regeneration factors expressed on myeloid expression in macrophage-like cells is required for tail regeneration in Xenopus laevis tadpoles.

Xenopus laevis tadpoles can regenerate whole tails after amputation. We have previously reported that interleukin 11 (il11) is required for tail regeneration. In this study, we have screened for genes that support tail regeneration under Il11 signaling in a certain cell type and have identified the previously uncharacterized genes Xetrov90002578m.L and Xetrov90002579m.S [referred to hereafter as regeneration factors expressed on myeloid.L (rfem.L) and rfem.S]. Knockdown (KD) of rfem.L and rfem.S causes defects of tail regeneration, indicating that rfem.L and/or rfem.S are required for tail regeneration. Single-cell RNA sequencing (scRNA-seq) revealed that rfem.L and rfem.S are expressed in a subset of leukocytes with a macrophage-like gene expression profile. KD of colony-stimulating factor 1 (csf1), which is essential for macrophage differentiation and survival, reduced rfem.L and rfem.S expression levels and the number of rfem.L- and rfem.S-expressing cells in the regeneration bud. Furthermore, forced expression of rfem.L under control of the mpeg1 promoter, which drives rfem.L in macrophage-like cells, rescues rfem.L and rfem.S KD-induced tail regeneration defects. Our findings suggest that rfem.L or rfem.S expression in macrophage-like cells is required for tail regeneration.

Egress of mature murine regulatory T cells from the thymus requires RelA.

The mechanism of egress of mature regulatory T cells (Tregs) from the thymus to the periphery remains enigmatic, as does the nature of those factors expressed in the thymic environment. In this study, we examined the fate of thymic Tregs in TNF-α/RelA double-knockout (TA-KO) mice, because TA-KO mice retain a Treg population in the thymus but have only a small Treg population at the periphery. Transplantation of whole TA-KO thymus to under the kidney capsule of Rag1-null mice failed to induce the production of donor-derived splenic Tregs expressing neuropilin-1, which is reported to be a marker of naturally occurring Tregs, indicating that TA-KO thymic Tregs either do not leave the thymus or are lost at the periphery. We next transplanted enriched TA-KO thymic Tregs to the peripheries of TA-KO mice and traced mouse survival. Transplantation of TA-KO thymic Tregs rescued the lethality in TA-KO mice, demonstrating that TA-KO thymic Tregs remained functional at the periphery. The TA-KO thymic Treg population had highly demethylated CpG motifs in the foxp3 locus, indicating that the cells were arrested at a late mature stage. Also, the population included a large subpopulation of Tregs expressing IL-7Rα, which is a possible marker of late-stage mature Tregs. Finally, TA-KO fetal liver chimeric mice developed a neuropilin-1(+) splenic Treg population from TA-KO cells, suggesting that Treg arrest was caused by a lack of RelA in the thymic environment. Taken together, these results suggest that egress of mature Tregs from the thymus depends on RelA in the thymic environment.

NF-κB RELA-deficient bone marrow macrophages fail to support bone formation and to maintain the hematopoietic niche after lethal irradiation and stem cell transplantation.

Bone remodeling and hematopoiesis are interrelated and bone marrow (BM) macrophages are considered to be important for both bone remodeling and maintenance of the hematopoietic niche. We found that NF-κB Rela-deficient chimeric mice, generated by transplanting Rela (-/-) fetal liver cells into lethally irradiated hosts, developed severe osteopenia, reduced lymphopoiesis and enhanced mobilization of hematopoietic stem and progenitor cells when BM cells were completely substituted by Rela-deficient cells. Rela (-/-) hematopoietic stem cells from fetal liver had normal hematopoietic ability, but those harvested from the BM of osteopenic Rela (-/-) chimeric mice had reduced repopulation ability, indicating impairment of the microenvironment for the hematopoietic niche. Osteopenia in Rela (-/-) chimeric mice was due to reduced bone formation, even though osteoblasts differentiated from host cells. This finding indicates impaired functional coupling between osteoblasts and hematopoietic stem cell-derived cells. Rela-deficient BM macrophages exhibited an aberrant inflammatory phenotype, and transplantation with wild-type F4/80(+) BM macrophages recovered bone formation and ameliorated lymphopoiesis in Rela (-/-) chimeric mice. Therefore, RELA in F4/80(+) macrophages is important both for bone homeostasis and for maintaining the hematopoietic niche after lethal irradiation and hematopoietic stem cell transplantation.

Suppression of the immune response potentiates tadpole tail regeneration during the refractory period.

Regenerative ability varies depending on animal species and developmental stage, but the factors that determine this variability remain unclear. Although Xenopus laevis tadpole tails possess high regenerative ability, this is transiently lost during the ;refractory period'. Here, we show that tail amputation evokes different immune responses in wound tail stumps between the ;refractory' and ;regeneration' periods: there was delayed or prolonged expression of some immune-related genes in the refractory period, whereas there was no obvious or transient expression of other immune-related genes in the regeneration periods. In addition, immune suppression induced by either immunosuppressant treatment or immune cell depletion by knockdown of PU.1 significantly restored regenerative ability during the refractory period. These findings indicate that immune responses have a crucial role in determining regenerative ability in Xenopus tadpole tails.

Early fin primordia of zebrafish larvae regenerate by a similar growth control mechanism with adult regeneration.

Some vertebrate species, including urodele amphibians and teleost fish, have the remarkable ability of regenerating lost body parts. Regeneration studies have been focused on adult tissues, because it is unclear whether or not the repairs of injured tissues during early developmental stages have the same molecular base as that of adult regeneration. Here, we present evidence that a similar cellular and molecular mechanism to adult regeneration operates in the repair process of early zebrafish fin primordia, which are composed of epithelial and mesenchymal cells. We show that larval fin repair occurs through the formation of wound epithelium and blastema-like proliferating cells. Cell proliferation is first induced in the distal-most region and propagates to more proximal regions, as in adult regeneration. We also show that fibroblast growth factor signaling helps induce cell division. Our results suggest that the regeneration machinery directing cell proliferation in response to injury may exist from the early developmental stages.