Efferent connections of the striatum with the Ep field of the temporal cortex in the cat

When horseradish peroxidase was injected into the Ep area of the temporal cortex of 5 cats, the distribution of the labelled neurons in the strio-pallidum and in the nucleus of Meynert was similar in all the cases. In the striatum predominantly large cells (in the nucleus caudatus and in the putamen), as well as middle and small (in the putamen) cells were labelled. Comparing the form and size of the labelled cells in the striatum, revealed in Golgi preparations, it is possible to conclude that large labelled neurons correspond to long-axonal sparsely-branching reticular neurons, and middle and small--to long-axonal densely-branching dendroid "spinular" neurons. The large cells of the striatum can be considered as a part of a vast macrocellular ascending system of the forebrain, its preservation maintains the higher integrative functions of the brain.     

Ultrastructural tracer studies on the permeability of the Malpighian tubule of the Pill Millipede,Glomeris marginata (Villers)

Summary The electron-dense tracers ferritin, and iron-dextran, and the protein horseradish peroxidase, have been used to investigate the ultrastructural basis of permeability in the upper and lower segments of the Malpighian tubules of Glomeris marginata. All these materials were able to cross the basal lamina and enter the tubule lumen of the upper segment, and it was established that horseradish peroxidase was able to enter the channels which interrupt the apical junctions.In the upper segment, ferritin, iron-dextran, and horseradish peroxidase are all taken up and accumulated within intracellular vesicles. In the lower segment ferritin and iron-dextran enter the cells but become generally distributed over the cyptoplasm, as well as entering membrane-bounded vacuoles. The behaviour of horseradish peroxidase could not be assessed owing to the presence of endogenous peroxidase activity in the cells.After fixation by direct application of glutaraldehyde to the undissected tubules, the extracellular spaces contained large numbers of membrane-bounded vesicles. The significance of these observations is discussed in relation to the physiological activities of the tubules.The authors are indebted to the Science Research Council for financial supportThe authors wish to thank Mrs. Margarita Petri for her technical assistance and advice     

Fine structural and ultracytochemical studies on the lymphocytes in three types of genetic mucopolysaccharidoses

Lymphocytes from 6 patients with 3 types of genetic mucopolysaccharidoses (Hurler's syndrome, Hunter's syndrome and Morquio's syndrome) contained numberous vacuoles in their cytoplasm. The size of the vacuoles ranged from approximately 300 nm to 750 nm. The percentage of the lymphocytes with vacuoles varied from 10% to 38%. The vacuoles showed acid phosphatase activity, which indicated their lysosommal nature. Staining with dialyzed iron solution usually localized acid mucosubstance in the peripheral region of these vacuoles after glutaraldehyde fixation. Ferritin and horseradish peroxidase were observed in the vacuoles after incubation of the patient's lymphocytes with these tracers. This finding indicates the participation of endocytosis in the formation of these vacuoles.     

Identification of tuberculo-ventral neurons in the polymorphic layer of the rat dorsal cochlear nucleus

The tuberculo-ventral tract represents a short nervous circuit within the auditory cochlear nuclei. Tuberculo-ventral neurons of the dorsal cochlear nucleus send isofrequency inhibitory inputs to bushy cells of the ventral cochlear nucleus. Injection of wheat germ agglutinin conjugated to horseradish peroxidase into the rat ventral cochlear nucleus, labelled tuberculo-ventral neurons retrogradely in the deep polymorphic layer of the ipsilateral dorsal cochlear nucleus. Five to 20% of the perimeter of these cells was covered by synaptic boutons, most of which contained flat and pleomorphic vesicles. These boutons contained glycine and sometimes GABA. Occasional small axo-somatic boutons contained round vesicles and were immunonegative for both glycine and GABA. This study shows that the synaptic profile of tuberculo-ventral neurons is different from that of other medium-size glycinergic neurons within the polymorphic layer or more superficial regions of the dorsal cochlear nucleus like cartwheel neurons. In fact the latter mostly receive boutons that contain pleomorphic vesicles.     

Sources of thalamic afferents projecting to the suprasylvian gyrus of the black sea porpoise

Neurons sending fibers to different loci of the suprasylvian gyrus (SSG) of the porpoise(Phocaena phocaena) cortex were located in the thalamus by retrograde horseradish peroxidase transport and fluorescent tracing techniques. Horseradish peroxidase injection into the anterior section of the suprasylvian gyrus led to retrograde labelling of neurons in the lateral portion of the ventrobasal complex of nuclei and the ventroposteroinferior nucleus. A group of labelled cells was found in the ventral section of the main medial geniculate nucleus. Injecting bisbenzimide into different loci of the medial suprasylvian gyrus also led to retrograde labelling of neurons belonging to the ventral division of the main medial geniculate nucleus. Somewhat lower numbers of labelled cells were found in the inferior nucleus of the pulvinar. Small groups of labelled neurons were also found in the lateral nucleus of the pulvinar, the medioventral nucleus of the medial geniculate body, and the posterior complex of nuclei. A similar distribution of labelled cells was also observed after injecting bisbenzimide into the more caudal portion of the gyrus, although the location of labelled cells in the ventral division of the main medial geniculate nucleus and the lower pulvinar nucleus were shifted in a lateral direction.A. N. Severtsov Institute of Animal Evolutionary Moprhology and Ecology, Academy of Sciences of the USSR, Moscow. National University, Singapore. Translated from Neirofiziologiya, Vol. 21, No. 4, pp. 529–539, July–August, 1989.     

Localization and morphometric analysis of masticatory muscle afferent neurons in the nucleus of the mesencephalic root of the trigeminal nerve in the cat

Injections of horseradish peroxidase (HRP) were made into the ipsilateral temporal muscle and contralateral masseter muscle of 10 cats in order to identify and characterize neurons in the nucleus of the mesencephalic root of the trigeminal nerve that innervate muscle receptors in the orofacial periphery. Neurons labelled by HRP injections and unlabelled cells from 5 control cats were measured with a computer-based image analyzer, and their position was mapped on a stereotaxic graph. Cells that innervate the masseter and temporal muscles were identified throughout the rostrocaudal extent of the nucleus. There was no indication of a somatotopic pattern nor of a specific segregation within the nucleus for cells innervating muscle receptors. The nucleus contained small, rounded unipolar neurons located primarily in the dorsal border of the periaqueductal gray (PAG) matter in the rostral part of the nucleus and larger oval unipolar neurons which were scattered throughout the nucleus, but were predominant in the pontine portion of the nucleus. HRP injections labelled both large and small cells, as well as occasional multipolar cells. The last-mentioned tended to be located in the lateral margins of the PAG. The mean geometric values obtained for the control group were: area 552.7 microns2 perimeter 110.3 microns; maximum diameter 36.0 microns. and diameter of an equivalent circle 26.1 microns. The mean values of the labelled neurons were: area 606.6 microns2; perimeter 100.1 microns; maximum diameter 36.0 microns, and diameter of an equivalent circle 27.2 microns.     

A proposed neural pathway for vocalization in South African clawed frogs,Xenopus laevis

Vocalizations of South African clawed frogs are produced by contractions of laryngeal muscles innervated by motor neurons of the caudal medulla (within cranial nerve nucleus IX-X). We have traced afferents to laryngeal motor neurons in male and female frogs using retrograde axonal transport of horseradish peroxidase conjugated to wheat germ agglutinin (HRP-WGA). After iontophoretic injection of HRP-WGA into n. IX-X, retrogradely labelled neurons were seen in the contralateral n. IX-X, in rhombencephalic reticular nuclei, and in the pre-trigeminal nucleus of the dorsal tegmental area (DTAM) of both males and females.     

THE FINE STRUCTURAL LOCALIZATION OF ENDOGENOUS AND EXOGENOUS PEROXIDASE ACTIVITY IN KUPFFER CELLS OF RAT LIVER

Endogenous peroxidase activity has been demonstrated in sections of rat liver fixed briefly by glutaraldehyde perfusion and incubated in Graham and Karnovsky's medium for cytochemical demonstration of peroxidase activity (29). In 25–40% of sinusoidal cells, an electron-opaque reaction product is localized in segments of the endoplasmic reticulum, including the perinuclear cisternae, a few Golgi vesicles and saccules and in some large membrane-bounded granules. This staining is abolished after prolonged fixation or boiling of tissue sections in glutaraldehyde, and in the absence of H₂O₂ or DAB from the incubation medium. Furthermore, the reaction is inhibited completely by sodium azide and high concentrations of H₂O₂, and partially by KCN and aminotriazole. Among the different cells in hepatic sinusoids, the nonphagocytic "fat-storing" cells (39) are always peroxidase negative, whereas the lining cells in process of erythrophagocytosis are consistently peroxidase positive. The possible biological significance of endogenous peroxidase in Kupffer cells is discussed. In addition, the uptake of exogenous horseradish peroxidase by Kupffer cells has been investigated. The exogenous tracer protein, which in contrast to endogenous peroxidase of Kupffer cells is not inhibited by prolonged aldehyde fixation, is taken up by micropinocytosis and remains confined to the lysosomal system of Kupffer cells. The significance of these observations in respect to some recent studies suggesting localization of exogenous peroxidases in the endoplasmic reticulum of Kupffer cells and peritoneal macrophages (22, 23) is briefly discussed.     

A light- and electron-microscopic study of enzymes in the embryonic shell-forming tissue of the freshwater snail, Biomphalaria glabrata

Abstract. The mode of formation of the molluscan exoskeleton is still poorly understood, but studies on adult snails indicate that enzymes involved in vertebrate bone formation also participate in mollusc shell formation. The enzymes peroxidase, alkaline phosphatase, and acid phosphatase are expressed in a constant pattern and help to identify the different zones of the adult shell-forming tissue. The present study evaluates whether the expression of these enzymes is also a tool for the identification of the developing zones of the embryonic shell-forming tissue. Thus, we analyzed the temporal and spatial activity of the above-mentioned enzymes and of tartrate-resistant acid phosphatase in the shell forming tissues in Biomphalaria glabrata. Embryos of different age groups and adults were studied; alkaline phosphatase activity was seen in very young embryos in the shell field invagination prior to the secretion of any shell material, while peroxidase activity was present from the start of the periostracum production. Acid phosphatase, found in considerable amounts in yolk granules and albumen cells, appeared in the embryonic shell-forming tissue in relatively few Golgi stacks. Tartrate-resistant phosphatase was not present in embryos, but was found in adults in the same zone of the mantle edge as acid phosphatase. Using the enzymes as cell markers, the differentiation of the embryonic shell-forming tissue to the different zones of the adult mantle edge could clearly be followed.     

Use of peroxidatic-enzyme staining to enhance resolution of cultured mammalian cells under phase microscopy.

Staining of glutaraldehyde-fixed mammalian cells with peroxidatic enzymes (horseradish peroxidase or horse heart cytochrome c) greatly enhances resolution of their structure under phase microscopy. The topography of cell processes and regions of intercellular contact and overlapping is resolved precisely, even in dense cultures mounted in media which ordinarily do not permit clear demonstration of these areas. The technique is therefore a useful aid to the study of cultured cells with phase optics. Labeling depends on introducing free aldehydes into cells through the use of bifunctional fixatives such as glutaraldehyde. Acetone or formaldehyde fixation prevents staining, and labeling intensity is greatly diminished by pretreatment with spermine, a polyamine that reacts with glutaraldehyde. Electron microscopy reveals that peroxidase tags membranes preferentially; some areas are labeled smoothly, others in a punctate manner. Ribosomes are sharply contrasted, but nuclei remain unstained. Cytochrome c labels condensed nuclear chromatin intensely, and also stains ribosomes and portions of the cytoplasmic ground substance; membranes are mostly unmarked.     

Use of Peroxidatic-Enzyme Staining to Enhance Resolution of Cultured Mammalian Cells Under Phase Microscopy

Staining of glutaraldehyde-fixed mammalian cells with peroxidatic enzymes (horseradish peroxidase or horse heart cytochrome c) greatly enhances resolution of their structure under phase microscopy. The topography of cell processes and regions of intercellular contact and overlapping is resolved precisely, even in dense cultures mounted in media which ordinarily do not permit clear demonstration of these areas. The technique is therefore a useful aid to the study of cultured cells with phase optics. Labeling depends on introducing free aldehydes into cells through the use of bi functional fixatives such as glutaraldehyde. Acetone or formaldehyde fixation prevents staining, and labeling intensity is greatly diminished by pretreatment with spermine, a polyamine that reacts with glutaraldehyde. Electron microscopy reveals that peroxidase tags membranes preferentially; some areas are labeled smoothly, others in a punctate manner. Ribosomes are sharply contrasted, but nuclei remain unstained. Cytochrome c labels condensed nuclear chromatin intensely, and also stains ribosomes and portions of the cyto plamic ground substance; membranes are mostly unmarked.     

The inhibition of peroxidase and indole-3-acetic acid oxidase activity by British Anti-Lewisite

British Anti-Lewisite (BAL) binds to horseradish peroxidase in a manner which results in inhibition of both peroxidatic and oxidative functions of the enzyme. BAL competes with hydrogen peroxide for binding on peroxidase, and the inhibition of peroxidatic activity is irreversible. Solutions of purified horseradish peroxidase and individually resolved peroxidase isozymes show a gradual loss of peroxidatic activity with time when incubated with BAL. In these same treatments, however, the inhibition of indole-3-acetic acid (IAA) oxidase activity is immediate. With increasing amounts of enzyme in the incubation mixture, IAA oxidase activity is not completely inhibited and is observed following a lag period in the assay which shortens with longer incubation times. Peroxidase activity during this same time interval shows a lag period which increases with longer incubation times. Lowering the pH removed the lag period for oxidase activity, but did not change the pattern of peroxidase activity. These results suggest that the sites for the oxidation of indole-3-acetic acid and for peroxidatic activity may not be identical in horseradish peroxidase isozymes.     

Descending neuronal projections to the lumbar segment of the spinal cord of cats

In the experiments, performed on cats by means of retrograde axonal horseradish peroxidase transport, localization of the sources of descending supra- and propriospinal projections to the area of the lumbar parts of the spinal cord, where the generator of locomotor movements is located. After local administration of horseradish peroxidase into the spinal cord, the greatest amount of the labelled neurons is observed in the ipsilateral reticular formation and in the Koelliker-Fuse nucleus. Comparison of the number of neurons, forming the descending projections from the I cervical up to the IV lumbar segments demonstrates an essential predominance of short propriospinal connections over the long, as well as over the supraspinal ones.     

Cells of origin of the hippocampal afferent projection from the nucleus reuniens thalami

Summary Neurons of the nucleus reuniens thalami stained with Golgi methods are compared to cells in this nucleus labelled in retrograde fashion after hippocampal injections of horseradish peroxidase. The cellular morphology ranges from fusiform to multiangular with most cells showing radiating processes characteristic of neurons in the reticular core. Dendrites are long and relatively smooth, with a few sparsely distributed spinous processes. These cells are comparable to the cholinergic cells of the median septal/diagonal band area which also project into the hippocampal formation.We would like to thank Mr. Al Cibivicious for his excellent technical assistance. This research was supported in part by general research funds awarded to R.H.B. by East Tennessee State University     

Differential Distribution of Retinoic Acid Synthesis in the Chicken Embryo as Determined by Immunolocalization of the Retinoic Acid Synthetic Enzyme, RALDH-2

Retinaldehyde dehydrogenase type 2 (RALDH-2) is a major retinoic acid generating enzyme in the early embryo. Here we report the immunolocalization of this enzyme (RALDH-2-IR) in stage 6-29 chicken embryos; we also show that tissues that exhibit strong RALDH-2-IR in the embryo contain RALDH-2 and synthesize retinoic acid. RALDH-2-IR indicates dynamic and discrete patterns of retinoic acid synthesis in the embryo, particularly within the somitic mesoderm, lateral mesoderm, kidney, heart, and spinal motor neurons. Prior to somitogenesis, RALDH-2-IR is present in the paraxial mesoderm with a rostral boundary at the level of the presumptive first somite; as the somites form, they exhibit strong RALDH-2-IR. Cervical presomitic mesoderm exhibits RALDH-2-IR but thoracic presomitic mesoderm does not. Neural crest cells do not express detectable levels of RALDH-2, but migrating crest cells are associated with RALDH-2 expressing mesoderm. The developing limb mesoderm expresses little RALDH-2-IR; however, RALDH-2-IR is strongly expressed in tissues adjacent to the limb. The most lateral, earliest-projecting motor neurons at all levels of the spinal cord exhibit RALDH-2-IR. Subsequently, many additional motor neurons in the brachial and lumbar cord regions express RALDH-2-IR. Motor neuronal expression of RALDH-2-IR is present in the growing axons as they extend to the periphery, indicating a potential role of retinoic acid in nerve influences on peripheral differentiation. With the exception of a transient expression in the facial/vestibulocochlear nucleus, cranial motor neurons do not express detectable levels of RALDH-2-IR.     

The beta sector of the rabbit's dorsal lateral geniculate nucleus

The beta sector of the rabbit's dorsal lateral geniculate nucleus is a small region of nerve cells scattered among the fibres of the geniculocortical pathway. In its topographical relations it resembles the perigeniculate nucleus of carnivores, which contains neurons driven by geniculate and visual cortical neurons and which sends inhibitory fibres back into the geniculate relay. We have traced retinogeniculate, geniculocortical and corticogeniculate pathways in rabbits by using horseradish peroxidase or radioactively labelled proline and have found that the beta sector resembles the perigeniculate nucleus in receiving no direct retinal afferents, sending no efferents to the visual cortex (V-I), and receiving afferents from the visual cortex. The corticogeniculate afferents are organized so that the visual field map in the beta sector and the main part of the lateral geniculate relays are aligned, as are the maps in the cat's perigeniculate nucleus and the main part of the geniculate relay of carnivores. Electron microscopical studies show similar types of axon terminals in the rabbit and the cat for the main part of the geniculate relay on the one hand and for the beta sector and the perigeniculate nucleus on the other. Earlier observations that the proportion of putative inhibitory terminals (F-type terminals) is lower in the rabbit's than the cat's geniculate region are confirmed. A major difference between the beta sector and the perigeniculate nucleus has been revealed by immunohistochemical staining for GABA. Whereas almost all of the cat's perigeniculate cells appear to be GABAergic, the proportion in the beta sector is much lower, and not significantly different from that found in the main part of the rabbit's geniculate relay. It is concluded that the beta sector shares many of the organizational features of the perigeniculate nucleus. A common developmental origin seems probable, but the functional differences remain to be explored.     

Neurons forming striatonigral connections in the rat brain

Using the retrograde axonic transport of horseradish peroxidase method the striatal neurons projections to substance nigra have been studied in rats. After peroxidase injection into substance nigra a considerable number of small and medium sized neurons (10-20 mkm) become labelled in the ipsilateral striatum. Large labelled striatal cells (20-25 mkm) have been found. Among labelled striatal neurons multipolar cells with triangular and oval body prevailed. The number of cells with elongated multipolar or spindle-shaped body was less. The data obtained disprove the conception that only large ("giant") neurons form the efferent striatal pathways to substance nigra.     

Enzymatic enhancement of the catalytic rate of sulfhydryl oxidase

The rate of oxidation of glutathione by solubilized sulfhydryl oxidase was significantly enhanced in the presence of horseradish peroxidase (donor:hydrogen-peroxide oxidoreductase, EC 1.11.1.7). This enhancement was proportional to the amount of active peroxidase in the assay, but could not be attributed solely to the oxidation of glutathione catalyzed by the peroxidase. A change in the Soret region of the horseradish peroxidase spectrum was observed when both glutathione and peroxidase were present. Moreover, addition of glutathione to a sulfhydryl oxidase/horseradish peroxidase mixture resulted in a rapid shift of the absorbance maximum from 403 nm to 417 nm. This shift indicates the oxidation of horseradish peroxidase. Spectra for three isozyme preparations of horseradish peroxidase, two acidic and one basic, all underwent this red-shift in the presence of sulfhydryl oxidase and glutathione. Cysteine and N-acetylcysteine could replace glutathione. Addition of catalase had no effect on the oxidation of peroxidase, indicating that the peroxide involved in the reaction was not derived from that released into the bulk solution by sulfhydryl oxidase-catalyzed thiol oxidation. Further evidence for a direct transfer of the hydrogen peroxide moiety was obtained by addition of glutaraldehyde to a sulfhydryl oxidase/horseradish peroxidase/N-acetylcysteine mixture. Size exclusion chromatography revealed the formation of a high-molecular-weight species with peroxidase activity, which was completely resolved from native horseradish peroxidase. Formation of this species was absolutely dependent on the presence of both the cysteine-containing substrate and sulfhydryl oxidase. The observed enhancement of sulfhydryl oxidase catalytic activity by the addition of horseradish peroxidase supports a bi uni ping-pong mechanism proposed previously for sulfhydryl oxidase.     

Altered reabsorption of protein by the renal cortex in rats treated with hypertonic saline or mannitol.

The reabsorption of horseradish peroxidase (HRP) by the proximal tubule cells of rat kidneys was investigated by measuring the concentration of HRP in total particulate fractions of the cortex 1/4 and 1 hr after intravenous injection, and by correlated cytochemical observations. When compared to the corresponding values of the control animals, the concentration of HRP 1 hr after injection was decreased approximately 10-fold in the renal cortex of rats which had received an intravenous injection of hypertonic saline or two subcutaneous injections of mannitol. The plasma clearance and the urinary excretion of HRP were not altered significantly after injection of hypertonic saline, but the plasma clearance was decreased and the urinary excretion increased after injection of mannitol. When the dose of injected HRP was varied, the reabsorption of HRP by the renal cortex was proportional to the dose in the experimental and the control animals. Cytochemical staining for peroxidase activity also showed that the phagosomes and phagolysosomes of the proximal tubule cells contained much less peroxidase in the experimental rats than in the control rats. After injection of mannitol, large vacuoles appeared in the proximal tubule cells. The vacuoles often contained peroxidase-positive granules (phagosomes) which varied in diameter from the limit of microscopic visibility up to several microns. Most of the vacuoles did not react for acid phosphatase activity, but lysosomes were often aggregated around the vacuoles and seemed to release acid phosphatase into the cytoplasm. Certain analogies between the reabsorption of protein and that of water by the proximal tubule cells are discussed.     

Ascending and descending projections to the inferior colliculus in the rat

The ascending and descending projections to the central nucleus of the inferior colliculus (IC) were studied with the aid of retrograde transport of horseradish peroxidase (HRP). HRP-labelled cells were found in contralateral cochlear nuclei, where the majority of different cell types was stained. Few labelled cells were observed in the ipsilateral cochlear nuclei. HRP-positive neurones were found in all nuclei of the superior olivary complex on the ipsilateral side with the exception of the medial nucleus of the trapezoid body, which was never labelled either ipsilaterally or contralaterally. The largest concentration of HRP-labelled cells was usually observed in the ipsilateral superior olivary nucleus. Smaller numbers of labelled cells were present in contralateral nuclei of the superior olivary complex. Massive projections to the inferior colliculus were found from the contralateral and ipsilateral dorsal nucleus of the lateral lemniscus and ipsilateral ventral nucleus of the lateral lemniscus. Many neurones of the central and external nuclei of the contralateral inferior colliculus were labelled with HRP. Topographic organisation of the pathways ascending to the colliculus was expressed in the cochlear nuclei, lateral superior olivary nucleus and in the dorsal nucleus of the lateral lemniscus. HRP--positive cells were found in layer V of the ipsilateral auditory cortex, however, the evidence for topographic organisation was lacking.