The expression profile and function of Satb2 in zebrafish embryonic development

The present study shows the expression profile and function of the homeobox gene, satb2 during zebrafish embryonic development. Satb2 was ubiquitously expressed from the 1 cell stage to the 10-somite stage in zebrafish embryos. Satb2 showed stage-specific expression profiles such as in the pronephric duct at 24 hpf, the branchial arches at 36 hpf, and the ganglion cell layer of the retina and fins at 48 hpf. Additionally, satb2 knockdown embryos were arrested at 50–60% epiboly, and transplantation experiments with satb2 knockdown cells showed migration defects. Interestingly, satb2 knockdown cells also exhibited down-regulation of dynamin II and VAMP4, which are involved in exocytosis and endocytosis, respectively. Furthermore, satb2 knockdown cells have a disorganized actin distribution and an underdeveloped external yolk syncytial layer, both of which are involved in epiboly. These results suggest that satb2 has a functional role in epiboly. This role may potentially be the regulation of endo-exocytic vesicle transport-dependent cell migration and/or the regulation of the development of the yolk syncytial layer.     

微小染色体维系蛋白3基因在斑马鱼早期胚胎发育过程中的表达

目的:制备地高辛标记的微小染色体维系蛋白3(MCM3)基因的RNA探针,研究MCM3在斑马鱼早期发育中的时空表达。方法:收集并固定受精后24 h时期的野生型斑马鱼胚胎,提取总RNA,制备DIG标记的MCM3 RNA反义探针,整胚原位杂交,研究MCM3在斑马鱼胚胎早期发育过程的表达。结果:斑马鱼的MCM3氨基酸序列与小鼠、人具有高度同源性,通过不同时期胚胎的原位杂交,发现MCM3在早期发育过程中普遍性表达,胚胎受精后0~2 hMCM3在增殖性区域泛表达,受精后14~22 h在中枢神经系统、发育未成熟的眼部、体节及增殖性区域表达,受精后24 h在血液、中枢神经、翼板中脑、视觉盖及增殖性区域表达,受精后48 h在头部及肛门增殖性区域表达。结论:明确了MCM3在斑马鱼胚胎发育过程中的表达模式,证明其与早期斑马鱼发育细胞增殖密切相关,为研究该基因功能提供了一定的理论基础。     

斑马鱼胚胎发育过程中TGF-1基因的表达特征分析

为研究转化生长因子 (Transforming growth factor , TGF)1对斑马鱼胚胎发育的调控作用, 通过NCBI获得TGF-1基因序列, TGF-1 cDNA全长1571 bp, 编码377个氨基酸。系统进化树分析发现, TGF-蛋白按照不同的类型严格聚类, 斑马鱼TGF-1与其他鱼类的TGF-1聚集到一个分支, 在进化中非常保守。对斑马鱼胚胎进行RT-PCR和Real-Time PCR检测显示, TGF-1基因为母源表达基因, 在分节期之前的表达水平比较低, 而从咽囊期开始持续高水平的表达。胚胎整体原位杂交发现, TGF-1基因在斑马鱼24 hpf 胚胎中开始有特异信号出现, TGF-1基因的表达主要分布在腮弓、侧线原基、耳囊、嗅觉基板、心脏和前肾等处, 表明TGF-1基因可能参与斑马鱼胚胎免疫调节、循环系统发育和侧线形成。用低氧处理斑马鱼胚胎, 发现低氧处理24h后斑马鱼胚胎发育延迟。利用Real-Time PCR和胚胎整体原位杂交检测发现, 低氧处理后发育延迟的斑马鱼胚胎中TGF-1 mRNA表达量较常氧组显著降低。以上结果表明, TGF-1基因参与斑马鱼胚胎发育调控, 并且可能与低氧处理后斑马鱼胚胎发育延迟有关。研究结果将为深入研究斑马鱼TGF-1基因的功能奠定基础。       

Effects of Low‐Dose Embryonic Thyroid Disruption and Rearing Temperature on the Development of the Eye and Retina in Zebrafish

Thyroid hormones are required for vertebrate development, and disruption of the thyroid system in developing embryos can result in a large range of morphologic and physiologic changes, including in the eye and retina. In this study, our anatomic analyses following low‐dose, chronic thyroid inhibition reveal that both methimazole (MMI) exposure and rearing temperature affect eye development in a time‐ and temperature‐dependent fashion. Maximal sensitivity to MMI for external eye development occurred at 65 hr postfertilization (hpf) for zebrafish reared at 28°C, and at 69 hpf for those reared at 31°C. Changes in eye diameter corresponded to changes in thickness of two inner retinal layers: the ganglion cell layer and the inner plexiform layer, with irreversible MMI‐induced decreases in layer thickness observed in larvae treated with MMI until 66 hpf at 28°C. We infer that maximal sensitivity to MMI between 65 and 66 hpf at 28°C indicates a critical period of thyroid‐dependent eye and retinal development. Furthermore, our results support previous work that shows spontaneous escape from MMI‐induced effects potentially due to embryonic compensatory actions, as our data show that embryos treated beyond the critical period generally resemble controls     

Expression of protocadherin-9 and protocadherin-17 in the nervous system of the embryonic zebrafish

In this study we analyzed expression patterns of two δ-protocadherins, protocadherin-9 and protocadherin-17, in the developing zebrafish using in situ hybridization and RT-PCR methods. Both protocadherins were mainly detected in the embryonic central nervous system, but each showed a distinct expression pattern. Protocadherin-9 message (Pcdh9) was expressed after 10 h post fertilization (hpf). It was found mainly in small clusters of cells in the anteroventral forebrain and ventrolateral hindbrain, and scattered cells throughout the spinal cord of young embryos (24 hpf). Pcdh9 expression in the hindbrain was segmental, reflecting a neuromeric organization, which became more evident at 34 hpf. As development proceeded, Pcdh9 expression increased throughout the brain, while its expression in the spinal cord was greatly reduced. Pcdh9 was also found in the developing retina and statoacoustic ganglion. Protocadherin-17 message (Pcdh17) expression began much earlier (1.5–2 hpf) than Pcdh9. Similar to Pcdh9 expression, Pcdh17 expression was found mainly in the anteroventral forebrain at 24 hpf, but its expression in the hindbrain and spinal cord, confined mainly to lateroventral regions of the hindbrain and anterior spinal cord, was more restricted than Pcdh9. As development proceeded, Pcdh17 expression was increased both in the brain and spinal cord: detected throughout the brain of two- and three-day old embryos, strongly expressed in the retina and in lateral regions of spinal cord in two-day old embryos. Its expression in the retina and spinal cord was reduced in three-day old embryos. Our results showed that expression of these two protocadherins was both spatially and temporally regulated.     

Developmental effects of trichloroacetate in Zebrafish embryos: Association with the production of superoxide anion

To assess the developmental toxicity of trichloroacetate (TCA), zebrafish embryos were exposed to 8 to 48 mM of TCA and evaluated for developmental milestones from 8‐ to 144‐hour postfertilization (hpf). All developmental toxicities are reported in this paper. Embryos were found to have developed edema in response to 16 to 48 mM of TCA exposure at 32‐ to 80‐hpf, experienced delay in hatching success in response to 24 to 48 mM at 80‐hpf. Lordosis was observed in developing embryos exposed to 40 to 48 mM at 55‐ to 144‐hpf. The observed toxic effects of TCA exposure were found to be concentration and exposure period independent. Effects were found to be associated with increases in superoxide anion production, but these increases were also found to be concentration and time independent. TCA resulted in concentration‐dependent increases in embryonic lethality at 144‐hpf, with an LC₅₀ determined to be 29.7 mM.     

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.     

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.     

Sodium benzoate exposure downregulates the expression of tyrosine hydroxylase and dopamine transporter in dopaminergic neuronsin developing zebrafish

BACKGROUND: Recent data have demonstrated that treatment with sodium benzoate (SB) leads to significant developmental defects in motor neuron axons and neuromuscular junctions in zebrafish larvae, thereby implying that SB can be neurotoxic. This study examined whether SB affects the development of dopaminergic neurons in the zebrafish brain. METHODS: Zebrafish embryos were exposed to different concentrations of SB for various durations, during which the survival rates were recorded, the expression of tyrosine hydroxylase (TH) and dopamine transporter (DAT) in the neurons in the ventral diencephalon were detected by in situ hybridization and immunofluorescence, and the locomotor activity of larval zebrafish was measured. RESULTS: The survival rates were significantly decreased with the increase of duration and dose of SB-treatment. Compared to untreated clutch mates (untreated controls), treatment with SB significantly downregulated expression of TH and DAT in neurons in the ventral diencephalon of 3-day post-fertilization (dpf) zebrafish embryos in a dose-dependent manner. Furthermore, there was a marked decrease in locomotor activity in zebrafish larvae at 6dpf in response to SB treatment. CONCLUSIONS: The results suggest that SB exposure can cause significantly decreased survival rates of zebrafish embryos in a time- and dose-dependent manner and downregulated expression of TH and DAT in dopaminergic neurons in the zebrafish ventral diencephalon, which results in decreased locomotor activity of zebrafish larvae. This study may provide some important information for further elucidating the mechanism underlying SB-induced developmental neurotoxicity. Birth Defects Res (Part B)86: 85-91, 2009. © 2009 Wiley-Liss, Inc.     

Dichloroacetate-induced developmental toxicity and production of reactive oxygen species in zebrafish embryos

Dichloroacetate (DCA) is one of the toxic by products that are formed during the chlorine disinfection process of drinking water. In this study, the developmental toxicity of DCA has been determined in zebrafish (Danio rerio) embryos. Embryos were exposed to different concentrations (4, 8, 16, and 32 mM) of the compound at the 4 h postfertilization (hpf) stage of development, and were observed for different developmental toxic effects at 8, 24, 32, 55, 80, and 144 hpf. Exposure of embryos to 8-32 mM of DCA resulted in significant increases in the heart rate and blood flow of the 55 and 80 hpf embryos that turned into significant decreases at the 144 hpf time point. At 144 hpf, malformations of mouth structure, notochord bending, yolk sac edema and behavioral effects including perturbed swimming and feeding behaviors were also observed. DCA was also found to produce time- and concentration-dependent increases in embryonic levels of superoxide anion (O2*-) and nitric oxide (NO), at various stages of development. The results of the study suggest that DCA-induced developmental toxic effects in zebrafish embryos are associated with production of reactive oxygen species in those embryos.     

Expression patterns of lgr4 and lgr6 during zebrafish development

Leucine-rich repeat (LRR)-containing G protein-coupled receptors (LGRs) belong to the superfamily of G protein-coupled receptors, and are characterized by the presence of seven transmembrane domains and an extracellular domain that contains a series of LRR motifs. Three Lgr proteins – Lgr4, Lgr5, and Lgr6 – were identified as members of the LGR subfamily. Mouse Lgr4 has been implicated in the formation of various organs through regulation of cell proliferation during development, and Lgr5 and Lgr6 are stem cell markers in the intestine or skin. Although the expression of these three genes has already been characterized in adult mice, their expression profiles during the embryonic and larval development of the organism have not yet been defined. We cloned two zebrafish lgr genes using the zebrafish genomic database. Phylogenetic analyses showed that these two genes are orthologs of mammalian Lgr4 and Lgr6. Zebrafish lgr4 is expressed in the neural plate border, Kupffer’s vesicle, neural tube, otic vesicles, midbrain, eyes, forebrain, and brain ventricular zone by 24 h post-fertilization (hpf). From 36 to 96 hpf, lgr4 expression is detected in the midbrain–hindbrain boundary, otic vesicles, pharyngeal arches, cranial cartilages such as Meckel’s cartilages, palatoquadrates, and ceratohyals, cranial cavity, pectoral fin buds, brain ventricular zone, ciliary marginal zone, and digestive organs such as the intestine, liver, and pancreas. In contrast, zebrafish lgr6 is expressed in the notochord, Kupffer’s vesicle, the most anterior region of diencephalon, otic vesicles, and the anterior and posterior lateral line primordia by 24 hpf. From 48 to 72 hpf, lgr6 expression is confined to the anterior and posterior neuromasts, otic vesicles, pharyngeal arches, pectoral fin buds, and cranial cartilages such as Meckel’s cartilages, ceratohyals, and trabeculae. Our results provide a basis for future studies aimed at analyzing the functions of zebrafish Lgr4 and Lgr6 in cell differentiation and proliferation during organ development.