Single-cell Transcriptome Analysis Identifies Senescent Osteocytes as Contributors to Bone Destruction in Breast Cancer Metastasis.
Jesús Delgado-CalleManish AdhikariJapneet KaurHayley SabolAric AnloagueSharmin KhanNoriyoshi KuriharaMarta Diaz-delCastilloChristina Møller AndreasenC Lowry BarnesJeffrey StamboughMichela PalmieriOlivia Reyes-CastroElena AmbroginiMaria AlmeidaCharles O'BrienIntawat NookaewPublished in: Research square (2024)
Breast cancer bone metastases increase fracture risk and are a major cause of morbidity and mortality among women. Upon colonization by tumor cells, the bone microenvironment undergoes profound reprogramming to support cancer progression that disrupts the balance between osteoclasts and osteoblasts, leading to bone lesions. Whether such reprogramming affects matrix-embedded osteocytes remains poorly understood. Here, we demonstrate that osteocytes in breast cancer bone metastasis develop premature senescence and a distinctive senescence-associated secretory phenotype (SASP) that favors bone destruction. Single-cell RNA sequencing identified osteocytes from mice with breast cancer bone metastasis enriched in senescence and SASP markers and pro-osteoclastogenic genes. Using multiplex in situ hybridization and AI-assisted analysis, we detected osteocytes with senescence-associated distension of satellites, telomere dysfunction, and p16 Ink4a expression in mice and patients with breast cancer bone metastasis. In vitro and ex vivo organ cultures showed that breast cancer cells promote osteocyte senescence and enhance their osteoclastogenic potential. Clearance of senescent cells with senolytics suppressed bone resorption and preserved bone mass in mice with breast cancer bone metastasis. These results demonstrate that osteocytes undergo pathological reprogramming by breast cancer cells and identify osteocyte senescence as an initiating event triggering bone destruction in breast cancer metastases.
Keyphrases
- bone mineral density
- bone loss
- single cell
- soft tissue
- bone regeneration
- dna damage
- endothelial cells
- postmenopausal women
- breast cancer cells
- high throughput
- stress induced
- type diabetes
- cell proliferation
- cell death
- dna methylation
- polycystic ovary syndrome
- skeletal muscle
- signaling pathway
- data analysis
- bioinformatics analysis