Publications by authors named "Gabriel E Hoffman"

The complex roles of myeloid cells, including microglia and perivascular macrophages, are central to the neurobiology of Alzheimer's disease (AD), yet they remain incompletely understood. Here, we profiled 832,505 human myeloid cells from the prefrontal cortex of 1,607 unique donors covering the human lifespan and varying degrees of AD neuropathology. We delineated 13 transcriptionally distinct myeloid subtypes organized into 6 subclasses and identified AD-associated adaptive changes in myeloid cells over aging and disease progression.

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Polygenic scores (PGS) enable the exploration of pleiotropic effects and genomic dissection of complex traits. Here, in 421,889 individuals with European ancestry from the Million Veteran Program and UK Biobank, we examine how PGS of 17 neuropsychiatric traits are related to membership in 22 broad professional categories. Overall, we find statistically significant but weak (the highest odds ratio is 1.

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Brain region- and cell-specific transcriptomic and epigenomic features are associated with heritability for neuropsychiatric traits, but a systematic view, considering cortical and subcortical regions, is lacking. Here, we provide an atlas of chromatin accessibility and gene expression profiles in neuronal and non-neuronal nuclei across 25 distinct human cortical and subcortical brain regions from 6 neurotypical controls. We identified extensive gene expression and chromatin accessibility differences across brain regions, including variation in alternative promoter-isoform usage and enhancer-promoter interactions.

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Large-scale genome-wide association studies of schizophrenia have uncovered hundreds of associated loci but with extremely limited representation of African diaspora populations. We surveyed electronic health records of 200,000 individuals of African ancestry in the Million Veteran and All of Us Research Programs, and, coupled with genotype-level data from four case-control studies, realized a combined sample size of 13,012 affected and 54,266 unaffected persons. Three genome-wide significant signals - near , , and - are the first to be independently identified in populations of predominantly African ancestry.

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  • - The study examined the gene expression differences in specific excitatory neurons from the brains of individuals with Down syndrome (DS) compared to controls to understand their roles in neurodegeneration and potential therapies for Alzheimer’s disease (AD).
  • - More than 2,300 differentially expressed genes (DEGs) were identified in both layers of pyramidal neurons, including 100 genes from the extra chromosome 21, indicating a complex pattern of gene dysregulation beyond just trisomic genes.
  • - Key genes like amyloid precursor protein (APP) and superoxide dismutase 1 (SOD1) were highlighted as important regulators of neuronal dysfunction, suggesting they could be targets for new treatments aimed at improving cognitive decline in DS
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  • Individuals with Down syndrome (DS) develop Alzheimer's disease (AD) pathology in midlife, particularly affecting CA1 neurons in the hippocampus, but the underlying mechanisms are not fully understood.
  • This study compared pyramidal neurons (PNs) in an aged female DS/AD mouse model to control mice, focusing on how spatial positioning within the CA1 region impacts neuronal dysfunction.
  • Results showed significant differences in gene expression based on the spatial location of neurons, indicating deeper CA1 neurons are more linked to cognitive functions compared to superficial ones, highlighting the role of spatial localization in neuronal vulnerability.
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  • Schizophrenia's complexity has made it difficult to understand its mechanisms and develop effective treatments; a new study addresses this by examining transcriptomic changes at the single-cell level in the human prefrontal cortex of 140 individuals.
  • The researchers found that excitatory neurons were the most affected, with changes related to neurodevelopment and synapse function, and identified both common and rare genetic risk factors influencing these neuronal alterations.
  • Their findings reveal two distinct groups of individuals with schizophrenia based on specific excitatory and inhibitory neuron states, linking genetic risk to cellular changes and enhancing our understanding of schizophrenia's underlying biology.
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  • The study investigates how genetic variants in specific brain cell regulatory elements contribute to disease risk by analyzing chromatin accessibility in neurons and non-neurons from human brain samples.
  • Researchers found 34,539 open chromatin areas, with only 10.4% being common between neuron and non-neuron cells, indicating that genetic regulation varies by cell type.
  • By identifying 476 regulatory variants with functional impacts, the research enhances understanding of brain gene regulation and its link to diseases, offering valuable insights into potential therapeutic targets.
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Single-cell genomics is a powerful tool for studying heterogeneous tissues such as the brain. Yet little is understood about how genetic variants influence cell-level gene expression. Addressing this, we uniformly processed single-nuclei, multiomics datasets into a resource comprising >2.

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Sample-wise deconvolution methods estimate cell-type proportions and gene expressions in bulk tissue samples, yet their performance and biological applications remain unexplored, particularly in human brain transcriptomic data. Here, nine deconvolution methods were evaluated with sample-matched data from bulk tissue RNA sequencing (RNA-seq), single-cell/nuclei (sc/sn) RNA-seq, and immunohistochemistry. A total of 1,130,767 nuclei per cells from 149 adult postmortem brains and 72 organoid samples were used.

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Article Synopsis
  • - Single-cell genomics helps us study diverse brain tissues, revealing how genetic variants affect gene expression at the cell level through an analysis of over 2.8 million nuclei from the prefrontal cortex across 388 individuals.
  • - Researchers identified more than 550,000 specific regulatory elements and over 1.4 million expression-quantitative-trait loci linked to various cell types, allowing them to develop networks that illustrate the impact of aging and neuropsychiatric disorders on cellular changes.
  • - An integrative model was created to predict single-cell gene expression and simulate cellular changes, which identified around 250 genes associated with disease risk and relevant drug targets tied to specific cell types.
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Enhancers play an essential role in the etiology of schizophrenia; however, the dysregulation of enhancer activity and its impact on the regulome in schizophrenia remains understudied. To address this gap in our knowledge, we assessed enhancer and gene expression in 1,382 brain samples comprising cases with schizophrenia and unaffected controls. Dysregulation of enhancer expression was concordant with changes in gene expression, and was more closely associated with schizophrenia polygenic risk, suggesting that enhancer dysregulation is proximal to the genetic etiology of the disease.

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Microglia, the innate immune cells of the central nervous system, have been genetically implicated in multiple neurodegenerative diseases. We previously mapped the genetic regulation of gene expression and mRNA splicing in human microglia, identifying several loci where common genetic variants in microglia-specific regulatory elements explain disease risk loci identified by GWAS. However, identifying genetic effects on splicing has been challenging due to the use of short sequencing reads to identify causal isoforms.

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Background: Genotypes are strongly associated with disease phenotypes, particularly in brain disorders. However, the molecular and cellular mechanisms behind this association remain elusive. With emerging multimodal data for these mechanisms, machine learning methods can be applied for phenotype prediction at different scales, but due to the black-box nature of machine learning, integrating these modalities and interpreting biological mechanisms can be challenging.

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Non-coding variants increase risk of neuropsychiatric disease. However, our understanding of the cell-type specific role of the non-coding genome in disease is incomplete. We performed population scale (N=1,393) chromatin accessibility profiling of neurons and non-neurons from two neocortical brain regions: the anterior cingulate cortex and dorsolateral prefrontal cortex.

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Non-coding variants increase risk of neuropsychiatric disease. However, our understanding of the cell-type specific role of the non-coding genome in disease is incomplete. We performed population scale (N=1,393) chromatin accessibility profiling of neurons and non-neurons from two neocortical brain regions: the anterior cingulate cortex and dorsolateral prefrontal cortex.

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Background: Converging evidence from large-scale genetic and postmortem studies highlights the role of aberrant neurotransmission and genetic regulation in brain-related disorders. However, identifying neuronal activity-regulated transcriptional programs in the human brain and understanding how changes contribute to disease remain challenging.

Methods: To better understand how the activity-dependent regulome contributes to risk for brain-related disorders, we profiled the transcriptomic and epigenomic changes following neuronal depolarization in human induced pluripotent stem cell-derived glutamatergic neurons (NGN2) from 6 patients with schizophrenia and 5 control participants.

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Advances in single-cell and -nucleus transcriptomics have enabled generation of increasingly large-scale datasets from hundreds of subjects and millions of cells. These studies promise to give unprecedented insight into the cell type specific biology of human disease. Yet performing differential expression analyses across subjects remains difficult due to challenges in statistical modeling of these complex studies and scaling analyses to large datasets.

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Nucleotide variants in cell type-specific gene regulatory elements in the human brain are major risk factors of human disease. We measured chromatin accessibility in sorted neurons and glia from 1,932 samples of human postmortem brain and identified 34,539 open chromatin regions with chromatin accessibility quantitative trait loci (caQTL). Only 10.

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Sample-wise deconvolution methods have been developed to estimate cell-type proportions and gene expressions in bulk-tissue samples. However, the performance of these methods and their biological applications has not been evaluated, particularly on human brain transcriptomic data. Here, nine deconvolution methods were evaluated with sample-matched data from bulk-tissue RNAseq, single-cell/nuclei (sc/sn) RNAseq, and immunohistochemistry.

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Advances in single-cell and -nucleus transcriptomics have enabled generation of increasingly large-scale datasets from hundreds of subjects and millions of cells. These studies promise to give unprecedented insight into the cell type specific biology of human disease. Yet performing differential expression analyses across subjects remains difficult due to challenges in statistical modeling of these complex studies and scaling analyses to large datasets.

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Article Synopsis
  • ADHD is a common neurodevelopmental disorder with a strong genetic basis, as shown in a large study involving 38,691 individuals with the disorder compared to 186,843 controls.
  • Researchers found 27 significant genomic regions linked to ADHD, with many genes related to early brain development and certain brain cell types, suggesting a biological basis for the disorder.
  • The study also highlighted that many genetic factors influencing ADHD overlap with other psychiatric conditions and are correlated with cognitive challenges, particularly in areas like attention and reasoning.
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Post-acute sequelae of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) infection are debilitating, clinically heterogeneous and of unknown molecular etiology. A transcriptome-wide investigation was performed in 165 acutely infected hospitalized individuals who were followed clinically into the post-acute period. Distinct gene expression signatures of post-acute sequelae were already present in whole blood during acute infection, with innate and adaptive immune cells implicated in different symptoms.

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