Zebrafish optineurin: genomic organization and transcription regulation.

Optineurin (OPTN) is involved in a variety of mechanisms, such as autophagy, vesicle trafficking, and nuclear factor kappa-B (NF-κB) signaling. Mutations in the OPTN gene have been associated with different pathologies, including glaucoma, amyotrophic lateral sclerosis, and Paget's disease of bone. Since the relationship between fish and mammalian OPTN is not well understood, the objective of the present work was to characterize the zebrafish optn gene and protein structure and to investigate its transcriptional regulation. Through a comparative in silico analysis, we observed that zebrafish optn presents genomic features similar to those of its human counterpart, including its neighboring genes and structure. A comparison of OPTN protein from different species revealed a high degree of conservation in its functional domains and three-dimensional structure. Furthermore, our in vitro transient-reporter analysis identified a functional promoter in the upstream region of the zebrafish optn gene, along with a region important for its transcription regulation. Site-directed mutagenesis revealed that the NF-κB motif is responsible for the activation of this region. In conclusion, with this study, we characterize zebrafish optn and our results indicate that zebrafish can be considered as an alternative model to study OPTN's biological role in bone-related diseases.

Pilot study of jadomycin B pharmacokinetics and anti-tumoral effects in zebrafish larvae and mouse breast cancer xenograft models.

Despite numerous therapeutic options, multidrug resistance (MDR) remains an obstacle to successful breast cancer therapy. Jadomycin B, a natural product derived from Streptomyces venezuelae ISP5230, maintains cytotoxicity in MDR human breast cancer cells. Our objectives were to evaluate the pharmacokinetics, toxicity, anti-tumoral, and anti-metastatic effects of jadomycin B in zebrafish larvae and mice. In a zebrafish larval xenograft model, jadomycin B significantly reduced the proliferation of human MDA-MB-231 cells at or below its maximum tolerated dose (40 µm). In female Balb/C mice, a single intraperitoneal dose (6 mg/kg) was rapidly absorbed with a maximum serum concentration of 3.4 ± 0.27 µm. Jadomycin B concentrations declined biphasically with an elimination half-life of 1.7 ± 0.058 h. In the 4T1 mouse mammary carcinoma model, jadomycin B (12 mg/kg every 12 h from day 6 to 15 after tumor cell injection) decreased primary tumor volume compared to vehicle control. Jadomycin B-treated mice did not exhibit weight loss, nor significant increases in biomarkers of impaired hepatic (alanine aminotransferase) and renal (creatinine) function. In conclusion, jadomycin B demonstrated a good safety profile and provided partial anti-tumoral effects, warranting further dose-escalation safety and efficacy studies in MDR breast cancer models.

Functional analysis of co-expression networks of zebrafish ace2 reveals enrichment of pathways associated with development and disease.

Human Angiotensin I Converting Enzyme 2 (ACE2) plays an essential role in blood pressure regulation and SARS-CoV-2 entry. ACE2 has a highly conserved, one-to-one ortholog (ace2) in zebrafish, which is an important model for human diseases. However, the zebrafish ace2 expression profile has not yet been studied during early development, between genders, across different genotypes, or in disease. Moreover, a network-based meta-analysis for the extraction of functionally enriched pathways associated with differential ace2 expression is lacking in the literature. Herein, we first identified significant development-, tissue-, genotype-, and gender-specific modulations in ace2 expression via meta-analysis of zebrafish Affymetrix transcriptomics datasets (ndatasets = 107); and the correlation analysis of ace2 meta-differential expression profile revealed distinct positively and negatively correlated local functionally enriched gene networks. Moreover, we demonstrated that ace2 expression was significantly modulated under different physiological and pathological conditions related to development, tissue, gender, diet, infection, and inflammation using additional RNA-seq datasets. Our findings implicate a novel translational role for zebrafish ace2 in organ differentiation and pathologies observed in the intestines and liver.

[Cancer cell transplantation in zebrafish: From translational research to personalized medicine]. / La transplantation de cellules tumorales chez le poisson zèbre : de la recherche translationnelle à la médecine personnalisée.

Primarily used in genetic studies of development, the zebrafish (Danio rerio) has rapidly emerged as a promising animal model of human cancer. Cancer cell transplantation in zebrafish constitutes a key platform for clinical research since it allows to study cellular and molecular events involved in various aspects of tumorigenesis and to evaluate the efficacy of therapeutic molecules in vivo. Applied to patient-derived cells, the xenotransplantation approach in zebrafish allows to define the most appropriate therapeutic strategies for specific alterations found in patients in the context of personalized medicine. This review discusses the zebrafish transplantation model for the study of cancer development and drug discovery.

Transplantable zebrafish models of neuroendocrine tumors.

Neuroendocrine tumors (NETs) are rare neoplasms whose incidence is increasing. NETs constitute a heterogeneous group of tumors. Their clinical features, functional properties, and clinical course are different on the basis of their site of origin. Due to the heterogeneity of these tumors, a coordinated multidisciplinary approach is required in these patients. However, medical doctor encounters many difficulties when providing care for patients with NETs. This review provides an overview of the state of the art of zebrafish model in the cancer research with a main focus on NETs.

Identifying small RNAs derived from maternal- and somatic-type rRNAs in zebrafish development.

rRNAs are non-coding RNAs present in all prokaryotes and eukaryotes. In eukaryotes there are four rRNAs: 18S, 5.8S, 28S, originating from a common precursor (45S), and 5S. We have recently discovered the existence of two distinct developmental types of rRNA: a maternal-type, present in eggs and a somatic-type, expressed in adult tissues. Lately, next-generation sequencing has allowed the discovery of new small-RNAs deriving from longer non-coding RNAs, including small-RNAs from rRNAs (srRNAs). Here, we systemically investigated srRNAs of maternal- or somatic-type 18S, 5.8S, 28S, with small-RNAseq from many zebrafish developmental stages. We identified new srRNAs for each rRNA. For 5.8S, we found srRNA consisting of the 5' or 3' halves, with only the latter having different sequence for the maternal- and somatic-types. For 18S, we discovered 21 nt srRNA from the 5' end of the 18S rRNA with a striking resemblance to microRNAs; as it is likely processed from a stem-loop precursor and present in human and mouse Argonaute-complexed small-RNA. For 28S, an abundant 80 nt srRNA from the 3' end of the 28S rRNA was found. The expression levels during embryogenesis of these srRNA indicate they are not generated from rRNA degradation and might have a role in the zebrafish development.

Diving into the world of alcohol teratogenesis: a review of zebrafish models of fetal alcohol spectrum disorder.

The term fetal alcohol spectrum disorder (FASD) refers to the entire suite of deleterious outcomes resulting from embryonic exposure to alcohol. Along with other reviews in this special issue, we provide insight into how animal models, specifically the zebrafish, have informed our understanding of FASD. We first provide a brief introduction to FASD. We discuss the zebrafish as a model organism and its strengths for alcohol research. We detail how zebrafish has been used to model some of the major defects present in FASD. These include behavioral defects, such as social behavior as well as learning and memory, and structural defects, disrupting organs such as the brain, sensory organs, heart, and craniofacial skeleton. We provide insights into how zebrafish research has aided in our understanding of the mechanisms of ethanol teratogenesis. We end by providing some relatively recent advances that zebrafish has provided in characterizing gene-ethanol interactions that may underlie FASD.

Hydrogen peroxide regulates angiogenesis-related factors in tumor cells.

Tumor angiogenesis is required for tumor development and growth, and is regulated by several factors including ROS. H2O2 is a ROS with an important role in cell signaling, but how H2O2 regulates tumor angiogenesis is still poorly understood. We have xenografted tumor cells with altered levels of H2O2 by catalase overexpression into zebrafish embryos to study redox-induced tumor neovascularization. We found that vascular recruitment and invasion were impaired if catalase was overexpressed. In addition, the overexpression of catalase altered the transcriptional levels of several angiogenesis-related factors in tumor cells, including TIMP-3 and THBS1. These two anti-angiogenic factors were found to be H2O2-regulated by two different mechanisms: TIMP-3 expression in a cell-autonomous manner; and, THBS1 expression that was non-cell-autonomous. Our work shows that intracellular H2O2 regulates the expression of angiogenic factors and the formation of a vessel network. Understanding the molecular mechanisms that govern this multifunctional effect of H2O2 on tumor angiogenesis could be important for the development of more efficient anti-angiogenic therapies.