Microcebus murinus: a useful primate model for human cerebral aging and Alzheimer's disease?

Age-associated dementia, in particular Alzheimer's disease (AD), will be a major concern of the 21st century. Research into normal brain aging and AD will therefore become increasingly important. As for other areas of medicine, the availability of good animal models will be a limiting factor for progress. Given the complexity of the human brain, the identification of appropriate primate models will be essential to further knowledge of the disease. In this review, we describe the features of brain aging and age-associated neurodegeneration in a small lemurian primate, the Microcebus murinus, also referred to as the mouse lemur. The mouse lemur has a relatively short life expectancy, and animals over 5 years of age are considered to be elderly. Among elderly mouse lemurs, the majority show normal brain aging, whereas approximately 20% develop neurodegeneration. This Microcebus age-associated neurodegeneration is characterized by a massive brain atrophy, abundant amyloid plaques, a cytoskeletal Tau pathology and a loss of cholinergic neurons. While elderly mouse lemurs with normal brain aging maintain memory function and social interaction, animals with age-associated neurodegeneration lose their cognitive and social capacities and demonstrate certain similarities with age-associated human AD. We conclude that M. murinus is an interesting primate model for the study of normal brain aging and the biochemical dysfunctions occurring in age-associated neurodegeneration. Mouse lemurs might also become an increasingly important model for the development of novel treatments in this domain.

Association of a gliotoxic activity with active multiple sclerosis in US patients.

We recently found that cerebrospinal fluid (CSF) from multiple sclerosis (MS) patients contains a gliotoxic activity which induces programmed cell death of astrocytes and oligodendrocytes and could be the main contributing factor to the massive glial cell death seen in MS active lesions. A previous clinical study aimed at evaluating the gliotoxicity of CSF from a cohort of MS patients from France indicated that MS patients with the active form of the disease do indeed present significant CSF gliotoxicity. To extend this observation, the effect of 141 CSFs from United States patients with different neurological diseases (including 71 MS) was tested on immortalized astrocytes. A cell death assay showed that a gliotoxic activity is significantly present in the CSF from MS patients with the active forms. Thus, this gliotoxic activity may represent a critical pathogenic factor in the neuropathology of active MS by playing a role both in demyelinisation and alteration of the blood-brain barrier.

Abnormal reinnervation of skeletal muscle in a tenascin-C-deficient mouse.

The possible involvement of tenascin-C in the reinnervation of a skeletal muscle was investigated in the tenascin-C-deficient mouse (T-/-) produced by Saga et al. (1992; Genes Dev 6:1821-1831). The pattern of reinnervation, observed after denervation of the triangularis sterni muscle, differs in T-/- and wild-type muscles in several traits. Axonal growth and stability of terminal arbors are impaired in the T-/- muscle: Some axons in mutant muscles grow beyond their original targets and reinnervate other synaptic sites, which may become dually innervated. In contrast to wild type, polyinnervation increases with time after denervation in T-/- muscles and is still present 7 months after nerve crush. The expression of a tenascin-C mRNA product disappears between 1 and 2 months after nerve crush. Of interest is that this transcriptional regulation in T-/- muscles occurs when major alterations in the morphology of regenerating endings become obvious. These observations strongly implicate tenascin-C in the formation, maturation, and stabilization of the neuromuscular junction.

Modulation of HSP25 expression during anterior horn motor neuron degeneration in the paralysé mouse mutant.

The paralysé spontaneous mutation in mice involves degeneration and death of anterior horn motor neurons. Mutant mice are not viable past postnatal day 16. At present, the mechanisms involved in motor neuron death are unknown. Here, we investigate the expression of the small heat shock protein Hsp25, in the spinal cord of paralysé at two different stages during postnatal development, i.e., day 11 and day 14. Western blot analysis reveals that the level of Hsp25 was strikingly different in paralysé as compared to control littermates. Hsp25 expression level in paralysé at day 11 was much lower than in control mice. At day 14, an opposite pattern was observed. Such pattern seems to be restricted to spinal cord, since level of Hsp25 in other tissues (lung, brain, liver, and heart) was quite similar. Immunofluorescence examination of the lumbar spinal cord sections reveals that in control mice, Hsp25 was expressed at high level in motor neurons located in the ventral horn at both day 11 and day 14. By contrast, in paralysé mice, Hsp25 staining within the motor neurons was barely detectable except as a spot in the nucleolus (day 11). At the end stage of the disease (day 14), not only was Hsp25 staining even less intense in motor neurons, but also a strong Hsp25 staining was observed in reactive astrocytes within the gray matter. Taken together, these data suggest that Hsp25 expression is differently modulated in neuronal and glial cells during neurodegenerative processes leading to motor neuron death.

Transient massive DNA fragmentation in nervous system during the early course of a murine neurodegenerative disease.

In neurodegenerative diseases, such as Alzheimer's disease or HIV encephalitis, neuronal DNA fragmentation has been observed at unexpected high frequencies, without definitive evidence for activation of an irreversible apoptotic pathway. The wobbler mouse is a suggested genetic model of neurodegenerative disease. The mutant mouse develops normally until the fourth week of age when atrophy and weakness of forelimb muscles become apparent. There is a slow progression of the disease and wobbler mice may survive for several months. Spinal cord examination reveals the presence of several motoneurons with perikaryal vacuolar degeneration. In this study, we observed, using terminal dUTP nick-end-labelling staining in mutant spinal cord sections, a massive although very transient DNA fragmentation in different cell types, including glial cells and motoneurons, before the apparition of any clinical symptoms. In older wobbler mice, this DNA fragmentation had completely disappeared and the majority of motoneurons survived. To our knowledge, this is the first example of a massive and transient DNA fragmentation in the central nervous system during the early course of a neurodegenerative disease.

Specific features of chronic astrocyte gliosis after experimental central nervous system (CNS) xenografting and in Wobbler neurological mutant CNS.

This study sets out to compare and contrast the astrocyte reaction in two unrelated experimental designs both resulting in marked chronic astrogliosis and natural motoneuron death in the wobbler mutant mouse and brain damage in the context of transplantation of xenogeneic embryonic CNS tissue into the striatum of newborn mice. The combined use of GFAP-labeling and confocal imaging allows the morphological comparison between these two different types of astrogliosis. Our findings demonstrate that, in mice, after tissue transplantation in the striatum, gliosis is not restricted to the regions of damage: it occurs not only near the site of transplantation, the striatum, but also in more distant regions of the CNS and particularly in the spinal cord. In the wobbler mutant mouse, a strong gliosis is observed in the spinal cord, site of motoneuronal cell loss. However, moderate astrocytic reaction (increased GFAP-immunoreactivity) can also be found in other wobbler CNS regions, remote from the spinal cord. In the wobbler ventral horn, where neurons degenerate, the hypertrophied reactive astrocytes exhibit a dramatic increase of glial fibrils and surround the motoneuron cell bodies, occupying most of the motoneuron environment. The striking and specific presence of hypertrophic astrocytes in wobbler mice accompanied by a dramatic increase of glial fibrils located in the vicinity of motoneuron cell bodies suggests that short astrogliosis fills the space left by degenerating motoneurons and interferes with their survival. In the spinal cord of xenografted mice, chronic astrogliosis is also observed, but only glial processes without hypertrophied cell bodies are found in the neuronal micro-environment. It is tempting to speculate that gliosis in the wobbler spinal cord, the local accumulation of astrocyte cell bodies, and high density of astrocytic processes may interfere with the diffusion of neuroactive substances in gliotic tissue, some of which are neurotoxic, and cooperate or even trigger neuronal death.

Regulated expression of the proteoglycan SPOCK in the neuromuscular system.

SPOCK is prevalent in developing synaptic fields of the central nervous system (Charbonnier et al., 2000. Mech. Dev. 90, 317-321). The expression of SPOCK during neuromuscular junction (NMJ) formation was compared to agrin and acetylcholine receptor (AChR) distribution. SPOCK is detected within the myogenic masses during the early steps of embryonic development, and distributed in the cytoplasm of myotubes before coclustering with AChRs. In the adult, SPOCK is present in axons and is highly expressed by Schwann cells. SPOCK altered expression pattern after nerve lesioning, or cholinergic transmission blockade, strongly indicate that its cellular distribution at the NMJ depends on innervation.

Myoneurin, a novel member of the BTB/POZ-zinc finger family highly expressed in human muscle.

Initially characterized as Drosophila developmental regulators, the BTB/POZ and zinc finger proteins (BTB/POZ-ZF) constitute a growing family of proteins with gene expression regulatory functions since they have been shown to be involved in both transcriptional activation and repression of various genes in a broad range of species, including mammals. Here we report the cloning of a novel human transcript, coding for a 68-kDa deduced BTB/POZ-ZF protein. This molecule, called myoneurin on the basis of its prevalent expression in the neuromuscular system, contains an amino-terminal BTB/POZ domain and eight tandemly repeated zinc-finger motifs of the C(2)H(2) type. The murine myoneurin, identified in the mouse embryo, is highly homologous to the human protein.

Particle-associated retroviral RNA and tandem RGH/HERV-W copies on human chromosome 7q: possible components of a 'chain-reaction' triggered by infectious agents in multiple sclerosis?

Different groups have observed retrovirus particle (RVP) production in cell cultures from patients with multiple sclerosis (MS). This in vitro production appeared relatively specific for MS versus healthy controls, but was likely to be enhanced or activated by infectious triggers such as Herpesviruses (e.g. HSV, EBV). Independent molecular analysis of retroviral RNA associated with RVP revealed two different genetic families of endogenous retroviral elements (HERV): MSRV/HERV-W and RGH/HERV-H. Interestingly, these sequences were detected by mutually exclusive primers in RT - PCR amplifications. Surprisingly, these two HERV families both contain an ancestral proviral copy inserted in chromosome 7q21-22 region at about 1 kb of distance of each other. Another HERV-W proviral sequence is located within a T-cell alpha-delta receptor (TCR) gene in chromosome 14q11.2 region. Interestingly, these two regions correspond to genetic loci previously identified as potentially associated with 'multigenic' susceptibility to MS and TCR alpha chain genetic determinants have been reported to be statistically associated with MS. A plausible role for infectious agents triggering a co-activation of the chromosome 7q HERV tandem (replicative retrovirus and/or other virus and/or intracellular bacteria) and, eventually, other HERV copies, is discussed. The role of particular HERV polymorphism and the production of pathogenic molecules (gliotoxin and superantigen) possibly associated with retroviral expression are also evoked. An integrative concept of pathogenic 'chain-reaction' in MS involving several step-specific pathogenic 'agents' and 'products' somewhat interacting with particular genetic elements would federate most partial data obtained on MS, including retroviral expression.

Alterations in contractile properties and expression of myofibrillar proteins in wobbler mouse muscles.

The purpose of this study was to characterize the alterations in muscle contractile (tension-pCa relationship) and biochemical (myosin heavy and light chains, troponin C content) properties in a hereditary motoneuron disease. The study was performed on wobbler mouse mutants which presented a neuronal degeneration. The time course of the disease was followed at 5 and 7 weeks in sternocleidomastoid (SCM) and soleus muscles. The wobbler disease was found to induce a shift from fast to slow myosin heavy-chain isoform expression in SCM and soleus muscles. The analysis of the myosin light-chain (MLC) composition revealed, for the SCM muscles, the appearance of the slow isoforms at 5 weeks and an increase in the regulatory MLC2 content at 7 weeks. A significant increase in the slow troponin C isoform content was found in both types of wobbler muscles at 7 weeks. The wobbler soleus and SCM muscles presented an age- and fiber-type-related atrophy, characterized by a decline in absolute maximal tension and fiber diameter. A decrease in calcium sensitivity was observed at 7 weeks for the soleus fibers and at both 5 and 7 weeks for the SCM. The results indicated fast-to-slow changes in contractile and biochemical properties of the wobbler soleus and SCM muscles, which occurred during the motoneuron degeneration process previously described in the wobbler pathology.

New perspectives in multiple sclerosis: retroviral involvement and glial cell death.

Retroviral involvement in the pathogenic cascade in multiple sclerosis (MS) and a cytotoxic activity with narrow specificity towards glial cells have been recently considered as credible working hypotheses to explain some of the complex pathophysiological and neuropathological features of MS. The partial characterization of exogenous retroviral sequences, thought to be associated with MS, has led us to the identification of new human endogenous retroviruses closely related to the extracellular multiple sclerosis associated retrovirus (MSRV). These endogenous retroviruses (HERV-TcR and HERV-7q) have the potential to be transcribed into RNA and proteins. Interestingly, the env domain of HERV-7q could code for a 59.8 kDa secreted glycoprotein (called enverin) with an immunoregulatory region. The presence in various MS biological fluids of a cytotoxic activity able to induce programmed cell death for oligodendrocytes and astrocytes suggests the possibility of a demyelination phenomenon as part of direct glial cell damage. Moreover, both retroviral expression and cytotoxic factor production have been evidenced in MS monocyte/macrophage cultures and MS cerebrospinal fluid. It is now crucial to better characterize the endo/exo retroviruses possibly involved in MS and their pathogenic potential, and to identify the contributing factor(s) to the gliotoxicity found in the MS cerebrospinal fluid or serum, as well as to elucidate the mechanism of induction of the observed programmed glial cell death.

Influence of factors secreted by wobbler astrocytes on neuronal and motoneuronal survival.

During late postnatal development, mice with the autosomal recessive wobbler mutation (wr/wr) develop motoneuron degeneration associated with astrogliosis in the spinal cord. In vitro, primary wobbler astrocytes are also affected, exhibiting abnormal cell-cell contacts. To characterize further the wobbler disease, we investigated the in vitro effects of wobbler astrocytes on primary neuronal cultures from the spinal cords of 15-day-old wild-type mouse and rat embryos. Cocultures with the wobbler astrocytes, or direct addition of wobbler astrocyte-conditioned medium, led to a decrease in neuron number in primary mixed neuronal cultures, containing motoneurons and interneuron-like cells. In contrast, wobbler astrocyte-conditioned medium enhanced survival of highly purified motoneurons. These in vitro results suggest the possibility that wobbler astrocytes act not on motoneurons directly but, rather, through other spinal neurons to induce motoneuron degeneration in the wobbler disease.

Expression of the proteoglycan SPOCK during mouse embryo development.

SPOCK is a modular proteoglycan, with homology with proteins involved in cell adhesion processes and neurogenesis. We have previously shown that SPOCK transcripts predominate in the adult mouse brain. Here, we report its expression during mouse embryonic development by in situ hybridization, and immunocytochemistry. SPOCK is actively expressed at the onset of neurogenesis during periods of neuron migration and axonal outgrowth. At a later developmental stage, its expression is particularly prevalent within developing synaptic fields. In the peripheral nervous system, SPOCK expression is also developmentally regulated particularly in dorsal root ganglion neurons.

Astrocyte proliferation induced by wobbler astrocyte conditioned medium is blocked by tumor necrosis factor-alpha (TNF-alpha) and interleukin-1beta (IL-1beta) neutralizing antibodies in vitro.

The wobbler mutant mouse (wr/wr) displays motoneuron degeneration and astrocyte reactivity in the spinal cord. We have previously reported that, in vitro, primary wobbler astrocytes display morphological and biochemical changes. In this report, we show that wobbler astrocyte conditioned medium enhances the in vitro proliferation of normal neonatal primary astrocytes. This stimulated proliferation is correlated with high levels of IL1-beta and TNF-alpha cytokines in the conditioned medium of wobbler astrocytes. Neutralizing antibodies directed against both IL1-beta and TNF-alpha block the wobbler astrocyte conditioned medium-enhanced astrocyte proliferation. Moreover, IL1-beta and TNF-alpha mRNAs are elevated in the wobbler spinal cord. All these data suggest that diffusible IL1-beta and TNF-alpha are involved in the processus of astrogliosis observed in the wobbler spinal cord.

Genomic organization and expression of the ubiquitin-proteasome complex-associated protein Rbx1/ROC1/Hrt1.

Rbx1/ROC1/Hrt1 (Rbx1) has been recently shown to be involved in the regulation of protein turn-over. Here, we report the organization of the human Rbx1 gene, established by both a cloning and a functional genomics approach. The human gene, composed of five exons, encompasses 22.3 kb on chromosome 22q 13. The expression of Rbx1 transcripts (0.5 kb) appears developmentally regulated during mouse embryonic development and is prevalent in the adult mouse genital tract. A Genbank database search for Rbx1 related sequences in various species, from plants to mammals, is indicative of a high degree of evolutionary conservation in mouse rat and zebra fish and also, for the main functional part of the molecule, in other living species, although their gene structures can be significantly altered.

Endogenous retroviruses and multiple sclerosis. II. HERV-7q.

The search for new endogenous retroviral sequences, on the basis of sequence homologies with the pol gene of the recently reported multiple sclerosis associated retrovirus (MSRV), allowed us to identify a full length endogenous retrovirus sequence located on the long arm of human chromosome 7. This retrovirus, HERV-7q, includes in its env region, within a single 1,620 bp open reading frame, a 664 bp domain almost identical to a 3' non-coding region of the rab7 gene. Transcripts encompassing both the env and the 3' LTR regions of HERV-7q have already been identified as expressed sequence tags, suggesting that this env-like gene might code for a 538 amino acid long deduced protein.

[Endogenous retroviral sequences analogous to that of the new retrovirus MSRV associated with multiple sclerosis (part 1)]. / Séquences rétrovirales endogènes analogues à celle du nouveau rétrovirus MSRV associé à la sclérose en plaques (1re partie).

Multiple sclerosis (MS) is still of unknown origin and may involve autoimmune, genetic and viral components in a pathogenic sequence whose relative importance is yet to be determined. A peptide, isolated from the cerebrospinal fluid of MS patients, is similar to a fragment of the pol protein reverse transcriptase (RT) of the newly reported MSRV retrovirus. The 700 amino acid sequence of MSRV-RT is closely related to a novel human retroviral-like sequences. We also identified a gag-like sequence upstream of this human genomic RT-like sequence, which allowed us to identify altogether 4,000 nucleotides, possibly coding for an endogenous retroviruses. Homologous sequences found in other locations in the human genome seem to characterize a new family of retroviral endogenous sequences, which may be of relevance to multiple sclerosis.

An endogenous retrovirus with nucleic acid sequences similar to those of the multiple sclerosis associated retrovirus at the human T-cell receptor alpha, delta gene locus.

Retroviruses are suspected to be involved in the pathogenesis of autoimmune diseases, such as multiple sclerosis (MS). Here, we describe a complete cartography of a novel human endogenous retroviral sequence with a pol domain which shares a high homology with the pol sequence of the multiple sclerosis associated retrovirus (MSRV). Since this new endogenous retroviral sequence is located in the close vicinity of the locus of the human gene coding for the T-cell receptor (TcR) alpha and delta chains on chromosome 14, it could be of potential interest for the understanding of MS pathogenesis.