Project description:Periodontitis is increasingly linked to diverse brain disorders, yet causal mechanisms remain elusive. Here we demonstrate that ligature-induced oral dysbiosis in mice is sufficient to perturb central function. Six weeks of periodontitis produced anxiety-like behavior and motor deficits, accompanied by microglial depletion, reduced neuronal activity and region-selective transcriptional down-regulation in the frontal cortex. Pharmacological microglial ablation phenocopied, and glucocorticoid-receptor blockade rescued, these abnormalities, implicating microglia and activation of the hypothalamic–pituitary–adrenal axis. 16S rRNA gene sequencing revealed significant shifts in oral and gut microbiota that were partially normalized by a broad-spectrum antibiotic cocktail. Antibiotics alone elevated corticosterone but did not affect microglia or behavior, indicating that dysbiosis and glucocorticoids act synergistically on the brain dysfunction. Antibiotic treatment restored microglial density and behaviors in ligature mice, despite plasma corticosterone levels remaining elevated and comparable to those in antibiotic-treated controls. Our findings suggest oral dysbiosis as a tractable driver of neuroimmune dysfunction and redefine periodontitis as a systemic disorder with direct consequences for brain health.

Project description:The goal of this study was to understand the link between maternal oral dysbiosis and the gut health of offspring. We demonstrate that maternal oral dysbiosis can have lasting health impacts on offspring. Ligature-induced periodontitis in mothers promotes the expansion of oral pathobionts in the mouth, which are transmitted to the infant gut, rendering offspring more susceptible to enteritis. Notably, although these maternal oral pathobionts are eradicated as the microbiota matures, the imprinted susceptibility to enteritis persists into adulthood.

Project description:Purpose: The goal of this study was to characterize the gingival oral barrier immunity of mouse periodontitis gingiva. Method: A silk thread (ligature) was tied wround the mouse maxillary molar. Mouse palatal gingiva was harvested at 1 days after the ligature placement. Gingival cells were harvested and subjected to 10X Genomix scRNA-seq. Cell Ranger processed data were analysed.

Project description:Purpose: The goal of this study was to characterize the gingival oral barrier immunity of mouse early periodontitis gingiva. Method: A silk thread (ligature) was tied wround the mouse maxillary molar. Mouse palatal gingiva was harvested at 1 days after the ligature placement. Gingival cells were harvested and subjected to 10X Genomix scRNA-seq. Cell Ranger processed data were analysed.

Project description:Genetic defects in neutrophil function or trafficking are highly associated with oral inflammation and periodontitis. The leukocyte NADPH oxidase enzymes complex is a multi-subunit enzyme that has been described to play important immunomodulatory roles in limiting the inflammatory responses of neutrophils and macrophages. Here, we determined the impact of loss of NADPH oxidase dependent reactive oxygen species (ROS) generation in gingival inflammatory responses using a model of ligature induced murine periodontitis.

Project description:Microglia colonize the brain parenchyma at early stages of development and accumulate in specific regions where they actively participate in cell death, angiogenesis, neurogenesis and synapse elimination. A recurring feature of embryonic microglial distribution is their association with developing axon tracts which, together with in vitro data, supports the idea of a physiological role for microglia in neurite development. Yet the demonstration of this role of microglia is still lacking. Here, we have studied the consequences of microglial dysfunction on the formation of the corpus callosum, the largest connective structure in the mammalian brain, which shows consistent microglial accumulation during development. We studied two models of microglial dysfunction: the loss-of-function of DAP12, a key microglial-specific signaling molecule, and a model of maternal inflammation by peritoneal injection of LPS at E15.5. We performed transcriptional profiling of maternally inflamed and Dap12-mutant microglia at E17.5. We found that both treatments principally down-regulated genes involved in nervous system development and function, particularly in neurite formation. We then analyzed the functional consequences of these microglial dysfunctions on the formation of the corpus callosum. We also took advantage of the Pu.1-/- mouse line, which is devoid of microglia. We now show that all three models of altered microglial activity resulted in the same defasciculation phenotype. Our study demonstrates that microglia are actively involved in the fasciculation of corpus callosum axons. To investigate possible roles for microglial during brain development, we challenged microglial function by two complementary approaches. First, we induced maternal inflammation by peritoneal injection of LPS into pregnant dams. Next, we analyzed the consequences of a loss of function of DAP12, a signaling molecule specifically expressed in microglia that is crucial for several aspects of microglia biology (references in Wakselman et al., 2008). We compared the gene expression profiles of microglia from control, maternally-inflamed by LPS (MI), and Dap12-mutated embryos. We isolated RNA from FACS sorted maternally inflamed (by LPS) and Dap12-mutant microglia at E17.5 pooled per pregnant dam; as a control we included PBS treated and untreated (UT) microglia. We compared gene expression between maternally inflamed microlgia (PBSvsLPS) and DAP12-mutant microglia (UTvsDAP12KO).

Project description:Ligature induced periodontitis in mice

Project description:Microglia, the resident immune cells of the central nervous system (CNS), have two distinct phenotypes in the developing brain: amoeboid form, known to be amoeboid microglial cells (AMC) and ramified form, known to be ramified microglial cells (RMC) alongside several intermediate forms. The AMC are characterized by being proliferative, phagocytic and migratory whereas the RMC are quiescent and exhibit a slow turnover rate. The AMC transform into RMC with advancing age, and this transformation is indicative of the gradual shift in the microglial functions. Both AMC and RMC respond to CNS inflammation, and they become hypertrophic when they are activated by trauma, infection or neurodegenerative stimuli. The molecular mechanisms and functional significance of morphological transformation of microglia during normal development and in disease conditions is not clear. It is hypothesized that AMC and RMC are functionally regulated by a specific set of genes encoding various signaling molecules and transcription factors. To address this, we carried out cDNA microarray analysis using lectin-labeled AMC and RMC isolated from frozen tissue sections of the corpus callosum of 5-day and 4-week old rat brain respectively, by laser capture microdissection (LCM). The global gene expression profiles of both microglial phenotypes were compared and the differentially expressed genes in AMC and RMC were clustered based on their functional annotations. This genome wide comparative analysis helps in identifying genes that are specific to AMC and RMC. The novel and specific molecules identified in both microglial phenotypes can be targeted for therapeutic purposes in developing and adult brain diseases. We used microarrays to identify the genes specific to amoeboid and ramified microglia. RNA was isolated from the laser-captured amoeboid and ramified microglia from the corpus callosum of 5-day and 4-week old rat brain. The RNA was hybridised onto Affymetrix Rat 230 2.0 array.

Project description:We assessed the transcriptomic profile at the late stage on day 10 at the end of the ligature-induced periodontitis model through RNA-seq.

Project description:Neuroligin-4 (NL4) loss-of-function mutations are strongly associated with monogenic heritable abnormalities linked with Autism Spectrum Disorder (ASD). NL4 mutation in mice causes ASD related alterations in both, the synaptic and behavioral phenotype. Since microglia closely regulate synaptic development and are implicated as key players in ASD development and progression, we here studied microglial properties in the NL4-/- mouse model. We show that loss of NL4 caused altered behavior and impaired hippocampal gamma oscillations predominantly in male mice. In parallel, microglial density, morphology, and response to injury specifically in the CA3 region of the hippocampus were altered in NL4-deficient males only. A transcriptomic and proteomic analysis revealed a strong impact of sexual dimorphism on molecular alterations in microglia of NL4-deficient compared to wildtype mice. Estrogen application in male NL4-/- animals partially restored the impaired social behavior and the altered microglial phenotype. Together, these results indicate that loss of NL4 affects not only neuronal network activity and behavior, but changes in addition the phenotype of microglia in a sex-specific manner that could be targeted by estrogen treatment.