Human peripheral monocytes capture elements of the state of microglial activation in the brain

Despite a growing focus on neuroimmune mechanisms of Alzheimer’s disease (AD), the role of peripheral monocytes remains largely unknown. Circulating monocytes communicate with the brain’s resident myeloid cells, microglia, via chemical signaling and can directly infiltrate the brain parenchyma.1 Thus, molecular signatures of monocytes may serve as indicators of neuropathological events unfolding in the CNS.2–5 However, no studies have yet directly tested the association of monocyte gene expression on longitudinal cognitive decline or postmortem neuropathology and brain gene expression in aging. Here we present a resource of RNA sequencing of purified CD14+ human monocytes - including an eQTL map - from over 200 elderly individuals, most with accompanying bulk brain RNA sequencing profiles, longitudinal cognitive assessments, and detailed postmortem neuropathological examinations. We tested the direct correlation of gene expression between monocytes and bulk brain tissue, finding very few significant signals driven largely by genetic variation. However, we did identify sets of monocyte-expressed genes that were highly predictive of postmortem microglial activation, diffuse amyloid plaque deposition, and cerebrovascular disease. Our findings prioritize potential blood-based molecular biomarkers for AD; they also reveal the previously unknown architecture of shared gene expression between the CNS and peripheral immune system in aging.

Current Knowledge of Microglia in Traumatic Spinal Cord Injury

Microglia are the resident immune cells in the central nervous system (CNS). After traumatic spinal cord injury (SCI), microglia undergo activation, proliferation, and changes in gene and protein expression and morphology, with detrimental and beneficial effects. Activated microglia cause secondary neuronal injury via the production of proinflammatory cytokines, reactive oxygen species, and proteases. However, activated microglia also promote neuronal repair through the secretion of anti-inflammatory growth factors and cytokines. Proinflammatory cytokines increase endothelial permeability, promote A1 astrocyte activation and axonal demyelination, and reduce neural stem/progenitor cells (NSPCs), leading to the exacerbation of neuronal injury. In contrast, anti-inflammatory factors facilitate angiogenesis, reduce reactive astrocytes, and promote axonal remyelination and the propagation of NSPCs, contributing to tissue repair and locomotor recovery. Due to its limited regenerative capacity, the CNS requires beneficial microglia for continuous protection against injury. Understanding and regulating microglial activation status are beneficial to reducing detrimental effects and promoting repair behaviors and to obtain more information on efficient therapies for traumatic SCI. This review discusses microglial activation and the differences between microglia and similar immune cells, microglial interactions with other cells in the spinal cord, and the progress in the development of therapies targeting microglia in SCI.

Evidence of Microglial Immune Response Following Coronavirus PHEV Infection of CNS

Porcine hemagglutinating encephalomyelitis virus (PHEV) is a highly neurotropic coronavirus that invades the host central nervous system (CNS) and causes neurological dysfunction. Microglia are key immune cells in the CNS, however, whether and how they response to PHEV infection remains unclear. Herein, microglial activation and proliferation were detected in the CNS of PHEV-infected mice, as along with the proinflammatory response. Moreover, the production of proinflammatory cytokines induced by moderately activated microglia limited viral replication in the early stage of infection. Microglial depletion assays showed that during late infection, excess activation of microglia aggravated neurological symptoms, BBB destruction, and peripheral monocyte/macrophage infiltration into the CNS. Using an in vitro brain slice model, PHEV was identified to specifically and moderately induce microglial activation in the absence of peripheral immune cells infiltration. Consistently, macrophage clearance from circulating blood indicated that peripheral monocytes/macrophages crossing the BBB of mice were responsible for excess activation of microglia and CNS damage in late PHEV infection. Overall, our findings provide evidence supporting a dual role for microglia in the host CNS in response to coronavirus PHEV invasion.

Perilla frutescens Leaf Extract Attenuates Vascular Dementia-Associated Memory Deficits, Neuronal Damages, and Microglial Activation

Vascular dementia (VaD) is characterized by a time-dependent memory deficit and essentially combined with evidence of neuroinflammation. Thus, polyphenol-rich natural plants, which possess anti-inflammatory properties, have received much scientific attention. This study investigated whether Perilla frutescens leaf extract (PFL) exerts therapeutic efficacy against VaD. Sprague Dawley rats were divided into five groups: SO, sham-operated and vehicle treatment; OP, operated and vehicle treatment; PFL-L, operated and low-dose (30 mg/kg) PFL treatment; PFL-M, operated and medium-dose (60 mg/kg) PFL treatment; and PFL-H, operated and high-dose (90 mg/kg) PFL treatment. Two-vessel occlusion and hypovolemia (2VO/H) were employed as a surgical model of VaD, and PFL was given orally perioperatively for 23 days. The rats underwent the Y-maze, Barnes maze, and passive avoidance tests and their brains were subjected to histologic studies. The OP group showed VaD-associated memory deficits, hippocampal neuronal death, and microglial activation; however, the PFL-treated groups showed significant attenuations in all of the above parameters. Using lipopolysaccharide (LPS)-stimulated BV-2 cells, a murine microglial cell line, we measured PFL-mediated changes on the production of nitric oxide (NO), TNF-α, and IL-6, and the activities of their upstream MAP kinases (MAPKs)/NFκB/inducible NO synthase (iNOS). The LPS-induced upregulations of NO, TNF-α, and IL-6 production and MAPKs/NFκB/iNOS activities were globally and significantly reversed by 12-h pretreatment of PFL. This suggests that PFL can counteract VaD-associated structural and functional deterioration through the attenuation of neuroinflammation.

The Beneficial Effects of Heme Oxygenase 1 and Hydrogen Sulfide Activation in the Management of Neuropathic Pain, Anxiety- and Depressive-like Effects of Paclitaxel in Mice

Chemotherapy-induced peripheral neuropathy constitutes an unresolved clinical problem that severely decreases the quality of the patient’s life. It is characterized by somatosensory alterations, including chronic pain, and a high risk of suffering mental disorders such as depression and anxiety. Unfortunately, an effective treatment for this neuropathology is yet to be found. We investigated the therapeutic potential of cobalt protoporphyrin IX (CoPP), a heme oxygenase 1 inducer, and morpholin-4-ium 4-methoxyphenyl(morpholino) phosphinodithioate dichloromethane complex (GYY4137), a slow hydrogen sulfide (H2S) donor, in a preclinical model of paclitaxel (PTX)-induced peripheral neuropathy (PIPN) in mice. At three weeks after PTX injection, we evaluated the effects of the repetitive administration of 5 mg/kg of CoPP and 35 mg/kg of GYY4137 on PTX-induced nociceptive symptoms (mechanical and cold allodynia) and on the associated emotional disturbances (anxiety- and depressive-like behaviors). We also studied the mechanisms that could mediate their therapeutic properties by evaluating the expression of key proteins implicated in the development of nociception, oxidative stress, microglial activation, and apoptosis in prefrontal cortex (PFC) and dorsal root ganglia (DRG) of mice with PIPN. Results demonstrate that CoPP and GYY4137 treatments inhibited both the nociceptive symptomatology and the derived emotional alterations. These actions were mainly mediated through potentiation of antioxidant responses and inhibiting oxidative stress in the DRG and/or PFC of mice with PIPN. Both treatments normalized some plasticity changes and apoptotic reactions, and GYY4137 blocked microglial activation induced by PTX in PFC. In conclusion, this study proposes CoPP and GYY4137 as good candidates for treating neuropathic pain, anxiety- and depressive-like effects of PTX.

Inhibition of Voltage-Gated Hv1 Alleviates LPS-Induced Neuroinflammation via Regulation of Microglial Metabolic Reprogramming

Background Neuroinflammation plays an important role in the onset and advancement of cognitive loss and neurodegenerative disorders. The voltage-gated H channel (Hv1) has been reported to be involved in microglial activation and act as key drivers of neuroinflammation. This study aims at evaluating the mechanism of Hv1 involvement in neuroinflammation and the therapeutic potential of Hv1 inhibitor, 2-guanidinobenzimidazole (2-GBI), in a model of lipopolysaccharide (LPS)-induced neuroinflammation. Methods We investigated the influence of Hv1 inhibitor (2-GBI) on the generation of reactive oxidative species (ROS), metabolic reprogramming, and inflammatory mediators in vitro and examined the therapeutic potential of 2-GBI on microglial activation and hippocampal neuroinflammation in vivo. Novel object recognition and Y-maze were employed to assess cognitive function. Results 2-GBI reduced the LPS-induced proinflammatory response and aerobic glycolysis in microglia. HIF1α overexpression mediated aerobic glycolysis reprogramming alleviated by 2-GBI. We reported that Hv1 inhibitor exerted a protective effect on LPS-induced neuroinflammation through the ROS/HIF1α and PI3K/AKT/HIF1α pathways -mediated aerobic glycolysis. The cell death of PC12 induced by microglia-mediated neuroinflammation was reversed in a transwell co-culture system by 2-GBI. Furthermore, in vivo results suggested that 2-GBI mitigated the neuroinflammatory processes and recognition injury through regulation of microglial metabolic reprogramming. Conclusion 2-GBI protects LPS-induced neuroinflammation, neuronal cell death, and subsequently reverses the hippocampus-dependent cognitive deficits through regulation of microglial metabolic reprogramming. Taken together, these results demonstrate a key role for Hv1 in driving a pro-inflammatory microglia phenotype in neuroinflammation.