Georgina Gáti scite author profile

Perineuronal matrix is an extracellular protein scaffold to shape neuronal responsiveness and survival. Whilst perineuronal nets engulf the somatodendritic axis of neurons, axonal coats are focal extracellular protein aggregates surrounding individual synapses. Here, we addressed the chemical identity and subcellular localization of both perineuronal and perisynaptic matrices in the human hippocampus, whose neuronal circuitry is progressively compromised in Alzheimer's disease. We hypothesized that (1) the cellular expression sites of chondroitin sulphate proteoglycan-containing extracellular matrix associate with specific neuronal identities, reflecting network dynamics, and (2) the regional distribution and molecular composition of axonal coats must withstand Alzheimer's disease-related modifications to protect functional synapses. We show by epitope-specific antibodies that the perineuronal protomap of the human hippocampus is distinct from other mammals since pyramidal cells but not calretinin(+) and calbindin(+) interneurons, neurochemically classified as novel neuronal subtypes, lack perineuronal nets. We find that cartilage link protein-1 and brevican-containing matrices form isolated perisynaptic coats, engulfing both inhibitory and excitatory terminals in the dentate gyrus and entorhinal cortex. Ultrastructural analysis revealed that presynaptic neurons contribute components of perisynaptic coats via axonal transport. We demonstrate, by combining biochemical profiling and neuroanatomy in Alzheimer's patients and transgenic (APdE9) mice, the preserved turnover and distribution of axonal coats around functional synapses along dendrite segments containing hyperphosphorylated tau and in amyloid-β-laden hippocampal microdomains. We conclude that the presynapse-driven formation of axonal coats is a candidate mechanism to maintain synapse integrity under neurodegenerative conditions.

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Revival of Calcium-Binding Proteins for Neuromorphology: Secretagogin Typifies Distinct Cell Populations in the Avian Brain

Gáti

Lendvai

Hökfelt³

et al. 2014

Brain Behav Evol

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In the vertebrate nervous system, the Ca²⁺-binding proteins parvalbumin, calbindin and calretinin have been extensively used to elaborate the molecular diversity of neuronal subtypes. Secretagogin is a phylogenetically conserved Ca²⁺-binding protein, which marks neuronal populations largely distinct from other Ca²⁺-binding proteins in mammals. Whether secretagogin is expressed in nonmammalian vertebrates, particularly in birds, and, if so, with a brain cytoarchitectonic design different from that of mammals is unknown. Here, we show that secretagogin is already present in the hatchlings' brain with continued presence into adulthood. Secretagogin-immunoreactive neurons primarily accumulate in the olfactory bulb, septum, subpallial amygdala, hippocampus, hypothalamus, habenular nuclei and deep layers of the optic tectum of adult domestic chicks (Gallus domesticus). In the olfactory bulb, secretagogin labels periglomerular neurons as well as a cell continuum ascending dorsomedially, reaching the ventricular wall. Between the hippocampus and septal nuclei, the interconnecting thin septal tissue harbors secretagogin-immunoreactive neurons that contact the ventricular wall with their ramifying dendritic processes. Secretagogin is also present in the neuroendocrine hypothalamus, with particularly rich neuronal clusters seen in its suprachiasmatic and infundibular nuclei. Secretagogin expression identified a hitherto undescribed cell contingent along intratelencephalic cell-free laminae separating brain regions or marking the palliosubpallial boundary, as well as a dense neuronal population in the area corticoidea lateralis. In both the telencephalon and midbrain, secretagogin complemented the distribution of the canonical ‘neuronal' Ca²⁺-binding proteins. Our findings identify novel neuronal subtypes, connectivity patterns in brain areas functionally relevant to olfaction, orientation, behavior as well as endocrine functions, which will help refine existing concepts on the neuronal diversity and organizational principles of the avian brain.

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Chondroitin sulfate proteoglycan-based extracellular matrix in chicken (Gallus domesticus) brain

et al. 2009

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Distribution and classification of aggrecan‐based extracellular matrix in the thalamus of the rat

Gáti

Morawski

Lendvai

et al. 2010

J of Neuroscience Research

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Extracellular matrix molecules take part in functional isolation and stabilization of neuronal compartments but form a vivid interface between neuronal elements at the same time. Previous studies have shown that the accumulation of extracellular matrix, especially its typical phenotypic form, termed perineuronal nets, correlates not only with the functional properties of the single neuron but also with the functional properties of the whole brain area. In contrast to recent advances in investigating neocortex, the present study mapped the occurrence and phenotypic appearance of aggrecan-based matrix accumulation throughout the rat thalamus. Results showed that divisions of thalamus that relay information to cortical fields known rather for their plastic properties exibit a poor matrix immunoreactivity, whereas matrix accumulation is more enhanced in nuclei connected to primary cortical regions. In addition to perineuronal nets, extracellular matrix condensed in another peculiar form, in 2-5-μm, large, round or oval structures, as described by Brückner et al. ([ 2008] Neuroscience 151:489-504) as axonal coats (ACs). Multiple labelling experiments showed that specific excitatory afferents were not ensheathed with these structures. At the same time, inhibitory endings were occasionally enwrapped in ACs. Electron microscopic analysis showed that aggrecan-immunoreactive profiles were present mostly around inhibitory terminals but also in all neuronal compartments. We suggest that aggrecan-based extracellular matrix is formed by both pre- and postsynaptic elements and is preferably associated with inhibitory terminals in the extracellular space.

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Chondroitin sulphate proteoglycan-based perineuronal net establishment is largely activity-independent in chick visual system

Gáti

Morawski

Lendvai

et al. 2010

Journal of Chemical Neuroanatomy

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Georgina Gáti

Neurochemical mapping of the human hippocampus reveals perisynaptic matrix around functional synapses in Alzheimer’s disease

Revival of Calcium-Binding Proteins for Neuromorphology: Secretagogin Typifies Distinct Cell Populations in the Avian Brain

Chondroitin sulfate proteoglycan-based extracellular matrix in chicken (Gallus domesticus) brain

Distribution and classification of aggrecan‐based extracellular matrix in the thalamus of the rat

Chondroitin sulphate proteoglycan-based perineuronal net establishment is largely activity-independent in chick visual system

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