Changes in morphology and spatial position of coiled bodies during NGF-induced neuronal differentiation of PC12 cells

Interphase nuclei are organized into structural and functional domains. The coiled body, a nuclear organelle of unknown function, exhibits cell type-specific changes in number and morphology. Its association with nucleoli and with small nuclear ribonucleo-proteins (snRNPs) indicates that it functions in RNA processing. In cycling cells, coiled bodies are round structures not associated with nucleoli. In contrast, in neurons, they frequently present as nucleolar "caps." To test the hypothesis that neuronal differentiation is accompanied by changes in the spatial association of coiled bodies with nucleoli and in their morphology, PC12 cells were differentiated into a neuronal phenotype with nerve growth factor (NGF) and coiled bodies detected by immunocytochemical localization of p80-coilin and snRNPs. The fraction of cells that showed coiled bodies as nucleolar caps increased from 1.6 +/- 0.9% (mean +/- SEM) in controls to 16.5 +/- 1.6% in NGF-differentiated cultures. The fraction of cells with ring-like coiled bodies increased from 17.2 +/- 5.0% in controls to 57.8 +/- 4.4% in differentiated cells. This was accompanied by a decrease, from 81.2 +/- 5.7% to 25.7 +/- 3.1%, in the fraction of cells with small, round coiled bodies. SnRNPs remained associated with typical coiled bodies and with ring-like coiled bodies during NGF-induced recruitment of snRNPs to the nuclear periphery. Together with the observation that coiled bodies are also present as nucleolar caps in sensory neurons, the results indicate that coiled bodies alter their morphology and increase their association with nucleoli during NGF-induced neuronal differentiation.     

Structural organization of the intact bacterial cellulosome as revealed by electron microscopy

The architecture of the intact cellulosome of Clostridium thermocellum, a huge extracellular multi-polypetide bacterial enzyme complex engaged in degradation of cellulose, was investigated by electron microscopy. This was done because former electron microscopic studies aimed at elucidation of the structure of polycellulosomes and cellulosomes were restricted by the fact that data on macromolecular details could only be derived from deformed or disrupted enzyme complexes, or by application of cryo preparation and imaging techniques yielding insufficient resolution. The shape of well-preserved cellulosomes was more or less spherical, often similar to that of an olive fruit with a cavity. Therein, multiple fibrillar structures could be visualized, interpreted to be the proximal stretches of copies of the fibrillar protein Cip A ('scaffoldin'), the nonenzymatic scaffolding protein known to function as attachment site for the enzymatic subunits, as well as fibrillar parts of anchoring proteins. The enzymatic subunits were depicted to be attached, in a repetitive fashion, to the distal stretches of the Cip A proteins. The enzymatic subunits were seen, in the intact cellulosome, to form a shell-like complex substructure surrounding the cavity. Obviously, this kind of architecture makes sure that the catalytic domains of the enzymatic subunits are exposed to the environment, and, hence, to the substrate, the cellulose fibrils. Attempts were made to demonstrate the alternating occurrence of coiled domains and fibrillar stretches along the elongated protein Cip A previously characterized by sequencing, X-ray, and NMR studies. To this end, Cip A molecules, with adhering enzymatic subunits, were partially removed from their native location within the cellulosome, "stretched" by hydromechanical forces directly on the electron microscopic support film, negatively stained, and depicted by electron microscopy. The alternating occurrence of presumed coiled domains and fibrillar stretches along Cip A could be visualized, together with detached enzymatic subunits found on the support film.     

Subcellular distribution of survival motor neuron (SMN) protein: possible involvement in nucleocytoplasmic and dendritic transport

Spinal muscular atrophy (SMA) is among the most common recessive autosomal diseases and is characterized by the loss of spinal motor neurons. A gene termed 'Survival of Motor Neurons' (SMN) has been identified as the SMA-determining gene. Recent work indicates the involvement of the SMN protein and its associated protein SIP1 in spliceosomal snRNP biogenesis. However, the function of SMN remains unknown. Here, we have studied the subcellular localization of SMN in the rat spinal cord and more generally in the central nervous system (CNS), by light fluorescence and electron microscopy. SMN immunoreactivity (IR) was found in the different regions of the spinal cord but also in various regions of the CNS such as the brainstem, cerebellum, thalamus, cortex and hippocampus. In most neurons, we observed a speckled labelling of the cytoplasm and a discontinuous staining of the nuclear envelope. For some neurons (e.g. brainstem nuclei, dentate gyrus, cortex: layer V) and, in particular in motoneurons, SMN-IR was also present as prominent nuclear dot-like-structures. In these nuclear dots, SMN colocalized with SIP1 and with fibrillarin, a marker of coiled bodies. Ultrastructural studies in the anterior horn of the spinal cord confirmed the presence of SMN in the coiled bodies and also revealed the protein at the external side of nuclear pores complexes, in association with polyribosomes, and in dendrites, associated with microtubules. These localizations suggest that, in addition to its involvement in the spliceosome biogenesis, the SMN protein could also play a part in nucleocytoplasmic and dendritic transport.     

Ultrastructural abnormalities with inclusions in Onuf's nucleus in motor neuron disease (amyotrophic lateral sclerosis)

This study describes an ultrastructural examination focused on motor neurons in Onuf's nucleus in the spinal cord of four control patients without neurological disease (45-70 years) and six motor neuron disease (MND) patients (38-79 years; duration 8 months-19 years) who showed no somato-vesical dysfunction. Prompted by recent studies suggesting some sphincteric motor neurons may succumb to MND, this study sought to determine whether the wider population of neurons in Onuf's nucleus display ultrastructural cytopathology which is normally undetectable in histological preparations. Spinal cords were removed 3-20 h after death, and 1 mm slices of cord rapidly fixed in modified Karnovsky medium were processed for both light- and electronmicroscopy. 'Control motor neurons' had intact neuronal and nuclear membranes. Nissl bodies chiefly comprised ordered structures of alternate lamellae of rough endoplasmic reticulum and arrays of polyribosomes. The Golgi complexes consisted of multilamellated curvilinear stacks of ER. No intraneuronal filamentous or Bunina body inclusions were observed, but occasional axonal spheroids were seen in the neuropil. In MND, histological evidence of sparing in Onuf's nucleus was associated with abnormal ultrastructure of the motor neurons. Some sphincteric neurons were atrophic, whereas in the others, Nissl bodies were reduced in number, showed loss of structural organization or comprised polyribosomal aggregates. Golgi complexes had disrupted lamellated organization or consisted solely of distended ER. Intraneuronal filamentous Lewy-body or skein-like inclusions and Bunina bodies were identified in Onuf's nucleus of three subjects (duration of MND 8 months-2 years). The results of the present study indicate that Onuf's nucleus is vulnerable in MND, and preservation of sphincter function with qualitative histological evidence of 'sparing' does not necessarily imply a corresponding lack of ultrastructural cytopathology in this nucleus.     

Microperoxisome distribution in the central nervous system of the rat

The distribution of microperoxisomes was studied in areas of the central nervous system having high concentrations of catecholaminergic neurons and in areas lacking this neuron type, using the alkaline DAB cytochemical method for catalase. Substantial numbers of microperoxisomes are found in neurons in the locus coeruleus and in nucleus A1 of the medulla, as well as in the substantia nigra, whereas few catalase-reactive bodies are seen in neurons of the cerebrum and cerebellum. The number of catalase-reactive microperoxisomes per unit area in the catecholaminergic neurons of the CNS is comparable to the number seen previously in neurons of the peripheral cervical sympathetic ganglia. Some spinal cord neurons also contain reactive microperoxisomes. Catalase-reactive microperoxisomes are numerous in oligodendrocytes of all areas studied, and in ependymal cells bordering the third and fourth ventricles. Astrocytes contain few reactive structures in the cytoplasm near the nucleus, but they are readily found in astrocytic processes and end-feet.     

A novel 95-kD protein is located in a linker between cytoplasmic microtubules and basal bodies in a green flagellate and forms striated filaments in vitro

The flagellar basal apparatus comprises the basal bodies and the attached fibrous structures, which together form the organizing center for the cytoskeleton in many flagellated cells. Basal apparatus were isolated from the naked green flagellate Spermatozopsis similis and shown to be composed of several dozens of different polypeptides including a protein band of 95 kD. Screening of a cDNA library of S. similis with a polyclonal antibody raised against the 95-kD band resulted in a full-length clone coding for a novel protein of 834 amino acids (90.3 kD). Sequence analysis identified nonhelical NH2- and COOH-terminal domains flanking a central domain of approximately 650 residues, which was predicted to form a series of coiled-coils interrupted by short spacer segments. Immunogold labeling using a polyclonal antibody raised against the bacterially expressed 95-kD protein exclusively decorated the striated, wedge-shaped fibers, termed sinister fibers (sf-fibers), attached to the basal bodies of S. similis. Striated fibers with a periodicity of 98 nm were assembled in vitro from the purified protein expressed from the cloned cDNA indicating that the 95-kD protein could be a major component of the sf-fibers. This structure interconnects specific triplets of the basal bodies with the microtubular bundles that emerge from the basal apparatus. The sf-fibers and similar structures, e.g., basal feet or satellites, described in various eukaryotes including vertebrates, may be representative for cytoskeletal elements involved in positioning of basal bodies/centrioles with respect to cytoskeletal microtubules and vice versa.     

Somatomedin C (insulin-like growth factor I) levels in patients with chronic fatigue syndrome

A rabbit antiserum was raised against the N-terminal fragment peptide, GEGLSS (Gly-Glu-Gly-Leu-Ser-Ser) of bovine neuropeptide AF (NPAF, A18Famide). NPAF is an octadecapeptide isolated from the bovine brain together with neuropeptide FF (NPFF). GEGLSS-like immunoreactivity was localized with immunofluorescence technique in colchicine-treated rats in neuronal cell bodies of the supraoptic (SON) and paraventricular (PVN) hypothalamic nuclei. A few neurons were also observed in the retrochiasmatic part of the SON. GEGLSS-like immunoreactivity was also localized to nerve terminals of the posterior pituitary. No GEGLSS-ir neuronal cell bodies were observed in the medial hypothalamus, in an area that contains NPFF-ir neurons. GEGLSS immunoreactivity was also seen in the fibers and terminals of nucleus of the solitary tract. We injected a retrograde tracer, fluorogold, to the posterior pituitary gland and visualized GEGLSS-ir neuronal cell bodies double-labeled with the tracer in SON, PVN, and SOR. The pituitary stalk transsection totally abolished the GEGLSS-ir structures from the posterior pituitary. Our results suggest that GEGLSS immunoreactivity in the rat brain has a more limited distribution than NPFF immunoreactivity. GEGLSS immunoreactivity was partially colocalized with arginine-vasopressin and oxytocin in neuronal cell bodies in the SON and PVN. Considering the fact that the known rat NPFF-NPAF precursor does not contain GEGLSS structure, the detected GEGLSS immunoreactivity may be derived from a previously unknown precursor.     

Morphological changes in aging cell lines of Paramecium aurelia. II. Macronuclear alterations

Electron microscopic examination of aging P. aurelia showed that the macronucleus undergoes characteristic structural changes. The surface of the aging macronucleus was highly invaginated. Compared with young macronuclei, the chromatin bodies appeared to be smaller and condensed, and were fewer per unit area of the aging macronucleus. The nucleolar bodies also showed morphological alterations. In many aging macronuclei the nucleolar bodies appeared to be aggregated. Large ring-shaped or coiled loops of nucleoli were also observed. These changes in the ultrastructure of macronucleus in the aging paramecia suggest that the macronucleus in the aging cells is less active in the synthesis of macromolecules and transport of material to the cytoplasm.     

Pharmacological and second messenger signalling selectivities of cloned P2Y receptors

An autopsy case of a 67-year-old man with typical clinical features of progressive supranuclear palsy (PSP) characterized by impairment of vertical ocular pursuit movement, pseudobulbar palsy, nuchal stiffness, parkinsonism, and dementia is described. In addition to typical pathological changes of PSP, the present case showed fronto-temporal cortical atrophy, accompanied with various Gallyas/tau-positive neuronal and glial structures such as neurofibrillary tangles, pretangle neurons, glial coiled bodies, astrocytic plaques and argyrophilic threads in the cerebral cortex and subcortical nuclei, and many senile plaques throughout the whole cerebral cortex. The present report suggests that PSP and corticobasal degeneration share a common background in neuronal and glial pathologies, that pathological changes of PSP and Alzheimer's disease are mixed in the entorhinal cortex, amygdala. Meynert nucleus, and hypothalamus, and that dementia with frontal lobe-like syndrome in PSP is related to the frontal and temporal cortical pathologies, and is cortical dementia as well as subcortical dementia.     

Immunohistochemical localization of the inositol 1,4,5-trisphosphate receptor in the human nervous system

A monoclonal antibody raised against the mouse cerebellar inositol trisphosphate receptor was used to study the immunohistochemical localization of this protein in the human central nervous system. As in the brain of rodents, strong immunoreactivity was found in dendrites, axon and cell bodies of Purkinje cells, as well as in nerve endings in the cerebellar and vestibular nuclei. Cerebellar efferent fibres were the only positive structures demonstrated in the brainstem and no immunostaining could be detected in the spinal cord or dorsal root ganglia. By contrast, numerous immunoreactive neurons were present in several telencephalic and diencephalic structures, including the brain cortex, hippocampus, basal ganglia, basal forebrain, amygdala and thalamus. Immunostaining of these brain neurons was weaker than that found in Purkinje cells and was evident in cell bodies and dendrites. Thus, the human brain contains a molecule cross-reacting with the mouse inositol trisphosphate receptor protein that is expressed in a pattern similar to that found in rodents. These findings can be of great importance for understanding the function of this protein in normal brain and its modifications in neuropathological disorders.     

Experimental brain injury induces expression of amyloid precursor protein, which may be related to neuronal loss in the hippocampus

Previous reports have demonstrated that some focal brain injuries increase amyloid precursor protein (APP) immunoreactivity in the region surrounding the injury where it was localized, in damaged axons and in pre-alpha 2 cells of the entorhinal cortex. However, to date, APP expression in the hippocampus remote from the impact site has not been comprehensively studied. Therefore, we have evaluated APP expression not only in the locally injured cerebral cortex but also in the hippocampus remote from the impact site. In the present paper, diffuse axonal injury was induced in rats in midline fluid percussion injury. APP expression was examined post injury using Western blot analysis and immunohistochemistry. Western blot analysis demonstrated that the expression of 100-kd APP was increased in both the cerebral cortex and hippocampus 24 h after injury. It then decreased in the hippocampus, but did not change in the cerebral cortex, 7 days after injury. Immunohistochemical studies showed increased immunoreactivity of APP in the neuronal perikarya and reactive astrocytes near the region of injury in the cerebral cortex 24 h to 7 days after injury. In the hippocampus, APP accumulated in the CA3 neurons 24 h and 3 days after injury, although no hemorrhagic lesions were seen at that site. The APP positive neurons in CA3 showed shrunken cell bodies and pyknotic nuclei 3 days after injury, and some of the neurons in CA3 had disappeared by 7 days postinjury. The results of present study suggest that traumatic brain injury induces overexpression and accumulation of APP in neuronal perikarya and that these events are followed by degeneration of CA3 neurons. Further, the decline in APP expression in the hippocampus is thought to be due to neuronal loss in CA3 subsector.     

Dendritic morphology of presumptive vasoconstrictor and pilomotor neurons and their relations with neuropeptide-containing preganglionic fibres in lumbar sympathetic ganglia of guinea-pigs

We have used intracellular dye-filling combined with multiple-labelling immunofluorescence to examine the dendritic morphology of neurons and their relations with neuropeptide-containing preganglionic terminals in the lumbar sympathetic chain of guinea-pigs. Presumptive vasoconstrictor neurons with immunoreactivity for both tyrosine hydroxylase and neuropeptide Y dendritic fields that were significantly smaller, on average, than those of presumptive pilomotor neurons containing immunoreactivity to tyrosine hydroxylase but not to neuropeptide Y. However, there was considerable variation in the sizes of the dendritic fields of the vasoconstrictor neurons. Preganglionic nerve terminals containing immunoreactivity to calcitonin gene-related peptide, but not to substance P, only surrounded cell bodies of vasoconstrictor neurons containing immunoreactivity to tyrosine hydroxylase and neuropeptide Y. In most cases, the neuropeptide-containing preganglionic terminals were not associated closely with the distal dendrites of these neurons. Few neuropeptide-containing terminals were associated closely with either the cell bodies or dendrites of the pilomotor neurons. These results show that there is a considerable range in the size of dendritic trees of sympathetic final motor neurons. Some of this variation is related to the pathways within which the neurons lie, so that presumptive pilomotor neurons generally are larger than presumptive vasoconstrictor neurons. The marked variation in size of vasoconstrictor neurons raises the possibility that there may be a size dependent recruitment of these neurons, similar to that seen in pools of spinal motor neurons. The distribution of the peptide-containing preganglionic endings suggests that they would act predominantly at the cell body and proximal dendrites of the final motor neurons.     

Galanin immunoreactive neurons in the medulla oblongata of rats

The distribution of galanin-immunoreactive (-ir) neurons in the medulla oblongata was mapped with light microscopic immunohistochemistry. No immunopositive perikarya were seen in untreated rats. Two days after colchicine treatment, galanin immuno-positive neurons were localized in the following areas: 1) raphe nuclei (magnus, pallidus and obscurus); 2) in various parts of the reticular formation, mainly in the territory of the catecholaminergic groups and in the peritrigeminal subdivision of the lateral reticular nucleus; 3) vagal nuclei (nucleus of the solitary tract, nucleus ambiguous); 4) two cell groups at the ventral surface of the rostro-caudal middle portion of the medulla oblongata (they do not correspond to any known demarkated anatomical nuclei, but related to the chemosensitive medullary area); 5) in the gelatinous part of the spinal trigeminal nucleus. The wide distribution of galanin neurons in the medulla support data that had been reported on the role of this peptide in various viscerosensory and autonomic mechanisms. In addition to these, galanin seems to be an important factor in the restoration of lesioned neurons (nerve growth factor-like activity). An increased galanin mRNA expression can be seen in dorsal vagal or hypoglossal motor neurons after intracranial transections of vagal or hypoglossal nerves, respectively. Transections of the olivocerebellar tract induced galanin gene expression in neurons of the contralateral inferior olive. After brainstem hemisection, galanin immunopositivity was seen in cells of the nucleus of the solitary tract due to the transection of ascending projections of this primary autonomic center in the medulla oblongata.     

Electron microscopy of postmortem autolysis of rat muscle tissue

To define the progression of ultrastructural changes in normal muscle at post mortem, rat gastrocnemius muscles were studied at various times after storage at +4 degrees C and +22 degrees C. Degeneration of the I-zone (discoid necrosis) and membranous bodies were found to be similar to that seen in muscle diseases, and lamellar formations were seen in mitochondria. At +4 degrees C there was contraction of the sarcomere which vanished in 12 h and inter-filamentous oedema appeared. Z-line degeneration was seen at 24 h and at 4 days all Z-lines had disappeared, and the H-zone showed darkening. In the same samples collapse or ruptures of the I band were seen. At 8 days the H-zones and M-lines were still discernible. In the early stages the mitochondria showed swelling and loss of matrix granules, while later they showed broken cristae and outer membranes, and flocculent densities. At 4 days rearrangement of the cristal material into long pentalaminar "needles" was seen in a few mitochondria. At 4 and 8 days membranous bodies were seen and the T-system and sarcoplasmic reticulum showed ruptures and disintegration into vesicles. The nucleus showed increasing condensation of chromatin at the periphery and clearing of the center. Polysomes and glycogen were reduced at 2 h, and has practically vanished at 24 h. At 22 degrees C the changes were the same but appeared about 4 times as quickly as at +4 degrees C.     

Nitric oxide-synthesising neurons in the central subnucleus of the nucleus tractus solitarius provide a major innervation of the rostral nucleus ambiguus in the rabbit

We describe an intramedullary nitric oxide synthase (NOS) neural pathway that projects from the nucleus tractus solitarius (NTS) to the rostral nucleus ambiguus (NA) in the rabbit. With the use of NADPH diaphorase histochemistry and NOS immunohistochemistry, a compact group of NOS-positive perikarya was identified in the central subnucleus of the NTS dorsomedial to the tractus solitarius and rostral to the obex. A dense network of NOS terminals was seen in the rostral NA. We investigated whether NOS terminals in the NA derive from NOS perikarya in the central NTS and whether the central NOS pathway links esophageal afferents and efferents. In some rabbits, the central NTS was unilaterally lesioned. In others, Phaseolus vulgaris-leucoagglutinin (PHA-L) was injected into the central NTS, or cholera toxin-gold was injected into the NA, or cholera toxin-horseradish peroxidase (HRP) was injected into the wall of the esophagus. The medulla was subsequently processed to demonstrate PHA-L, cholera toxin-gold, HRP, and NOS reactivity. Seven days after the NTS lesion, we observed a marked decrease in the density of NOS terminals in the ipsilateral NA. After injection of PHA-L into the central NTS, a dense group of PHA-L fibres was seen in the rostral NA, principally ipsilaterally. Afferent fibres from the esophagus were found around the NOS cell bodies in the central NTS, and many of these NOS neurons were double labeled with cholera toxin-gold after injection of this tracer into the NA. NOS terminals were found around NA neurons that were retrogradely labelled from the esophagus. We conclude that the NOS neurons in the central NTS act as interneurons in a central pathway connecting esophageal afferents and efferents.     

Application of infrared spectroscopy to development of stable lyophilized protein formulations

Global cerebral ischemia selectively damages neurons, but its contribution to glial cell death is uncertain. Accordingly, adult male rats were sacrificed by perfusion fixation at 1, 2, 3, 5, and 14 days following 10 minutes of global ischemia. This insult produces CA1 hippocampal neuronal death at post-ischemic (PI) day 3, but minor or no damage to neurons in other regions. In situ end labeling (ISEL) and immunohistochemistry identified fragmented DNA of dead or dying glia and distinguished glial subtypes. Rare ISEL-positive oligodendroglia, astrocytes, and microglia were present in control brain. Apoptotic bodies and ISEL-positive glia significantly increased at PI day 1 in cortex and thalamus (p < 0.05), but were similar to controls in other regions and at other PI intervals. Most were oligodendroglia, although ISEL-positive microglia and astrocytes were also observed. These results show that oligodendroglia die rapidly after brief global ischemia and are more sensitive than neurons in certain brain regions. Their selective vulnerability to ischemia may be responsible for the delayed white matter damage following anoxia or CO poisoning or that associated with white matter arteriopathies. Glial apoptosis could contribute to the DNA ladders of apoptotic oligonucleosomes that have been found in post-ischemic brain.