Your search keyword '"Attila G. Bagó"' showing total 2 results

1. Cell-specific expression of key mitochondrial enzymes limits OXPHOS in astrocytes of the adult human neocortex and hippocampal formation.

Author

Dobolyi, Arpád, Cservenák, Melinda, Bagó, Attila G., Chen, Chun, Stepanova, Anna, Paal, Krisztina, Lee, Jeonghyoun, Palkovits, Miklós, Hudson, Gavin, and Chinopoulos, Christos

Subjects

ASTROCYTES, NEOCORTEX, HIPPOCAMPUS (Brain), MITOCHONDRIAL proteins, OXIDATIVE phosphorylation

Abstract

The astrocyte-to-neuron lactate shuttle model entails that, upon glutamatergic neurotransmission, glycolytically derived pyruvate in astrocytes is mainly converted to lactate instead of being entirely catabolized in mitochondria. The mechanism of this metabolic rewiring and its occurrence in human brain are unclear. Here by using immunohistochemistry (4 brains) and imaging mass cytometry (8 brains) we show that astrocytes of the adult human neocortex and hippocampal formation express barely detectable amounts of mitochondrial proteins critical for performing oxidative phosphorylation (OXPHOS). These data are corroborated by queries of transcriptomes (107 brains) of neuronal versus non-neuronal cells fetched from the Allen Institute for Brain Science for genes coding for a much larger repertoire of entities contributing to OXPHOS, showing that human non-neuronal elements barely expressed mRNAs coding for such proteins. With less OXPHOS, human brain astrocytes are thus bound to produce more lactate to avoid interruption of glycolysis. Human brain astrocytes lack OXPHOS, ensuring lactate formation and shuttling to neurons. [ABSTRACT FROM AUTHOR]

Published

2024

2. Perisomatic Inhibition and Its Relation to Epilepsy and to Synchrony Generation in the Human Neocortex.

Author

Tóth, Estilla Zsófia, Szabó, Felicia Gyöngyvér, Kandrács, Ágnes, Molnár, Noémi Orsolya, Nagy, Gábor, Bagó, Attila G., Erőss, Loránd, Fabó, Dániel, Hajnal, Boglárka, Rácz, Bence, Wittner, Lucia, Ulbert, István, and Tóth, Kinga

Subjects

INTERNEURONS, CANNABINOID receptors, SYNCHRONIC order, EPILEPSY, PYRAMIDAL neurons, NEOCORTEX

Abstract

Inhibitory neurons innervating the perisomatic region of cortical excitatory principal cells are known to control the emergence of several physiological and pathological synchronous events, including epileptic interictal spikes. In humans, little is known about their role in synchrony generation, although their changes in epilepsy have been thoroughly investigated. This paper demonstraits how parvalbumin (PV)- and type 1 cannabinoid receptor (CB1R)-positive perisomatic interneurons innervate pyramidal cell bodies, and their role in synchronous population events spontaneously emerging in the human epileptic and non-epileptic neocortex, in vitro. Quantitative electron microscopy showed that the overall, PV+ and CB1R+ somatic inhibitory inputs remained unchanged in focal cortical epilepsy. On the contrary, the size of PV-stained synapses increased, and their number decreased in epileptic samples, in synchrony generating regions. Pharmacology demonstrated—in conjunction with the electron microscopy—that although both perisomatic cell types participate, PV+ cells have stronger influence on the generation of population activity in epileptic samples. The somatic inhibitory input of neocortical pyramidal cells remained almost intact in epilepsy, but the larger and consequently more efficient somatic synapses might account for a higher synchrony in this neuron population. This, together with epileptic hyperexcitability, might make a cortical region predisposed to generate or participate in hypersynchronous events. [ABSTRACT FROM AUTHOR]

Published

2022