In vitro analysis of the transcriptional regulatory mechanism of zebrafish pou5f3.

Zebrafish pou5f3 (previously named pou2), a close homologue of mouse Oct4, encodes a PouV-family transcription factor. pou5f3 has been implicated in diverse aspects of developmental regulation during embryogenesis. In the present study, we addressed the molecular function of Pou5f3 as a transcriptional regulator and the mechanism by which pou5f3 expression is transcriptionally regulated. We examined the influence of effector genes on the expression of the luciferase gene under the control of the upstream 2.1-kb regulatory DNA of pou5f3 (Luc-2.2) in HEK293T and P19 cells. We first confirmed that Pou5f3 functions as a transcriptional activator both in cultured cells and embryos, which confirmed autoregulation of pou5f3 in embryos. It was further shown that Luc-2.2 was activated synergistically by pou5f3 and sox3, which is similar to the co-operative activity of Oct4 and Sox2 in mice, although synergy between pou5f3 and sox2 was less obvious in this zebrafish system. The effects of pou5f3 deletion constructs on the regulation of Luc-2.2 expression revealed different roles for the three subregions of the N-terminal region in Pou5f3 in terms of its regulatory functions and co-operativity with Sox3. Electrophoretic mobility shift assays confirmed that Pou5f3 and Sox3 proteins specifically bind to adjacent sites in the 2.1-kb DNA and that there is an interaction between the two proteins. The synergy with sox3 was unique to pou5f3-the other POU factor genes examined did not show such synergy in Luc-2.2 regulation. Finally, functional interaction was observed between pou5f3 and sox3 in embryos in terms of the regulation of dorsoventral patterning and convergent extension movement. These findings together demonstrate co-operative functions of pou5f3 and sox3, which are frequently coexpressed in early embryos, in the regulation of early development.

Mesendoderm specification depends on the function of Pou2, the class V POU-type transcription factor, during zebrafish embryogenesis.

Zebrafish pou2, encoding the class V POU transcription factor orthologous to mouse Oct-3/4, has been implicated in different aspects of development, such as dorsoventral patterning, endoderm formation, and brain regionalization, by analyzing pou2 mutant embryos. In the present study, we first conducted overexpression of pou2-modified genes by mRNA injection, and found that pou2 and its active form (vp-pou2) augmented mesoderm formation and suppressed endoderm specification, whereas repressive pou2 (en-pou2) affected the formation of the mesoderm and endoderm in a different manner. To avoid complications that might arise from different pou2 functions during the course of development, we used a transgenic line harboring inducible en-pou2 (HEP), which could function in a dominant-negative manner. We found that suppressing endogenous pou2 by HEP induction at the mid-blastula stage enhanced endoderm development at the expense of mesoderm, whereas the same treatment in the late blastulae promoted mesoderm formation and suppressed the endoderm specification. Further analyses using HEP induction revealed that, from late epiboly to early somitogenesis, pou2 regulated additional developmental aspects, such as brain regionalization, heart development, and tail formation. Our findings suggest that Pou2 functions in multiple aspects of vertebrate development, especially in the binary decision of the mesendoderm to mesoderm and endoderm in different ways depending on the developmental stage.

Pou2, a class V POU-type transcription factor in zebrafish, regulates dorsoventral patterning and convergent extension movement at different blastula stages.

Zebrafish pou2, which encodes a class V POU transcription factor considered to be an orthologue of mouse Oct-3/4, has been implicated by mutant analysis in dorsoventral (DV) patterning, gastrulation, and endoderm formation in early embryos and later in the regionalization of the neural plate. A series of gain-of-function experiments were conducted in the present study to directly reveal the roles pou2 plays in embryogenesis. We first revealed that injecting low-dose wild-type pou2 mRNA ventralizes embryos. Similar overexpression of activated (vp-) pou2 resulted in the same effects, whereas repressive (en-) pou2 caused dorsalization, supporting the previously proposed idea that pou2 is involved in DV patterning and that pou2 is a transcriptional activator. In contrast, high-dose mRNA for pou2 and its modified genes affected convergent extension (CE) movement. We observed similar activities for mouse Oct-3/4, suggesting conservation of the roles of this POU family in vertebrate development. To determine the critical stage for the functions of pou2 in embryos, we established a transgenic (Tg) fish line harboring en-pou2 under regulation of a heat-shock promoter (HEP) and found that the exposure of HEP Tg embryos to heat shock at the midblastula (sphere) stage dorsalized embryos, whereas induction of HEP at the late blastula stage (30-50% epiboly) affected CE movement. The defects due to HEP induction were rescued by introducing wild-type pou2 mRNA before the heat treatments. Collectively, these data demonstrated that pou2 regulates DV patterning and CE movement in zebrafish embryos at the midblastula and late blastula stages, respectively.

Behavioral screening for nightblindness mutants in zebrafish reveals three new loci that cause dominant photoreceptor cell degeneration.

Here we report three dominant nightblindness mutations in zebrafish: nightblindness e (nbe), nightblindness f (nbf) and nightblindness g (nbg). The mutants were isolated in the F1 generation of N-ethyl-N-nitrosourea (ENU) mutagenized zebrafish using a behavioral assay based on visually mediated escape responses. Subsequently, electroretinographic (ERG) recordings were made, and histological sections were screened for degenerative processes. For each mutant line, correlation analysis between behavioral, ERG and histological parameters was performed, and their relationships were determined by either calculating the Pearson correlation coefficient or by ANOVA. nbe is characterized by severe rod outer segments (ROS) degeneration. The degeneration correlates weakly with behavioral threshold and ERG b-wave amplitude, however, behavioral threshold correlates strongly with ERG b-wave. nbf is characterized by a dual histological pathology: patchy ROS-degeneration and 'gaps' homogeneously distributed over the outer nuclei layer (ONL) and between cone outer segments (COS). The correlations between histological pathology and behavioral threshold, and between behavioral threshold and ERG b-wave amplitude are obvious, but the correlation between histology and b-wave amplitude is less prominent. nbg is characterized by moderate ROS degeneration and moderate correlation between histology and behavioral threshold. Interestingly, behavioral threshold correlated inversely with ERG b-wave amplitude and threshold. Thus, contrary to what is normally seen in other nightblindness mutants, in nbg, the fish with the lowest behavioral threshold had the smallest b-waves amplitudes and the highest b-wave threshold. In our interpretation, the major impairment in nbe is photoreceptor-specific. In nbf, both photoreceptor degeneration and altered post-photoreceptor signaling are responsible for the behavioral deficit. In nbg, we find hypersensitivity at a post-photoreceptoral level concurrently with behavioral impairment.

Combined effects of caffeine and malnutrition on the newborn rat's myocardium.

We hypothesized that the pathological effects on the neonatal rat heart could be aggravated by Cu deficiency due to the combined effects of caffeine exposure and malnutrition. Upon birth, pups were mixed and randomly picked; 8 pups were assigned to each dam and then divided into 4 groups. Group 1 dams received a normal diet containing 20% protein. Group 2 dams were fed 20% protein diet supplemented with caffeine (4 mg/100 g BW). Group 3 dams received 6% protein diet as a malnourished group, and group 4 dams received 6% protein diet supplemented with caffeine (4 mg/100 g BW). On postnatal day 10, dams and pups were killed. Group 2 tended to have a decrease in the Cu levels of dams' plasma and milk and in pups' plasma and heart tissue compared to those of group 1. This pattern was not observed consistently between groups 3 and 4. Transmission electron microscopy of group 2 pups' hearts revealed a degree of disruption in the mitochondria compared to normal mitochondria seen in group 1. There was no consistent change in the mitochondria of group 4 compared to group 3. The caffeine level observed in all categories of group 4 (dams' plasma and milk, pups' plasma and heart tissue) was lower than those in group 2. Although malnutrition affected body weight and heart weight, combined effects of caffeine and malnutrition on Cu content in the neonatal heart was relatively minor compared to the well nourished group. This well nourished group showed that the effects of caffeine on Cu were more consistent, resulting the changes of mitochondria.