Gangliosides,sialoglycoproteins and acetylcholinesterase of the developing mouse brain

Summary The developmental accretion of up to nine individual gangliosides in foetal brains, peri- and postnatal cortices, postnatal cerebelli and olfactory lobes and in the liver and the spleen were investigated in mice and compared with that of glycoprotein-bound sialic acid and the activity of the acetylcholinesterase.In foetal brain and in postnatal liver and spleen more sialic acid was found bound to glycoproteins than to gangliosides. In postnatal brain structures, however, ganglioside-NeuAc predominated and increased between the 7th and 21st d about 2-fold in the olfactory lobes and cerebellum and more than 3-fold in the cortex.During foetal development the relative quantities (mol %) as well as the absolute concentrations (compared with the fresh weight) of GM1, GM2 and GM3 in the brain decreased, whereas those of GD1a, GD1b and GQ increased.This pattern change continued perinatally in the cortex up to the end of the first week. Thereafter the pattern changed little, but the concentration of all gangliosides present increased much more rapidly, especially between the 10th and 13th d.The postnatal cerebellum and olfactory lobes contained higher concentrations of GM1 and GM3 than the cortex, both gangliosides decreasing in favour of their di-, tri- and tetrasialo-homologues during the third postnatal week.In all brains structures the accretion of GD1a and GT1 was proportional to the increase in the activity of the acetylcholinesterase.Unlike the brain structures, the ganglioside pattern in the liver and spleen, characterised by a predominance of monosialogangliosides and of GD3, did not change noticeably during the first three weeks after birth.The coincidence of the changes in ganglioside accretion observed in the different brain structures with successive periods of morphological differentiation further support the suggestion that gangliosides may play an important role in control of the growth and differentiation of developing nerve cells.Abbreviations GM3 II³NeuAc-GgOse₂Cer - GM2 II³NeuAc-GgOse₃Cer - GM1 II³NeuAcGgOse₄Cer - GD1a IV³NeuAc-, II³ NeuAc-GgOse₄Cer - GD3 II³ NeuAc₂-GgOse₂Cer - GD2 II³ NeuAc₂-GgOse₃ Cer - GD1b II³ NeuAc₂-GgOse₄ Cer - GT1 IV³ NeuAc-, II³ NeuAc₂-GgOse₄ Cer - GQ IV³ NeuAc-, II³ NeuAc₃-GgOse₄ Cer - NeuAc N-acetylneuraminic acid (sialic acid) - AChE Acetylcholinesterase     

Changes of brain gangliosides in chicken and mice during heterothermic development

Developmental profiles of brain gangliosides of chicken and mice were correlated to thermo-biological parameters. In parallel with an increasing body temperature and resistance to cold stress (within the first 11 postnatal days) the brain gangliosides change to a less polar pattern, indicated by a higher proportion of oligosialogangliosides.     

Developmental profiles of arylsulfatases A and B in rat cerebral cortex and spinal cord.

Arylsulfatases A (EC 3.1.6.1) and B (EC 3.1.6.12) are lysosomal enzymes that can remove sulfate groups from sulfatides and sulfo-glycosaminoglycans, respectively. The activities of these enzymes in cerebral cortex and in spinal cord of developing rat pups were measured. The tissues were homogenized and the arylsulfatases A and B in the soluble fraction were separated from each other by anion exchange chromatography on DE-52 cellulose. Subsequently, the enzyme activities were assayed with p-nitrocatechol sulfate as substrate at 37 degrees C and pH 5.6. We observed a developmental profile of arylsulfatase A, similar to that previously reported for cerebroside sulfatase (EC 3.1.6.8; (Van der Pal et al. (1990) Biochim. Biophys. Acta 1043, 91-96]. The activity of arylsulfatase A increased gradually during development, whereas arylsulfatase B rose more steeply, peaked around day 15 and declined thereafter. As a consequence the ratio between B and A forms of arylsulfatase dropped from about 4 in 1-week-old pups to 2.2 (cortex) and 0.7 (cord) in 7-week-old rat pups.     

Compartments and perivascular arrangement of the meninges covering the cerebral cortex of the rat

Summary The intercellular clefts of the brain and the leptomeninges, and the perivascular spaces were studied with reference to the results obtained in a previous study (Krisch et al. 1983). The spatial relationships of these compartments were analyzed at the electron-microscopic level. Horse-radish peroxidase (HRP) was injected into the brain or into the contralateral ventricle.The pattern of distribution of HRP depends on the boundary situation in the individual compartments. The inner and outer pial layers accompany the vessels intruding into the brain. In the Virchow-Robin space the pial funnel obliterates within a short distance. The inner arachnoid layer is continuous with the outer arachnoid layer when it covers the vessels traversing the meningeal space. The perivascular compartment is not in communication with the arachnoid space; moreover, the pial funnel within the Virchow-Robin space is sealed off against the arachnoid space.Thus, blood vessels traversing the meningeal spaces and subsequently penetrating the brain surface are exposed to the common intercellular compartment represented by the intercellular clefts of the brain and the leptomeninges; this compartment does not communicate with the other compartments. The cerebrospinal fluid located in this intercellular compartment is preferentially drained into the upper cervical lymph nodes.Supported by the Deutsche Forschungsgemeinschaft (Grant Nr. Kr 569/5) and the Stiftung Volkswagenwerk.     

Developmental Changes in the Biosynthesis of Sialoglycoprotein Substrates for Intrinsic Synaptic Sialidase

Abstract: N′-Acetyl-d -[6-³H]mannosamine was administered to 13- and 28-day-old rats by intraventricular injection. At various time intervals following the injection, synaptic membranes were prepared and the incorporation of radiolabel into sialic acid residues released from endogenous glycoproteins and gangliosides by intrinsic sialidase determined. Radiolabel was incorporated into synaptic membrane gangliosides and glycoproteins, and at all times tested, >90% of the label was associated with sialic acid. Sialic acid released from endogenous glycoproteins by intrinsic sialidase present in 28-day membranes incorporated only 20–25% as much radiolabel per nmole as sialic acid released by mild acid hydrolysis or by exogenous neuraminidase. In contrast, sialic acid released from glycoproteins present in 13-day-old membranes by intrinsic sialidase, mild acid hydrolysis, or exogenous neuraminidase all were similarly labelled. At both ages the specific radioactivity (cpm/nmol) of sialic acid released from gangliosides by the intrinsic enzyme was similar to the total ganglioside sialic acid released by mild acid hydrolysis. The results identify glycoprotein substrates for intrinsic synaptic membrane sialidase as a distinct metabolic class in the mature brain and suggest the occurrence of a developmentally related change in the metabolism of these glycoproteins.     

Developmental profiles of gangliosides in trisomy 19 mice

The ganglioside composition of the cerebrum, cerebellum, brainstem, liver, heart, and spleen was analyzed quantitatively in trisomy 19 (Ts19) mice aged 4 to 12 days postpartum. The developmental profiles of cerebral gangliosides were similar in Ts19 mice and control littermates: Total ganglioside-sialic acid as well as the proportions of the individual gangliosides GD1a and GM1 increased with age, while the percentages of GQ1b and GT1b decreased during development. Both the accretion of the total ganglioside content and the development of the individual ganglioside fractions were delayed by 2-3 days in the Ts19 telencephalon. Likewise, the shift from the b- to the a-pathway of ganglioside synthesis was retarded. Ganglioside development was equally delayed in the cerebellum and the brainstem of Ts19 mice. Since in Ts19 mice, morphogenesis of several brain regions is similarly delayed by 2 days, these results confirm the usefulness of gangliosides as biochemical markers for brain maturation. In contrast to brain gangliosides, the ganglioside composition of the Ts19 livers was clearly distinguished from that of control livers. Total ganglioside-bound sialic acid was increased by 35-50% in Ts19 livers. This elevation in ganglioside content not explicable by a simple delay in development was mainly due to an increase in GD3 and fraction 2, which is likely to contain GD1a and GD1b. In contrast, GM2 which increased considerably with age in control mice persisted on a low level in Ts19 livers. Comparable alterations of the ganglioside pattern were neither observed in the spleen nor in the heart of Ts19 mice. The data presented give additional evidence that ganglioside synthesis in the liver is under a different regulation mechanism than that in the brain, heart, and spleen.     

Ganglioside changes in the chicken optic lobes and cerebrum during embryonic development

Summary The developmental profiles of 15 different gangliosides of the optic lobes and cerebrum of the chicken were followed from the 6 th day of incubation to hatching and correlated to morphological development. Five of these gangliosides appearing in both structures between the sixth and tenth day, have not been reported previously in higher vertebrates. Three chromatographed on TLC-plates similarly to G_T3, G_T2, and G_T1c gangliosides, which have been demonstrated in fish brain. One fraction moved just below G_Q1b and is suggested, to contain G_Q1c. These novel gangliosides, which are possibly related to a recently proposed separate and probably phylogenetically older biosynthetic pathway, contained up to 20% of total ganglioside sialic acid. The fifth novel fraction, containing up to 16% of total ganglioside-sialic acid, moved below the penta-sialoganglioside G_P1 and is suggested to contain hexa-sialogangliosides.There were two main changes in ganglioside synthesis, which were identical in both structures.The first occurred from the sixth to the eleventh day, parallel to decreased proliferation, maximal cell migration and neuroblast differentiation, G_D3 and G_D2 decreased rapidly in favour of G_Q1b, G_P1, and to the novel fractions, described above.The second occurred from the eleventh to the eighteenth day, parallel to increased growth and arborization of dendrites and axons as well as functional establishment of synaptic contacts, there was a sharp rise in the amount of G_D1b, G_T1b, and G_D1a. Concomitantly the novel gangliosides decreased. At hatching G_D1a was the predominant ganglioside. G_M3, G_M2, and G_M1 were always minor fractions, each accounting for less than 4% of total ganglioside-sialic acid. G_M4 was never detected, indicating neglegible myelinisation until hatching.Abbreviations NeuAc N-Acetylneuraminic acid - G_M4 I³NeuAc-GalCer - G_M3 II³NeuAc-LacCer - G_M2 II³NeuAc-G_gOse₃Cer - G_M1 II³NeuAc-G_gOse₄Cer - G_D3 II³(NeuAc)₂LacCer - G_D1a IV³NeuAc, II³NeuAc G_gOse₄Cer - G_T3 II³ (NeuAc)₃LacCer - G_D2 II³(NeuAc)₂G_gOse₃Cer - G_D1b II³(NeuAc)₂G_gOse₃Cer - G_D1b II³(NeuAc)₂G_gOse₄Cer - G_T2 II³(NeuAc)₃G_gOse₃Cer - G_T1b IV³NeuAc, II³(NeuAc)₂G_gOse₄Cer - G_T1c II³(NeuAc)₃G_gOse₄Cer - G_Q1b IV³(NeuAc)₂ II³(NeuAc)₂G_gOse₄Cer - G_Q1c IV³NeuAc, II³(NeuAc)₃G_gOse₄Cer - G_P1 IV³(NeuAc)₂, II³(NeuAc)₃G_gOse₄Cer - G_H(?) IV₃(NeuAc)₃, II³(NeuAc)₃G_gOse₄Cer     

Developmental Changes in Ganglioside Composition and Synthesis in Embryonic Rat Brain

Developmental changes in ganglioside composition and biosynthesis was studied in rat brain between embryonic day (E) 14 and birth. In E14 brains, GM3 and GD3 were predominant. At E16, "b" series gangliosides, such as GD1b, GT1b, and GQ1b, increased in content. After E18, "a" series gangliosides such as GM1, GD1a, and GT1a increased in content, and the content of GM3 and GD3 markedly decreased. Because of these changes in composition, we determined the activities, in homogenates of embryonic brains, of two key enzymes of ganglioside synthesis: sialyltransferase for the synthesis of GD3 from GM3 and N-acetylgalactosaminyltransferase for GM2 synthesis from GM3. The sialyltransferase activity (GM3----GD3) was constant between E14 and E18 but decreased rapidly from E18 to birth. In contrast, the N-acetylgalactosaminyltransferase activity (GM3----GM2) increased between E14 and E18 but was constant from E18 to birth. These changes in ganglioside composition and enzymatic activities indicate that during development there is a shift from synthesis of the simplest gangliosides of the "a" and "b" pathways to synthesis of the more complex gangliosides.     

Day-night cycle of lipidic composition in rat cerebral cortex

A study of the lipidic pattern of the cerebral cortex of the normal adult rat during the daynight cycle was carried out. The changes observed were the following: phosphatidylcholine, phosphatidylethanolamine, phosphatidylinositol and phosphatidylserine plus phosphatidic acid showed a peak at 16:00 hr possibly due to a general increase in phospholipid biosynthesis. During the nocturanl period the variations of phosphatidylcholine and phosphatidylethanolamine were not clearly observe, they might be due to an increase in the interconversion or exchange reaction, since the ratio phosphatidylcholine/phosphatidylethanolamine showed a significative change at 04:00 hr. This occurred because small but opposite changes in both phospholipids were observed, suggesting an increase in the methylation reactions of phospholipids. Cardiolipin showed a significant peak at 04:00 hr. Plasmalogens exhibited significative changes, an important diminution at 16:00 hr and a prominent peak at 24:00 hr. Cholesterol levels were high during the light period and low in the dark one. Cerebrosides and gangliosides showed no day-night variations. The changes observed indicate a phenomenon of biological rhythmicity synchronized by the photoperiod, suggesting that these fluctuations could act as physiological modulators of the properties and functions of the nerve cell membrane.     

Synaptic terminal parameters in unanaesthetized rat cerebral cortex

The ultrastructure of synapses from the molecular layer of parietal cortex was examined in two groups of unanesthetized rats. Rats of the first group were killed by stunning across the back of the neck, and those of the second group by the introduction of fixative through a preimplanted carotid artery cannula. Comparison of synapses from the two groups revealed that the distribution of synaptic types was the same. A larger percentage of synapses of the cannulated group has vesicle attachment sites than did those of the stunned group. The area and perimeter of the presynaptic terminals were significantly larger in synapses from the cannulated group, although the equivalent length of the postsynaptic thickening was less. The mean value for synaptic curvature was greater in the cannulated group, although over 80% of synapses in both groups had positive curvatures. No significant differences were found between the groups for the relationships between presynaptic terminal area and synaptic vesicle number, and between postsynaptic thickening length and synaptic curvature. Membrane recycling is suggested as a mechanism of accounting for the differences. The preponderance of postively-curved synapses in unanesthetized material may indicate a preponderance of functioning synapses.     

Developmental Changes in the Oligosaccharide Composition of Synaptic Junctional Glycoproteins

Synaptic junctions (SJs) were isolated from the forebrains of rats ranging in postnatal age from 10 days to greater than 1 year. SJ glycoproteins that react with Concanavalin A (Con A) were isolated by chromatography on Con A-agarose and separated by gel electrophoresis. The concentrations of the major SJ Con A binding (Con A+) glycoproteins (apparent Mr 180,000, 130,000, and 110,000) increased between 10 and 28 days, with GP180 and GP110 showing greater relative increases than GP130. Con A binding oligosaccharides associated with 10-day SJs were sensitive to digestion with endoglycosidase C11 and alpha-mannosidase, indicating that they were of the high-mannose type, as previously shown for 28-day SJs. Con A+ oligosaccharides from rats of increasing postnatal age were analyzed by chromatography on Biogel P-4. Two major oligosaccharides, containing five and eight mannose residues, were present in SJs of all ages examined. During development the ratio of man5 to man8 oligosaccharides increased, so that man5 constituted the predominant species in 28-day and adult SJs. Peptide mapping experiments showed that GP180, GP130, and GP110 were each associated with a unique polypeptide composition. Little or no change in peptide composition of the major SJ glycoproteins occurred during development.     

Size and charge isomers of acetylcholinesterase in the cerebral cortex of young and aged rats

Previous studies in this laboratory showed an age-related decline of acetylcholinesterase (AChE) activity in the cerebral cortex of rats. In the present study the age-related differences in enzymatic activity were evaluated in terms of individual molecular forms. Extracts containing total, soluble and membrane-bound AChE were analyzed both by ultracentrifugation in sucrose gradient and by non-denaturing gradient polyacrylamide gel electrophoresis. By ultracentrifugation two molecular forms, namely 10S and 4S (corresponding to tetrameric-G4 and monomeric-G1 forms, respectively) were separated in extracts of total and soluble AChE, while only 10S forms were present in extracts of membrane-bound AChE. Electrophoresis of soluble AChE extracts revealed slowly- and fast-migrating bands, grouped in two clusters of at least three bands each; membrane-bound AChE contained only a single slowly-migrating band. Electrophoresis of the single forms isolated by ultracentrifugation showed that slowly- and fast-migrating bands corresponded to G4 and G1 forms, respectively. Therefore, in soluble AChE no one-to-one relationship between charge- and size-isomers was observed; on the contrary, such relationship has been shown for membrane-bound AChE. This implies that soluble G4 forms and membrane-bound-G4 form are electrophoretically different, being heterogeneous the former and homogeneous the latter. The age-related decline of total AChE, accompanied by a decrease of G4/G1 ratio, depended mainly on a decrease of membrane-bound AChE while soluble AChE and its G4/G1 ratio was unchanged. The qualitative pattern of charge isomers was not modified by aging.     

Age-dependent modifications of mitochondrial proteins in cerebral cortex and striatum of rat brain

The protein composition of free mitochondria purified from cerebral cortex and striatum during aging was analyzed by gel electrophoresis. Mitochondria were isolated from cerebral cortex and striatum of 4-, 12-, and 24-month-old rat brain. The percent amount of mitochondrial proteins after gel-electrophoretic separation was determined densitometrically. A significant decrease in the amount of two polypeptides (with molecular weights of 20 and 16 kDa, respectively) in both brain regions during aging was found. The decrease was higher in the striatum indicating a greater vulnerability of this brain area to the aging process. The age-dependent modifications of mitochondrial proteins observed may play an important role in several mitochondrial functions, such as energy transduction and transport processes as well as in structural changes occurring with age, causing altered membrane permeability and fluidity.     

Somatostatin binding to dissociated cells from rat cerebral cortex

A method has been developed for the study of somatostatin (SS) binding to dissociated cells from rat cerebral cortex. Binding of [¹²⁵I][Tyr¹¹]SS to cells obtained by mechanical dissociation of rat cerebral cortex was dependent on time and temperature, saturable, reversible and highly specific. Under conditions of equilibrium, i.e., 60 min at 25°C, native SS inhibited tracer binding in a dose-dependent manner. The Scatchard analysis of binding data was linear and yielded a dissociation constant of 0.60±0.08 nM with a maximal binding capacity of 160±16 fmol/mg protein. The binding of [¹²⁵I][Tyr¹¹]SS was specific as shown in experiments on tracer displacement by the native peptide, SS analogues, and unrelated peptides.     

Sleep deprivation induces the unfolded protein response in mouse cerebral cortex

Little is known about the molecular mechanisms underlying sleep. We show the induction of key regulatory proteins in a cellular protective pathway, the unfolded protein response (UPR), following 6 h of induced wakefulness. Using C57/B6 male mice maintained on a 12:12 light/dark cycle, we examined, in cerebral cortex, the effect of different durations of prolonged wakefulness (0, 3, 6, 9 and 12 h) from the beginning of the lights-on inactivity period, on the protein expression of BiP/GRP78, a chaperone and classical UPR marker. BiP/GRP78 expression is increased with increasing durations of sleep deprivation (6, 9 and 12 h). There is no change in BiP/GRP78 levels in handling control experiments carried out during the lights-off period. PERK, the transmembrane kinase responsible for attenuating protein synthesis, which is negatively regulated by binding to BiP/GRP78, is activated by dissociation from BiP/GRP78 and by autophosphorylation. There is phosphorylation of the elongation initiation factor 2alpha and alteration in ribosomal function. These changes are first observed after 6 h of induced wakefulness. Thus, prolonging wakefulness beyond a certain duration induces the UPR indicating a physiological limit to wakefulness.     

Cellular localization of gangliosides in the developing mouse cerebellum: analysis using the weaver mutant

Abstract: The distribution of gangliosides was studied in the weaver ( wv/wv ) mutant mouse, where the vast majority of postmitotic granule cell neurons die prior to their differentiation. The wv mutation also shows a dosage effect, as granule cell migration is slowed or retarded in the + /wv heterozygotes. By correlating changes in ganglioside composition with the well-documented histological events that occur during cerebellar development in the normal (+/+), heterozygous ( +/wv ), and weaver ( wv/ wv ) mutant mice, information was obtained on the cellular localization and function of gangliosides. Ganglioside G_M1 may be enriched in granule cell growth cones and play an important role in neurite outgrowth. A striking accumulation of G_M1, which may result from altered metabolism, occurred in the adult wvlwv mice. G_D3 was heavily concentrated in undifferentiated granule cells, but was rapidly displaced by the more complex gangliosides during differentiation. G_D1a became enriched in granule cells during formation of synaptic and dendritic membranes, whereas G_T1a appeared enriched in Purkinje cell synaptic spines. A possible fucose-containing ganglioside was quantitated only in the wvlwv mice. Ganglioside G_T1b became enriched in granule cells during synaptogenesis, whereas G_Q1b became enriched in these cells after synaptogenesis. The concentrations of G_T1b and especially G_Q1b increased continuously with age. Our results provide further evidence for a differential cellular enrichment of gangliosides in the mouse cerebellum and also suggest that certain gangliosides may be differentially distributed within the membranes of these cells at various stages of development.     

Oligosaccharide Composition, Localization, and Developmental Changes of a CNS-Specific (F3-87-8) Glycoprotein

The F3-87-8 glycoprotein was isolated from rat brain by immunoaffinity chromatography after biosynthetic labeling by intracerebral administration of [3H]glucosamine, and the oligosaccharide composition of pronase-derived glycopeptides was determined by sequential lectin affinity chromatography and alkali treatment. Triantennary complex oligosaccharides (65%) and O-glycosidic oligosaccharides (18%) were the predominant types present, accompanied by 7-10% each of biantennary and high-mannose oligosaccharides. Twenty-two percent of the complex oligosaccharides had a fucose residue linked to the proximal N-acetylglucosamine of the chitobiose units. No poly(N-acetyllactosaminyl) or hybrid oligosaccharides were detected. Immunocytochemical studies on the localization of this glycoprotein in developing rat brain demonstrated that in 1-week postnatal cerebellum, there is light staining of the internal granule cell layer and surrounding the Purkinje cells. By 2 weeks, an intense staining of myelinating fiber tracts appears, accompanied by much lighter staining in the granule cell layer and at the base of the molecular layer. Staining of the white matter remains strong at 3 weeks postnatal, together with significant staining throughout the molecular layer, and then decreases in both areas by 1 month. In adult brain there is relatively uniform staining of approximately equal intensity in the white matter, granule cell layer, and molecular layer, whereas the Purkinje cell bodies appear unstained throughout development. In agreement with a previously reported immunochemical analysis, no staining was seen in other tissues, confirming the CNS-specific localization of this glycoprotein.     

Independent development of presynaptic specializations in olfactory cortex of the fetal rat

Summary Electron microscopy was used to study synaptogenesis in prepyriform cortex of fetal rat pups during early stages of synapse formation. Of special interest is the frequent occurrence of unapposed, developing synaptic specializations in axon and growth cone profiles. The location and morphology of the unapposed specializations suggests that thay are presynaptic in nature. These presumably immature presynaptic specializations are found in the lateral olfactory tract and subjacent cortex. Intermediate forms between uncontacted presynaptic specializations and definitive synapses suggest a synaptogenic sequence in which initial development of an immature presynaptic specialization begins without apposition of a postsynaptic element at that location. This implies that initiation of presynaptic development is not dependent upon postsynaptic contact and also raises the question of whether synaptic contacts could be established via presynaptic induction of postsynaptic formation.Dr. Westrum is an Affiliate of the CDMRC at the University of Washington. The research was supported in part by NIH Grants NS09678, NS17111 (NINCDS), and DE04942 (NIDR), DHHS     

Cholinergic receptor alterations in the cerebral cortex of spinal cord injured rat

Many areas of the cerebral cortex process sensory information or coordinate motor output necessary for control of movement. Disturbances in cortical cholinergic system can affect locomotor coordination. Spinal cord injury causes severe motor impairment and disturbances in cholinergic signalling can aggravate the situation. Considering the impact of cortical cholinergic firing in locomotion, we focussed the study in understanding the cholinergic alterations in cerebral cortex during spinal cord injury. The gene expression of key enzymes in cholinergic pathway - acetylcholine esterase and choline acetyl transferase showed significant upregulation in the cerebral cortex of spinal cord injured group compared to control with the fold increase in expression of acetylcholine esterase prominently higher than cholineacetyl transferase. The decreased muscarinic receptor density and reduced immunostaining of muscarinic receptor subtypes along with down regulated gene expression of muscarinic M1 and M3 receptor subtypes accounts for dysfunction of metabotropic acetylcholine receptors in spinal cord injury group. Ionotropic acetylcholine receptor alterations were evident from the decreased gene expression of alpha 7 nicotinic receptors and reduced immunostaining of alpha 7 nicotinic receptors in confocal imaging. Our data pin points the disturbances in cortical cholinergic function due to spinal cord injury; which can augment the locomotor deficits. This can be taken into account while devising a proper therapeutic approach to manage spinal cord injury.     

Three dimensional organization of mammalian adrenal cortex

Summary The adrenal cortex of different mammals was studied by SEM in order to demonstrate its actual three-dimensional organization. In the rat, as well as in the cat and pig, the adrenal cortex appeared as a tunnelled continuum of polyhedral cells arranged in plate-like structures (laminae). This laminar arrangement was more evident in the inner fasciculate and reticular zones where the cortex revealed a striking similarity to liver tissue. The polyhedral cells of all cortical zones possessed regular facets populated by small pits, larger invaginations and numerous microvilli with the exception of very short and smooth areas probably corresponding to attachment zones and/or gap junctions. This cellular architecture produced a labyrinthic system of intercellular channels or lacunae in which the capillaries were suspended.The pericapillary areas of this labyrinth contained microvilli, amorphous material, a delicate net of fibrils and occasional cells. The intercellular compartment of this lacunar system was mainly bordered by numerous microvilli arising from endocrine cells.The luminal surface of the capillary wall showed not only irregularly protruding margins (interpretable as endothelial junctions) but also clearly overlapping and flattened endothelial extensions.In all the animals and areas of the adrenal cortex examined, the endothelial wall was provided with abundant clusters of small fenestrations (about 50 nm in diameter) generally arranged in sieve plates. Larger fenestrations were noted mainly in the fasciculate and reticular zones of the cat and pig and occasionally in the rat.A final point related to the nature and significance of sinusoidal fenestrations was the occurrence of irregularly shaped and intracapillary located cells mainly noted in the deeper zones of the fasciculate and reticular zones of the gland. These elements — possessing the surface characteristics of macrophages — were observed, with their irregular and slender evaginations, in close proximity to the large fenestrations in a manner reminiscent of Kupffer cells within the lumen of liver sinusoids.