Project description:Amyloid protein deposit, like Aβ plaques, is a pathological hallmark of Alzheimer’s disease (AD). While plenty of amyloid imaging reagents available for diagnosis, their composition associated with disease etiology is challenging to analyze in intact tissue sample. Herein, we report an amyloid-targeting probe to photocatalyze in-situ labeling and profiling of Aβ plaques in AD brain tissue via single electron transfer (SET) mechanism. First, we render this amyloid probe with photocatalytic labeling function by fragment fusion of classical scaffolds of fluorescent amyloid sensors. Second, we demonstrate its labeling selectivity to amyloid proteins over monomer counterparts. Mechanistically, we show spatially resolved labeling is driven by the short-lived SET photocatalytic process. Finally, we use this probe to capture and profile the composition of amyloid plagues in Alzheimer’s disease brain tissue. Surpassing other AD proteomics datasets, our work spatially resolves pathogenic Aβ and typical AD biomarkers as top-ranked hits. Together, the short-lived SET-driven photocatalysis spatially restrains protein labeling to occur in ultra-proximity to amyloids, allowing for microscope-free amyloid tissue microdissection at molecular level.

Project description:Amyloid plaque is a pathological hallmark in Alzheimer's disease (AD) brain with their composition associated with dis-ease etiology. Here, we report a photocatalyst, namely AmyCAT, that selectively binds to amyloid fibrils in AD brain tis-sue and undergoes Dexter energy transfer (DET) to catalyze carbene production for amyloid proximity labeling. First, we design the AmyCAT photocatalyst to generally bind different types of amyloids. Second, we energetically match the DET effect in a 12 × 4 photocatalysts-substrates array to activate diazo substrate into reactive carbene by visible green light (530~545 nm). Further, we demonstrate that the optimal AmyCAT probe catalyzes pan-amyloid protein labeling with 30-fold selectivity over folded counterparts. Mechanistic studies confirm the photocatalytic labeling is indeed via DET pro-cess, which tailors the proximity effect for spatially confined amyloid labeling. Finally, we employ the AmyCAT photo-catalyst to label, enrich and profile amyloid plagues in AD brain tissue, revealing key proteins and pathways associated with AD pathological deposition and etiology.

Project description:Amyloid plaque is a pathological hallmark in Alzheimer's disease (AD) brain with their composition associated with dis-ease etiology. Here, we report a photocatalyst, namely AmyCAT, that selectively binds to amyloid fibrils in AD brain tis-sue and undergoes Dexter energy transfer (DET) to catalyze carbene production for amyloid proximity labeling. First, we design the AmyCAT photocatalyst to generally bind different types of amyloids. Second, we energetically match the DET effect in a 12 × 4 photocatalysts-substrates array to activate diazo substrate into reactive carbene by visible green light (530~545 nm). Further, we demonstrate that the optimal AmyCAT probe catalyzes pan-amyloid protein labeling with 30-fold selectivity over folded counterparts. Mechanistic studies confirm the photocatalytic labeling is indeed via DET pro-cess, which tailors the proximity effect for spatially confined amyloid labeling. Finally, we employ the AmyCAT photo-catalyst to label, enrich and profile amyloid plagues in AD brain tissue, revealing key proteins and pathways associated with AD pathological deposition and etiology.

Project description:We quantified genome-wide levels of H3K27ac in post-mortem entorhinal cortex tissue samples, identifying widespread Alzheimer's disease (AD)-associated acetylomic variation. Differentially acetylated peaks were identified in the vicinity genes implicated in both tau and amyloid neuropathology (MAPT, APP, PSEN1, PSEN2), as well as genomic regions containing variants associated with sporadic late-onset AD (CR1, TOMM40). Both MAPT and PSEN2 are characterized by an extended hyperacetylated region upstream of the TSS  mapping to enhancers in the brain. We show that genes annotated to AD-associated hyper- and hypoacetylated peaks are enriched for brain- and neuropathology-related  functions.

Project description:Alzheimer’s disease (AD) is a chronic ageing related neurodegenerative disease which is characterized by loss of synapses and neurons in the vulnerable brain regions. Expression perturbations of amyloid β (Aβ) and tau protein in the brain are two hallmarks of AD. Aβ is abnormally generated from amyloid precursor protein (APP) which is broadly distributed in different brain regions including the hippocampus and cortex. It is believed that increased Aβ expression plays a causative role in the early stage of AD pathology. Aβ protein interacts with the signaling pathways that control the phosphorylation of the microtubule-associated protein tau, which eventually disrupts the neuronal circuitry as well as network connectivity leading to neurodegenerative processes observed in AD. In addition, substantial molecular and neurodegenerative changes occur in the initial stage of AD even before the cognitive symptoms are evident, which makes the early diagnosis of AD vital to any timely disease stabilization and treatment. However, despite myriad efforts and substantial progress in the field to decipher the molecular mechanisms of disease onset and its progression, specific causes underlying AD pathology remain ill-defined. There is an urgent need to identify novel mechanism based interventional approaches that can stop, or slow down, the progression of AD. Therefore, it is important to improve the knowledge of the early AD and have a better understanding of the underlying molecular mechanisms induced by Aβ. In this study, we performed comparative quantitative proteomics on different brain regions of 2.5 months old APP/PS1 mice (hippocampus, frontal cortex, parietal cortex and cerebellum) in order to investigate the early stage impact of AD. Although over 5000 proteins were identified in all regions, the proteome response across regions was greatly varied. As expected, the greatest proteome perturbation was detected in the hippocampus and frontal cortex (AD-susceptible brain regions), compared to only 155 changed proteins in the cerebellum (less vulnerable region to AD). Increased expression of APP protein was identified in all brain regions. The expression of the majority of the other proteins between hippocampus and cortex areas was not similar, highlighting differential effects of the disease on different brain regions. A series of AD associated markers and pathways were identified as overexpressed in the hippocampus including glutamatergic synapse, GABAergic synapse, retrograde endocannabinoid signaling, long-term potentiation, and calcium signaling. In contrast, the expression of same proteins and pathways was negatively regulated in frontal and parietal cortex regions. Additionally, an increased expression of proteins associated with the oxidative phosphorylation pathway in hippocampus was not evident in the two cortices. Interestingly, an increased expression of proteins involved with myelination, neurofilament cytoskeleton organization, and glutathione metabolism was identified in cortex areas, while these were reduced in the hippocampus. The results obtained from this study highlight important information on brain region specific protein expression changes occurring in the early stages of AD.

Project description:Alzheimer’s disease (AD) is characterized by memory loss and neuropsychiatric symptoms associated with cerebral accumulation of amyloid-β (Aβ) and tau, but how memory and emotional neural circuits are disrupted by AD pathology remains unclear. Here, we investigated the transcriptional vulnerability of memory and emotional circuits to concomitant Aβ and tau pathologies in transgenic mice expressing mutant human amyloid precursor protein (APP) and Tau (APP/Tau mice) in excitatory neurons. At 9 months, we detected common and region-specific transcriptional responses in the hippocampus and basolateral amygdala (BLA) of APP/Tau mice, including astrocytic, microglia and 63 AD-associated genes. These findings suggest that Aβ and tau pathologies disrupt region-specific gene expression programs underlying vulnerability of memory and emotional circuits to AD neuropathology.

Project description:This project delineates the amyloid proteome in Alzheimer's Disease (AD) mouse brain tissue using a novel covalent labeling strategy. Unlike conventional Congo Red (CR), which only provides non-covalent staining and cannot use for protein enrichment, our CR-alkyne probe utilizes a boron-azo bioconjugation chemistry to form irreversible bonds with amyloid-associated proteins. This critical covalent linkage enables the specific enrichment of labeled proteins via the alkyne handle for LC-MS/MS analysis. The dataset directly contrasts with background proteins identified from control samples treated with native CR, which lacks the alkyne handle and covalent enrichment capability. This comparative design rigorously distinguishes true amyloid plaque constituents from non-specifically bound proteins, providing a high-confidence profile of the amyloid proteome and its interactors for understanding AD pathology.

Project description:We identified widespread DNA methylation changes associated with the development of both tau and amyloid neuropathology, including differentially methylated positions (DMPs) and regions (DMRs) at loci previously implicated in AD and overlapping changes identified in our ongoing analyses of human post-mortem AD brains.

Project description:We identified widespread DNA methylation changes associated with the development of both tau and amyloid neuropathology, including differentially methylated positions (DMPs) and regions (DMRs) at loci previously implicated in AD and overlapping changes identified in our ongoing analyses of human post-mortem AD brains.

Project description:To reveal the pathologic mechanisms involved in large deposits of Aβ amyloid plaques selectively in subiculum region during early stage of AD pathogenesis, high resolution liquid chromatography-tandem mass spectrometry (LC-MS/MS) was employed to profile the proteomic changes in different stages of AD. We analyzed the proteome of SUB regions microdissected from wild type (WT) and 5×FAD (AD) mice at 3, 6 and 12 months of age with three biological replicates via data-independent acquisition (DIA) proteomic approach, which had higher stability and coverage and less missing data than label-free quantitative method (LFQ) facilitating identification of low-abundance proteins [1]. In-depth analysis of all replicates using Spectronaut identified 131483 peptides assembling into 8948 protein groups, and more than 4000 proteins was detected in each SUB region, of which 4840 proteins were quantified.