Your search keyword '"Eenjes, Evelien"' showing total 3 results

1. Epigenetic memory of radiotherapy in dermal fibroblasts impairs wound repair capacity in cancer survivors.

Author

Bian, Xiaowei, Piipponen, Minna, Liu, Zhuang, Luo, Lihua, Geara, Jennifer, Chen, Yongjian, Sangsuwan, Traimate, Maselli, Monica, Diaz, Candice, Bain, Connor A., Eenjes, Evelien, Genander, Maria, Crichton, Michael, Cash, Jenna L., Archambault, Louis, Haghdoost, Siamak, Fradette, Julie, Sommar, Pehr, Halle, Martin, and Xu Landén, Ning

Subjects

WOUND healing, CANCER survivors, LONG-term memory, BREAST cancer, FIBROBLASTS, SKIN regeneration

Abstract

Radiotherapy (RT), a common cancer treatment, unintentionally harms surrounding tissues, including the skin, and hinders wound healing years after treatment. This study aims to understand the mechanisms behind these late-onset adverse effects. We compare skin biopsies from previously irradiated (RT+) and non-irradiated (RT−) sites in breast cancer survivors who underwent RT years ago. Here we show that the RT+ skin has compromised healing capacity and fibroblast functions. Using ATAC-seq, we discover altered chromatin landscapes in RT+ fibroblasts, with THBS1 identified as a crucial epigenetically primed wound repair-related gene. This is further confirmed by single-cell RNA-sequencing and spatial transcriptomic analysis of human wounds. Notably, fibroblasts in both murine and human post-radiation wound models show heightened and sustained THBS1 expression, impairing fibroblast motility and contractility. Treatment with anti-THBS1 antibodies promotes ex vivo wound closure in RT+ skin from breast cancer survivors. Our findings suggest that fibroblasts retain a long-term radiation memory in the form of epigenetic changes. Targeting this maladaptive epigenetic memory could mitigate RT's late-onset adverse effects, improving the quality of life for cancer survivors. The molecular mechanisms underlying the late-onset adverse effects of radiotherapy remain to be explored. Here, the authors observe compromised wound healing capacity in irradiated skin from breast cancer survivors and highlight THBS1 as a key epigenetically primed wound repair-related gene. [ABSTRACT FROM AUTHOR]

Published

2024

2. Distinct roles for SOX2 and SOX21 in differentiation, distribution and maturation of pulmonary neuroendocrine cells.

Author

Eenjes, Evelien, Benthem, Floor, Boerema-de Munck, Anne, Buscop-van Kempen, Marjon, Tibboel, Dick, and Rottier, Robbert J.

Abstract

Pulmonary neuroendocrine (NE) cells represent a small population in the airway epithelium, but despite this, hyperplasia of NE cells is associated with several lung diseases, such as congenital diaphragmatic hernia and bronchopulmonary dysplasia. The molecular mechanisms causing the development of NE cell hyperplasia remains poorly understood. Previously, we showed that the SOX21 modulates the SOX2-initiated differentiation of epithelial cells in the airways. Here, we show that precursor NE cells start to develop in the SOX2 + SOX21 + airway region and that SOX21 suppresses the differentiation of airway progenitors to precursor NE cells. During development, clusters of NE cells start to form and NE cells mature by expressing neuropeptide proteins, such as CGRP. Deficiency in SOX2 resulted in decreased clustering, while deficiency in SOX21 increased both the numbers of NE ASCL1 + precursor cells early in development, and the number of mature cell clusters at E18.5. In addition, at the end of gestation (E18.5), a number of NE cells in Sox2 heterozygous mice, did not yet express CGRP suggesting a delay in maturation. In conclusion, SOX2 and SOX21 function in the initiation, migration and maturation of NE cells. [ABSTRACT FROM AUTHOR]

Published

2023

3. Generation of a biotinylatable Sox2 mouse model to identify Sox2 complexes in vivo.

Author

Schilders, Kim, Eenjes, Evelien, Edel, Gabriëla, de Munck, Anne Boerema, van Kempen, Marjon Buscop, Demmers, Jeroen, Wijnen, René, Tibboel, Dick, and Rottier, Robbert J.

Abstract

Sox2 is a Sry-box containing family member of related transcription factors sharing homology in their DNA binding domain. Sox2 is important during different stages of development, and previously we showed that Sox2 plays an important role in branching morphogenesis and epithelial cell differentiation in lung development. The transcriptional activity of Sox2 depends on its interaction with other proteins, leading to 'complex-specific' DNA binding and transcriptional regulation. In this study, we generated a mouse model containing a biotinylatable-tag targeted at the translational start site of the endogenous Sox2 gene (bioSox2). This tag was biotinylated by the bacterial birA protein and the resulting bioSox2 protein was used to identify associating partners of Sox2 at different phases of lung development in vivo (the Sox2 interactome). Homozygous bioSox2 mice are viable and fertile irrespective of the biotinylation of the bio tag, indicating that the bioSox2 gene is normally expressed and the protein is functional in all tissues. This suggests that partners of Sox2 are most likely able to associate with the bioSox2 protein. BioSox2 complexes were isolated with high affinity using streptavidin beads and analysed by MALDI-ToF mass spectrometry analysis. Several of the identified binding partners are already shown to have a respiratory phenotype. Two of these partners, Wdr5 and Tcf3, were validated to confirm their association in Sox2 complexes. This bioSox2 mouse model will be a valuable tool for isolating in vivo Sox2 complexes from different tissues. [ABSTRACT FROM AUTHOR]

Published

2018