The skin confers biophysical and immunological protection through a complex cellular network established early in embryonic development. We profiled the transcriptomes of more than 500,000 single cells from developing human fetal skin, healthy adult skin, and adult skin with atopic dermatitis and psoriasis. We leveraged these datasets to compare cell states across development, homeostasis, and disease. Our analysis revealed an enrichment of innate immune cells in skin during the first trimester and clonal expansion of disease-associated lymphocytes in atopic dermatitis and psoriasis. We uncovered and validated in situ a reemergence of prenatal vascular endothelial cell and macrophage cellular programs in atopic dermatitis and psoriasis lesional skin. These data illustrate the dynamism of cutaneous immunity and provide opportunities for targeting pathological developmental programs in inflammatory skin diseases.
Cell competition where ‘loser’ cells are eliminated by neighbors with higher fitness is a widespread phenomenon in development. However, a growing body of evidence argues cells with somatic mutations compete with their wild type counterparts in the earliest stages of cancer development. Recent studies have begun to shed light on the molecular and cellular mechanisms that alter the competitiveness of cells carrying somatic mutations in adult tissues. Cells with a ‘winner’ phenotype create clones which may expand into extensive fields of mutant cells within normal appearing epithelium, favoring the accumulation of further genetic alterations and the evolution of cancer. Here we focus on how mutations which disrupt the Notch signaling pathway confer a ‘super competitor’ status on cells in squamous epithelia and consider the broader implications for cancer evolution.
The dynamics of a genetically labeled cell population may be used to infer the laws of cell division in mammalian tissue. Recently, we showed that in mouse tail skin, where proliferating cells are confined to a two-dimensional layer, cells proliferate and differentiate according to a simple stochastic model of cell division involving just one type of proliferating cell that may divide both symmetrically and asymmetrically. Curiously, these simple rules provide excellent predictions of the cell population dynamics without having to address the cells' spatial distribution. Yet, if the spatial behavior of cells is addressed by allowing cells to diffuse at random, one deduces that density fluctuations destroy tissue confluence, implying some hidden degree of spatial regulation of cell division. To infer the mechanism of spatial regulation, we consider a two-dimensional model of cell fate that preserves the overall population dynamics. By identifying the resulting behavior with a three-species variation of the voter model, we predict that proliferating cells in the basal layer should cluster. Analysis of empirical correlations of cells stained for proliferation activity confirms that the expected clustering behavior is indeed seen in nature. As well as explaining how cells maintain a uniform two-dimensional density, these findings present an interesting experimental example of voter-model statistics in biology.
In the embryonic neural plate, a subset of precursor cells with neurogenic potential differentiates into neurons. This process of primary neurogenesis requires both the specification of cells for neural differentiation, regulated by Notch signaling, and the activity of neurogenic transcription factors such as neurogenin and NeuroD which drive the program of neural gene expression. Here we study the role of Hes6, a member of the hairy enhancer of split family of transcription factors, in primary neurogenesis in Xenopus embryos. Hes6 is an atypical Hes gene in that it is not regulated by Notch signaling and promotes neural differentiation in mouse cell culture models. We show that depletion of Xenopus Hes6 (Xhes6) by morpholino antisense oligonucleotides results in a failure of neural differentiation, a phenotype rescued by both wild type Xhes6 and a Xhes6 mutant unable to bind DNA. However, an Xhes6 mutant that lacks the ability to bind Groucho/TLE transcriptional co-regulators is only partly able to rescue the phenotype. Further analysis reveals that Xhes6 is essential for the induction of neurons by both neurogenin and NeuroD, acting via at least two distinct mechanisms, the inhibition of antineurogenic Xhairy proteins and by interaction with Groucho/TLE family proteins. We conclude Xhes6 is essential for neurogenesis in vivo, acting via multiple mechanisms to relieve inhibition of proneural transcription factor activity within the neural plate.
Hes6 is a basic helix-loop-helix transcription factor homologous to Drosophila Enhancer of Split (EoS) proteins. It is known to promote neural differentiation and to bind to Hes1, a related protein that is part of the Notch signalling pathway, affecting Hes1-regulated transcription. We show that Hes6 is expressed in the murine embryonic myotome and is induced on C2C12 myoblast differentiation in vitro. Hes6 binds DNA containing the Enhancer of Split E box (ESE) motif, the preferred binding site of Drosophila EoS proteins, and represses transcription of an ESE box reporter. When overexpressed in C2C12 cells, Hes6 impairs normal differentiation, causing a decrease in the induction of the cyclin-dependent kinase inhibitor, p21Cip1, and an increase in the number of cells that can be recruited back into the cell cycle after differentiation in culture. In Xenopus embryos, Hes6 is co-expressed with MyoD in early myogenic development. Microinjection of Hes6 RNA in vivo in Xenopus embryos results in an expansion of the myotome, but suppression of terminal muscle differentiation and disruption of somite formation at the tailbud stage. Analysis of Hes6 mutants indicates that the DNA-binding activity of Hes6 is not essential for its myogenic phenotype, but that protein-protein interactions are. Thus, we demonstrate a novel role for Hes6 in multiple stages of muscle formation.
Human keratinocytes express several adhesive receptors of the integrin family. Expression is normally confined to the basal (proliferative) layer of keratinocytes, both in mature epidermis and during development. Altered expression patterns are observed during wound healing, in psoriasis and in squamous cell carcinomas. Keratinocyte integrins are subject to both transcriptional and post-translational regulation and ligand binding ability can be modulated independently of expression. Studies with cultured keratinocytes suggest a variety of functions for the receptors: adhesion to extracellular matrix proteins, intercellular adhesion, stratification, lateral migration and the regulation of terminal differentiation. Three distinct subpopulations of basal keratinocytes, with characteristics of stem cells, transit amplifying cells and cells committed to differentiate, can be distinguished on the basis of differences in integrin expression and function.
Abstract HPV-positive (HPV+) head and neck squamous cell carcinoma (HNSCC) tumors typically have p53 loss due to the activity of the human papillomavirus (HPV)-encoded E6 protein and the E6-associated protein (HPVE6-AP) which mediate the degradation of wild-type (WT) p53 (p53α). The loss of p53 is thought to be a major contributor to the pathogenesis of HPV+ HNSCC, which comprise approximately 35% of all HNSCC. Currently, standard care for HPV+HNSCC includes radiation and chemotherapy. However long-term toxicity related to these treatments is a concern, and there is a need for newer therapeutic strategies. Previously, we reported that two alternatively spliced, functional truncated isoforms of p53 (p53β and p53γ, comprising of exons 1 to 9β or 9γ, respectively) are degraded by nonsense-mediated decay (NMD), a regulator of aberrant mRNA stability. Here, using HPV+HNSCC cell line models, we show that NMD inhibition rescues p53β/γ isoforms and activates p53 pathway. Furthermore, we show that p53β/γ isoforms are more stable compared to p53α in these cells, with reduced vulnerabililty to HPVE6-AP- mediated degradation, and that p53β/γ isoforms contribute to increased expression of p53 transcriptional targets p21 and PUMA following NMD inhibition. Consistent with p53 pathway activation, NMD inhibition enhanced radiosensitivity of HNSCC cells. NMD inhibition attenuated colony forming ability and disrupted cell cycle progression. To evaluate the therapeutic implications of NMD inhibition, we assessed the in vivo growth of HPV+ UMSCC47 tumors. Nude mice were injected with UMSCC47 cells either subcutaneously or orthotopically in the tongue and randomized to receive vehicle or with an NMD inhibitor. In both tumor models, we observed a significant reduction in tumor volume with NMD inhibition as compared to the vehicle-treated animals. To investigate whether NMD inhibition induced the expression of p53β/γ isoforms and activated the p53 pathway in vivo, we collected tumor tissues from animals and evaluated expression of p53 isoforms and transcriptional targets by RT-PCR. We observed increased expression of p53γ, p21, GADD45A and PUMA mRNAs in NMD inhibitor treated UMSCC47 tumors, compared to their respective vehicle treated controls. These results identify NMD inhibition as a novel therapeutic strategy for restoration of p53 function in major subgroups of p53-deficient HPV+ HNSCC tumors. Citation Format: Jayanthi Gudikote, Tina Cascone, Alissa Poteete, Piyada Sitthideatphaiboon, Sonia Patel, Yan Yang, Fahao Zhang, Lerong Li, Li Shen, Monique Nilsson, Phillip Jones, Jing Wang, Jean-Christophe Bourdon, Faye M. Johnson, John V. Heymach. Targeting nonsense-mediated decay restores p53 function in HPV-associated head and neck cancers [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 5733.
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