Germline Disruption of Retinal Pigment Epithelium-Expressed Zebrafish rlbp1b Results in Selective Dim Light Visual Behavior Deficits and Provides a Screening Platform for Evaluating the Pathogenicity of Human RLBP1 Variants.

Cellular retinaldehyde binding protein (CRALBP) plays a crucial role in the visual cycle by chaperoning 11-cis-retinoids. Mutations in its encoding gene RLBP1 lead to inherited retinal diseases with the common feature of poor night vision. Zebrafish possess two RLBP1 paralogs, rlbp1a and rlbp1b, with distinct retinal expression profiles, providing a bespoke opportunity to dissect cell-specific functions of CRALBP.

The dark and bright sides of retinal G protein-coupled receptor (RGR) in vision and disease.

The visual chromophore 11-cis-retinal (11cRAL) is essential to vertebrate phototransduction and therefore, must be regenerated so vision can be sustained. 11cRAL regeneration mediated by the classical visual cycle is insufficient under photopic conditions. Expressed in the retinal pigment epithelium (RPE) and Müller glia, the retinal G protein-coupled receptor (RGR) can act as an alternative visual cycle photoisomerase, photogenerating 11cRAL in bright light conditions.

Emc1 is essential for vision and zebrafish photoreceptor outer segment morphogenesis.

Inherited retinal diseases (IRDs) are a rare group of eye disorders characterized by progressive dysfunction and degeneration of retinal cells. In this study, we characterized the raifteirí (raf) zebrafish, a novel model of inherited blindness, identified through an unbiased ENU mutagenesis screen. A mutation in the largest subunit of the endoplasmic reticulum membrane protein complex, emc1 was subsequently identified as the causative raf mutation.

The myocardium utilizes a platelet-derived growth factor receptor alpha (Pdgfra)-phosphoinositide 3-kinase (PI3K) signaling cascade to steer toward the midline during zebrafish heart tube formation.

Coordinated cell movement is a fundamental process in organ formation. During heart development, bilateral myocardial precursors collectively move toward the midline (cardiac fusion) to form the primitive heart tube. Extrinsic influences such as the adjacent anterior endoderm are known to be required for cardiac fusion.

The myocardium utilizes Pdgfra-PI3K signaling to steer towards the midline during heart tube formation.

Coordinated cell movement is a fundamental process in organ formation. During heart development, bilateral myocardial precursors collectively move towards the midline (cardiac fusion) to form the primitive heart tube. Along with extrinsic influences such as the adjacent anterior endoderm which are known to be required for cardiac fusion, we previously showed that the platelet-derived growth factor receptor alpha (Pdgfra) is also required.

Using Live Imaging to Examine Early Cardiac Development in Zebrafish.

Visualizing dynamic cellular behaviors using live imaging is critical to the study of cell movement and to the study of cellular and embryonic polarity. Similarly, live imaging can be vital to elucidating the pathology of genetic disorders and diseases. Model systems such as zebrafish, whose in vivo development is accessible to both the microscope and genetic manipulation, are particularly well-suited to the use of live imaging.

A unique macrophage subpopulation signals directly to progenitor cells to promote regenerative neurogenesis in the zebrafish spinal cord.

Central nervous system injury re-initiates neurogenesis in anamniotes (amphibians and fishes), but not in mammals. Activation of the innate immune system promotes regenerative neurogenesis, but it is fundamentally unknown whether this is indirect through the activation of known developmental signaling pathways or whether immune cells directly signal to progenitor cells using mechanisms that are unique to regeneration. Using single-cell RNA-seq of progenitor cells and macrophages, as well as cell-type-specific manipulations, we provide evidence for a direct signaling axis from specific lesion-activated macrophages to spinal progenitor cells to promote regenerative neurogenesis in zebrafish.