Pleiotropic effects of Sox2 during the development of the zebrafish epithalamus

The Roles of Histamine Receptor 1 (hrh1) in Neurotransmitter System Regulation, Behavior, and Neurogenesis in Zebrafish

Histamine receptors mediate important physiological processes and take part in the pathophysiology of different brain disorders. Histamine receptor 1 (HRH1) is involved in the development of neurotransmitter systems, and its role in neurogenesis has been proposed. Altered HRH1 binding and expression have been detected in the brains of patients with schizophrenia, depression, and autism. Our goal was to assess the role of hrh1 in zebrafish development and neurotransmitter system regulation through the characterization of hrh1-/- fish generated by the CRISPR/Cas9 system. Quantitative PCR, in situ hybridization, and immunocytochemistry were used to study neurotransmitter systems and genes essential for brain development. Additionally, we wanted to reveal the role of this histamine receptor in larval and adult fish behavior using several quantitative behavioral methods including locomotion, thigmotaxis, dark flash and startle response, novel tank diving, and shoaling behavior. Hrh1-/- larvae displayed normal behavior in comparison with hrh1+/+ siblings. Interestingly, a transient abnormal expression of important neurodevelopmental markers was evident in these larvae, as well as a reduction in the number of tyrosine hydroxylase 1 (Th1)-positive cells, th1 mRNA, and hypocretin (hcrt)-positive cells. These abnormalities were not detected in adulthood. In summary, we verified that zebrafish lacking hrh1 present deficits in the dopaminergic and hypocretin systems during early development, but those are compensated by the time fish reach adulthood. However, impaired sociability and anxious-like behavior, along with downregulation of choline O-acetyltransferase a and LIM homeodomain transcription factor Islet1, were displayed by adult fish.

Transcription factors interact with RNA to regulate genes

Transcription factors (TFs) orchestrate the gene expression programs that define each cell's identity. The canonical TF accomplishes this with two domains, one that binds specific DNA sequences and the other that binds protein coactivators or corepressors. We find that at least half of TFs also bind RNA, doing so through a previously unrecognized domain with sequence and functional features analogous to the arginine-rich motif of the HIV transcriptional activator Tat. RNA binding contributes to TF function by promoting the dynamic association between DNA, RNA, and TF on chromatin. TF-RNA interactions are a conserved feature important for vertebrate development and disrupted in disease. We propose that the ability to bind DNA, RNA, and protein is a general property of many TFs and is fundamental to their gene regulatory function.

A Realistic Mixture of Persistent Organic Pollutants Affects Zebrafish Development, Behavior, and Specifically Eye Formation by Inhibiting the Condensin I Complex

Persistent organic pollutants (POPs) are posing major environmental and health threats due to their stability, ubiquity, and bioaccumulation. Most of the numerous studies of these compounds deal with single chemicals, although real exposures always consist of mixtures. Thus, using different tests, we screened the effects on zebrafish larvae caused by exposure to an environmentally relevant POP mixture. Our mixture consisted of 29 chemicals as found in the blood of a Scandinavian human population. Larvae exposed to this POP mix at realistic concentrations, or sub-mixtures thereof, presented growth retardation, edemas, retarded swim bladder inflation, hyperactive swimming behavior, and other striking malformations such as microphthalmia. The most deleterious compounds in the mixture belong to the per- and polyfluorinated acids class, although chlorinated and brominated compounds modulated the effects. Analyzing the changes in transcriptome caused by POP exposure, we observed an increase of insulin signaling and identified genes involved in brain and eye development, leading us to propose that the impaired function of the condensin I complex caused the observed eye defect. Our findings contribute to the understanding of POP mixtures, their consequences, and potential threats to human and animal populations, indicating that more mechanistic, monitoring, and long-term studies are imperative.

SOX19b regulates the premature neuronal differentiation of neural stem cells through EZH2-mediated histone methylation in neural tube development of zebrafish

Objective

Neural tube defects (NTDs) are the most serious and common birth defects in the clinic. The SRY-related HMG box B1 (SoxB1) gene family has been implicated in different processes of early embryogenesis. Sox19b is a maternally expressed gene in the SoxB1 family that is found in the region of the presumptive central nervous system (CNS), but its role and mechanism in embryonic neural stem cells (NSCs) during neural tube development have not yet been explored. Considering that Sox19b is specific to bony fish, we intended to investigate the role and mechanism of Sox19b in neural tube development in zebrafish embryos.

Material and methods

Morpholino (MO) antisense oligonucleotides were used to construct a Sox19b loss-of-function zebrafish model. The phenotype and the expression of related genes were analysed by in situ hybridization and immunolabelling. Epigenetic modifications were detected by western blot and chromatin immunoprecipitation.

Results

In this study, we found that zebrafish embryos exhibited a reduced or even deleted forebrain phenotype after the expression of the Sox19b gene was inhibited. Moreover, we found for the first time that knockdown of Sox19b reduced the proliferation of NSCs; increased the transcription levels of Ngn1, Ascl1, HuC, Islet1, and cyclin-dependent kinase (CDK) inhibitors; and led to premature differentiation of NSCs. Finally, we found that knockdown of Sox19b decreased the levels of EZH2/H3K27me3 and decreased the level of H3K27me3 at the promoters of Ngn1 and ascl1a.

Conclusion

Together, our data demonstrate that Sox19b plays an essential role in early NSC proliferation and differentiation through EZH2-mediated histone methylation in neural tube development. This study established the role of transcription factor Sox19b and epigenetic factor EZH2 regulatory network on NSC development, which provides new clues and theoretical guidance for the clinical treatment of neural tube defects.

Identification and expression of transcription factor sox2 in large yellow croaker Larimichthys crocea

As an important transcription and pluripotency factor, Sox2 plays its functions essentially in the regulation of self-renewal and pluripotency of embryonic and neural stem cells, as well as embryogenesis, organogenesis, neurogenesis and regeneration. The data is lacking on Sox2 in large yellow croaker (Larimichthys crocea) (Lc-Sox2) which is a limitation on the generation of induced pluripotent stem cells (iPSCs). In this study, Lc-sox2 was cloned by RACE (rapid amplification of cDNA ends) and analyzed by Bioinformatics. The quantitative real-time PCR (qRT-PCR) and whole mount in situ hybridization (WISH) were used to detect the expression of Lc-sox2. The full-length cDNA sequence of Lc-sox2 is 2135 bp and encodes a 322-aa (amino acids). Lc-Sox2 possesses a highly conserved HMG-box as DNA-binding domain, maintains highly conserved with vertebrates, particularly with teleosts. In tissues, Lc-sox2 was expressed with gender difference in brain and eye (female > male), in embryos, Lc-sox2 was expressed with a zygotic type that the high level expression began to appear in the gastrula stage. The spatio-temporal expression patterns of Lc-sox2 suggested the potential involvement in embryogenesis, neurogenesis, gametogenesis and adult physiological processes of large yellow croaker. Our results contributed to better understanding of Sox2 from large yellow croaker.

Subtypes of hypoxia-responsive cells differentiate into neurons in spinal cord of zebrafish embryos after hypoxic stress

BACKGROUND INFORMATION

Neuron stem/progenitor cells (NSPCs) of zebrafish central nervous system (CNS) are known to thrive during oxygen recovery after hypoxia, but not all cell types have been fully characterised due to their heterogeneities. In addition, an in vivo model system is not available that can help us to identify what type-specific cell populations that are involved in neural regeneration and to track their cell fate after regeneration. To solve these issues, we employed a zebrafish transgenic line, huORFZ, which harbours an inhibitory upstream open reading frame of human chop mRNA fused downstream with GFP reporter and driven by cytomegalovirus promoter. When huORFZ embryos were exposure to hypoxic stress, followed by oxygen recovery, GFP was exclusively expressed in some particular cells of CNS. Unlike GFP-negative cells, all GFP-expressing cells were not apoptotic, indicating that cell populations that are able to survive after hypoxia can be identified through this approach.

RESULTS

When GFP-expressing cells of spinal cord were studied, we found mostly NSPCs and radial glia cells (RGs), along with a few oligodendrocyte progenitor cells and oligodendrocytes, all termed as hypoxia-responsive recovering cells (HrRCs). After hypoxic stress, these GFP-positive HrRCs did not undergo apoptosis, but GFP-negative neurons did. Prolonged recovery time after hypoxia was correlated with higher proportions of GFP(+)-NSPCs and GFP(+)-RGs, in contrast to lower proportions of proliferating/differentiating GFP(-)-NSPCs and GFP(-)-RGs. Among HrRCs subtypes, only GFP(+)-NSPCs and GFP(+)-RGs proliferated, migrated and differentiated into functional neurons during oxygen recovery. When some HrRCs were ablated in the spinal cord of hypoxia-exposed huORFZ embryos, swimming performance was impaired, suggesting that HrRCs are involved in neuronal regeneration.

CONCLUSION

We demonstrated type-specific cell populations able to respond sensitively to hypoxic stress in the spinal cord of zebrafish embryos and that these type-specific populations play a role in neural regeneration.

SIGNIFICANCE

Among heterogeneous cell types that exist in the spinal cord of zebrafish embryos after hypoxia, the particular cells that are resistant to hypoxia and also involved in neuronal regeneration can be clearly identified and dynamically traced using a transgenic model fish.

Conserved genetic pathways associated with microphthalmia, anophthalmia, and coloboma

The human eye is a complex organ whose development requires extraordinary coordination of developmental processes. The conservation of ocular developmental steps in vertebrates suggests possible common genetic mechanisms. Genetic diseases involving the eye represent a leading cause of blindness in children and adults. During the last decades, there has been an exponential increase in genetic studies of ocular disorders. In this review, we summarize current success in identification of genes responsible for microphthalmia, anophthalmia, and coloboma (MAC) phenotypes, which are associated with early defects in embryonic eye development. Studies in animal models for the orthologous genes identified overlapping phenotypes for most factors, confirming the conservation of their function in vertebrate development. These animal models allow for further investigation of the mechanisms of MAC, integration of various identified genes into common developmental pathways and finally, provide an avenue for the development and testing of therapeutic interventions.