Thymalin

Peripheral Oxidation-Inflammation and Immunosenescence in Triple-Transgenic Mice for Alzheimer's Disease (3xTg-AD) at Early Neuropathological Stages of Disease and Decrease of Immune Impairment by Voluntary Exercise.

Mónica De la Fuente, Antonio Garrido, Carmen Vida +2 more

Inflammatory-oxidative stress generated by immune cells plays an important role in aging and in age-related neurodegenerative disorders such as Alzheimer's disease (AD). Triple-transgenic mice for AD (3xTg-AD) are a suitable model for mimicking this disease in an age-dependent manner. We previously showed that peritoneal leukocyte functions and their redox-inflammatory state are altered early in female 3xTg-AD mice, which exhibit premature aging compared to non-transgenic (NTg) animals. However, their characteristics at 9 months of age, when they present an early neuropathological state, and the sex differences are not known. Here, we analyzed several spleen and thymus leukocyte functions (chemotaxis, natural killer activity, and lymphoproliferation in response to mitogens), pro-inflammatory (IL-1B, TNF-alpha) and anti-inflammatory (IL-10) released cytokine concentrations, and redox parameters (glutathione concentrations and glutathione peroxidase, glutathione reductase, and xanthine oxidase activities) in male and female 3xTg-AD mice compared to age-matched controls. We also analyzed the effects of voluntary physical exercise on immune functions. Our results show that 9-month-old male and female 3xTg-AD mice have worse immune functions, redox state, and inflammation than NTg counterparts. Physical exercise improves immune function. Thus, accelerated aging reflected by peripheral immunosenescence and oxidation-inflammation in 3xTg-AD mice precedes hallmark neuropathology, and exercise can slow down AD progression.

Erzhi pills: a potential aging-modulating agent targeting immunosenescence in mice.

Zhirui Fang, Wei Sun, Na Li +9 more

Erzhi Pills (EZP), a traditional Chinese herbal formula, has demonstrated potential aging-modulating properties, while its mechanisms in modulating immunosenescence remain incompletely understood. Two complementary aging murine models were employed to investigate the anti-immunosenescence efficacy of EZP, providing experimental validation for its translational application in delaying age-related immune decline. Morphological and physiological parameters were monitored and thymic/splenic organ coefficients were calculated. Histopathological evaluation of thymic involution was performed via hematoxylin-eosin (H&E) staining. Flow cytometry quantified splenic T cell subsets (naïve/memory CD4+ and CD8+ T cells). Reverse transcription quantitative PCR (RT-qPCR) analyzed mRNA expression of key immunosenescence markers (Lin28a, GDF-11, Sirt1, IL-2, IL-17), while enzyme-linked immunosorbent assay (ELISA) measured serum levels of pro-inflammatory cytokines (TNF-α, IFN-γ). Metabolomic profiling further elucidated EZP's bioactive pathways. EZP administration significantly attenuated age-related degeneration in both murine models by restoring thymic and splenic architecture, as evidenced by increased organ coefficients and reduced histopathological damage. EZP rebalanced T cell homeostasis through selective expansion of naïve T cells and contraction of memory T cell subsets, with a pronounced increase in CD8+ T cell populations. At the molecular level, EZP upregulated Lin28a, Sirt1, and IL-2 expression while modulating systemic cytokine profiles-reducing TNF-α and augmenting IFN-γ in the natural aging cohort. These findings suggest EZP mitigates chronic inflammatory aging and enhances immune responsiveness of effector T cells. EZP's anti-aging mechanism was mediated by fatty acid metabolism modulation. This study provides evidence supporting EZP's potential as a novel therapeutic strategy for immunosenescence and warrants further investigation into its clinical translation for geriatric populations.

The impact of growth hormone (GH) on immunosenescence: exploring the role of B and T cells.

Badra Bashir, Marcella van Hoolwerff, Fabian Benencia +4 more

Immunosenescence is a gradual decline in immune function, leading to increased susceptibility to infections and autoimmune conditions. Growth hormone (GH) has been shown to have an effect on both immune function and aging. In fact, the absence of GH-induced intracellular signaling can slow the aging process, as demonstrated by the longest-lived laboratory mouse (GH receptor gene disrupted or GHR-/- mice). Because GH receptors (GHR) are expressed in B and T cells, and these cells undergo age-related changes that impact immune function, we hypothesized that decreased GH action protects from immunosenescence. To validate this hypothesis, this study aimed to characterize differences in B cell and T cell populations within the lymphoid organs of aged female GHR-/- mice (24 months of age) compared to wild-type controls.

Aging and Thymosin Alpha-1.

Maria A Simonova, Igor Ivanov, Natalia S Shoshina +9 more

Aging is characterized by immune decline, mainly due to thymic involution-the age-related shrinkage of the thymus gland. This leads to reduced T-cell production, chronic inflammation, and increased susceptibility to age-related diseases. Thymosin alpha-1 (Tα1), a peptide hormone produced by the thymus, exhibits potent immunomodulatory, anti-inflammatory, and antioxidant properties. It helps restore immune function by stimulating T-cell differentiation, enhancing thymic output, and modulating dendritic cell and macrophage activity. Preclinical and clinical studies show that Tα1 can improve vaccine response in the elderly and mitigate immunosenescence. The hybrid drug Refnot (a fusion of tumor necrosis factor alpha (TNFα) and Tα1) combines Tα1's immunomodulation with TNF's antitumor activity but has reduced toxicity. It represents a promising therapeutic approach to counteract age-related immune dysfunction and inflammation, potentially by slowing the aging process. Further research is needed to validate its long-term efficacy and safety in geriatrics.

A multi-tissue integration of immunocytes and inflammaging biomarkers predicts biological age through LASSO-optimized modeling.

Jiawei Yang, Haichen Zhang, Qiong Zhang +8 more

Immunosenescence, a recognized hallmark of aging, is characterized by imbalances in immunocyte populations and a state of chronic inflammation. However, the tissue-specific dynamics of these changes and their potential as predictive biomarkers for aging remain poorly characterized. In this study, we established a multi-tissue immunological signature as a robust predictor of biological age by integrating immunocyte and cytokine profiling. Using Sprague-Dawley (SD) rats from five age groups (1-12 months), we systematically quantified 45 immunocyte subsets across peripheral blood, mesenteric lymph nodes, thymus, and spleen using flow cytometry, and profiled 22 serum cytokines/chemokines via Flexible Multi-Analyte Profiling (xMAP). Firstly, classic age-dependent shifts were observed across our rat samples, including progressive thymic involution and depletion of peripheral T-cells. Cytokine levels exhibited age-related chronic inflammation progression, marked by elevated IL-1α, granulocyte colony-stimulating factor (G-CSF), and TNF-α. To integrate these multidimensional datasets into a predictive aging metric, we employed Least Absolute Shrinkage and Selection Operator (LASSO) regression, selecting 22 biomarkers through regularization (λ = 0.111). The integrated model combining cellular and cytokine data demonstrated superior performance (training R2 = 0.957, validation R2 = 0.887), outperforming single-modality models based on immunocytes or cytokines. Notably, splenic parameters dominated the aging signature, contributing seven biomarkers representing 60% of model weight-particularly Th-cell expansion and Tc-cell depletion. Peripheral blood Th-cell proportion emerged as another key predictor. Our findings position the spleen as a critical aging hub and identify peripheral/splenic Th-cell modulation as promising therapeutic targets for age-related immune dysfunction, revealing novel mechanistic insights into aging-associated immune remodeling.

Effects of Long-term low-dose intermittent rapamycin administration on glucose metabolism and immune system of SAMP8 and SAMR1 mice.

Luiz Adriano Damasceno Queiroz, Rafael Santos Barros, Josiane Betim Assis +6 more

Aging involves a gradual decline in physiological integrity, and rapamycin (RAPA) has demonstrated potential as an anti-aging agent. Nonetheless, its effects on glucose metabolism and immune function may vary based on dosage and administration regimen. This study investigates the impact of intermittent low-dose RAPA on glucose metabolism and immune function in Senescence-Accelerated Mouse Prone 8 (SAMP8) and Senescence-Accelerated Mouse Resistant 1 (SAMR1) mice. Twelve-week-old male SAMP8 and SAMR1 mice were treated with RAPA (0.78 µg/kg) every five days for six months. Glucose uptake, mitochondrial respiratory capacity, spleen and thymus immunophenotype, lymphoproliferation, and cytokine profiles were evaluated. Our findings indicate that RAPA reduced glucose uptake in the bladder and the percentage of FoxP3+ lymphocytes in the spleen of SAMP8 mice, while enhancing mitochondrial respiratory control and ATP production in liver. In SAMR1 mice, RAPA administration led to a decrease in CD3+ thymocytes and splenic lymphoproliferative capacity, while also enhanced mitochondrial performance. Comparisons between Control groups revealed that SAMP8 mice exhibited higher glucose uptake in several tissues, lower lymphocyte populations in spleen and thymus, altered CD4+/CD8+ ratios, and reduced IL-4 expression compared with SAMR1 mice. The findings reinforce the potential of RAPA to modulate aging-related processes, highlighting improvements in mitochondrial function and energy metabolism across strains with different aging processes. However, the immunosuppressive effects of RAPA remain evident, even at low doses administered intermittently, in an age- and strain-specific manner. These findings emphasize the therapeutic potential of RAPA while underscoring the need for customized dosing strategies to balance efficacy and safety. These data highlight mitochondrial metabolic improvements as the primary benefit of intermittent low-dose RAPA and suggest potential clinical relevance for conditions involving compromised mitochondrial energy metabolism.

Thymic Bmi-1 hampers γδT17 generation and its derived RORγt-IL-17A signaling to delay cardiac aging.

Qiuyi Wang, Yue Wang, Yujie Lin +13 more

New immunosenescence targets for preventing senescence-associated pathological cardiac hypertrophy (SA-PCH) need to be explored. In the present study, with physiologically aged human and mouse samples, the IL-17A level increased with physiological aging, heart failure (HF), and SA-PCH and was negatively correlated with thymic Bmi-1 expression. Bmi-1f/fLckCre+ mice and Bmi-1f/f littermates were generated to determine whether Bmi-1 delayed T cell aging by maintaining thymic T cell development to prevent SA-PCH. As a result, Bmi-1 promoted thymic T cell development by upregulating Notch signaling and prevented DN1 T cells from differentiating into γδT17 cells by downregulating γδT17 cell differentiation signaling. Bmi-1 upregulated Notch signaling by inhibiting p53-mediated Ikzf1 transcription at the -1,863 to -1,849 Ikzf1 promoter region. Bmi-1-RING1B promoted RORγt ubiquitination and degradation by proteasome to inhibit the production of IL-17A in γδT17 cells. Bmi-1 also downregulated Rorc transcribed by c-Maf by trimethylating H3K27 at the -1,511 to -1,497 Rorc promoter region. Subsequently, the number of peripheral γδT17 cells infiltrating the heart tissues was reduced, while alleviating IL-17A-dependent cardiac aging, hypertrophy, dysfunction, senescence-associated secretory phenotype (SASP), and macrophage-myofibroblast transition, ultimately improving SA-PCH. The RORγt inhibitor SR1001 and IL-17A neutralizing antibody ixekizumab prevented thymic RORγt-IL-17A-dependent SA-PCH. Furthermore, RORγt bound to Bmi-1 through ARG237 and to RING1B through GLU235, which could be used as a therapeutic strategy for SA-PCH to construct binding peptides promoting Bmi-1-RING1B binding to RORγt and degrading RORγt for inhibiting γδT17 cell differentiation and IL-17A production. Thus, thymic Bmi-1 prevented IL-17A-dependent SA-PCH by decreasing γδT17 cell numbers.

Divergent immediate and delayed effects of juvenile exposure to doxorubicin on the thymus in C57BL/6 mice.

Benu George, Korbyn J V Dahlquist, Marianne K O Grant +7 more

The long-term effects of doxorubicin (DOX) chemotherapy on thymic immune function in childhood cancer survivors remain inadequately understood. This study explores the immediate and delayed impacts of low-dose DOX on thymic immune populations using a juvenile mouse model. Male mice received intraperitoneal DOX injections (4 mg/kg/week) for three weeks, with evaluations performed at one- and five-weeks post treatment. Thymic samples were collected and analyzed using multi-parameter flow cytometry to assess changes in immune cell composition and phenotype. Additionally, real-time polymerase chain reaction (RT-PCR) was employed to measure gene expression of cytokines and senescence markers. One week after DOX administration, significant thymic atrophy was evident. While mature CD3+CD4+ T-cell frequency remained unchanged, CD3+CD8+ T-cells significantly increased, suggesting differential effects on T-cell subsets. PD1+ expression increased across naïve and memory CD4+ T-cell subsets, suggesting activation or exhaustion. Additionally, Ki67+ expression was elevated in naïve and memory CD8+ T-cells, indicating enhanced proliferation. Gene expression analysis revealed upregulation of Foxn1, Pax1, Ifnγ, and Il7 whereas Il6 and Il17 were downregulated. Furthermore, Cdkn1a (p21) expression was elevated, suggesting immune dysregulation and early immunosenescence. At five weeks, thymic weight rebounded; however, T-cell subsets displayed persistent perturbations. Central memory and effector memory CD4+ T-cells were reduced, while naïve CD4+ T-cells showed increased Ki67+ expression. In contrast, CD8+ T-cells subsets remained largely unchanged, except for a decrease in central memory cells. Although expression of thymus-related genes was normalized, p21 expression remained elevated, suggesting lingering immunosenescence. These findings highlight the complex effects of DOX, including acute thymic atrophy due to T-cell depletion, and a delayed recovery with persistent immunosenescence, underscoring the need for strategies to preserve immune function in childhood cancer survivors.

RANKL treatment restores thymic function and improves T cell-mediated immune responses in aged mice.

Jérémy C Santamaria, Jessica Chevallier, Léa Dutour +11 more

Age-related thymic involution, leading to reduced T cell production, is one of the major causes of immunosenescence. This results in an increased susceptibility to cancers, infections, and autoimmunity and in reduced vaccine efficacy. Here, we identified that the receptor activator of nuclear factor κB (RANK)-RANK ligand (RANKL) axis in the thymus is altered during aging. Using a conditional transgenic mouse model, we demonstrated that endothelial cells depend on RANK signaling for their cellularity and functional maturation. Decreased RANKL availability during aging resulted in a decline in cellularity and function of both endothelial cells and thymic epithelial cells, contributing to thymic involution. We then found that, whereas RANKL neutralization in young mice mimicked thymic involution, exogenous RANKL treatment in aged mice restored thymic architecture as well as endothelial cell and epithelial cell abundance and functional properties. Consequently, RANKL improved T cell progenitor homing to the thymus and boosted T cell production. This cascade of events resulted in peripheral T cell renewal and effective antitumor and vaccine responses in aged mice. Furthermore, we conducted a proof-of-concept study that showed that RANKL stimulates endothelial cells and epithelial cells in human thymic organocultures. Overall, our findings suggest that targeting the RANK-RANKL axis through exogenous RANKL administration could represent a therapeutic strategy to rejuvenate thymic function and improve T cell immunity during aging.

Cannabidiol, a Strategy in Aging to Improve Redox State and Immunity in Male Rats.

Mónica De la Fuente, Noelia Joyera, Judith Félix +4 more

Aging is characterized by oxidative stress and immune function impairment, and is associated with increased morbidity. Cannabidiol (CBD) has anti-oxidant properties, but its role in aging has been scarcely studied. This work aims to test the effect of CBD on the redox state and immunity during aging in rats. In this study, 15-month-old male Long Evans rats received 10 mg/kg b.w/day of CBD in their diet for 10 weeks and were compared with same-age control and 2-month-old rats serving as a young control group, both following a standard diet. After treatment, they were sacrificed, and the spleen, thymus, and total blood cells were collected. Redox parameters such as glutathione reductase and peroxidase activities, reduced (GSH) and oxidized (GSSG) glutathione concentration, GSSG/GSH ratio, and lipid peroxidation were evaluated. Moreover, immune functions (chemotaxis, natural killer activity, and lymphoproliferation) were analyzed in the spleen. Results show that the 15-month-old control rats exhibited increased oxidative stress and immunosenescence compared to the 2-month-old rats. However, the CBD-treated animals showed higher anti-oxidant defenses, lower oxidants in the spleen, thymus, and blood cells, and better immunity in the spleen than the corresponding age-matched controls. Therefore, CBD administration neutralizes oxidative stress and improves immunity, suggesting it is a strategy for achieving healthy aging.

Effects of low-dose rapamycin on lymphoid organs of mice prone and resistant to accelerated senescence.

Rafael Dos Santos Barros, Luiz Adriano Damasceno Queiroz, Josiane Betim de Assis +7 more

Aging is a complex, natural, and irreversible phenomenon that subjects the body to numerous changes in the physiological process, characterized by a gradual decline in the organism's homeostatic mechanisms, closely related to immunosenescence. Here, we evaluated the regulation of immunosenescence in lymphoid organs of senescence-accelerated prone 8 (SAM-P8) and senescence-accelerated resistant 1 (SAM-R1) mice treated with a low dose of rapamycin (RAPA). Mice were treated with a dose of 7.1 µg/kg RAPA for 2 months and had body mass and hematological parameters analyzed prior and during treatment. Cellular and humoral parameters of serum, bone marrow, thymus, and spleen samples were evaluated by ELISA, histology, and flow cytometry. Changes in body mass, hematological parameters, cell number, and in the secretion of IL-1β, IL-6, TNF-α, IL-7, and IL-15 cytokines were different between the 2 models used. In histological analyses, we observed that SAM-P8 mice showed faster thymic involution than SAM-R1 mice. Regarding the T lymphocyte subpopulations in the spleen, CD4+ and CD8+ T cell numbers were higher and lower, respectively, in SAM-P8 mice treated with RAPA, with the opposite observed in SAM-R1. Additionally, we found that the low dose of RAPA used did not trigger changes that could compromise the immune response of these mice and the administered dose may have contributed to changes in important lymphocyte populations in the adaptive immune response and the secretion of cytokines that directly collaborate with the maturation and proliferation of these cells.

Role of thymosin α1 in restoring immune response in immunological nonresponders living with HIV.

Chaoyu Chen, Jiangrong Wang, Jingna Xun +6 more

Immunological nonresponders (INRs) living with HIV are at increased risk of co-infection and multiple tumors, with no effective strategy currently available to restore their T-cell immune response. This study aimed to explore the safety and efficacy of thymosin α1 in reconstituting the immune response in INRs.

Age-associated impairment of T cell immunity is linked to sex-dimorphic elevation of N-glycan branching.

Haik Mkhikian, Ken L Hayama, Khachik Khachikyan +15 more

Impaired T cell immunity with aging increases mortality from infectious disease. The branching of Asparagine-linked glycans is a critical negative regulator of T cell immunity. Here we show that branching increases with age in females more than males, in naïve more than memory T cells, and in CD4+ more than CD8+ T cells. Female sex hormones and thymic output of naïve T cells (TN) decrease with age, however neither thymectomy nor ovariectomy altered branching. Interleukin-7 (IL-7) signaling was increased in old female more than male mouse TN cells, and triggered increased branching. N-acetylglucosamine, a rate-limiting metabolite for branching, increased with age in humans and synergized with IL-7 to raise branching. Reversing elevated branching rejuvenated T cell function and reduced severity of Salmonella infection in old female mice. These data suggest sex-dimorphic antagonistic pleiotropy, where IL-7 initially benefits immunity through TN maintenance but inhibits TN function by raising branching synergistically with age-dependent increases in N-acetylglucosamine.

Calorie restriction modulates neuro-immune system differently in young and aged rats.

Apala Chakraborty, Soumyabrata Banerjee, Biswajit Mukherjee +2 more

Aging weakens and deregulates the immune system and plays an impact on the central nervous system (CNS). A crosstalk in between the CNS-mediated immune system and the body's overall innate immunity is often found to increase and subsequently accelerate neurodegeneration and behavioural impairment during aging. Dietary calorie restriction (CR) is found to be a beneficial non-invasive anti-aging therapy as it shows rejuvenation of stress response, brain functions and behaviour during aging. The present investigation deals with the consequence of CR diet supplementation for two different duration (one and two consecutive months) on aging-related alteration of the immune response in male albino Wistar rats at the level of (a) lymphocyte viability, proliferation, cytotoxicity, and DNA fragmentation in blood, spleen, and thymus and (b) cytokines (IL-6, IL-10, and TNF-α) in blood, spleen, thymus and different brain-regions to understand the effect of CR diet on neuroimmune system. The results depict that CR diet consumption for consecutive one and two months by the aged (18 and 24 months) rats significantly attenuated the aging-related (a) decrease of blood, splenic and thymic lymphocyte viability, proliferative activity, cytotoxicity, and IL-10 level and (b) increase of (i) blood, splenic and thymic DNA fragmentation and (ii) IL-6 and TNF-α level in those tissues and also in different brain regions. Unlike older rats, in young (4 months) rats, the consumption of CR diet under similar conditions affected those above-mentioned immune parameters reversibly and adversely. This study concludes that (a) aging significantly (p < 0.01) deregulates the above-mentioned immune parameters, (b) consecutive consumption of CR diet for one and two months is (i) beneficial (p < 0.05) to the aging-related immune system [lymphocyte viability, lymphocyte proliferation, cytotoxicity, pro (IL-6 and TNF-α)- and anti (IL-10)-inflammatory cytokines], but (ii) adverse (p < 0.05) to the immune parameters of the young rats, and (c) consumption of CR diet for consecutive two months is more potent (p < 0.05) than that due to one month.

Naïve Regulatory T Cell Subset Is Altered in X-Linked Agammaglobulinemia.

Pavel V Shelyakin, Ksenia R Lupyr, Evgeny S Egorov +13 more

The interplay between T- and B-cell compartments during naïve, effector and memory T cell maturation is critical for a balanced immune response. Primary B-cell immunodeficiency arising from X-linked agammaglobulinemia (XLA) offers a model to explore B cell impact on T cell subsets, starting from the thymic selection. Here we investigated characteristics of naïve and effector T cell subsets in XLA patients, revealing prominent alterations in the corresponding T-cell receptor (TCR) repertoires. We observed immunosenescence in terms of decreased diversity of naïve CD4+ and CD8+ TCR repertoires in XLA donors. The most substantial alterations were found within naïve CD4+ subsets, and we have investigated these in greater detail. In particular, increased clonality and convergence, along with shorter CDR3 regions, suggested narrower focused antigen-specific maturation of thymus-derived naïve Treg (CD4+CD45RA+CD27+CD25+) in the absence of B cells - normally presenting diverse self and commensal antigens. The naïve Treg proportion among naïve CD4 T cells was decreased in XLA patients, supporting the concept of impaired thymic naïve Treg selection. Furthermore, the naïve Treg subset showed prominent differences at the transcriptome level, including increased expression of genes specific for antigen-presenting and myeloid cells. Altogether, our findings suggest active B cell involvement in CD4 T cell subsets maturation, including B cell-dependent expansion of the naïve Treg TCR repertoire that enables better control of self-reactive T cells.

Impact of Aging on the Phenotype of Invariant Natural Killer T Cells in Mouse Thymus.

Georgia Papadogianni, Inga Ravens, Oliver Dittrich-Breiholz +2 more

Invariant natural killer T (iNKT) cells represent a subclass of T cells possessing a restricted repertoire of T cell receptors enabling them to recognize lipid derived ligands. iNKT cells are continuously generated in thymus and differentiate into three main subpopulations: iNKT1, iNKT2, and iNKT17 cells. We investigated the transcriptomes of these subsets comparing cells isolated from young adult (6-10 weeks old) and aged BALB/c mice (25-30 weeks of age) in order to identify genes subject to an age-related regulation of expression. These time points were selected to take into consideration the consequences of thymic involution that radically alter the existing micro-milieu. Significant differences were detected in the expression of histone genes affecting all iNKT subsets. Also the proliferative capacity of iNKT cells decreased substantially upon aging. Several genes were identified as possible candidates causing significant age-dependent changes in iNKT cell generation and/or function such as genes coding for granzyme A, ZO-1, EZH2, SOX4, IGF1 receptor, FLT4, and CD25. Moreover, we provide evidence that IL2 differentially affects homeostasis of iNKT subsets with iNKT17 cells engaging a unique mechanism to respond to IL2 by initiating a slow rate of proliferation.

Thymalin: Activation of Differentiation of Human Hematopoietic Stem Cells.

V Kh Khavinson, N S Linkova, I M Kvetnoy +4 more

Thymalin is a polypeptide complex isolated from the thymus and regulating the functions of the immune system. Thymalin is effective in therapy of acute respiratory syndrome, chronic obstructive bronchitis, and other immunopathology. Thymalin increases functional activity of T lymphocytes, but the targeted molecular mechanism of its biological activity requires further study. We studied the influence of thymalin on differentiation of human hematopoietic stem cells (HSC) and expression of CD28 molecule involved in the implementation of antiviral immunity in COVID-19 infection. It was found that thymalin reduced the expression of CD44 (stem cell marker) and CD117 (molecule of the intermediate stage of HSC differentiation) by 2-3 times and increased the expression of CD28 (marker of mature T lymphocytes) by 6.8 times. This indirectly indicates that thymalin stimulated differentiation of CD117+ cells into mature CD28+T lymphocytes. It is known that in patients with severe COVID-19, the number of CD28+, CD4+, CD8+T lymphocytes in the blood decreased, which attested to a pronounced suppression of immunity. It is possible that the antiviral effect of thymalin consists in compensatory stimulation of HSC differentiation into CD28+T lymphocytes at the stage of immunity suppression in unfavorable course of viral infection. Thymalin can be considered as an immunoprotective peptide drug for the prevention of COVID-19.

Biomodulina T partially restores immunosenescent CD4 and CD8 T cell compartments in the elderly.

Danay Saavedra, Silvia A Fuertes, Gisela M Suárez +8 more

The changes that occur in the immune system with aging are commonly termed immunosenescence. Immunosenescence affects almost all components and functions of the immune response. The most commonly described change is a decrease in numbers and proportions of naïve T cells combined with the increase of terminally differentiated T lymphocytes, mainly affecting CD8+ T cells. The changes in the naïve T cell compartment are principally attributed to thymic involution and lifelong chronic antigen stimulation, among other triggers. Several strategies such as hormonal products, thymic peptides, or cytokines have been proposed for the restoration of the immune system. Here we show the effects of Biomodulina T (BT) on several populations of the immune system when administered to elderly patients diagnosed with recurrent respiratory infections. BT is a polypeptide fraction of bovine thymus, a Cuban product that obtained sanitary registration in 1994 for its immunomodulatory effects. We found that CD4+ naïve T, CD8+ stem cell-like memory (SCM) T, CD4+ recent thymic emigrants (RTE) T and CD4+ CD31+ naïve T cells increased with the administration of BT, whereas CD4+ and CD8+ T cells expressing PD1 decreased after the treatment with BT. Additionally, the proliferative capacity of CD4+ T cells measured by Ki67 expression, and the CD4+ T cell ability to produce IFN-γ were also improved by BT. Moreover, BT did not increase CD4+ Tregs. Altogether, these findings suggest that BT administration is a promising strategy for immune restoration in elderly patients and improvement of immunotherapeutic potential in cancer patients.

Transcription factor networks in aged naïve CD4 T cells bias lineage differentiation.

Bin Hu, Guangjin Li, Zhongde Ye +4 more

With reduced thymic activity, the population of naïve T cells in humans is maintained by homeostatic proliferation throughout adult life. In young adults, naïve CD4 T cells have enormous proliferative potential and plasticity to differentiate into different lineages. Here, we explored whether naïve CD4 T-cell aging is associated with a partial loss of this unbiased multipotency. We find that naïve CD4 T cells from older individuals have developed a propensity to develop into TH9 cells. Two major mechanisms contribute to this predisposition. First, responsiveness to transforming growth factor β (TGFβ) stimulation is enhanced with age due to an upregulation of the TGFβR3 receptor that results in increased expression of the transcription factor PU.1. Secondly, aged naïve CD4 T cells display altered transcription factor profiles in response to T-cell receptor stimulation, including enhanced expression of BATF and IRF4 and reduced expression of ID3 and BCL6. These transcription factors are involved in TH9 differentiation as well as IL9 transcription suggesting that the aging-associated changes in the transcription factor profile favor TH9 commitment.

Cell-type-specific role of lamin-B1 in thymus development and its inflammation-driven reduction in thymus aging.

Sibiao Yue, Xiaobin Zheng, Yixian Zheng

Cellular architectural proteins often participate in organ development and maintenance. Although functional decay of some of these proteins during aging is known, the cell-type-specific developmental role and the cause and consequence of their subsequent decay remain to be established especially in mammals. By studying lamins, the nuclear structural proteins, we demonstrate that lamin-B1 functions specifically in the thymic epithelial cells (TECs) for proper thymus organogenesis. An up-regulation of proinflammatory cytokines in the intra-thymic myeloid immune cells during aging accompanies a gradual reduction of lamin-B1 in adult TECs. We show that these cytokines can cause senescence and lamin-B1 reduction of the young adult TECs. Lamin-B1 supports the expression of TEC genes that can help maintain the adult TEC subtypes we identified by single-cell RNA-sequencing, thymic architecture, and function. Thus, structural proteins involved in organ building and maintenance can undergo inflammation-driven decay which can in turn contribute to age-associated organ degeneration.

Immunosenescence-like state is accelerated by constant light exposure and counteracted by melatonin or turmeric administration through DJ-1/Nrf2 and P53/Bax pathways.

Hanan A El-Bakry, Ismail Ahmed Ismail, Safaa S Soliman

The awareness of the interrelationship between immunosenescence and constant light exposure can provide new insights into the consequences of excessive exposure to light at night due to light pollution or shift work. Here, we investigated whether constant light exposure (LL) acts as an inducer of immunosenescence. We also determined the role of melatonin or turmeric in reversing the putative effects of constant light and explored for the first time the underlying molecular mechanisms. Young (3-4-month-old) rats were exposed daily to LL alone or in combination with each of melatonin and turmeric for 12 weeks. A group of aged rats (18-months old; n = 6) was used as a reference for natural immunosenescence. Constant light exposure resulted in remarkable pathophysiological alterations resembling those noticed in normal aged rats, manifested as apparent decreases in antioxidant activities as well as Nrf2 and DJ-1 expressions, striking augmentation in oxidative stress, proinflammatory cytokines and expression of TNFα, Bax, and p53 genes, and deleterious changes of lymphoid organs, Co-administration of melatonin or turmeric was able to reverse all alterations induced by LL through upregulation of Nrf2/DJ-1 and downregulation of p53/Bax pathways. These data suggest that LL accelerates immunosenescence via oxidative stress and apoptotic pathways. They also demonstrate for the first time that turmeric is comparable to melatonin in boosting the immune function and counteracting the LL-associated immunosenescence. These effects suggest that turmeric supplementation can be used as an inexpensive intervention to prevent circadian disruption-related immunosenescence. However, to validate the effects of turmeric on humans further studies are warranted.

[Transplantation of bone marrow mesenchymal stem cell improves antioxidant capacity and immune activity of aging model rats ].

Zhihong Wang, Yun Lin, Weimin Chen +2 more

To investigate the impact of bone marrow mesenchymal stem cell( BMSC) transplantation on the antioxidant capacity and immune activity of aging rats induced by D-galactose.

[Immune system and rheumatic diseases in the elderly].

Michael Schirmer

Impairments of the immune system play an important role in all immun-mediated rheumatic diseases. Recently, the following news were reported: · Early aging of the immune system with thymus insufficiency has now been reported for both patients with rheumatoid arthritis and axial spondyloarthritis, without prethymic lack of progenitors at least in rheumatoid arthritis.. · For giant cell arteritis, the most frequent vasculitis in the elderly, an increased expression of IL-17A in temporal artery biopsies coincides with good prognosis and reponse to glucocorticoids.. · Concerning immunosenescence in systemic lupus erythematosus, BAFF appears to have an important role for relapses after B-cell depletion.. For the future it can be anticipated that the use of unified classification criteria for rheumatic diseases (as with the new 2012 EULAR / ACR classification criteria for polymyalgia rheumatica) will ensure better comparability of immunological studies also in the elderly.

T cell senescence and cardiovascular diseases.

Hee Tae Yu, Sungha Park, Eui-Cheol Shin +1 more

Age-related changes in the immune system, commonly termed "immunosenescence," contribute to deterioration of the immune response and fundamentally impact the health and survival of elderly individuals. Immunosenescence affects both the innate and adaptive immune systems; however, the most notable changes are in T cell immunity and include thymic involution, the collapse of T cell receptor (TCR) diversity, an imbalance in T cell populations, and the clonal expansion of senescent T cells. Senescent T cells have the ability to produce large quantities of proinflammatory cytokines and cytotoxic mediators; thus, they have been implicated in the pathogenesis of many chronic inflammatory diseases. Recently, an increasing body of evidence has suggested that senescent T cells also have pathogenic potential in cardiovascular diseases, such as hypertension, atherosclerosis, and myocardial infarction, underscoring the detrimental roles of these cells in various chronic inflammatory responses. Given that cardiovascular disease is the number one cause of death worldwide, there is great interest in understanding the contribution of age-related immunological changes to its pathogenesis. In this review, we discuss general features of age-related alterations in T cell immunity and the possible roles of senescent T cells in the pathogenesis of cardiovascular disease.

Immunometabolism: Unravelling the puzzle to longevity and immunity.

Elisabeth Kugelberg

Prolongevity hormone FGF21 protects against immune senescence by delaying age-related thymic involution.

Yun-Hee Youm, Tamas L Horvath, David J Mangelsdorf +2 more

Age-related thymic degeneration is associated with loss of naïve T cells, restriction of peripheral T-cell diversity, and reduced healthspan due to lower immune competence. The mechanistic basis of age-related thymic demise is unclear, but prior evidence suggests that caloric restriction (CR) can slow thymic aging by maintaining thymic epithelial cell integrity and reducing the generation of intrathymic lipid. Here we show that the prolongevity ketogenic hormone fibroblast growth factor 21 (FGF21), a member of the endocrine FGF subfamily, is expressed in thymic stromal cells along with FGF receptors and its obligate coreceptor, βKlotho. We found that FGF21 expression in thymus declines with age and is induced by CR. Genetic gain of FGF21 function in mice protects against age-related thymic involution with an increase in earliest thymocyte progenitors and cortical thymic epithelial cells. Importantly, FGF21 overexpression reduced intrathymic lipid, increased perithymic brown adipose tissue, and elevated thymic T-cell export and naïve T-cell frequencies in old mice. Conversely, loss of FGF21 function in middle-aged mice accelerated thymic aging, increased lethality, and delayed T-cell reconstitution postirradiation and hematopoietic stem cell transplantation (HSCT). Collectively, FGF21 integrates metabolic and immune systems to prevent thymic injury and may aid in the reestablishment of a diverse T-cell repertoire in cancer patients following HSCT.

Somatotrope GHRH/GH/IGF-1 axis at the crossroads between immunosenescence and frailty.

Gwennaelle Bodart, Lindsay Goffinet, Gabriel Morrhaye +6 more

Immunosenescence, characterized by complex modifications of immunity with age, could be related to frailty syndrome in elderly individuals, leading to an inadequate response to minimal aggression. Functional decline (i.e., the loss of ability to perform activities of daily living) is related to frailty and decreased physiological reserves and is a frequent outcome of hospitalization in older patients. Links between immunosenescence and frailty have been explored and 20 immunological parameters, including insulin-like growth factor-1 (IGF-1), thymopoeisis, and telomere length, were shown to be affected in elderly patients with functional decline. A strong relationship between IGF-1 and thymic ouput was evidenced. IGF-1, a mediator of growth hormone (GH), was subsequently shown to induce interleukin-7 secretion in cultured primary human thymic epithelial cells. We are exploring the stress hypothesis in which an acute stressor is used as the discriminator of frailty susceptibility. GH can counteract the deleterious immunosuppressive effects of stress-induced steroids. Under nonstress conditions, the immunosenescent system preserves physiological responses, while under stress conditions, the combination of immunosenescence and a defect in the somatotrope axis might lead to functional decline.

[Clinical consequences of immunosenescence in chronic kidney diseases].

Jamal Bamoulid, Clémence Carron, Thomas Crépin +2 more

Diversity and clonal selection in the human T-cell repertoire.

Qian Qi, Yi Liu, Yong Cheng +7 more

T-cell receptor (TCR) diversity, a prerequisite for immune system recognition of the universe of foreign antigens, is generated in the first two decades of life in the thymus and then persists to an unknown extent through life via homeostatic proliferation of naïve T cells. We have used next-generation sequencing and nonparametric statistical analysis to estimate a lower bound for the total number of different TCR beta (TCRB) sequences in human repertoires. We arrived at surprisingly high minimal estimates of 100 million unique TCRB sequences in naïve CD4 and CD8 T-cell repertoires of young adults. Naïve repertoire richness modestly declined two- to fivefold in healthy elderly. Repertoire richness contraction with age was even less pronounced for memory CD4 and CD8 T cells. In contrast, age had a major impact on the inequality of clonal sizes, as estimated by a modified Gini-Simpson index clonality score. In particular, large naïve T-cell clones that were distinct from memory clones were found in the repertoires of elderly individuals, indicating uneven homeostatic proliferation without development of a memory cell phenotype. Our results suggest that a highly diverse repertoire is maintained despite thymic involution; however, peripheral fitness selection of T cells leads to repertoire perturbations that can influence the immune response in the elderly.

The polyfunctionality of human memory CD8+ T cells elicited by acute and chronic virus infections is not influenced by age.

Alina Lelic, Chris P Verschoor, Mario Ventresca +6 more

As humans age, they experience a progressive loss of thymic function and a corresponding shift in the makeup of the circulating CD8+ T cell population from naïve to memory phenotype. These alterations are believed to result in impaired CD8+ T cell responses in older individuals; however, evidence that these global changes impact virus-specific CD8+ T cell immunity in the elderly is lacking. To gain further insight into the functionality of virus-specific CD8+ T cells in older individuals, we interrogated a cohort of individuals who were acutely infected with West Nile virus (WNV) and chronically infected with Epstein Barr virus (EBV) and Cytomegalovirus (CMV). The cohort was stratified into young (<40 yrs), middle-aged (41-59 yrs) and aged (>60 yrs) groups. In the aged cohort, the CD8+ T cell compartment displayed a marked reduction in the frequency of naïve CD8+ T cells and increased frequencies of CD8+ T cells that expressed CD57 and lacked CD28, as previously described. However, we did not observe an influence of age on either the frequency of virus-specific CD8+ T cells within the circulating pool nor their functionality (based on the production of IFNγ, TNFα, IL2, Granzyme B, Perforin and mobilization of CD107a). We did note that CD8+ T cells specific for WNV, CMV or EBV displayed distinct functional profiles, but these differences were unrelated to age. Collectively, these data fail to support the hypothesis that immunosenescence leads to defective CD8+ T cell immunity and suggest that it should be possible to develop CD8+ T cell vaccines to protect aged individuals from infections with novel emerging viruses.