Histochemistry of the glycogen body of the turkey spinal cord

Summary Enzyme histochemical studies of the glycogen body of the turkey showed very little activity of suocinic dehydrogenase and cytochrome oxidase in the glycogen body cells, and marked activity of lactic dehydrogenase, NAD-diaphorase and the hexosemonophosphate shunt enzymes. Gradients of histochemical staining intensity for lactic and succinic dehydrogenase in the glycogen body and spinal cord were confirmed by biochemical assays of homogenates of these tissues. It was concluded that glycogen body metabolism is predominantly glycolytic. Alkaline phosphatase activity was weak; acid phosphatase activity was moderate. There was no acetyl cholinesterase or nonspecific cholinesterase activity in the glycogen body.This investigation was supported by U. S. Public Health Grant B 3250.Submitted in partial fulfillment of Masters' degree requirements.     

The craniocaudal extent of the glycogen body in the domestic chicken

All birds have a glial enclosed, glycogen-containing structure in the lumbosacral region of their spinal cords. Recently, a dorsal, central, glycogen-rich area surrounding the central canal in the brachial spinal cord was described in domestic chickens. In order to topographically delineate and histochemically describe this structure, fresh, frozen serial sections of chicken brains and spinal cords were processed for glycogen content, phosphorylase, succinic dehydrogenase and cholinesterase activities. The glycogen-rich area surrounding the central canal in the lumbosacral region is found at all levels of the spinal cord and lower medulla. In the upper medulla, it is located in the midline floor immediately ventral to the ependyma. It persists in this position until the level of the oculomotor complex where it ends. Phosphorylase positive regions closely parallel the glycogen distribution. No succinic dehydrogenase or cholinesterase activities are found in these areas.     

A histochemical study of cervical motor neurons and the posterior latissimus dorsi muscle in normal and dystropic chickens.

A chromatolysis study, 14 to 21 days following denervation, showed the spinal cord representation of the nerve to the posterior latissimus dorsi muscle to be in the ventrolateral cell column between cervical ganglia 14 and 15. to characterize cevical neruos nt undergoing chromatolysis, histochemical stuies were done the cords of additional nondenervated animals. Staining reactions for beta-hydrocybutyrate dehydrogenase, succinic dehydrogenase and cholinesterase did not reveal any quantitative differences between motor neurons in cervical segments 14 and 15 of normal and dystrophic birds. Motor neurons are positive for beta-hydroxybutyrate dehydrogenase and succinic dehydrogenase, but the surrounding neuropil is positive for the latter only. No pseudocholinesterase activity is found in the ventral horn cells, but true cholinesterase is present in most of the neurons...     

Development of the glycogen body of the Japanese quail, Coturnix japonica. I. Light microscopy of early development

The glycogen body is a functionally enigmatic structure located in lumbosacral region of the spinal cord in birds. This tissue is unique to birds, and, although it is believed to be present in all species, studies on the glycogen body to date have been confined largely to the domestic chicken. The present study is the first to describe the glycogen body of the Japanese quail (Coturnix japonica) during incubation and at hatching. Light microscopy and histochemistry were used to identify the glycogen body in the spinal cord of the developing quail beginning at 7 days of incubation and to ascertain the presence of nerve fibers in that tissue at hatching.     

Development of the glycogen body of the Japanese quail, Coturnix japonica: II. Observations of electron microscopy

Transmission electron microscopic observations of the relationships of the cells of the glycogen body and those of nervous tissue in the lumbosacral spinal cord show that one day after hatching, glycogen cells at the lateral margins of the glycogen body lie in close association with elements of the neuropil in the adjacent spinal cord. Glycogen cells and their processes appear to extend into the neuropil, where they contact other glycogen cells, blood vessels, neurons, and neuroglia. Junctional complexes and synapses occur among glycogen cells, astrocytes, and oligodendrocytes. Other indications of specialized activities were surmised by the presence of annulate lamellae in continuity with extensive arrays of smooth endoplasmic reticulum in several glycogen cells. These observations enhance our earlier views that cells of the avian glycogen body are metabolically active in the synthesis and degradation of glycogen for neuronal support and myelination in the central nervous system.     

Comparison of Cell Body Size and Oxidative Enzyme Activity in Motoneurons between the Cervical and Lumbar Segments in the Rat Spinal Cord after Spaceflight and Recovery

The cell body sizes and succinate dehydrogenase (SDH) activities of motoneurons in the dorsolateral region of the ventral horn at the cervical and lumbar segments in the rat spinal cord were determined following 9 days of spaceflight with or without 10 days of recovery on Earth. The motoneurons were divided into three types based on their cell body sizes; small-, medium-, and large-sized motoneurons. In control rats, there was no difference in the cell body size or SDH activity of small- and large-sized motoneurons between the cervical and lumbar segments. The SDH activity of medium-sized motoneurons in control rats was higher in the lumbar segment than in the cervical segment, while the cell body sizes of medium-sized motoneurons were identical. The SDH activity of medium-sized motoneurons in the lumbar segment decreased to a level similar to that in the cervical segment of control rats following spaceflight. In addition, the decreased SDH activity of medium-sized motoneurons persisted for at least 10 days of recovery on Earth. It is concluded that spaceflight selectively affects the SDH activity of medium-sized motoneurons in the lumbar segment of the spinal cord, which presumably innervate skeletal muscles having an antigravity function.     

A cytoarchitectonic scheme for the spinal cord of the domestic fowl, Gallus gallus domesticus: lumbar region.

In Nissl stained and silver impregnated transverse sections of the chick spinal cord it is possible to subdivide the gray matter of the lumbar region into ten cytoarchitectonically discrete regions or laminae. The laminae are basically similar in both brachial and lumbar regions of the chick cord, with minor exceptions in the dorsal horn. The laminar scheme postulated for the chick cord is , with the exception of the glycogen body and orientation of laminae 1, 2 and 3 in the dorsal horn, similar to the laminar scheme proposed by Rexed (1954) for the cat.     

Enzyme histochemistry of the spinal cord after experimental transection (Th 9) in the cat

Subpial complete resection of a 10 mm segment of the spinal cord at Th 9 was performed in 9 adult cats. Topographic enzyme histochemical investigations of the terminal clubs were performed after different survival times after transection in 7 cats and three days after a subsequent one-week-delayed autologous sciatic grafting procedure in the remaining two cats. For acid phosphatase (ACP), the count of active terminal clubs was high (200 per m2) from 12 hours until day 3 after transection. Then the count of active terminal clubs decreased to a low level (20 per m2) and remained the same until day 14. Removal of necrotic tissue and subsequent grafting with autologous sciatic nerve did not change these findings. For succinate dehydrogenase (SDH), the numbers of terminal clubs showed the same pattern at a lower level. The SDH defined terminal clubs were smaller than the ACP ones. The length of the SDH positive area decreased after 7 days while the ACP positive area remained the same until day 14. The SDH active terminal clubs are overgrown by the ACP positive terminal clubs, after the 7th day. Considering that SDH is linked to constructive activity in mitochondria and ACP to destructive activity in lysosomes, this phenomenon might be responsible for the termination of the capacity of the spinal cord tissue to regenerate.     

Comparison of the anatomical morphology of cervical vertebrae between humans and macaques: related to a spinal cord injury model

Non-human primates are most suitable for generating cervical experimental models, and it is necessary to study the anatomy of the cervical spine in non-human primates when generating the models. The purpose of this study was to provide the anatomical parameters of the cervical spine and spinal cord in long-tailed macaques (Macaca fascicularis) as a basis for cervical spine-related experimental studies. Cervical spine specimens from 8 male adult subjects were scanned by micro-computed tomography, and an additional 10 live male subjects were scanned by magnetic resonance imaging. The measurements and parameters from them were compared to those of 12 male adult human subjects. Additionally, 10 live male subjects were scanned by magnetic resonance imaging, and the width and depth of the spinal cord and spinal canal and the thickness of the anterior and posterior cerebrospinal fluid were measured and compared to the relevant parameters of 10 male adult human subjects. The tendency of cervical parameters to change with segmental changes was similar between species. The vertebral body, spinal canal, and spinal cord were significantly flatter in the human subjects than in the long-tailed macaques. The cerebrospinal fluid space in the long-tailed macaques was smaller than that in the human subjects. The anatomical features of the cervical vertebrae of long-tailed macaques provide a reference for establishing a preclinical model of cervical spinal cord injury.     

Characteristics of spinal cord-evoked responses in man

The averaged electrical potentials evoked by the stimulation of the peripheral nerves were recorded with surface electrodes over the lumbosacral, lower thoracic and cervical spine and with epidurally placed electrodes in the cervical area. The waveforms of the lumbosacral and cervical spinal cord potentials show similar complexity reflecting peripheral and central generators. The larger negative wave with at least two components is followed by a slower positive deflection. Evoked potentials recorded over the cervical segments of the spinal cord with epidural electrodes are of much higher amplitude and more complex waveform than those recorded with surface electrodes.     

The blood-brain barrier of the chick glycogen body (corpus gelatinosum) and its functional implications

Among recent vertebrates only birds possess a glycogen body (corpus gelatinosum), located in the rhomboidal sinus of the lumbosacral region of the spinal cord and separated from the neural tissue proper. Because of the specific topographical situation of this circumventricular organ, the structure of its vascular system is of special interest with respect to the still unsolved functional problems. The existence of a blood-brain barrier is demonstrated by the exclusion of intravascularly injected tracer (horseradish peroxidase), and immunocytochemical demonstration of glucose transporter-1 as a functional marker and of neurothelin, occludin and ZO-1 as structural markers. Alkaline phosphatase and gamma-glutamyltransferase activities, two enzyme reactions frequently used for demonstration of an established blood-brain barrier in vitro, were localized histochemically on the plasmalemma of glycogen body cells and were absent from the endothelium. In addition, local enlargements of the intercellular space were observed by transmission and scanning electron microscopy. In accordance with the concept of a third circulation the cerebrospinal fluid may be the vehicle for distributing substances originating in the glycogen body to the CNS, while the vascular endothelium maintains the internal milieu by virtue of its dynamic barrier functions.     

Adrenocorticoid action in the spinal cord: Some unique molecular properties of glucocorticoid receptors

1. Glucocorticoid hormones affect several functions of the spinal cord, such as synaptic transmission, biogenic amine content, lipid metabolism, and the activity of some enzymes (ornithine decarboxylase, glycerolphosphate dehydrogenase), indicating that this tissue is a target of adrenal hormones. 2. Corticosterone, the main glucocorticoid of the rat, is detected at all regional levels of the spinal cord, and cold stress increases this steroid, predominantly in the cervical regions. 3. Intracellular glucocorticoid receptors have been found in the spinal cord, with higher concentrations in the cervical and lumbar enlargements. Prima facie, these receptors presented biochemical, stereospecifical, and physicochemical properties similar to those of receptors found in other regions of the nervous system. The prevalent form in the spinal cord is the type II receptor, although type I is also present in small amounts. 4. The type II glucocorticoid receptor of the spinal cord shows an affinity lower (Kd 3.5 nM) than that of the hippocampal type II site (Kd 0.7 nM) when incubated with [3H]dexamethasone. This condition may impair the nuclear translocation of the spinal cord receptor. 5. Another peculiar property of spinal cord type II site is a greater affinity for DNA-cellulose binding than the hippocampal receptor during heat-induced transformation. Also, the spinal cord receptor shows resistance to the action of RNAse A, an enzyme which increases DNA-cellulose binding of the hippocampal receptor, indicating that both receptors may be structurally different. 6. Therefore, it is possible that a different subclass of type II, or "classical glucocorticoid receptor," is present in the spinal cord. This possibility makes the cord a useful system for studying diversity of glucocorticoid receptors of the nervous system, especially the relationship between receptor structure and function.     

Acid hydrolases and other enzymes in secondary demyelination: a quantitative histochemical study in the wobbler mouse

Abstract— The hereditary motor neuron degeneration found in the wobbler (wr) mouse was studied as a model of secondary demyelination. Lysosomal enzymes (acid phosphatase, acid proteinase, β-glucuronidase and β-galactosidase) were found elevated about three-fold in the white matter of the affected cervical spinal cord as compared with normal controls; but they were either not increased, or increased much less, in the anterior horn. Since gliosis and influx of phagocytic cells are minimal in this model, the high hydrolase levels are believed to arise primarily from (a) the accumulations of axonal dense bodies seen in involved areas, and (b) from indigenous cells engaged in breaking down the myelin fragments. Thus, secondary demyelination may, at least in this case, be initiated by enzymes of local origin. DNA levels per unit weight of tissue in both white and gray matter of wobbler cervical cord were elevated 40-50 per cent over controls. However, this was considered to reflect the stunted growth of wobbler mice rather than proliferation or influx of cells (an altered ratio of DNA to protein was demonstrated in the brain). Wobbler mice had similar levels of lactic dehydrogenase as controls; glucose-6-phosphate dehydrogenase was moderately elevated, and glycerol-3-phosphate dehydrogenase was less active in the anterior horn but more active in the white matter of the spinal cord.     

Reissner's fiber and the wall of the central canal in the lumbo-sacral region of the bovine spinal cord

Summary Reissner's fiber (RF) of the subcommissural organ (SCO), the central canal and its bordering structures, and the filum terminale were investigated in the bovine spinal cord by use of transmission electron microscopy, histochemical methods and light-microscopic immunocytochemistry. The primary antisera were raised against the bovine RF, or the SCO proper. Comparative immunocytochemical studies were also performed on the lumbo-sacral region of the rat, rabbit, dog and pig.At all levels of the bovine spinal cord, RF was strongly immunoreactive with both antisera. From cervical to upper sacral levels of the bovine spinal cord there was an increasing number of ependymal cells immunostainable with both antisera. The free surface of the central canal was covered by a layer of immunoreactive material. At sacral levels small subependymal immunoreactive cells were observed. From all these structures sharing the same immunoreactivity, only RF was stained by the paraldehyde-fuchsin and periodicacid-Schiff methods.At the ultrastructural level, ependymal cells with numerous protrusions extending into the central canal were seen in the lower lumbar segments, whereas cells displaying signs of secretory activity were principally found in the ependyma of the upper sacral levels. A few cerebrospinal fluid-contacting neurons were observed at all levels of the spinal cord; they were immunostained with an anti-tubulin serum.The lumbo-sacral segments of the dog, rat and rabbit, either fixed by vascular perfusion or in the same manner as the bovine material, did not show any immunoreactive structure other than RF.The possibilities that the immunoreactive ependymal cells might play a secretory or an absorptive role, or be the result of post-mortem events, are discussed.Supported by Grant I/38259 from the Stiftung Volkswagenwerk, Federal Republic of Germany, and Grant RS-82-18 from the Dirección de Investigaciones, Universidad Austral de ChileThe authors wish to thank Dr. Enrique Romeny from the Valdivia abattoir for kindly providing the bovine spinal cords     

The existence of a glycogenic body in the spinal cord of a cyprinodontiform teleost,Jenynsia lineata (Jenyns 1842)

Summary A distinct spinal cord structure is described in the teleostean fish J. lineata wich occupies the medial dorsal aspect of the cord, and extends in depth from the dorsal surface to the tectum of the central canal. This structure is characterized by the presence of large quantities of glycogen; this feature makes it similar in certain aspects to the glycogenic body of birds. The name of glycogenic body has been proposed for this structure.     

Triphosphopyridine nucleotide-dependent enzymes in the developing spinal cord of the rabbit

Abstract— Total lipid and the activity of five enzymes closely related to the generation of NADPH have been measured in the anterior horn region and dorsal columns of rabbit spinal cord during the period of rapid myelination. Lipid deposition progressed to a much greater extent in the dorsal columns than in the anterior horn region; however, the age at which one-half of the total adult level of lipid accumulated in both regions was the same, i.e. 19-20 days after birth. During the first 15 days of postnatal development of the dorsal columns, glucose-6-phosphate dehydrogenase changed in parallel with lipid content; however, in the anterior horn region changes in lipid were not accompanied by increases in glucose-6-phosphate dehydrogenase. In contrast to changes in glucose-6-phosphate dehydrogenase, the activity of malic enzyme increased in the anterior horn region but remained relatively constant in the dorsal columns during development. The activities of two other enzymes of the pentose phosphate pathway, 6-phosphogluconate dehydrogenase and transketolase, measured at various intervals after birth, did not directly parallel changes in the activity of glucose-6-phosphate dehydrogenase in the dorsal columns. In both areas of the developing spinal cord the activity of NADP⁺-dependent isocitrate dehydrogenase was greater than the activities of the other three dehydrogenases but it did not parallel changes in lipid content of either region. A relationship between the requirements for reducing equivalents and the activities of the four NADP⁺-dependent dehydrogenases is suggested by the finding that both areas of the adult spinal cord contained lower activities of these enzymes than those observed during the initial 26 days of development. The differences noted in the two areas of the spinal cord during development suggest that mechanisms for the generation of NADPH differ in gray and white matter.     

Morphology of lumbar-projecting lateral vestibulospinal neurons in the brainstem and cervical spinal cord in the squirrel monkey

The lateral vestibulospinal tract (LVST) is one of the major descending pathways controlling the extensor musculature of the body. To determine whether individual LVST neurons terminating in the lumbosacral spinal segments issue collaterals more rostrally to exert an influence of the cervical ventral horn intracellular recording and biocytin labeling techniques were used in the squirrel monkey. Only neurons monosynaptically related to the 8th nerve and antidromically identified to project below T12 were selected for study. The axon course through the brainstem and cervical spinal cord was examined in 37 LVST neurons. The average distance of recovered axon was 17.3 mm (4.5-31.7 mm). None could be antidromically activated from shocks applied to the rostral medial longitudinal fasciculus near the 3rd nuclei; and no collaterals were observed in the brainstem. Of the 37 neurons, only 1 axon issued a collateral to innervate the ventral horn, primarily in the region of the spinal accessory motoneurons; this single collateral provided a relatively minor input compared to that of LVST neurons terminating in the cervical cord. Thus, secondary, caudal-projecting LVST neurons represent a private, and mostly rapid, communication pathway between dorsal Deiters' nucleus and the motor circuits controlling the lower limbs and tail.     

Histochemical characterization of myotomal muscle in the roach, Rutilus rutilus (L.)

A histochemical study of the myotomal muscles in the roach revealed three main muscle regions: red, intermediate and white. These were distinguished on the basis of glycogen content, succinate dehydrogenase (SDH), and myofibrillar ATPase (mATPase) activity. Except for the red fibre region, none of these described regions is homogeneous. The principal new findings are the toniclike fibre, the presence of a transitional zone with two fibre types, and the mosaic organization of the white fibre region. The significance of this type of myotome architecture in relation to the locomotion of the species is discussed.     

An ultrastructural study of the craniocaudal continuation of the glycogen body

An ultrastructural analysis of the chicken glycogen body and its craniocaudal continuation areas shows a continuum of astroglial cell types. Characteristic glycogen body astroglia are confined to the classically defined body located in the chicken lumbosacral spinal cord. These are large cells which have an eccentric dark nucleus surrounded by a rim of dense cytoplasm which contains the usual complement of organelles. The remainder of the cell volume is occupied by alpha and beta glycogen particles interspersed with a flocculo-granular material continuous with the main cytoplasmic mass. Astroglial cells of continuation areas usually have a light cytoplasm and a centrally placed nucleus. They contain beta glycogen particles of varying sizes, but like the glycogen body cells, may have beta particles as large as 45 nm. Such particles, which resemble four leaf clovers in shape, are suggestive of an ordered substructure. Gliofilaments are not always conspicuous in astroglial perikarya, but large numbers of them are present in the processes. Although the continuation areas are mostly confined to gray matter regions, the contained astroglial processes exhibit circular, triangular, or cylindrical shapes and form an unpatterned mosaic. Astrocytic processes forming the glia limitans on the anterior and posterior margins of the cord often contain conspicuous amounts of glycogen. The ultrastructural identification of such large amounts of glycogen within the chicken nervous system suggests that it plays a major role in avian neural metabolism.