Spatial and temporal expression patterns of chitinase genes in developing zebrafish embryos

Chitinases and chitinase like proteins play an important role in mammalian immunity and functions in early zebrafish development have been suggested. Here we report identification of six zebrafish chitinases and chitinase like proteins (called CHIA.1–6) belonging to the glycoside hydrolase family 18, and determine their spatial and temporal expression at 10 stages of zebrafish development.CHIA.4 is highly maternally expressed and it is expressed 100 fold above any other CHIA gene at zygote through to blastula stage. Later, after the maternal to zygotic transition, CHIA.4 expression decreases to the same level as CHIA.5 and CHIA.6. Subsequently, CHIA.1, CHIA.2, CHIA.3 and CHIA.4, CHIA.5, CHIA.6 each follow distinct paths in terms of expression levels.Until 4 days post fertilization the spatial expression patterns of all six CHIA genes overlap extensively, with expression detected predominantly in vascular, ocular and intestinal tissues. At 5 days post fertilization CHIA.1, CHIA.2 and CHIA.3 are expressed almost exclusively in the stomach, whereas CHIA.4, CHIA.5 and CHIA.6 are also prominently expressed in the liver. These different expression patterns may contribute to the establishment of a basis on which functional analysis in older larvae may be founded.     

The HMGB protein gene family in zebrafish: Evolution and embryonic expression patterns

The High-Mobility Group Box (HMGB) proteins are highly abundant proteins with both nuclear and extracellular roles in key biological processes. In mammals, three family members are present: HMGB1, HMGB2 and HMGB3. We characterized the HMGB family in zebrafish and report a detailed phylogenetic analysis of HMGB proteins. The B1, B2, and B3 subfamilies are present in cartilaginous fish, bony fish, and tetrapods, while jawless fish sequences emerge as basal to the gene family expansion. Two co-orthologs of each mammalian HMGB gene are present in zebrafish. All six zebrafish hmgb genes are maternally expressed, but huge differences in expression levels exist during embryonic development. The hmgb2a/hmgb2b genes are the most highly expressed, while hmgb3b is expressed at the lowest level. Remarkably, hmgb3 genes are not present in fugu, medaka, Tetraodon and stickleback. Our analysis highlights substantial overlaps, but also subtle differences and specificities in the expression patterns of the zebrafish hmgb genes.     

The embryonic expression patterns of zebrafish genes encoding LysM-domains

The function and structure of LysM-domain containing proteins are very diverse. Although some LysM domains are able to bind peptidoglycan or chitin type carbohydrates in bacteria, in fungi and in plants, the function(s) of vertebrate LysM domains and proteins remains largely unknown. In this study we have identified and annotated the six zebrafish genes of this family, which encode at least ten conceptual LysM-domain containing proteins. Two distinct sub-families called LysMD and OXR were identified and shown to be highly conserved across vertebrates. The detailed characterization of LysMD and OXR gene expression in zebrafish embryos showed that all the members of these sub-families are strongly expressed maternally and zygotically from the earliest stages of a vertebrate embryonic development. Moreover, the analysis of the spatio-temporal expression patterns, by whole mount and fluorescent in situ hybridizations, demonstrates pronounced LysMD and OXR gene expression in the zebrafish brain and nervous system during stages of larval development. None of the zebrafish LysMD or OXR genes was responsive to challenge with bacterial pathogens in embryo models of Salmonella and Mycobacterium infections. In addition, the expression patterns of the OXR genes were mapped in a zebrafish brain atlas.     

Identification and Expression of the Family of Classical Protein-Tyrosine Phosphatases in Zebrafish

Protein-tyrosine phosphatases (PTPs) have an important role in cell survival, differentiation, proliferation, migration and other cellular processes in conjunction with protein-tyrosine kinases. Still relatively little is known about the function of PTPs in vivo. We set out to systematically identify all classical PTPs in the zebrafish genome and characterize their expression patterns during zebrafish development. We identified 48 PTP genes in the zebrafish genome by BLASTing of human PTP sequences. We verified all in silico hits by sequencing and established the spatio-temporal expression patterns of all PTPs by in situ hybridization of zebrafish embryos at six distinct developmental stages. The zebrafish genome encodes 48 PTP genes. 14 human orthologs are duplicated in the zebrafish genome and 3 human orthologs were not identified. Based on sequence conservation, most zebrafish orthologues of human PTP genes were readily assigned. Interestingly, the duplicated form of ptpn23, a catalytically inactive PTP, has lost its PTP domain, indicating that PTP activity is not required for its function, or that ptpn23b has lost its PTP domain in the course of evolution. All 48 PTPs are expressed in zebrafish embryos. Most PTPs are maternally provided and are broadly expressed early on. PTP expression becomes progressively restricted during development. Interestingly, some duplicated genes retained their expression pattern, whereas expression of other duplicated genes was distinct or even mutually exclusive, suggesting that the function of the latter PTPs has diverged. In conclusion, we have identified all members of the family of classical PTPs in the zebrafish genome and established their expression patterns. This is the first time the expression patterns of all members of the large family of PTP genes have been established in a vertebrate. Our results provide the first step towards elucidation of the function of the family of classical PTPs.     

Insights in KIR2.1 channel structure and function by an evolutionary approach; cloning and functional characterization of the first reptilian inward rectifier channel KIR2.1, derived from the California kingsnake (Lampropeltis getula californiae)

Potassium inward rectifier K_IR2.1 channels contribute to the stable resting membrane potential in a variety of muscle and neuronal cell-types. Mutations in the K_IR2.1 gene KCNJ2 have been associated with human disease, such as cardiac arrhythmias and periodic paralysis. Crystal structure and homology modelling of K_IR2.1 channels combined with functional current measurements provided valuable insights in mechanisms underlying channel function. K_IR2.1 channels have been cloned and analyzed from all main vertebrate phyla, except reptilians. To address this lacuna, we set out to clone reptilian K_IR2.1 channels. Using a degenerated primer set we cloned the KCNJ2 coding regions from muscle tissue of turtle, snake, bear, quail and bream, and compared their deduced amino acid sequences with those of K_IR2.1 sequences from 26 different animal species obtained from Genbank. Furthermore, expression constructs were prepared for functional electrophysiological studies of ectopically expressed K_IR2.1 ion channels. In general, KCNJ2 gene evolution followed normal phylogenetic patterns, however turtle K_IR2.1 ion channel sequence is more homologues to avians than to snake. Alignment of all 31 K_IR2.1 sequences showed that all disease causing K_IR2.1 mutations, except V93I, V123G and N318S, are fully conserved. Homology models were built to provide structural insights into species specific amino acid substitutions. Snake K_IR2.1 channels became expressed at the plasmamembrane and produced typical barium sensitive (IC₅₀ ∼6 μM) inward rectifier currents.     

Identification and functional characterization of zebrafish K2P10.1 (TREK2) two-pore-domain K+ channels

Two-pore-domain potassium (K_2P) channels mediate K⁺ background currents that stabilize the resting membrane potential and contribute to repolarization of action potentials in excitable cells. The functional significance of K_2P currents in cardiac electrophysiology remains poorly understood. Danio rerio (zebrafish) may be utilized to elucidate the role of cardiac K_2P channels in vivo. The aim of this work was to identify and functionally characterize a zebrafish otholog of the human K_2P10.1 channel. K_2P10.1 orthologs in the D. rerio genome were identified by database analysis, and the full zK_2P10.1 coding sequence was amplified from zebrafish cDNA. Human and zebrafish K_2P10.1 proteins share 61% identity. High degrees of conservation were observed in protein domains relevant for structural integrity and regulation. K_2P10.1 channels were heterologously expressed in Xenopus oocytes, and currents were recorded using two-electrode voltage clamp electrophysiology. Human and zebrafish channels mediated K⁺ selective background currents leading to membrane hyperpolarization. Arachidonic acid, an activator of hK_2P10.1, induced robust activation of zK_2P10.1. Activity of both channels was reduced by protein kinase C. Similar to its human counterpart, zK_2P10.1 was inhibited by the antiarrhythmic drug amiodarone. In summary, zebrafish harbor K_2P10.1 two-pore-domain K⁺ channels that exhibit structural and functional properties largely similar to human K_2P10.1. We conclude that the zebrafish represents a valid model to study K_2P10.1 function in vivo.     

Zebrafish chordin-like and chordin are functionally redundant in regulating patterning of the dorsoventral axis

Chordin is the prototype of a group of cysteine-rich domain-containing proteins that bind and modulate signaling of various TGFβ-like ligands. Chordin-like 1 and 2 (CHL1 and 2) are two members of this group that have been described in human, mouse, and chick. However, in vivo roles for CHL1 and 2 in early development are unknown due to lack of loss-of-function analysis. Here we identify and characterize zebrafish, Danio rerio, CHL (Chl). The chl gene is on a region of chromosome 21 syntenic with the area of murine chromosome 7 bearing the CHL2 gene. Inability to identify a separate zebrafish gene corresponding to the mammalian CHL1 gene suggests that Chl may serve roles in zebrafish distributed between CHL1 and CHL2 in other species. Chl is a maternal factor that is also zygotically expressed later in development and has spatiotemporal expression patterns that differ from but overlap those of zebrafish chordin (Chd), suggesting differences but also possible overlap in developmental roles of the two proteins. Chl, like Chd, dorsalizes embryos upon overexpression and is cleaved by BMP1, which antagonizes this activity. Loss-of-function experiments demonstrate that Chl serves as a BMP antagonist with functions that overlap and are redundant with those of Chd in forming the dorsoventral axis.     

Comparative genomics analysis reveals gene family expansion and changes of expression patterns associated with natural adaptations of flowering time and secondary metabolism in yellow <Emphasis Type="Italic">Camellia</Emphasis>

Yellow-flowering species are unique in the genus Camellia not only for their bright yellow pigments but also the health-improving substances in petals. However, little is known regarding the biosynthesis pathways of pigments and secondary metabolites. Here, we performed comparative genomics studies in two yellow-flowered species of the genus Camellia with distinctive flowering periods. We obtained 112,190 and 89,609 unigenes from Camellia nitidissima and Camellia chuongtsoensis, respectively, and identified 9547 gene family clusters shared with various plant species and 3414 single-copy gene families. Global gene expression analysis revealed six comparisons of differentially expressed gene sets in different developmental stages of floral bud. Through the identification of orthologous pairs, conserved and specific differentially expressed genes (DEGs) between species were compared. Functional enrichment analysis suggested that the gibberellin (GA) biosynthesis pathway might be related to the alteration of flowering responses. Furthermore, the expression patterns of secondary metabolism pathway genes were analyzed between yellow- and red-flowered Camellias. We showed that the key enzymes involved in glycosylation of flavonoids displayed differential expression patterns, indicating that the direct glycosylation of flavonols rather than anthocyanins was pivotal to coloration and health-improving metabolites in the yellow Camellia petals. Finally, the gene family analysis of UDP-glycosyltransferases revealed an expansion of group C members in C. nitidissima. Through comparative genomics analysis, we demonstrate that changes of gene expression and gene family members are critical to the variation of natural traits. This work provides valuable insights into the molecular regulation of trait adaptations of floral pigmentation and flowering timing.     

Expression analysis of the family of 14-3-3 proteins in zebrafish development

14-3-3 proteins comprise a family of dimeric multi-functional proteins present in all eukaryotes, that are important in a whelm of ubiquitous biological processes. We have analyzed the genomic structure of all 14-3-3s from zebrafish comprising 11 genes and have analyzed their phylogeny. The gene family was cloned and its expression pattern in zebrafish embryogenesis was analyzed by whole mount in situ hybridization and microarray analysis with gene specific probes. We demonstrate that maternal mRNA of 14-3-3s is expressed evenly at the first cell division. At later stage all genes are expressed in a patterned way with, in most cases, intricate patterns in the developing brain. Our result shows distinct expression patterns of various genes. Microarray results show that differences in expression levels of highly similar 14-3-3 genes also occur in the adult stage.     

Expression analysis of nel during zebrafish embryonic development

Nel is a multimeric extracellular glycoprotein which predominantly expressed in the nervous system and play an important role in neural development and functions. There are three nel paralogues included nell2a, nell2b, and nell3 in zebrafish, while systematic expression analysis of the nel family is still lacking. In this study, we performed a phylogenetic analysis on 7 species, in different species the nell2a are highly conserved, as is nell2b. Then, the expression profiles of nell2a, nell2b and nell3 were detected by in situ hybridization in zebrafish embryo, and the result showed that nel genes highly enriched in the central nervous system, but distributed in different regions of the brain. In addition, nell2a is also expressed in the olfactory pit, spinal cord, otic vesicle and retina (ganglion cell layer), nell2b was detected to express in gill arches, olfactory epithelium, olfactory pit, spinal cord, photoreceptor and retina (ganglion cell layer), it should be noted that the expression of nell3 is special, was only detected at 96 hpf in the brain and spinal cord of zebrafish. Overall, our results indicate that nell2a and nell2b genes are expressed in the nervous system and eyes of zebrafish embryo, while nell3 is expressed in different regions in the nervous system. The phylogenetic analysis also shows that nell3 sequences are significantly different from nell2a and nell2b. This study provides new evidence to better understand the role of nel in zebrafish embryo development.     

Molecular cloning and expression of phospholipase C epsilon 1 in zebrafish

Phospholipase C (PLC) is a key enzyme that generates inositol 1,4,5-triphosphate (IP₃) and diacylglycerol (DAG), two second messengers in signal transduction. Phospholipase Cε (PLCE1) is a unique member of the PLC family in that it carries both RasGEF and Ras-associating (RA) domains and may serve as an activator and an effector of small GTPases. Recently, mutations in PLCE1 have been associated with early-onset nephrotic syndrome. We have identified the zebrafish ortholog of PLCE1 and characterized its expression pattern in zebrafish embryos by in situ hybridization. Zebrafish plce1 gene encodes a protein of 2248 amino acids that shares 56% identity with mammalian PLCε. During zebrafish embryonic development, plce1 is expressed in a dynamic pattern in a variety of organs, such as brain, muscle, liver, and pronephric glomeruli. Our results suggest that zebrafish may be used as a model organism to address the function of PLCε during the development of these organs.     

Sequence and expression analysis of the Arabidopsis IQM family

Four major families have been found so far to possess the calmodulin binding IQ motif/s in plants: the IQD, the myosin, the CAMTA and the CNGC family. We have systematically identified and characterized a novel IQ motif-containing protein family, IQM, in Arabidopsis (Arabidopsis thaliana) using bioinformatics methods. IQM family contains six-member proteins (IQM1-6) which share sequence homology with a pea heavy metal-induced protein 6 and a ribosome-inactivating protein, trichosanthin, as well as IQ motif. IQM family can be divided into two groups, IQM3 and the other member proteins, based on sequence similarity and phylogenetic analysis of sequences. Though almost constitutive expression patterns were found in various plant organs of 6-week-old plants for IQM1 and 2, the other genes exhibited distinct organ-specific expression patterns. Light irradiation and treatment with heavy metals such as CdCl₂ or Pb(NO₃)₂ and high concentrations of mannitol or NaCl also changed expression of each IQM gene in a distinct manner in 7-day-old seedlings. However, treatment with various hormones, such as auxin, abscisic acid, gibberellin, methyl jasmonate and ethylene precursor, did not affect gene expression significantly. These results suggest that each IQM family gene plays a different role in plant development and responses to environmental cues.     

Multi-target Chromogenic Whole-mount In Situ Hybridization for Comparing Gene Expression Domains in Drosophila Embryos

To analyze gene regulatory networks active during embryonic development and organogenesis it is essential to precisely define how the different genes are expressed in spatial relation to each other in situ. Multi-target chromogenic whole-mount in situ hybridization (MC-WISH) greatly facilitates the instant comparison of gene expression patterns, as it allows distinctive visualization of different mRNA species in contrasting colors in the same sample specimen. This provides the possibility to relate gene expression domains topographically to each other with high accuracy and to define unique and overlapping expression sites. In the presented protocol, we describe a MC-WISH procedure for comparing mRNA expression patterns of different genes in Drosophila embryos. Up to three RNA probes, each specific for another gene and labeled by a different hapten, are simultaneously hybridized to the embryo samples and subsequently detected by alkaline phosphatase-based colorimetric immunohistochemistry. The described procedure is detailed here for Drosophila, but works equally well with zebrafish embryos.     

Molecular cloning and gene expression of the prox1a and prox1b genes in the medaka,Oryzias latipes

Prox1 is a prospero-related homeobox gene. Prox1 is expressed in various internal organs and is related to those differentiations. Small fishes such as the zebrafish and the medaka are useful model animals in the clarification of the mechanism of development. The zebrafish prox1 is also identified, and it contributes to clarifying the function of prox1. However, it is necessary to note that many genes are duplicated in teleost fishes. In this study, we identified the orthologs of the mammalian prox1 gene in the medaka. The gene was also duplicated in the medaka, and we named it prox1a and prox1b. In silico analysis from the perspective of synteny indicated that medaka prox1a was similar to the prox1 gene of other vertebrates. Medaka prox1a was expressed in all internal organs that we have examined by RT-PCR. In contrast, medaka prox1b expression was limited to the brain, heart, liver, kidney, thymus, gill, testis, and ovary. This suggests that the two prox1 genes do not have a complementary relationship. In addition, we examined their expression patterns during embryonic development using whole-mount in situ hybridization. The expression pattern of prox1a showed a pattern similar to that of zebrafish prox1. In contrast, medaka prox1b was expressed asymmetrically in part of the central nervous system, especially strongly in the right side of the habenula.