Tyramide signal amplification (TSA) is a highly sensitive method for histochemical analysis. Previously, we reported a TSA system, biotinyl tyramine-glucose oxidase (BT-GO), for bright-filed imaging. Here, we develop fluorochromized tyramide-glucose oxidase (FT-GO) as a multiplex fluorescent TSA system. FT-GO involves peroxidase-catalyzed deposition of fluorochromized tyramide (FT) with hydrogen peroxide produced by enzymatic reaction between glucose and glucose oxidase. We showed that FT-GO enhanced immunofluorescence signals while maintaining low background signals. Compared with indirect immunofluorescence detections, FT-GO demonstrated a more widespread distribution of monoaminergic projection systems in mouse and marmoset brains. For multiplex labeling with FT-GO, we quenched antibody-conjugated peroxidase using sodium azide. We applied FT-GO to multiplex fluorescent in situ hybridization, and succeeded in labeling neocortical interneuron subtypes by coupling with immunofluorescence. FT-GO immunofluorescence further increased the detectability of an adeno-associated virus tracer. Given its simplicity and a staining with a high signal-to-noise ratio, FT-GO would provide a versatile platform for histochemical analysis.
Tyramide signal amplification (TSA), also called catalyzed reporter deposition (CARD), is a highly sensitive enzymatic method that enables the detection of low-abundance targets in histochemical analysis. TSA utilizes the catalytic activity of peroxidase (POD) to yield high-density labeling of targets in situ1,2. POD reacting with hydrogen peroxide (H2O2) catalyzes oxidative condensation of tyramide to produce highly reactive intermediates, tyramide radicals. The activated tyramide covalently binds to electron-rich moieties such as tyrosine, phenylalanine and tryptophan at or near the POD. The short half-life of the tyramide radicals restricts the deposition of tyramide3.
TSA was originally introduced for the detection of immunosorbent and immunoblotting assays more than thirty years ago1. Soon after its introduction, TSA was adapted to immunohistochemistry (IHC), lectin histochemistry and neuroanatomical tract tracing methods by Adams4. TSA has been further implemented in detection procedures for DNA and RNA in situ hybridization (ISH) histochemistry5,6,7 and electron microscopy8,9. Given its simplicity, high sensitivity, high specificity and broad applicability, TSA has become an essential tool for histochemical analysis.
Previously, we reported a straightforward and cost-effective TSA system, biotinyl tyramine-glucose oxidase (BT-GO), for bright-filed imaging10,11. Unlike conventional TSA systems, where H2O2 is added directly to their reaction mixtures4,5,6,7,12, BT-GO utilizes H2O2 produced by oxidation of glucose by glucose oxidase to deposit BT onto tissues13. H2O2 is thermodynamically unstable and readily decomposes to oxygen and water in light, heat or in the presence of metal ions. Enzymatic reaction between glucose and glucose oxidase supplies the compound stably during BT-GO reaction, improving operational stability of the TSA system. BT-GO provides a substantial increase in sensitivity; we10,11 and others14,15 have applied BT-GO to chromogenic IHC including axonal projection analysis. BT-GO has been further adapted for an mRNA fluorescence ISH (FISH) technique by coupling with fluorochrome-conjugated streptavidin16,17,18. Although haptenized tyramides including BT are invaluable reagents for TSA, fluorochromized tyramide (FT) can be visualized directly by fluorescent microscopy without additional staining with avidin or antibodies (Abs) against haptens, which potentially induce background signals. FT further permits multiplex histochemical labeling that allows for simultaneous detection of multiple targets within a single specimen, enabling analysis of spatial organization of the target molecules in the context of the tissue architecture.
Here, we developed FT-GO (Fluorochromized Tyramide-Glucose Oxidase) as a multiplex fluorescent TSA system. FT-GO involves POD-catalyzed deposition of fluorochromized tyramide (FT) with H2O2 produced during oxidation of glucose by glucose oxidase, as with BT-GO. We adapted FT-GO to immunofluorescence (IF), multiplex IF, multiplex mRNA FISH histochemistry and neuroanatomical tract tracing with an adeno-associated virus (AAV) tracer. FT-GO provided strong labeling with a high signal-to-noise ratio in each application.
Signal enhancement in IF with FT-GO
FT-GO is a fluorescent TSA system that utilizes H2O2 produced during oxidation of glucose by glucose oxidase to deposit FT onto tissues (Fig. 1). H2O2 is thermodynamically unstable and decomposes to form water and oxygen, compromising operational stability of TSA systems. In the FT-GO signal amplification, enzymatic reaction between glucose and glucose oxidase exerts stable supply of the thermodynamically unstable compound. The phenolic part of FT and H2O2 react with POD to produce highly reactive intermediates, tyramide radicals, which in turn bind to electron-rich moieties such as tyrosine residue in a covalent manner in the vicinity of POD.
We first examined signal amplification characteristics of FT-GO in IF for a neuronal marker, Rbfox3 (also known as neuronal nuclei [NeuN]). Using direct, indirect and FT-GO IF methods, we stained layer 2/3 neurons in the mouse primary somatosensory cortex (S1) with an Ab against Rbfox3 (clone A6019). Brain sections containing the S1 were reacted with the Ab serially diluted tenfold from 1:100 to 1:100, 000 (Fig. 2). Fluorescence signals amplified with FT-GO were much stronger than those detected with the direct and indirect IF detections at any concentrations tested (Fig. 2a–l). Quantitative analysis showed that FT-GO yielded 64.4 to 183.4 fold and 9.7 to 34.1 fold signal amplification compared with the direct and indirect IF detection, respectively (Fig. 2m). The fluorescence signals obtained by FT-GO were less affected by Ab dilution: the ratio of maximum to minimum mean signal intensity in the serial dilution experiments was 3.1, 3.9 and 1.1 for the direct, indirect and FT-GO IF detections.
Monoaminergic fibers, such as catecholaminergic (CA) and serotonergic (5-HT) fibers, are highly ramified into fine varicose axonal processes in their projection areas20,21, hampering high-fidelity visualization of the projection systems. We used FT-GO signal amplification to visualize the fine axonal morphology of monoaminergic fibers. Tyrosine hydroxylase (TH) and serotonin transporter (Slc6a4) were chosen as makers for CA and 5-HT fibers. Compared with an indirect IF detection, FT-GO showed a more diffuse and widespread distribution of TH-immunoreactivity (IR) throughout the brain, in addition to the dense and localized IR in brain regions such as the caudate-putamen (CPu), amygdala and hypothalamus (Fig. 3a,e). At high magnification, FT-GO demonstrated fine axonal morphology of TH-positive fibers in the cerebral cortex, hippocampus and thalamus, where TH-positive fibers diffusely innervated (Fig. 3f–h). In contrast, TH-positive fibers were only faintly labeled in these brain regions using the indirect detection (Fig. 3b–d). FT-GO also provided dramatically increased sensitivity in Slc6a4 IF: while FT-GO visualized a diffuse and widespread projection of Slc6a4-positive fibers throughout the brain, only faintly labeled fibers were observed in indirect IFs under the same imaging condition (Supplementary Fig. S1a,b). FT-GO further succeeded in visualizing 5-HT axons at single fiber resolution in brain regions including the cerebral cortex, hippocampus and thalamus (Supplementary Fig. S1c–e). Importantly, in the IF assay, we used five times lower concentration of the primary Ab in the FT-GO detection in comparison with the indirect detection.
We then explored the applicability and scalability of FT-GO signal amplification to large-brained animals. The common marmoset (Callithrix jacchus) is becoming increasingly popular as a non-human primate model for neuroscience research22,23. We adapted FT-GO to IF microscopy experiments with an Ab against TH in the marmoset brain. FT-GO again provided an increase in sensitivity in brain sections of marmosets, compared with an indirect IF detection (Fig. 4). While dense and localized IF signals for TH were detected in brain regions such as the caudate nucleus, putamen and hypothalamus in FT-GO IFs, only weak signals were obtained by the indirect IF under the same imaging condition (Fig. 4a,b). Additionally, FT-GO showed diffused IRs for TH in brain regions such as the cerebral cortex, thalamus and hippocampus (Fig. 4b). High power views revealed individual TH-positive fibers in these brain regions (Fig. 4c–e). We further found cell bodies frequently labeled for TH by FT-GO IF in the cerebral cortex (Fig. 4c), which have not been described in the marmoset.
Multiplex IF and mRNA FISH histochemistry with FT-GO
Simultaneous detection of multiple distinct targets within a single tissue section allows for analyzing spatial organization of the targets in the context of the tissue architecture. For adaptation of multiplex labeling with FT-GO, Ab-conjugated POD must be inactivated prior to subsequent detection rounds. A number of methods have been described for quenching POD activity, including incubation with H2O2, low pH buffer, and NaN3. Heat-mediated removal of primary/secondary Ab-POD complex has been implemented to TSA-based multiplex IF24,25. Of these, we choose NaN3 for quenching POD activity because of its less deleterious effects on antigenicity, antigen–antibody binding, hybridized strands and tissue integrity. We first asked whether NaN3 was effective at quenching Ab-conjugated POD in FT-GO. For this, we carried out two rounds of FT-GO with different color FT sequentially in IF for Rbfox3. Between the first and second round, brain sections were treated with high concentration of NaN3 [2% (w/v)] or phosphate buffered saline (PBS). Ineffective quenching of Ab-conjugated POD should result in deposit of the FT used in the second round of FT-GO due to residual activity of POD. We found effective inactivation of Ab-conjugated POD with NaN3: while fluorescence signals from the second round of FT-GO were detected in almost all cells labeled by the first round of FT-GO in PBS-treated brain sections (Supplementary Fig. S2a–c), these signals were completely vanished by incubation with NaN3 (Supplementary Fig. S2d–f). We then conducted multiplex IF with FT-GO. Mouse hippocampal sections were reacted with Abs against Rbfox3, an astrocytic marker, glial fibrillary acidic protein (Gfap) and a microglial marker, allograft inflammatory factor 1 (Aif1) (also known as ionized calcium binding adaptor molecule 1 [Iba1]), and these Abs were multiply detected with FT-GO. Specific distribution and no obvious colocalization of Rbfox3, Gfap and Aif1 IRs in the mouse hippocampal region demonstrated multiplex detection with FT-GO (Fig. 5a–i). FT-GO IF for Rbfox3 clearly showed pyramidal cell layers of cornu ammonis regions and granule cell layers of the dentate gyrus (DG) (Fig. 5a,d,h). FT-GO IFs for Gfap and Aif1 revealed near even distributions of astrocytic and microglial cells in the mouse hippocampal formation (Fig. 5a). At high magnification, we observed thick Gfap cytoskeleton radiating out from a central hub (Fig. 5b,f) and thin tortuous and ramified processes emanating from small cell bodies of microglial cells, which is characteristic of resting microglia (Fig. 5c,g). FT-GO signal amplification substantially increased Gfap IR, morphologically resembling reactive astrocytes (Fig. 5b,f). FT-GO IF further demonstrated tubular IRs for Gfap, which was likely astrocytic endfeet surrounding blood vessels (Fig. 5b), and Gfap-positive processes oriented radially in the supra- and infra-blades of DG (Fig. 5f). The Gfap-positive processes were extended from the subgranular zone of DG that was determined by FT-GO IF for Rbfox3 (Fig. 5f,i), indicating Gfap-positive processes emanating from neural stem cells26.
Multiplex mRNA FISH histochemistry facilitates identifying molecular signatures of individual cell populations in fixed tissues27,28,29. Neocortical interneurons contain a tremendous diversity in term of their gene expressions30,31,32. We then adapted FT-GO to multiplex mRNA FISH histochemistry, and combined with indirect IF detections for neurochemical markers to label specific subtypes of interneurons. We focused on parvalbumin (Pvalb) or cholecystokinin (Cck)-expressing GABAergic interneurons that compose two major populations of perisomatic interneurons in the mouse cerebral cortex33. We performed fluorescence quadruple labeling experiments for Slc17a7 (also known as vesicular glutamate transporter 1 [Vglut1]) mRNA, Gad1 (also known as glutamate decarboxylase 67 [Gad67]) mRNA, Pvalb protein and proCck peptide to label Pvalb or Cck-expressing neocortical GABAergic interneurons. Slc17a7 and Gad1 are markers for glutamatergic and GABAergic neurons in the dorsal telencephalon. Cck is also expressed by subpopulations of neocortical glutamatergic neurons34. Mouse brain sections were hybridized with complementary RNA (cRNA) probes for Slc17a7 and Gad1, and FT-GO signal amplification was applied in the detection procedure. The Ab-POD conjugated was inactivated with NaN3 after each round of FT deposition. Hybridization signals for Slc17a7 and Gad1 were clearly visualized with FT-GO (Fig. 6a–c): while Slc17a7 cRNA probe densely labeled all layers of the cerebral cortex, pyramidal cell layers of cornu ammonis regions and granule cell layers of the DG, scattered hybridization signals of Gad1 were found in these brain regions. IF signals for Pvalb and Cck were also clearly detected in our labeling system (Fig. 6d,e). We succeeded in labeling Pvalb and Cck-expressing neocortical GABAergic interneurons: neurons that expressed Gad1 mRNA and Pvalb protein, and Gad1 mRNA and proCck peptide were found in the quadruple labeling (Fig. 6g–i). Mutually exclusive expression of Slc17a7 and Gad1 validated multiplex detection of mRNA expressions with FT-GO (Fig. 6f).
Increase of detectability of an AAV tracer with FT-GO IF
AAV vectors carrying fluorescent protein (FP) reporter genes are widely used as anterograde neuronal tracers with equivalent sensitivity and specificity to classical tracers35,36. Although AAV vectors mediate robust fluorescence labeling of infected neurons, Ab amplification for the FPs is useful to increase detectability of AAV tracers37,38. TSA has been adapted to neuroanatomical tract tracing studies with classical tracers4, and FT-GO increased detectability of IF compared with indirect detections (Figs. 2, 3 and 4, Supplementary Fig. S1). Lastly, we adapted FT-GO IF to increase detectability of an anterograde AAV tracer, AAV2/1-SynTetOff-mRFP1. AAV-SynTetOff is a single AAV vector Tet-Off platform which is composed of regulator and response elements separated by an insulator39. The regulator element expresses tTA, which is driven a human synapsin I promoter, whereas the response element produced a reporter protein under the control of a TRE promoter. The AAV tracer was stereotaxically injected into the CPu to label the striatofugal projection system. The AAV-injected mice were sacrificed 7 to 10 days after injections. Brain sections were cut along the striatonigral axis, and adjacent sections were examined for fluorescence imaging of mRFP1 and FT-GO IF with an Ab against RFP (Fig. 7). FT-GO IF substantially increased detectability of the anterograde AAV tracer. While native fluorescence of mRFP1 was hardly detected outside the CPu (Fig. 7a), FT-GO IF visualized the whole striatofugal projection system: FT-GO IF labeled fibers arising from the CPu extended caudally to the brainstem, forming axon terminal fields in the external segment of the globus pallidus (GPe) and substantia nigra (SN) (Fig. 7b).
TSA is a highly sensitive enzymatic amplification method that enables detection of low-abundance targets and dramatic signal enhancement. In the present study, we reported FT-GO signal amplification as a multiplex fluorescent TSA system. Unlike conventional TSA systems, FT-GO involves POD-catalyzed deposition of FT with H2O2 produced during oxidation of glucose by glucose oxidase. We adapted FT-GO to several histochemical techniques, including IF, mRNA FISH histochemistry and neuroanatomical tract tracing with an AAV tracer. FT-GO gave strong labeling with a high signal-to-noise ratio in each application.
TSA has provided a remarkable increase in sensitivity of histochemical analysis, such as IHC, IF and DNA and RNA ISH histochemistry4,5,6,7,12. As with other TSA methods, FT-GO gave strong labeling in Rbfox3 IF (Fig. 2), and was implemented to mRNA FISH histochemistry (Fig. 6), where the increased sensitivity afforded by TSA is critical for detection of low-abundance mRNA targets6,7. The signal amplification efficiency of FT-GO, the enhancement of 9.7 to 34.1 fold over an indirect IF detection (Fig. 2m), is comparable to that of previous investigations with the range of 4- to 18-fold40,41. We utilized the high sensitivity of FT-GO to visualize fine-grain anatomy of CA and 5-HT projection systems in the mouse and marmoset brain (Fig. 3, 4, Supplementary Fig. S1) and increase detectability of an anterograde AAV tracer (Fig. 7).
The compatibility of FT-GO signal amplification to marmoset brain sections demonstrated its applicability and scalability to large-scale tissues (Fig. 4). FT-GO facilitates a high-throughput and cost-effective imaging of large-scale tissues in following ways. First, FT-GO saves image acquisition time, as strong fluorescence signal obtained by FT-GO supports reduced exposures to fluorescent and/or laser light. An improvement in image acquisition time can deliver a significant enhancement of throughput of imaging. Second, FT-GO allows to reduce the amount of primary Abs used for staining (Fig. 2, Supplementary Fig. S1). The fluorescence enhancement by FT-GO allows for using more diluted concentrations of primary Abs in comparison with conventional IF detections. This is critical in staining of large-scale tissues where a large amount of Abs is required. Additionally, inactivation of the Ab-conjugated POD with NaN3 enables application of multiple primary Abs in one step, avoiding need for multiple time-consuming cycles of staining with primary Abs. This is in contrast to a TSA-based multiplex IF with heat-mediated stripping of the primary/secondary Ab-POD complex that needs sequential primary Ab binding24,25.
Resolution is one of the main considerations for in situ signal amplification techniques. Although FT-GO IF visualized CA and 5-HT axons at single fiber resolution in brain regions where they diffusely innervated (Fig. 3, Supplementary Fig. S1), we did not rigorously assess the resolution of in situ signal amplification with FT-GO in this study. TSA can lead to blurring of signals and decreased resolution because of free diffusion of tyramide radicals before their covalent deposition on electron-rich moieties at or near the POD42,43. Addition of viscosity-increasing agents and/or an agent to reduce tyramide radicals lifetime to TSA reaction mixtures improves localization of fluorochromized and haptenized tyramide42,43. Further studies are needed to determine the resolution of in situ signal amplification with FT-GO.
Multiplex labeling enables detection of multiple targets on the same tissue section, allowing for examination of spatial arrangement of target molecules. For multiplexing with FT-GO, we inactivated Ab-conjugated POD by incubation with high concentration of NaN3 (Fig. 6). Quenching Ab-conjugated POD with NaN3 would be effective for multiplex labeling with other TSA systems. Incubation with NaN3 has less impact on antigenicity, antigen–antibody binding, hybridized strands and tissue integrity, compared with other POD blocking agents such as H2O2 and low pH buffer44. We took advantage of the less deleterious effects of NaN3, and succeed in quadruple labeling combined with mRNA FISH histochemistry and IF (Fig. 7). A TSA-based multiplex IF utilizes heat-mediated stripping of the primary/secondary Ab-POD complex, which is accomplished through covalent deposition of FT on tissues, allowing for use of multiple Abs raised in the same species24,25. However, heat treatment might lead to degradation or enhancement of epitopes and tissue distortion. Importantly, the heat-mediated stripping, which can result in dissociation of hybridized probes, is not compatible with multiplex detection of hybridization signals.
AAV vectors carrying FP reporter genes enable robust fluorescent labeling of infected neurons with equivalent sensitivity to classical tracers, and are used as sensitive anterograde tracers for neuroanatomical mapping35,36. FT-GO IF labeled neuronal processes that were not detectable when observing native fluorescence, indicating that FT-GO IF increases detectability of an anterograde AAV tracer (Fig. 7). High reporter gene expression, which can be implemented by usage of strong promoters, insertion of posttranscriptional regulatory elements, preparations of high-titered virus vectors and/or longer survival times, achieves enhancement of viral-mediated fluorescence signals, increasing detectability of AAV tracers39,45,46,47,48. However, AAV-mediated high reporter gene expression and/or multiplicity of infection of AAV vectors could result in toxicity to neuronal, glial and neural progenitor cells49,50,51,52,53. Amplifying low tracer signals with FT-GO IF would provide a highly sensitive neuroanatomical tract tracing technique with minimal toxicity.
In summary, we have developed FT-GO as a multiplex TSA system. In the TSA system, oxidation of glucose by glucose oxidase is implemented to supply H2O2 for effective deposition of FT. FT-GO enables detection of low abundance targets as well as enhancement of fluorescence signals. Quenching of Ab-conjugated POD with high concentration of NaN3 permits in situ fluorescence detection of multiple target molecules with FT-GO. Given its simplicity, high sensitivity and high specificity, FT-GO would provide a versatile platform for histochemical analysis.
All animal experiments were approved by the Institutional Animal Care and Use Committees of Juntendo University (Approval No. 2021245 and 2021246) and Kyoto University (Approval No. Med Kyo 20031), and conducted in accordance with Fundamental Guidelines for Proper Conduct of Animal Experiments by the Science Council of Japan (2006). All animal experiments were performed in compliance with ARRIVE (Animal Research: Reporting In Vivo Experiments) guidelines.
Eight- to twelve-week-old male C57BL/6J mice (Nihon SLC) were used. All mice were maintained in specific pathogen-free conditions under a 12/12 h light/dark cycle (light: 08:00–20:00) with ad libitum access to food and water.
31-month-old male and 33-months-old female common marmosets (body weight, 360 and 290 g; bred in our laboratory) were housed on a 14/10 h light/dark cycle (light: 07:00–21:00). The animals were fed twice a day with solid food. Water was provided ad libitum. Each cage was furnished with a wooden perch, a food tray and an automatic water dispenser. The marmosets were received stereotaxic injections of AAV vectors encoding GFP or RFP: analyses of these data are not included in the current study. We found no obvious abnormalities in gross brain anatomy associated with the AAV injection.
Mice were anesthetized with an intraperitoneal injection of sodium pentobarbital (200 mg/kg; Somnopentyl, Kyoritsu Seiyaku) and perfused transcardially with 20 mL of PBS at 4 ºC, followed by the same volume of 4% paraformaldehyde (PFA) (1.04005.1000, Merck Millipore) in 0.1 M phosphate buffer (PB; pH 7.4) at 4 ºC. The brains of mice were removed and postfixed in the same fixative overnight (for IF) or 3 days (for FISH) at 4 ºC. Perfusion fixation of marmoset brains was performed as described previously54.
The fixed brains were cryoprotected in 30% sucrose in 0.1 M PB (for IF) or 30% sucrose in diethylpyrocarbonate (DEPC)-treated 0.1 M PB at 4 °C (for FISH), and cut coronally or sagittally into 30- or 40-µm-thick sections on a freezing microtome (2000R; Leica Biosystems)13. The sections were stored in PBS containing 0.2% NaN3 at 4 °C (for IF) or an antifreeze solution (for FISH) that contained 30% glycerol and 30% ethylene glycol in DEPC-treated 40 mM PBS at − 20 °C until use.
Following preincubation for 10 min with an FT-GO reaction mixture that contained 10 µM FT, 3 µg/mL glucose oxidase (16831-14, Nacalai Tesque) and 1 or 2% bovine serum albumin in 0.1 M PB, FT-GO reaction was initiated by adding β-d-glucose (16804-32, Nacalai Tesque) into the reaction mixture at 20 µg/mL and proceeded for 30 min. The concentrations of glucose oxidase and β-d-glucose were determined in reference to our previous studies in BT-GO10,11. The FT used were: CF488A tyramide (92171, Biotium), CF568 tyramide (92173, Biotium) and CF647 tyramide (96022, Biotium).
IF in tissue sections
Free-floating immunostaining was carried out as follows. Tissue sections were washed twice for 10 min in 0.3% Triton X-100 in PBS (PBS-X) and reacted for overnight to 3 days with primary Abs in PBS-X containing 0.12% λ-carrageenan (035-09693; Sigma-Aldrich) and 1% normal donkey serum (S30-100ML, Merck Millipore) (PBS-XCD). After washing twice for 10 min in PBS-X, the sections were then reacted for 2 − 4 h with secondary Abs in PBS-XCD. The sections were washed twice for 10 min in PBS-X. Some of the sections were counterstained with NeuroTrace 435/455 Blue or NeuroTrace 530/615 Red Fluorescent Nissl Stain (1:100, N21479 or N21482, Thermo Fisher Scientific) in PBS-X. The sections were mounted onto glass slides (Superfrost micro slide glass APS-coated, Matsunami Glass) and coverslipped with 50% glycerol, 2.5% 1,4-diazabicyclo[2.2.2]octane, and 0.02% NaN3 in PBS (pH 7.4). Endogenous peroxidase activity was quenched with 1% H2O2 in PBS for 30 min prior to immunostaining. For multiplex FT-GO IFs, the Ab-POD conjugate was inactivated with 2% NaN3 in PBS for 4 h after each round of FT deposition. All incubations were performed at 20–25 ºC. Primary Abs (pAbs) and secondary Abs (sAbs) used are listed in Supplementary Table S1 and S2 online.
Multiplex fluorescent in situ hybridization histochemistry
Multiplex FISH on free-floating sections was carried out as reported previously16,29, with some modifications. Briefly, tissue sections were quenched with 2% H2O2 in 0.1 M PB, acetylated with 0.25% acetic anhydride in 0.1 M triethanolamine, prehybridized in a hybridization buffer and hybridized with a mixture of 1.0 µg/ml digoxigenin (DIG)- and 1.0 µg/ml fluorescein isothiocyanate (FITC)-labeled cRNA probes. After high-stringency washes and RNase A digestion, the sections were reacted with POD-conjugated sheep (Sh) polyclonal anti-FITC Ab, Fab fragments (1:1000, 11 426 346 910, Roche Diagnostics, RRID:AB_840257). Subsequently, the sections were washed twice for 10 min in 0.1 M Tris–HCl (pH 7.5) buffered 0.9% saline (TS7.5) containing 0.1% (v/v) Tween-20 (TNT), incubated for 10 min in 0.1 M PB and developed with first FT-GO reaction. After washes for 10 min each in 0.1 M PB and PBS, the Ab-POD conjugate was inactivated with 2% NaN3 in PBS for 4 h. Following washes for 10 min each in PBS, TNT and TS7.5, the sections were then reacted with POD-conjugated Sh polyclonal anti-DIG Ab, Fab fragments (1:1000, 11 207 733 910, Roche Diagnostics, RRID:AB_514500), washed with TNT, incubated in 0.1 M PB and developed with the second FT-GO reaction. Antisense and sense single-strand riboprobes were transcribed in vitro using DIG or FITC RNA labeling kit (Roche Diagnostics). cRNA probes for Gad155 and Slc17a756 were used.
For indirect IF for neurochemical markers, the sections processed for multiplex FISH were washed twice for 10 min in 0.1 M PB, incubated for 10 min each in PBS and PBS-X, reacted with pAbs and sAbs, and mounted onto slides as described above.
AAV vector construction, production and injection
For the construction of pAAV2-SynTetOff-mRFP1-BGHpA, the coding sequence of mRFP157 was amplified and replaced with the GFP sequence of an entry vector, pENTR1A-SV40LpA-tTAad-SYN-insulator-TRE-GFP-BGHpA39, through the BamHI/MluI sites. The resultant entry vector, pENTR1A-SV40LpA-tTAad-SYN-insulator-TRE-mRFP1-BGHpA, was reacted with pAAV2-DEST(f)39 by homologous recombination with LR clonase II (11791020, Thermo Fisher Scientific), yielding pAAV2-SynTetOff-mRFP1-BGHpA.
The AAV vector was produced and purified as described previously58. In brief, pAAV2-SynTetOff-mRFFP1-BGHpA and helper plasmids were transfected into HEK293T cells (RCB2202, RIKEN BioResource Research Center) with polyethylenimine (23966, Polysciences). Virus particles collected from the cell lysate and supernatant were purified by ultracentrifugation with OptiPrep (1114542, Axis-Shield) and concentrated by ultrafiltration with Amicon Ultra-15 Centrifugal Filter Unit (UFC903024, Merck Millipore). The physical titer of the virus vector (genome copies (gc)/mL) was determined by quantitative PCR with the purified virus solutions.
Stereotaxic injection of the AAV vector was carried out as reported previously13,59. After anesthetization with intraperitoneal injection of a mixture of medetomidine (0.3 mg/kg; Domitor, Zenoaq), midazolam (4 mg/kg; Dormicum, Astellas Pharma), and butorphanol (5 mg/kg; Vetorphale, Meiji Seika Pharma), mice were placed on a stereotaxic apparatus (SR50, Narishige). Subsequently, a 0.2 µL solution of AAV2/1-SynTetOff-mRFFP1-BGHpA (1.0 × 1012 gc/mL) was delivered to the CPu (AP + 0.5 mm, ML ± 2.0 mm relative to bregma, DV –2.5 mm from the brain surface) through a glass micropipette attached to Picospritzer III (Parker Hannifin). The mice were recovered from anesthesia with intraperitoneal injection of atipamezole (1.5 mg/kg; Antisedan, Zenoaq) and maintained for seven to ten days.
Image acquisition and processing
Images of tissue sections were acquired with a confocal laser scanning microscope (TCS SP8; Leica Microsystem) using a 5× air (HCX PL Fluotar 5×/0.15, numerical aperture [NA] = 0.15, Leica Microsystems), 10× air (HCX PL APO 10×/0.40 CS, NA = 0.40, Leica Microsystems), 16× multi-immersion (HC FLUOTAR 16×/0.60 IMM CORR VISIR, NA = 0.60, Leica Microsystems) and 25× water-immersion (HC FLUOTAR L 25x/0.95 W VISIR, NA = 0.95, Leica Microsystems) objective lens. The confocal pinhole was set to 1.0 to 5.0 Airy unit. Confocal z-stack images were collected at 1.0 to 30 μm intervals at 512 × 512 or 1024 × 1024 pixel resolution. Acquired images were tiled, stitched and processed to create maximum intensity projection using Leica Application Suite X software (LAS X, ver. 184.108.40.20676, Leica Microsystems) and ImageJ software60 (ver. 1.53, National Institutes of Health). The global brightness and contrast of the images were adjusted with ImageJ software.
To assess the signal amplification resulting from FT-GO reaction, the fluorescence intensity (arbitrary units [AU]) of Rbfox3 IF in layer 2/3 of the S1 was measured using ImageJ software. Rbfox3-positive cells with visible nucleoli located at approximately 3.0 µm depth from the surface were subjected to analysis. Nucleoli were identified with NeuroTrace 530/615 Red Fluorescent Nissl Stain.
Statistical analyses were conducted with the aid of GraphPad Prism 9 software (ver. 9.3.1 (350), GraphPad Software). Kruskal–Wallis test followed by Dunn’s post hoc test was used for comparisons among independent groups. Data are represented as means ± standard deviations (SDs). All tests were two-sided. The exact values of n are indicated in the corresponding figure legends. Statistical significance was set at P < 0.05.
The datasets generated during and/or analyzed during the current study and all biological materials reported in this article are available from the corresponding author on reasonable request.
Bobrow, M. N., Harris, T. D., Shaughnessy, K. J. & Litt, G. J. Catalyzed reporter deposition, a novel method of signal amplification: Application to immunoassays. J. Immunol. Methods 125, 279–285. https://doi.org/10.1016/0022-1759(89)90104-x (1989).
Bobrow, M. N., Shaughnessy, K. J. & Litt, G. J. Catalyzed reporter deposition, a novel method of signal amplification. II. Application to membrane immunoassays. J. Immunol. Methods 137, 103–112. https://doi.org/10.1016/0022-1759(91)90399-z (1991).
Bobrow, M. N., Litt, G. J., Shaughnessy, K. J., Mayer, P. C. & Conlon, J. The use of catalyzed reporter deposition as a means of signal amplification in a variety of formats. J. Immunol. Methods 150, 145–149. https://doi.org/10.1016/0022-1759(92)90073-3 (1992).
Adams, J. C. Biotin amplification of biotin and horseradish peroxidase signals in histochemical stains. J. Histochem. Cytochem. 40, 1457–1463. https://doi.org/10.1177/40.10.1527370 (1992).
Kerstens, H. M., Poddighe, P. J. & Hanselaar, A. G. A novel in situ hybridization signal amplification method based on the deposition of biotinylated tyramine. J. Histochem. Cytochem. 43, 347–352. https://doi.org/10.1177/43.4.7897179 (1995).
Raap, A. K. et al. Ultra-sensitive FISH using peroxidase-mediated deposition of biotin- or fluorochrome tyramides. Hum. Mol. Genet. 4, 529–534. https://doi.org/10.1093/hmg/4.4.529 (1995).
Komminoth, P. & Werner, M. Target and signal amplification: Approaches to increase the sensitivity of in situ hybridization. Histochem. Cell Biol. 108, 325–333. https://doi.org/10.1007/s004180050173 (1997).
Mayer, G. & Bendayan, M. Biotinyl-tyramide: A novel approach for electron microscopic immunocytochemistry. J. Histochem. Cytochem. 45, 1449–1454. https://doi.org/10.1177/002215549704501101 (1997).
Stanarius, A., Topel, I., Schulz, S., Noack, H. & Wolf, G. Immunocytochemistry of endothelial nitric oxide synthase in the rat brain: A light and electron microscopical study using the tyramide signal amplification technique. Acta Histochem. 99, 411–429. https://doi.org/10.1016/S0065-1281(97)80034-7 (1997).
Furuta, T., Kaneko, T. & Deschenes, M. Septal neurons in barrel cortex derive their receptive field input from the lemniscal pathway. J. Neurosci. 29, 4089–4095. https://doi.org/10.1523/JNEUROSCI.5393-08.2009 (2009).
Kuramoto, E. et al. Two types of thalamocortical projections from the motor thalamic nuclei of the rat: a single neuron-tracing study using viral vectors. Cereb. Cortex 19, 2065–2077. https://doi.org/10.1093/cercor/bhn231 (2009).
Berghorn, K. A., Bonnett, J. H. & Hoffman, G. E. cFos immunoreactivity is enhanced with biotin amplification. J. Histochem. Cytochem. 42, 1635–1642. https://doi.org/10.1177/42.12.7983364 (1994).
Okamoto, S. et al. Exclusive labeling of direct and indirect pathway neurons in the mouse neostriatum by an adeno-associated virus vector with Cre/lox system. STAR Protoc. 2, 100230. https://doi.org/10.1016/j.xpro.2020.100230 (2021).
Igarashi, K. M. et al. Parallel mitral and tufted cell pathways route distinct odor information to different targets in the olfactory cortex. J. Neurosci. 32, 7970–7985. https://doi.org/10.1523/JNEUROSCI.0154-12.2012 (2012).
Takeuchi, Y. et al. Large-scale somatotopic refinement via functional synapse elimination in the sensory thalamus of developing mice. J. Neurosci. 34, 1258–1270. https://doi.org/10.1523/JNEUROSCI.3865-13.2014 (2014).
Ma, Y. et al. Expression of gap junction protein connexin36 in multiple subtypes of GABAergic neurons in adult rat somatosensory cortex. Cereb. Cortex 21, 2639–2649. https://doi.org/10.1093/cercor/bhr051 (2011).
Li, Z. H. et al. Coexpression of VGLUT1 and VGLUT2 in precerebellar neurons in the lateral reticular nucleus of the rat. Brain Res. Bull. 162, 94–106. https://doi.org/10.1016/j.brainresbull.2020.06.008 (2020).
Sun, Y. et al. Involvement of the ventrolateral periaqueductal gray matter-central medial thalamic nucleus-basolateral amygdala pathway in neuropathic pain regulation of rats. Front. Neuroanat. 14, 32. https://doi.org/10.3389/fnana.2020.00032 (2020).
Mullen, R. J., Buck, C. R. & Smith, A. M. NeuN, a neuronal specific nuclear protein in vertebrates. Development 116, 201–211 (1992).
Matsuda, W. et al. Single nigrostriatal dopaminergic neurons form widely spread and highly dense axonal arborizations in the neostriatum. J. Neurosci. 29, 444–453. https://doi.org/10.1523/JNEUROSCI.4029-08.2009 (2009).
Ren, J. et al. Single-cell transcriptomes and whole-brain projections of serotonin neurons in the mouse dorsal and median raphe nuclei. Elife https://doi.org/10.7554/eLife.49424 (2019).
Okano, H. et al. Brain/MINDS: A Japanese National Brain Project for Marmoset Neuroscience. Neuron 92, 582–590. https://doi.org/10.1016/j.neuron.2016.10.018 (2016).
Miller, C. T. et al. Marmosets: A neuroscientific model of human social behavior. Neuron 90, 219–233. https://doi.org/10.1016/j.neuron.2016.03.018 (2016).
Toth, Z. E. & Mezey, E. Simultaneous visualization of multiple antigens with tyramide signal amplification using antibodies from the same species. J. Histochem. Cytochem. 55, 545–554. https://doi.org/10.1369/jhc.6A7134.2007 (2007).
Stack, E. C., Wang, C., Roman, K. A. & Hoyt, C. C. Multiplexed immunohistochemistry, imaging, and quantitation: A review, with an assessment of tyramide signal amplification, multispectral imaging and multiplex analysis. Methods 70, 46–58. https://doi.org/10.1016/j.ymeth.2014.08.016 (2014).
Seri, B., Garcia-Verdugo, J. M., McEwen, B. S. & Alvarez-Buylla, A. Astrocytes give rise to new neurons in the adult mammalian hippocampus. J. Neurosci. 21, 7153–7160 (2001).
Kosman, D. et al. Multiplex detection of RNA expression in Drosophila embryos. Science 305, 846. https://doi.org/10.1126/science.1099247 (2004).
Komatsu, Y., Watakabe, A., Hashikawa, T., Tochitani, S. & Yamamori, T. Retinol-binding protein gene is highly expressed in higher-order association areas of the primate neocortex. Cereb. Cortex 15, 96–108. https://doi.org/10.1093/cercor/bhh112 (2005).
Hioki, H. et al. Vesicular glutamate transporter 3-expressing nonserotonergic projection neurons constitute a subregion in the rat midbrain raphe nuclei. J. Comp. Neurol. 518, 668–686. https://doi.org/10.1002/cne.22237 (2010).
Tasic, B. et al. Shared and distinct transcriptomic cell types across neocortical areas. Nature 563, 72–78. https://doi.org/10.1038/s41586-018-0654-5 (2018).
Hodge, R. D. et al. Conserved cell types with divergent features in human versus mouse cortex. Nature 573, 61–68. https://doi.org/10.1038/s41586-019-1506-7 (2019).
Network, B. I. C. C. A multimodal cell census and atlas of the mammalian primary motor cortex. Nature 598, 86–102. https://doi.org/10.1038/s41586-021-03950-0 (2021).
Freund, T. F. & Katona, I. Perisomatic inhibition. Neuron 56, 33–42. https://doi.org/10.1016/j.neuron.2007.09.012 (2007).
Hokfelt, T. et al. Some aspects on the anatomy and function of central cholecystokinin systems. Pharmacol. Toxicol. 91, 382–386. https://doi.org/10.1034/j.1600-0773.2002.910617.x (2002).
Oh, S. W. et al. A mesoscale connectome of the mouse brain. Nature 508, 207–214. https://doi.org/10.1038/nature13186 (2014).
Wang, Q. et al. Systematic comparison of adeno-associated virus and biotinylated dextran amine reveals equivalent sensitivity between tracers and novel projection targets in the mouse brain. J. Comp. Neurol. 522, 1989–2012. https://doi.org/10.1002/cne.23567 (2014).
Harris, J. A., Oh, S. W. & Zeng, H. Adeno-associated viral vectors for anterograde axonal tracing with fluorescent proteins in nontransgenic and cre driver mice. Curr. Protoc. Neurosci. 20, 21–18. https://doi.org/10.1002/0471142301.ns0120s59 (2012).
Winnubst, J. et al. Reconstruction of 1,000 projection neurons reveals new cell types and organization of long-range connectivity in the mouse brain. Cell 179, 268–281213. https://doi.org/10.1016/j.cell.2019.07.042 (2019).
Sohn, J. et al. A single vector platform for high-level gene transduction of central neurons: Adeno-associated virus vector equipped with the tet-off system. PLoS ONE 12, e0169611. https://doi.org/10.1371/journal.pone.0169611 (2017).
Chao, J., DeBiasio, R., Zhu, Z., Giuliano, K. A. & Schmidt, B. F. Immunofluorescence signal amplification by the enzyme-catalyzed deposition of a fluorescent reporter substrate (CARD). Cytometry 23, 48–53. https://doi.org/10.1002/(SICI)1097-0320(19960101)23:1<48::AID-CYTO7>3.0.CO;2-I (1996).
Saka, S. K. et al. Immuno-SABER enables highly multiplexed and amplified protein imaging in tissues. Nat. Biotechnol. 37, 1080–1090. https://doi.org/10.1038/s41587-019-0207-y (2019).
Chen, Y. et al. Mapping 3D genome organization relative to nuclear compartments using TSA-Seq as a cytological ruler. J. Cell Biol. 217, 4025–4048. https://doi.org/10.1083/jcb.201807108 (2018).
van Gijlswijk, R. P., Wiegant, J., Raap, A. K. & Tanke, H. J. Improved localization of fluorescent tyramides for fluorescence in situ hybridization using dextran sulfate and polyvinyl alcohol. J. Histochem. Cytochem. 44, 389–392. https://doi.org/10.1177/44.4.8601698 (1996).
King, R. S. & Newmark, P. A. In situ hybridization protocol for enhanced detection of gene expression in the planarian Schmidtea mediterranea. BMC Dev. Biol. 13, 8. https://doi.org/10.1186/1471-213X-13-8 (2013).
Loeb, J. E., Cordier, W. S., Harris, M. E., Weitzman, M. D. & Hope, T. J. Enhanced expression of transgenes from adeno-associated virus vectors with the woodchuck hepatitis virus posttranscriptional regulatory element: implications for gene therapy. Hum. Gene Ther. 10, 2295–2305. https://doi.org/10.1089/10430349950016942 (1999).
Soderblom, C. et al. 3D imaging of axons in transparent spinal cords from rodents and nonhuman primates. eNeuro https://doi.org/10.1523/ENEURO.0001-15.2015 (2015).
Sakaguchi, R., Leiwe, M. N. & Imai, T. Bright multicolor labeling of neuronal circuits with fluorescent proteins and chemical tags. Elife https://doi.org/10.7554/eLife.40350 (2018).
Nieuwenhuis, B. et al. Optimization of adeno-associated viral vector-mediated transduction of the corticospinal tract: Comparison of four promoters. Gene Ther. 28, 56–74. https://doi.org/10.1038/s41434-020-0169-1 (2021).
Klein, R. L. et al. Efficient neuronal gene transfer with AAV8 leads to neurotoxic levels of tau or green fluorescent proteins. Mol. Ther. 13, 517–527. https://doi.org/10.1016/j.ymthe.2005.10.008 (2006).
Howard, D. B., Powers, K., Wang, Y. & Harvey, B. K. Tropism and toxicity of adeno-associated viral vector serotypes 1, 2, 5, 6, 7, 8, and 9 in rat neurons and glia in vitro. Virology 372, 24–34. https://doi.org/10.1016/j.virol.2007.10.007 (2008).
Bockstael, O. et al. Rapid transgene expression in multiple precursor cell types of adult rat subventricular zone mediated by adeno-associated type 1 vectors. Hum. Gene Ther. 23, 742–753. https://doi.org/10.1089/hum.2011.216 (2012).
Watakabe, A. et al. Comparative analyses of adeno-associated viral vector serotypes 1, 2, 5, 8 and 9 in marmoset, mouse and macaque cerebral cortex. Neurosci. Res. 93, 144–157. https://doi.org/10.1016/j.neures.2014.09.002 (2015).
Johnston, S. et al. AAV ablates neurogenesis in the adult murine hippocampus. Elife https://doi.org/10.7554/eLife.59291 (2021).
Furuta, T. et al. Multi-scale light microscopy/electron microscopy neuronal imaging from brain to synapse with a tissue clearing method, ScaleSF. Science https://doi.org/10.1016/j.isci.2021.103601 (2022).
Tamamaki, N. et al. Green fluorescent protein expression and colocalization with calretinin, parvalbumin, and somatostatin in the GAD67-GFP knock-in mouse. J. Comp. Neurol. 467, 60–79. https://doi.org/10.1002/cne.10905 (2003).
Watakabe, A., Ohsawa, S., Hashikawa, T. & Yamamori, T. Binding and complementary expression patterns of semaphorin 3E and plexin D1 in the mature neocortices of mice and monkeys. J. Comp. Neurol. 499, 258–273. https://doi.org/10.1002/cne.21106 (2006).
Campbell, R. E. et al. A monomeric red fluorescent protein. Proc. Natl. Acad. Sci. U S A 99, 7877–7882. https://doi.org/10.1073/pnas.082243699 (2002).
Takahashi, M., Ishida, Y., Kataoka, N., Nakamura, K. & Hioki, H. Receptor and Ion Channel Detection in the Brain (eds. Lujan, R. & Ciruela, F.). 323–341. (Springer, 2021).
Okamoto, S. et al. Overlapping projections of neighboring direct and indirect pathway neostriatal neurons to globus pallidus external segment. iScience https://doi.org/10.1016/j.isci.2020.101409 (2020).
Schneider, C. A., Rasband, W. S. & Eliceiri, K. W. NIH Image to ImageJ: 25 years of image analysis. Nat. Methods 9, 671–675. https://doi.org/10.1038/nmeth.2089 (2012).
The authors thank Ayaka Ansai and Naoko Imai (Juntendo University) for their technical assistance. This study was supported by JSPS KAKENHI (JP20K07231 to K.Y.; JP21H03529 to T.F.; JP20K07743 to M.K.; JP21H02589 and JP20H05628 to M.W.; JP21H02592 to H.H.) and Scientific Research on Innovative Area “Resonance Bio” (JP18H04743 to H.H.). This study was also supported by the Japan Agency for Medical Research and Development (AMED) (JP21dm0207112 to T.F. and H.H.; JP19dm0207093 and JP18dm0207020 to T.I.), Moonshot R&D from the Japan Science and Technology Agency (JST) (JPMJMS2024 to H.H.), Fusion Oriented Research for disruptive Science and Technology (FOREST) from JST (JPMJFR204D to H.H.), Grants-in-Aid from the Research Institute for Diseases of Old Age at the Juntendo University School of Medicine (X2016 to K.Y.; X2001 to H.H.), and the Private School Branding Project.
The authors declare no competing interests.
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Yamauchi, K., Okamoto, S., Ishida, Y. et al. Fluorochromized tyramide-glucose oxidase as a multiplex fluorescent tyramide signal amplification system for histochemical analysis. Sci Rep 12, 14807 (2022). https://doi.org/10.1038/s41598-022-19085-9