Abstract
Organismal ageing is associated with a decline in cellular and molecular functions. One of the hallmarks of ageing is stem cell exhaustion which occurs due to dynamic changes in the stem cell – niche microenvironment. Ageing affects stem cell potency impacting self-renewal and differentiation trajectories. Blood cell homeostasis in the hematopoietic system is tightly regulated by a fine balance between stemness and differentiation. Here, we employ the Drosophila hematopoietic organ, the larval lymph gland (LG) to investigate the impact of modulating cellular ageing on organ homeostasis. LG consists of a Posterior Signalling Center (PSC) that acts as a stem cell niche and maintains the prohemocytes housed in the Medullary Zone (MZ). Cortical Zone (CZ) consists of differentiated hemocytes namely plasmatocytes, crystal cells and lamellocytes. Intricate signalling networks active in the PSC and MZ orchestrate and regulate homeostasis. In this study, we characterize the effect of genetic perturbation of the molecular circuitry of ageing locally and systemically to investigate its effect on LG blood cell homeostasis. Genetic modulation of cellular ageing displays traditional hallmarks of ageing validating our model in the LG. Our results indicate that induction of accelerated ageing both locally and systemically leads to a reduction in stem cell niche size, DNA damage accumulation and increased progenitor differentiation whereas decelerated ageing shows an opposite trend. We show that the Integrated Stress Response (ISR) pathway is activated upon inducing accelerated ageing in the LG hemocytes possibly to recoup back to homeostatic conditions. Furthermore, LG’s of ISR pathway mutants or upon perturbation of ISR pathway components in prohemocytes show increased blood cell differentiation indicating disruption of homeostasis. Genetic epistasis analysis shows that ectopic over-expression of ISR pathway genes in an accelerated ageing scenario over and above the existing levels can rescue the defects in blood cell homeostasis. Overall, our study explores how modulation of cellular aging locally or systemically can impact tissue homeostasis. Our research paves way to understand the cellular mechanisms underlying an aged versus young stem cell-niche microenvironment and how its abrogation may lead to onset of disease.
Competing Interest Statement
The authors have declared no competing interest.