GH Is a Component of SASP in Aging Tissue

Deficient GH signaling results in lifespan extension in murine and human models, while patients with uncontrolled acromegaly and transgenic mice overexpressing GH have a shorter lifespan. Colon polyp development increases with age, and also with GH excess in acromegaly. Aging is characterized by senescent cell accumulation with p53/p21 or p16 upregulation as well as cell cycle arrest and expression of a senescence-associated secretory phenotype (SASP). Senescence is reinforced by the SASP, which comprises pro-inflammatory cytokines, chemokines, growth modulators, angiogenic factors, and matrix metalloproteinases. SASP contributes to pro-aging phenotypes, and depletion or removal of senescent cells increases lifespan by partially protecting from age-related pathologies. Senescence, triggered by genotoxic insult with DNA damage, can be reversed by p53 inactivation; senescent cells with low p53 and unrepaired DNA damage can then re-enter the cell cycle (Beausejour et al, EMBO 2003), potentially resulting in chromosomal instability. We showed GH induction in non-pituitary senescent cells leading to suppressed p53/p21 (Chesnokova PNAS 2013). We now show that, in senescent human colon cells (hNCC) and in 3-dimensional human intestinal organoids, non-pituitary GH (npGH) is a component of SASP. In response to DNA damage, npGH is expressed and secreted locally as measured by RT-PCR, WB, and ELISA. High autocrine/paracrine GH further exacerbate DNA damage and reverses senescent in colon cells, enabling them to re-enter the cell cycle, as evidenced by p53 downregulation and increased Ki67 expression. Senescent colon cells expressing high intracellular GH form colonies in soft agar, indicative of cell transformation and proliferation, while GH deletion by shRNA results in Ki67 downregulation and decreased colony formation and size. The SASP protein CXCL1, a chemo-attractant that also functions to eliminate senescent cells, dose-dependently activates GH in hNCC and in intestinal organoids. GH, in turn, suppresses CXCL1 expression. Consistent with these findings, colon CXCL1 was induced in GHRKO mice, and also in hNCC with abrogated GH signaling by shRNA. Taken together with our finding that GH accumulates in aging normal human colon tissue and co-localizes in cells expressing senescence-associated β-galactosidase, these results suggest that GH, as a SASP component, initiates senescent cell proliferation and transformation. By inhibiting CXCL1, GH also functions to attenuate immune-mediated senescent cell elimination that protects aging tissue from deleterious effects of SASP. These mechanisms may underly an initial step in age-associated epithelial polyp development.