The COVID-19 pandemic has revealed the pronounced vulnerability of the elderly and chronically-ill to SARS-CoV-2-induced morbidity and mortality. Cellular senescence contributes to inflammation, multiple chronic diseases, and age-related dysfunction, but effects on responses to viral infection are unclear. Here, we demonstrate that senescent cells (SnC) become hyper-inflammatory in response to pathogen-associated molecular patterns (PAMPs), including SARS-CoV-2 Spike protein-1, increasing expression of viral entry proteins and reducing anti-viral gene expression in non-SnCs through a paracrine mechanism. Old mice acutely infected with pathogens that included a SARS-CoV-2-related mouse β-coronavirus experienced increased senescence and inflammation with nearly 100% mortality. Targeting SnCs using senolytic drugs before or after pathogen exposure significantly reduced mortality, cellular senescence, and inflammatory markers and increased anti-viral antibodies. Thus, reducing the SnC burden in diseased or aged individuals should enhance resilience and reduce mortality following viral infection, including SARS-CoV-2.
Immunosurveillance of secondary lymphoid organs (SLO) is performed by central memory T cells that recirculate through blood. Resident memory T (Trm) cells remain parked in nonlymphoid tissues and often stably express CD69. We recently identified Trm cells within SLO, but the origin and phenotype of these cells remains unclear. Using parabiosis of "dirty" mice, we found that CD69 expression is insufficient to infer stable residence of SLO Trm cells. Restimulation of nonlymphoid memory CD8 T cells within the skin or mucosa resulted in a substantial increase in bona fide Trm cells specifically within draining lymph nodes. SLO Trm cells derived from emigrants from nonlymphoid tissues and shared some transcriptional and phenotypic signatures associated with nonlymphoid Trm cells. These data indicate that nonlymphoid cells can give rise to SLO Trm cells and suggest vaccination strategies by which memory CD8 T cell immunosurveillance can be regionalized to specific lymph nodes.
SUMMARY Microbial exposures can define an individual’s basal immune state. Cohousing specific pathogen-free (SPF) mice with pet store mice, which harbor numerous infectious microbes, results in global changes to the immune system, including increased circulating phagocytes and elevated inflammatory cytokines. How these differences in the basal immune state influence the acute response to systemic infection is unclear. Cohoused mice exhibit enhanced protection from virulent Listeria monocytogenes (LM) infection, but increased morbidity and mortality to polymicrobial sepsis. Cohoused mice have more TLR2+ and TLR4+ phagocytes, enhancing recognition of microbes through pattern-recognition receptors. However, the response to a TLR2 ligand is muted in cohoused mice, whereas the response to aTLR4 ligand is greatly amplified, suggesting a basis for the distinct response to Listeria monocytogenes and sepsis. Our data illustrate how microbial exposure can enhance the immune response to unrelated challenges but also increase the risk of immunopathology from a severe cytokine storm.
Metazoans relegate specific tasks to dedicated organs that are established early in development, occupy discrete anatomic locations, and typically remain fixed in size. The adult immune system arises from a centralized hematopoietic niche that maintains self-renewing potential 1 , 2 , and upon maturation, becomes distributed throughout the body to monitor environmental perturbations, regulate tissue homeostasis, and mediate organism-wide defense. This study examines how immunity is integrated within adult mouse tissues while addressing issues of durability, expansibility, and contribution to organ cellularity. Focusing on antiviral T cell immunity, we observe durable maintenance of resident memory T cells (T RM ) up to 450 days after infection. Once established, resident T cells did not require the T cell receptor for survival or retention of a poised effector-like state. While resident memory indefinitely dominated most mucosal organs, surgical separation of parabiotic mice unexpectedly revealed a tissue-resident provenance for bloodborne effector memory T cells, and circulating memory slowly made substantial contributions to tissue immunity in some organs. Following additional microbial experiences via serial immunizations or pet shop mice co-housing, for most tissues we find tissue pliancy allows for the accretion of tissue-resident memory, without axiomatic erosion of preexisting antiviral T cell immunity. Extending these findings, we demonstrate tissue residence and organ pliancy are generalizable aspects underlying the homeostasis of innate and adaptive immunity. The immune system-at-large grows commensurate to microbial experience reaching up to 25% of visceral organ cellularity. Regardless of location, many white blood cell populations adopted a tissue residency program within nonlymphoid organs. Thus, residence, rather than renewal or recirculation, typifies nonlymphoid immune surveillance, and organs serve as a pliant storage reservoir that can accommodate the continuous expansion of the cellular immune system throughout life. While hematopoiesis (‘to make blood’) restores certain elements of the immune system, in parallel, nonlymphoid organs sustain an accrual of durable tissue-autonomous cellular immunity, resulting in the progressive decentralization of organismal immune homeostasis.
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