Populations of memory CD8 T cells can be maintained for their entire lifetime of the host once formed, and these cells confer protection against intracellular infections and mediate antitumor immunity (1–5). Generation of these cells is an important objective for many vaccination strategies (6–9). Compared to their naïve counterparts, memory CD8 T cells typically exist at a much higher frequency, are localized to different lymphoid and non-lymphoid tissues throughout the body and have a less stringent activation mechanism (10–13). These characteristics allow memory CD8 T cells to quantitively and qualitatively mount a more robust immune response than naïve CD8 T cells, collectively resulting in more effective control of intracellular pathogens (14–16). Significant heterogeneity exists within the memory CD8 T cell pool at epigenetic, transcriptional, and protein expression levels prompting further classification based on their phenotype, localization, and function (17–21). Thanks to their durability and diverse subsets, memory CD8 T cells provide protective responses against reinfections even years after the initial challenge; however, the quantitative and qualitative changes experienced by memory CD8 T cells responses after the onset of a lymphopenic event such as sepsis remain to be fully understood.

Sepsis is defined as an exaggerated immune response to a systemic infection that leads to organ dysfunction (22). The disseminated infection initially triggers the exacerbated generation of an array of pro- and anti-inflammatory cytokines, collectively regarded as “cytokine storm” (23, 24). Most sepsis patients can now survive the acute phase of sepsis as recent advancements in critical care have alleviated the tissue/organ damage inflicted by the cytokine storm (25). However, transient lymphopenia and long-lasting immune dysfunction (termed ‘immunoparalysis’) follows the cytokine storm, rendering surviving patients more susceptible to secondary infections, viral reactivation, and decreased 5-year survival compared to non-septic patients (26–29).

Sepsis is a challenging health crisis affecting nearly 50 million people annually, with a mortality rate of approximately 20%. It disproportionally affects the elderly; 75% of sepsis-related mortality occurs in individuals above 65 (30–32). On the other hand, as individuals age, they accumulate more memory T cells due to vaccinations and (re)infections which is associated with decreased susceptibility to infections. In fact, memory CD8 T cells constitute more than two-thirds of the CD8 T cell population in adult humans (33–35). Tissue-wide presence of memory T cells and their crucial role in protecting against pathogens call for a detailed analysis of the impact of sepsis on memory T cells. Hence, investigating the short- and long-term effects of sepsis on memory T cells is imperative. In this review, we will first provide an overview of different subsets of memory CD8 T cells and how time and multiple antigen encounters influence their characteristics. We will then discuss the acute and sustained impairments of sepsis on memory CD8 T cells.

Different models have been proposed to explain the origin and formation of antigen (Ag)-specific memory CD8 T (T_MEM) cells following the rapid expansion/contraction of effector CD8 T cells (36, 37). One model argues for the linear differentiation of naïve CD8 T cells to effector CD8 T cells and then to memory CD8 T cells (38–43). An alternative model proposes memory CD8 T cells are directly derived from naïve CD8 T cells without undergoing the effector phase differentiation (44–46). Elegant human and murine studies have provided compelling evidence to support both models; however, one common theme between the two theories is that there exist two subsets of memory precursor (MP) or terminal effector (TE) CD8 T cells by which the former population gives rise to the memory pool and the latter is programmed to contraction (40, 41, 47). Presence and appropriate number of both subsets at the right time is crucial to clear the pathogen without causing immunopathology and generating a diverse memory pool for recall responses. MP and TE cells have been conventionally parsed out based on CD127 and KLRG1 expression. MP cells are CD127^hi and KLRG1^lo, whereas TE cells are CD127^lo and KLRG1^hi (40), although recent work suggests a fraction of KLRG1⁺ effector cells can contribute to the memory pool (48–50). Nevertheless, the combination of Ag stimulation strength, inflammatory milieu, and tissue microenvironment alters Ag-specific CD8 T cell transcriptional programs, so that either subset is formed shortly after Ag encounter (15, 51–58). MP CD8 T cells express high levels of EOMES (59), FOXO1 (60), BCL-6 (61), ID3 (62), and TCF-1 (63, 64), whereas TE CD8 T cells express high levels of T-bet (40, 65), BLIMP-1 (66), ID2 (62), and Zeb2 (67). Each of these transcription factors (TF) plays a vital role in the formation, differentiation, and fate of effector cells. For example, Ag-specific CD8 T cells lacking EOMES or TCF-1 display diminished ability in differentiating to long-lasting memory CD8 T cells. In contrast, T-bet deficient CD8 T cells do not give rise to TE CD8 T cells (59, 63).

The first category of T_MEM cells ( Table 1 ) is circulating memory (T_CIRCM) CD8 T cells, which have been classically subdivided into two subsets of CD62L^lo CCR7^lo effector (T_EM) and CD62L^hi CCR7^hi central memory (T_CM) CD8 T cells ( Table 1 ) (68). T_CIRCM CD8 cells can circulate between blood, secondary lymphoid organs, and non-lymphoid organs. However, the expression of lymph node homing receptors CCR7 and CD62L enhance the localization of T_CM cells in lymph nodes (LN) and white pulp of spleen, whereas T_EM cells are more prevalent in blood, red pulp of spleen, and non-lymphoid tissues (10, 68, 69). Functional studies have indicated both subsets are robust producers of IFN-γ and TNF-α in response to cognate Ag stimulation, but CD62L⁺ T_CM cells have enhanced proliferative potential and IL-2 production. In contrast, T_EM cells exhibit more efficient cytotoxicity and effector-like functions. The differential localization and functional abilities of T_CM and T_EM cells render each subset more effective against different pathogens, determined by the nature of infection elicited by each pathogen. For example, T_CM cells are more protective against LCMV-clone 13 and malignancies, while T_EM cells clear intracellular bacterium Listeria monocytogenes (LM) infections more efficiently (21, 70–73). Nevertheless, the distinct localization and functional abilities of T_EM and T_CM cells confer protection against a wide range of pathogens.

In addition to T_CIRCM, tissue-resident memory (T_RM) CD8 T cells are non-lymphoid tissue-restricted T_MEM cells that patrol tissues for pathogen invasion ( Table 1 ) (74–76). These cells are typically situated in barrier sites and act as first responders upon Ag re-encounter with their sensing and alarm function; they mediate protection through cytotoxicity and/or secreting cytokines to recruit other immune cells to the site of pathogen invasion (75, 77–80). Although Hobit⁺ MP cells in non-lymphoid tissues (NLTs) are thought to be the major population contributing to the T_RM pool (76, 81, 82), it is not yet clear whether the potentiation of the effector cells to T_RM fate is induced either in the circulation prior to NLT recruitment or once located into NLT (83). T_RM cell fate requires downregulation of T-bet, EOMES, and TCF-1 to enable responsiveness to TGF-β, which signals for expression CD103, a critical tissue retention factor important in the generation of T_RM in epithelial tissue (58, 84, 85). Additionally, HOBIT/Blimp1 and Runx3 play a critical role in T_RM formation and differentiation (82, 86–88). ‘IV exclusion’ (89) and expression of tissue residence markers such as CD69 and CD103 are the most widely-used markers to distinguish T_RM cells from other T_MEM cells (76, 90). However, technically-challenging parabiosis experiments remain the gold-standard method to determine tissue residency (74, 91). Due to their strategic localization, which allows for early defense against pathogens, many studies have explored vaccination strategies that generate long-lasting T_RM cells to improve the efficacy of immunizations (92–98).

With the advent of multi-spectral flow cytometry and single-cell transcriptomics, the heterogeneity of both T_EM and T_CM populations has become more evident. CD62L^- T_CIRCM can further be subdivided into two populations of CD127^- CD27^- or CD127⁺ CD27⁺ subsets. The former subset is a descendant of KLRG1⁺ TE cells and termed long-lived effector cells (LLEC) (49) and/or terminally-differentiated effector memory cells (t-T_EM) (50), as they express TE signature genes such as KLRG1 and CX3CR1 as well as some memory-signature genes such as Bcl2 and TCF-1. Compared to T_CM and CD127⁺ T_EM cells, t-T_EM cells demonstrate the highest expression of granzymes and provide robust protection in LM rechallenge models on a per-cell basis indicating superior cytolytic function, but t-T_EM cells show impaired IL-2 production and poor tumor control. Interestingly, once t-T_EM cells are parsed out of CD62L^- T_CIRCM and T_EM cells are redefined as CD127⁺ CD62L^- memory CD8 T cells, the functional differences between the redefined T_EM and CD62L⁺ T_CM cells are minimized. This suggests the t-TE_M cells that make up a significant population of CD62L^- T_CIRCM cells may drive the differences that have previously been reported with respect to proliferative and cytotoxic abilities of CD62L⁺ and CD62L^- T_CIRCM cells.

Recent studies have shed light on the heterogeneity within the T_CM population. A small subset of CD62L⁺ TCF1⁺ MP cells with restrained effector-phase proliferation and expression of inhibitory receptors have been identified to give rise to a multipotent subset of T_CM cells with superior recall responses (99), matching another finding where CD62L⁺ TCF1^hi MP cells form T_CM cells with stemness features (100). Additionally, a study by Bresser et al. suggests the replicative history of the T_CM pool dictates the transcriptional program and functionality of T_CM cells (101). Specifically, T_CM that have undergone fewer prior cell divisions demonstrate quiescence and stemness features with more efficient recall responses than the T_CM with more cell divisions which exhibit effector-like characteristics. The quiescent cells within the T_CM pool share features of self-renewal and multipotency with stem cell-like memory cells (T_SCM) that remain poorly defined in murine models (42, 45).

Much of the heterogeneity described to the T_RM population is attributed to the distinct tissue microenvironment that T_RM cells are exposed to from tissue to tissue (102–104). Differential microenvironmental features lead to the phenotypic and transcriptomic alterations during the generation, differentiation, and maintenance of T_RM cells found in different organs, even in the same infectious model (105). This is well-reflected in the distinct T_RM markers and tissue-specific retention proteins; for example, despite the uniform expression of CD69 by T_RM cells in different tissues, expression of CD103, adhesion molecule CD49a, and chemokine receptors CXCR3 and CXCR6 are variable (103, 104). Notably, the heterogeneity of T_RM cells from different tissues is not limited to surface markers. It is also observed in transcriptional makeup and genome accessibility as tissue milieu instructs T_RM cells with a transcriptional network required for specific tissue adaptation (76, 105). Recent work also suggests T_RM cells within the small intestine could be further subdivided into stem-like Id3^hi T_RM and effector-like Id3^lo T_RM cells with differential multipotency and effector function capacity (106). Nevertheless, more studies are needed to fully delineate the heterogeneity within T_RM pool.

One hallmark of T_MEM cells generated via infection and/or vaccination is their ability to maintain their number and function for the life of the individual. The durability of T_MEM in an Ag-independent fashion relies on homeostatic signals from IL-7 and IL-15 that promote memory T cell survival (107). Despite their relative numerical stability, the CD8 memory pool undergoes significant transcriptional and phenotypic changes over time. With increasing time, the frequency of T_CIRCM cells expressing TCF1, Bcl6, Id3, and EOMES and long-term memory maintenance genes such as CD27, CD127, and CD122 increases while the expression of T-bet, Zeb2, Runx1, and Id2 and effector-like genes such as CX3CR1 and KLRG1 decreases. At an early memory timepoint, T_EM cells with high expression of effector-like genes are the dominant subset of T_CIRCM; however, superior hemostatic proliferative capacity of T_CM cells and/or direct conversion of CD127⁺ CD62L^- T_EM cells to T_CM cells results in gradual increase in T_CM representation over time. This results in late T_CIRCM cells to possess greater capacity for IL-2 production, secondary expansion, and higher order memory potential than early T_CIRCM cells (5, 21, 36, 108). On the other hand, T_RM cells of distinct tissues exhibit differential longevity; lung T_RM cells wane over time resulting in loss of protection (109, 110) while skin T_RM cells persist for a long time with robust protective function (111). Nevertheless, few studies have examined the impact of time on the phenotype and function of T_RM cells.

Following pathogen re-encounter and secondary expansion of primary (1°) T_CIRCM cells, secondary (2°) T_CIRCM cells are generated which can give rise to higher order T_CIRCM cells upon additional Ag encounter. Higher order T_CIRCM cells display differential tissue localization, phenotypic, and functional characteristics than 1° T_CIRCM cells. With increasing number of Ag stimulations, higher order T_MEM cells become more cytolytic with greater ability in trafficking to peripheral tissues, but reduced progression to a T_CM phenotype, responsiveness to homeostatic cues, and proliferative capacity (112–116). ‘T_EM -like’ features of higher order T_MEM cells render this population more protective than 1° T_MEM cells against pathogens, such as LM, that primarily infect and localize to peripheral tissues (73, 117). Although the more Ag encounters T_MEM cells experience, the more they become phenotypically and functionally like T_EM cells, gene set enrichment analysis (GSEA) shows no progressive enrichment in T_EM-associated genes in 2°, 3°, or 4° T_MEM cells (118). Hence, repeated Ag stimulation induces major changes in gene expression patterns of individual cells as opposed to merely changing the T_EM : T_CM ratio.

Antigenic challenge induces robust cytokine response from 1° T_RM cells which recruits immune cells including T_RM precursors to the site of infection to generate more T_RM population. Data suggested that 1° T_RM cells could also proliferate upon reinfection to give rise to 2° T_RM cells (119, 120); however, recent findings provided evidence that different subsets of T_RM possess different proliferation capacity. Using a fate-mapping system to track CD103-expressing CD8 T cells, von Hoesslin et al. and Fung et al. showed that CD103⁺ T_RM cells have limited proliferation capacity, but CD103^- T_RM cells undergo robust expansion upon Ag re-encounter, further highlighting the heterogeneity within T_RM pool (121, 122). Nonetheless, successive Ag exposures improve the longevity and protective function of T_RM pool; for example, 4° influenza-specific T_RM cells show enhanced durability and heterosubtypic immunity than 1° T_RM cells (123). This is attributed to continuous localization of 4° T_EM cells to lungs followed by subsequent conversion to T_RM cells. Several studies have reported lymph node T_RM cells in the context of skin and lung infections (124, 125) and Ag re-encounter may lead to migration of T_RM offspring to the draining lymph node (125). Similarly, repeated Ag exposures result in higher lymph node T_RM cells and increased representation of CD103⁺ CD69⁺ LN T_RM cells, leading to better local protection than 1° T_RM cells (126). Overall, repetitive Ag encounter consolidates the T_RM memory pool through the formation of higher order T_RM cells and/or differentiating pre-existing T_CIRCM to T_RM cells upon recruiting to the tissue.

Sepsis significantly reduces the number of lymphocytes (127–130), including CD8 T cells, via apoptosis (131–133). While naive (T_N) CD8 T cells are more susceptible to radiation-induced apoptosis and are lost to a greater extent than T_CIRCM cells (134), both T_N and T_CIRCM cells display similar susceptibility to the sepsis-induced numerical decline (135–137). Additionally, further investigation into the subset composition of T_CIRCM cells before and after sepsis reveals the numerical decline of T_CM is equal to that of CD62L^- T_EM cells. Hence, sepsis stochastically targets CD8 T cells, and all circulating CD8 T cells are lost in a non-discriminatory fashion regardless of their antigen exposure history ( Figures 1B, C ) (135, 137). Indeed, this interpretation is validated as 1° and 4° T_CIRCM cells exhibit similar fold loss following a septic event (138).

Unlike T_CIRCM cells, T_RM cell numbers remain unchanged following sepsis-induction that leads to low mortality levels (0-20% - moderate sepsis). Using a vaccinia infection model to generate T_CIRCM and T_RM with the same Ag specificity, we found the number of ‘IV positive’ T_CIRCM cells significantly declined after moderate sepsis, but the number of ‘IV negative’ skin T_RM cells were held constant ( Figure 2A , middle) (137, 139). Interestingly, T_RM cells within tumors and non-lymphoid organs are also more protected from radiation-induced cell death than circulatory T cells (140). Two explanations were postulated to justify the resistance of T_RM cells to sepsis-induced apoptosis. One is that T_RM-specific factors may protect this subset from sepsis-mediated apoptosis, as T_RM and T_CIRCM cells are phenotypically and transcriptionally distinct. Alternatively, the local environment in which T_CIRCM and T_RM cells reside may predispose one subset to sepsis-induced apoptosis but protect the other. Specifically, T_RM cells that reside in NLTs and have limited access to circulation may be more protected from the cytokine storm than the T_CIRCM cell typically found in blood and SLO. While the first explanation has yet to be examined, the second one was tested elegantly through varying the severity of sepsis. To do so, the cecal ligation and puncture (CLP) method with one or two punctures was implemented to recapitulate moderate or severe sepsis, respectively (141, 142). Moderate CLP-induced sepsis did not inflict enough damage to increase endothelial vascular permeability and leakage of cytokine storm to NLTs; however, severe sepsis led to a disruption of the endothelial barrier exposing the once-shielded NLT to pro- and anti-inflammatory cytokines (and other proteins and metabolites). Therefore, severe sepsis not only instigates a more dramatic T_CIRCM cell loss compared to moderate sepsis, but it also results in a significant decline in the number of T_RM cells ( Figure 1A , right) (142). Overall, these data demonstrate T_CIRCM and T_RM cells display differential susceptibility to sepsis due to their distinct anatomical localization.

Sepsis-induced lymphopenia is a transient event, and lymphocyte numbers will eventually return to pre-sepsis levels. However, there is limited information detailing the mechanisms responsible for the numerical restoration and the long-term impact of sepsis on T cell biology. Longitudinal studies using TCR-transgenic CD8 T cells (i.e., P14) adoptively transferred into C57/Bl6 recipients have shown that the number of both T_N and T_CIRCM cells quickly bounce back to the pre-sepsis baseline state. Lymphopenia-induced proliferation is thought to drive the numerical recovery of T_N and T_CIRCM cells as IL-7 and IL-15 mediate rapid proliferation of surviving lymphocytes to fill the empty space. Increased frequency of Ki-67⁺, marker for cell cycling and a non-G₀ status, T_N and T_CIRCM cells in both murine and human septic samples provides evidence for increased proliferation of CD8 T cells after resolution of the acute phase of sepsis (143, 144). Recent murine and clinical studies have exploited the pro-survival features of IL-7 on T cells, as IL-7 treatment alleviates sepsis-indued T cell loss via preventing apoptosis and accelerating numerical recovery of lymphocytes (145–147). This notion has opened new lines of investigation to explore the therapeutic effects of IL-7 and other cytokine complex treatments in ameliorating sepsis-induced immune dysfunction.

Despite apparent numerical recovery of T_N cells, the composition and phenotype of the post-sepsis T_N pool is altered. Reduced primary effector responses in the post-septic host indicates an incomplete repertoire recovery and a less diverse T_N pool. This is indeed the case for naïve Ag-specific CD4 T cells (148), but it remains to be determined if the same thing occurs for CD8 T cells. In addition, some studies suggest post-sepsis T_N cells have increased expression of memory-associated markers, such as CD11a, for an unknown period ( Figure 1D ) (143). These observations have prompted more detailed investigation into long-term impact of sepsis on the numerically recovered T_MEM compartment.

Transcriptional analysis of T_CIRCM cells from sepsis survivors indicates that sepsis causes a long-lasting ‘transcriptional scar’ in T_CIRCM cells by inducing transcriptional changes both immediately after onset of sepsis and during the recovery phase. Specifically, T_CIRCM cells from CLP hosts show upregulation of pathways that work in concert to aid in cell cycling and increase the proliferation output long after sepsis induction. Additionally, T_CIRCM transcripts from sham hosts are more effector-like whereas T_CIRCM transcripts from CLP hosts are enriched in sets of genes associated with long-term memory, pointing to potential composition differences between the two groups. Indeed, the post-sepsis environment greatly shapes the phenotype and the composition of T_CIRCM pool. Precisely, the numerical recovery of T_CIRCM cells is accompanied with increased representation of T_CM cells, the memory subset with highest proliferation capacity ( Figure 1D ). Examining the effector and memory-related markers shows the enrichment of CD62L⁺ KLRG1^- CD127⁺ CX3CR1^- T_CIRCM cells in the septic host. The enrichment of T_CM cells is ascribed to the enhanced capacity of T_CM cells to sense lymphopenia-induced homeostatic cues that trigger rapid cell cycling and enrichment of T_CM cells in the T_CIRCM pool (144). Taken together, despite equal susceptibility of T_CIRCM subsets to sepsis, surviving T_CIRCM cells with greater homeostatic proliferation potential preferentially repopulate the lymphopenic space leading to long-lasting altered T_CIRCM subset composition.

1° T_CIRCM cells are not the only T_MEM cells affected by sepsis. Our lab has recently demonstrated that higher order T_CIRCM cells are equally susceptible to the sepsis-induced death as 1° T_CIRCM cells. This is particularly important as the human population, especially the elderly with the highest susceptibility to sepsis complications, is seeded with a diverse pool of T_MEM cells and different Ag exposure histories. Additionally, we speculated the diminished baseline proliferative capacity of higher order T_CIRCM cells vs. 1° T_CIRCM cells leads to preferential numerical recovery of 1° T_CIRCM cells and dilution of higher order T_CIRCM cells post-sepsis. Examining Ki-67 expression and BrdU incorporation of 1° and 4° T_CIRCM cells revealed that unlike in 1° T_CIRCM cells, sepsis did not invoke vigorous proliferation in 4° T_CIRCM cells. Subsequently, the frequency of 4° T_CIRCM cells progressively decreased while 1° T_CIRCM increased resulting in a less diverse T_CIRCM pool. Despite triggering rapid proliferation of 1° T_CIRCM cells, administration of IL-7 did not boost the numerical restoration of 4° T_CIRCM cells which further capitalizes the accumulation of 1° T_CIRCM cells after sepsis (138). Overall, the post-sepsis environment favors the repopulation of T_CIRCM cells with high proliferative capacity, leading to altered subset composition and reduced heterogeneity within the T_CIRCM pool.

Increased susceptibility of sepsis survivors to previously-encountered pathogens and viral reactivation insinuates compromised protection conferred by T_MEM. The impact of sepsis on the protective capacity of T_MEM can be dissected at different levels because the ‘per cell’ functional fitness (such as cytolytic capacity and cytokine secretion) of T_MEM cells is key in mediating pathogen clearance, in addition to their number, tissue localization, and ability to communicate with other cells being crucial for mounting a protective immune response. Thus, we will next discuss the immediate effect of sepsis on functional capacity of different subsets of the T_MEM pool and finish with a description of the long-term impact of sepsis on T_MEM -mediated immunity.

Lymphopenia is not the only immunological catastrophe that a septic host experiences shortly after the onset of sepsis. Sepsis impairs the Ag-dependent functions of T_CIRCM on a per cell basis. Particularly, sepsis diminishes the IFN-γ production in response to cognate Ag resulting in decreased Ag sensitivity and functional avidity of T_CIRCM cells. In response to the cognate antigen, the compromised cytokine production and proliferative capacity of T_CIRCM render septic hosts more susceptible to homologous reinfections. Nevertheless, T_MEM cells do not mediate protection only in presence of their cognate Ag. When T_MEM are ‘bathed’ in a highly inflammatory environment, they are activated to produce more cytokines and cytotoxic granules such as granzyme B. This ‘bystander activation’ of T_MEM is Ag-independent, but inflammation-dependent (149–152). Interestingly, sepsis also impairs the Ag-independent functions of T_MEM. In response to a heterologous infection, upregulation of activation markers and granzyme B was compromised in T_CIRCM of CLP hosts (135). Together, these results suggest sepsis impairs the Ag-dependent and -independent functions of T_CIRCM through influencing T-cell intrinsic and extrinsic factors.

Due to their localization to NLTs and being shielded from the damages of moderate cytokine storm, T_RM maintain their numbers, and their ‘sensing and alarm’ function as measured by IFN-γ production in response to Ag stimulation ( Figure 2B , middle). Surprisingly, despite the intact number and function of T_RM in the post-septic host, the protective capacity of T_RM is diminished after moderate sepsis. In vaccina virus (VacV)-immune mice that underwent either CLP or sham surgeries, CLP hosts showed sustained high viral load and inability to clear VacV after re-challenge (139). Interestingly, this finding is contrary to other data suggesting T_RM confer better protection than T_CIRCM against VacV reinfections (74). This difference raises the question as to how sepsis diminishes the protective capacity of T_RM despite their unchanged numbers and function. Subsequent investigation revealed that sepsis decreases the ability of vascular endothelium to express chemokines and adhesion molecules in response to T_RM inflammatory cues ( Figure 2B , middle), resulting in the inefficient recruitment of effector cells to the site of pathogen invasion and ultimately poor pathogen control (139). In severe sepsis, the numerical decline of T_RM further exacerbates the diminished protection in localized reinfections ( Figure 2B , right) (142). Collectively, these results suggest sepsis diminishes T_RM recall responses through disrupting their ability to recruit effector cells.

How tissue-specific factors contribute to the resistance of T_RM cells to moderate sepsis-induced cell death and functional impairment remains elusive. Blockade of TGF-β has been shown to render tumor T_RM cells more susceptible to radiation-induced numerical decline (140); hence, the potential role of TGF-β signaling in maintaining T_RM number and function after moderate sepsis should be explored. Additionally, the impact of sepsis on T_RM cells within NLTs other than skin and SLO T_RM cells in draining LN should be further investigated. While the data from our laboratory suggest that skin T_RM cells that are anatomically separated from circulation are numerically and functionally protected from moderate sepsis, the crosstalk of SLO T_RM cells with circulatory factors and the increased exposure of liver T_RM cells to blood may increase the sensitivity of SLO and liver T_RM cells to sepsis-mediated numerical loss and dysfunction. On the other hand, one could also argue for presence of shared T_RM-specific factors that protect T_RM cells found in different tissues from moderate sepsis regardless of their localization.

Our discussion so far has focused on describing the functional impairments with the CD8 T cell compartment that ensue after septic insult. While they shed light on factors contributing to the increased susceptibility of septic hosts early after the insult, a noticeable percentage of sepsis survivors suffer from long-lasting immunoparalysis. Our studies on the T_CIRCM pool long after sepsis suggest the impairment in cytokine production after restimulation is resolved. In fact, a higher frequency of T_CIRCM from CLP hosts produce IL-2 in response to Ag stimulation when examined 30 days post-sepsis. Increased IL-2 production aligns with the enrichment of T_CM in the T_CIRCM pool at a late time post sepsis, as these cells have better IL-2 production than T_EM. However, the preferential skewing of T_CIRCM pool by cells with the greatest proliferative capacity (i.e., 1° T_CM) results in the reduced prevalence of T_CIRCM cells with greatest cytotoxic function (T_EM and higher order T_CIRCM cells) (138, 144). Enrichment of T_CM negatively impacted the ability of CLP hosts to clear pathogens in a LM rechallenge model (144). Additionally, recent studies have identified T_EM as the population seeding T_RM pools (109). T_CM overrepresentation may affect the maintenance of the T_RM pool by decreasing the supply of T_EM. Overall, a memory pool with a diverse (but balanced) subset of cells is needed for the host to mount the most robust immune response possible. Enrichment of a subset of T_MEM at the expense of other subsets may substantially affect the overall fitness of T_MEM pool as each subset possesses a specialized role and function.

Sepsis research has shifted focus to characterizing the factors leading to the long-lasting state of immunoparalysis that emerges following the resolution of acute phase of sepsis. Since sepsis survivors show increased susceptibility to secondary and recurring infections, these studies demand an in-depth analysis of the impact of sepsis on memory lymphocytes – the body’s most potent weapon in fighting against reinfections. Circulating memory CD8 T cells undergo substantial numerical attrition and functional impairment shortly after a septic insult deriving the host susceptible to heterologous and homologous reinfections. Additionally, tissue-resident memory CD8 T cells also display a diminished ability in recruiting effector cells in response to localized re-infections. Despite the apparent numerical recovery and per cell function, circulatory memory CD8 T cells demonstrate long-lasting changes in their transcriptional and epigenetic programs after sepsis resolution, with the most proliferative subset being overrepresented over time. Therefore, sepsis ultimately leads to altered subset composition and reduced heterogeneity in memory CD8 T cells in the circulation. Further investigation is required to delineate the long-term sepsis-induced changes in function and maintenance of tissue-resident memory CD8 T cells.

All authors listed have made a substantial, direct, and intellectual contribution to the work and approved it for publication.