RNase L represses hair follicle regeneration through altered innate immune signaling
Charles S. Kirby, … , Robert H. Silverman, Luis A. Garza
Charles S. Kirby, … , Robert H. Silverman, Luis A. Garza
Published February 4, 2025
Citation Information: J Clin Invest. 2025;135(6):e172595. https://doi.org/10.1172/JCI172595.
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Research Article Dermatology Inflammation Article has an altmetric score of 3

RNase L represses hair follicle regeneration through altered innate immune signaling

Abstract

Mammalian injury responses are predominantly characterized by fibrosis and scarring rather than functional regeneration. This limited regenerative capacity in mammals could reflect a loss of proregeneration programs or active suppression by genes functioning akin to tumor suppressors. To uncover programs governing regeneration in mammals, we screened transcripts in human participants following laser rejuvenation treatment and compared them with mice with enhanced wound-induced hair neogenesis (WIHN), a rare example of mammalian organogenesis. We found that Rnasel–/– mice exhibit an increased regenerative capacity, with elevated WIHN through enhanced IL-36α. Consistent with RNase L’s known role to stimulate caspase-1, we found that pharmacologic inhibition of caspases promoted regeneration in an IL-36–dependent manner in multiple epithelial tissues. We identified a negative feedback loop, where RNase L–activated caspase-1 restrains the proregenerative dsRNA-TLR3 signaling cascade through the cleavage of toll-like adaptor protein TRIF. Through integrated single-cell RNA-seq and spatial transcriptomic profiling, we confirmed OAS & IL-36 genes to be highly expressed at the site of wounding and elevated in Rnasel–/– mouse wounds. This work suggests that RNase L functions as a regeneration repressor gene, in a functional trade off that tempers immune hyperactivation during viral infection at the cost of inhibiting regeneration.

Authors

Charles S. Kirby, Nasif Islam, Eric Wier, Martin P. Alphonse, Evan Sweren, Gaofeng Wang, Haiyun Liu, Dongwon Kim, Ang Li, Sam S. Lee, Andrew M. Overmiller, Yingchao Xue, Sashank Reddy, Nathan K. Archer, Lloyd S. Miller, Jianshi Yu, Weiliang Huang, Jace W. Jones, Sooah Kim, Maureen A. Kane, Robert H. Silverman, Luis A. Garza

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Figure 5

Caspases, known downstream mediators of RNase L, restrain IL-36 release and regeneration.

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Caspases, known downstream mediators of RNase L, restrain IL-36 release ...
(A) dsRNA activation of RNase L stimulates NLRP3 & Caspase-1 illustration. (B) QV-D-OPh induces elevation of neutrophils in unwounded skin shown by t-SNE analysis and quantification (n = 3, 2-way ANOVA, P < 0.05) (C) QV-D-OPh for 48 hours induces Il36a mRNA in cultured mouse keratinocytes (n = 6, 1-way ANOVA, ****P < 0.0001, **P = 0.0012). (D) QV-D-OPh induces IL-36α protein without inhibition of the receptor antagonist IL-36RN in whole-cell lysates of MEKs (P < 0.05 by 2-way ANOVA, n = 3). (E) siRNA knockdown of caspase-1 in mouse keratinocytes leads to elevated secretion of IL-36α. (F) Schematic of the pan-caspase inhibitor Q-VD-OPh intraperitoneal injection (1.33 mM) of mice wounded to measure WIHN. IP injections were done 1 day before and 10 days after wounding C57BL/6J mice with 1.25 × 1.25cm2 square wounds. Mice were then sacrificed at wound-day 21 to measure WIHN. (G) QV-D-OPh promoted WIHN compared with vehicle, as shown by CSLM and AP staining (n = 6 versus 7, 2-tailed unpaired t test, P < 0.0001). (H) Histology of G comparing vehicle to Q-VD-OPh–treated mouse skin sections. Neogenic hair follicles (purple) are shown aggregated at the center of the scar. Scale bar: 100 μm. (I) Immunostaining of reepithelialized wounded tissue shows elevated IL-36α in Q-VD-OPh–treated mice. (J) Il36r–/– mice do not respond to Q-VD-OPh treatment and are unable to regenerate hair follicles after wounding (n = 7, 2-tailed unpaired t test). (K) Histology of WIHN scars from J. Scale bar: 200 μm.