Project description:Neurofilament light chain (NfL) is a neuron-specific cytoskeletal protein that provides structural support for axons and is released into the extracellular space following neuronal injury. While NfL has been extensively studied as a disease biomarker, the underlying release mechanisms and role in neurodegeneration remain poorly understood. Here, we find that neurons secrete low baseline levels of NfL, while neuronal damage triggers calpain-driven proteolysis and release of fragmented NfL. Secreted NfL activates microglia cells, which can be blocked with anti-NfL antibodies. We utilize in vivo single-cell RNA sequencing to profile brain cells after injection of recombinant NfL into the mouse hippocampus and find robust macrophage and microglial responses. Consistently, NfL knock-out mice ameliorate microgliosis and delay symptom onset in the SOD1 mouse model of amyotrophic lateral sclerosis (ALS). Our results show that released NfL can activate myeloid cells in the brain and is, thus, a potential therapeutic target for neurodegenerative diseases.

Project description:Blood-based neurofilament light (sNfL) indicates neuroaxonal injury in multiple sclerosis and is on the cusp of being implemented into clinical routine. However, anatomical origins and pathophysiological mechanisms of NfL release during acute relapses and later chronic disease stages are still poorly understood. Here, we applied immunohistochemistry, single molecule array, spatial transcriptomics and microglia/axon co-cultures to gain insight into spatio-temporal NfL release in experimental autoimmune encephalomyelitis (EAE). Results: Association of spinal cord white matter lesions and sNfL levels revealed a distinct, stage-dependent anatomical pattern of neuroaxonal damage: In chronic EAE, sNfL levels were predominately associated with anterolateral lumbar lesions, whereas in early EAE sNfL showed no correlation with lesions in any anatomical location. Furthermore, neuroaxonal damage in late EAE was largely confined to white matter lesions, but showed a widespread distribution in early EAE. Followingthis spatio-temporal pattern of neuroaxonal damage, spatial transcriptomics revealed a widespread cyto- and chemokine response at early disease stages, whereas late EAE was characterized by a prominent glial cell accumulation in white matter lesions. These findings were corroborated by immunohistochemistry and micro-glia/axon co-cultures, which further revealed a strong association between CNS myeloid cell activation and neuroaxonal damage both in vivo and in vitro. Interpretation: Our data demonstrate that sNfL release in EAE driven by CNS myeloid cells exhibits progress in a disease stage-dependent centripetal manner from normal-appearing white matter to focal white matter lesions. These findings may further aid the interpretation of elevated sNfL levels in multiple sclerosis patients at different disease stages.

Project description:Secreted neurofilament light chain (NfL) after neuronal damage induces myeloid cell activation and neuroinflammation [scRNA-Seq]

Project description:Secreted neurofilament light chain (NfL) after neuronal damage induces myeloid cell activation and neuroinflammation [bulkRNA-Seq]

Project description:Sporadic Creutzfeldt-Jakob disease (sCJD) is the most prevalent form of human prion disease and it is characterized by the presence of neuronal loss, spongiform degeneration, chronic inflammation and the accumulation of misfolded and pathogenic prion protein (PrPSc). The molecular mechanisms underlying these alterations are largely unknown, but the presence of intracellular neuronal calcium (Ca+2) overload, a general feature in models of prion diseases, is suggested to play a key role in prion pathogenesis. Here we describe the presence of massive regulation of Ca+2 responsive genes in sCJD brain tissue, accompanied by two Ca+2-dependent processes: endoplasmic reticulum stress and the activation of the cysteine proteases Calpains 1/2. Pathogenic Calpain activation in sCJD is linked to the cleavage of their cellular substrates, impaired autophagy and lysosomal damage, which is partially reversed by Calpain inhibition in a cellular prion model. Calpain 1 treatment enhances seeding activity of PrPSc in a prion conversion assay. Neuronal lysosomal impairment caused by Calpain over activation leads to the release of the lysosomal protease Cathepsin S that in sCJD mainly localises in axons. Additionally, massive Cathepsin S overexpression is detected in microglial cells. Alterations in Ca+2 homeostasis and activation of Calpain-Cathepsin axis already occur at pre-clinical stages of the disease as detected in a humanized sCJD mouse model. Altogether our work indicates that unbalanced Calpain-Cathepsin activation is a relevant contributor to the pathogenesis of sCJD at multiple molecular levels and a potential target for therapeutic intervention.

Project description:Dimethyl fumarate (DMF) is an oral drug approved for relapsing multiple sclerosis (MS) that leads to reduction of neurofilament light (NFL). This may be related to dynamics and persistence of microRNA signatures in the peripheral blood of treatment-naïve MS patients before and after dimethyl fumarate (DMF) at different time points. 210 blood samples were collected from 51 treatment-naïve patients at baseline (BL) and after 1-3, 4-7, 9-15 and 21-27 months of DMF and from 22 controls from the phase IV TREMEND trial. Using microarray, 1,085 miRNAs were two-folds above the background and compared versus NFL. Altered miRNA profiles peaked after 4-7 months. MiR-16-5p and miR-4306, involved in the NF-kB-pathway, were upregulated in low NFL samples, while miR-940 and miR-4665-3p were upregulated in high NFL samples. NFL and miRNA correlations were strongest after 4-7 months DMF. In four patients with blood samples taken at all 5 time points, time-series analysis found miR-146a-5p, the inhibitor of the NF-kB-pathway, increased 1-3 months after treatment. DMF induces dynamic changes in composite miRNA profiles 4-7 months after initiation, several involved in the NF-kB-pathway. Upregulation of miR-16-5p and miR-4306 in low-NFL, while miR-940 and miR-4665-3p in high-NFL samples may indicate a response to DMF treatment.

Project description:In order to overcome the defect of Nanofat, we developed Nanofat lysate (NFL) by repeated freeze-thawing lysis preparation on Nanofat. During the preparation, cell membranes of Nanofat cells were ruptured and the cellular contents were released. Thus, NFL may have storage stability in low temperature. Therefore, to investigate the effects of the stimulation of TNF-α on primary chondrocytes and the effect of NFL, we can speculate that unique genetic profiles in vitro might exist with different interventions.

Project description:Older age is the primary risk factor for most chronic diseases, including Alzheimer’s disease (AD). Current preclinical models to study brain aging and AD are mainly transgenic and harbor mutations intended to mirror brain pathologies associated with human brain aging/AD (e.g., by increasing production of amyloid precursor protein, amyloid beta [Aβ], and/or phosphorylated tau, all of which are key pathological mediators of AD). Although these models may provide insight on pathophysiological processes in AD, none completely recapitulate the disease and its strong age-dependence, and there has been limited success in translating preclinical results and treatments to humans. Here, we describe two non-transgenic guinea pig (GP) models, a standard PigmEnTed (PET) strain and lesser-studied Dunkin-Hartley (DH) strain, that may naturally mimic key features of brain aging and AD in humans. We show that brain aging in PET GP is transcriptomically similar to human brain aging, whereas older DH brains are transcriptomically more similar to human AD. Both strains/models also exhibit increased neurofilament light chain (NFL, a marker of neuronal damage) with aging, and DH animals display greater S100 calcium-binding protein B (S100β), ionized calcium-binding adapter molecule 1 (Iba1), and Aβ and phosphorylated tau— which are all important markers of neuroinflammation-associated AD. Collectively, our results suggest that both the PET and DH GP may be useful, non-transgenic models to study brain aging and AD, respectively.

Project description:Microglia influence neurofilament deposition in ALS iPSC-derived motor neurons

Project description:Importance: An intronic hexanucleotide repeat expansion (HRE) in C9orf72 is the commonest monogenic cause of the neurodegenerative diseases amyotrophic lateral sclerosis (ALS) and frontotemporal dementia (FTD). Predicting those who will develop neurodegeneration and its timing will be essential to initiating and assessing preventative therapy. This requires consideration of both compensatory, protective mechanisms and pathogenic events prior to overt neurodegeneration. Objective: To identify biochemical changes in individuals at higher risk of developing ALS or FTD via C9orf72 HRE heterozygosity. Design: Cross sectional observational study. Setting: Tertiary ALS or dementia referral centre. Participants: People with established ALS or FTD, either due to C9orf72 HRE or apparently sporadic cases; asymptomatic first-degree relatives of those with a known C9orf72 HRE; asymptomatic non-carrier controls. Exposure: C9orf72 HRE. Main outcomes: Relative abundance of 30 predefined cerebrospinal fluid biomarkers of ALS and FTD comparing asymptomatic C9orf72 HRE carriers and age-matched non-carriers. Differential abundance of proteins quantified using data independent acquisition mass spectrometry and neurofilament light chain measured by electrochemiluminescent assay. Results: Data for 19 people with sporadic ALS, 10 people with C9orf72 ALS, 14 people with sporadic FTD, 10 people with C9orf72 FTD, 48 asymptomatic C9orf72 HRE carriers and 39 non-carrier controls were analysed. Ubiquitin carboxyl-hydrolase isozyme L1 levels were higher in asymptomatic C9orf72 HRE carriers compared with age-matched non-carriers (log2fold change 0.20, FDR-adjusted p-value = 0.034). Neurofilament light chain levels did not differ significantly between groups. Ubiquitin carboxyl-hydrolase isozyme L1 levels remained elevated after exclusion of those with high neurofilament light chain levels, after adjusting for NFL level and after adjusting for age. Conclusions and relevance: Elevated cerebrospinal fluid ubiquitin carboxyl-hydrolase isozyme L1 levels in C9orf72 hexanucleotide repeat expansion carriers occurs in the absence of elevation in neurofilament light chain, potentially reflecting mechanisms that precede the phase of neurodegeneration characterised by rapid neuronal loss. Such mechanisms may have either compensatory or pathogenic roles. Ubiquitin carboxyl-terminal hydrolase isozyme L1 elevation brings forward the window on the changes associated with the C9orf72 HRE carrier state, with the potential to inform understanding penetrance and approaches to prevention.