Quadruple Immunostaining of the Olfactory Bulb for Visualization of Olfactory Sensory Axon Molecular Identity Codes

Podsumowanie

Olfactory sensory neurons express a wide variety of axon-sorting molecules to establish proper neural circuitry. This protocol describes an immunohistochemical staining method to visualize combinatorial expressions of axon-sorting molecules at the axon termini of olfactory sensory neurons.

Streszczenie

The mouse olfactory system is often used to study mechanisms of neural circuit formation　because of its simple anatomical structure. An Olfactory Sensory Neuron (OSN) is a bipolar cell with a single dendrite and a single unbranched axon. An OSN expresses only one Olfactory Receptor (OR) gene, OSNs expressing a given type of OR converge their axons to a few sets of invariant glomeruli in the Olfactory Bulb (OB). A remarkable feature of OSN projection is that the expressed ORs play instructive roles in axonal projection. ORs regulate the expression of multiple axon-sorting molecules and generate the combinatorial molecular code of axon-sorting molecules at the OSN axon termini. Thus, to understand the molecular mechanisms of OR-specific axon guidance mechanisms, it is vital to characterize their expression profiles at the OSN axon termini within the same glomerulus. The aim of this article was to introduce methods for collecting as many glomeruli as possible on a single OB section and for performing immunostaining using multiple antibodies. This would allow the comparison and analysis of the expression patterns of axon-sorting molecules without staining variation between OB sections.

Wprowadzenie

During development, neurons are precisely connected with each other to form proper neural circuits, which is critical for the normal brain function. Since aberrant neural circuits in the brain are thought to be the cause of mental disorders such as autism and schizophrenia, understanding the mechanisms of neural circuit formation is one of the major challenges in the field of neuroscience.

In the mouse olfactory system, each Olfactory Sensory Neuron (OSN) in the Olfactory Epithelium (OE) expresses only one functional Olfactory Receptor (OR) gene and OSNs expressing the same OR converge their axons to a specific pair of glomeruli at stereotyped locations in the Olfactory Bulb (OB)^1,2. The mouse olfactory system is an excellent model system for studying the molecular mechanisms of neural circuit formation because researchers can utilize the OR expression to identify a specific subtype of OSNs and visualize the projection sites of OSN axons as clear glomerular structures. A remarkable feature of OSN projection is that ORs play instructive roles in projecting OSN axons to the OB^3,4,5,6. More specifically, after OSN axons are guided to approximate target regions, they are segregated to form glomerulus in an OR-dependent manner. Previous studies have shown that OR molecules control the expression of axon-sorting molecules, which regulate glomerular segregation^7,8. Moreover, accumulating evidence suggests that OR molecules generate the neuronal identity code by a unique combination of axon-sorting molecules⁹. Thus, to understand the mechanism of OR-dependent glomerular segregation, it is necessary to characterize the expression profiles of axon-sorting molecules in OSNs.

Fluorescent immunostaining is a common method to visualize the expression of specific genes. Since proteins of axon-sorting molecules are predominantly localized to OSN axons, researchers need to use OB sections to characterize their expression patterns in OSNs. Coronal sectioning of the OB has been routinely used for immunostaining. However, this preparation loses the topographic information along the anterior-posterior axis in the same OB section. We therefore developed a parasagittal preparation of the medial side of the OB, which can mount as many surrounding glomeruli as possible on the same OB section. Combined with immunostaining using multiple antibodies, this preparation allows the comparison and analysis of the expression patterns of axon-sorting molecules without staining variation between OB sections.

Furthermore, an immunohistochemical staining method has been presented without post-fixation with PFA and sucrose treatment. This method allows researchers to obtain enough high-quality staining data for multivariable data analysis. The protocols presented here will provide details of powerful methods for researchers who study the olfactory neural circuit formation.

Protokół

All experimental procedures were performed with the approval of the animal experiment ethics committee at the University of Tokyo and according to the University of Tokyo guidelines for the care and use of laboratory animals.

1. Preparation of Solutions

1. Prepare 0.01 M Phosphate-Buffered Saline (PBS): add a PBS tablet (0.14 M NaCl, 0.0027 M KCl, 0.010 M PO₄^3-, pH 7.4) to 1 L distilled water and stir at RT until it is completely dissolved.
2. Prepare 4% paraformaldehyde (PFA) in PBS: add 4 g of PFA to 100 mL PBS. Stir the solution at 60 °C until it is completely dissolved.
   1. After dissolving the PFA in PBS, adjust the pH of the solution to 7.4 with 1 N sodium hydroxide (NaOH). Then, cool on ice and filter the solution through a filter paper to remove any particulate matter. Store at 4 °C.
      Caution: Take appropriate care when using these reagents. Handle with care and use gloves, safety goggles, and lab coat under a chemical hood.
      NOTE: Use fresh 4% PFA solution prepared within 2 d.
3. Prepare 0.01 M PBS supplemented with 0.3% Triton X-100 (PBST): add 3 mL of Triton X- 100 to 997 mL of PBS. Stir the solution at RT until it is completely dissolved.
4. Prepare 1% and 5% blocking solution: add 10 g of skim milk to 200 mL PBST to prepare 5% blocking solution. Stir at RT until it is completely dissolved. Dilute 5% blocking solution five times with PBST to prepare 1% blocking solution.

2. Preparation of Parasagittal OB Sections

1. Use animals between 1-2 weeks of age. These age groups are suitable for the following experiments because glomeruli are clearly visible and the brain can be cut with the skull.
2. Anesthetize the animal with an intraperitoneal injection of pentobarbital (50 mg/kg body weight). Perfuse the animal transcardially with ice-cold 4% PFA in PBS. Handle with care and use gloves, safety goggles, and lab coat under a chemical hood.
3. After perfusion, cut off the head with scissors and remove the skin carefully. Then, insert a blade of the scissors into the space between the upper and lower teeth and cut horizontally to remove the lower jawbone. Trim away excess tissue with forceps and scissors to leave the olfactory tissue including the OB and OE.
   NOTE: Do not remove the skull surrounding the OB as this retains the medial glomeruli aligned vertically straight.
4. Immerse the olfactory tissue in PBS to remove the air in the nasal cavity. Cut off the posterior part of the brain vertically and place the olfactory tissue on the bottom of the embedding mold with the cutting face down. Fill the mold with Optimal Cutting Temperature (O.C.T.) compound and then immerse the mold into liquid nitrogen.
   1. After the tissue in the compound is completely frozen, incubate it in the cryostat at -20 °C for 1 h.
5. Make serial parasagittal sections (10 µm) of the OB with a cryostat and collect them by sticking to MAS-coated glass slides. After sticking, dry the slides immediately with a blow dryer.

3. Day 1: Quadruple Immunostaining of the OB Slices 

1. Wash the slides for 5 min with PBS at RT. Repeat 3 times.
2. Block the nonspecific binding sites by incubating the slides for 1 h with the 5% blocking solution at RT.
3. Incubate the slides O/N with a cocktail of primary antibodies (400 µL each slide) in the 1% blocking solution at RT. Use the following primary antibodies: guinea pig anti-Kirrel2 antibody (1:1000), goat anti-Semaphorin-7A (Sema7A) antibody (1:500), rat anti-OL-protocadherin (OLPC) antibody (1:500), and mouse anti-vesicular glutamate transporter2 (VGLUT2) antibody (1:500).

4. Day 2: Quadruple Immunostaining of the OB Slices 

1. Discard the primary antibody solution and wash the slides for 5 min with PBST at RT. Repeat 3 times.
2. Incubate the slides for 1 h with a cocktail of secondary antibodies (400 µL each slide) in PBS at RT. Use the following secondary antibodies: donkey anti-mouse Alexa Fluor 405 (1:400), donkey anti-goat Alexa Fluor 488 (1:400), donkey anti-guinea pig Alexa Fluor 555 (1:400), and donkey anti-rat Alexa Fluor 647 (1:400).
   NOTE: All secondary antibodies should come from the same host species. Choose a different wavelength of fluorescence of secondary antibodies for each primary antibody to ensure no overlap of wavelengths.
3. Discard the solution and wash the slides for 5 min with PBS at RT. Repeat 3 times.
4. Mount coverslips on the slides with the mounting medium. For this, apply 2 drops of the mounting medium on each slide, and then, put a coverslip by removing the air bubbles.

5. Intensity Measurements

1. Obtain fluorescent images with a fluorescence microscope. Use the following filter cubes: DAPI filter cube (360/40 nm excitation, 460/50 nm emission, and 400 nm dichroic mirror) for Alexa Fluor 405 signals, GFP filter cube (470/40 nm excitation, 525/50 nm emission, and 495 nm dichroic mirror) for Alexa Fluor 488, TRITC filter cube (545/25 nm excitation, 605/70 nm emission, and 565 nm dichroic mirror) for Alexa Fluor 555, and Cy5 filter cube (620/60 nm excitation, 700/75 nm emission, and 600 nm dichroic mirror) for Alexa Fluor 647.
   Note: Adjust the exposure time to obtain fluorescent signals of the image without saturation.
2. Define the glomerular structure by immunofluorescence signals of VGLUT2. Measure staining intensities of axon-sorting molecules within glomeruli with ImageJ.

6. Data Analysis

1. Subtract background signals from the staining intensities of axon-sorting molecules.
2. Prepare the expression data matrix, which has columns composed of axon-sorting molecules and rows composed of the glomeruli.
3. Perform a principal component analysis (PCA) using the prepared expression dataset. Then, obtain the PCA scores, contribution ratios, and factor loadings of each principal component.

Wyniki

The olfactory glomerular map is formed by initial global targeting and subsequent glomerular segregation of OSN axons^1,2. Glomerular segregation is regulated by the adhesive/repulsive axonal interactions mediated by axon-sorting molecules whose expression levels are determined by expressed OR molecules⁷. The axon-sorting molecules involved in glomerular segregation are expressed in a position-independent mo...

Dyskusje

Quadruple immunostaining of parasagittal OB sections enabled the visualization and quantification of the expression levels of as many as four axon-sorting molecules simultaneously in a larger number of glomeruli. By analyzing these multivariable data with PCA, the characteristics for the expression of those molecules can be speculated.

For successful staining, the tissue sample preparation is critically important. Some protocols suggest that tissues should be post-fixed with 4% PFA and treated...

Materiały

Name	Company	Catalog Number	Comments
Phosphate-Buffered Saline (PBS) Tablets, pH7.4	TAKARA BIO	T9181
Skim Milk	nacalai tesque	31149-75
goat anti-Sema7A antibody	R&D Systems	AF2068
rat anti-OLPC antibody	Merck Millipore	MABT20
mouse anti-VGLUT2 antibody	Merck Millipore	MAB5504
goat anti-BIG-2 antibody	R&D Systems	AF2205
gunea pig anti-Kirrel2 antibody	Operon Biotechnologies		Anti-Kirrel2 antibodies were generated by immunizing guinea pigs with KLH-conjugated synthetic peptides (644-673aa): CRLYRARAGYLTTPHPRAFTSYMKPTSFGP
donkey anti-mouse Alexa Fluor 405	Abcam	ab175658
donkey anti-goat Alexa Fluor 488	Jackson ImmunoResearch	705-545-003
donkey anti-guinea pig Alexa Fluor 555	Thermo Fisher Scientific	A21432
donkey anti-rat Alexa Fluor 647	Jackson ImmunoResearch	712-605-153
Paraformaldehyde (PFA)	Wako	162-16065
MAS coated slide glasses	MATSUNAMI	MAS-01
forceps	Fine Science Tools	11253-27
Vannas Spring Scissors	Fine Science Tools	15000-00
dissecting scissors	Fine Science Tools	14090-09
fluorescent microscope	KEYENCE	BZ-X700
DAPI filter cube	KEYENCE	OP-87762
GFP filter cube	KEYENCE	OP-87763
TRITC filter cube	KEYENCE	OP-87764
Cy5 filter cube	KEYENCE	OP-87766
filter paper	ADVANTEC	00011185
O.C.T compound	Sakura Finetek	M71484