Tert-expressing cells contribute to salivary gland homeostasis and tissue regeneration after radiation therapy.
Li GuanVignesh ViswanathanYuyan JiangSivakamasundari VijayakumarHongbin CaoJunfei ZhaoDeana Rae Crystal ColburgPatrick NeuhöferYiru ZhangJinglong WangYu XuEyiwunmi E LaseindeRachel HildebrandMobeen RahmanRichard L FrockChristina KongPhilip A BeachySteven ArtandiQuynh-Thu LePublished in: Genes & development (2024)
Salivary gland homeostasis and regeneration after radiotherapy depend significantly on progenitor cells. However, the lineage of submandibular gland (SMG) progenitor cells remains less defined compared with other normal organs. Here, using a mouse strain expressing regulated CreERT2 recombinase from the endogenous Tert locus, we identify a distinct telomerase-expressing (Tert High ) cell population located in the ductal region of the adult SMG. These Tert High cells contribute to ductal cell generation during SMG homeostasis and to both ductal and acinar cell renewal 1 year after radiotherapy. Tert High cells maintain self-renewal capacity during in vitro culture, exhibit resistance to radiation damage, and demonstrate enhanced proliferative activity after radiation exposure. Similarly, primary human SMG cells with high Tert expression display enhanced cell survival after radiotherapy, and CRISPR-activated Tert in human SMG spheres increases proliferation after radiation. RNA sequencing reveals upregulation of "cell cycling" and "oxidative stress response" pathways in Tert High cells following radiation. Mechanistically, Tert appears to modulate cell survival through ROS levels in SMG spheres following radiation damage. Our findings highlight the significance of Tert High cells in salivary gland biology, providing insights into their response to radiotherapy and into their use as a potential target for enhancing salivary gland regeneration after radiotherapy.
Keyphrases
- induced apoptosis
- radiation therapy
- single cell
- cell cycle arrest
- early stage
- radiation induced
- stem cells
- oxidative stress
- endothelial cells
- signaling pathway
- cell therapy
- cell death
- endoplasmic reticulum stress
- squamous cell carcinoma
- dna damage
- transcription factor
- climate change
- high intensity
- pluripotent stem cells