Temporal and spatial expression of the four Igf ligands and two Igf type 1 receptors in zebrafish during early embryonic development

The insulin-like growth factor (Igf) family is an evolutionarily conserved system essential for normal growth and development in vertebrates. Unlike mammals, four distinct Igf ligands (Igf1, Igf2a, Igf2b and Igf3) and two Igf type 1 receptors (Igf1ra and Igf1rb) are present in zebrafish. However, the localization of these multiple ligands and receptors especially the recently discovered igf3 during early development of zebrafish is poorly understood. In this study, detailed expression patterns of these components of the Igf system during embryogenesis of zebrafish were analyzed. It was found that igf1 is specifically expressed in the trigeminal ganglia region from 18 hpf to 72 hpf, while igf2a is restricted to the caudal regions of the notochord from 14 hpf to 18 hpf as well as in the midbrain, dorsal hind brain and otic vesicle at 24 hpf. On the other hand, igf2a is highly expressed in the midbrain and pharyngeal arch region at 48 hpf, followed by its appearance in the liver and brain at 72 hpf, while igf2b is restricted to the floor plate and hypochord from 12 hpf to 18 hpf, and strong expression is also detected in the midbrain and dorsal hind brain at 24 hpf. The teleost specific igf3 is highly expressed in the pharyngeal arch region before 24 hpf, but is then restricted to the sternohyoideus after 48 hpf. The receptor subtype igf1ra is ubiquitously expressed before 24 hpf but is confined to the brain at 72 hpf. However, igf1rb is widely expressed before 10 hpf, but is more confined to the brain region at 24 hpf and 72 hpf. This dynamic temporal-spatial expression during embryogenesis of zebrafish, together with the unique and overlapping expression patterns of the Igf ligands and receptors suggest the coordination of the divergent functions of the Igf system during early development in zebrafish.     

Nonmuscle myosin II-B (myh10) expression analysis during zebrafish embryonic development

Nonmuscle myosin II (NM II) is the name given to the multi-subunit protein product of three genes (myh9, myh10, and myh14) encoding different nonmuscle myosin heavy chains. The three NM II isoforms share a very similar molecular structure and play important roles in a variety of fundamental biological processes. NM II-B (myh10) has been shown to be essential for the formation of mouse neural system and heart. But so far the complete knowledge for its expression in developing zebrafish embryos is lacking. In current study, we proved the conservation of zebrafish NM II-B in vertebrate evolution by in silicon analysis. Afterwards the NM II-B (myh10) expression was demonstrated to initiate after gastrulation stage. At 20 hpf, the expression is mainly restricted in central nervous system (CNS). It was maintained and expanded to sensor organ including eye, otic vesicle, and olfactory bulb at 36 hpf and later. We also detected myh10 mRNA hybridization signal in 48 hpf zebrafish heart. In addition, we investigated myh9a and myh9b mRNA distribution in zebrafish developing embryos. It was shown that myh10 and myh9 have distinct expression pattern, with myh9s not in neural system but in epidermis, enveloping layer (EVL). Our study provides new insight into the NM II expression and the use of this model organism to tackle future studies on the role of NM II in embryo development.     

Glutathione redox dynamics and expression of glutathione-related genes in the developing embryo

Embryonic development involves dramatic changes in cell proliferation and differentiation that must be highly coordinated and tightly regulated. Cellular redox balance is critical for cell fate decisions, but it is susceptible to disruption by endogenous and exogenous sources of oxidative stress. The most abundant endogenous nonprotein antioxidant defense molecule is the tripeptide glutathione (γ-glutamylcysteinylglycine, GSH), but the ontogeny of GSH concentration and redox state during early life stages is poorly understood. Here, we describe the GSH redox dynamics during embryonic and early larval development (0–5 days postfertilization) in the zebrafish (Danio rerio), a model vertebrate embryo. We measured reduced and oxidized glutathione using HPLC and calculated the whole embryo total glutathione (GSH_T) concentrations and redox potentials (E_h) over 0–120 h of zebrafish development (including mature oocytes, fertilization, midblastula transition, gastrulation, somitogenesis, pharyngula, prehatch embryos, and hatched eleutheroembryos). GSH_T concentration doubled between 12 h postfertilization (hpf) and hatching. The GSH E_h increased, becoming more oxidizing during the first 12 h, and then oscillated around −190 mV through organogenesis, followed by a rapid change, associated with hatching, to a more negative (more reducing) E_h (−220 mV). After hatching, E_h stabilized and remained steady through 120 hpf. The dynamic changes in GSH redox status and concentration defined discrete windows of development: primary organogenesis, organ differentiation, and larval growth. We identified the set of zebrafish genes involved in the synthesis, utilization, and recycling of GSH, including several novel paralogs, and measured how expression of these genes changes during development. Ontogenic changes in the expression of GSH-related genes support the hypothesis that GSH redox state is tightly regulated early in development. This study provides a foundation for understanding the redox regulation of developmental signaling and investigating the effects of oxidative stress during embryogenesis.     

Nephrotoxicity assessments of acetaminophen during zebrafish embryogenesis

We used a green fluorescent kidney line, Tg(wt1b:GFP), as a model to access the acetaminophen (AAP)-induced nephrotoxicity dynamically. Zebrafish (Danio rerio) embryos at different developmental stages (12–60 hpf) were treated with different dosages of AAP (0–45 mM) for different time courses (12–60 h). Results showed that zebrafish embryos exhibited no evident differences in survival rates and morphological changes between the mock-treated control (0 mM) and 2.25 mM AAP-exposure (12–72 hpf) groups. In contrast, after higher doses (22.5 and 45 mM) of exposure, embryos displayed malformed kidney phenotypes, such as curved, cystic pronephric tube, pronephric duct, and a cystic and atrophic glomerulus. The percentages of embryos with malformed kidney phenotypes increased as the exposure dosages of AAP increased. Interestingly, under the same exposure time course (12 h) and dose (22.5 mM), embryos displayed higher percentages of severe defects at earlier developmental stage of exposure (12–24 hpf), whereas embryos displayed higher percentages of mild defects at later exposure (60–72 hpf). With an exposure time course less than 24 h of 45 mM AAP, no embryo survived by the developmental stage of 72 hpf. These results indicated that AAP-induced nephrotoxicity depended on the exposure dose, time course and developmental stages. Immunohistochemical experiments showed that the cells' morphologies of the pronephric tube, pronephric duct and glomerulus were disrupted by AAP, and consequently caused cell death. Real-time RT-PCR revealed embryos after AAP treatment decreased the expression of cox2 and bcl2, but increased p53 expression. In conclusion, AAP-induced defects on glomerulus, pronephric tube and pronephric duct could be easily and dynamically observed in vivo during kidney development in this present model.     

A manganese superoxide dismutase in blood clam Tegillarca granosa: molecular cloning, tissue distribution and expression analysis

Apolipoproteins are carrier proteins that bind to lipids to form lipoprotein particles and have been shown to play an important role in lipid metabolism. In this study, a full-length cDNA for apolipoprotein E, named AsapoE, was cloned from the Chinese sturgeon (Acipenser sinensis). This cDNA sequence is 1289 bp in length, and codes for a polypeptide of 274 amino acid residues, which is 45% and 42% identical to that of the rainbow trout and zebrafish, respectively, and 39%, 30%, and 29% identical to frog, mouse, and human respectively. The predicted AsApoE protein has a conserved amphipathic α-helix region with the potential to bind to lipids. RT-PCR analysis reveals that AsapoE is expressed in all tissues examined with a preferential expression in the kidney and liver. During the embryo development stage, AsapoE mRNA is low but still detectable at gastrula stage embryos; then AsapoE mRNAs reach a higher level in muscle contraction stage embryos, this relatively stable expression persists during the following embryogenic stages and declines 1 day after hatching. These results will serve as a basis for comparative studies on vertebrate apoE genes.     

Expression of protocadherin 18 in the CNS and pharyngeal arches of zebrafish embryos

Here, we report the results of molecular cloning and expression analyses of a non-clustered protocadherin (pcdh), pcdh18 in zebrafish embryos. The predicted zebrafish pcdh18 protein shows 6566% identity and 7879% homology with its mammalian and Xenopus counterparts. It has a Disabled-1 binding motif in its cytoplasmic domain, which is characteristic of pcdh18. Zebrafish embryos expressed pcdh18 by the early gastrula stage, 6 h post-fertilization (hpf), in their animal cap but not in the germ ring or the shield. pcdh18 was expressed in the neural tube and the central nervous system (CNS) from 12 hpf. Some populations of cells in the lateral neural tube and spinal cord of 1218 hpf embryos expressed pcdh18, but expression in these cells disappeared by 24 hpf. The hindbrain of embryos at 2456 hpf expressed pcdh18 in cells closely adjacent to the rostral and caudal rhombomeric boundaries in a thread-like pattern running in the dorsoventral direction. The pcdh18-positive cells were localized in the ventral part of the hindbrain at 24 hpf and in the dorsal part from 36 hpf. pcdh18 was also expressed in the telencephalon, diencephalon, tectum, upper rhombic lip, retina and otic vesicle. Expression in the CNS decreased markedly before hatching. Pharyngeal arch primordia, arches, jaws and gills expressed pcdh18, and the molecule was also expressed in some endodermal cells in late embryos.     

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.     

Expression of Na+/K+-ATPase α-subunit mRNA during embryonic development of the crayfish Astacus leptodactylus

Astacus leptodactylus is a decapod crustacean fully adapted to freshwater where it spends its entire life cycle after hatching under huge osmoconcentration differences between the hemolymph and surrounding freshwater. We investigated the expression of mRNA encoding one ion transport-related protein, Na⁺/K⁺-ATPase α-subunit, and one putative housekeeping gene, β-actin, during crayfish ontogenesis using quantitative real-time PCR. A 216-amino acid part of the open reading frame region of the cDNA coding for the Na⁺/K⁺-ATPase α-subunit was sequenced from total embryo, juvenile and adult gill tissues. The predicted amino acid sequence showed a high percentage similarity to those of other invertebrates (up to 95%) and vertebrates (up to 69%). β-actin expression exhibited modest changes through embryonic development and early post-embryonic stage. The Na⁺/K⁺-ATPase α-subunit gene was expressed in all studied stages from metanauplius to juvenile. Two peaks of expression were observed: one in young embryos at 25% of embryonic development (EI = 100 μm), and one in embryos just before hatching (at EI = 420 μm), continuing in the freshly hatched juveniles. The Na⁺/K⁺-ATPase expression profile during embryonic development is time-correlated with the occurrence of other features, including ontogenesis of excretory antennal glands and differentiation of gill ionocytes linked to hyperosmoregulation processes and therefore involved in freshwater adaptation.     

Differences in egg deposition of corticosterone and embryonic expression of corticosterone metabolic enzymes between slow and fast growing broiler chickens

Glucocorticoids (GCs) are vital for embryonic development and their bioactivity is regulated by the intracellular metabolism involving 11β-hydroxysteroid dehydrogenases (11β-HSDs) and 20-hydroxysteroid dehydrogenase (20-HSD). Here we sought to reveal the differences in egg deposition of corticosterone and embryonic expression of corticosterone metabolic enzymes between slow and fast growing broiler chickens (Gallus gallus). Eggs of fast-growing breed contained significantly higher (P < 0.05) corticosterone in the yolk and albumen, compared with that of a slow-growing breed. 11β-HSD1 and 11β-HSD2 were expressed in relatively higher abundance in the liver, kidney and intestine, following similar tissue-specific ontogenic patterns. In the liver, expression of both 11β-HSD1 and 11β-HSD2 was upregulated (P < 0.05) towards hatching, yet 20-HSD displayed distinct pattern showing a significant decrease (P < 0.05) on posthatch day 1 (D1). Hepatic mRNA expression of 11β-HSD1 and 11β-HSD2 was significantly higher in fast-growing chicken embryos at all the embryonic stages investigated and so was the hepatic protein content on embryonic day of 14 (E14) for 11β-HSD1 and on E14 and D1 for 11β-HSD2. 20-HSD mRNA was higher in fast-growing chicken embryos only on E14. Our data provide the first evidence that egg deposition of corticosterone, as well as the hepatic expression of glucocorticoid metabolic enzymes, differs between fast-growing and slow-growing chickens, which may account, to some extent, for the breed disparities in embryonic development.