Subhasis Mohanty

Age-associated decrease in TLR function in primary human dendritic cells predicts influenza vaccine response.

We evaluated TLR function in primary human dendritic cells (DCs) from 104 young (age 21–30 y) and older (≥65 y) individuals. We used multicolor flow cytometry and intracellular cytokine staining of myeloid DCs (mDCs) and plasmacytoid DCs (pDCs) and found substantial decreases in older compared with young individuals in TNF-α, IL-6, and/or IL-12 (p40) production in mDCs and in TNF-α and IFN-α production in pDCs in response to TLR1/2, TLR2/6, TLR3, TLR5, and TLR8 engagement in mDCs and TLR7 and TLR9 in pDCs. These differences were highly significant after adjustment for heterogeneity between young and older groups (e.g., gender, race, body mass index, number of comorbid medical conditions) using mixed-effect statistical modeling. Studies of surface and intracellular expression of TLR proteins and of TLR gene expression in purified mDCs and pDCs revealed potential contributions for both transcriptional and posttranscriptional mechanisms in these age-associated effects. Moreover, intracellular cytokine production in the absence of TLR ligand stimulation was elevated in cells from older compared with young individuals, suggesting a dysregulation of cytokine production that may limit further activation by TLR engagement. Our results provide evidence for immunosenescence in DCs; notably, defects in cytokine production were strongly associated with poor Ab response to influenza immunization, a functional consequence of impaired TLR function in the aging innate immune response.

Age-Associated Defect in Human TLR-1/2 Function

The effects of aging on human TLR function remain incompletely understood. We assessed TLR function and expression in peripheral blood monocytes from 159 subjects in 2 age categories, 21–30 and >65 years of age, using a multivariable mixed effect model. Using flow cytometry to assess TLR-induced cytokine production, we observed a substantial, highly significant defect in TLR1/2-induced TNF-α (p = 0.0003) and IL-6 (p < 0.0001) production, in older adults compared with young controls. In contrast to findings in aged mice, other TLR (including TLR2/6)-induced cytokine production appeared largely intact. These differences were highly significant even after correcting for covariates including gender, race, medications, and comorbidities. This defect in TLR1/2 signaling may result from alterations in baseline TLR1 surface expression, which was decreased by 36% in older adults (p < 0.0001), whereas TLR2 surface expression was unaffected by aging. Production of IL-6 (p < 0.0001) and TNF-α (p = 0.003) after stimulation by N-palmitoyl-S-[2,3-bis(palmitoyloxy)-(2R,S)-propyl]-Cys-[S]-Ser1-[S]-Lys(4) trihydrochloride was strongly associated with TLR1 surface expression. Diminished TLR1/2 signaling may contribute to the increased infection-related morbidity and mortality and the impaired vaccine responses observed in aging humans.

Prevaccine Determination of the Expression of Costimulatory B7 Molecules in Activated Monocytes Predicts Influenza Vaccine Responses in Young and Older Adults

BACKGROUND Innate immunity, including Toll-like receptor (TLR)-mediated expression of the B7 costimulatory molecules CD80 and CD86, is critical for vaccine immunity. We examined whether CD80 and CD86 expression vary with aging and predict response to the trivalent inactivated influenza vaccine. METHODS One hundred sixty-two subjects between 21 and 30 years of age (the young group) or > or =65 years of age (the older group) enrolled before vaccination. We determined TLR-induced monocyte CD80/CD86 expression by flow cytometry and vaccine antibody responses by hemagglutination inhibition. RESULTS The mean increase in TLR-induced CD80(+) monocytes was reduced in older, compared with young, adults by 68% (P=.0002), and each decile increase of CD80(+) cells was associated with an 8.5% increase in mean number of vaccine strains with a > or =4-fold titer increase (P=.01) and a 3.8% increase in mean number of strains with a postvaccine titer > or =1 : 64 (P=.037). Each decile decrease of CD86(+) cells was associated with an 11% increase in the mean number of strains with a 4-fold increase (P=.002) and a 3.9% increase in the mean number of strains with a postvaccine titer > or =1 : 64 (P=.07). CONCLUSIONS CD80 and CD86 expression on activated monocytes is highly associated with influenza vaccine response. This approach prospectively identifies adults unlikely to respond to immunization who may benefit from alternative vaccines or antiviral prophylaxis during influenza outbreaks.

Top3β is an RNA topoisomerase that works with fragile X syndrome protein to promote synapse formation

Topoisomerases are crucial for solving DNA topological problems, but they have not been linked to RNA metabolism. Here we show that human topoisomerase 3β (Top3β) is an RNA topoisomerase that biochemically and genetically interacts with FMRP, a protein that is deficient in fragile X syndrome and is known to regulate the translation of mRNAs that are important for neuronal function, abnormalities of which are linked to autism. Notably, the FMRP-Top3β interaction is abolished by a disease-associated mutation of FMRP, suggesting that Top3β may contribute to the pathogenesis of mental disorders. Top3β binds multiple mRNAs encoded by genes with neuronal functions linked to schizophrenia and autism. Expression of one such gene, that encoding protein tyrosine kinase 2 (ptk2, also known as focal adhesion kinase or FAK), is reduced in the neuromuscular junctions of Top3β mutant flies. Synapse formation is defective in Top3β mutant flies and mice, as well as in FMRP mutant flies and mice. Our findings suggest that Top3β acts as an RNA topoisomerase and works with FMRP to promote the expression of mRNAs that are crucial for neurodevelopment and mental health.

Mx1 reveals innate pathways to antiviral resistance and lethal influenza disease

Flu immunity shows its age As we age, our immune systems change; in many ways not for the better. For instance, the elderly account for 90% of influenza deaths annually. Pillai et al. now report that influenza-infected human monocytes, a type of immune cell, exhibit reduced antiviral activity. In influenza-infected mice, two innate immune sensing pathways work together to promote antiviral immunity to influenza. Mice lacking antiviral immunity (similar to the situation in elderly people) had elevated bacterial burdens in their lungs and increased inflammatory responses, which both contributed to their increased susceptibility to influenza. Science, this issue p. 463 How age and the innate immune system affect influenza immunity is discussed. Influenza A virus (IAV) causes up to half a million deaths worldwide annually, 90% of which occur in older adults. We show that IAV-infected monocytes from older humans have impaired antiviral interferon production but retain intact inflammasome responses. To understand the in vivo consequence, we used mice expressing a functional Mx gene encoding a major interferon-induced effector against IAV in humans. In Mx1-intact mice with weakened resistance due to deficiencies in Mavs and Tlr7, we found an elevated respiratory bacterial burden. Notably, mortality in the absence of Mavs and Tlr7 was independent of viral load or MyD88-dependent signaling but dependent on bacterial burden, caspase-1/11, and neutrophil-dependent tissue damage. Therefore, in the context of weakened antiviral resistance, vulnerability to IAV disease is a function of caspase-dependent pathology.

Prolonged Proinflammatory Cytokine Production in Monocytes Modulated by Interleukin 10 After Influenza Vaccination in Older Adults

We evaluated in vivo innate immune responses in monocyte populations from 67 young (aged 21-30 years) and older (aged ≥65 years) adults before and after influenza vaccination. CD14(+)CD16(+) inflammatory monocytes were induced after vaccination in both young and older adults. In classical CD14(+)CD16(-) and inflammatory monocytes, production of tumor necrosis factor α and interleukin 6, as measured by intracellular staining, was strongly induced after vaccination. Cytokine production was strongly associated with influenza vaccine antibody response; the highest levels were found as late as day 28 after vaccination in young subjects and were substantially diminished in older subjects. Notably, levels of the anti-inflammatory cytokine interleukin 10 (IL-10) were markedly elevated in monocytes from older subjects before and after vaccination. In purified monocytes, we found age-associated elevation in phosphorylated signal transducer and activator of transcription-3, and decreased serine 359 phosphorylation of the negative IL-10 regulator dual-specificity phosphatase 1. These findings for the first time implicate dysregulated IL-10 production in impaired vaccine responses in older adults.

Defective p53 engagement after the induction of DNA damage in cells deficient in topoisomerase 3β

The type IA topoisomerases have been implicated in the repair of dsDNA breaks by homologous recombination and in the resolution of stalled or damaged DNA replication forks; thus, these proteins play important roles in the maintenance of genomic stability. We studied the functions of one of the two mammalian type IA enzymes, Top3β, using murine embryonic fibroblasts (MEFs) derived from top3β−/− embryos. top3β−/− MEFs proliferated more slowly than TOP3β+/+ control MEFs, demonstrated increased sensitivity to DNA-damaging agents such as ionizing and UV radiation, and had increased DNA double-strand breaks as manifested by increased γ-H2-AX phosphorylation. However, incomplete enforcement of the G1–S cell cycle checkpoint was observed in top3β−/− MEFs. Notably, ataxia-telangiectasia, mutated (ATM)/ATM and Rad3-related (ATR)-dependent substrate phosphorylation after UV-B and ionizing radiation was impaired in top3β−/− versus TOP3β+/+ control MEFs, and impaired up-regulation of total and Ser-18-phosphorylated p53 was observed in top3β−/− cells. Taken together, these results suggest an unanticipated role for Top3β beyond DNA repair in the activation of cellular responses to DNA damage.

Defective signal transduction in B lymphocytes lacking presenilin proteins

The mammalian presenilin (PS) proteins mediate the posttranslational cleavage of several protein substrates, including amyloid precursor protein, Notch family members, and CD44, but they have also been suggested to function in diverse cellular processes, including calcium-dependent signaling and apoptosis. We carried out an integrative computational study of multiple genomic datasets, including RNA expression, protein interaction, and pathway analyses, which implicated PS proteins in Toll-like receptor signaling. To test these computational predictions, we analyzed mice carrying a conditional allele of PS1 and a germ line-inactivating allele of PS2, together with Cre site-specific recombinase expression under the influence of CD19 control sequences. Notably, B cells deficient in both PS1 and PS2 function have an unexpected and substantial deficit in both lipopolysaccharide and B cell antigen receptor-induced proliferation and signal transduction events, including a defect in anti-IgM-mediated calcium flux. Taken together, these results demonstrate a fundamental and unanticipated role for PS proteins in B cell function and emphasize the potency of (systems level) integrative analysis of whole-genome datasets in identifying novel biologic signal transduction relationships. Our findings also suggest that pharmacologic inhibition of PS for the treatment of conditions such as Alzheimers disease may have potential consequences for immune system function.

Development of autoimmunity in mice lacking DNA topoisomerase 3β

Mice lacking DNA topoisomerase 3β are predisposed to a shortened lifespan, infertility, and lesions in multiple organs resulting from inflammatory responses. Examination of the immune system of 6- and 52-week-old top3β−/− mice revealed no significant aberrations in their central and peripheral tolerance or in T lymphocyte activation. However, the older but not the younger cohort shows a high incidence of serum autoantibodies relative to their TOP3β+/+ age-mates. The mutant mice also show an increase in numerical aberrations of chromosomes in splenocytes and bone marrow cells, as well as an increase in apoptotic cells in the thymus. Thus, it appears plausible that the inflammatory lesions in top3β−/− mice are caused by the development of autoimmunity as they age: Chromosomal abnormalities in top3β−/− mice might lead to a persistent increase in apoptotic cells, which might in turn lead to the progression of autoimmunity.

DNA Methylation Regulates the Differential Expression of CX3CR1 on Human IL-7Rαlow and IL-7Rαhigh Effector Memory CD8+ T Cells with Distinct Migratory Capacities to the Fractalkine

DNA methylation is an epigenetic mechanism that modulates gene expression in mammalian cells including T cells. Memory T cells are heterogeneous populations. Human effector memory (EM) CD8+ T cells in peripheral blood contain two cell subsets with distinct traits that express low and high levels of the IL-7Rα. However, epigenetic mechanisms involved in defining such cellular traits are largely unknown. In this study, we use genome-wide DNA methylation and individual gene expression to show the possible role of DNA methylation in conferring distinct traits of chemotaxis and inflammatory responses in human IL-7Rαlow and IL-7Rαhigh EM CD8+ T cells. In particular, IL-7Rαlow EM CD8+ T cells had increased expression of CX3CR1 along with decreased DNA methylation in the CX3CR1 gene promoter compared with IL-7Rαhigh EM CD8+ T cells. Altering the DNA methylation status of the CX3CR1 gene promoter changed its activity and gene expression. IL-7Rαlow EM CD8+ T cells had an increased migratory capacity to the CX3CR1 ligand fractalkine compared with IL-7Rαhigh EM CD8+ T cells, suggesting an important biological outcome of the differential expression of CX3CR1. Moreover, IL-7Rαlow EM CD8+ T cells induced fractalkine expression on endothelial cells by producing IFN-γ and TNF-α, forming an autocrine amplification loop. Overall, our study shows the role of DNA methylation in generating unique cellular traits in human IL-7Rαlow and IL-7Rαhigh EM CD8+ T cells, including differential expression of CX3CR1, as well as potential biological implications of this differential expression.