Cell aggregation: role of acid mucopolysaccharides.

Factors that induce cell aggregation are released by several types of chick embryo and mammalian cell cultures. These aggregation factors are also present in some serums. The factors in each of the preparations tested were inactivated by treatment with bovine testicular hyaluronidase. Conversely, hyaluronic acid promoted aggregation of only those cells that were aggregated by media containing the factors. These factors appear to be acid mucopolysaccharides, with hyaluronic acid being a major component.

Transformation of chick embryo neuroretinal cells by Rous sarcoma virus in vitro: induction of cell proliferation.

Neuroretinal cells from 7-day-old chick embryos are transformed and induced to proliferate after infection with Rous sarcoma virus in vitro. Susceptibility of neuroretinal cells to the virus is also dependent on the stage of development since infection of cells from 10-day-old embryos is uneffective.

Crystallin gene expression and lentoid body formation in quail embryo neuroretina cultures transformed by the oncogenic retrovirus Mill Hill 2 or Rous sarcoma virus.

The lens-specific proteins alpha and delta crystallins and lentoid bodies, structures that follow a differentiation pathway similar to that of the lens, regularly appear after 4 to 5 weeks in quail embryo neuroretina monolayer cultures. We have investigated the effects of the avian oncogenic retroviruses Mill Hill 2 and Rous sarcoma virus on this process. Quail embryo neuroretina cells transformed by Mill Hill 2 virus were established into permanent cultures that synthesized alpha and delta crystallins and contained stem cells for the production of lentoid bodies. In contrast, transformation with the Rous sarcoma virus mutant tsNY-68 blocked the appearance of mRNA crystallins, but cytoplasmic alpha and delta crystallin mRNA and alpha crystallin appeared 44 h after a shift to the nonpermissive temperature. However, delta crystallins and lentoid bodies were only present after 7 days. The crystallins of transformed quail neuroretina cultures were immunologically indistinguishable from those of quail lenses and of normal quail embryo neuroretina cultures.

Serum factors and v-src control two complementary mitogenic pathways in quail neuroretinal cells in culture.

Quail neuroretinal cells (QNR cells) from 7-day-old embryos do not proliferate even in the presence of 8% fetal calf serum. After infection by the Rous sarcoma virus (RSV) they proliferate actively and exhibit a transformed phenotype; this effect is mediated by the oncoprotein pp60v-src. Secondary cultures infected by the thermosensitive strain tsNY68 of RSV are blocked in G0 either by thermal inactivation of pp60v-src at 41.5 degrees C or by serum deprivation at the permissive temperature (36.5 degrees C). Cell division is reinduced either by pp60v-src thermal renaturation or by subsequent serum addition. Our results indicate that v-src and serum control two synergic pathways leading to G0/G1 transition in QNR cells. In order to characterize genes related to the mitogenic and transforming effects of v-src in nerve cells, we have constructed a cDNA library from QNR cells transformed by tsNY68. We report the properties of five molecular clones isolated by differential screening of this library. Unlike immediate-early genes like c-fos, they are induced in mid and late G1. Four of them correspond to unknown mRNAs and the last one codes for nucleolin. This set of v-src-regulated genes is likely to code for functions deficient in terminally differentiated QNR cells and necessary for the progression in G1.

Retinal dysplasia in mice lacking p56lck.

The product of the proto-oncogene p56lck is a non-receptor tyrosine kinase member of the Src family. It is found in T cells (Marth et al., 1985, 1988) and in the mouse brain (Omri et al., 1996; Van Tan et al., 1996). In this report, we describe experiments showing that Lck is present in the mouse retina neurons. Lck gene expression was identified after isolating and sequencing the specific 5' and 3' part of the cDNA obtained by RT-PCR. In adult retina Lck immunoreactivity was most abundant in photoreceptor cells and within the outer plexiform layers. Staining was also observed in the inner nuclear and plexiform layers. In transgenic mice, the disruption of the Lck gene had serious consequences on the organization of the retina causing retinal dysplasia. These mice have partial retinal detachment with infolding and rosette formation in the photoreceptor sheet. These retinal abnormalities observed in Lck deficient mice lead to the loss of normal architecture of the photoreceptor and the inner nuclear layers, and provide an important role of Lck protein in the retina development. The lack of the Lck protein produces a spectrum of retinal pathology that resembles human retinopathy of prematurity (ROP).

A novel cDNA corresponding to transcripts expressed in retina post-mitotic neurons.

The long term objective of this study is to isolate genes specifically expressed at the onset of neuronal cell cycle withdrawal. As an experimental paradigm we have used a quail neuroretinal cell clone (clone K2) immortalized by a thermosensitive mutant of Rous Sarcoma Virus. K2 cells proliferate at 36 degrees C but stop synthesizing DNA after a shift to 41.5 degrees C. We have constructed a cDNA library from K2 cells transferred to 41.5 degrees C and autosubtracted with RNAs from K2 cells maintained at 36 degrees C. This strategy has led to the isolation of cDNAs which recognize mRNAs expressed in quail neuroretina (NR) during development. We report here one of these cDNAs, cDNA QN1, that hybridizes with transcripts expressed in retina neurons, in parallel with their withdrawal from the cell cycle. QN1 ORF codes for a 138 kDa polypeptide corresponding to the protein observed in Western blot analysis. A role of QN1 product(s) on neuronal quiescence is suggested by the positive effect of an antisense oligonucleotide on DNA synthesis of K2 cells.

Astrocytic cerebellar cell clones synthesize the beta' isoforms of the beta-tubulin protein family.

We have analysed the isotubulin pattern of three astrocytic cell clones, derived from spontaneously established permanent cell cultures originating from 8-day postnatal mice cerebellar explants, in comparison with that of primary astroglial cultures from embryonic brain and cerebellum. These astrocytic clones, which may represent the different astroglial cell types of mouse cerebellum, did not produce the alpha- and beta-acidic isoforms, these being found only in cells of neuronal lineage. However, the three astrocytic clones, but not the primary astroglial cultures, did synthesize the beta'-tubulin isoforms; in addition quantitative analysis of the beta' proteins showed a positive correlation between the ability of the cells to extend processes and their synthesis of the beta' isoforms. These data suggest that the presence of beta'-tubulin is not specific for neuronal cells but may be related to the ability of cells from the nervous system to extend processes.

A novel glial fibrillary acidic protein mRNA lacking exon 1.

Glial fibrillary acidic protein (GFAP) is the major intermediate filament protein in the mature astrocytes. We have assayed for the presence of GFAP mRNA gene in mouse tissues outside the nervous system. Nuclease S1 protection experiments show that RNAs lacking exon 1 are transcribed in bone marrow. From a mouse bone marrow cDNA library we isolated GFAP cDNAs which start in the 3' part of intron 1 and contain all the downstream GFAP exons. The new GFAP mRNAs, which we call GFAP gamma mRNAs, are already present in the brain at embryonic day 15 and in adult forebrain and cerebellum. Their presence in astrocytic cell lines suggests that astrocytes may be the site of in vivo expression of these mRNAs. In addition we have detected GFAP gamma mRNAs in mouse spleen. Furthermore in human an analogous GFAP mRNA containing the 3' part of intron 1 and lacking the exon 1 is also present in adult brain. These results suggest a new regulation of the GFAP gene expression.

Astrocytic cell clones derived from established cultures of 8-day postnatal mouse cerebella.

Clonal permanent cell lines with astrocytic properties have been established from explant cultures of 8-day postnatal mouse cerebella after in vitro spontaneous transformation, i.e. without the addition of carcinogens or oncogenic viruses. The cell lines were derived in a multistage process. Slowly proliferating foci with several morphologies appeared 4 months after initiation of the cultures and became progressively enriched by cells with a homogeneous appearance. These cells could be established into permanent cell lines from which many clones were obtained. Some of these cloned cell lines bound anti-GFAP sera and therefore appeared to be astrocytic. According to their morphology, 3 separate types of these GFAP-positive clones could be distinguished. Type I and II cells had small somata; type I had several short processes, while type II had two processes, one of which was very thin and long (greater than 200 microns). Type III cells had large flat somata and no processes. The three types of clonal cell lines were labeled by monoclonal antibodies which bind to astrocytes in vivo. In particular, three monoclonal antibodies (BSP-3, M2 and M3) bound only to type II cells in a distinct pattern. Type I and II astrocytes are pseudodiploid and type III, heteroploid. The properties of these different clonal cell lines are very stable. We have thus obtained permanently established clonal cultures of mouse cerebellum astrocyte-like cells, which might be the in vitro counterparts of fibrous (type I), or velamentous (type III) astrocytes and of Golgi epithelial cells (type II).

A glial fibrillary acidic protein (GFA)-containing cell clone derived from mouse cerebella transformed 'in vitro' by SV-40.

A clonal cell line containing the glial fibrillary acidic protein (GFA) was derived from cultures of 14 day post-natal C57Bl mouse cerebella, transformed by SV-40. All the cells are GFA-positive - even in sparse exponential cultures - have been astroglial morphology and contain the intranuclear SV-40 T-antigen.

Expression of gamma-glutamyl transpeptidase in mouse perivascular astrocytes and in a protoplasmic-like astroglial cell clone.

Gamma-glutamyl transpeptidase (GGT) is known to be present in the central nervous system (CNS) but its cellular localization is still subject to controversy. In this report, we have investigated, with a specific antiserum, the immunolabelling pattern of GGT in the adult mouse CNS at the light and electron microscopic (EM) levels. At the optical level, GGT immunoreactivity ensheathes the majority of vessels in the grey matter. Immunoelectron microscopy shows that labelling is essentially due to the presence of GGT in the astrocytic endfeet which surround vessels. In addition, some pericytes and periendothelial cells are also clearly labelled. We then investigated GGT activity in astroglial cell clones which may represent the in vitro counterpart of the main astroglial cell types. The striking result is that a protoplasmic-like astroglial cell clone shows a noticeable GGT activity, while, in contrast, no activity was detected in the fibrous and the Golgi-Bergmann-like astroglial clones. Taken together, these data indicate that, in the mouse CNS, GGT is essentially present in protoplasmic astrocytes.

The presence of glutamic acid decarboxylase and gamma-aminobutyric acid immunoreactivity in photoreceptors of hatching quail retina.

The presence of glutamic acid decarboxylase (GAD) and gamma-aminobutyric acid (GABA) was investigated in neuroretina sections from hatching quail embryos by immunocytochemistry. The photoreceptors were found to be intensely immunoreactive to anti-GAD antiserum and to two distinct anti-GABA antisera.

Brain parenchyma vessels and the angiotensin system.

It is now recognized that the brain contains an autonomous angiotensin (AG) system, including the aminopeptidases A and N required for angiotensin metabolism. Using immunohistochemical techniques, we show that capillary pericytes and periendothelial cells of other vessels express aminopeptidase A (APA) and aminopeptidase N (APN) at their plasma membrane in adult mouse brain parenchyma. We therefore investigated the localization of angiotensin II(III), known as putative substrates for these enzymes, as well as that of their precursor angiotensin I. We report here the presence of immunoreactivity to angiotensin I and II(III) around most brain vessels. Angiotensins are present at the plasma membrane of brain parenchymal cells, presumably perivascular astrocytes which are also immunoreactive to AT1-receptor antibodies. The very close relationship between AGII(III) and their metabolizing enzymes APA and APN suggests a specific functional role for brain perivascular angiotensins.

Quail neural crest cells transformed by Rous sarcoma virus can be established into differentiating permanent cell cultures.

Quail neural crest cells derived from the truncal neural primordium, infected in vitro by Rous sarcoma virus (RSV) in January 1978, were induced to multiply and have been established into permanent cultures. These cultures contain cells that differentiate into melanocytes, neuron-like cells and flat cells. About 50% of these different cell types are tetanus-toxin positive. Electrophysiological studies have shown that some cells can generate action potentials similar to those reported in quail neural crest primary cultures. Taken together these data show that the RSV-transformed quail neural crest permanent cultures are composed of stem cells which can differentiate into cell types specific for neural crest.

Cells with neuronal properties in permanent cultures of quail embryo neuroretinas infected with Rous sarcoma virus.

Neuroretina cells from 7-day quail embryos infected 'in vitro' with the mutant ts NY-68 of Rous sarcoma virus, were established into permanent cultures. An initial stage of cellular proliferation was followed by a period of minimal multiplication. After recovery from this crisis, cell proliferation resumed. About 30% of the cells had binding sites for tetanus toxin and the monoclonal antibody A2B5 which seem to be specific for neurons, and an ultrastructural study suggested the presence of neurons and Müller (astroglial) cells. The specific activity of glutamic acid decarboxylase, the enzyme responsible for the synthesis of the neurotransmitter gamma-aminobutyric acid was high (10-30 nmol CO2/h/mg of protein) and electrophysiology showed that some cells had 'active' membranes. After about 18 months in culture, approximately 20% of the cells were able to respond to electrical stimulation by producing action potentials which were inhibited by 10(-7) M tetrodotoxin. These electrophysiological properties are stable: they have been repeatedly found at regular intervals throughout a 20 months period. Furthermore, a clone in which all tested cells are excitable, has been derived from the mass culture. Quail embryo neuroretina cells with typical neuronal properties can thus be established into permanent cultures after infection with Rous sarcoma virus.

Microglia derive from progenitors, originating from the yolk sac, and which proliferate in the brain.

Microglia, the resident CNS macrophages, represent about 10% of the adult brain cell population. Although described a long time ago, their origin and developmental lineage is still debated. While del Rio-Hortega suggested that microglia originate from meningeal macrophages penetrating the brain during embryonic development, many authors claim that brain parenchymal microglia derive from circulating blood monocytes originating from bone marrow. We have previously reported that the late embryonic and adult mouse brain parenchyma contains potential microglial progenitors [F. Alliot, E. Lecain, B. Grima, B. Pessac, Microglial progenitors with a high proliferative capacity in the embryonic and the adult mouse brain, Proc. Natl. Acad. Sci. U.S.A. 88 (1991) 1541-1545]. We now report that they can be detected in the brain rudiment from embryonic day 8, after their appearance in the yolk sac and that their number increases until late gestation. We also show that microglia appear during embryonic development and that their number increases steadily during the first two postnatal weeks, when about 95% of microglia are born. Finally, the main finding of this study is that microglia is the result of in situ proliferation, as shown by the high proportion of parenchymal microglial cells that express PCNA, a marker of cell multiplication, in embryonic and postnatal brain. Taken together, our data support the hypothesis that terminally differentiated brain parenchymal microglia are derived from cells originating from the yolk sac whose progeny actively proliferates in situ during development.

Role of astroglial cell clones in the survival and differentiation of cerebellar embryonic neurons.

To investigate the role of astrocytes in the survival and differentiation of cerebellar neurons during development, we have used astroglial cell clones, derived from 8-day postnatal cerebellar explants and which might be the in vitro equivalents of the 3 main types of cerebellar astrocytes, the Golgi epithelial cells and their Bergmann processes, the velate protoplasmic and the fibrous astrocytes (F. Alliot and B. Pessac, Brain Res., 306 (1984) 283-291). Nearly all single cells, dissociated from 15-day embryonic mouse cerebella and seeded at low density, adhered to layers of each of the cerebellar astroglial cell clones as well as to other glial lines or artificial substrates. However, the cerebellar embryonic neurons survived well only on monolayers of either the 'Golgi-Bergmann'-like or the 'velate protoplasmic'-like clones. On these layers, 60-80% of the neurons were still present after 5 days of co-culture, while only less than 5% survived on the other types of substrates. The differentiation pattern of the neurons surviving on the 'Golgi-Bergmann' and the 'velate protoplasmic' astroglial clones was studied with markers of postmitotic granule cells, the major neuronal population in adult cerebellum. The velate protoplasmic-like clone was the only one able to support the coordinate acquisition by most surviving neurons of the phenotypic characteristics of granule cells, i.e. a distinct morphology, a specific epitope binding the monoclonal antibody 7-8 D2 and immunoreactivity to glutamate. These data show a broad heterogeneity in the capacity of astroglial cell clones to support embryonic cerebellar neurons. In addition, they indicate that neuronal survival per se is not sufficient for the acquisition of a differentiated neuronal phenotype.

A spontaneously immortalized mouse microglial cell line expressing CD4.

We have derived a microglial clone, named C8-B4, from the 8-day mouse cerebellum organ culture which gave rise to distinct astroglial cell lines as previously reported. Indeed, the C8-B4 clone expresses classical microglial markers (MAC1, F4/80, 2-4G2) and appears to be derived from a committed microglial precursor since it does not express differentiation antigens present during the early stage of the monocytic lineage. This microglial clone expresses two characteristics not previously reported for microglial cell lines: it synthesizes the CD4 molecule and produces and releases large amounts of glutamate.

Ly-6C is expressed in brain vessels endothelial cells but not in microglia of the mouse.

The Ly-6C antigen is expressed in various cell types of the immune system, including macrophages. Using the monoclonal antibody ER-MP20 which specifically recognises Ly-6C, we have investigated whether brain parenchymatous microglia express Ly-6C in vivo as well as in vitro. In brain sections from developing and adult C57/BI mice, all vessels were strongly immunolabelled. Electron microscopic immunohistochemistry showed that the endothelial cells are the cell type expressing Ly-6C. In contrast, we never observed immunoreactivity on microglia; however, microglial cells proliferating in vitro were strongly ER-MP20 positive. These data show that Ly-6C is not a marker for microglia in vivo.

[Microglia: origin and development]. / Microglie: origine et développement.

As suggested by Del Rio Ortega a long time ago, it is now widely accepted that microglia are the resident macrophages of the central nervous system. Microglia represent about 10% of the adult brain cell population. We have previously shown that the late embryonic and adult mouse brain contain potential microglial progenitors. We report here that microglial progenitors can be detected in neural folds from embryonic day 8. They originate from the yolk sac in which macrophage progenitors are found from embryonic day 7. We also report that the bulk of microglial cells (about 95%) appear during post-natal development. A major finding is that microglia arise by an intense in situ proliferation comparable to that of neural cells. Taken together, these results show that adult mouse microglia originate from cells migrating from the yolk sac and whose progeny actively proliferates in the brain during development.