Researchers here provide data on the correlations between (a) secreted proteins circulating in blood that are distinct to senescent cells of various types, and (b) a number of different age-related conditions. Some cell types are better than others when it comes to the strength of correlation between the burden of senescence as assessed by circulating proteins and status of given age-related condition. This process of mapping the landscape of senescence and aging sets the stage for the development of better assays that can inform patients as to the risk resulting from the burden of senescence, and later the degree of improvement produced by therapies capable of reducing the burden of senescent cells.
Senescence is characterized in part by proteomic expression changes, including the secretion of pro-inflammatory cytokines and other proteins, which become amplified during sustained senescence and in large part drive its deleterious effect in a chronic, age-related context. These senescence-associated proteins (SAPs) have since proven to be heterogeneous by cell type and senescence-inducing stimulus.
One promising technique in assessing individual senescence burden is through the quantification of SAPs in circulating plasma. The plasma senescence burden has previously demonstrated compelling clinical associations, including with age, frailty, and mortality. In recent years, a group of senescence-targeting compounds collectively known as senotherapeutics has been investigated for their limited and context dependent senescence-attenuating effects. Senotherapeutic drugs have demonstrated an ability to lower circulating SAPs in human trials, and to partially alleviate some aging phenotypes.
A remarkable recent finding is that beyond general clinical traits such as age and mortality, organ-specific proteins can be tracked in circulation and used to model organ age and organ-specific clinical traits. Considering the previously demonstrated clinical relevance of circulating canonical senescence signatures, examining cell type-specific senescence signatures in circulation could similarly shed light on the unique clinical relevance of organ-specific senescence.
In this study, senescence signatures from the Senescence Catalog (SenCat), including 14 human cell types such as peripheral blood mononuclear cells, renal epithelial cells, vascular smooth muscle cells, among others, are examined for their clinical relevance in circulation in two longitudinal studies: 1,275 participants of the Baltimore Longitudinal Study of Aging (BLSA) and 997 participants of the Invecchiare in Chianti (InCHIANTI) study. Notably, pooled senescence proteins outperformed non-senescence proteins in predicting many clinical parameters such as age and hypertension, and in many instances cell type senescence signatures mapped most strongly to their corresponding health domain. Importantly, the immune cell senescence signature is associated with future onset of several diseases such as diabetes.
Link: https://doi.org/10.64898/2026.02.06.26345739
View the full article at FightAging
