Transferred mitochondria accumulate reactive oxygen species, promoting proliferation.
Chelsea U KidwellJoseph R CasaliniSoorya PradeepSandra D SchererDaniel GreinerDefne BayikDionysios C WatsonGregory S OlsonJustin D LathiaJarrod S JohnsonJared RutterAlana L WelmThomas A ZangleMinna Roh-JohnsonPublished in: eLife (2023)
Recent studies reveal that lateral mitochondrial transfer, the movement of mitochondria from one cell to another, can affect cellular and tissue homeostasis 1,2 . Most of what we know about mitochondrial transfer stems from bulk cell studies and have led to the paradigm that functional transferred mitochondria restore bioenergetics and revitalize cellular functions to recipient cells with damaged or non-functional mitochondrial networks 3 . However, we show that mitochondrial transfer also occurs between cells with functioning endogenous mitochondrial networks, but the mechanisms underlying how transferred mitochondria can promote such sustained behavioral reprogramming remain unclear. We report that unexpectedly, transferred macrophage mitochondria are dysfunctional and accumulate reactive oxygen species in recipient cancer cells. We further discovered that reactive oxygen species accumulation activates ERK signaling, promoting cancer cell proliferation. Pro-tumorigenic macrophages exhibit fragmented mitochondrial networks, leading to higher rates of mitochondrial transfer to cancer cells. Finally, we observe that macrophage mitochondrial transfer promotes tumor cell proliferation in vivo . Collectively these results indicate that transferred macrophage mitochondria activate downstream signaling pathways in a ROS-dependent manner in cancer cells, and provide a model of how sustained behavioral reprogramming can be mediated by a relatively small amount of transferred mitochondria in vitro and in vivo .
Keyphrases
- reactive oxygen species
- oxidative stress
- cell proliferation
- cell death
- induced apoptosis
- signaling pathway
- single cell
- adipose tissue
- endoplasmic reticulum
- stem cells
- dna damage
- cell cycle
- squamous cell carcinoma
- minimally invasive
- mesenchymal stem cells
- young adults
- papillary thyroid
- genome wide
- lymph node metastasis