RNA interference: mechanisms and applications.

RNA interference (RNAi) is a phenomenon induced by double-stranded RNA (dsRNA) in which gene expression is inhibited through specific degradation of mRNA. The mechanism involves conversion of dsRNA into short RNAs that direct ribonucleases to homologous mRNA targets. This process is related to normal defence against viruses and mobilisation of transposons. Treatment with dsRNA has become an important method for analysing gene functions in invertebrate organisms. RNAi has also been demonstrated in several vertebrate species but with lower efficiency. Development of procedures for in vivo production of dsRNA may provide efficient tools for tissue- and stage-specific gene targeting.

Molecular cloning and embryonic expression of Xenopus Six homeobox genes.

Six genes are vertebrate homologues of the homeobox-containing gene sine oculis, which plays an essential role in controlling Drosophila compound eye development. Here we report the identification and expression patterns of all three subfamilies of Xenopus Six genes. Two Six2 subfamily genes (Six1, Six2) showed very similar expression patterns in cranial ganglia, otic placodes and the eyes. Non-neural expression of Six1 and Six2 was observed with mesodermal head mesenchyme, somites and their derivatives, the muscle anlagen of the embryonic trunk. In addition, Six2 expression was also found with mesenchyme associated with the developing stomach and pronephros. Expression of Six3 subfamily genes (Six3.1, Six3.2, Six6.1, and Six6.2) was restricted to the developing head, where expression was especially observed in derivatives of the forebrain (eyes, optic stalks, the hypothalamus and pituitary gland). Interestingly, expression of all Six3 subfamily members but Six6.2 was also found with the pineal gland primordium and the tegmentum. Expression of Six4 subfamily genes (Six4.1, Six4.2) was present in the developing visceral arches, placodal derivatives (otic vesicle, olfactory system), head mesenchyme and the eye. The observed dynamic expression patterns are largely conserved between lower and higher vertebrates and imply important roles of Six family genes not only in eye formation and myogenesis, but also in the development of the gut, the kidney and of placode-derived structures.

Molecular cloning and characterization of five opsin genes from the marine flatfish Atlantic halibut (Hippoglossus hippoglossus).

Most molecular studies on the visual system in fish have been performed on freshwater teleosts such as goldfish and zebrafish where cones and rods appear simultaneously. Many marine fishes have long larval phase in the upper pelagic zone before transformation into a juvenile and a benthic life style. The retina at the larval stages consists of only single cone cells; later during metamorphosis double cones and rods develop. The flatfish Atlantic halibut (Hippoglossus hippoglossus) is a typical example of a marine species with such a two-step retina development. In this study, we have cloned five different opsins from Atlantic halibut larvae and juvenile retinas. Sequence comparisons with other opsins and phylogenetic analysis show that the five genes belong to the opsins of long-wavelength sensitive (L); middle-wavelength sensitive, M(Cone) and M(Rod); and short-wavelength sensitive, S(Blue) and S(Ultraviolet), respectively. In situ hybridization analysis reveals expression in double cone (L and M(Cone)), single cone (S(Blue) and S(Ultraviolet)), and rod (M(Rod)) types of photoreceptor cells in juvenile halibut retina. The visual system in Atlantic halibut seems therefore to have all four types of cone photoreceptors in addition to rod photoreceptors. This work shows for the first time molecular isolation of a complete set of retinal visual pigment genes from a marine teleost and describes the first cloning of an ultraviolet-sensitive opsin type from a marine teleost.

Identification and distribution of nitric oxide synthase in the brain of adult zebrafish.

Nitric oxide (NO) is proposed to be involved in developmental and plastic processes. We investigated the presence and distribution of nitric oxide synthase (NOS) in the zebrafish (Danio rerio) using molecular and histochemical techniques. A partial gene sequence corresponding to the neuronal NOS isoform (nNOS) was identified, and in situ hybridization revealed cellular nNOS mRNA expression throughout the brain of adult zebrafish, distributed in distinct central nuclei and in proliferation zones. NOS immunoreactivity and nicotinamide adenine dinucleotide phosphate diaphorase activity partly coincided with the nNOS mRNA expression, however was present also in additional neuronal and non-neuronal cell types. The results indicate the occurrence of different NOS isoforms in the adult brain, of which nNOS may participate in neurotransmission, and in mechanisms related to the continuous growth and neuronal plasticity of the teleost brain.

Characterisation of the promoter region of the zebrafish six7 gene.

The Drosophila homeobox gene sine oculis and its murine homologue Six3 have both been shown to have regulatory functions in eye and brain development. In zebrafish, three Six3-related genes with conserved expression during early eye and head formation have been identified. One of these, six7, is first expressed at the gastrula stage in the involuting axial mesoderm, and later in the overlying neuroectoderm from which the forebrain and optic primordium develop. To elucidate the mechanisms regulating six7 expression, we isolated a 2.7-kb fragment of the 5'-flanking region. Three sequentially deleted fragments of this upstream region were used to produce GFP reporter constructs for analysis of tissue-specific expression in zebrafish embryos. The results show that a 625-bp upstream fragment is sufficient to direct strong expression of the reporter during gastrulation and early neurulation. The proximal part of the promoter contains binding sites for various constitutive transcription factors and an additional upstream element that was shown to be critical in directing expression to the anterior region of the zebrafish brain.

A novel paired domain DNA recognition motif can mediate Pax2 repression of gene transcription.

The paired domain (PD) is an evolutionarily conserved DNA-binding domain encoded by the Pax gene family of developmental regulators. The Pax proteins are transcription factors and are involved in a variety of processes such as brain development, patterning of the central nervous system (CNS), and B-cell development. In this report we demonstrate that the zebrafish Pax2 PD can interact with a novel type of DNA sequences in vitro, the triple-A motif, consisting of a heptameric nucleotide sequence G/CAAACA/TC with an invariant core of three adjacent adenosines. This recognition sequence was found to be conserved in known natural Pax5 repressor elements involved in controlling the expression of the p53 and J-chain genes. By identifying similar high affinity binding sites in potential target genes of the Pax2 protein, including the pax2 gene itself, we obtained further evidence that the triple-A sites are biologically significant. The putative natural target sites also provide a basis for defining an extended consensus recognition sequence. In addition, we observed in transformation assays a direct correlation between Pax2 repressor activity and the presence of triple-A sites. The results suggest that a transcriptional regulatory function of Pax proteins can be modulated by PD binding to different categories of target sequences.

Double-stranded RNA induces specific developmental defects in zebrafish embryos.

Treatment with double-stranded RNA (dsRNA) has been shown to interfere with the function of specific genes in various invertebrate species. However, it has not yet been reported that this technique can be applied to vertebrates as well. We have investigated whether dsRNA treatment will inhibit gene function in zebrafish embryos. By microinjecting dsRNA corresponding to three genetically characterised genes we produced embryonic defects that were similar to the known mutant phenotypes of these loci. The efficiency of inducing specific defects (20-30%) was about 10-fold higher than in experiments with antisense RNA. We also observed that the level of the endogenous mRNA in zebrafish embryos was substantially reduced throughout the embryo following dsRNA injection. However, the interference of gene function showed a strong dependence on the amount of dsRNA. These findings suggest that dsRNA-mediated interference will become an important tool for analysing the functional roles of genes in zebrafish and other vertebrates.

Six class homeobox genes in drosophila belong to three distinct families and are involved in head development.

The vertebrate Six genes are homologues of the Drosophila homeobox gene sine oculis (so), which is essential for development of the entire visual system. Here we describe two new Six genes in Drosophila, D-Six3 and D-Six4, which encode proteins with strongest similarity to vertebrate Six3 and Six4, respectively. In addition, we report the partial sequences of 12 Six gene homologues from several lower vertebrates and show that the class of Six proteins can be subdivided into three major families, each including one Drosophila member. Similar to so, both D-Six3 and D-Six4 are initially expressed at the blastoderm stage in narrow regions of the prospective head and during later stages in specific groups of head midline neurectodermal cells. D-Six3 may also be essential for development of the clypeolabrum and several head sensory organs. Thus, the major function of the ancestral Six gene probably involved specification of neural structures in the cephalic region.

Three structurally and functionally conserved Hlx genes in zebrafish.

For the Hlx class, which includes homeodomains (HD) that are similar to Drosophila H2.0, few members have been identified in vertebrates. In this report, we describe three zebrafish genes, hlx1, hlx2 and hlx3, related to the murine Dbx genes. The proteins encoded by hlx1 and hlx2 have about the same sequence identity to Dbx1 (approximately 60%), suggesting that they derive from a duplication in the fish lineage. This is supported by similarities in the embryonic expression patterns and promoter sequence conservation. The zebrafish Hlx3 protein is related to murine Dbx2, but it is apparently too diverged to be orthologous. Our phylogenetic analysis of all the known HD sequences of the Hlx class also shows that it can be divided into at least two distinct families. All the Dbx-like genes have similar expression in the embryonic nervous system. However, the initial expression patterns of the zebrafish hlx genes are quite unique, suggesting that some functional divergence has occurred between fish and mammals.

A zebrafish Six4 homologue with early expression in head mesoderm.

Similar to the Drosophila homeobox gene sine oculis, several of the vertebrate homologues (Six genes) are expressed during eye formation and differentiation. In addition, most of these vertebrate genes show expression in mesodermal derivatives in adults and/or earlier stages of development. We have identified a zebrafish (Danio rerio) gene, six8, which shows the greatest similarity to murine Six4. The deduced proteins of these two genes have an overall sequence identity of 41%, while the homeodomains and Six domains are highly conserved, 90% and 81%, respectively. The spatiotemporal expression pattern of six8 was analyzed by RT-PCR and in situ hybridization. Transcripts were detected in a wide range of embryonic stages and in adults. Notably, the strongest expression was observed in head mesoderm of late gastrula and early neurula stages.

Transient expression of a novel Six3-related zebrafish gene during gastrulation and eye formation.

Both the Drosophila homeobox gene sine oculis and its murine homologue Six3 have regulatory functions in eye development. In zebrafish, in addition to two previously reported homologues of murine Six3, we have identified a related gene (six7). Although the deduced Six7 protein shares less than 68% sequence identity with the other known zebrafish Six3-like proteins, the embryonic expression patterns have highly conserved features. The six7 transcripts are first detected in involuting axial mesendoderm and, subsequently, in the overlying neurectoderm from which the forebrain and optic primordia develop. Similar to the two other zebrafish Six3 homologues, the expression boundaries of six7 correspond quite closely with the edges of the optic vesicles. Hence, the partially overlapping expression domains of these three six genes probably contribute to anteroposterior specification and in defining the eye primordia.

Expression of two zebrafish homologues of the murine Six3 gene demarcates the initial eye primordia.

The murine homeobox gene Six3 and its Drosophila homologue sine oculis both have regulatory functions in eye development. We report the isolation and characterization of two zebrafish genes, six3 and six6, that are closely related to the murine Six3 gene. Zebrafish six3 may be the structural orthologue, while the six6 gene is more similar with respect to embryonic expression. Transcripts of both zebrafish six genes are first detected in involuting axial mesendoderm and, subsequently, in the overlying anterior neural plate from which the optic vesicles and the forebrain will develop. Direct correspondence between six3/six6 expression boundaries and the optic vesicles indicate essential roles in defining the eye primordia. During later stages only the six6 gene displays similar features of expression in the eyes and rostral brain as reported previously for murine Six3.

The zebrafish Pax3 and Pax7 homologues are highly conserved, encode multiple isoforms and show dynamic segment-like expression in the developing brain.

This study describes the isolation and characterization of zebrafish homologues of the mammalian Pax3 and Pax7 genes. The proteins encoded by both zebrafish genes are highly conserved (>83%) relative to the known mammalian sequences. Also the neural expression patterns during embryogenesis are very similar to the murine homologues. However, observed differences in neural crest and mesodermal expression relative to mammals could reflect some functional divergence in the development of these tissues. For the zebrafish Pax7 protein we report the first full-length amino acid sequences in vertebrates and show the existence of three additional isoforms which have truncations in the homeodomain and/or the C-terminal region. These novel variants provide evidence for additional isoform diversity of vertebrate Pax proteins.

A vasa-like gene in zebrafish identifies putative primordial germ cells.

The vasa gene is essential for germline formation in Drosophila. Vasa-related genes have been isolated from several organisms including nematode, frog and mammals. In order to gain insight into the early events in vertebrate germline development, zebrafish was chosen as a model. Two zebrafish vasa-related genes were isolated, pl10a and vlg. The pl10a gene was shown to be widely expressed during embryogenesis. The vlg gene and vasa belong to the same subfamily of RNA helicase encoding genes. Putative maternal vlg transcripts were detected shortly after fertilization and from the blastula stage onwards, expression was restricted to migratory cells most likely to be primordial germ cells.

Solid phase technology improves coupled gel shift/footprinting analysis.

For the analysis of protein-DNA interactions by coupled gel-shift/footprinting, DNA fragments need to be extracted from polyacrylamide gels and subsequently separated on high resolution gels. Due to impurities in the extracted DNA, single nucleotide resolution is frequently not achieved. We now describe an improved experimental strategy that employs transient coupling of DNA fragments to a solid support in order to extract DNA of high purity quantitatively, rapidly and reliably. As an example, we describe the application of our protocol to the 'in-gel footprinting' by copper phenanthroline. The method should also find application to the chemical interference assays.

Embryonic expression and DNA-binding properties of zebrafish pax-6.

Zebrafish pax-6 (pax[zf-a]) and its murine homologue are structurally and functionally related to the Drosophila paired box gene eyeless, a master control gene for eye development. This report details the zebrafish pax-6 embryonic expression pattern both at the mRNA and protein level. Transcripts are first detected in the presumptive forebrain and hindbrain regions of the neural plate. After formation of the neural keel, Pax-6 protein accumulates within the same two domains. Expression is also observed in the optic vesicles and lens placodes, confirming that the Pax-6 protein is expressed in those areas of the eye where it is assumed to control differentiation. The relative DNA-binding affinity of the zebrafish Pax-6 protein to different categories of Pax recognition sites is shared with the murine homologue.

A novel vertebrate svp-related nuclear receptor is expressed as a step gradient in developing rhombomeres and is affected by retinoic acid.

The protein encoded by the zebrafish gene svp[40] belongs to a distinct group within the steroid hormone receptor superfamily that includes Drosophila seven-up and several vertebrate orphan receptors. Svp[40] shares a particularly high degree of amino acid sequence identity (approximately 86%) with the mammalian transcription factors ARP-1 and COUP. The gene is expressed in specific regional and segmental domains within the developing brain. Correspondence between this expression pattern and early sites of neuronal differentiation and axonogenesis in the rostral brain may reflect an involvement in neural patterning. During the early embryonic stages when hindbrain rhombomeres are formed, a segmental expression pattern is established as a step gradient. The single steps of this gradient coincide directly with the four anteriormost segments suggesting a role in controlling rhombomere-specific expression of genes contributing to cell differentiation in the hindbrain. Since COUP/ARP-1 and retinoic acid receptors (RARs/RXRs) are known to have similar DNA-binding specificities, different levels of Svp[40] might modulate retinoid signaling through competition for binding to specific RAREs in the promoters of target genes. Treatment of zebrafish embryos with retinoic acid affects the svp[40] step gradient and causes an elimination of a regional expression domain in the retina. These observations are consistent with svp[40] being an integral part of the retinoid signaling network during hindbrain and eye development.

Regulatory gene expression boundaries demarcate sites of neuronal differentiation in the embryonic zebrafish forebrain.

During development of the zebrafish forebrain, a simple scaffold of axon pathways is pioneered by a small number of neurons. We show that boundaries of expression domains of members of the eph, forkhead, pax, and wnt gene families correlate with the positions at which these neurons differentiate and extend axons. Analysis of genetically or experimentally altered forebrains indicates that if a boundary is maintained, there is appropriate neural differentiation with respect to the boundary. Conversely, in the absence of a boundary, there is concomitant disruption of neural patterning. We also show that a strip of cells within the dorsal diencephalon shares features with ventral midline cells. This strip of cells fails to develop in mutant fish in which specification of the ventral CNS is disrupted, suggesting that its development may be regulated by the same inductive pathways that pattern the ventral midline.

Expression of the zebrafish gene hlx-1 in the prechordal plate and during CNS development.

The zebrafish hlx-1 gene belongs to the H2.0 subfamily of homeobox genes and is closely related to the mouse Dbx gene with respect to both homeodomain homology (96.7%) and neural expression during embryogenesis. Analysis of hlx-1 expression by in situ hybridization reveals several particularly interesting features. In late gastrula embryos, hlx-1 transcripts are detected within a circular area in the region of the presumptive rostral brain. Subsequently, the expression domain becomes restricted to the hypoblast and undergoes dynamic changes involving conversion into a longitudinal stripe which elongates and retracts following a temporal sequence. The site of transient hlx-1 expression along the ventral midline of the rostral neurectoderm, which in part corresponds to the prechordal plate, suggests a role in the determination of head mesoderm as well as in patterning of the rostral brain. As the midline stripe gradually disappears, the hlx-1 gene becomes regionally expressed within the diencephalon and at a specific dorsoventral level along the hindbrain and spinal cord. In the hindbrain, expression is initiated in dorsoventrally restricted transversal stripes which correlate with the segmental pattern of rhombomeres. The stripes fuse into bilateral columns that are later converted to two series of paired transversal stripes at the rhombomere borders. This pattern is consistent with the proposed subdivision of hindbrain segments into rhombomere centers separated by border regions.