Ultrastructure and synaptic architecture of spinal motoneurons in the frog (Rana catesbeiana)

An electron-microscopic analysis of spinal motoneurons and their synapses was carried out in a frog (Rana catesbeiana). Six different types of boutons (S, F, M, P, C and GS) have been identified. Their distribution on spinal motoneuron somata and proximal dendrites is described. The mean linear percentage of the surface area covered by boutons is 26.1 +/- 1.9%. S-type boutons are preferentially concentrated on the soma and proximal dendrites. The relative number of S-type boutons (58.7%) was greater (p less than 0.01) than that of F-type boutons (41.3%). This is in contrast to mammalian spinal motoneurons where F-type boutons are much more numerous on the soma than S-type boutons. F-type boutons are randomly distributed and the average ratio of S:F-type boutons is 20:14 (S:F ratio = 1.4). In contrast, M-type boutons synapse exclusively on the distal part of the dorsal dendrites and are restricted to the intermediate zone or to the dorsal horn. P-type boutons form synapses upon the large M-type boutons. The polarity of these axoaxonic synapses is always from P to M. Similarities and differences between the synaptology of frog and mammalian spinal motoneurons are discussed.     

BULK ISOLATION OF LARGE VENTRAL SPINAL NEURONS

—Cell bodies of spinal neurons can be isolated in bulk fractions, using methods developed for neurons from brain. The technique described here includes sieving steps which allow one to purify and concentrate selectively the larger neuronal perikarya (50 μm or more), most of which could be alpha motoneurons. An average of 170,000 large neurons can be obtained from 50 g of trimmed bovine ventral enlargements. Roughly 6% of the total large neurons in the ventral grey matter are recovered, and 85% of the isolated neurons are larger than 50 μm in their smallest dia. Non-neuronal contaminants, mostly capillary fragments, account for 19% of the total particles in the fraction. Each isolated neuron contains an average of 9690 pg protein and 1353 pg RNA and hydrolyses 2·2 pmol of acetylthiocholine/min. Pretreatment of the spinal tissue with collagenase before cell isolation is also evaluated here.     

Ipsilateral,ventral corticospinal tract of the adult rat: Ultrastructure,myelination and synaptic connections

The corticospinal tract (CST) of the rat is a widely used model system in developmental, physiological, and regeneration studies. The CST of the rat consists of a main tract, that runs in the dorsomedial funiculus and several minor components. We have shown earlier that one of the minor components, the ipsilateral, ventral CST, projects all the way down the spinal cord in the adult rat and single fibers form large terminal arbors in their spinal target areas. Here we investigated its ultrastructure and compared it to that of CST fibers of the main tract. By the use of anterograde axonal tracing with biotin dextran-amine (BDA) and pre-embedding avidin-peroxidase histochemistry we investigated axon diameters and myelination using electron microscopy. Ipsilateral, ventral CST fibers were found to run in the ventral funiculus close to the midline. They were intermingled with heavily myelinated large diameter axons, presumably reticulospinal, vestibulospinal, or tectospinal fibers. Ipsilateral, ventral CST fibers were of small diameter (0.68 μm, ±0.04) and about [frac34] of them were moderately myelinated (9.64 ± 0.7 layers of myelin). Co-localization of a rhodamine-dextrane anterograde tracer with the presynaptic marker synaptophysin using confocal microscopy and electron microscopy revealed varicosities on terminal arborisations to be presynaptic boutons and clearly demonstrated contacts to neurons in intermediate laminae of the spinal cord at lumbar spinal levels. This study extends our earlier work indicating that the ipsilateral, ventral CST component of the adult rat is a morphologically complete CST component and may perform similar functions to the main CST component.     

Effect of inhibitory amino acid antagonists on postsynaptic potentials of motoneurons of the frog Rana ridibunda

On preparations of the isolated spinal cord of the frog Rana ridibunda at intracellular recording from lumbar motoneurons, it is shown that response to the 10 mM GABA application decreased selectively by 40.7 ± 23.7% (n = 6) as a result of the spinal cord treatment with bicuculline (100–150 μM), while response to the Gly application decreased selectively by 50.7 ± 17.8% (n = 10) after the spinal cord treatment with strychnine (5–10 μM). Both strychnine and bicuculline produced potentiation of EPSP by amplitude and duration as well as paroxysmal depolarizational shifts (PDS). Strychnine produced more effectively the potentiation, while bicuculline—PDS. The inhibitory Gly effect decreased significantly the DR and RF EPSP (a decrease of amplitude and duration) as a result of the spinal cord treatment with strychnine (5–10 μM), but not with bicuculline. The inhibitory GABA effect on the DR and RF EPSP decreased as a result of the spinal cord treatment with bicuculline only in a half of the studied motoneurons and to the lesser degree than the inhibitory Gly effect on the same EPSP at the strychnine treatment. Based of the obtained data, it is suggested that the inhibitory effects on the excitatory inputs of the motoneuron in the frog are expressed weaker than in mammals and are related predominantly to the GABA and Gly effects on receptors of interneurons. It is suggested that GABA specifically acts mostly on GABA_A receptors, whereas Gly—on Gly receptors, although there is some part of cross-inhibition. Original Russian Text ? G. G. Kurchavyi, N. I. Kalinina, and N. P. Vesselkin, 2006, published in Zhurnal Evolyutsionnoi Biokhimii i Fiziologii, 2006, Vol. 42, No. 5, pp. 463–471. The present work is a continuation of the work [1].     

库蚊虫霉的形态及不同因子对分生孢子萌发的影响

对1987年5月福建南平库蚊上的虫霉流行病进行观察和鉴定,结果表明库蚊虫霉(Entomophthora culicis)是流行病的主要病原菌(92.4％),其次为弯孢虫疫霉(Eryniacurvispora)(2.9％),同时在库蚊的个体上存在着这两种虫霉的复合感染(4.7％)。库蚊虫霉分生孢子钟罩形,基部平截,端部尖突。分生孢子10.3×13.3-6.6×11.6μm,平均12.1±0.15×9.0±0.15μm,长径比1.40—1.75。休眠孢子内生或外生,平均27.1±0.14μm。假根粗大,无固着器,囊状体缺乏。在蛋黄培养基上生长微弱。对不同因子影响分生孢子萌发进行了初步的研究。     

Motoneuron subtypes show specificity in glycine receptor channel abnormalities in a transgenic mouse model of amyotrophic lateral sclerosis

Amyotrophic lateral sclerosis (ALS) is a progressive neurodegenerative disease characterized by selective loss of motoneurons. Recently we studied glycine receptors (GlyRs) in motoneurons in an ALS mouse model expressing a mutant form of human superoxide dismutase-1 with a Gly93→Ala substitution (G93A-SOD1). Living motoneurons in dissociated spinal cord cultures were identified by using transgenic mice expressing eGFP driven by the Hb9 promoter. We showed that GlyR-mediated currents were reduced in large-sized (diameter > 28 μm) Hb9-eGFP(+) motoneurons from G93A-SOD1 embryonic mice. Here we analyze GlyR currents in a morphologically distinct subgroup of medium-sized (diameter 10-28 μm) Hb9-eGFP(+) motoneurons, presumably gamma or slow-type alpha motoneurons. We find that glycine-induced current densities were not altered in medium-sized G93A-SOD1 motoneurons. No significant differences in glycinergic mIPSCs were observed between G93A-SOD1 and control medium-sized motoneurons. These results indicate that GlyR deficiency early in the disease process of ALS is specific for large alpha motoneurons.     

Neuronal organization of the lateral basilar region of the cat spinal cord

The neuronal organization of the lateral basilar region (LBR) of gray matter in the cervical portion of the cat spinal cord was studied by light and electron microscopy. It was found that LBR neurons form a homogeneous group with regard to the size of their soma. The ordinary pale ultrastructure of the cytoplasm is found in 96.8% of neurons examined. The ultrastructure of the cytoplasm of the small cells (3.2%) is dark and their matrix has high electron density. Most endings on LBR neurons have spherical vesicles (of the S-type). Endings with flattened vesicles (F-type) are next in order of numerical frequency. In some endings, besides the ordinary synaptic vesicles, there are other vesicles with an osmiophilic center, and endings with a dense matrix and numerous spherical vesicles. Endings of the F-type are relatively more numerous on dendrites of LBR neurons than on their soma. Axodendritic synapses form 87.8% of the synaptic connections of the LBR, and axo-somatic synapses 9.2%. The few axo-axonal synapses are formed by small endings with small synaptic vesicles and large plaques with spherical vesicles. The latter frequently make contact with several dendrites simultaneously. The functional role of the various neuronal structures of LBR in the transmission of descending and afferent influences is discussed.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. A. N. Severtsov Institute of Evolutionary Morphology and Ecology of Animals, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 4, No. 3, pp. 296–302, May–June, 1972.     

Intracellular purine deposits in the gecarcinid land crab Gecarcoidea natalis

The terrestrial crab Gecarcoidea natalis stores large amounts of purine in the body. The major component of the purine deposits is urate (85% of the total purines). The other 15% is comprised of hypoxanthine, guanine, and xanthine. Microscopy studies reveal that these urate deposits are located intracellularly in spongy connective tissue cells throughout the body. Urate exists as numerous membrane-bound crystals 1 μm in diameter. Vesicles thought to represent urate vesicles at various stages of development are also present in the cytoplasm of the cell. Few organelles are visible in the urate storage cells, and it is unlikely that the urate is synthesized on site. Crabs (N = 2) fed a high-nitrogen diet have greater numbers of urate storage cells at more connective tissue sites, and the cells are larger (36.3 ± 1.8 μm (mean ± SE) and 44.0 ± 1.4 μm (mean ± SE)) and contain more urate than urate storage cells in animals collected from the field (N = 3) or maintained in the laboratory on a low-nitrogen diet (N = 1). The mean diameter of urate storage cells in animals fed a diet low in nitrogen and field-collected animals ranges from (13.5 ± 0.5 μm (SE) - 22.3 ± 1.0 μm (SE)). This histological study supports a strong correlation between purine accumulation and the nitrogen content of the diet. J. Morphol. 231:101-110, 1997. © 1997 Wiley-Liss, Inc.     

Effects of DNA and synthetic oligodeoxyribonucleotides on the binding properties of a cGMP-binding protein from Dictyostelium discoideum

Previously, we identified a cGMP-binding protein (cGBP) in Dictyostelium discoideum that can exist in two forms: a fast-dissociating (F-type) activity and a slow-dissociating (S-type) activity. Moreover, the F-type activity was converted effectively to S-type by the addition of nucleic acids, especially DNA (Parissenti, A.M. and Coukell, M. B. (1989) J. Cell Sci. 92, 291-301). In this study, we examined the effects of heterologous DNA and various synthetic homo-oligodeoxyribonucleotides on the cGMP-binding properties of partially purified F-type activity. Equilibrium and kinetic binding experiments revealed that DNA increased the affinity of the protein for cGMP without altering the number of binding sites. However, the presence of DNA decreased only slightly the apparent Kd of the protein for cGMP because the nucleic acid also reduced the rate of cGMP association. Addition of oligo(dGMP)8 or oligo(dCMP)8 to the protein increased both total cGMP binding and the conversion of F-type activity to S-type; in contrast, oligo(dAMP)8 or oligo(dTMP)8, at the same concentration, had no effect. Oligodeoxycytidylic acids with chain lengths less than about eight nucleotides were also ineffective or inhibitory. Analysis of cGMP binding to intact, filipin-permeabilized cells revealed a binding activity with association and dissociation rates comparable to isolated S-type activity. This observation suggests that in vivo the cGBP might exist in its S-form.     

Immunohistochemical demonstration of calbindin-D 28K (CABP28K) in the spinal cord motoneurons of teleost fish

Summary The distribution and localization of the calciumbinding protein, calbindin-D 28K (CaBP28K), in the spinal cord motoneurons of larvae of the teleost fish, Apteronotus leptorhynchus (Gymnotidae) and Pollimyrus isidori (Mormyridae), and in the adult goldfish, Carassius auratus (Cyprinidae), were determined by means of immunohistochemistry. Sections of whole larvae and goldfish spinal cord were reacted with a polyclonal antibody to rat renal CaBP28K. CaBP28K was located by the PAP technique (Sternberger). It was found in the soma, dendrites, axons and axon terminals of spinal motoneurons but not in those of electromotoneurons of Apteronotus leptorhynchus, whereas it occurred in both motoneurons and electromotoneurons of the larval electric organ of Pollimyrus isidori. In these species CaBP28K was also present in the electromotoneuron axon terminals that make synaptic contacts with the pedicles of the electrocytes. In adult Carassius auratus, CaBP28K was found in the soma, dendrites and axons of certain spinal motoneurons. The results indicate that, in teleosts, the motoneurons containing CaBP28K may represent a well-defined population within the spinal cord; the role of this protein in these cells remains to be determined.     

Chance or design? Some specific considerations concerning synaptic boutons in cat visual cortex

To understand the rules by which axons lay down their synaptic boutons we analyzed the linear bouton distributions in 39 neurons (23 spiny, 13 smooth) and 3 thalamic axons, which were filled intracellularly with horseradish peroxidase (HRP) during in vivo experiments in cat area 17. The variation of the total number of boutons and the total axonal length was large (789–7912 boutons, 12–126 mm). The overall linear bouton density for smooth cells was higher than that of spiny cells and thalamic afferents (mean ± sd, 110 ± 21 and 78 ± 27 boutons per mm of axonal length). The distribution of boutons varied according to their location on the tree. Distal axon collaterals (first and second order segments in Horton-Strahler ordering) of smooth neurons had a 3.5 times higher, spiny cells and thalamic afferents a 2 times higher bouton density compared to the higher order (more proximal) segments. The distribution of interbouton intervals was positively skewed and similar for cells of the same type. In most cases a γ-distribution fitted well, but the distributions had a tendency to have a heavier tail. To a first approximation these bouton distributions are consistent with both diffuse and specific models of interneuronal connections. Quite simple rules can explain these distributions and the connections between the different classes of neurons.     

Ultrastructural localization of substance P immunoreactivity in the ventral horn of the rat spinal cord

Summary At the light microscope level, the minute concentrations of substance P (SP) in rat spinal ventral horn can be visualized best by amplification with the double bridge PAP method of Vacca et al. (1975; 1980) in 5 m paraffin tissue sections. Morphologically, the immunoreactive sites resemble punctate bodies. They occur in close apposition with the large ventral horn cells and their associated neuronal processes. By the Sternberger PAP procedure, we now describe these punctate bodies at the electron microscope level. Ultrastructurally, they appear as tiny boutons (terminal and preterminal) and small unmyelinated processes. The boutons and processes typically contain one to several immunolabeled dense core vesicles among many immunolabeled clear vesicles. They range in size near the limit of resolution of the light microscope (LM), thereby justifying further the use of LM amplification staining by the double bridge method. The immunolabeled boutons often synapse with large smooth dendrites (which may originate from motoneurons) by asymmetrical or symmetrical synaptic densities. Their synaptic densities appear immunostained as well. The data support the view that the electrophysiological action of SP in the ventral horn occurs in part by synaptic action along the processes of the ventral horn cells. Other mechanisms of action are considered for the peptide as well. Additional types of membrane specializations (synaptoid junctions) and SP neural circuits are described below.The work, presented at the Histochemical Society's 29 Annual Meeting in Vancouver, B.C. April 1–2, 1978, was partially supported by CCHD 10-12-04-3600-67 (LLV)     

The distribution of single P2x1-receptor clusters on smooth muscle cells in relation to nerve varicosities in the rat urinary bladder

The distribution of purinergic (P2x1) receptors on smooth muscle cells in relation to autonomic nerve varicosities in the rat urinary bladder has been determined using immunofluorescence and confocal microscopy. P2x1 receptors were visualized using rabbit polyclonal antibodies against the extracellular domain of the P2x1 receptor, and varicosities were visualized using a mouse monoclonal antibody against the ubiquitous synaptic vesicle proteoglycan SV2. Two size classes of P2x1 receptor clusters were observed on the smooth muscle cells of the detrusor, namely, a large ellipse of mean long axis 1.23 ± 0.21 μm and short axis 0.92 ± 0.17 μm and a smaller spherical cluster with a mean diameter of 0.40 ± 0.04 μm. The latter occured in much greater numbers than the former in selected areas, with a density as high as 0.8 per μm2 or two orders of magnitude more than the larger-sized clusters. The large clusters are in general located beneath varicosities, with only 4.5% of P2x1 clusters not possessing an overlying varicosity. None of the small clusters was associated with varicosities. Three-dimensional reconstruction of the P2x1 and SV2 labelling at individual varicosities showed that the varicosities were immediately apposed to the P2x1 receptor clusters. On occasions, two or more small SV2-labelled varicosities about 0.7 μm in diameter each with a receptor patch were found juxtaposed to each other; these might represent the splitting up of a single large varicosity. These observations are discussed in relation to the identity of the autonomic neuromuscular junction.     

The use of intensity‐based Doppler variance method for single vessel response to functional neurovascular activation

This study presents 1 use of optical coherence tomography (OCT) angiography technique to examine neurovascular coupling effect. Repeated B‐scans OCT recording is performed on the rat somatosensory cortex with cranial window preparation while its contralateral forepaw is electrically stimulated to activate the neurons in rest. We use an intensity‐based Doppler variance (IBDV) algorithm mapped cerebral blood vessels in the cortex, and the temporal alteration in blood perfusion during neurovascular activation is analyzed using the proposed IBDV quantitative parameters. By using principal component analysis‐based Fuzzy C Means clustering method, the stimulus‐evoked vasomotion patterns were classified into 3 categories. We found that the response time of small vessels (resting diameter 14.9 ±6.6 μm), middle vessels (resting diameter 21.1 ±7.9 μm) and large vessels (resting diameter 50.7 ±6.5 μm) to achieve 5% change of vascular dilation after stimulation was 1.5, 2 and 5.5 seconds, respectively. Approximately 5% peak change of relative blood flow (RBF) in both small and middle vessels was observed. The large vessels react slowly and their responses nearly 4 seconds delayed, but no significant change in RBF of the large vessels was seen.      

Partial cloning and expression of mRNA coding choline acetyltransferase in the spinal cord of the goldfish, Carassius auratus

Choline acetyltransferase (ChAT, EC 2.3.1.6) synthesizes a neurotransmitter, acetylcholine in cholinergic neurons. ChAT is considered to be the most specific marker for cholinergic neurons. To obtain a better marker of the neurons, as the first step, we isolated a partial ChAT cDNA from the goldfish (Carassius auratus) brain by RT-PCR methods. The partial cDNA of the goldfish ChAT was composed of 718 nucleotides. The amino acid sequence of the goldfish ChAT is approximately 70% identical to those of mammalian and chicken ChAT. Northern blot analysis demonstrated that ChAT mRNA was expressed in the brain and the spinal cord of the goldfish, and much abundant in the spinal cord. In the spinal cord of the goldfish, ChAT-positive neurons were detected mainly in the ventral horn by in situ hybridization. In addition, fluorescence in situ hybridization combined with a retrograde labeling by using True Blue demonstrated ChAT mRNA positive neurons were exactly motoneurons. In the cord, putative presynaptic sympathetic neurons were also labeled.     

Calpain Inhibition Prevents Ethanol-Induced Alterations in Spinal Motoneurons

Long-term exposure of ethanol (EtOH) alters the structure and function in brain and spinal cord. The present study addresses the mechanisms of EtOH-induced damaging effects on spinal motoneurons in vitro. Altered morphology and biochemical changes of such damage were demonstrated by in situ Wright staining and DNA ladder assay. EtOH at low to moderate (25–50 mM) concentrations induced damaging effects in the motoneuronal scaffold which involved activation of proteases like μ-calpain and caspase-3. Caspase-8 was seen only at higher (100 mM) EtOH concentration. Further, pretreatment with calpeptin, a potent calpain inhibitor, confirmed the involvement of active proteases in EtOH-induced damage to motoneurons. The lysosomal enzyme cathepsin D was also elevated in the motoneurons by EtOH, and this effect was significantly attenuated by inhibitor treatment. Overall, EtOH exposure rendered spinal motoneurons vulnerable to damage, and calpeptin provided protection, suggesting a critical role of calpain activation in EtOH-induced alterations in spinal motoneurons.     

Cryopreservation of pluripotent stem cell aggregates in defined protein‐free formulation

Cultivation of undifferentiated pluripotent stem cells (PSCs) as aggregates has emerged as an efficient culture configuration, enabling rapid and controlled large scale expansion. Aggregate‐based PSC cryopreservation facilitates the integrated process of cell expansion and cryopreservation, but its feasibility has not been demonstrated. The goals of current study are to assess the suitability of cryopreserving intact mouse embryonic stem cell (mESC) aggregates and investigate the effects of aggregate size and the formulation of cryopreservation solution on mESC survival and recovery. The results demonstrated the size‐dependent cell survival and recovery of intact aggregates. In particular, the generation of reactive oxygen species (ROS) and caspase activation were reduced for small aggregates (109 ± 55 μm) compared to medium (245 ± 77 μm) and large (365 ± 141 μm) ones, leading to the improved cell recovery. In addition, a defined protein‐free formulation was tested and found to promote the aggregate survival, eliminating the cell exposure to animal serum. The cryopreserved aggregates also maintained the pluripotent markers and the differentiation capacity into three‐germ layers after thawing. In summary, the cryopreservation of small PSC aggregates in a defined protein‐free formulation was shown to be a suitable approach toward a fully integrated expansion and cryopreservation process at large scale. © 2012 American Institute of Chemical Engineers Biotechnol. Prog., 2013     

Glutamic Acid Decarboxylase-Containing Neurons in the Dorsal Column Nuclei of the Cat

The retrograde transport of horseradish peroxidase (HRP) and immunocytochemistry for glutamic acid decarboxylase (GAD) have been employed to examine whether local circuit neurons (LCNs) exist in the dorsal column nuclei (DCN) and whether these neurons may be GABA-ergic. Observations focused on the dorsal part of the middle cuneate nucleus (MCd), since this region has been previously shown to contain projecting neurons whose axons terminate almost exclusively in the contralateral thalamus. After large injections of HRP in the nucleus ventralis posterolateralis and surrounding structures of the feline thalamus, the majority of neurons in MCd are labeled. These represent about 89% of the neurons in MCd as counted in 40-μm frozen sections, and about 69% as counted in plastic-embedded, 2.5-μm-thick section. Unlabeled by the same injections are some medium to largeneurons at the dorsal rim of MCd, and many characteristically small (X ±250/μm²) neurons at the periphery of the cell clusters formed by thalamic-projecting neurons. These small neurons represent 10-12% of the neuronal population of MCd, as counted in 40-μm-thick frozen sections, and about 30%, as counted in plastic-embedded, 2.5-μm-thick sections. Neurons in this size range are also unlabeled after injection of retrograde tracer in the pretectal area, inferior and superior colliculi, inferior olivary complex, and/or spinal cord. These injections, however, result in the labeling of neurons along the dorsal rim of MCd and/or in other regions of the cuneate nucleus.

In adult, colchicine-treated cats, the use of anti-GAD serum reveals a population of labeled neurons uniformly distributed throughout the DCN. In MCd, these are small (X =±235 μm²) neurons mainly intercalated between cell clusters, and represent about 25% of the neuronal population of this nuclear subdivision as counted in plastic-embedded, 2.5-μm-thick sections. Labeled processes densely infiltrate the cell clusters, and labeled varicosities appear to cover the soma and dendrites of unlabeled neurons. At the electron-microscopic level, most labeled profiles contain vesicles and correpond to F boutons usually involved in “axoaxonic” contacts with terminals of dorsal root afferent and presynaptic to dendrites. Other vesicle-containing, GAD-positive endings seem to correspond to the P boutons described by Ellis and Rustioni (1981) and are believed to be, at least in part, of dendritic origin. It is suggested that GAD-positive neurons are GABA-ergic LCNs and that these can mediate both pre- and postsynaptic inhibition. Their integrative role is likely to be more complex than postulated by previous electrophysiological studies.