The basis of clinicopathological heterogeneity in TDP-43 proteinopathy

Abstract Transactive response DNA-binding protein 43 kDa (TDP-43) was identified as a major disease-associated component in the brain of patients with amyotrophic lateral sclerosis (ALS), as well as the largest subset of patients with frontotemporal lobar degeneration with ubiquitinated inclusions (FTLD-U), which characteristically exhibits cytoplasmic inclusions that are positive for ubiquitin but negative for tau and α-synuclein. TDP-43 pathology occurs in distinct brain regions, involves disparate brain networks, and features accumulation of misfolded proteins in various cell types and in different neuroanatomical regions. The clinical phenotypes of ALS and FTLD-TDP (FTLD with abnormal intracellular accumulations of TDP-43) correlate with characteristic distribution patterns of the underlying pathology across specific brain regions with disease progression. Recent studies support the idea that pathological protein spreads from neuron to neuron via axonal transport in a hierarchical manner. However, little is known to date about the basis of the selective cellular and regional vulnerability, although the information would have important implications for the development of targeted and personalized therapies. Here, we aim to summarize recent advances in the neuropathology, genetics and animal models of TDP-43 proteinopathy, and their relationship to clinical phenotypes for the underlying selective neuronal and regional susceptibilities. Finally, we attempt to integrate these findings into the emerging picture of TDP-43 proteinopathy, and to highlight key issues for future therapy and research.

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Location Matters: Navigating Regional Heterogeneity of the Neurovascular Unit

Frontiers in Cellular Neuroscience ◽

10.3389/fncel.2021.696540 ◽

2021 ◽

Vol 15 ◽

Author(s):

Louis-Philippe Bernier ◽

Clément Brunner ◽

Azzurra Cottarelli ◽

Matilde Balbi

Keyword(s):

Brain Function ◽

Energy Demand ◽

Neurovascular Unit ◽

Cell Types ◽

Brain Regions ◽

Regional Heterogeneity ◽

Regional Specialization ◽

Multiple Cell ◽

Cellular Components ◽

The Brain

The neurovascular unit (NVU) of the brain is composed of multiple cell types that act synergistically to modify blood flow to locally match the energy demand of neural activity, as well as to maintain the integrity of the blood-brain barrier (BBB). It is becoming increasingly recognized that the functional specialization, as well as the cellular composition of the NVU varies spatially. This heterogeneity is encountered as variations in vascular and perivascular cells along the arteriole-capillary-venule axis, as well as through differences in NVU composition throughout anatomical regions of the brain. Given the wide variations in metabolic demands between brain regions, especially those of gray vs. white matter, the spatial heterogeneity of the NVU is critical to brain function. Here we review recent evidence demonstrating regional specialization of the NVU between brain regions, by focusing on the heterogeneity of its individual cellular components and briefly discussing novel approaches to investigate NVU diversity.

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Common and rare variant association analyses in Amyotrophic Lateral Sclerosis identify 15 risk loci with distinct genetic architectures and neuron-specific biology

10.1101/2021.03.12.21253159 ◽

2021 ◽

Author(s):

Wouter van Rheenen ◽

Rick A.A. van der Spek ◽

Mark K. Bakker ◽

Joke J.F.A. van Vugt ◽

Paul J. Hop ◽

...

Keyword(s):

Amyotrophic Lateral Sclerosis ◽

Rare Variants ◽

Unmet Need ◽

Life Time ◽

Cell Types ◽

Brain Regions ◽

Multiple Traits ◽

Association Analyses ◽

Als Patients ◽

Lateral Sclerosis

AbstractAmyotrophic lateral sclerosis (ALS) is a fatal neurodegenerative disease with a life-time risk of 1 in 350 people and an unmet need for disease-modifying therapies. We conducted a cross-ancestry GWAS in ALS including 29,612 ALS patients and 122,656 controls which identified 15 risk loci in ALS. When combined with 8,953 whole-genome sequenced individuals (6,538 ALS patients, 2,415 controls) and the largest cortex-derived eQTL dataset (MetaBrain), analyses revealed locus-specific genetic architectures in which we prioritized genes either through rare variants, repeat expansions or regulatory effects. ALS associated risk loci were shared with multiple traits within the neurodegenerative spectrum, but with distinct enrichment patterns across brain regions and cell-types. Across environmental and life-style risk factors obtained from literature, Mendelian randomization analyses indicated a causal role for high cholesterol levels. All ALS associated signals combined reveal a role for perturbations in vesicle mediated transport and autophagy, and provide evidence for cell-autonomous disease initiation in glutamatergic neurons.

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STAB: a spatio-temporal cell atlas of the human brain

Nucleic Acids Research ◽

10.1093/nar/gkaa762 ◽

2020 ◽

Vol 49 (D1) ◽

pp. D1029-D1037

Author(s):

Liting Song ◽

Shaojun Pan ◽

Zichao Zhang ◽

Longhao Jia ◽

Wei-Hua Chen ◽

...

Keyword(s):

Human Brain ◽

Single Cell ◽

Temporal Dynamics ◽

Cell Types ◽

Brain Regions ◽

Molecular Characteristics ◽

Great Effort ◽

Brain Functions ◽

Spatio Temporal ◽

The Brain

Abstract The human brain is the most complex organ consisting of billions of neuronal and non-neuronal cells that are organized into distinct anatomical and functional regions. Elucidating the cellular and transcriptome architecture underlying the brain is crucial for understanding brain functions and brain disorders. Thanks to the single-cell RNA sequencing technologies, it is becoming possible to dissect the cellular compositions of the brain. Although great effort has been made to explore the transcriptome architecture of the human brain, a comprehensive database with dynamic cellular compositions and molecular characteristics of the human brain during the lifespan is still not available. Here, we present STAB (a Spatio-Temporal cell Atlas of the human Brain), a database consists of single-cell transcriptomes across multiple brain regions and developmental periods. Right now, STAB contains single-cell gene expression profiling of 42 cell subtypes across 20 brain regions and 11 developmental periods. With STAB, the landscape of cell types and their regional heterogeneity and temporal dynamics across the human brain can be clearly seen, which can help to understand both the development of the normal human brain and the etiology of neuropsychiatric disorders. STAB is available at http://stab.comp-sysbio.org.

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Regulation and Modulation of pH in the Brain

Physiological Reviews ◽

10.1152/physrev.00010.2003 ◽

2003 ◽

Vol 83 (4) ◽

pp. 1183-1221 ◽

Cited By ~ 518

Author(s):

MITCHELL CHESLER

Keyword(s):

Intracellular Ph ◽

Neural Activity ◽

Extracellular Fluid ◽

Cell Types ◽

Brain Regions ◽

Metabolic Products ◽

Homeostatic Function ◽

Acid Extrusion ◽

Activity Dependent ◽

The Brain

Chesler, Mitchell. Regulation and Modulation of pH in the Brain. Physiol Rev 83: 1183-1221, 2003; 10.1152/physrev.00010.2003.—The regulation of pH is a vital homeostatic function shared by all tissues. Mechanisms that govern H+ in the intracellular and extracellular fluid are especially important in the brain, because electrical activity can elicit rapid pH changes in both compartments. These acid-base transients may in turn influence neural activity by affecting a variety of ion channels. The mechanisms responsible for the regulation of intracellular pH in brain are similar to those of other tissues and are comprised principally of forms of Na+/H+ exchange, Na+-driven Cl-/HCO3- exchange, Na+-HCO3- cotransport, and passive Cl-/HCO3- exchange. Differences in the expression or efficacy of these mechanisms have been noted among the functionally and morphologically diverse neurons and glial cells that have been studied. Molecular identification of transporter isoforms has revealed heterogeneity among brain regions and cell types. Neural activity gives rise to an assortment of extracellular and intracellular pH shifts that originate from a variety of mechanisms. Intracellular pH shifts in neurons and glia have been linked to Ca2+ transport, activation of acid extrusion systems, and the accumulation of metabolic products. Extracellular pH shifts can occur within milliseconds of neural activity, arise from an assortment of mechanisms, and are governed by the activity of extracellular carbonic anhydrase. The functional significance of these compartmental, activity-dependent pH shifts is discussed.

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MRI of Capn15 knockout mice and analysis of Capn15 distribution reveal possible roles in brain development and plasticity

10.1101/763888 ◽

2019 ◽

Cited By ~ 1

Author(s):

Congyao Zha ◽

Carole A Farah ◽

Vladimir Fonov ◽

David A. Rudko ◽

Wayne S Sossin

Keyword(s):

Brain Development ◽

Knockout Mice ◽

Brain Plasticity ◽

Small Animal ◽

Cell Types ◽

Cysteine Proteases ◽

Brain Regions ◽

Conditional Knockout ◽

Specific Cell ◽

The Brain

AbstractPurposeThe non-classical Small Optic Lobe (SOL) family of calpains are intracellular cysteine proteases that are expressed in the nervous system and appear to play an important role in neuronal development in both Drosophila, where loss of this calpain leads to the eponymous small optic lobes, and in mouse and human, where loss of this calpain (Capn15) leads to eye anomalies. However, the brain regions where this calpain is expressed and the areas most affected by the loss of this calpain have not been carefully examined.ProceduresWe utilize an insert strain where lacZ is expressed under the control of the Capn15 promoter, together with immunocytochemistry with markers of specific cell types to address where Capn 15 is expressed in the brain. We use small animal MRI comparing WT, Capn15 knockout and Capn15 conditional knockout mice to address the brain regions that are affected when Capn 15 is not present, either in early development of the adult.ResultsCapn15 is expressed in diverse brain regions, many of them involved in plasticity such as the hippocampus, lateral amygdala and Purkinje neurons. Capn15 knockout mice have smaller brains, and present specific deficits in the thalamus and hippocampal regions. There are no deficits revealed by MRI in brain regions when Capn15 is knocked out after development.ConclusionsAreas where Capn15 is expressed in the adult are not good markers for the specific regions where the loss of Capn15 specifically affects brain development. Thus, it is likely that this calpain plays distinct roles in brain development and brain plasticity.

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A Connectome of the Adult Drosophila Central Brain

10.1101/2020.01.21.911859 ◽

2020 ◽

Cited By ~ 34

Author(s):

C. Shan Xu ◽

Michal Januszewski ◽

Zhiyuan Lu ◽

Shin-ya Takemura ◽

Kenneth J. Hayworth ◽

...

Keyword(s):

Large Fraction ◽

Large Data ◽

Fruit Fly ◽

Cell Types ◽

Brain Regions ◽

Central Complex ◽

Data Set ◽

New Methods ◽

Central Brain ◽

The Brain

AbstractThe neural circuits responsible for behavior remain largely unknown. Previous efforts have reconstructed the complete circuits of small animals, with hundreds of neurons, and selected circuits for larger animals. Here we (the FlyEM project at Janelia and collaborators at Google) summarize new methods and present the complete circuitry of a large fraction of the brain of a much more complex animal, the fruit fly Drosophila melanogaster. Improved methods include new procedures to prepare, image, align, segment, find synapses, and proofread such large data sets; new methods that define cell types based on connectivity in addition to morphology; and new methods to simplify access to a large and evolving data set. From the resulting data we derive a better definition of computational compartments and their connections; an exhaustive atlas of cell examples and types, many of them novel; detailed circuits for most of the central brain; and exploration of the statistics and structure of different brain compartments, and the brain as a whole. We make the data public, with a web site and resources specifically designed to make it easy to explore, for all levels of expertise from the expert to the merely curious. The public availability of these data, and the simplified means to access it, dramatically reduces the effort needed to answer typical circuit questions, such as the identity of upstream and downstream neural partners, the circuitry of brain regions, and to link the neurons defined by our analysis with genetic reagents that can be used to study their functions.Note: In the next few weeks, we will release a series of papers with more involved discussions. One paper will detail the hemibrain reconstruction with more extensive analysis and interpretation made possible by this dense connectome. Another paper will explore the central complex, a brain region involved in navigation, motor control, and sleep. A final paper will present insights from the mushroom body, a center of multimodal associative learning in the fly brain.

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Selective Vulnerability

10.1093/med/9780190607166.003.0006 ◽

2017 ◽

Cited By ~ 1

Author(s):

Robert Laureno

Keyword(s):

Amyotrophic Lateral Sclerosis ◽

Brain Structures ◽

Selective Vulnerability ◽

Brain Regions ◽

Degenerative Diseases ◽

Selective System ◽

Hereditary Disorders ◽

The Brain ◽

Lateral Sclerosis ◽

Different Parts

This chapter on “Selective Vulnerability” examines the selective vulnerability of different parts of the brain to particular diseases. In one disease, certain areas of brain are particularly vulnerable. In other diseases, different parts of the brain are more susceptible. The concept of selective vulnerability was originally applied to toxic/metabolic and hereditary disorders, but it is also useful in thinking about other neuropathologic processes including neoplastic, infectious, demyelinative, vascular, and traumatic diseases. Diseases can selectively affect brain systems, brain structures, or brain regions. Selective system involvement is clear in degenerative diseases such as amyotrophic lateral sclerosis; selective structure involvement occurs in carbon monoxide’s effect on the globus pallidus; selective region involvement is found in myelinolysis.

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S100A6 and Its Brain Ligands in Neurodegenerative Disorders

International Journal of Molecular Sciences ◽

10.3390/ijms21113979 ◽

2020 ◽

Vol 21 (11) ◽

pp. 3979

Author(s):

Anna Filipek ◽

Wiesława Leśniak

Keyword(s):

Mammalian Cells ◽

Brain Structures ◽

Cell Types ◽

Cytoskeletal Organization ◽

High Level ◽

S100a6 Protein ◽

Different Cell Types ◽

The Brain ◽

Lateral Sclerosis

The S100A6 protein is present in different mammalian cells and tissues including the brain. It binds Ca2+ and Zn2+ and interacts with many target proteins/ligands. The best characterized ligands of S100A6, expressed at high level in the brain, include CacyBP/SIP and Sgt1. Research concerning the functional role of S100A6 and these two ligands indicates that they are involved in various signaling pathways that regulate cell proliferation, differentiation, cytoskeletal organization, and others. In this review, we focused on the expression/localization of these proteins in the brain and on their possible role in neurodegenerative diseases. Published results demonstrate that S100A6, CacyBP/SIP, and Sgt1 are expressed in various brain structures and in the spinal cord and can be found in different cell types including neurons and astrocytes. When it comes to their possible involvement in nervous system pathology, it is evident that their expression/level and/or subcellular localization is changed when compared to normal conditions. Among diseases in which such changes have been observed are Alzheimer’s disease (AD), amyotrophic lateral sclerosis (ALS), epileptogenesis, Parkinson’s disease (PD), Huntington’s disease (HD), and others.

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Localization of Free and Bound Metal Species through X-Ray Synchrotron Fluorescence Microscopy in the Rodent Brain and Their Relation to Behavior

Brain Sciences ◽

10.3390/brainsci9040074 ◽

2019 ◽

Vol 9 (4) ◽

pp. 74 ◽

Cited By ~ 6

Author(s):

Caroline Neely ◽

Stephen Lippi ◽

Antonio Lanzirotti ◽

Jane Flinn

Keyword(s):

Fluorescence Microscopy ◽

Cell Signaling ◽

Cell Types ◽

Brain Regions ◽

Metal Species ◽

X Ray ◽

Mediate Cell ◽

And Behavior ◽

Regulatory Functions ◽

The Brain

Biometals in the brain, such as zinc, copper, and iron, are often discussed in cases of neurological disorders; however, these metals also have important regulatory functions and mediate cell signaling and plasticity. With the use of synchrotron X-ray fluorescence, our lab localized total, both bound and free, levels of zinc, copper, and iron in a cross section of one hemisphere of a rat brain, which also showed differing metal distributions in different regions within the hippocampus, the site in the brain known to be crucial for certain types of memory. This review discusses the several roles of these metals in brain regions with an emphasis on hippocampal cell signaling, based on spatial mapping obtained from X-ray fluorescence microscopy. We also discuss the localization of these metals and emphasize different cell types and receptors in regions with metal accumulation, as well as the potential relationship between this physiology and behavior.

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Computational modeling of tau pathology spread reveals patterns of regional vulnerability and the impact of a genetic risk factor

Science Advances ◽

10.1126/sciadv.abg6677 ◽

2021 ◽

Vol 7 (24) ◽

pp. eabg6677

Author(s):

Eli J. Cornblath ◽

Howard L. Li ◽

Lakshmi Changolkar ◽

Bin Zhang ◽

Hannah J. Brown ◽

...

Keyword(s):

Expression Patterns ◽

Brain Regions ◽

Spatial Proximity ◽

Leucine Rich Repeat ◽

Related Gene ◽

Tau Pathology ◽

Anatomical Connectivity ◽

Regional Vulnerability ◽

The Impact ◽

The Brain

Neuropathological staging studies have suggested that tau pathology spreads through the brain in Alzheimer’s disease (AD) and other tauopathies, but it is unclear how neuroanatomical connections, spatial proximity, and regional vulnerability contribute. In this study, we seed tau pathology in the brains of nontransgenic mice with AD tau and quantify pathology development over 9 months in 134 brain regions. Network modeling of pathology progression shows that diffusion through the connectome is the best predictor of tau pathology patterns. Further, deviations from pure neuroanatomical spread are used to estimate regional vulnerability to tau pathology and identify related gene expression patterns. Last, we show that pathology spread is altered in mice harboring a mutation in leucine-rich repeat kinase 2. While tau pathology spread is still constrained by anatomical connectivity in these mice, it spreads preferentially in a retrograde direction. This study provides a framework for understanding neuropathological progression in tauopathies.

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