The expression of Quox 1, a homeodomain-containing protein, in sympathetic ganglion cells is regulated in vitro by growth factors.

Quox 1, a quail homeobox gene, is the first vertebrate Antp-type homeobox gene to be described that is expressed in the forebrain. We have already shown that the Quox 1 protein is specifically expressed in post-mitotic sensory neurons. A subpopulation of sympathetic ganglion cells was also found to be labelled by anti-Quox 1 in vitro, but it is not clear whether this protein is expressed in sympathetic ganglion cells in vivo and, if so, the conditions which regulate its expression in vitro. In the present study, we used immunocytochemistry to find out whether Quox 1 expression in sympathetic ganglion cells in vitro is regulated by environmental signals. We found that several peptide growth factors can regulate Quox 1 expression in cultured sympathetic ganglion cells, and that they do so at physiological concentration and in a variety of ways. Basic fibroblast growth factor (FGF-2) induces Quox 1 protein expression, whereas insulin and human insulin-like growth factor-I (IGF-I) down-regulate Quox 1 expression.

Isolation of quail qMEF2D gene and its expression pattern in the developing central nervous system.

We report here the identification of the first avian MEF2 gene, termed qMEF2D. qMEF2D is the first MEF2 protein that contains 41 repeats of glutamine in the C-terminal. This quail gene is more abundantly expressed, in a transient fashion, in the developing brain than in the muscle cells.

alphaB-crystallin interacts with cytoplasmic intermediate filament bundles during mitosis.

The small heat-shock protein alphaB-crystallin interacts with intermediate filament proteins. Using cosedimentation assay, we showed previously that in vitro binding of alphaB-crystallin to peripherin and vimentin was temperature-dependent. Furthermore, when NIH 3T3 cells were submitted to different stress conditions a dynamic reorganization of the intermediate filament network was observed concomitantly with the recruitment of alphaB-crystallins on the intermediate filament proteins. Thus, the intracellular state of alphaB-crystallin correlated directly with the remodeling of the intermediate filament network in response to stress. Here, we show data suggesting that alphaB-crystallin is implicated in remodeling of intermediate filaments during cell division. We investigated the intracellular distribution of alphaB-crystallin in naturally occurring mitotic NIH 3T3 cells and in neuroblastoma N2a and N1E115 cells. In NIH 3T3 cells, alphaB-crystallin remained diffused throughout the cell cycle. Subcellular fractionation of alphaB-crystallin showed that alphaB-crystallin remained in the cytosolic compartment during mitosis. Furthermore, alphaB-crystallin accumulated in mitotically arrested NIH 3T3 cells. This increased level of alphaB-crystallin protein was due to an increased level of alphaB-crystallin mRNA in mitotic NIH 3T3 cells. In the neuroblastoma cells, the intermediate filaments were rearranged into thick cable-like structures and alphaB-crystallin was recruited onto them. In neuroblastoma N2a cells the level of expression did not change during the cell cycle. However, a small fraction of alphaB-crystallin switched onto the insoluble fraction in mitotically arrested N2a cells. Our results suggested that depending on the state of rearrangement of the intermediate filament network during mitosis alphaB-crystallin was either recruited onto the intermediate filaments or upregulated in the cytosolic compartment.

Expression of peripherin, NADPH-diaphorase and NOS in the adult rat neocortex.

Peripherin is mainly expressed in peripheral neurones and in CNS neurones which extend axons into peripheral nerves. However, this intermediate filament protein has also been detected in a few other neurones entirely located within the CNS. The present study focuses on the adult rat neocortex. Peripherin immunoreactive (P+) neuronal somata and their neuritic extensions were observed in cortical layers II, III, V and VI, while a few P+ nerve fibres could be seen in layer I. All the P+ neurones could be selectively stained using reduced nicotinamide adenine dinucleotide phosphate diaphorase (NADPH-d) histochemistry, a typical feature of aspiny neurones. Some of the P+ neurones could also be immunostained with an antibody raised against nitric oxide synthase (NOS). These results provide evidence that peripherin is present in a discrete population of aspiny interneurones of the adult rat neocortex. The functional significance of the co-expression of peripherin and NOS needs further investigation.

Trophic action of pharmacological substances with a guanidine group on mouse neuroblastoma cells and chick ganglionic neurons in culture.

A series of substances (designated CTQ compounds) with a guanidine group have been synthesized and tested for their ability to promote neuronal survival and neurite outgrowth. Mouse neuroblastoma clonal cell lines grown in serum-containing medium for 10 days as well as primary cultures of embryonic chicken ganglion neurons grown in serum-free defined medium for 1 or 2 days have been used for the experiments. Among the various CTQ compounds (CTQ1-CTQ20) tested, only CTQ8 exerted positive neurotrophic effects on these peripheral neuronal cells. At a concentration of 10(-4) M, CTQ8 enhanced neuritogenesis of neuroblastoma cells. However, the most striking influence of CTQ8 was its promoting effect (6- to 10-fold) on the survival of chicken ciliary and dorsal root ganglionic neurons at concentrations ranging from 10(-3) M to 5 x 10(-4) M.

AlphaB-crystallin interacts with intermediate filaments in response to stress.

The small heat shock protein alphaB-crystallin interacts with intermediate filament proteins. Using a co-sedimentation assay, we showed that in vitro binding of alphaB-crystallin to peripherin and vimentin was temperature-dependent. Specifically, a synthetic peptide representing the first ten residues of alphaB-crystallin was involved in this interaction. When cells were submitted to different stress conditions such as serum starvation, hypertonic stress, or heat shock, we observed a dynamic reorganisation of the intermediate filament network, and concomitant recruitment of alphaB-crystallins on intermediate filament proteins. Under normal conditions alphaB-crystallin was extracted from cells by detergent. In stressed cells, alphaB-crystallin colocalised with intermediate filament proteins, and became resistant to detergent extraction. The intracellular state of alphaB-crystallin seemed to correlate directly with the remodelling of the intermediate filament network in response to stress. This suggested that alphaB-crystallin functions as a molecular chaperone for intermediate filament proteins.

Three different states of the chromatin structure of the mouse peripherin gene.

The chromatin structure of the mouse peripherin gene domain was analyzed in peripherin-positive and -negative cell lines. At least nine DNase I hypersensitive sites (HSS) are present within the 20-kb peripherin domain in the mouse neuroblastoma cell lines which express peripherin. Three of them are situated in intron I and intron III, the others being distributed within the 5' flanking region up to -5.5 kb. The presence of these sites was also investigated in the peripherin chromatin domain of peripherin-negative cell lines. Two other types of HSS distribution were observed along the peripherin gene according to the category of cell considered: constantly peripherin-negative cells, or negative cells arising from transiently peripherin-expressing precursors. From comparison of HSS patterns in these cell lines with those of neuroblastoma cells, it can be predicted that HSS located in the region -1500/+800 bp participate in cell-specific expression of the mouse peripherin gene.

Cell type-specific expression of the mouse peripherin gene requires both upstream and intragenic sequences in transgenic mouse embryos.

Peripherin is a neuron-specific type III intermediate filament protein expressed in well-defined populations of neurons projecting towards peripheral targets. To investigate the molecular mechanisms by which a gene is expressed in a specific subset of neurons, we used a transgenic approach in order to define peripherin gene sequences that are necessary for cell-type specific expression. Transgenic mice carrying different various genomic regions of the mouse peripherin gene fused to the Escherichia coli lacZ reporter gene were generated. We used three different peripherin/lacZ constructs containing either 5.8 kb upstream sequences, or both 5.8 kb upstream and 1.1 kb intragenic sequences, or 1.1 kb intragenic sequences associated with an heterologous promoter. Analysis of lacZ gene expression in transgenic mouse embryos showed that cell type-specific expression of the mouse peripherin gene requires both upstream and intragenic sequences. Analysis of transgenic mouse lines expressing the construct containing both upstream and intragenic sequences showed that this transgene contains all regulatory elements essential for both spatial and temporal expression of the mouse peripherin gene during embryogenesis. Furthermore, lacZ+ positive cells isolated from these transgenic lines by fluorescence-activated cell sorting (FACS) can be stained with a peripherin antibody, demonstrating that the transgene containing both upstream and intragenic sequences is expressed in peripherin neurons. These mouse peripherin upstream and intragenic sequences can now be used to identify cis-acting regulatory elements and transcription factors involved in peripherin gene regulation.

[Neuronal intermediate filament proteins]. / Les protéines de filaments intermédiaires neuronales.

The characteristics of the seven intermediate filament proteins expressed during the development of neurons are reviewed. The most extensively studied have been neurofilament proteins (NFP) and peripherin. The relative plasticity of the peripherin network can account for its possible role during development when the axons of the neurons in which this protein is expressed have to find their targets crossing a non-neural environment probably in answer to signals from this environment and from their respective targets. Peripherin may assume a similar role when axons regenerate. NFP are considered as maintaining the axonal caliber, thus ensuring a normal axonal transport. Their network is highly disrupted in several diseases, particularly in motor neuron diseases. Mice transgenic for human NFP or in which mouse NFP are overexpressed have been obtained and are considered as animal models for these diseases.

Aggregation of a subpopulation of vimentin filaments in cultured human skin fibroblasts derived from patients with giant axonal neuropathy.

Giant axonal neuropathy (GAN) is a generalized disorder of intermediate filament networks which results in the formation of an ovoid aggregate in a large variety of cell types. We investigated the cytoskeletal organization of cultured skin fibroblasts derived from three GAN patients by indirect immunofluorescence, confocal, and electron microscopy. Whereas the organization of microfilaments seemed normal, the microtubule network appeared disorganized and tangled. The organization of the intermediate filament network, composed of vimentin, was probed with three antibodies directed against different epitopes: two vimentin-specific antibodies, a monoclonal antibody (mAb V9) and a polyclonal antibody, and a serum specific for all type III IFPs (PI serum). These experiments showed that 20% of cultured skin fibroblasts from GAN patients have a vimentin aggregate composed of densely packed filaments which coexists with a well-organized vimentin network. After depolymerization of microtubules with nocodazole, all fibroblasts from GAN patients contained a vimentin aggregate which seemed to arise from a subpopulation of vimentin filaments normally integrated in the vimentin network. Such aggregates were never observed in any condition in control fibroblasts. Moreover, the ultrastructural analysis of GAN cells revealed the presence of swollen mitochondria. We suggest that GAN may be due to a defect in a factor which stabilizes cytoplasmic intermediate filament networks, and we speculate on its identification and properties.

Distribution of neurofilament proteins and peripherin in the rat pituitary gland.

The distribution of neurofilament proteins and peripherin in the pituitary gland of the rat was studied with a panel of monoclonal and polyclonal antibodies recognizing different neurofilament subunits. In the posterior lobe, a dense plexus of neurofilament- and peripherin-immunoreactive fibers was seen. In the intermediate lobe neurofilament- and peripherin-immunoreactivity was seen only in nerve fibers in the connective tissue septa, while no immunoreactivity was seen in parenchymal nerve fibers. Bilateral sympathetic ganglionectomy did not affect peripherin-immunoreactivity, indicating that the peripherin-immunoreactive fibers are of central origin. In the anterior lobe, a few solitary neurofilament- and peripherin-immunoreactive fibers were observed. Western blotting confirmed the presence of 150 kD and 200 kD neurofilament proteins in the posterior lobe. No neurofilament protein was detected in the intermediate and anterior lobes. Abundant intermediate filaments were seen with electron microscopy in the nerve fibers of the connective tissue septa in the intermediate lobe. In the parenchymal nerve fibers only microtubules were seen, indicating that the lack of neurofilament immunoreactivity is due to absence of neurofilaments.

Mice lacking vimentin develop and reproduce without an obvious phenotype.

To address the biological role of vimentin in the context of the living organism, we have introduced a null mutation of the vimentin gene into the germ line of mice. Surprisingly, animals homozygous for this mutation developed and reproduced without an obvious phenotype. Immunoblotting, immunofluorescence, and immunogold labeling analysis confirmed the absence of vimentin and of the corresponding filament network. Furthermore, no compensatory expression of another intermediate filament could be demonstrated. While these results leave open the question of the possible role of vimentin in unusual situations or pathological conditions, they show that a conspicuous developmental and cell-specific structure that is an integral part of the cytoskeleton can be eliminated without apparent effect on mouse reproduction and development.

Identification of a peripherin dimer: changes during axonal development and regeneration of the rat sciatic nerve.

Western blotting of rat dorsal root ganglion (DRG) and sciatic nerve under nonreducing conditions revealed that a peripherin-specific antibody recognized a protein species of 116/130 kDa, pI 5.6, in addition to peripherin (56 kDa, pI 5.6). We showed that this 116/130 kDa protein is a disulfide dimer of peripherin, because it gave rise to a single protein band comigrating with peripherin under reducing conditions and yielded the same proteolytic pattern as peripherin upon N-chlorosuccinimide digestion. In addition, the immunological characteristics of the resulting peptides were identical to those of peripherin. We investigated the changes in peripherin monomer and dimer protein levels during axonal development and regeneration. During postnatal development, quantitative analysis of western blots of DRG proteins showed a significant increase in peripherin monomer (+52%) and dimer (+33%) levels from the day of birth [postnatal day 0 (P0)] to P7. The monomer levels remained high until P14 and then decreased so that at P21 and later ages, the monomer levels were similar to those observed at birth. In contrast, the dimer levels decreased continuously after P7, and in the adult, its level represented only 30% of the level at birth. Changes in [35S]methionine incorporation into adult DRG proteins were studied during regeneration of axotomized sciatic axons. Quantitative analysis of proteins showed a strong increase in labeling of both peripherin monomer (+56%) and dimer (+88%) 7 days after the crush. These levels, which remained high until 28 days after the axotomy, had returned to normal 70 days post axotomy. Our results show that peripherin monomer and dimer greatly increase during DRG fiber development and regeneration, suggesting that the two forms are involved in the growth of axons.

Expression of peripherin in solid transplants of foetal spinal cord and dorsal root ganglia grafted to the injured cervical spinal cord of adult rats.

The expression of the neuronal type III intermediate filament protein peripherin was studied in E14 spinal cord fragments and E15 dorsal root ganglia 1-30 weeks after their transplantation to the injured cervical spinal cord of the adult rat. In the dorsal root ganglion transplants, the surviving neurons generally appeared as a rather healthy looking population of small strongly immunoreactive cells which are very similar to the small dorsal root ganglion neurons of adult control rats. In the spinal cord transplants, there were only a few peripherin-immunoreactive neurons, morphologically close to the motoneurons or to the preganglionic sympathetic neurons of adult rats. In both types of transplants, peripherin expression of the immunoreactive neurons was apparently correlated with the previously established ability of these transplanted neurons for extensive axonal growth into a co-grafted peripheral nerve.

Peripherin and neurofilaments: expression and role during neural development.

This review focuses attention on the expression of peripherin and the low-molecular mass neurofilament protein during development, as well as on recent results concerning the roles of these neuronal proteins. Peripherin is the only type III intermediate filament that has been shown to be expressed in neurons but exclusively in motor, sensory and sympathetic neurons; moreover, it is co-expressed with neurofilament proteins (NFP). Clearly, peripherin is expressed concomitantly with axonal growth during development, and its synthesis appears necessary to axonal regeneration in the adult. As to NFP, they are presumed to maintain the axonal diameter and thereby ensure a normal conduction velocity. In many neuropathies, either occurring in man or provoked by different means in animals, the neurofilament network is disrupted thus giving rise to bundles of filaments in perikarya or along axons; consequently, the axonal transport is impaired. The possible significance of the overexpression of NFP is discussed.

Organization and expression of intermediate filaments in epithelial cells expressing the HTLV-I Tax protein.

Intermediate filaments (IF) represent major components of the cytoskeletal network. These proteins which are differentially expressed according to the cell type, constitute a dynamic structure which not only contributes to the cell architecture but also defines its state of differentiation. Furthermore, numerous observations have shown that the IF network is altered in cells transformed by tumorigenic viruses. We have previously demonstrated that HTLV-I (human T-cell leukemia virus type I) transformed T cells were characterized by a high level of vimentin transcripts and that the HTLV-I Tax regulatory protein was able to transactivate the vimentin promoter transfected into Jurkat and HeLa cells. To enlarge the scope of this study, we investigated the effects of the Tax protein on the expression and organization of IF of epithelial cells in which the IF network is composed of vimentin and cytokeratin. To this aim, we have developed a model of epithelial cells (HeLa) stably expressing the tax sequences which were introduced by using retrovirus-mediated gene transfer. Half of the Tax expressing HeLa clones were loosely adherent to the culture surface and were displaying remarkable morphological alterations, as ascertained by the presence of round-shaped or spindle-shaped cells. In these cells, expression of this viral protein correlated to a pronounced disruption in the distribution of both the vimentin and the cytokeratin networks, as shown by immunofluorescence and ultrastructural analysis. Indeed, vimentin filaments appeared to be concentrated in discrete spots throughout the cytoplasm, while the cytokeratin filaments appeared to form a dense ring around the nucleus. More importantly, mRNA and protein analysis indicate an enhanced expression of the cytokeratin 7 gene.(ABSTRACT TRUNCATED AT 250 WORDS)

Peripherin, a neuronal intermediate protein, is stably expressed by neuroendocrine carcinomas of the skin, their xenograft on nude mice, and the corresponding primary cultures.

The histogenesis of neuroendocrine carcinomas of the skin is still controversial. To determine the degree of neural differentiation of these neoplasias, we studied the expression of intermediate filament proteins in tumoral tissues. Expressions of peripherin, the neurofilament protein NF-L, vimentin, and cytokeratin 8 were analyzed by immunohistochemical methods on 12 human primary tumors and 3 tumor xenografts on nude mice. Peripherin was detected in 10 primary tumors by immunofluorescence. The protein and the corresponding messenger RNA were identified by two-dimensional gel electrophoresis and Northern analysis in extracts of an immunofluorescence-negative tumor. Peripherin, NF-L, and cytokeratin 8 were detected in tumoral cells, whereas vimentin was found exclusively in the stroma. The histological and ultrastructural properties of the original cells of neuroendocrine carcinomas of the skin, as well as coexpression of peripherin, cytokeratin 8, and neurofilament polypeptides, were preserved in tumor xenografts and their primary cultures in vitro. These results bring new elements to the knowledge of the biology of neuroendocrine carcinomas of the skin and indicate that peripherin constitutes a marker for tumor identification.

Chromosomal localisation of the mouse and human peripherin genes.

Using a mouse cDNA probe encoding for the major part of peripherin, a type III intermediate filament protein, we have assigned, by in situ hybridization, the mouse and human peripherin genes, Prph, to the E-F region of chromosome 15 and to the q12-q13 region of chromosome 12, respectively. These regions are known as homologous chromosomal segments containing other intermediate filament genes (keratins) and also other genes which could be co-ordinately regulated.

Autoantibodies against pancreatic beta-cells: characterization by western blot analysis in the non-obese diabetic (NOD) mouse.

The NOD mouse is a relevant model for studying autoimmune diabetes. As in human insulin-dependent diabetes mellitus, the nature of the autoantigen towards which the immune system is directed remains to be clarified. It has been shown that T cells are central to the disease process. However, autoantibodies may be used as a probe to identify islet autoantigens to which self tolerance is defective. Using Western blot analysis, we characterized autoantibodies which are specific for a 58 kDa islet antigen and a 29 kDa antigen. The 58 kDa autoantigen was present in cellular extracts prepared from rat tumoral insulin-secreting cells (Rin5F) and NOD islets but not from most other non-insulin-secreting cell lines. By contrast the 29 kDa antigen was a ubiquitous antigen expressed in all cell lines tested and was not further characterized since it is very likely to be responsible for secondary immunization rather than play any role in the NOD disease process. Anti-58 kDa autoantibodies were detected in all diabetic male and female NOD animals as well as in sera from old non-diabetic NOD animals. Anti-58 kDa antibodies were not detected in sera from young NOD mice (less than 6 weeks of age) or in sera from other conventional laboratory strains of mice including autoimmune prone animals such as MRL/lpr and (NZB x NZW)F1 mice. A monoclonal antibody (72.2) specific for the 58 kDa structure was obtained, which allowed further characterization of the corresponding islet cell antigen. The expression of the 58 kDa antigen was evidenced by Western blot analysis in normal islets and in a mouse neuroblastoma cell line.

Structure of the mouse gene encoding peripherin: a neuronal intermediate filament protein.

The gene encoding mouse peripherin, a neuronal intermediate filament protein, has been cloned. Its sequence, through 1021 nucleotides composing the 5'-flanking region, nine exons, eight introns and 547 nucleotides of the 3'-flanking region, as well as its transcription initiation site have been determined. The amino acid coding sequence differs from that of the rat peripherin gene. The mouse gene has an additional histidine near the N-terminal end, and shows three conservative and two non-conservative changes. The promoter sequence, containing the binding sites for transcription factors as well as other sequences is homologous to promoter regions of other type III intermediate filament protein genes and other neuronal-specific genes.