Abstract
Zebrafish CNS axons regenerate robustly following injury; it is thought that CNS oligodendrocytes contribute to this response by expressing growth-promoting molecules. We characterized the mpz gene, which encodes myelin protein zero and is up-regulated in oligodendroglia following axonal injury. The 2.5-kb mpz mRNA is expressed from a single TATA box promoter. Four independent Tg(mpz:egfp) transgenic zebrafish lines, in which GFP was expressed under the mpz promoter and 10 kb of genomic 5'-flanking sequence, showed transgene expression in CNS oligodendrocytes from larval development through adulthood. Following optic nerve crush injury, the mpz:egfp transgene was strongly up-regulated in oligodendrocytes along the regenerating retinotectal projection, mirroring up-regulation of endogenous mpz mRNA. GFP-expressing oligodendroglia were significantly more abundant in the regenerating optic pathway, resulting from both transgene induction in oligodendroglial precursors and the birth of new cells. Up-regulation of the mpz:egfp transgene was not dependent on axonal regeneration, suggesting that the primary signal may be axonal loss, debris, or microglial infiltration. Deletion experiments indicated that an oligodendroglial enhancer located in the region from -6 to -10 kb with respect to the mpz transcriptional start site is dissociable from the cis-regulatory element mediating the mpz transcriptional response to axonal injury, which is located between -1 and -4 kb. These data show that different mechanisms regulate expression of zebrafish mpz in myelinating oligodendrocytes and its induction following axonal injury. The underlying molecular events could potentially be exploited to enhance axonal repair following mammalian CNS injury. The transgenic lines and cis-regulatory constructs reported here will facilitate identification of the relevant signaling pathways.
Highlights
Zebrafish CNS oligodendrocytes up-regulate axon growth-promoting genes following axonal injury
Deletion experiments indicated that an oligodendroglial enhancer located in the region from ؊6 to ؊10 kb with respect to the mpz transcriptional start site is dissociable from the cis-regulatory element mediating the mpz transcriptional response to axonal injury, which is located between ؊1 and ؊4 kb
By comparing the responses of different mpz:egfp transgene constructs to axonal injury in stable transgenic zebrafish, we show that the enhancer element responsible for up-regulation of mpz during this response is located within the region Ϫ1 to Ϫ4 kb with respect to the transcriptional start site, whereas a separate enhancer located between Ϫ6 and Ϫ10 kb is necessary for basal transcription of mpz in developing and mature oligodendrocytes
Summary
Zebrafish CNS oligodendrocytes up-regulate axon growth-promoting genes following axonal injury. Deletion experiments indicated that an oligodendroglial enhancer located in the region from ؊6 to ؊10 kb with respect to the mpz transcriptional start site is dissociable from the cis-regulatory element mediating the mpz transcriptional response to axonal injury, which is located between ؊1 and ؊4 kb These data show that different mechanisms regulate expression of zebrafish mpz in myelinating oligodendrocytes and its induction following axonal injury. By comparing the responses of different mpz:egfp transgene constructs to axonal injury in stable transgenic zebrafish, we show that the enhancer element responsible for up-regulation of mpz during this response is located within the region Ϫ1 to Ϫ4 kb with respect to the transcriptional start site, whereas a separate enhancer located between Ϫ6 and Ϫ10 kb is necessary for basal transcription of mpz in developing and mature oligodendrocytes These data suggest that the signaling pathways responsible for mpz expression during myelination and maintenance of CNS white matter are separable from those responding to axonal damage. The panel of transgenic animals we report here will be useful for further studies on myelination, oligodendroglial differentiation, and the role of oligodendrocytes in axonal regeneration
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