Florie A Mar scite author profile

Autophagy inhibitors are currently being evaluated in clinical trials for the treatment of diverse cancers, largely due to their ability to impede tumor cell survival and metabolic adaptation. More recently, there is growing interest in whether and how modulating autophagy in the host stroma influences tumorigenesis. Fibroblasts play prominent roles in cancer initiation and progression, including depositing type 1 collagen and other extracellular matrix (ECM) components, thereby stiffening the surrounding tissue to enhance tumor cell proliferation and survival, as well as secreting cytokines that modulate angiogenesis and the immune microenvironment. This constellation of phenotypes, pathologically termed desmoplasia, heralds poor prognosis and reduces patient survival. Using mouse mammary cancer models and syngeneic transplantation assays, we demonstrate that genetic ablation of stromal fibroblast autophagy significantly impedes fundamental elements of the stromal desmoplastic response, including collagen and proinflammatory cytokine secretion, extracellular matrix stiffening, and neoangiogenesis. As a result, autophagy in stromal fibroblasts is required for mammary tumor growth in vivo, even when the cancer cells themselves remain autophagy-competent . We propose the efficacy of autophagy inhibition is shaped by this ability of host stromal fibroblast autophagy to support tumor desmoplasia.

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Autophagy-independent senescence and genome instability driven by targeted telomere dysfunction

Mar¹,

Debnath²,

Stohr³

2015

Autophagy

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Abbreviations: ACD/Tpp1, adrenocortical dysplasia homolog (mouse); ATG5, autophagy-related 5, ATG7, autophagy-related 7; B2M, b-2-microglobulin; HBSS, Hank's buffered salt solution; HMECs, human mammary epithelial cells; MEFs, mouse embryonic fibroblasts; MT-HsTER, mutant template-Homo sapiens template-containing RNA; MT-MmTER, mutant template-Mus musculus template-containing RNA; OIS, oncogene-induced senescence; RBBP8/CtIP, retinoblastoma binding protein 8; SA-b-Gal, senescence-associated b-galactosidase; SASP, senescence associated secretory phenotype; TDIS, telomere dysfunction-induced senescence; TERT, telomerase reverse transcriptase; TIFs, telomere dysfunction-induced foci.Telomere dysfunction plays a complex role in tumorigenesis. While dysfunctional telomeres can block the proliferation of incipient cancer clones by inducing replicative senescence, fusion of dysfunctional telomeres can drive genome instability and oncogenic genomic rearrangements. Therefore, it is important to define the regulatory pathways that guide these opposing effects. Recent work has shown that the autophagy pathway regulates both senescence and genome instability in various contexts. Here, we apply models of acute telomere dysfunction to determine whether autophagy modulates the resulting genome instability and senescence responses. While telomere dysfunction rapidly induces autophagic flux in human fibroblast cell lines, inhibition of the autophagy pathway does not have a significant impact upon the transition to senescence, in contrast to what has previously been reported for oncogene-induced senescence. Our results suggest that this difference may be explained by disparities in the development of the senescence-associated secretory phenotype. We also show that chromosome fusions induced by telomere dysfunction are comparable in autophagy-proficient and autophagy-deficient cells. Altogether, our results highlight the complexity of the senescence-autophagy interface and indicate that autophagy induction is unlikely to play a significant role in telomere dysfunction-driven senescence and chromosome fusions.

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Florie A Mar

Autophagy in stromal fibroblasts promotes tumor desmoplasia and mammary tumorigenesis

Autophagy-independent senescence and genome instability driven by targeted telomere dysfunction

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