The zebrafish cationic amino acid transporter/glycoprotein-associated family: sequence and spatiotemporal distribution during development of the transport system b0,+ (slc3a1/slc7a9).

System b0,+ absorbs lysine, arginine, ornithine, and cystine, as well as some (large) neutral amino acids in the mammalian kidney and intestine. It is a heteromeric amino acid transporter made of the heavy subunit SLC3A1/rBAT and the light subunit SLC7A9/b0,+AT. Mutations in these two genes can cause cystinuria in mammals. To extend information on this transport system to teleost fish, we focused on the slc3a1 and slc7a9 genes by performing comparative and phylogenetic sequence analysis, investigating gene conservation during evolution (synteny), and defining early expression patterns during zebrafish (Danio rerio) development. Notably, we found that slc3a1 and slc7a9 are non-duplicated in the zebrafish genome. Whole-mount in situ hybridization detected co-localized expression of slc3a1 and slc7a9 in pronephric ducts at 24 h post-fertilization and in the proximal convoluted tubule at 3 days post-fertilization (dpf). Notably, both the genes showed co-localized expression in epithelial cells in the gut primordium at 3 dpf and in the intestine at 5 dpf (onset of exogenous feeding). Taken together, these results highlight the value of slc3a1 and slc7a9 as markers of zebrafish kidney and intestine development and show promise for establishing new zebrafish tools that can aid in the rapid screening(s) of substrates. Importantly, such studies will help clarify the complex interplay between the absorption of dibasic amino acids, cystine, and (large) neutral amino acids and the effect(s) of such nutrients on organismal growth.

Sequence analysis and spatiotemporal developmental distribution of the Cat-1-type transporter slc7a1a in zebrafish (Danio rerio).

Cationic amino acid transporter 1 (Cat-1 alias Slc7a1) is a Na+-independent carrier system involved in transport and absorption of the cationic amino acids lysine, arginine, histidine, and ornithine and has also been shown to be indispensable in a large variety of biological processes. Starting from isolated full-length zebrafish (Danio rerio) cDNA for slc7a1a, we performed comparative and phylogenetic sequence analysis, investigated the conservation of the gene during vertebrate evolution, and defined tissue expression during zebrafish development. Whole mount in situ hybridization first detected slc7a1a transcripts in somites, eyes, and brain at 14 h post-fertilization (hpf) with additional expression in the distal nephron at 24 hpf and in branchial arches at 3 days post-fertilization (dpf), with significant increase by 5 dpf. Taken together, the expression analysis of the zebrafish Cat-1 system gene slc7a1a suggests a functional role(s) during the early development of the central nervous system, muscle, gills, and kidney. Graphical abstract.

Zebrafish enhancer trap line showing maternal and neural expression of kctd15a.

Potassium channel tetramerization domain containing proteins (KCTDs), which share a conserved BTB (Bric-a-brac, Tramtrack, Broad complex) domain at their N-terminus, are known to be involved in both developmental and neural processes. However, the developmental expression patterns and functional roles of most vertebrate KCTDs remain unknown. Using enhancer-trapping technology, we have identified a transgenic zebrafish line (ub49) where the vector insertion is in close proximity to kctd15a, and where transgenic marker (eGFP) expression closely reflects endogenous kctd15a expression. Both ub49 and kctd15a show strong maternal expression that suggests a functional role during epiboly and gastrulation. At later developmental stages, expression of eGFP in ub49 also shares the same spatiotemporal features as kctd15a in several neural tissues, including cranial placode precursors, retina, and different areas of the developing brain. In the retina, we observed eGFP labeling of the inner nuclear layer (INL), including a heterogenous population of amacrine cells, and both laminae of the inner plexiform layer (IPL). This expression pattern suggests that Kctd15a proteins have several context-dependent functional roles in both developmental and neural processes. The enhancer trap line, which is the first transgenic reporter of Kctd gene expression in vertebrates, also provides a novel tool to study kctd15a function in vivo.

Distinct expression of two foxg1 paralogues in zebrafish.

The forkhead proteins (Fox) act as transcription factors in many biological processes in a wide range of species. One member of this superfamily, Foxg1, has essential roles in the development of eyes, telencephalon, ears and olfactory system. Zebrafish foxg1 has been reported to have similar roles as the mouse orthologue Foxg1. However, no data has been reported about possible zebrafish foxg1 paralogues. In this study we identified one zebrafish foxg1 paralogue by enhancer trapping, which we designate foxg1b. A more diverged paralogue, foxg1c, was identified by homology searches. Sequence comparisons indicate that both foxg1b and foxg1c are less related to mouse than the previously characterized foxg1. We report that foxg1b is expressed in a regionally restricted pattern within the developing eye, mainly in the dorsal-nasal retina, which is similar to the retinal expression of mouse Foxg1. By contrast, foxg1c is only expressed transiently in the eyes and forebrain between 14 and 20h post-fertilization, while expression was detected exclusively in the developing inner ear at later stages. Our results suggest that foxg1b and foxg1c have undergone expression pattern divergence during evolution that has resulted in functional specialization.

Labelling and targeted ablation of specific bipolar cell types in the zebrafish retina.

BACKGROUND: Development of a functional retina depends on regulated differentiation of several types of neurons and generation of a highly complex network between the different types of neurons. In addition, each type of retinal neuron includes several distinct morphological types. Very little is known about the mechanisms responsible for generating this diversity of retinal neurons, which may also display specific patterns of regional distribution. RESULTS: In a screen in zebrafish, using a trapping vector carrying an engineered yeast Gal4 transcription activator and a UAS:eGFP reporter cassette, we have identified two transgenic lines of zebrafish co-expressing eGFP and Gal4 in specific subsets of retinal bipolar cells. The eGFP-labelling facilitated analysis of axon terminals within the inner plexiform layer of the adult retina and showed that the fluorescent bipolar cells correspond to previously defined morphological types. Strong regional restriction of eGFP-positive bipolar cells to the central part of the retina surrounding the optic nerve was observed in adult zebrafish. Furthermore, we achieved specific ablation of the labelled bipolar cells in 5 days old larvae, using a bacterial nitroreductase gene under Gal4-UAS control in combination with the prodrug metronidazole. Following prodrug treatment, nitroreductase expressing bipolar cells were efficiently ablated without affecting surrounding retina architecture, and recovery occurred within a few days due to increased generation of new bipolar cells. CONCLUSION: This report shows that enhancer trapping can be applied to label distinct morphological types of bipolar cells in the zebrafish retina. The genetic labelling of these cells yielded co-expression of a modified Gal4 transcription activator and the fluorescent marker eGFP. Our work also demonstrates the potential utility of the Gal4-UAS system for induction of other transgenes, including a bacterial nitroreductase fusion gene, which can facilitate analysis of bipolar cell differentiation and how the retina recovers from specific ablation of these cells.

Treatment with small interfering RNA affects the microRNA pathway and causes unspecific defects in zebrafish embryos.

MicroRNAs (miRNAs) are generated from primary transcripts through sequential processing by two RNase III enzymes, Drosha and Dicer, in association with other proteins. This maturation is essential for their function as post-transcriptional regulators. Notably, Dicer is also a component of RNA-induced silencing complexes, which incorporate either miRNA or small interfering RNA (siRNA) as guides to target specific mRNAs. In zebrafish, processed miRNAs belonging to the miR-430 family have previously been shown to promote deadenylation and degradation of maternal mRNAs during early embryogenesis. We show that injection of one-cell-stage zebrafish embryos with siRNA causes a significant reduction in the endogenous levels of processed miR-430 and other miRNAs, leading to unspecific developmental defects. Coinjection of siRNA with preprocessed miR-430 efficiently rescued development. This indicates that the abnormalities generally observed in siRNA-treated zebrafish embryos could be due to inhibition of miR-430 processing and/or activity. Our results also suggest that the miRNA pathway in mammals, under some experimental or therapeutic conditions, may be affected by siRNA.

Isolation and characterization of two teleost melanopsin genes and their differential expression within the inner retina and brain.

Melanopsin is a newly discovered photopigment that is believed to be involved in the regulation of circadian rhythms in tetrapods. Here we describe the characterization of the first two teleost melanopsins (opn4a and opn4b) isolated from Atlantic cod (Gadus morhua). These two teleost genes belong to a subgroup of melanopsins that also include members from Xenopus, chicken, and Takifugu. In situ hybridization revealed that opn4a and opn4b are differentially expressed within the retina and brain. In the larval and adult retina, both melanopsins are expressed in a subset of cells in the inner retina, resembling amacrine and ganglion cells. In addition, opn4a is expressed in the horizontal cells, indicating a separate task for this gene. In the brain, the two melanopsins are separately expressed in two major retinal and extraretinal photosensitive integration centers, namely, the suprachiasmatic nucleus (opn4a) and the habenula (opn4b). The expression of opn4a in the suprachiasmatic nucleus in cod is similar to the melanopsin expression found in Xenopus. This suggests a conserved role for this opsin and an involvement in mediation of nonvisual photoreceptive tasks, such as entraining circadian rhythms and/or hypophysiotrophic systems. The differential expression of opn4b in the habenula suggests that this gene plays a role similar to that of opn4a, in that it is also situated in an area that integrates photic inputs from the pineal as well as other brain regions. Thus, the habenula may be an additional region that mediates photic cues in teleosts.

Zebrafish transgenic lines co-expressing a hybrid Gal4 activator and eGFP in tissue-restricted patterns.

We have used a Tol2-derived trapping vector, carrying a hybrid Gal4 gene and a UAS:eGFP reporter cassette, to identify 16 transgenic zebrafish lines expressing the fluorescent marker eGFP in tissue-restricted patterns during development. Most lines show co-expression of eGFP and a hybrid Gal4 transcription activator containing a truncated VP16 domain that facilitate induction of other UAS-transgenes (UAS:RFP). Notably, many of the transgenic lines are expressed in particular areas of the central nervous system, such as the retina. We mapped the genomic positions of most of the activated insertions, and for three retina-specific lines we also demonstrate that eGFP reports the expression of particular endogenous genes. One of the identified zebrafish genes shows expression in ventral retina, and encodes a protein containing a repulsive guidance molecule (RGM) domain, suggesting a role in axonal guidance during optic nerve formation. Among the lines labeling other tissues, three show early co-expression of eGFP and Gal4-VP16 in blood vessels, erythrocytes and other hematopoietic cells. Interestingly, the activated insertion in the erythrocyte line was mapped to a site near the globin cluster on chromosome 3. All the reported lines co-expressing eGFP and the hybrid Gal4 activator may have potential as genetic tools to study developmental processes.

Exploring microRNA functions in zebrafish.

The microRNA (miRNA) pathway and the phenomenon of RNA interference (RNAi) have similar mechanisms and depend partly on the same cellular factors. Humans may have more than 1000 different miRNAs, which are essential regulators of gene expression in many biological processes. RNAi-based techniques have become important tools in biomedical research and have great potential for use in disease therapy. Zebrafish (Danio rerio) provide several advantages for the study of miRNA functions. However, reliable RNAi-based gene silencing techniques have not been established for this important vertebrate model. In this article, we describe the highly efficient in vivo assays used to study miRNA functions in zebrafish and how these experimental approaches have uncovered new regulatory mechanisms in vertebrates. This research has also provided information that explains why RNAi techniques have been unsuccessful in zebrafish.

Inhibition of the microRNA pathway in zebrafish by siRNA.

The microRNA (miRNA) pathway and the phenomenon of RNA interference (RNAi), which have both been shown to involve targeting of mRNAs by small RNA molecules, are interconnected and depend partly on the same cellular machinery. RNAi in vertebrates was first reported in zebrafish (Danio rerio) 10 years ago. However, reliable RNAi-based gene silencing techniques, based on injection of small interfering RNAs (siRNAs) into zygotes, have not been established for this important vertebrate model because of unspecific developmental defects. We have recently shown that these side effects can be attributed to inhibition of the miRNA pathway by siRNAs at early embryonic stages. This review highlights these findings and the function of microRNAs in zebrafish development.

Autoregulatory binding sites in the zebrafish six3a promoter region define a new recognition sequence for Six3 proteins.

The homeodomain (HD) transcription factor Six3, which is a member of the Six/Sine oculis family, is essential for development of the eyes and forebrain in vertebrates. It has recently been claimed that the HDs of Six3 and other members of the Six family have a common recognition sequence, TGATAC. However, a different recognition sequence including the typical TAAT core motif, which has not yet been fully defined, has also been proposed for the Six3 HD in mice. Our study of the zebrafish orthologue six3a, which has an identical HD, shows that it binds in vitro to multiple TAAT-containing sites within its promoter region. Comparison of the different binding affinities for these sequences identifies three high-affinity sites with a common TAATGTC motif. Notably, this new recognition sequence, which is supported by our analysis of the influence of single-nucleotide substitutions on the DNA-binding affinity, is distinct from all of the DNA-binding specificities previously described in surveys of HDs. In addition, our comparison of Six3a HD binding to the novel TAATGTC motif and the common recognition sequence of Six family HDs (TGATAC) shows very similar affinities, suggesting two distinct DNA-binding modes. Transient reporter assays of the six3a promoter in zebrafish embryos also indicate that the three high-affinity sites are involved in autoregulation. In support of this, chromatin immunoprecipitation experiments show enrichment of Six3a binding to a six3a promoter fragment containing two clustered high-affinity sites. These findings provide strong evidence that the TAATGTC motif is an important target sequence for vertebrate Six3 proteins in vivo.

Zebrafish kidney marrow contains ABCG2-dependent side population cells exhibiting hematopoietic stem cell properties.

Zebrafish (Danio rerio) has emerged as a powerful genetic model for the study of vertebrate hematopoiesis. However, methods for detection and isolation of hematopoietic stem cells (HSCs) have not yet been reported. In mammals, the combination of Hoechst 33342 staining with flow cytometry can be used for separation of a bone marrow side population (SP), which is highly enriched for HSCs. We applied a similar procedure to hematopoietic kidney marrow cells from adult zebrafish, and identified a segregated cohort of SP cells, which demonstrate a set of features typical of stem cells. SP cells show extremely low scatter characteristics, and are small in size with a minimum of cytoplasm. Treatment of zebrafish kidney marrow cells with reserpine or fumitremorgin C, which inhibit the ABCG2 transporter responsible for Hoechst 33342 efflux, caused a clear reduction in the number of SP cells. Consistent with the quiescent state of HSCs, the SP cells are strongly resistant to the myelosuppressive agent 5-fluorouracil. In addition, SP cells specifically demonstrate higher expression of genes known to be markers of HSCs of mammals. Hence, our results show that the SP phenotype is conserved between mammals and teleosts, and the properties of the zebrafish SP cells indicate a significant enrichment for HSCs. These rapid flow cytometric methods for purification of HSCs from zebrafish may greatly facilitate genetic analysis of stem cells using the advantages of this vertebrate model.

RNAi and microRNAs: from animal models to disease therapy.

The discovery of the phenomenon of RNA interference (RNAi) and its existence in mammals quickly suggested a great potential for use in disease therapy. Rapid advances have been made in the development of RNAi-based technologies and promising results have been obtained from studies on mammalian cell culture systems and animal in vivo models. However, the progress in our understanding of the RNAi pathway and the related function of microRNAs (miRNAs) have also raised concerns regarding various types of side effects that may restrict the use of this technology in human therapy. At the same time, our new knowledge about the functional roles of miRNAs as regulators of many cellular processes, including proliferation, differentiation, development, and neuronal function, is revolutionizing cell biology and will have a major impact on medical research. In this review, we focus on the discoveries that have been made in animal models and how this insight can be translated to human medicine and disease therapy. In this connection, we will particularly discuss the challenges associated with the efforts to develop RNAi-based therapeutics.

Retinal expression of zebrafish six3.1 and its regulation by Pax6.

Homologues of the homeobox genes sine oculis (so) and eyeless (ey) are important regulators of eye development in both vertebrates and invertebrates. A Drosophila paralogue of so, optix, is an orthologue of the vertebrate Six3 gene family. Our analysis of zebrafish six3.1 demonstrated retinal expression in two separate cell layers and the ciliary marginal zone. This pattern is consistent with the observations of Six3 in other vertebrates and indicates functional conservation. We studied the 5(') flanking region of six3.1 and showed that separate enhancing elements are required for expression at different stages of eye development. This analysis also revealed specific binding of zebrafish Pax6.1 protein to an element required for six3.1 expression in ganglion cells. Furthermore, an enhancement of six3.1 transcription by Pax6.1 was observed by co-injection experiments. These results provide evidence for a direct regulatory interaction between vertebrate Pax6 and Six3 genes in eye development.