraformaldehyde (PFA)</td>
			<td style="width:212px;">Electron Microscopy Sciences</td>
			<td style="width:119px;">15714-5</td>
			<td>perfusion and hydrogel</td>
		</tr>
		<tr height="21">
			<td height="21" style="height:21px;width:216px;">2,2&#39;-thiodiethanol (TDE)</td>
			<td style="width:212px;">Sigma-Aldrich</td>
			<td style="width:119px;">166782-500G</td>
			<td>refractive index matching solution</td>
		</tr>
		<tr height="21">
			<td height="21" style="height:21px;width:216px;">40% acrylamide</td>
			<td style="width:212px;">Bio-Rad</td>
			<td style="width:119px;">161-0140</td>
			<td>hydrogel</td>
		</tr>
		<tr height="21">
			<td height="21" style="height:21px;width:216px;">2% bis-acrylamide</td>
			<td style="width:212px;">Bio-Rad</td>
			<td style="width:119px;">161-0142</td>
			<td>hydrogel</td>
		</tr>
		<tr height="21">
			<td height="21" style="height:21px;">VA-044 initiator</td>
			<td>Wako Pure Chemical Industries, Ltd.</td>
			<td>VA044</td>
			<td>hydrogel</td>
		</tr>
		<tr height="21">
			<td height="21" style="height:21px;width:216px;">boric acid</td>
			<td style="width:212px;">Sigma-Aldrich</td>
			<td style="width:119px;">B7901</td>
			<td>clearing buffer</td>
		</tr>
		<tr height="21">
			<td height="21" style="height:21px;width:216px;">sodium dodecyl sulfate (SDS)</td>
			<td style="width:212px;">Fisher</td>
			<td style="width:119px;">BP166-5</td>
			<td>clearing buffer</td>
		</tr>
		<tr height="21">
			<td height="21" style="height:21px;width:216px;">sodium hydroxide</td>
			<td style="width:212px;">Fisher</td>
			<td style="width:119px;">55255-1</td>
			<td>buffers</td>
		</tr>
		<tr height="21">
			<td height="21" style="height:21px;width:216px;">sodium azide</td>
			<td style="width:212px;">Sigma-Aldrich</td>
			<td style="width:119px;">52002-100G</td>
			<td>preservative</td>
		</tr>
		<tr height="21">
			<td height="21" style="height:21px;width:216px;">triton x-100</td>
			<td style="width:212px;">Sigma-Aldrich</td>
			<td style="width:119px;">X100-500G</td>
			<td>buffers</td>
		</tr>
		<tr height="21">
			<td height="21" style="height:21px;width:216px;">heparin</td>
			<td style="width:212px;">Sigma-Aldrich</td>
			<td style="width:119px;">H3393-50KU</td>
			<td>perfusion</td>
		</tr>
		<tr height="21">
			<td height="21" style="height:21px;width:216px;">sodium nitrate</td>
			<td style="width:212px;">Fisher</td>
			<td style="width:119px;">BP360-500</td>
			<td>perfusion</td>
		</tr>
		<tr height="21">
			<td height="21" style="height:21px;width:216px;">DAPI</td>
			<td style="width:212px;">Molecular Probes</td>
			<td style="width:119px;">D1306</td>
			<td>nuclear stain</td>
		</tr>
		<tr height="21">
			<td height="21" style="height:21px;width:216px;">99.9% isoflurane</td>
			<td style="width:212px;">Phoenix</td>
			<td style="width:119px;">57319-559-06</td>
			<td>anesthetic</td>
		</tr>
		<tr height="21">
			<td height="21" style="height:21px;width:216px;">hydrocholoric acid</td>
			<td style="width:212px;">Fisher</td>
			<td style="width:119px;">A1445-500</td>
			<td>buffers</td>
		</tr>
		<tr height="21">
			<td height="21" style="height:21px;width:216px;">glass bottom dish</td>
			<td style="width:212px;">Willco</td>
			<td style="width:119px;">HBSB-5040</td>
			<td>Willco dishes</td>
		</tr>
		<tr height="21">
			<td height="21" style="height:21px;width:216px;">reusable adhesive</td>
			<td style="width:212px;">Bostick</td>
			<td style="width:119px;">371351</td>
			<td>Blu-Tack</td>
		</tr>
		<tr height="21">
			<td height="21" style="height:21px;width:216px;">silicon elastomer</td>
			<td style="width:212px;">World Precision Instruments</td>
			<td style="width:119px;">KWIK-CAST</td>
			<td>Kwik-Cast</td>
		</tr>
		<tr height="21">
			<td height="21" style="height:21px;width:216px;">lint-free wipe</td>
			<td style="width:212px;">Kimberly-Clark</td>
			<td style="width:119px;">34120</td>
			<td>KimWipe</td>
		</tr>
		<tr height="21">
			<td height="21" style="height:21px;width:216px;">mouse brain matrix</td>
			<td style="width:212px;">Roboz</td>
			<td style="width:119px;">SA-2175</td>
			<td>sectioning tissue</td>
		</tr>
		<tr height="21">
			<td height="21" style="height:21px;width:216px;">matrix blades</td>
			<td style="width:212px;">Roboz</td>
			<td style="width:119px;">RS-9887</td>
			<td>sectioning tissue</td>
		</tr>
		<tr height="21">
			<td height="21" style="height:21px;width:216px;">peristaltic pump</td>
			<td style="width:212px;">Cole-Parmer</td>
			<td style="width:119px;">77122-24</td>
			<td>pefusion</td>
		</tr>
		<tr height="21">
			<td height="21" style="height:21px;">laser scanning confocal microscope</td>
			<td>Leica</td>
			<td>SP5</td>
			<td>microscopy</td>
		</tr>
		<tr height="21">
			<td height="21" style="height:21px;width:216px;">imaging software</td>
			<td style="width:212px;">Leica</td>
			<td style="width:119px;">LAS AF</td>
			<td>microscopy</td>
		</tr>
	</tbody>
</table>

optical clearing of the mouse central nervous system using passive clarity

Traditionally, tissue visualization has required that the tissue of interest be serially sectioned and imaged, subjecting each tissue section to unique non-linear deformations, dramatically hampering one's ability to evaluate cellular morphology, distribution and connectivity in the central nervous system (CNS). However, optical clearing techniques are changing the way tissues are visualized. These approaches permit one to probe deeply into intact organ preparations, providing tremendous insight into the structural organization of tissues in health and disease. Techniques such as Clear Lipid-exchanged Acrylamide-hybridized Rigid Imaging-compatible Tissue-hYdrogel (CLARITY) achieve this goal by providing a matrix that binds important biomolecules while permitting light-scattering lipids to freely diffuse out. Lipid removal, followed by refractive index matching, renders the tissue transparent and readily imaged in 3 dimensions (3D). Nevertheless, the electrophoretic tissue clearing (ETC) used in the original CLARITY protocol can be challenging to implement successfully and the use of a proprietary refraction index matching solution makes it expensive to use the technique routinely. This report demonstrates the implementation of a simple and inexpensive optical clearing protocol that combines passive CLARITY for improved tissue integrity and 2,2&#8242;-thiodiethanol (TDE), a previously described refractive index matching solution.

Visualizing the structural organization of the brain is critical for understanding how morphology and connectivity affect brain function in health and disease. Optical clearing techniques make it possible to image cell populations in 3D in intact tissues, allowing us to study morphology and connectivity cohesively.
Mice that express fluorescent proteins driven by promoters specific for sub-populations of cells permit one to teas...

Watch this Scientific Journal Video about Optical Clearing of the Mouse Central Nervous System Using Passive CLARITY at JoVE.com

Optical Clearing of the Mouse Central Nervous System Using Passive CLARITY

Optical clearing techniques are revolutionizing the way tissues are visualized. In this report we describe modifications of the original Clear Lipid-exchanged Acrylamide-hybridized Rigid Imaging-compatible Tissue-hYdrogel (CLARITY) protocol that yields more consistent and less expensive results.

Traditionally, tissue visualization has required that the tissue of interest be serially sectioned and imaged, subjecting each tissue section to unique ...

The overall goal of this protocol is to demonstrate modifications to the original CLARITY protocol, that yield more consistent and cost effective results. This method can help answer key questions in neuroscience, such as 3D morphology, and connectivity in the central nervous system. The main advantage of this technique is that it improves the consistency of optical clearing and microscopy in the mouse central nervous system.In a cost effective and reproduceable manner. Visual demonstration of this method is critical. As the imaging chamber construction is complicated and not readily obvious from written description.Obtain paraformaldehyde fixed brain and spinal cord tissue from mice expressing fluorescent proteins. Hemisect the brain by placing it in a plastic mouse brain matrix and cutting along the midline with a matrix blade. Add each hemisphere and spinal cord to separate 50 milliliter centrifuge tubes.Each containing 40 milliliters of hydrogel solution. Cover the tubes with aluminum foil to protect the fluorophores. And incubate the tubes containing samples and hydrogel at four degrees celsius with gentle shaking for seven days.Following the incubation period discard 25 milliliters of hydrogel leaving the sample and approximately 25 milliliters of hydrogel in the centrifuge tube. Next deoxygenate the sample by removing the cap, placing the centrifuge tube in a desiccator jar, and connecting the jar to a vacuum. Apply the vacuum for at least 10 minutes.Gently shake to dislodge the bubbles of emitted oxygen. After 10 minutes, replace the vacuum in the desiccator jar with 100%nitrogen gas over two to three minutes. Once the pressure equalizes and the top of the desiccator jar can be opened, quickly cap the tube to prevent the reintroduction of oxygen.Next polymerize the hydrogel by placing the tube with sample in a 37 degrees celsius water bath for three hours until polymerization is complete. After three hours the polymerized hydrogel will take on a gel like consistency. Use a spatula to remover the polymerized sample from the centrifuge tube then cut away the excess hydrogel from the sample.Lastly, remove the remaining hydrogel by placing the sample on a lint free wipe, and gently rubbing and rolling the tissue on it, leaving behind only a thin layer of polymerized hydrogel on the sample. To begin the process of lipid removal, transfer the polymerized sample to a clean 50 milliliter centrifuge tube with 45 milliliters of clearing buffer, and incubate at 45 degrees celsius with gentle shaking for seven days. Change the buffer daily during this initial seven day period by pouring off the used clearing buffer into a chemical waste container.And adding 45 milliliters of fresh clearing buffer. Once all lipids are solubilized and the tissue reaches transparency transfer the sample to a new 50 milliliter centrifuge tube filled with 45 milliliters of PBST, and wash four times at 40 degrees celsius with gentle shaking over the next 24 hours, to remove residual SDS. After the final PBST wash, transfer the sample to a clean 15 milliliter centrifuge tube filled with one microgram per milliliter DAPI and 1xPBST.Wrap with foil and incubate at room temperature for 24 hours. The next day wash three times in PBST at room temperature for at least six hours per wash. And then proceed to refractive index matching.To begin this part of the procedure, transfer the sample to a clean 15 milliliter centrifuge tube filled with 2-2 thiodiethanol and 1xPBS at PH 7.5 and incubate as shown on screen. Towards the end of the second incubation, create and imaging chamber by rolling a piece of reusable adhesive into a cylinder with uniform diameter just slightly greater than the thickness of the sample. Lay the cylinder in an open ended circle on a 40 millimeter glass bottom dish.Then use a P1000 pipette tip to create a seal between the reusable adhesive and glass by rolling it around the outer rim of the cylinder. Pipette approximately 100 microliters of 63%TDE onto the glass dish and spread it around to cover the glass surface within the circle of reusable adhesive. Then use a spatula to carefully place the sample in the middle of the circle taking care not to form bubbles.Next, pipette another 100 microliters of 63%TDE directly onto the sample, and immediately place a 40 millimeter circular cover glass over the reusable adhesive. Use the index, middle, and ring finger of both hands to carefully press around the perimeter of the circle until the cover glass makes contact with the sample. Now, slowly bring the glass bottom dish to an upright position resting against a surface, then add 63%TDE with a pipette until the solution reaches the small opening at the top.Use a lint free wipe to dry off the pipette tip so that the solution does not drip on the glass. Lastly, add silicon elastomer to the small opening to enclose the circle and create a closed chamber. Wait five minutes to dry, and then proceed to imaging.Place the imaging chamber with the sample inside on the stage of a laser scanning confocal microscope. Open the imaging software, to turn on the argon excitation laser, click the configuration tab at the top of the program, then the laser icon. Check the box next to argon to power the laser and move the slide scale to 30%Return to the acquire tab at the top.In the beam path settings box, go to the load-save setting box, and select the drop down menu to select the appropriate wavelength channel to emit YFP. In the channel settings box, select the appropriate objectives for imaging by clicking the red hyperlink labeled objective current object. Use objectives with a working distance greater than the thickness of the tissue.And a large numerical aperture to maximize the inplane image resolution, and to minimize optical section thickness. On the left column of drop down menus open the XY resolution window to set the acquisition matrix, called format to 1024x1024 or a value appropriate for the lateral resolution limit of the objective. Set the zoom factor as low as possible.1.7 is used here. In the same window set eighth line average and one frame average parameters by dropping down the individually labeled menus accordingly. Locate the sample using the stage controls.Once a representative field is visible, set the gain to between 760 to 780, and the offset to between 1.0 and 1.5 for YFP. Select tile scan. And then set the upper and lower limits of the Z stack to be acquired.Set the thickness of the optical section based on the objectives optical section resolution limit and then start the acquisition. This image shows YFP positive neurons in the cerebral cortex and hippocampus imaged as 5x magnification and reconstructed in 3D. The scale bar represents one millimeter.This maximum intensity projection of a 10x image stack of the cerebral cortex demonsrates the dendritic aborization of cortical layer five pyramidal neurons. Here the scale bar represents 100 microns. Here THY-1YFP expression is shown in an intact cervical and thoracic spinal cord, imaged at 5x magnification, and reconstructed in 3D.The scale bar represents two millimeters. Finally this maximum intensity projection of a 10x imaged stack of the spinal cord, demonstrates individual axons, scale bars represent 100 microns. If preformed properly this technique can be done in two to four weeks for whole spinal cords, and four to six weeks for hemisected brains.Following this procedure, other methods such as immunohistic chemistry can be preformed in order to answer questions that require more complex biochemical phenotyping. After watching this video you should have a good understanding of how to optically clear and image a mouse central nervous system. Using passive clarity, and laser confocal microscopy.

optical-clearing-mouse-central-nervous-system-using-passive

Research

JoVE Journal

Neuroscience

Multimodal Imaging of Stem Cell Implantation in the Central Nervous System of Mice

During the past decade, stem cell transplantation has gained increasing interest as primary or secondary therapeutic modality for a variety of diseases, both in preclinical and clinical studies. However, to date results regarding functional outcome and/or tissue regeneration following stem cell transplantation are quite diverse. Generally, a clinical benefit is observed without profound understanding of the underlying mechanism(s)1. Therefore, multiple efforts have led to the development of different molecular imaging modalities to monitor stem cell grafting with the ultimate aim to accurately evaluate survival, fate and physiology of grafted stem cells and/or their micro-environment. Changes observed in one or more parameters determined by molecular imaging might be related to the observed clinical effect. In this context, our studies focus on the combined use of bioluminescence imaging (BLI), magnetic resonance imaging (MRI) and histological analysis to evaluate stem cell grafting.
BLI is commonly used to non-invasively perform cell tracking and monitor cell survival in time following transplantation2-7, based on a biochemical reaction where cells expressing the Luciferase-reporter gene are able to emit light following interaction with its substrate (e.g. D-luciferin)8, 9. MRI on the other hand is a non-invasive technique which is clinically applicable10 and can be used to precisely locate cellular grafts with very high resolution11-15, although its sensitivity highly depends on the contrast generated after cell labeling with an MRI contrast agent. Finally, post-mortem histological analysis is the method of choice to validate research results obtained with non-invasive techniques with highest resolution and sensitivity. Moreover end-point histological analysis allows us to perform detailed phenotypic analysis of grafted cells and/or the surrounding tissue, based on the use of fluorescent reporter proteins and/or direct cell labeling with specific antibodies.
In summary, we here visually demonstrate the complementarities of BLI, MRI and histology to unravel different stem cell- and/or environment-associated characteristics following stem cell grafting in the CNS of mice. As an example, bone marrow-derived stromal cells, genetically engineered to express the enhanced Green Fluorescent Protein (eGFP) and firefly Luciferase (fLuc), and labeled with blue fluorescent micron-sized iron oxide particles (MPIOs), will be grafted in the CNS of immune-competent mice and outcome will be monitored by BLI, MRI and histology (Figure 1).

This article describes an optimized sequence of events for multimodal imaging of cellular grafts in rodent brain using: (i) in vivo bioluminescence and magnetic resonance imaging, and (ii) post mortem histological analysis. Combining these imaging modalities on a single animal allows cellular graft evaluation with high resolution, sensitivity and specificity.

During the past decade, stem cell transplantation has gained increasing interest as primary or secondary therapeutic modality for a variety of diseases, ...

Production of Lentiviral Vectors for Transducing Cells from the Central Nervous System

Efficient gene delivery in the central nervous system (CNS) is important in studying gene functions, modeling neurological diseases and developing therapeutic approaches. Lentiviral vectors are attractive tools in transduction of neurons and other cell types in CNS as they transduce both dividing and non-dividing cells, support sustained expression of transgenes, and have relatively large packaging capacity and low toxicity 1-3. Lentiviral vectors have been successfully used in transducing many neural cell types in vitro 4-6 and in animals 7-10.
Great efforts have been made to develop lentiviral vectors with improved biosafety and efficiency for gene delivery. The current third generation replication-defective and self-inactivating (SIN) lentiviral vectors are depicted in Figure 1. The required elements for vector packaging are split into four plasmids. In the lentiviral transfer plasmid, the U3 region in the 5' long terminal repeat (LTR) is replaced with a strong promoter from another virus. This modification allows the transcription of the vector sequence independent of HIV-1 Tat protein that is normally required for HIV gene expression 11. The packaging signal (&Psi;) is essential for encapsidation and the Rev-responsive element (RRE) is required for producing high titer vectors. The central polypurine tract (cPPT) is important for nuclear import of the vector DNA, a feature required for transducing non-dividing cells 12. In the 3' LTR, the cis-regulatory sequences are completely removed from the U3 region. This deletion is copied to 5' LTR after reverse transcription, resulting in transcriptional inactivation of both LTRs. Plasmid pMDLg/pRRE contains HIV-1 gag/pol genes, which provide structural proteins and reverse transcriptase. pRSV-Rev encodes Rev which binds to the RRE for efficient RNA export from the nucleus. pCMV-G encodes the vesicular stomatitis virus glycoprotein (VSV-G) that replaces HIV-1 Env. VSV-G expands the tropism of the vectors and allows concentration via ultracentrifugation 13. All the genes encoding the accessory proteins, including Vif, Vpr, Vpu, and Nef are excluded in the packaging system. The production and manipulation of lentiviral vectors should be carried out according to NIH guidelines for research involving recombinant DNA (<a href="http://oba.od.nih.gov/oba/rac/Guidelines/NIH_Guidelines.pdf" target="_blank">http://oba.od.nih.gov/oba/rac/Guidelines/NIH_Guidelines.pdf</a>). An approval from individual Institutional Biological and Chemical Safety Committee may be required before using lentiviral vectors. Lentiviral vectors are commonly produced by cotransfection of 293T cells with lentiviral transfer plasmid and the helper plasmids encoding the proteins required for vector packaging. Many lentiviral transfer plasmids and helper plasmids can be obtained from Addgene, a non-profit plasmid repository (<a href="http://www.addgene.org/" target="_blank">http://www.addgene.org/</a>). Some stable packaging cell lines have been developed, but these systems provide less flexibility and their packaging efficiency generally declines over time 14, 15. Commercially available transfection kits may support high efficiency of transfection 16, but they can be very expensive for large scale vector preparations. Calcium phosphate precipitation methods provide highly efficient transfection of 293T cells and thus provide a reliable and cost effective approach for lentiviral vector production.
In this protocol, we produce lentiviral vectors by cotransfection of 293T cells with four plasmids based on the calcium phosphate precipitation principle, followed by purification and concentration with ultracentrifugation through a 20% sucrose cushion. The vector titers are determined by fluorescence- activated cell sorting (FACS) analysis or by real time qPCR. The production and titration of lentiviral vectors in this protocol can be finished with 9 days. We provide an example of transducing these vectors into murine neocortical cultures containing both neurons and astrocytes. We demonstrate that lentiviral vectors support high efficiency of transduction and cell type-specific gene expression in primary cultured cells from CNS.

In this protocol we describe production, purification and titration of lentiviral vectors. We provide an example of lentiviral vector-mediated gene delivery in primary cultured neurons and astrocytes. Our methods may also apply to other cell types in vitro and in vivo.

Efficient gene delivery in the central nervous system (CNS) is important in studying gene functions, modeling neurological diseases and developing ...

Labeling of Single Cells in the Central Nervous System of Drosophila melanogaster

In this article we describe how to individually label neurons in the embryonic CNS of Drosophila melanogaster by juxtacellular injection of the lipophilic fluorescent membrane marker DiI. This method allows the visualization of neuronal cell morphology in great detail. It is possible to label any cell in the CNS: cell bodies of target neurons are visualized under DIC optics or by expression of a fluorescent genetic marker such as GFP. After labeling, the DiI can be transformed into a permanent brown stain by photoconversion to allow visualization of cell morphology with transmitted light and DIC optics. Alternatively, the DiI-labeled cells can be observed directly with confocal microscopy, enabling genetically introduced fluorescent reporter proteins to be colocalised. The technique can be used in any animal, irrespective of genotype, making it possible to analyze mutant phenotypes at single cell resolution.

Labeling of Single Cells in the Central Nervous System of Drosophila melanogaster

We present a technique for labeling single neurons in the central nervous system (CNS) of Drosophila embryos, which allows the analysis of neuronal morphology by either transmitted light or confocal microscopy.

In this  article we describe how to individually label neurons in the embryonic CNS of Drosophila melanogaster by juxtacellular injection of the ...

Direct Intraventricular Delivery of Drugs to the Rodent Central Nervous System

Due to an inability to cross the blood brain barrier, certain drugs need to be directly delivered into the central nervous system (CNS). Our lab focuses specifically on antisense oligonucleotides (ASOs), though the techniques shown in the video here can also be used to deliver a plethora of other drugs to the CNS. Antisense oligonucleotides (ASOs) have the capability to knockdown sequence-specific targets 1 as well as shift isoform ratios of specific genes 2. To achieve widespread gene knockdown or splicing in the CNS of mice, the ASOs can be delivered into the brain using two separate routes of administration, both of which we demonstrate in the video.
The first uses Alzet osmotic pumps, connected to a catheter that is surgically implanted into the lateral ventricle. This allows the ASOs to be continuously infused into the CNS for a designated period of time. The second involves a single bolus injection of a high concentration of ASO into the right lateral ventricle. Both methods use the mouse cerebral ventricular system to deliver the ASO to the entire brain and spinal cord, though depending on the needs of the study, one method may be preferred over the other.

We describe a method to target drugs to the central nervous system by either implanting a catheter or performing a bolus injection into the right lateral ventricle in mice. We focus specifically on the delivery of antisense oligonucleotides. This technique is readily adaptable to other drugs and to rats.

Due to an inability to cross the blood brain barrier, certain drugs need to be directly delivered into the central nervous system (CNS). Our lab focuses ...

In vivo Interrogation of Central Nervous System Translatome by Polyribosome Fractionation

Multiple processes are involved in gene expression including transcription, translation and stability of mRNAs and proteins. Each of these steps are tightly regulated, affecting the final dynamics of protein abundance. Various regulatory mechanisms exist at the translation step, rendering mRNA levels alone an unreliable indicator of gene expression. In addition, local regulation of mRNA translation has been particularly implicated in neuronal functions, shifting &#39;translatomics&#39; to the focus of attention in neurobiology. The presented method can be used to bridge transcriptomics and proteomics.
Here we describe essential modifications to the technique of polyribosome fractionation, which interrogates the translatome based on the association of actively translated mRNAs to multiple ribosomes and their differential sedimentation in sucrose gradients. Traditionally, working with in vivo samples, particularly of the central nervous system (CNS), has proven challenging due to the restricted amounts of material and the presence of fatty tissue components. In order to address this, the described protocol is specifically optimized for use with minimal amount of CNS material, as demonstrated by the use of single mouse spinal cord and brain. Briefly, CNS tissues are extracted and translating ribosomes are immobilized on mRNAs with cycloheximide. Myelin flotation is then performed to remove lipid rich components. Fractionation is performed on a sucrose gradient where mRNAs are separated according to their ribosomal loading. Isolated fractions are suitable for a range of downstream assays, including new genome wide assay technologies.

In vivo Interrogation of Central Nervous System Translatome by Polyribosome Fractionation

This protocol illustrates essential modifications of polyribosome fractionation in order to study the translatome of in vivo CNS samples. It allows global assessment of translation and transcription regulation through the isolation and comparison of total RNA to ribosome bound RNA fractions.

Multiple processes are involved in gene expression including transcription, translation and stability of mRNAs and proteins. Each of these steps are ...

In vivo Optogenetic Stimulation of the Rodent Central Nervous System

The ability to probe defined neural circuits in awake, freely-moving animals with cell-type specificity, spatial precision, and high temporal resolution has been a long sought tool for neuroscientists in the systems-level search for the neural circuitry governing complex behavioral states. Optogenetics is a cutting-edge tool that is revolutionizing the field of neuroscience and represents one of the first systematic approaches to enable causal testing regarding the relation between neural signaling events and behavior. By combining optical and genetic approaches, neural signaling can be bi-directionally controlled through expression of light-sensitive ion channels (opsins) in mammalian cells. The current protocol describes delivery of specific wavelengths of light to opsin-expressing cells in deep brain structures of awake, freely-moving rodents for neural circuit modulation. Theoretical principles of light transmission as an experimental consideration are discussed in the context of performing in vivo optogenetic stimulation. The protocol details the design and construction of both simple and complex laser configurations and describes tethering strategies to permit simultaneous stimulation of multiple animals for high-throughput behavioral testing.

In vivo Optogenetic Stimulation of the Rodent Central Nervous System

Optogenetics has become a powerful tool for use in behavioral neuroscience experiments. This protocol offers a step-by-step guide to the design and set-up of laser systems, and provides a full protocol for carrying out multiple and simultaneous in vivo optogenetic stimulations compatible with most rodent behavioral testing paradigms.

The ability to probe defined neural circuits in awake, freely-moving animals with cell-type specificity, spatial precision, and high temporal resolution ...

Novel Passive Clearing Methods for the Rapid Production of Optical Transparency in Whole CNS Tissue

Since the development of CLARITY, a bioelectrochemical clearing technique that allows for three-dimensional phenotype mapping within transparent tissues, a multitude of novel clearing methodologies including CUBIC (clear, unobstructed brain imaging cocktails and computational analysis), SWITCH (system-wide control of interaction time and kinetics of chemicals), MAP (magnified analysis of the proteome), and PACT (passive clarity technique), have been established to further expand the existing toolkit for the microscopic analysis of biological tissues. The present study aims to improve upon and optimize the original PACT procedure for an array of intact rodent tissues, including the whole central nervous system (CNS), kidneys, spleen, and whole mouse embryos. Termed psPACT (process-separate PACT) and mPACT (modified PACT), these novel techniques provide highly efficacious means of mapping cell circuitry and visualizing subcellular structures in intact normal and pathological tissues. In the following protocol, we provide a detailed, step-by-step outline on how to achieve maximal tissue clearance with minimal invasion of their structural integrity via psPACT and mPACT.

Here, we present two novel methodologies, psPACT and mPACT, for achieving maximal optical transparency and subsequent microscopic analysis of tissue vasculature in the intact rodent whole CNS.

Since the development of CLARITY, a bioelectrochemical clearing technique that allows for three-dimensional phenotype mapping within transparent tissues, ...

Electrophysiological Recording of The Central Nervous System Activity of Third-Instar Drosophila Melanogaster

The majority of the currently available insecticides target the nervous system and genetic mutations of invertebrate neural proteins oftentimes yield deleterious consequences, yet the current methods for recording nervous system activity of an individual animal is costly and laborious. This suction electrode preparation of the third-instar larval central nervous system of Drosophila melanogaster, is a tractable system for testing the physiological effects of neuroactive agents, determining the physiological role of various neural pathways to CNS activity, as well as the influence of genetic mutations to neural function. This ex vivo preparation requires only moderate dissecting skill and electrophysiological expertise to generate reproducible recordings of insect neuronal activity. A wide variety of chemical modulators, including peptides, can then be applied directly to the nervous system in solution with the physiological saline to measure the influence on the CNS activity. Further, genetic technologies, such as the GAL4/UAS system, can be applied independently or in tandem with pharmacological agents to determine the role of specific ion channels, transporters, or receptors to arthropod CNS function. In this context, the assays described herein are of significant interest to insecticide toxicologists, insect physiologists, and developmental biologists for which D. melanogaster is an established model organism. The goal of this protocol is to describe an electrophysiological method to enable the measurement of electrogenesis of the central nervous system in the model insect, Drosophila melanogaster, which is useful for testing a diversity of scientific hypotheses.

Electrophysiological Recording of The Central Nervous System Activity of Third-Instar  Drosophila Melanogaster

This protocol describes a method to record the descending electrical activity of the Drosophila melanogaster central nervous system to enable the cost-efficient and convenient testing of pharmacological agents, genetic mutations of neural proteins, and/or the role of unexplored physiological pathways.

The majority of the currently available insecticides target the nervous system and genetic mutations of invertebrate neural proteins oftentimes yield ...

Transplantation of Chemogenetically Engineered Cortical Interneuron Progenitors into Early Postnatal Mouse Brains

Neuronal development is regulated by a complex combination of environmental and genetic factors. Assessing the relative contribution of each component is a complicated task, which is particularly difficult in regards to the development of &#947;-aminobutyric acid (GABA)ergic cortical interneurons (CIs). CIs are the main inhibitory neurons in the cerebral cortex, and they play key roles in neuronal networks, by regulating both the activity of individual pyramidal neurons, as well as the oscillatory behavior of neuronal ensembles. They are generated in transient embryonic structures (medial and caudal ganglionic eminences -&#160;MGE and CGE) that are very difficult to efficiently target using in utero electroporation approaches. Interneuron progenitors migrate long distances during normal embryonic development, before they integrate in the cortical circuit. This remarkable ability to disperse and integrate into a developing network can be hijacked by transplanting embryonic interneuron precursors into early post-natal host cortices. Here, we present a protocol that allows genetic modification of embryonic interneuron progenitors using focal ex vivo electroporation. These engineered interneuron precursors are then transplanted into early post-natal host cortices, where they will mature into easily identifiable CIs. This protocol allows the use of multiple genetically encoded tools, or the ability to regulate the expression of specific genes in interneuron progenitors, in order to investigate the impact of either genetic or environmental variables on the maturation and integration of CIs.

Here we present a protocol, designed to use chemogenetic tools to manipulate the activity of cortical interneuron progenitors transplanted into the cortex of early postnatal mice.

Neuronal development is regulated by a complex combination of environmental and genetic factors. Assessing the relative contribution of each component is ...

Intrathecal Delivery of Antisense Oligonucleotides in the Rat Central Nervous System

The blood brain barrier (BBB) is an important defense against the entrance of potentially toxic or pathogenic agents from the blood into the central nervous system (CNS). However, its existence also dramatically lowers the accessibility of systemically administered therapeutic agents to the CNS. One method to overcome this, is to inject those agents directly into the cerebrospinal fluid (CSF), thus bypassing the BBB. This can be done via implantation of a catheter for either continuous infusion using an osmotic pump, or for single bolus delivery. In this article, we describe a surgical protocol for delivery of CNS-targeting antisense oligonucleotides (ASOs) via a catheter implanted directly into the cauda equina space of the adult rat spine. As representative results, we show the efficacy of a single bolus ASO intrathecal (IT) injection via this catheterization system in knocking down the target RNA in different regions of the rat CNS. The procedure is safe, effective and does not require expensive equipment or surgical tools. The technique described here can be adapted to deliver drugs in other modalities as well.

Here, we describe a method for delivering drugs to the rat central nervous system by implanting a catheter into the lumbar intrathecal space of the spine. We focus on the delivery of antisense oligonucleotides, though this method is suitable for delivery of other therapeutic modalities as well.

The blood brain barrier (BBB) is an important defense against the entrance of potentially toxic or pathogenic agents from the blood into the central ...