Project description:NeuroCHARGE Consortium GWAS of White Matter Hyperintensities on MRI

Project description:Focal white matter lesions occur in most neurodegenerative disorders. Despite occurring early in disease, white matter lesions are considered either independent of, or secondary to, grey matter neuroinflammation, synapse loss and altered neuronal activity. Notably their functional impact on neuronal circuits has been understudied. To address this, we generated a focal white matter lesion in an anatomically well-defined circuit, in which white matter lesions occur in many neurodegenerative disorders. Here we show that focal white matter lesions evoke transient neuronal activity changes and microgliosis, with subsequent synapse loss and increased microglia engulfment in the grey matter, which is reversed if myelin regeneration completes. Grey matter microgliosis is often considered detrimental but we show that it is an integral part of the myelin regenerative process. When we prevent these transient changes in the grey matter, myelin regeneration is blocked in the white matter. Conversely, inducing myelin regeneration failure leads to chronic neuroinflammation in the grey matter, suggesting that myelin regeneration failure drives sustained grey matter microglial activation. This recapitulates the low-grade inflammation considered to be a dominant mechanism underlying neurodegeneration. Our findings reveal a form of regenerative plasticity coupling white matter integrity to grey matter function - a novel mechanism of neuroplasticity that may underlie multiple neurodegenerative conditions - and highlights the potential of targeting myelin regeneration to prevent chronic inflammation.

Project description:NEI NEIGHBOR Consortium Glaucoma GWAS

Project description:Aging results in both grey and white matter degeneration, but the specific microglial responses are unknown. Using single-cell RNA sequencing from white and grey matter separately, we identified white matter associated microglia (WAM), which share parts of the disease-associated microglia (DAM) gene signature and are characterized by the activation of genes implicated in phagocytic activity and lipid metabolism. WAM depend on triggering receptor expressed on myeloid cells 2 (TREM2) signaling and are aging dependent. In the aged brain, WAM form independently of apolipoprotein E (APOE), which is in contrast to mouse models of Alzheimer’s disease, in which microglia with WAM gene signature are generated prematurely and in an APOE-dependent pathway similar to DAM. Within the white matter, microglia frequently cluster in nodules, where they are engaged in clearing degenerated myelin. Thus, WAM may represent a potentially protective response required to clear degenerated myelin accumulating during white matter aging and disease.

Project description:Vanishing white matter (VWM) is a leukodystrophy that primarily manifests in young children. In this disease, the brain white matter is differentially affected in a predictable pattern with telencephalic brain areas being more severely affected, while others remain allegedly completely spared. Using high-resolution mass spectrometry-based proteomics, we investigated the proteome patterns of the severely affected white matter in the frontal lobe and normal appearing pons in VWM and control cases to identify molecular bases underlying regional vulnerability. By comparing VWM patients to controls, we identified disease-specific proteome patterns. We showed substantial pathogenic changes in both the frontal white matter and pons at the protein level. Side-by-side comparison of brain region-specific proteome patterns further revealed regional differences. We found that different cell types are affected in the VWM frontal white matter than in the pons. Gene ontology and pathway analyses identified involvement of region distinct biological processes, of which pathways implicated in cellular respiratory metabolism were overarching features. In the VWM frontal white matter, proteome changes were associated with decrease in glycolysis/gluconeogenesis and metabolism of various amino acids. By contrast, in the VWM pons white matter, we found a decrease in oxidative phosphorylation. Taken together, our data show that brain regions are affected in parallel in VWM, but to different degrees. We found region-specific involvement of different cell types and discovered that cellular respiratory metabolism is differently affected across white matter regions in VWM. These region-specific changes help explain regional vulnerability to pathology in VWM.

Project description:We compared the transcriptomic responses in the mouse white matter tissue drive white matter lesions following LPC- and L-NIO-induced injury.

Project description:Tissue progenitors maintain the integrity of organ systems through aging and stress. The brain’s white matter regions experience ischemic lesions and age-dependent degeneration. Brain white matter contains progenitors, oligodendrocyte precursor cells (OPCs), which can repair some insults. The response of OPCs to white matter ischemia and aging is not known. We characterized the response of OPCs to white matter stroke using OPC reporter mice, cell migration tracking, OPC specific RNA sequencing, and mechanistic studies in candidate biochemical pathways in the aged brain. White matter stroke induces initial proliferation of local OPCs but blocks differentiation, shunting a portion into astrocytes. Candidate signaling pathways for this differentiation block including novel interactions of inhibin and matrilin-2 and new roles of NgR1 ligands following white matter stroke. Stroke induces inhibin expression in astrocytes and downregulates OPC matrilin-2 that contributes into OPC differentiation block. Antagonism of NgR1 ligands promotes OPC differentiation by attenuating the OPC astrocytic transformation and enhances functional recovery from stroke in aged animals.

Project description:White matter aging drives microglial diversity

Project description:Chronic alcohol consumption can lead to alchohol-related brain damage (ARBD). Despite the well known acute effects of alcohol the mechanism responsible for chronic brain damage is largely unknown. Pathologically the major change is the loss of white matter while neuronal loss is mild and restricted to a few areas such as the prefrontal cortex. In order to improve our understanding of ARBD pathogenesis we used microarrays to explore the white matter transcriptome of alcoholics and controls. Our results suggest that hepatic encephalopathy, along with two confounders, gray matter contamination and low RNA quality, are major drivers of gene expression in ARBD. All three exceeded the effects of alcohol itself. In particular, low quality RNA samples were characterized by an upregulation of protein translation machinery while hepatic encephalopathy was associated with a downregulation of mitochondrial energy metabolism pathways. The findings in HE alcoholics are consistent with the metabolic acidosis seen in this condition. In contrast non-HE alcoholics had widespread but only subtle changes in gene expression in their white matter. The initial cohort was compromised of four alcoholics without hepatic encephalopathy (non-HE alcoholics), three alcoholics with HE (HE alcoholics) and three neurologically normal controls. For each indvidual frozen white matter was sampled in the superior frontal gyrus (prefrontal cortex) and the precentral gyrus (motor cortex). These two cortices experience either moderate (prefrontal cortex) or no neuronal loss (motor cortex) with alcohol-related brain damage. Each white matter sample was divided in two before RNA was extracted to give two 'biological' repeats and a total of 40 samples. Subsequently eight duplicates were removed due to their gray matter contamination or low RNA quality to leave a 32-sample cohort (23 alcoholic (including eight with HE ) and nine control samples.

Project description:Focal white matter lesions occur in most neurodegenerative disorders1-4. They are well characterised in multiple sclerosis (MS) but much less understood in other conditions. Despite occurring early in disease, white matter lesions are considered either independent of or secondary to grey matter neuroinflammation, synaptic loss and altered neuronal activity5-8. Notably their functional impact on neuronal circuits has been overlooked. To address this, we performed a focal white matter lesion in an anatomically well-defined circuit, in which white matter lesions occur in many neurodegenerative disorders. Here we show that focal white matter lesions evoke transient neuronal activity changes and microgliosis, synaptic loss and increased engulfment in the grey matter, which resolves by the time myelin regeneration completes. Synaptic loss and microgliosis are often considered detrimental but we show they are instead an integral part of the myelin regenerative process. When we prevent these transient changes in the grey matter, myelin regeneration is blocked in the white matter. Conversely, inducing myelin regeneration failure leads to chronic neuroinflammation in the grey matter, suggesting that myelin regeneration failure drives sustained microglial activation. This recapitulates the low-grade inflammation considered to be a dominant mechanism underlying neurodegeneration8-11. Hence, we present a novel mechanism that may underlie multiple conditions and highlight the potential of targeting myelin regeneration to prevent chronic neuroinflammation.