(Zebra)fishing for nephrogenesis genes

Frataxin deficiency and the pathology of Friedreich's Ataxia across tissues

Friedreich's Ataxia (FRDA) is a neurodegenerative disease that affects a variety of different organ systems. The disease is caused by GAA repeat expansions in intron 1 of the Frataxin gene (FXN), which results in a decrease in the expression of the FXN protein. FXN is needed for the biogenesis of iron-sulfur clusters (ISC) which are required by key metabolic processes in the mitochondria. Without ISCs those processes do not occur properly. As a result, reactive oxygen species accumulate, and the mitochondria cease to function. Iron is also thought to accumulate in the cells of certain tissue types. These processes are thought to be intimately related to the pathologies affecting a myriad of tissues in FRDA. Most FRDA patients suffer from loss of motor control, cardiomyopathy, scoliosis, foot deformities, and diabetes. In this review, we discuss the known features of FRDA pathology and the current understanding about the basis of these alterations.

Zebrafish as a model for human epithelial pathology

Zebrafish (Danio rerio) have emerged as an influential model for studying human epithelial pathology, particularly because of their genetic similarity to humans and their unique physiological traits. This review explores the structural and functional homology between zebrafish and human epithelial tissues in organs, such as the gastrointestinal system, liver, and kidneys. Zebrafish possess significant cellular and functional homology with mammals, which facilitates the investigation of various diseases, including inflammatory bowel disease, nonalcoholic fatty liver disease, and polycystic kidney disease. The advantages of using zebrafish as a model organism include rapid external development, ease of genetic manipulation, and advanced imaging capabilities, allowing for the real-time observation of disease processes. However, limitations exist, particularly concerning the lack of organs in zebrafish and the potential for incomplete phenocopy of human conditions. Despite these challenges, ongoing research in adult zebrafish promises to enhance our understanding of the disease mechanisms and regenerative processes. By revealing the similarities and differences in epithelial cell function and disease pathways, this review highlights the value of zebrafish as a translational model for advancing our knowledge of human health and developing targeted therapies.

Emx2 is an essential regulator of ciliated cell development across embryonic tissues

Cilia are hair-like organelles with vital physiological roles, and ciliogenesis defects underlie a range of severe congenital malformations and human diseases. Here, we report that empty spiracles homeobox 2 (emx2) is essential for cilia development across multiple embryonic tissues including the ear, neuromasts and Kupffer's vesicle (KV), which establishes left/right axial pattern. emx2 deficient embryos manifest altered fluid homeostasis and kidney defects including decreased multiciliated cells (MCCs), determining that emx2 is essential to properly establish several renal lineages. Further, emx2 deficiency disrupted renal monociliated cells, MCCs and led to aberrant basal body positioning. We reported that emx2 regulates prostaglandin biosynthesis in ciliogenesis and renal fate changes through key factors including ppargc1a, ptgs1 and PGE2. Our findings reveal essential roles of emx2 in tissue cilia development, and identify emx2 as a critical regulator of prostaglandin biosynthesis during renal development and ciliogenesis, providing insights relevant for future treatments of ciliopathies.

Using Zebrafish to Study Multiciliated Cell Development and Disease States

Multiciliated cells (MCCs) serve many important functions, including fluid propulsion and chemo- and mechanosensing. Diseases ranging from rare conditions to the recent COVID-19 global health pandemic have been linked to MCC defects. In recent years, the zebrafish has emerged as a model to investigate the biology of MCCs. Here, we review the major events in MCC formation including centriole biogenesis and basal body docking. Then, we discuss studies on the role of MCCs in diseases of the brain, respiratory, kidney and reproductive systems, as well as recent findings about the link between MCCs and SARS-CoV-2. Next, we explore why the zebrafish is a useful model to study MCCs and provide a comprehensive overview of previous studies of genetic components essential for MCC development and motility across three major tissues in the zebrafish: the pronephros, brain ependymal cells and nasal placode. Taken together, here we provide a cohesive summary of MCC research using the zebrafish and its future potential for expanding our understanding of MCC-related disease states.

The amazing axolotl: robust kidney regeneration following acute kidney injury

The incidence of kidney disease from acute and chronic conditions continues to escalate worldwide. Interventions to replace renal function after organ failure remain limited to dialysis or transplantation, as human kidneys exhibit a limited capacity to repair damaged cells or regenerate new ones. In contrast, animals ranging from flies to fishes and even some mammals like the spiny mouse exhibit innate abilities to regenerate their kidney cells following injury. Now, a recent study has illuminated how the Mexican salamander, Ambystoma mexicanum, most commonly known as the axolotl, possesses a kidney with remarkable similarity to humans, which can robustly regenerate following acute chemical damage. These discoveries position the axolotl as a new model that can be used to advance our understanding about the fundamental mechanisms of kidney regeneration.