Mario Merlini

Fibrinogen-induced perivascular microglial clustering is required for the development of axonal damage in neuroinflammation

Blood-brain barrier disruption, microglial activation and neurodegeneration are hallmarks of multiple sclerosis. However, the initial triggers that activate innate immune responses and their role in axonal damage remain unknown. Here we show that the blood protein fibrinogen induces rapid microglial responses toward the vasculature and is required for axonal damage in neuroinflammation. Using in vivo two-photon microscopy, we demonstrate that microglia form perivascular clusters before myelin loss or paralysis onset and that, of the plasma proteins, fibrinogen specifically induces rapid and sustained microglial responses in vivo. Fibrinogen leakage correlates with areas of axonal damage and induces reactive oxygen species release in microglia. Blocking fibrin formation with anticoagulant treatment or genetically eliminating the fibrinogen binding motif recognized by the microglial integrin receptor CD11b/CD18 inhibits perivascular microglial clustering and axonal damage. Thus, early and progressive perivascular microglial clustering triggered by fibrinogen leakage upon blood-brain barrier disruption contributes to axonal damage in neuroinflammatory disease.

Microglial NFκB-TNFα hyperactivation induces obsessive–compulsive behavior in mouse models of progranulin-deficient frontotemporal dementia

Significance Frontotemporal dementia (FTD) is a disease characterized by degeneration of the frontal and/or temporal lobes of the brain. Symptoms of FTD include changes in personality, such as loss of social awareness and impulse control. A significant portion of inherited FTD cases are due to mutations in progranulin (PGRN). These mutations lead to a decrease in the production of PGRN. How lower levels of PGRN lead to FTD is unknown. Here, we show that humans carrying PGRN mutations and mice lacking PGRN display obsessive–compulsive disorders (OCDs). In mice, OCD behavior results partially from elevated levels of the cytokine TNFα and aberrant activation of immune cells of the brain known as microglia. Our findings provide evidence that targeting innate immune pathways could be a new therapeutic strategy to treat FTD. Frontotemporal dementia (FTD) is the second most common dementia before 65 years of age. Haploinsufficiency in the progranulin (GRN) gene accounts for 10% of all cases of familial FTD. GRN mutation carriers have an increased risk of autoimmune disorders, accompanied by elevated levels of tissue necrosis factor (TNF) α. We examined behavioral alterations related to obsessive–compulsive disorder (OCD) and the role of TNFα and related signaling pathways in FTD patients with GRN mutations and in mice lacking progranulin (PGRN). We found that patients and mice with GRN mutations displayed OCD and self-grooming (an OCD-like behavior in mice), respectively. Furthermore, medium spiny neurons in the nucleus accumbens, an area implicated in development of OCD, display hyperexcitability in PGRN knockout mice. Reducing levels of TNFα in PGRN knockout mice abolished excessive self-grooming and the associated hyperexcitability of medium spiny neurons of the nucleus accumbens. In the brain, PGRN is highly expressed in microglia, which are a major source of TNFα. We therefore deleted PGRN specifically in microglia and found that it was sufficient to induce excessive grooming. Importantly, excessive grooming in these mice was prevented by inactivating nuclear factor κB (NF-κB) in microglia/myeloid cells. Our findings suggest that PGRN deficiency leads to excessive NF-κB activation in microglia and elevated TNFα signaling, which in turn lead to hyperexcitability of medium spiny neurons and OCD-like behavior.

In vivo imaging of the neurovascular unit in CNS disease

The neurovascular unit—comprised of glia, pericytes, neurons and cerebrovasculature— is a dynamic interface that ensures physiological central nervous system (CNS) functioning. In disease dynamic remodeling of the neurovascular interface triggers a cascade of responses that determine the extent of CNS degeneration and repair. The dynamics of these processes can be adequately captured by imaging in vivo, which allows the study of cellular responses to environmental stimuli and cell-cell interactions in the living brain in real time. This perspective focuses on intravital imaging studies of the neurovascular unit in stroke, multiple sclerosis (MS) and Alzheimer disease (AD) models and discusses their potential for identifying novel therapeutic targets.

Sirtuin 5 as a novel target to blunt blood–brain barrier damage induced by cerebral ischemia/reperfusion injury

BACKGROUND In acute ischemic stroke (AIS) patients, impaired blood-brain barrier (BBB) integrity is associated with hemorrhagic transformation and worsened outcome. Yet, the mechanisms underlying these relationships are poorly understood and consequently therapeutic strategies are lacking. This study sought to determine whether SIRT5 contributes to BBB damage following I/R brain injury. METHODS AND RESULTS SIRT5 knockout (SIRT5-/-) and wild type (WT) mice underwent transient middle cerebral artery (MCA) occlusion (tMCAO) followed by 48h of reperfusion. Genetic deletion of SIRT5 decreased infarct size, improved neurological function and blunted systemic inflammation following stroke. Similar effects were also achieved by in vivo SIRT5 silencing. Immunohistochemical analysis revealed decreased BBB leakage and degradation of the tight junction protein occludin in SIRT5-/- mice exposed to tMCAO as compared to WT. In primary human brain microvascular endothelial cells (HBMVECs) exposed to hypoxia/reoxygenation (H/R), SIRT5 silencing decreased endothelial permeability and upregulated occludin and claudin-5; this effect was prevented by the PI3K inhibitor wortmannin. Lastly, SIRT5 gene expression was increased in peripheral blood monocytes (PBMCs) of AIS patients at 6h after onset of stroke compared to sex- and age-matched healthy controls. CONCLUSION SIRT5 is upregulated in PBMCs of AIS patients and in the MCA of WT mice exposed to tMCAO; SIRT5 mediates I/R-induced brain damage by increasing BBB permeability through degradation of occludin. This effect was reproduced in HBMVECs exposed to H/R, mediated by the PI3K/Akt pathway. Our findings shed new light on the mechanisms of I/R-dependent brain damage and suggest SIRT5 as a novel therapeutic target.

In Vivo Imaging of CNS Injury and Disease

In vivo optical imaging has emerged as a powerful tool with which to study cellular responses to injury and disease in the mammalian CNS. Important new insights have emerged regarding axonal degeneration and regeneration, glial responses and neuroinflammation, changes in the neurovascular unit, and, more recently, neural transplantations. Accompanying a 2017 SfN Mini-Symposium, here, we discuss selected recent advances in understanding the neuronal, glial, and other cellular responses to CNS injury and disease with in vivo imaging of the rodent brain or spinal cord. We anticipate that in vivo optical imaging will continue to be at the forefront of breakthrough discoveries of fundamental mechanisms and therapies for CNS injury and disease.

Extravascular CD3+ T Cells in Brains of Alzheimer Disease Patients Correlate with Tau but Not with Amyloid Pathology: An Immunohistochemical Study

Background: Strong genetic and epidemiological evidence points to a crucial role of the immune system in the development of Alzheimer disease (AD). CD3+ T lymphocytes have been described in brains of postmortem AD patients and in transgenic models of AD-like cerebral amyloidosis and tau pathology. However, the occurrence of T cells in AD brains is still controversial; furthermore, the relationship between T cells and hallmarks of AD pathology (amyloid plaques and neurofibrillary tangles) remains to be established. Objectives: We have studied the occurrence of T cells in postmortem hippocampi and mid frontal gyrus (MFG) samples of AD patients (Braak stage V-VI) and nondemented control subjects and correlated it with amyloid and tau pathology burden. Methods: Confocal microscopy and bright-field immunohistochemistry were used to identify brain-associated T cells. Extravascular CD3+ T cells were quantified and compared to nondemented controls. In addition, numbers of extravascular CD3+ T cells were correlated with amyloid (6E10 staining) and tau pathology (AT8 staining) in the same sections. Results: Several CD3+, extravascular T cells were observed in the brains of AD patients, mostly of the CD8+ subtype. AD hippocampi harbored significantly increased numbers of extravascular CD3+ T cells compared to nondemented controls. CD3+ T cells significantly correlated with tau pathology but not with amyloid plaques in AD samples. Conclusions: Our data support the notion of T-cell occurrence in AD brains and suggest that, in advanced stages of AD, T-cell extravasation is driven by tau-related neurodegenerative changes rather than by cerebral amyloidosis. T cells could be crucial for driving the amyloid-independent phase of the AD pathology.

Corrigendum to ‘Sirtuin 5 as a novel target to blunt blood–brain barrier damage induced by cerebral ischemia/reperfusion injury’ [Int. J. Cardiol. 260 (2018) 148–155]

Sirtuin 5 as a novel target to blunt blood-brain barrier damage induced by cerebral ischemia/reperfusion injury. [Int J Cardiol. 2018]

Alzheimer disease makes new blood contacts

In this issue of Blood, Chen and colleagues demonstrate an unanticipated role for the contact system in a murine model of Alzheimer disease (AD). The study bolsters the key role of vascular dysfunction in AD by identifying factor XII (FXII) activation as a new molecular player in AD pathogenesis through mechanisms linked to cerebral fibrin deposition, neuroinflammation, and neuronal damage.1