Type IV collagen aggregates promote keratinocyte proliferation and formation of epidermal layer in human skin equivalents.

Type IV collagen isolated from lens capsule without enzymatic treatment is known to form a gel under physiological condition and influences cellular activities. In case of human keratinocytes, the suppression of proliferation on reconstituted type IV collagen gels was reported in monolayer culture. In this study, we examined effects of type IV collagen isolated from porcine lens capsule on epidermal formation in human skin equivalents (HSEs). Type IV collagen aggregates were prepared under the culture condition and the aggregates suppressed keratinocyte proliferation in monolayer culture as well as the culture on the gels. In HSEs, type IV collagen aggregates were reconstituted on the surface of contracted collagen gels containing human dermal fibroblasts and the keratinocytes were then cultured on the aggregates for 14 days. Interestingly, in HSEs with type IV collagen aggregates, the BrdU-positive keratinocytes were increased and the thickness of the epidermal layer was around twice than that of control culture. Epidermal differentiation markers were expressed in the upper layer of the epidermis and the defined deposition of human basement membrane components were increased at the dermal-epidermal junction. These results indicate that the type IV collagen aggregates stimulate the proliferation of basal keratinocytes and improve the stratification of epidermal layers in HSEs.

Dynamic stem cell selection safeguards the genomic integrity of the epidermis.

Maintaining genomic integrity and stability is crucial for life; yet, no tissue-driven mechanism that robustly safeguards the epithelial genome has been discovered. Epidermal stem cells (EpiSCs) continuously replenish the stratified layers of keratinocytes that protect organisms against various environmental stresses. To study the dynamics of DNA-damaged cells in tissues, we devised an in vivo fate tracing system for EpiSCs with DNA double-strand breaks (DSBs) and demonstrated that those cells exit from their niches. The clearance of EpiSCs with DSBs is caused by selective differentiation and delamination through the DNA damage response (DDR)-p53-Notch/p21 axis, with the downregulation of ITGB1. Moreover, concomitant enhancement of symmetric cell divisions of surrounding stem cells indicates that the selective elimination of cells with DSBs is coupled with the augmented clonal expansion of intact stem cells. These data collectively demonstrate that tissue autonomy through the dynamic coupling of cell-autonomous and non-cell-autonomous mechanisms coordinately maintains the genomic quality of the epidermis.

IGF-1R deficiency in human keratinocytes disrupts epidermal homeostasis and stem cell maintenance.

BACKGROUND: Epidermal stem cells (ESCs) are keratinocytes that reside in the basal layer of the epidermis and mediate epidermal homeostasis. Insulin-like growth factor 1 (IGF-1) signaling through its receptor (IGF-1R) has been identified as an important regulator in rodent skin development and differentiation. However, the role of IGF-1/IGF-1R signaling in human keratinocytes is not yet well understood. OBJECTIVE: This study aimed to clarify the role of IGF-1/IGF-1R signaling in human epidermal homeostasis. METHODS: IGF-1R specific knockout (KO) HaCaT keratinocytes were generated by CRISPR-Caspase-9-mediated non-homologous end joining frame-shift mutations. Further, the behavior of these keratinocytes in epidermal homeostasis was investigated using reconstructed epidermis and human skin equivalents. RESULTS: IGF-1R KO HaCaT keratinocytes were successfully established and produced thin epidermis in three-dimensional culture models. Keratin10-positive cells were frequently found in the basal layer of the reconstructed epidermis. CONCLUSIONS: IGF-1/IGF-1R signaling was demonstrated to play a key role in maintaining human epidermal homeostasis. This method provides a new framework to investigate gene function in human epidermal homeostasis.

Role of the hypoxia response pathway in lens formation during embryonic development of Xenopus laevis.

The RING finger ubiquitin ligase seven in absentia homolog 2 (Siah2) was identified in the R7 photoreceptor cells of Drosophila melanogaster, and it regulates the stability of prolyl hydroxylase domains (PHDs), with a concomitant effect on HIF-1α availability in the hypoxia response pathway. We previously reported that the hypoxia response pathway contributes to eye development during the embryonic development of Xenopus laevis. In this paper, the role of Siah2-mediated hypoxia response pathway in eye development of X. laevis embryos was further characterized. Xenopus Siah2 (xSiah2) mRNA was detected in lens tissue and xSiah2 overexpression caused a thickened lens placode, leading to loss of the optic lens. In embryos overexpressing xSiah2, lens marker gene transcription was reduced, suggesting that xSiah2 contributes to lens formation. xSiah2 overexpression decreased Xenopus PHD accumulation and increased Xenopus HIF-1α (xHIF-1α) accumulation. xHIF-1α degeneration with resveratrol restored the optical abnormality caused by xSiah2 overexpression, suggesting that the xSiah2-mediated hypoxia response pathway contributes to lens formation. Moreover, xSiah2 overexpression decreased endothelial-mesenchymal transition (EMT)-related Notch signaling-responsive genes transcription during the invasion of the lens placode. Our results suggest that the hypoxia response pathway plays an important role in the regulation of the EMT via the Notch signaling pathway during lens formation.

Isolation of Xenopus HIF-prolyl 4-hydroxylase and rescue of a small-eye phenotype caused by Siah2 over-expression.

Hypoxia is an important physiological condition during embryonic development. Hypoxia-inducible factor (HIF) is the mediator of hypoxic response of cells. The prolyl hydroxylase (PHD) of HIF plays a key role in stabilizing of HIF and the oxygen homeostasis of organisms. In this study, we isolated two PHD proteins, PHD45 and PHD28, and characterized them during the embryonic development of Xenopus laevis, which is an excellent model for embryonic development because of the ease of embryonic manipulation and the feasibility of transgenesis. Based on amino acid sequences, Xenopus PHD45 and PHD28 were homologous with human PHD2 and PHD3, respectively. In embryonic development, PHD45 expression was complementary to that of PHD28. xHIF-1alpha protein level was at a maximum around stage 20 when expression of PHD45 disappeared, while expression of PHD28 reached a maximum at stage 20, suggesting that PHD28 is inducible by HIF-1alpha. Recently, Siah2 was found to be an ubiquitin ligase of PHD proteins and to regulate degradation of PHD proteins. Over-expression of xSiah2 decreased PHD45 but not PHD28 and caused the small-eye phenotype of Xenopus. Additional over-expression of PHD47 rescued the abnormality caused by xSiah2, suggesting that the level of expression or activity of PHD proteins is important to the maintenance of homeostasis in embryonic development.