Denise Paulin

A missense mutation in the alphaB-crystallin chaperone gene causes a desmin-related myopathy.

Desmin-related myopathies (DRM) are inherited neuromuscular disorders characterized by adult onset and delayed accumulation of aggregates of desmin, a protein belonging to the type III intermediate filament family, in the sarcoplasma of skeletal and cardiac muscles. In this paper, we have mapped the locus for DRM in a large French pedigree to a 26-cM interval in chromosome 11q21–23. This region contains the αB-crystallin gene (CRYAB), a candidate gene encoding a 20-kD protein that is abundant in lens and is also present in a number of non-ocular tissues, including cardiac and skeletal muscle. αB-crystallin is a member of the small heat shock protein (shsp) family and possesses molecular chaperone activity. We identified an R120G missense mutation in CRYAB that co-segregates with the disease phenotype in this family. Muscle cell lines transfected with the mutant CRYAB cDNA showed intracellular aggregates that contain both desmin and αB-crystallin as observed in muscle fibers from DRM patients. These results are the first to identify a defect in a molecular chaperone as a cause for an inherited human muscle disorder.

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.

Early segregation of a neuronal precursor cell line in the neural crest as revealed by culture in a chemically defined medium

This article addresses the problem of the segregation of cell lines during the development of peripheral nervous system components from the neural crest. We show here that committed precursors of peripheral neurons are present in the crest before the migration of its cells has started. If cultured in a serum-deprived medium, a subpopulation of the crest cells readily differentiates into neurons without dividing. Neuronal markers such as neurofilament proteins and receptor sites for tetanus toxin are not expressed in the committed neuronal precursors, but appear after a few hours in culture. They are coexpressed in neurons with the mesenchymal intermediate filament protein, vimentin, which is common to all neural crest cells regardless of their prospective fate. A strong inhibitory effect of serum factor(s) on neurite outgrowth is demonstrated. We show also that conditions stimulating proliferation of crest cells are incompatible with promotion of neuronal differentiation and vice-versa.

Antibodies as probes of cellular differentiation and cytoskeletal organization in the mouse blastocyst

Abstract Indirect immunofluorescence microscopy has been used to detect cytoskeletal proteins, which allow a distinction between the two cell types present in the mouse blastocyst: i.e. the cells of the inner cell mass (ICM) and the outer trophoblastic cells. Antibodies against three classes of intermediate-sized filaments (cytokeratins, desmin and vimentin), as well as antibodies against actin and tubulin were studied. Antibodies against prekeratin stain the outer trophoblastic cells but not the ICM in agreement with the findings on adult tissues that cytokeratins are a marker for various epithelial cells. Interestingly, vimentin filaments typical of mesenchymal cells as well as of cells growing in culture seem to be absent in both cell types of the blastocyst. Thus, the cytokeratins of the trophoblastic cells seem to be the first intermediate-sized filaments expressed in embryogenesis. Antibodies to tubulin and actin show that microtubules and microfilaments are ubiquitous structures, although microfilaments have a noticeably different organization in the two cell types. In addition, since early embryogenic multipotential cells show close similarities to teratocarcinomic cells, a comparison is made between the cells of the blastocyst, embryonal carcinoma cells (EC cells) and an epithelial endodermal cell line (PYS2 cells) derived from EC cells. EC cells display vimentin filaments whereas PYS2 cells show both vimentin and cytokeratin filaments. The results emphasize the usefulness of antibodies specific for different classes of intermediate filaments in further embryological studies, and suggest that cells of the blastocyst and EC cells differ with respect to vimentin filaments.

The importance of intermediate filaments in the adaptation of tissues to mechanical stress: Evidence from gene knockout studies

Research over the past few years on the function of intermediate filaments in cells in culture has not produced convincing results, because the key role of intermediate filaments is within tissues and at certain periods of development. Only recently the technique of gene knockout has been used to examine intermediate filaments in mice and has provided the first evidence that intermediate filaments are directly involved in cell resilience and the maintenance of tissue integrity. Knockout of the gene encoding keratin K8 is lethal in the embryo, and results in hepatic or intestinal lesions, while knockout of the K14 or K10 genes leads to rupture of stratified epithelia. Knockout of the gene encoding desmin causes the rupture of skeletal and cardiac muscle, and collapse of blood vessel walls. Knockout of the gene coding for GFAP leads to a loss of cerebral white matter, and knockout of the gene coding for vimentin causes degeneration of the cerebellar Purkinje cells. The results reveal the lack of compensation by another intermediate filament. Tissues without intermediate filaments fall apart; they are mechanically unstable, unable to resist physical stress, and this leads to cell degeneration. By maintaining the shape and plasticity of the cell, the intermediate filament network acts as an integrator within the cell space. The state of mechanical force imposed on a tissue or a cell can alter the shape of certain elements of the cytoskeleton and thus participate to the control of cell functions.

Neurons induce GFAP gene promoter of cultured astrocytes from transgenic mice

In order to investigate the influence of neuron‐glia interaction on astrocyte differentiation, we used a transgenic mouse bearing part of the gene promoter of the astrocytic maturation marker GFAP linked to the β‐galactosidase (β‐gal) reporter gene. Addition of embryonic cerebral hemisphere (CH) neurons to transgenic CH astrocyte monolayers increased by 50–60% β‐gal positive cell number. Such event was dependent on the brain regional origin of the neurons and was followed by an arrest of astrocytes from the cell cycle and induction of glial differentiation. Time‐course assays demonstrated that maximum effect was observed after 24 h of coculture. Addition of conditioned medium (CM) derived from CH neurons also increased β‐gal positive CH astrocytic cell number. However, such CM had no effect on midbrain and cerebellum astroglia. Together, these data suggest that neurons secrete brain region‐specific soluble factors which induce GFAP gene promoter, as measured by β‐gal expression, thus suggesting that neuron‐glia interaction might induce the astrocytic differentiation program. GLIA 26:97–108, 1999.

Human desmin gene: cDNA sequence, regional localization and exclusion of the locus in a familial desmin-related myopathy

Abstract Desmin is a muscle-specific intermediate filament that is encoded by a gene assigned to human chromosome 2q35. Desmin-related myopathies are inherited disorders characterized by an intrasarcoplasmic accumulation of desmin. Recently, the knockout of the desmin gene was shown to generate a myopathic syndrome in transgenic mice, suggesting that functional abnormality of desmin may generate similar clinical symptoms in mouse and human. To determine the potential role of the desmin gene in a well-defined desmin-related myopathy (autosomal dominant form of Fardeau), human desmin cDNAs obtained from affected and unaffected individuals were cloned, sequenced and compared. No obvious mutation was detected. A BssHII restriction fragment length polymorphism (RFLP) was identified in exon 6 of the desmin gene. This RFLP was associated with a previously identified EcoRV RFLP in exon 4 to generate a tetra-allelic system, which was tested for linkage to the desmin-related myopathy in three families. The human desmin gene was localized within an 11-cM interval on chromosome 2q using a panel of radiation hybrids. This 11-cM region was clearly excluded by linkage analysis in the three desmin-related myopathy families using a set of highly polymorphic microsatellite markers. These results suggest that the desmin gene is not primarily involved in this disease.

Mammalian cell lines can be efficiently established in vitro upon expression of the SV40 large T antigen driven by a promoter sequence derived from the human vimentin gene

Summary— The aim of this study was to investigate a new method to enhance the efficiency to create mammalian cell lines. Cell immortalization was achieved by intranuclear microinjection of a recombinant DNA construct composed of a constitutive promoter controlling the genes encoding immortalizing proteins; the sequences coding for the large T and small t antigens were fused downstream of regulatory elements from the vimentin gene, the activation of which characterizes the vast majority of cells growing in vitro. Data show that the efficiency of the immortalizing procedures using the SV40 early genes could be enhanced by the control elements derived from the human vimentin (HuVim) 5′ sequences that contained nucleotides −878 to +93 from the CAP site. This HuVim 830−T/t recombinant was used to create cell lines from numerous primary cultures of different origins: rabbit, porcine and human endothelial cells, rabbit and bovine epithelial cells. A set of large T‐expressing cells was derived, and these cells retained characteristics of differentiated cells: binding of Ulex europaeus lectin and synthesis of Factor VIII for human endothelial cells; network of cytokeratin for bovine oviductal cells and rabbit mammary cells.

Actin and tubulin in teratocarcinoma cells. Amount and intracellular organization upon cytodifferentiation.

Embryonal carcinoma (EC) cells and differentiated derivatives grown in tissue culture have rather similar amounts of actin and tubulin. Indirect immunofluorescent microscopy with antibodies to actin shows striking differences in the actin organization in the different teratocarcinoma derivatives. In the EC cells, actin is found predominantly in ruffles and in surface protrusions, as well as in the cytoplasm, but microfilament bundles are not seen. Some of the differentiated clones contain strongly stained microfilament bundles; others contain actin arrangements which appear to be characteristic of the particular cell type. Indirect immunofluorescence microscopy with antibody to tubulin suggests that cytoplasmic microtubules are present both in the EC cells and in the various differentiated states studied. However, the ease with which microtubules can be documented is dependent on how cells are spread on the substratum. During in vitro differentiation of EC cells, changing patterns of actin distribution appear. Cells at the edge of the colony show the characteristic changes in microfilament and microtubular organization before those in the center.

A 28-bp negative element with multiple factor-binding activity controls expression of the vimentin-encoding gene

The promoter of the human vimentin-encoding gene (VIM) contains two enhancers separated by a negative region. The distal and proximal enhancers bind the transcription factors, AP-1 and NK-kappaB, respectively, which contribute to serum induction of Vim synthesis. We were interested in looking for particular regulatory elements that might be responsible for tissue-specific extinction and culture-dependent activation of human VIM. We have identified a 48-bp sequence in the distal enhancer which had not been reported before. This sequence includes a negative element, NE2, which confers transcriptional repression in transfection experiments and binds at least two factors in vitro. NE2 may participate in the differentiation-stage-specific control of VIM expression which involves multiple regulatory sequences and several positive and negative trans-acting factors.