Document Type
Article
Publication Date
5-26-2022
Publication Title
eLife
Abstract
De novo limb regeneration after amputation is restricted in mammals to the distal digit tip. Central to this regenerative process is the blastema, a heterogeneous population of lineage-restricted, dedifferentiated cells that ultimately orchestrates regeneration of the amputated bone and surrounding soft tissue. To investigate skeletal regeneration, we made use of spatial transcriptomics to characterize the transcriptional profile specifically within the blastema. Using this technique, we generated a gene signature with high specificity for the blastema in both our spatial data, as well as other previously published single-cell RNA-sequencing transcriptomic studies. To elucidate potential mechanisms distinguishing regenerative from non-regenerative healing, we applied spatial transcriptomics to an aging model. Consistent with other forms of repair, our digit amputation mouse model showed a significant impairment in regeneration in aged mice. Contrasting young and aged mice, spatial analysis revealed a metabolic shift in aged blastema associated with an increased bioenergetic requirement. This enhanced metabolic turnover was associated with increased hypoxia and angiogenic signaling, leading to excessive vascularization and altered regenerated bone architecture in aged mice. Administration of the metabolite oxaloacetate decreased the oxygen consumption rate of the aged blastema and increased WNT signaling, leading to enhanced in vivo bone regeneration. Thus, targeting cell metabolism may be a promising strategy to mitigate aging-induced declines in tissue regeneration.
PubMed ID
35616636
Volume
11
Creative Commons License
This work is licensed under a Creative Commons Attribution 4.0 International License.
Recommended Citation
Tower, Robert J.; Busse, Emily; Jaramillo, Josue; Lacey, Michelle; Hoffseth, Kevin; Guntur, Anyonya R.; Simkin, Jennifer; and Sammarco, Mimi C., "Spatial Transcriptomics Reveals Metabolic Changes Underly Age-dependent Declines In Digit Regeneration" (2022). School of Medicine Faculty Publications. 1020.
https://digitalscholar.lsuhsc.edu/som_facpubs/1020
10.7554/eLife.71542