Retrograde tracing of neural pathways with a protein gold complex. II. Electron microscopic demonstration of projections and collaterals

This paper describes a sensitive method for tracing neural connections at the electron microscopic (EM) level using a new compound produced through the coupling of colloidal gold particles to a wheat germ agglutinin horseradish peroxidase conjugate (the WGA*HRP-gold complex). Visualization of retrogradely labeled cells at the EM level was achieved either directly by gold particles scanning or after silver enhancement. By using different sizes of gold particles individually coupled to WGA*HRP and injected in different brain areas EM detection of multiple retrograde labeling was possible. Thus retrogradely labeled cells were first identified at the light microscopic level through HRP histochemistry with tetramethylbenzidine as a chromogen and then examined under the electron microscope after osmication and embedding. Gold particles were readily identified as electron dense, round dots in spherical grey vesicles. Identification of different sizes of gold particles often localized in the same vesicle established that the protein-gold complex can be used to study collateralisation of parental axons.     

Retrograde tracing of neural pathways with a protein gold complex

Summary This paper describes a sensitive method for tracing neural connections at the electron microscopic (EM) level using a new compound produced through the coupling of colloidal gold particles to a wheat germ agglutinin horseradish peroxidase conjugate (the WGA^*HRP-gold complex). Visualization of retrogradely labeled cells at the EM level was achieved either directly by gold particles scanning or after silver enhancement. By using different sizes of gold particles individually coupled to WGA^*HRP and injected in different brain areas EM detection of multiple retrograde labeling was possible. Thus retrogradely labeled cells were first identified at the light microscopic level through HRP histochemistry with tetramethylbenzidine as a chromogen and then examined under the electron microscope after osmication and embedding. Gold particles were readily identified as electron dense, round dots in spherical grey vesicles. Identification of different sizes of gold particles often localized in the same vesicle established that the protein-gold complex can be used to study collateralisation of parental axons.     

Protein-gold complexes as neuronal markers for long-term tracing studies

In this study, we have tested the possible use of protein-gold complexes as neuronal markers for long-term tracing studies in rat. The tracer we have used consisted of colloidal gold particles coupled to wheat-germ agglutinin apohorseradish peroxidase conjugate (WGA-apoHRP). The neuronal labeling was studied for survival periods of up to nineteen months following injection in the central nervous system. Maximal visualization of the gold particles was achieved through gold silver intensification. The tracer could be detected throughout the entire range of periods considered. The injection site consisted of a dense black core and retrogradely labeled cells were characterized by round black granules over the cell body. The retrogradely labeled cells were cytochemically characterized by demonstrating their transmitter content. Thus protein-gold complexes may be used as long-term neuronal markers compatible with the persistance of the vital functions of the labeled cells.     

Protein-gold complexes as neuronal markers for long-term tracing studies

Summary In this study, we have tested the possible use of protein-gold complexes as neuronal markers for long-term tracing studies in rat. The tracer we have used consisted of colloidal gold particles coupled to wheat-germ agglutinin apohorseradish peroxidase conjugate (WGA-apoHRP). The neuronal labeling was studied for survival periods of up to nineteen months following injection in the central nervous system. Maximal visualization of the gold particles was achieved through gold silver intensification. The tracer could be detected throughout the entire range of periods considered. The injection site consisted of a dense black core and retrogradely labeled cells were characterized by round black granules over the cell body. The retrogradely labeled cells were cytochemically characterized by demonstrating their transmitter content. Thus protein-gold complexes may be used as long-term neuronal markers compatible with the persistance of the vital functions of the labeled cells.     

Retrograde tracing of neural pathways with a protein-gold complex

Summary In this study I have used a tracer complex made of wheat germ agglutinin horseradish peroxidase conjugate (WGA*HRP) coupled to colloidal gold for retrograde tracing of neuronal pathways at the light microscopic level. Visualization of the gold was achieved by silver precipitation (the gold silver intensification method) with gold particles acting as specific cores of nucleation. The presence of horseradish peroxidase in the protein conjugate allowed this method to be compared with classical histochemistry using tetramethylbenzidine as a chromogen. The gold silver intensification method proved to be reliable, specific and sensitive. It has been demonstrated to be useful with fixatives containing a high percentage of paraformaldehyde and compatible with histochemical procedures to show projections of transmitter specific pathways.     

Retrograde tracing of neural pathways with a protein-gold complex. I. Light microscopic detection after silver intensification

In this study I have used a tracer complex made of wheat germ agglutinin horseradish peroxidase conjugate (WGA*HRP) coupled to colloidal gold for retrograde tracing of neuronal pathways at the light microscopic level. Visualization of the gold was achieved by silver precipitation (the gold silver intensification method) with gold particles acting as specific cores of nucleation. The presence of horseradish peroxidase in the protein conjugate allowed this method to be compared with classical histochemistry using tetramethylbenzidine as a chromogen. The gold silver intensification method proved to be reliable, specific and sensitive. It has been demonstrated to be useful with fixatives containing a high percentage of paraformaldehyde and compatible with histochemical procedures to show projections of transmitter specific pathways.     

Stabilization of the tetramethylbenzidine (TMB) reaction product: application for retrograde and anterograde tracing, and combination with immunohistochemistry

Tetramethylbenzidine (TMB) as a substrate for horseradish peroxidase (HRP) histochemistry is more sensitive than other chromogens. Its instability in aqueous solutions and ethanol, however, has limited its application. We now report a method for stabilizing TMB by incubation in combinations of diaminobenzidine (DAB)/cobalt (Co2+)/H2O2. The stabilized TMB product was unaffected by long-term exposures to ethanol, neutral buffers, and subsequent immunohistochemical staining procedures. A procedure is recommended for optimal stabilization of TMB that affords a sensitivity for demonstrating retrogradely labeled perikarya comparable to standard TMB histochemistry. The physical characteristics of the reaction product make it suitable for combination with the unlabeled antibody, peroxidase-antiperoxidase (PAP) immunohistochemical staining procedure. This was established by staining retrogradely labeled neurons in the basal forebrain with a monoclonal antibody against choline acetyltransferase. Because the stabilized TMB product exhibited a superior sensitivity over cobalt ion intensification of the DAB-based reaction product (DAB-Co), it offers a distinct advantage over previously described combination procedures.     

Localization of immunoreactive tyrosine hydroxylase in the goldfish retina with pre-embedding immunolabeling with one-nanometer colloidal gold particles and gold toning.

The goal of this study was to develop an alternative to silver intensification for visualizing small colloidal gold particles by light and electron microscopy. The isolated goldfish retina was labeled with rabbit antiserum to tyrosine hydroxylase and 1-nm colloidal gold-conjugated goat anti-rabbit IgG. The gold particles were enlarged by toning with gold chloride, followed by reduction in oxalic acid. Dopaminergic interplexiform cells were clearly visible by light microscopy and, in lightly-fixed material treated with detergent, they were labeled in their entirety. Labeling was qualitatively similar, although less extensive, in material fixed and processed for electron microscopy. The labeled processes were apparent in ultra-thin sections viewed at low magnification, but the gold-toned particles were not so large that they obscured subcellular structures. The procedure apparently had no deleterious effects on the tissue, since the ultrastructural preservation was comparable to that seen with other pre-embedding immunolabeling methods. The technique was simple, reliable and, since the gold solutions were so dilute, relatively inexpensive.     

Biotin amplification of biotin and horseradish peroxidase signals in histochemical stains.

A procedure is described for intensifying histochemical reactions by amplification of biotinylated sites. This is achieved by deposition of biotinylated tyramine on the tissue through the enzymatic action of horseradish peroxidase (HRP). The amplified biotin sites are subsequently visualized by binding them to avidin, to which a marker is attached. This amplification greatly increases the sensitivity of staining procedures that employ HRP (and/or biotin) in tissue. For neuroanatomical pathway tracing methods, the procedure greatly increases the detectability of the injected tracer. For lectin histochemistry and immunohistochemistry, the amplification requires that the lectin or primary antibody be greatly diluted. This dilution results in less background staining and yet strong signals are produced even when very dilute reagents are used. Alternatively, the amplification permits much shorter incubations in primary antibodies when dilutions are used that would ordinarily be used with conventional bridge techniques. The procedure is also useful for amplifying very weak signals, such as those of immunoreactions in glutaraldehyde-fixed tissue. The amplification procedure, together with the availability of avidin probes labeled with fluorochromes, colloidal gold, or enzyme systems other than HRP, provides a means of greatly increasing the versatility of a variety of histochemical reactions, including those for detecting in situ hybridization probes, in addition to increasing the sensitivity of the reactions.     

Ultrastructural visualization of anterogradely transported horseradish peroxidase in developing corticospinal tract of rat

Until now a satisfactory method for electron microscopic (EM) detection of anterogradely transported horseradish peroxidase (HRP) in developing neural tissue, using sensitive chromogen tetramethylbenzidine (TMB), has not been described. Use of the stabilizing agent ammoniumheptamolybdate (AHM), in combination with a modified prolonged osmication [4 hr at pH 5.0 in 0.1 M phosphate buffer (PB)] made possible visualization of HRP-TMB-(AHM) reaction product at the ultrastructural level in outgrowing corticospinal tract (CST) fibers of young postnatal rat. This reaction product appeared to be very distinctive and clearly detectable, making ultrastructural identification of HRP-labeled outgrowing CST fibers in rat spinal cord rather easy. In addition, the procedure described in this report preserves the ultrastructural details of the developing neural tissue.     

Selective binding, uptake, and retrograde transport of tetanus toxin by nerve terminals in the rat iris. An electron microscope study using colloidal gold as a tracer

A series of specific macromolecules (tetanus toxin, cholera toxin, nerve growth factor [NGF], and several lectins) have been shown to be transported retrogradely with high selectivity from terminals to cell bodies in various types of neurons. Under identical experimental conditions (low protein concentrations injected), most other macromolecules, e.g. horseradish peroxidase (HRP), albumin, ferritin, are not transported in detectable amounts. In the present EM study, we demonstrate selective binding of tetanus toxin to the surface membrane of nerve terminals, followed by uptake and subsequent retorgrade axonal transport. Tetanus toxin or albumin was adsorbed to colloidal gold particles (diam 200 A). The complex was shown to be stable and well suited as an EM tracer. 1-4 h after injection into the anterior eye chamber of adult rats, tetanus toxin-gold particles were found to be selectively associated with membranes of nerve terminals and preterminal axons. Inside terminals and axons, the tracer was localized mainly in smooth endoplasmic reticulum (SER)-like membrane compartments. In contrast, association of albumin-gold complexes with nervous structures was never observed, in spite of extensive uptake into fibroblasts. Electron microscope and biochemical experiments showed selective retrograde transport of tetanus toxin-gold complexes to the superior cervical ganglion. Specific binding to membrane components at nerve terminals and subsequent internalization and retrograde transport may represent an important pathway for macromolecules carrying information from target organs to the perikarya of their innervating neurons.     

Immunogold labeling of metaphase cells

A method is presented for the phenotypic identification of metaphase cells stained for chromosome aberration and SCE analysis. The cells are labeled in suspension with antibodies conjugated with colloidal gold, and then chromosome preparations are made using a cytocentrifuge. A silver development (IGSS) procedure is used to enhance the gold labeling for light microscopy. A variety of fixatives may be employed, permitting various cytogenetic and cytochemical staining procedures to be used.     

DNA sequence mapping using electron microscopy

DNA sequences can be mapped on chromosomes at high resolution in the electron microscope after hybridization with a nonisotopically labeled probe followed by detection with a two-step antibody reaction employing a colloidal gold tag. Hybridization probes can be modified with biotin-dUTP, digoxigenin-dUTP, dinitrophenyl-dUTP, or N-acetoxy-2-acetylaminofluorene (AAF). The availability of different sizes of colloidal gold particles permits the simultaneous detection of several sequences. In addition, low signals can be amplified either with an antibody sandwich scheme or by silver intensification. This technology is applicable both to TEM and SEM preparations of chromosomes, and we have used it to map a number of highly and moderately repeated sequences on whole mount metaphase chromosomes.     

1-naphthol-pyronin B as a novel substrate for silver intensification: application to light and electron microscopic immunocytochemistry of neuroendocrine systems

We describe a modification of silver intensification of immunoperoxidase end-product using 1-naphthol (1N) and 1N enhanced by pyronin B after suppressing nonspecific tissue argyrophilia with a solution of penicillamine and merthiolate buffered near neutral pH. This approach facilitates the preservation of a second antigen sequentially labeled in the same tissue section for light microscopic double immunolabeling experiments and also allows retention of ultrastructural detail. Using this protocol, we obtained rapid and uniform silver intensification of somatostatin (SRIF)-immunoreactive (IR) neuronal perikarya and processes in the rat hypothalamic paraventricular nucleus (PVN). Ultrastructurally, 1N- and 1N-pyronin B-silver intensified reaction product was clearly recognized by the presence of a coarse intracellular precipitate of high electron density. Light microscopic double-immunolabeling studies demonstrated the association between SRIF- and thyrotropin-releasing hormone (TRH)-IR neuronal systems in the PVN. We propose that silver intensification of 1N and 1N-pyronin B is a useful alternative to standard methods of silver intensification of immunoperoxidase reaction product at both light and ultrastructural levels and may be particularly amenable for double-immunolabeling studies.     

Origin of the met-enkephalinergic innervation of the lateral septum in the rat

Summary The location of the cells giving rise to the methionine-enkephalin (Met-Enk)-ergic innervation of the lateral septal nucleus has been investigated in the rat by combining immunohistochemistry and retrograde axonal tracing. Small volumes (0.06 l) of apo-horseradish peroxidase (Apo-HRP) conjugated to wheat-germ agglutinin (WGA) and coupled with colloidal gold particles (WGA-ApoHRP-gold) were injected into the lateral septum. The retrogradely labeled cell bodies were visualized by silver intensification of the gold particles on Vibratome sections that were subsequently processed for immunohistochemistry for Met-Enk. Cells labeled with WGA-ApoHRP-gold were observed in the septal area, throughout the hypothalamus (mainly in the perifornical and lateral nuclei) and in the mesencephalon. The localization of Met-Enk-immunoreactive cells was as previously described. With the exception of a few septal cells close to the injection site, doubly labeled cells were found only in the perifornical nucleus of the hypothalamus. Almost all perifornical magnocellular cells were doubly labeled ipsilateral to the injection site, whereas on the opposite side, only about 25% of the Met-Enk-immunoreactive cells contained WGA-ApoHRP-gold. Other brain regions containing retrogradely labeled or Met-Enk-immunoreactive cells (particularly the raphe nuclei) did not show double-labeled neurons. This study demonstrates, using a new and sensitive technique for specific neurochemical tracing of tracts, that the origin of the Met-Enk-ergic innervation of the rat lateral septal nuclei lies in the magnocellular perifornical nuclei of the hypothalamus. The precise involvement of this pathway in limbic functions remains to be determined.     

The Intrinsic Organization of the Ventroposterolateral Nucleus and Related Reticular Thalamic Nucleus of the Rat: A Double-Labeling Ultrastructural Investigation with γ-Aminobutyric Acid Immunogold Staining and Lectin-Conjugated Horseradish Peroxidase

An electron-microscopic investigation of the synaptic organization of the rat's ventroposterolateral nucleus (VPL) and of a reticular thalamic nucleus (RTN) area related to somatosensory thalamic nucleus was performed. In a group of 11 rats, wheatgerm agglutinin conjugated to horseradish peroxidase (WGA:HRP) was injected either in the first somatosensory area of cortex (SI) or in the dorsal column nuclei (DCN). The retrogradely and/or anterogradely transported enzyme was visualized using paraphenylenediamine-pyrocatechol (PPD-PC) as substrate. In a second series of six experiments, an immunocytochemical procedure using a specific anti-γ-aminobutyric acid (anti-GABA) was employed. Postembedding localization of GABA was performed for ultrastructural observation by means of the colloidal gold immunostaining procedure. Thin sections of recognized VPL and RTN areas from WGA:HRP-injected animals were further processed for immunocytochemistry in order to localize simultaneously, at the electron-microscopic level, the transported enzyme and GABA.

The results obtained with this procedure demonstrated that HRP-labeled terminals from DCN contacted the soma and proximal dendrites of VPL neurons, while the terminals labeled after SI cortical injections were predominantly localized to the distal portion of the dendrites. The same cortical injection also determined the presence of labeled synaptic boutons contacting the soma, and both proximal and distal dendrites of RTN neurons. GABA-immunolabeled terminals were observed in VPL in a number larger than those observed with other methods, since not only typical F terminals were labeled but also terminals containing round and/or pleomorphic vesicles. GABA-ergic terminals contacted the soma and the proximal and distal dendrites of VPL neurons, while in RTN cells they made synaptic contact mainly with the soma and proximal dendrites. In the double-labeling experiments, terminals containing both HRP and specific immunogold GABA staining were never observed.

The present data provide a direct demonstration of the presence of a strong inhibitory input from RTN upon VPL neurons and of the existence of autoinhibition within RTN neurons.     

Immunogold–silver staining-on-a-chip biosensor based on cross-flow chromatography

Immunogold–silver staining (IGSS) was adopted in cross-flow chromatographic analysis in which immunological reactions and silver intensification were sequentially conducted in the vertical and horizontal directions, respectively. Factors controlling the performance, except the silver substrate solution, were optimized to increase the signal-to-background ratio in measurements of cardiac troponin I as a model analyte. In generating the signal, the size of colloidal gold catalyst was critical; the smallest size (5-nm diameter) in the selected range yielded the highest colorimetric signal. To maintain the low background, two processes, blocking the remaining surfaces of membrane after antibody immobilization and washing the residual tracer after immunological reaction, were necessary. Self-nucleation of silver ions also caused a background signal and was controlled to some degree by decreasing the hydrodynamic force that arose when the substrate solution was supplied in the horizontal direction. Finally, a new chip (IGSS-on-a-chip; IOC) that allowed for convenient, efficient IGSS was produced by injection molding of plastic. This method enhanced the detection capability by 51-fold compared to the conventional rapid test kit using 30 nm-sized colloidal gold as the tracer. The IOC biosensor results also showed that silver intensification yield via cross flow after immunological reaction was 19% higher than that by traditional incubation.     

Optimal Parameters for the Histochemical Demonstration of Acetylcholinesterase in Plastic Sections of Rat Brain

A modified method for improved preservation and optical resolution of acetylcholinesterase (AChE)-containing structures in adult rat brain is described. Optimal tissue preparation included fixation in paraformaldehyde 4%, glutaraldehyde 0.1%, and sucrose 7% in 0.1 M Sorensen's phosphate buffer, pH 7.4, rinsing in buffer 50 mM with respect to NLL, Q and 2% with respect to sucrose, acetone dehydration, vacuum infiltration widi LKB Historesin, and polymerization at 4 C, overnight incubation of 10 μm sections at 37 C in the AChE histochemical reaction mixture and silver intensification according to Hedreen et al. Demonstration of AChE enzyme activity in the cholinergic projection from the rat basal forebrain to the ipsilateral hippocampus exemplifies the usefulness of the technique. The method provides an excellent demonstration of AChE-positive axonal processes and enables the pharmacohis-tochemical visualization of cholinergic neurons. This procedure offers a convenient method for analysis of cholinergic neurons that avoids potential artifacts inherent in other AChE histochemical procedures.     

Enhanced ultrastructural visualization of the horseradish peroxidase-tetramethylbenzidine reaction product

Ultrastructural visualization of the horseradish peroxidase-tetramethylbenzidine (HRP-TMB) reaction product within trigeminal ganglion cells and brain stem axons and terminals following HRP injections into the pulpal chambers of cat teeth is enhanced by utilization of a modified osmication procedure that converts the reaction product to a markedly stable and electron-dense form. The results following the use of the modified osmication procedure (pH 5.0 phosphate buffer at 20 degrees C for 12 hours) are compared to results obtained by following Carson's osmication protocol (Carson KA, Mesulam M-M: J Histochem Cytochem 30:425, 1982; Carson KA, Mesulam M-M: In Tracing Neural Connections with Horseradish Peroxidase. Edited by M-M Mesulam. J Wiley, Chichester, England, 1982, p 153-184) (pH 6.0 phosphate buffer at 45 degrees C for 45 min). The results suggest that the conversion of the HRP-TMB reaction product to an electron-dense form during osmication is intimately associated with the pH of the phosphate buffer and the total time of osmication.     

Sensitivity in horseradish peroxidase neurohistochemistry: a comparative and quantitative study of nine methods.

Nine currently available methods for HRP neurohistochemistry have been compared with each other on matching tissue sections from four rats and four rhesus monkeys. The nine methods investigated in this report are the diaminobenzidine (DAB) procedures of LaVail JH and LaVail MM (J Comp Neurol 157:303, 1974), of Adams JC (Neuroscience 2:141, 1977) and of Streit P and Reubi JC (Brain Res 126:530, 1977); the benzidine dihydrochloride (BDHC) procedures of Mesulam M-M (J Histochem Cytochem 24:1273, 1976) and of De Olmos J and Heimer L (Neurosci Lett 6:107, 1977); the o-dianisidine (O-D) procedure of De Olmos J (Exp Brain Res 29:541, 1977); the p-phenylenediamine dihydrochloride and pyrocatechol (PPD-PC) procedure of Hanker JS et al., (Histochem J 9:789, 1977) and the tetramethyl benzidine (TMB) procedures of Mesulam M-M (J Histochem Cytochem 26:106, 1978) and of De Olmos J et al. (J Comp Neurol 181:213, 1978). Quantitative comparisons were based on counts of retrogradely labeled perikarya. The extent of anterograde transport and the size of the injection site were also compared at a more qualitative level. The results indicate that one TMB procedure (Mesulam M-M, J Histochem Cytochem 26:106, 1978) is distinctly superior to each of the other eight procedures in the number of labeled perikarya that it can demonstrate. Furthermore, these differences are statistically significant at better than the 0.05 level of confidence. Differences in sensitivity are most evident when the perikarya contain small quantities of transported HRP. The same TMB method also demonstrates more anterograde transport and a larger injection site than all the other procedures. If less sensitive procedures are employed, afferent or efferent connections that are clearly demonstrated by this TMB procedure are either underestimated or completely overlooked. It is suggested that sensitivity in HRP neurohistochemistry is determined by multiple factors which include the method of fixation, post-fixation storage, the choice of chromogen, the incubation parameters, the type of HRP enzyme that is administered, and the postreaction treatment.