Partial characterization of the 5'-flanking region of trout IP: a Po-like gene containing a PLP-like promoter

Emerging concepts in oligodendrocyte and myelin formation, inputs from the zebrafish model

Oligodendrocytes (OLs) are the myelinating cells of the central nervous system (CNS), which are derived from OL precursor cells. Myelin insulates axons allowing the saltatory conduction of action potentials and also provides trophic and metabolic supports to axons. Interestingly, oligodendroglial cells have the capacity to sense neuronal activity, which regulates myelin sheath formation via the vesicular release of neurotransmitters. Neuronal activity-dependent regulation of myelination is mediated by specialized interaction between axons and oligodendroglia, involving both synaptic and extra-synaptic modes of communications. The zebrafish has provided key advantages for the study of the myelination process in the CNS. External development and transparent larval stages of this vertebrate specie combined with the existence of several transgenic reporter lines provided key advances in oligodendroglial cell biology, axo-glial interactions and CNS myelination. In this publication, we reviewed and discussed the most recent knowledge on OL development and myelin formation, with a focus on mechanisms regulating these fundamental biological processes in the zebrafish. Especially, we highlighted the critical function of axons and oligodendroglia modes of communications and calcium signaling in myelin sheath formation and growth. Finally, we reviewed the relevance of these knowledge's in demyelinating diseases and drug discovery of pharmacological compounds favoring myelin regeneration.

The Current Challenges for Drug Discovery in CNS Remyelination

The myelin sheath wraps around axons, allowing saltatory currents to be transmitted along neurons. Several genetic, viral, or environmental factors can damage the central nervous system (CNS) myelin sheath during life. Unless the myelin sheath is repaired, these insults will lead to neurodegeneration. Remyelination occurs spontaneously upon myelin injury in healthy individuals but can fail in several demyelination pathologies or as a consequence of aging. Thus, pharmacological intervention that promotes CNS remyelination could have a major impact on patient’s lives by delaying or even preventing neurodegeneration. Drugs promoting CNS remyelination in animal models have been identified recently, mostly as a result of repurposing phenotypical screening campaigns that used novel oligodendrocyte cellular models. Although none of these have as yet arrived in the clinic, promising candidates are on the way. Many questions remain. Among the most relevant is the question if there is a time window when remyelination drugs should be administrated and why adult remyelination fails in many neurodegenerative pathologies. Moreover, a significant challenge in the field is how to reconstitute the oligodendrocyte/axon interaction environment representative of healthy as well as disease microenvironments in drug screening campaigns, so that drugs can be screened in the most appropriate disease-relevant conditions. Here we will provide an overview of how the field of in vitro models developed over recent years and recent biological findings about how oligodendrocytes mature after reactivation of their staminal niche. These data have posed novel questions and opened new views about how the adult brain is repaired after myelin injury and we will discuss how these new findings might change future drug screening campaigns for CNS regenerative drugs.

Phylogeny of proteolipid proteins: divergence, constraints, and the evolution of novel functions in myelination and neuroprotection

The protein composition of myelin in the central nervous system (CNS) has changed at the evolutionary transition from fish to tetrapods, when a lipid-associated transmembrane-tetraspan (proteolipid protein, PLP) replaced an adhesion protein of the immunoglobulin superfamily (P0) as the most abundant constituent. Here, we review major steps of proteolipid evolution. Three paralog proteolipids (PLP/DM20/DMalpha, M6B/DMgamma and the neuronal glycoprotein M6A/DMbeta) exist in vertebrates from cartilaginous fish to mammals, and one (M6/CG7540) can be traced in invertebrate bilaterians including the planktonic copepod Calanus finmarchicus that possess a functional myelin equivalent. In fish, DMalpha and DMgamma are coexpressed in oligodendrocytes but are not major myelin components. PLP emerged at the root of tetrapods by the acquisition of an enlarged cytoplasmic loop in the evolutionary older DMalpha/DM20. Transgenic experiments in mice suggest that this loop enhances the incorporation of PLP into myelin. The evolutionary recruitment of PLP as the major myelin protein provided oligodendrocytes with the competence to support long-term axonal integrity. We suggest that the molecular shift from P0 to PLP also correlates with the concentration of adhesive forces at the radial component, and that the new balance between membrane adhesion and dynamics was favorable for CNS myelination.

Zebrafish myelination: a transparent model for remyelination?

There is currently an unmet need for a therapy that promotes the regenerative process of remyelination in central nervous system diseases, notably multiple sclerosis (MS). A high-throughput model is, therefore, required to screen potential therapeutic drugs and to refine genomic and proteomic data from MS lesions. Here, we review the value of the zebrafish (Danio rerio) larva as a model of the developmental process of myelination, describing the powerful applications of zebrafish for genetic manipulation and genetic screens, as well as some of the exciting imaging capabilities of this model. Finally, we discuss how a model of zebrafish myelination can be used as a high-throughput screening model to predict the effect of compounds on remyelination. We conclude that zebrafish provide a highly versatile myelination model. As more complex transgenic zebrafish lines are developed, it might soon be possible to visualise myelination, or even remyelination, in real time. However, experimental outputs must be designed carefully for such visual and temporal techniques.

Evolution of myelin proteolipid proteins: Gene duplication in teleosts and expression pattern divergence

The coevolution of neurons and their supporting glia to the highly specialized axon-myelin unit included the recruitment of proteolipids as neuronal glycoproteins (DMbeta, DMgamma) or myelin proteins (DMalpha/PLP/DM20). Consistent with a genome duplication at the root of teleosts, we identified three proteolipid pairs in zebrafish, termed DMalpha1 and DMalpha2, DMbeta1 and DMbeta2, DMgamma1 and DMgamma2. The paralogous amino acid sequences diverged remarkably after gene duplication, indicating functional specialization. Each proteolipid has adopted a distinct spatio-temporal expression pattern in neural progenitors, neurons, and in glia. DMalpha2, the closest homolog to mammalian PLP/DM20, is coexpressed with P0 in oligodendrocytes and upregulated after optic nerve lesion. DMgamma2 is expressed in multipotential stem cells, and the other four proteolipids are confined to subsets of CNS neurons. Comparing protein sequences and gene structures from birds, teleosts, one urochordate species, and four invertebrates, we have reconstructed major steps in the evolution of proteolipids.

Oligodendrocyte development and myelination in GFP-transgenic zebrafish

Green fluorescent protein (GFP) transgenic zebrafish technology has been employed to directly visualize and analyze dynamic developmental processes, such as cell migration and morphogenesis. Stable transgenic zebrafish that express GFP in oligodendrocytes can be a valuable tool to visualize complex myelination processes in vivo, as well as to conduct rapid mutagenesis screens for defective myelination mutants. We investigated whether two myelin gene promoters, the zebrafish P0 promoter and the mouse proteolipid protein (PLP) promoter, drive GFP expression in zebrafish oligodendrocytes. Transiently, both promoters drive enhanced GFP (EGFP) expression in morphologically identifiable oligodendrocytes, premyelinating oligodendrocytes, and possible oligodendrocyte precursors. We have established a stable transgenic zebrafish line, tg(plp:EGFP) zebrafish, at the F1 generation, which expresses enhanced GFP (EGFP) driven by the mouse PLP promoter. In this transgenic line, EGFP-expressing cells are visually detectable around 24-hr postfertilization (hpf), and later at 54 hpf, these cells start exhibiting the clear morphologic characteristics of oligodendrocytes. Shortly afterward, EGFP-expressing oligodendrocytes establish a ventral dominant distribution pattern throughout the central nervous system. This transgenic zebrafish line is likely to serve as a useful tool, in which normal myelination as well as abnormal myelination can be recorded under time-lapse confocal microscopy. Furthermore, it has the potential to greatly facilitate mutagenesis screening for novel dysmyelinating mutants.

Application of comparative genomics in fish endocrinology

This review discusses the ways in which comparative genomics can contribute to the study of fish endocrinology. First, the phylogenetic position of fish and an overview of their specific endocrine systems are presented. The emphasis will be on teleosts because they are the most abundant fishes and because most data are available for this group. Second, the complexity of fish genomics is reviewed. With the vast array of genome sizes and ploidy levels, assignment of gene orthology is more difficult in fish, but this is an absolute prerequisite in functional analysis and it is important to be aware of such genome plasticity when cloning genes. The ease with which a gene is cloned at the genomic level is directly related to genome size and complexity, a factor that is not known in the majority of fish species. Finally, the methodology is presented along with specific examples of parathyroid hormone-related protein (PTHrP) (a previously unidentified hormone in fish), calcium-sensing receptor, and calcitonin (with a duplication of this particular ligand in Fugu rubripes). Preliminary data also suggest that there are further duplicated genes in the calcium regulatory system. Comparative genomics has provided a valuable approach for isolating and characterizing a range of fish genes involved in calcium regulation. However, for understanding the physiology and endocrine regulation of this system, particularly with regard to gene duplication, an alternative approach is required in which conventional endocrinology techniques will play a significant role.

Characterization of myelination in the developing zebrafish

Myelination, the process by which glial cells ensheath and electrically insulate axons, has been investigated intensely. Nevertheless, knowledge of how myelination is regulated or how myelinating cells communicate with neurons is still incomplete. As a prelude to genetic analyses of these processes, we have identified zebrafish orthologues of genes encoding major myelin proteins and have characterized myelination in the larval zebrafish. Expression of genes corresponding to proteolipid protein (PLP/DM20), myelin protein zero (P0), and myelin basic protein (MBP) is detected at 2 days postfertilization (dpf), first in the ventral hindbrain, close to the midline. During the next 8 days, expression spreads rostrally to the midbrain and optic nerve, and caudally to the spinal cord. DM20 is expressed in the CNS only, while MBP transcripts are detected both in the CNS and in Schwann cells of the lateral line, cranial nerves, and spinal motor nerves. Unlike its closest homologue, trout IP1, zebrafish P0 transcripts were restricted to the CNS. Ultrastructurally, the expression of myelin genes correlated well with myelination, although myelination showed a temporal lag. Myelinated axons were first detected at 4 dpf in the ventral hindbrain, where they were loosely wrapped by processes of glia cells. By 7 dpf, bundles of heavily myelinated axons were observed in the same region. Axons in the lateral line and optic nerves were also surrounded by compact myelin. Conservation in gene expression patterns and the early appearance of myelinated axons, support using the zebrafish to dissect the process of myelination by a genetic approach.

GDNF family members and their receptors: expression and functions in two oligodendroglial cell lines representing distinct stages of oligodendroglial development

Glial cell line-derived neurotrophic factor (GDNF), neurturin (NTN), and persephin (PSP) constitute a subfamily of transforming growth factor-betas (TGF-betas) with prominent roles in the regulation of neuron survival and differentiation. Although numerous members of the TGF-beta superfamily are important regulators of glial cell functions in health and disease, it is unknown whether any member of the GDNF subfamily may have functions in normal or pathological glial cell performances. To begin to address this issue, we have studied expression and putative functions of GDNF, NTN, PSP, and their receptors in two cell lines representing models for oligodendrocyte progenitor cells (OLI-neu) and immature oligodendrocytes (OLN-93), respectively. RT-PCR analysis revealed expression of all three growth factor mRNAs in OLI-neu and OLN-93 cells. Expression was weak in OLI-neu cells, while both NTN and PSP mRNAs were strongly expressed in OLN-93 cells. Furthermore, OLI-neu and OLN-93 cells expressed transcripts encoding the GDNF receptors Ret and GFRalpha-1. The two splice variants for GFRalpha-2 were exclusively synthesized in OLI-neu cells. Similarly, primary O-2A progenitor cells and enriched mature oligodendrocytes expressed Ret, GFRalpha-1 and GFRalpha-2 mRNAs. Both GDNF and NTN stimulated DNA synthesis monitored by BrdU incorporation of OLI-neu cells in a dose-dependent fashion. Co-administration of TGF-beta significantly reduced this effect. Similarly, PDGF co-applied with GDNF or NTN down-regulated proliferation in OLI-neu cells. In contrast, OLN-93 cells did not respond to GDNF or NTN with increased incorporation of BrdU. Expression of GDNF, NTN, and their receptors and distinct effects in two model cell lines of oligodendrocyte development suggest that functions of members of the GDNF family and their receptors may not be restricted to neurons and may be implicated in oligodendrocyte development.