Simultaneous ultrastructural demonstration of retrogradely transported horseradish peroxidase and choline acetyltransferase immunoreactivity

In order to study the synaptic connections of neurons identified by their projection target and neurotransmitter content, we have adapted a method of combining retrograde tracing of horseradish peroxidase (HRP) and immunocytochemistry at the electron microscopic level. HRP was injected into the rat amygdala. Sections from the rostral forebrain were processed according to the 3,3'-diaminobenzidine/glucose oxidase reaction followed by choline acetyltransferase (ChAT) localization. Neurons in the ventral pallidum which contained both the diffuse immunoperoxidase reaction product (ChAT) and large electron dense bodies characteristic of retrogradely transported HRP were defined as double labeled, i.e. cholinergic neurons that project to the amygdaloid body.     

Simultaneous ultrastructural demonstration of retrogradely transported horseradish peroxidase and choline acetyltransferase immunoreactivity

Summary In order to study the synaptic connections of neurons identified by their projection target and neurotransmitter content, we have adapted a method of combining retrograde tracing of horseradish peroxidase (HRP) and immunocytochemistry at the electron microscopic level. HRP was injected into the rat amygdala. Sections from the rostral forebrain were processed according to the 3,3-diaminobenzidine/glucose oxidase reaction followed by choline acetyltransferase (ChAT) localization. Neurons in the ventral pallidum which contained both the diffuse immunoperoxidase reaction product (ChAT) and large electron dense bodies characteristic of retrogradely transported HRP were defined as double labeled, i.e. cholinergic neurons that project to the amygdaloid body.     

A reliable method for demonstrating axonal degeneration shortly after axotomy

A method has been elaborated by which degenerating axons can be selectively impregnated with silver. Based on reconsideration of the physicochemical mechanisms of the degeneration methods it takes advantage of physical developers over the chemical ones. The staining procedure is applied to frozen sections of brains fixed with formol. It consists of 6 steps: (1) pretreatment with alkaline hydroxylamine, (2) washing in acetic acid, (3) impregnation in silver nitrate in the presence of ferric ions, (4) washing in citric acid, (5) physical development, and (6) washing in acetic acid. By electron microscopy silver precipitates by this method are almost entirely restricted to the cytoplasm of dense, degenerating axons, sparing mitochondria and myelin sheaths. No special expertise is required to achieve reproducible results. Large numbers of sections treated simultaneously, and large sections, can be stained uniformly. Light microscopic criteria are described which help diagnose the source of possible failures. Low background staining allows dark field illumination and television image analysis to be applied. The method works at survival times of only 3 to 5 days after axotomy. Hence, degenerating axons and axon terminals can be stained in alternating sections from the same brain using this method and another being described separately, which, using different conditions, demonstrates degenerating axon terminals.     

The temporo-spatial course of degeneration after cutting cortico-cortical connections in adult rats

Summary Adult albino rats received callosotomies or lesions in the paracingular cortex. Between 12 h and 3 months after injury the structure and topography of the degeneration products were studied by light- and electron-microscopy. The degeneration process was quantified by television-image analysis applied to sections prepared according to a new technique that stains reliably degenerating terminals and lysosomes (Gallyas et al. 1980). All types of cortico-cortical connections show a multiphasic degeneration process: During a precursor stage a small number of dense bodies and mitochondrial granules are stained. These and the few early degenerating axon terminals are much more diffusely distributed than the large number of terminals that degenerate during the following period. The terminal degeneration shows a biphasic time course. One maximum appears at 2–7 days post operation, which corresponds to the well known direct consequence of axotomy. The second peak at 10–20 days post operation could be caused by transneuronal reorganization of the cortical connectivity. Terminal degeneration always begins along the borders between cortical regions and areas, but it may change its laminar and columnar distribution pattern during the second phase. The degeneration products that are phagocytosed by astrocytes seem to be removed by intracellular transport to their perivascular endfeet. The degeneration process ends with fiber degeneration which, especially in laminae I and VI, may form a separate peak after 20 days or more.On leave from: Department of Neurosurgery, University of Göttingen, Federal Republic of Germany;On leave from: First Department of Anatomy, Semmelweis University, Medical School, Budapest, Hungary     

Ascending projections to the hypothalamus and limbic nuclei from the dorsolateral pontine tegmentum: a biochemical and electron microscopic study.

Axons arising from the dorsolateral pontine tegmentum of the rat were traced in various hypothalamic and limbic nuclei by the electron microscopic degeneration method (0.5-8 day survival times) and by measuring regional norepinephrine (NE) concentrations after 12 days of survival using a radioenzymatic method. Significant reductions (41-85%) in NE contents were observed in the supraoptic, arcuate, basal and lateral amygdaloid nuclei and in the hippocampus 12 days after the bilateral electrolytic lesions of the locus coeruleus. No changes in NE concentrations were observed in the ventromedial, septal, central amygdaloid nuclei, in the median eminence and olfactory tubercle. Parabrachial lesions resulted in a decrease of NE content only in the olfactory tubercle. By means of electron microscopy terminal degeneration was found in the hypothalamic paraventricular, dorsomedial nuclei, in the median eminence, in the bed nucleus of the stria terminalis, in the central, lateral and basal amygdaloid nuclei, in the hippocampus and in the anterior ventral thalamic nucleus.     

A Reliable Method for Demonstrating Axonal Degeneration Shortly After Axotomy

A method has been elaborated by which degenerating axons can be selectively impregnated with silver. Based on a reconsideration of the physicochemical mechanisms of the degeneration methods it takes advantage of physical developers over the chemical ones. The staining procedure is applied to frozen sections of brains fixed with formol. It consists of 6 steps: (1) pretreatment with alkaline hydroxylamine, (2) washing in acetic acid, (3) impregnation in silver nitrate in the presence of ferric ions, (4) washing in citric acid, (5) physical development, and (6) washing in acetic acid. By electron microscopy silver precipitates by this method are almost entirely restricted to the cytoplasm of dense, degenerating axons, sparing mitochondria and myelin sheaths. No special expertise is required to achieve reproducible results. Large numbers of sections treated simultaneously, and large sections, can be stained uniformly. Light microscopic criteria are described which help diagnose the source of possible failures. Low background staining allows dark field illumination and television image analysis to be applied. The method works at survival times of only 3 to 5 days after axotomy. Hence, degenerating axons and axon terminals can be stained in alternating sections from the same brain using this method and another being described separately, which, using different conditions, demonstrates degenerating axon terminals.