A Morphological and Histological Investigation of Imperfect Lungfish Fin Regeneration

Regeneration, the replacement of body parts in a living animal, has excited scientists for centuries and our knowledge of vertebrate appendage regeneration has increased significantly over the past decades. While the ability of amniotes to regenerate body parts is very limited, members of other vertebrate clades have been shown to have rather high regenerative capacities. Among tetrapods (four-limbed vertebrates), only salamanders show unparalleled capacities of epimorphic tissue regeneration including replacement of organ and body parts in an apparently perfect fashion. The closest living relatives of Tetrapoda, the lungfish, show regenerative abilities that are comparable to those of salamanders and recent studies suggest that these high regenerative capacities may indeed be ancestral for bony fish (osteichthyans) including tetrapods. While great progress has been made in recent years in understanding the cellular and molecular mechanisms deployed during appendage regeneration, comparatively few studies have investigated gross morphological and histological features of regenerated fins and limbs. Likewise, rather little is known about how fin regeneration compares morphologically to salamander limb regeneration. In this study, we investigated the morphology and histology of regenerated fins in all three modern lungfish families. Data from histological serial sections, 3D reconstructions, and x-ray microtomography scans were analyzed to assess morphological features, quality and pathologies in lungfish fin regenerates. We found several anomalies resulting from imperfect regeneration in regenerated fins in all investigated lungfish species, including fusion of skeletal elements, additional or fewer elements, and distal branching. The similarity of patterns in regeneration abnormalities compared to salamander limb regeneration lends further support to the hypothesis that high regenerative capacities are plesiomorphic for sarcopterygians.

NRG1/ErbB signalling controls the dialogue between macrophages and neural crest-derived cells during zebrafish fin regeneration

Fish species, such as zebrafish (Danio rerio), can regenerate their appendages after amputation through the formation of a heterogeneous cellular structure named blastema. Here, by combining live imaging of triple transgenic zebrafish embryos and single-cell RNA sequencing we established a detailed cell atlas of the regenerating caudal fin in zebrafish larvae. We confirmed the presence of macrophage subsets that govern zebrafish fin regeneration, and identified a foxd3-positive cell population within the regenerating fin. Genetic depletion of these foxd3-positive neural crest-derived cells (NCdC) showed that they are involved in blastema formation and caudal fin regeneration. Finally, chemical inhibition and transcriptomic analysis demonstrated that these foxd3-positive cells regulate macrophage recruitment and polarization through the NRG1/ErbB pathway. Here, we show the diversity of the cells required for blastema formation, identify a discrete foxd3-positive NCdC population, and reveal the critical function of the NRG1/ErbB pathway in controlling the dialogue between macrophages and NCdC.

Characterization of the Zebrafish Cell Landscape at Single-Cell Resolution

Zebrafish have been found to be a premier model organism in biological and regeneration research. However, the comprehensive cell compositions and molecular dynamics during tissue regeneration in zebrafish remain poorly understood. Here, we utilized Microwell-seq to analyze more than 250,000 single cells covering major zebrafish cell types and constructed a systematic zebrafish cell landscape. We revealed single-cell compositions for 18 zebrafish tissue types covering both embryo and adult stages. Single-cell mapping of caudal fin regeneration revealed a unique characteristic of blastema population and key genetic regulation involved in zebrafish tissue repair. Overall, our single-cell datasets demonstrate the utility of zebrafish cell landscape resources in various fields of biological research.

An early Shh-H2O2 feedback loop controls the progression of the regenerative program during adult zebrafish fin regeneration

Reactive oxygen species (ROS), originally classified as toxic molecules, have attracted increasing interest given their actions in cell signaling. Among these molecules, Hydrogen peroxide (H2O2) is the major ROS produced by cells and acts as a second messenger to modify redox-sensitive proteins or lipids. After amputation, tight spatiotemporal regulation of ROS is required first for wound healing and later to initiate the regenerative program. However, the mechanisms carrying out this sustained ROS production and their integration with signaling pathways are still poorly understood. We focused on the early dialog between H2O2 and Sonic Hedgehog (Shh) during fin regeneration. We demonstrate that H2O2 controls Shh expression and that Shh in turn regulates the H2O2 level via a canonical pathway. Moreover, this tightly controlled feedback loop changes during the successive phases of the regenerative program. Dysregulation of the Hedgehog pathway has been implicated in several developmental syndromes, diabetes and cancer. These data support the existence of a very early feedback loop between Shh and H2O2 that might be more generally involved in various physiological or pathological processes. These new findings pave the way to improve regenerative processes, particularly in vertebrates.

The roles of NADPH oxidases during adult zebrafish fin regeneration

Sustained elevated levels of reactive oxygen species (ROS) have been shown to be essential for whole body, appendage and organ regeneration in various organisms, including planarians, Hydra, zebrafish, axolotl, Xenopus, geckos and mice. In the majority of cases these roles have been shown via the use of NADPH oxidase pharmacological inhibitors, which generally target all NAPDH oxidases (NOXes). To identify the specific NOX or NOXes essential for ROS production during adult fin regeneration in zebrafish, we generated nox mutants for duox, nox5 and cyba (a key subunit of NOXes 1-4). We also crossed these mutant lines to a transgenic line ubiquitously expressing HyPer, which permits the measurement of ROS levels in adult zebrafish fins. Using this approach, we found that homozygous duox mutants have significantly attenuated ROS levels following fin amputation, and this correlated with a significantly diminished rate of fin regeneration. While the other nox homozygous mutants (nox5 and cyba) showed less of an effect on ROS levels or adult fin regeneration, duox/cyba double mutants showed a more diminished rate of fin regeneration than duox mutants alone, suggesting that Nox1-4 do play a role during regeneration, but one that is secondary to that of Duox. This work also serendipitously found that ROS levels in amputated adult zebrafish fins oscillate during the day with a circadian rhythm.

Understanding the complexity of Epimorphic Regeneration in zebrafish: A Transcriptomic and Proteomic approach.

Genomic and Proteomic changes play a crucial role in perpetuating regeneration of complex tissues through differentiation and growth. The complex Epimorphic regeneration of zebrafish caudal fin tissue is hasty and absolute. This study was executed to understand the role of various genes/proteins involved in the regeneration of zebrafish caudal fin tissue through differential expression analysis. High throughput transcriptomics analysis involving Next Generation Sequencing approach and iTRAQ based quantitative proteomics analyses were performed on the regenerating tissue samples for various regenerating time points. Based on our study 1408 genes and 661 proteins were found differentially regulated in the regenerating caudal fin tissue for having at least 1-log fold change in their expression at 12hpa, 1, 2, 3 and 7dpa stages against control non-regenerating tissue. Interleukin, SLC, PRMT, HOX, neurotransmitter and several novel genes were found to be associated with regeneration for its differential regulation during the mechanism. Based on the network and pathway analysis the differentially regulated genes and proteins were found allied with activation of cell proliferation, cell viability, cell survival & cell movement and inactivation of organismal death, morbidity, necrosis, death of embryo & cell death. Network pathways such as Cancer & development disorder, Cell signaling molecular transport, organismal injury & abnormalities and Cellular development, growth & proliferation were found most significantly associated with the zebrafish caudal fin regeneration mechanism. This study has mapped a detailed insight of the genes/proteins expression associated with the epimorphic regeneration more profoundly.