Svanhild Nornes

Developmental control of Presenilin1 expression, endoproteolysis, and interaction in zebrafish embryos

Dominant mutations in presenilin1 (PS1) and presenilin2 (PS2) are a major cause of early-onset Alzheimers disease. In this report we analyze the expression of the zebrafish presenilin1 (Psen1) and presenilin2 (Psen2) proteins during embryogenesis. We demonstrate that Psen1 and Psen2 holoproteins are relatively abundant in zebrafish embryos and are proteolytically processed. Psen1 is maternally expressed, whereas Psen2 is expressed at later stages during development. The Psen1 C-terminal proteolytic fragment (CTF) is present at varying levels during embryogenesis, indicating the existence of developmental control mechanisms regulating its production. We examine the codependency of Psen1 and Psen2 expression during early embryogenesis. Forced overexpression of psen2 increases expression of Psen2 holoprotein, but not the N-terminal fragment (NTF), indicating that levels of Psen2 NTF are strictly controlled. Overexpression of psen2 did not alter levels of Psen1 holoprotein, CTF, or higher molecular weight complexes. Reduction of Psen1 activity in zebrafish embryos produces similar developmental defects to those seen for loss of PS1 activity in knockout mice. The relevance of these results to previous work on presenilin protein regulation and function are discussed. Our work shows that zebrafish embryos are a valid and valuable system in which to study presenilin interactions, regulation, and function.

Selective neuronal requirement for huntingtin in the developing zebrafish

Huntingtons disease shares a common molecular basis with eight other neurodegenerative diseases, expansion of an existing polyglutamine tract. In each case, this repeat tract occurs within otherwise unrelated proteins. These proteins show widespread and overlapping patterns of expression in the brain and yet the diseases are distinguished by neurodegeneration in a specific subset of neurons that are most sensitive to the mutation. It has therefore been proposed that expansion of the polyglutamine region in these genes may result in perturbation of the normal function of the respective proteins, and that this perturbation in some way contributes to the neuronal specificity of these diseases. The normal functions of these proteins have therefore become a focus for investigation as potential pathogenic pathways. We have used synthetic antisense morpholinos to inhibit the translation of huntingtin mRNA during early zebrafish development and have previously reported the effects of huntingtin reduction on iron transport and homeostasis. Here we report an analysis of the effects of huntingtin loss-of-function on the developing nervous system, observing distinct defects in morphology of neuromasts, olfactory placode and branchial arches. The potential common origins of these defects were explored, revealing impaired formation of the anterior-most region of the neural plate as indicated by reduced pre-placodal and telencephalic gene expression with no effect on mid- or hindbrain formation. These investigations demonstrate a specific ‘rate-limiting’ role for huntingtin in formation of the telencephalon and the pre-placodal region, and differing levels of requirement for huntingtin function in specific nerve cell types.

Independent and cooperative action of Psen2 with Psen1 in zebrafish embryos

Presenilin1 (PSEN1) and presenilin2 (PSEN2) are involved in the processing of type-1 transmembrane proteins including the amyloid precursor protein (APP), Notch and several others. PSEN1 has been shown to be crucial for proteolytic cleavage of Notch in developing animal embryos. Mouse embryos lacking Psen1 function show disturbed neurogenesis and somite formation, resembling Notch pathway mutants. However, loss of Psen2 activity reveals only a minor phenotype. Zebrafish embryos are a valuable tool for analysis of the molecular genetic control of cell differentiation since endogenous gene expression can be modulated in subtle and complex ways to give a phenotypic readout. Using injection of morpholino antisense oligonucleotides to inhibit protein translation in zebrafish embryos, we show that reduced Psen2 activity decreases the number of melanocytes in the trunk but not in the cranial area at 2 days post fertilisation (dpf). Reduced Psen2 activity apparently reduces Notch signalling resulting in perturbed spinal neurogenin1 (neurog1) expression, neurogenesis and trunk and tail neural crest development. Similar effects are seen for reduced Psen1 activity. These results suggest that Psen2 plays a more prominent role in Notch signalling and embryo development in zebrafish than in mammals. Intriguingly, decreased Psen2 activity increases the number of Dorsal Longitudinal Ascending (DoLA) interneurons in the spinal cord while decreased Psen1 activity has no effect. However, the effect on DoLAs of reduced Psen2 can be ameliorated by Psen1 loss. The effects of changes in Psen2 activity on DoLA interneurons and other cells in zebrafish embryos provide bioassays for more detailed dissection of Psen2 function.

Altering presenilin gene activity in zebrafish embryos causes changes in expression of genes with potential involvement in Alzheimer's disease pathogenesis.

Aberrant splicing and point mutations in the human presenilin genes, PSEN1 and PSEN2, have been linked to familial forms of Alzheimers disease. We have previously described that low-level aberrant splicing of exon 8 in zebrafish psen1 transcripts in zebrafish embryos produces potent dominant negative effects that increase psen1 transcription, cause a dramatic hydrocephalus phenotype, decreased pigmentation and other developmental defects. Similar effects are also observed after low-level interference with splicing of exon 8 of psen2. To determine the molecular etiology of these effects, we performed microarray analyses of global gene expression changes. Of the 100 genes that showed greatest dysregulation after either psen1 or psen2 manipulation, 12 genes were common to both treatments. Five of these have known function and showed increased expression: cyclin G1 (ccng1), prosaposin (psap), cathepsin Lb (ctslb), heat shock protein 70kDa (hsp70) and hatching enzyme 1 (he1). We used phylogenetic and conserved synteny analysis to confirm the orthology of zebrafish ccng1 with human CCNG1. We analyzed the expression of zebrafish ccng1 in developing embryos to 24 hours post fertilization (hpf). Decreased ccng1 expression does not rescue the hydrocephalus or pigmentation phenotypes of embryos with aberrant splicing of psen1 exon 8.

Transgenic Zebrafish Recapitulating tbx16 Gene Early Developmental Expression

We describe the creation of a transgenic zebrafish expressing GFP driven by a 7.5 kb promoter region of the tbx16 gene. This promoter segment is sufficient to recapitulate early embryonic expression of endogenous tbx16 in the presomitic mesoderm, the polster and, subsequently, in the hatching gland. Expression of GFP in the transgenic lines later in development diverges to some extent from endogenous tbx16 expression with the serendipitous result that one line expresses GFP specifically in commissural primary ascending (CoPA) interneurons of the developing spinal cord. Using this line we demonstrate that the gene mafba (valentino) is expressed in CoPA interneurons.

Zebrafish aplnra functions in epiboly

BackgroundThe zebrafish, Danio rerio, possesses the paralogous genes aplnra and aplnrb that are duplicates of an ancestral orthologue of the human APLNR gene encoding a G-protein coupled receptor that binds the peptide ligand APELIN and is required for normal cardiovascular function. aplnrb is required for migration of cells contributing to heart development in zebrafish embryos. aplnra is transcribed in a complex pattern during early development but its function in embryogenesis is largely unknown.FindingsBlockage of translation of aplnra mRNA in zebrafish embryos results in retarded or failed epiboly with the blastoderm apparently disconnected from the nuclei of the yolk syncytial layer. Gastrulation is also defective. Failure of correct tail extension is observed with ectopic structures resembling somites positioned dorsal to the spinal cord.Conclusionaplnra, unlike its duplicate aplnrb, is essential for normal epiboly, although this function appears to be independent of signalling activated by zebrafish Apelin. The defects in epiboly caused by loss of aplnra activity appear, at least partially, to be due to a requirement for aplnra activity in the yolk syncytial layer.

Robust homeostasis of Presenilin1 protein levels by transcript regulation

The Presenilin proteins are essential facilitators of numerous developmental and cell signaling pathways. Point mutations in the human PRESENILIN genes (including mutations affecting splicing) have been linked to familial Alzheimers disease. Zebrafish possess orthologues of the human PRESENILIN1 and PRESENILIN2 genes. We previously investigated forced aberrant splicing of zebrafish presenilin1 and discovered that high levels of incorporation into spliced transcripts of the intron cognate with human PRESENILIN1 intron 8 resulted in little or no change in Presenilin1 protein level and no identifiable embryonic phenotype. We now demonstrate that zebrafish embryos maintain relatively stable levels of normal Presenilin1 transcript and protein despite accumulating large amounts of aberrantly spliced presenilin1 transcript. We also show that increasing the levels of Presenilin1 protein decreases normal presenilin1 transcription. These two independent lines of evidence and the fact that blockage of Presenilin1 translation increases presenilin1 transcription support that regulation of presenilin1 transcript levels plays a major role in the homeostasis of Presenilin1 protein levels, presumably via a feedback mechanism that monitors the levels of Presenilin1 protein.