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Background
Ureaplasma species (spp.) are commonly regarded as low-virulent commensals but may cause invasive diseases in immunocompromised adults and in neonates, including neonatal meningitis. The interactions of Ureaplasma spp. with host defense mechanisms are poorly understood. This study addressed Ureaplasma-driven cell death, concentrating on apoptosis as well as inflammatory cell death.
Methods
Human brain microvascular endothelial cells (HBMEC) were exposed to Ureaplasma (U.) urealyticum serovar 8 (Uu8) and U. parvum serovar 3 (Up3). Resulting numbers of dead cells as well as mRNA levels and enzyme activity of key agents in programmed cell death were assessed by flow cytometry, RNA sequencing, and qRT-PCR, respectively. xCELLigence data were used for real-time monitoring of changes in cell adhesion properties.
Results
Both Ureaplasma isolates induced cell death (p < 0.05, vs. broth). Furthermore, Ureaplasma spp. enhanced mRNA levels for genes in apoptosis, including caspase 3 (Up3 p < 0.05, vs. broth), caspase 7 (p < 0.01), and caspase 9 (Up3 p < 0.01). Caspase 3 activity was increased upon Uu8 exposure (p < 0.01). Vice versa, Ureaplasma isolates downregulated mRNA levels for proteins involved in inflammatory cell death, namely caspase 1 (Uu8 p < 0.01, Up3 p < 0.001), caspase 4 (Uu8 p < 0.05, Up3 p < 0.01), NOD-like receptor pyrin domain-containing 3 (Uu8 p < 0.05), and receptor-interacting protein kinase 3 (p < 0.05).
Conclusions
By inducing apoptosis in HBMEC as main constituents of the blood-brain barrier, Ureaplasma spp. may provoke barrier breakdown. Simultaneous suppression of inflammatory cell death may additionally attenuate host defense strategies. Ultimate consequence could be invasive and long-term CNS infections by Ureaplasma spp.
Multiple sclerosis is an autoimmune disease of the central nervous system characterized by inflammatory, demyelinating lesions and neuronal death. Formerly regarded as a variant of MS, neuromyelitis optica (NMO)/Devic’s disease is now recognized as a distinct neurological disorder exhibiting characteristic inflammatory and demyelinated foci in the optic nerves and the spinal cord sparing the brain. With the introduction of the double-transgenic “Devic mouse” model featuring spontaneous, adjuvant-free incidence of autoimmune neuroinflammation due to the interaction of transgenic MOG-specific T and B cells, a promising tool was found for the analysis of factors triggering or preventing autoimmunity. The co-inhibitory molecule B7-H1 has been proposed to contribute to the maintenance of peripheral tolerance and to confine autoimmune inflammatory damage via the PD-1/B7-H1 pathway. Compared to Devic B7-H1+/+ mice, Devic B7-H1-/- mice developed clinical symptoms with a remarkably higher incidence rate and faster kinetics emphasized by deteriorated disease courses and a nearly quadrupled mortality rate. Remarkably enlarged immune-cell accumulation in the CNS of Devic B7-H1-/- mice, in particular of activated MOG-specific CD4+ T cells, correlated with the more severe clinical features. Our studies showed that the CNS not only was the major site of myelin-specific CD4+ T-cell activation but also that B7-H1 expression within the target organ significantly influenced T-cell activation and differentiation levels. Analysis at disease maximum revealed augmented accumulation of MOG-specific CD4+ T cells in the peripheral lymphoid organs of Devic B7-H1-/- mice partly due to increased T-cell proliferation rates. Transgenic MOG-specific B cells of Devic B7-H1-/- mice activated MOG-specific CD4+ T cells more efficiently than B cells of Devic B7-H1+/+ mice. This observation indicated a relevant immune-modulating role of B7-H1 on APCs (antigen-presenting cells) in this mouse model. We also assumed altered thymic selection processes to be involved in increased peripheral CD4+ T-cell numbers of Devic B7-H1-/- mice as we found more thymocytes expressing the transgenic MOG-specific T-cell receptor (TCR). Moreover, preliminary in vitro experiments hinted on an enhanced survival of TCRMOG-transgenic CD4+ T cells of Devic B7-H1-/- mice; a mechanism that might as well have led to higher peripheral T-cell accumulation. Elevated levels of MOG-specific CD4+ T cells in the periphery of Devic B7-H1-/- mice could have entailed the higher quantities in the CNS. However, mechanisms such as CNS-specific proliferation and/or apoptosis/survival could also have contributed. This should be addressed in future investigations. Judging from in vitro migration assays and adoptive transfer experiments on RAG-1-/- recipient mice, migratory behavior of MOG-specific CD4+ T cells of Devic B7-H1+/+ and Devic B7-H1-/- mice seemed not to differ. However, enhanced expression of the transmigration-relevant integrin LFA-1 on CD4+ T cells in young symptom-free Devic B7-H1-/- mice might hint on temporally differently pronounced transmigration capacities during the disease course. Moreover, we attributed the earlier conversion of CD4+ T cells into Th1 effector cells in Devic B7-H1-/- mice during the initiation phase to the lack of co-inhibitory signaling via PD-1/B7-H1 possibly leading to an accelerated disease onset. Full blown autoimmune inflammatory processes could have masked these slight effects of B7-H1 in the clinical phase. Accordingly, at peak of the disease, Th1 and Th17 effector functions of peripheral CD4+ T cells were comparable in both mouse groups. Moreover, judging from titers of MOG-specific IgG1 and IgM antibodies, alterations in humoral immunity were not detected. Therefore, clinical differences could not be explained by altered T-cell or B-cell effector functions at disease maximum. B7-H1 rather seemed to take inhibitory effect in the periphery during the initiation phase only and consistently within the target organ by parenchymal expression. Our observations indicate that B7-H1 plays a relevant role in the regulation of T-cell responses in this mouse model for spontaneous CNS autoimmunity. By exerting immune-modulating effects in the preclinical as well as the clinical phase of the disease, B7-H1 contributed to the confinement of the immunopathological tissue damage in Devic B7-H1+/+ mice mirrored by later disease onsets and lower disease scores. As a model for spontaneous autoimmunity featuring a close to 100 % incidence rate, the Devic B7-H1-/- mouse may prove instrumental in clarifying disease-triggering and -limiting factors and in validating novel therapeutic approaches in the field of autoimmune neuroinflammation, in particular the human Devic’s disease.
The neuronal ceroid lipofuscinoses (NCLs) are fatal neurodegenerative disorders in which the visual system is affected in early stages of disease. A typical accompanying feature is neuroinflammation, the pathogenic impact of which is presently unknown. In this study, the role of inflammatory cells in the pathogenesis was investigated in Palmitoyl-protein thioesterase 1-deficient (Ppt1-/-) and Ceroidlipofuscinosis, neuronal 3-deficient (Cln3-/-) mice, models of the infantile and juvenile forms of NCL, respectively. Focusing predominantly on the visual system, an infiltration of CD8+ cytotoxic Tlymphocytes and an activation of microglia/macrophage-like cells was observed early in disease. To analyze the pathogenic impact of lymphocytes, Ppt1-/- mice were crossbred with mice lacking lymphocytes (Rag1-/-) and axonal transport, perturbation and neuronal survival were scored. Lack of lymphocytes led to a significant amelioration of neuronal disease and reconstitution experiments revealed a crucial role of CD8+ cytotoxic T-lymphocytes. Lack of lymphocytes also caused an improved clinical phenotype and extended longevity. To investigate the impact of microglia/macrophage-like cells, Ppt1-/- and Cln3-/- mice were crossbred with mice lacking sialoadhesin (Sn-/-), a monocyte lineage-restricted cell adhesion molecule important for interactions between macrophage-like cells and lymphocytes. Similar to the lack of lymphocytes, absence of sialoadhesin significantly ameliorated the disease in Ppt1-/- and Cln3-/- mice. Taken together, both T-lymphocytes and microglia/macrophage-like cells were identified as pathogenic mediators in two distinct forms of fatal inherited neurodegenerative storage disorders. These studies expand the concept of secondary inflammation as a common pathomechanistic feature in some neurological diseases and provide novel insights that may be crucial for developing treatment strategies for different forms of NCL.