Nanoscale and functional heterogeneity of the hippocampal extracellular space

The extracellular space (ECS) and its constituents play a crucial role in brain development, plasticity, circadian rhythm, and behavior, as well as brain diseases. Yet, since this compartment has an intricate geometry and nanoscale dimensions, its detailed exploration in live tissue has remained an...

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Vydané v:Cell reports (Cambridge) Ročník 42; číslo 5; s. 112478
Hlavní autori: Grassi, Diego, Idziak, Agata, Lee, Antony, Calaresu, Ivo, Sibarita, Jean-Baptiste, Cognet, Laurent, Nägerl, U. Valentin, Groc, Laurent
Médium: Journal Article
Jazyk:English
Vydavateľské údaje: United States Elsevier Inc 30.05.2023
Cell Press
Elsevier
Predmet:
brain
CP: Neuroscience
extracellular matrix
extracellular space
immunoglobulin
Life Sciences
Neurons and Cognition
single molecule
single quantum dot imaging
super-resolution
single molecule
immunoglobulin
CP: Neuroscience
super-resolution
single quantum dot imaging
extracellular space
brain
extracellular matrix
ISSN:2211-1247, 2211-1247
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Abstract The extracellular space (ECS) and its constituents play a crucial role in brain development, plasticity, circadian rhythm, and behavior, as well as brain diseases. Yet, since this compartment has an intricate geometry and nanoscale dimensions, its detailed exploration in live tissue has remained an unmet challenge. Here, we used a combination of single-nanoparticle tracking and super-resolution microscopy approaches to map the nanoscale dimensions of the ECS across the rodent hippocampus. We report that these dimensions are heterogeneous between hippocampal areas. Notably, stratum radiatum CA1 and CA3 ECS differ in several characteristics, a difference that gets abolished after digestion of the extracellular matrix. The dynamics of extracellular immunoglobulins vary within these areas, consistent with their distinct ECS characteristics. Altogether, we demonstrate that ECS nanoscale anatomy and diffusion properties are widely heterogeneous across hippocampal areas, impacting the dynamics and distribution of extracellular molecules. [Display omitted] •Nanoscale map of the hippocampal formation extracellular space•The extracellular space characteristics differ between areas and layers•The CA1 stratum radiatum extracellular space is smaller but more fluid than in CA3•The extracellular space characteristics tune immunoglobulin distribution Grassi et al. describe the nanoscale organization of the extracellular space of the rodent hippocampus. Its physical properties differ strongly across the hippocampus, in particular between the stratum radiatum of CA1/3. These marked differences go hand in hand with differences in the dynamics and distribution of immunoglobulins in these areas.
AbstractList The extracellular space (ECS) and its constituents play a crucial role in brain development, plasticity, circadian rhythm, and behavior, as well as brain diseases. Yet, since this compartment has an intricate geometry and nanoscale dimensions, its detailed exploration in live tissue has remained an unmet challenge. Here, we used a combination of single-nanoparticle tracking and super-resolution microscopy approaches to map the nanoscale dimensions of the ECS across the rodent hippocampus. We report that these dimensions are heterogeneous between hippocampal areas. Notably, stratum radiatum CA1 and CA3 ECS differ in several characteristics, a difference that gets abolished after digestion of the extracellular matrix. The dynamics of extracellular immunoglobulins vary within these areas, consistent with their distinct ECS characteristics. Altogether, we demonstrate that ECS nanoscale anatomy and diffusion properties are widely heterogeneous across hippocampal areas, impacting the dynamics and distribution of extracellular molecules.The extracellular space (ECS) and its constituents play a crucial role in brain development, plasticity, circadian rhythm, and behavior, as well as brain diseases. Yet, since this compartment has an intricate geometry and nanoscale dimensions, its detailed exploration in live tissue has remained an unmet challenge. Here, we used a combination of single-nanoparticle tracking and super-resolution microscopy approaches to map the nanoscale dimensions of the ECS across the rodent hippocampus. We report that these dimensions are heterogeneous between hippocampal areas. Notably, stratum radiatum CA1 and CA3 ECS differ in several characteristics, a difference that gets abolished after digestion of the extracellular matrix. The dynamics of extracellular immunoglobulins vary within these areas, consistent with their distinct ECS characteristics. Altogether, we demonstrate that ECS nanoscale anatomy and diffusion properties are widely heterogeneous across hippocampal areas, impacting the dynamics and distribution of extracellular molecules.
The extracellular space (ECS) and its constituents play a crucial role in brain development, plasticity, circadian rhythm, and behavior, as well as brain diseases. Yet, since this compartment has an intricate geometry and nanoscale dimensions, its detailed exploration in live tissue has remained an unmet challenge. Here, we used a combination of single-nanoparticle tracking and super-resolution microscopy approaches to map the nanoscale dimensions of the ECS across the rodent hippocampus. We report that these dimensions are heterogeneous between hippocampal areas. Notably, stratum radiatum CA1 and CA3 ECS differ in several characteristics, a difference that gets abolished after digestion of the extracellular matrix. The dynamics of extracellular immunoglobulins vary within these areas, consistent with their distinct ECS characteristics. Altogether, we demonstrate that ECS nanoscale anatomy and diffusion properties are widely heterogeneous across hippocampal areas, impacting the dynamics and distribution of extracellular molecules. • Nanoscale map of the hippocampal formation extracellular space • The extracellular space characteristics differ between areas and layers • The CA1 stratum radiatum extracellular space is smaller but more fluid than in CA3 • The extracellular space characteristics tune immunoglobulin distribution Grassi et al. describe the nanoscale organization of the extracellular space of the rodent hippocampus. Its physical properties differ strongly across the hippocampus, in particular between the stratum radiatum of CA1/3. These marked differences go hand in hand with differences in the dynamics and distribution of immunoglobulins in these areas.
The extracellular space (ECS) and its constituents play a crucial role in brain development, plasticity, circadian rhythm, and behavior, as well as brain diseases. Yet, since this compartment has an intricate geometry and nanoscale dimensions, its detailed exploration in live tissue has remained an unmet challenge. Here, we used a combination of single-nanoparticle tracking and super-resolution microscopy approaches to map the nanoscale dimensions of the ECS across the rodent hippocampus. We report that these dimensions are heterogeneous between hippocampal areas. Notably, stratum radiatum CA1 and CA3 ECS differ in several characteristics, a difference that gets abolished after digestion of the extracellular matrix. The dynamics of extracellular immunoglobulins vary within these areas, consistent with their distinct ECS characteristics. Altogether, we demonstrate that ECS nanoscale anatomy and diffusion properties are widely heterogeneous across hippocampal areas, impacting the dynamics and distribution of extracellular molecules. [Display omitted] •Nanoscale map of the hippocampal formation extracellular space•The extracellular space characteristics differ between areas and layers•The CA1 stratum radiatum extracellular space is smaller but more fluid than in CA3•The extracellular space characteristics tune immunoglobulin distribution Grassi et al. describe the nanoscale organization of the extracellular space of the rodent hippocampus. Its physical properties differ strongly across the hippocampus, in particular between the stratum radiatum of CA1/3. These marked differences go hand in hand with differences in the dynamics and distribution of immunoglobulins in these areas.
The extracellular space (ECS) and its constituents play a crucial role in brain development, plasticity, circadian rhythm, and behavior, as well as brain diseases. Yet, since this compartment has an intricate geometry and nanoscale dimensions, its detailed exploration in live tissue has remained an unmet challenge. Here, we used a combination of single-nanoparticle tracking and super-resolution microscopy approaches to map the nanoscale dimensions of the ECS across the rodent hippocampus. We report that these dimensions are heterogeneous between hippocampal areas. Notably, stratum radiatum CA1 and CA3 ECS differ in several characteristics, a difference that gets abolished after digestion of the extracellular matrix. The dynamics of extracellular immunoglobulins vary within these areas, consistent with their distinct ECS characteristics. Altogether, we demonstrate that ECS nanoscale anatomy and diffusion properties are widely heterogeneous across hippocampal areas, impacting the dynamics and distribution of extracellular molecules.
ArticleNumber 112478
Author Sibarita, Jean-Baptiste
Cognet, Laurent
Groc, Laurent
Lee, Antony
Idziak, Agata
Grassi, Diego
Calaresu, Ivo
Nägerl, U. Valentin
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Issue 5
Keywords single molecule
immunoglobulin
CP: Neuroscience
super-resolution
single quantum dot imaging
extracellular space
brain
extracellular matrix
Language English
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Snippet The extracellular space (ECS) and its constituents play a crucial role in brain development, plasticity, circadian rhythm, and behavior, as well as brain...
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SubjectTerms brain
CP: Neuroscience
extracellular matrix
extracellular space
immunoglobulin
Life Sciences
Neurons and Cognition
single molecule
single quantum dot imaging
super-resolution
Title Nanoscale and functional heterogeneity of the hippocampal extracellular space
URI https://dx.doi.org/10.1016/j.celrep.2023.112478
https://www.ncbi.nlm.nih.gov/pubmed/37149864
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