Ageing and interferon gamma response drive the phenotype of neutrophils in the inflamed joint.

OBJECTIVE: Neutrophils are typically the most abundant leucocyte in arthritic synovial fluid. We sought to understand changes that occur in neutrophils as they migrate from blood to joint. METHODS: We performed RNA sequencing of neutrophils from healthy human blood, arthritic blood and arthritic synovial fluid, comparing transcriptional signatures with those from murine K/BxN serum transfer arthritis. We employed mass cytometry to quantify protein expression and sought to reproduce the synovial fluid phenotype ex vivo in cultured healthy blood neutrophils. RESULTS: Blood neutrophils from healthy donors and patients with active arthritis showed largely similar transcriptional signatures. By contrast, synovial fluid neutrophils exhibited more than 1600 differentially expressed genes. Gene signatures identified a prominent response to interferon gamma (IFN-γ), as well as to tumour necrosis factor, interleukin-6 and hypoxia, in both humans and mice. Mass cytometry confirmed that healthy and arthritic donor blood neutrophils are largely indistinguishable but revealed a range of neutrophil phenotypes in synovial fluid defined by downregulation of CXCR1 and upregulation of FcγRI, HLA-DR, PD-L1, ICAM-1 and CXCR4. Reproduction of key elements of this signature in cultured blood neutrophils required both IFN-γ and prolonged culture. CONCLUSIONS: Circulating neutrophils from patients with arthritis resemble those from healthy controls, but joint fluid cells exhibit a network of changes, conserved across species, that implicate IFN-γ response and ageing as complementary drivers of the synovial fluid neutrophil phenotype.

Do later-born birth cohorts of septuagenarians sleep better? A prospective population-based study of two birth cohorts of 70-year-olds.

Study Objectives: To investigate birth cohort differences in the prevalence of insomnia from ages 70 to 79. Methods: Data were drawn from population-based samples of two cohorts of septuagenarians; the early-born 1901-07-cohort, who took part in psychiatric examinations between 1971 and 1986 (n = 681), and the later-born 1930-cohort examined between 2000 and 2010 (n = 943). Examinations were conducted at ages 70, 75, and 79. Criteria for insomnia were identical across cohorts and included sleep dissatisfaction accompanied with complaints of difficulty initiating or maintaining sleep. Associations were analyzed with logistic growth curve models. Results: The later-born cohort had lower odds for insomnia at age 70 (OR = 0.52, 95% CI: 0.32-0.87) compared with the earlier born cohort. Age was not related to insomnia as a main effect but we found an interaction between age and birth cohort (OR = 1.14, 95% CI: 1.08-1.21); insomnia increased with age in the later but not in the early-born cohort. Women had higher odds for insomnia compared with men (OR = 3.10, 95% CI: 2.02-4.74), and there was an interaction between sex and birth cohort (OR = 0.51, 95% CI: 0.30-0.88; there were larger cohort differences among women than among men and less sex differences in the later than in the earlier born cohort. Also, there were no significant differences between the cohorts in taking sleep medications. Conclusions: Our findings provide evidence of improved self-reported sleep in later-born cohorts of septuagenarians, but the difference diminished with age. The prevalence of self-reported insomnia was greater in women than in men, but sex differences were less pronounced in the later-born cohort.

Altered NK cell development and enhanced NK cell-mediated resistance to mouse cytomegalovirus in NKG2D-deficient mice.

NKG2D is a potent activating receptor on natural killer (NK) cells and acts as a molecular sensor for stressed cells expressing NKG2D ligands such as infected or tumor-transformed cells. Although NKG2D is expressed on NK cell precursors, its role in NK cell development is not known. We have generated NKG2D-deficient mice by targeting the Klrk1 locus. Here we provide evidence for an important regulatory role of NKG2D in the development of NK cells. The absence of NKG2D caused faster division of NK cells, perturbation in size of some NK cell subpopulations, and their augmented sensitivity to apoptosis. As expected, Klrk1(-/-) NK cells are less responsive to tumor targets expressing NKG2D ligands. Klrk1(-/-) mice, however, showed an enhanced NK cell-mediated resistance to mouse cytomegalovirus infection as a consequence of NK cell dysregulation. Altogether, these findings provide evidence for regulatory function of NKG2D in NK cell physiology.

Multiple ITAM-coupled NK-cell receptors engage the Bcl10/Malt1 complex via Carma1 for NF-kappaB and MAPK activation to selectively control cytokine production.

Natural killer (NK) cells are innate immune cells that mediate resistance against viruses and tumors. They express multiple activating receptors that couple to immunoreceptor tyrosine-based activation motif (ITAM)-containing signaling chains for downstream cell activation. Ligation of activating NK-cell receptors induces NK-cell cytotoxicity and cytokine release. How these distinct events are selectively controlled is not well defined. Here we report the identification of a specific signaling pathway that operates downstream of the ITAM-coupled NK-cell receptors NK1.1, Ly49D, Ly49H, and NKG2D. Using primary NK cells from Bcl10(-/-), Malt1(-/-), Carma1(-/-), and Card9(-/-) mice, we demonstrate a key role for Bcl10 signalosomes in the activation of canonical NF-kappaB signaling as well as JNK and p38 MAPK upon NK-cell triggering. Bcl10 directly cooperates with Malt1 and depends on Carma1 (Card11) but not on Card9 for NK-cell activation. These Bcl10-dependent cascades selectively control cytokine and chemokine production but do not affect NK-cell differentiation or killing. Thus, we identify a molecular basis for the segregation of NK-cell receptor-induced signals for cytokine release and target cell killing and extend the previously recognized roles for CARD-protein/Bcl10/Malt1 complexes in ITAM receptor signaling in innate and adaptive immune cells.

CD21/CD19 coreceptor signaling promotes B cell survival during primary immune responses.

The adaptive immune response is tightly regulated to limit responding cells in an Ag-specific manner. On B cells, coreceptors CD21/CD19 modulate the strength of BCR signals, potentially influencing cell fate. The importance of the CD95 pathway was examined in response of B cells to moderate affinity Ag using an adoptive transfer model of lysozyme-specific Ig transgenic (HEL immunoglobulin transgene (MD4) strain) B cells. Although adoptively transferred Cr2+/+ MD4 B cells are activated and persist within splenic follicles of duck egg lysozyme-immunized mice, Cr2-/- MD4 B cells do not. In contrast, Cr2-/- MD4 lpr B cells persist after transfer, suggesting that lack of CD21/CD35 signaling results in CD95-mediated elimination. Cr2 deficiency did not affect CD95 levels, but cellular FLIP (c-FLIP) protein and mRNA levels were reduced 2-fold compared with levels in Cr2+/+ MD4 B cells. In vitro culture with Cr2+/+ MD4 B cells demonstrated that equimolar amounts of rHEL-C3d3 were more effective than hen egg lysozyme alone in up-regulating c-FLIP levels and for protection against CD95-mediated apoptosis. Collectively, this study implies a mechanism for regulating B cell survival in vivo whereby the strength of BCR signaling (including coreceptor) determines c-FLIP levels and protection from CD95-induced death.

Inflammatory arthritis requires Foxo3a to prevent Fas ligand-induced neutrophil apoptosis.

In inflammatory arthridities such as rheumatoid arthritis, cognate lymphocytes have long been considered instigators of autoimmunity, but accumulating evidence indicates that innate immune cells such as neutrophils and mast cells are responsible for a vast majority of acute and ongoing inflammation; however, the molecular mechanisms that govern them remain largely unknown. Here we show that such inflammation requires the forkhead transcription factor Foxo3a: Foxo3a-deficient mice are resistant to two models of neutrophilic inflammation, immune complex-mediated inflammatory arthritis and thioglycollate-induced peritonitis. This reflects a need for Foxo3a to maintain neutrophil vitality during inflammation by suppressing Fas ligand; because Foxo3a can bind and suppress the Fasl promoter, Foxo3a-deficient neutrophils upregulate Fas ligand and undergo apoptosis in response to TNF-alpha and IL-1, and Fas ligand blockade renders Foxo3a-deficient mice susceptible to both arthritis and peritonitis. Thus, Foxo3a ensures neutrophil survival during inflammation, identifying Foxo3a as therapeutic target in inflammation.