Cristobal Ibaceta scite author profile

Aging is the major risk factor for the development of dementia and neurodegenerative disorders, and the aging brain manifests severe deficits in buffering capacity by the proteostasis network. Accordingly, we investigated the significance of the unfolded protein response (UPR), a major signaling pathway that copes with endoplasmic reticulum (ER) stress, to normal mammalian brain aging. Genetic disruption of ER stress sensor IRE1α accelerated cognitive and motor dysfunction during aging. Exogenous bolstering of the UPR by overexpressing an active form of the transcription factor XBP1 restored synaptic and cognitive function in addition to reducing cell senescence.Remarkably, proteomic profiling of hippocampal tissue indicated that XBP1s expression corrected age-related alterations in synaptic function. Collectively, our data demonstrate that strategies to manipulate the UPR sustain healthy brain aging.One Sentence Summary: The IRE1/XBP1 pathway dictates when and how brain function declines during aging. Main Text:Normal aging is associated with progressive cognitive impairment, representing the most prevalent risk factor for the development of dementia in neurodegenerative disorders. Subtle structural and functional alterations in synapses are the main drivers of age-related cognitive decline (reviewed in 1), but the molecular mechanisms dictating these perturbations are still elusive. Decades of research have defined the hallmarks of

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Characterization of Retinal Functionality at Different Eccentricities in a Diurnal Rodent

Escobar

Reyes

Herzog

et al. 2018

Front. Cell. Neurosci.

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Although the properties of the neurons of the visual system that process central and peripheral regions of the visual field have been widely researched in the visual cortex and the LGN, they have scarcely been documented for the retina. The retina is the first step in integrating optical signals, and despite considerable efforts to functionally characterize the different types of retinal ganglion cells (RGCs), a clear account of the particular functionality of cells with central vs. peripheral fields is still wanting. Here, we use electrophysiological recordings, gathered from retinas of the diurnal rodent Octodon degus, to show that RGCs with peripheral receptive fields (RF) are larger, faster, and have shorter transient responses. This translates into higher sensitivity at high temporal frequencies and a full frequency bandwidth when compared to RGCs with more central RF. We also observed that imbalances between ON and OFF cell populations are preserved with eccentricity. Finally, the high diversity of functional types of RGCs highlights the complexity of the computational strategies implemented in the early stages of visual processing, which could inspire the development of bio-inspired artificial systems.

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Parallel processing of natural images by overlapping retinal neuronal ensembles

Pérez-Ortega¹,

Araya²,

Ibaceta³

et al. 2021

Preprint

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Even though the retinal microcircuit organization has been described in detail at the single-cell level, little is known about how groups of retinal cells' coordinated activity encode and process parallel information representing the spatial and temporal structure of changing environmental conditions. To describe the population dynamics of retinal neuronal ensembles, we used microelectrode array recordings that describe hundreds of retinal ganglion cells' simultaneous activity in response to a short movie captured in the natural environment where our subject develops their visual behaviors. The vectorization of population activity allowed the identification of retinal neuronal ensembles that synchronize to specific segments of natural stimuli. These synchronous retinal neuronal ensembles were reliably activated by the same stimuli at different trials, indicating a robust population response of retinal microcircuits. The generation of asynchronous events required integrating a physiologically meaningful time window larger than 80 ms, demonstrating that retinal neuronal ensembles' time integration filters non-structured visual information. Interestingly, individual neurons could be part of several ensembles indicating that parallel circuits could encode environmental conditions changes. We conclude that parallel neuronal ensembles could represent the functional unit of retinal computations and propose that the further study of retinal neuronal ensembles could reveal emergent properties of retinal circuits that individual cells' activity cannot explain.

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Functional Asymmetries between Central and Peripheral Retinal Ganglion Cells in a Diurnal Rodent

Escobar

Otero

Reyes

et al. 2018

Preprint

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The segregated properties of the visual system processing central or peripheral regions of the visual field have been widely studied in the visual cortex and the LGN, but rarely reported in retina. The retina performs complex computational strategies to extract spatial-temporal features that are in coherence with animal behavior and survival. Even if a big effort has been done to functionally characterize different retinal ganglion cell (RGC) types, a clear account of the particular functionality of central and peripheral cells is still missing. Here, using electrophysiological data obtained with a 256-MEA recording system on female diurnal rodent retinas (Octodon degus), we evidenced that peripheral RGCs have larger receptive fields, more sustained, faster and shorter temporal responses and sensitive to higher temporal frequencies with a broader frequency bandwidth than the center. Additionally, we also compared the asymmetries between ON and OFF cell populations present in each region, reporting that these asymmetries are dependent on the eccentricity. Finally, the presence of the asymmetries here reported emphasizes even more the complexity of computational strategies performed by the retina, which could serve as inspiration for the development of artificial visual systems.

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Abstract 475: Vasopressin Type 2 Receptor (v2r) Activation Increases Renin Expression In Renal Collecting Duct Cells.

et al. 2014

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Renin synthesis in juxtaglomerular cells (JGC) is mediated by intracellular cAMP accumulation and activation of PKA/CREB pathway. Recent evidence demonstrated that renin is expressed in renal collecting duct (CD) cells. Furthermore, it has been shown that CD renin is augmented in animal models of hypertension and kidney disease, despite the suppressed expression observed in JGC. Vasopressin activates V2R stimulating cAMP/PKA/CREB pathway and aquaporin-2 expression in apical plasma membrane of principal cells of the CD. We hypothesized that activation of V2R increases renin expression in mouse CD cell line M-1 through cAMP/PKA/CREB pathway. Desmopressin (ddAVP, 10-6 mol/L, 6 hrs), a specific V2R agonist, increased renin mRNA, prorenin protein levels in cell lysates and prorenin secretion to the culture media. To determine if this effect was related to PKA pathway, we used the PKA inhibitor H89. Co-treatment with ddAVP + H89 prevented the ddAVP-mediated increase in renin expression. To further confirm if the stimulation of renin synthesis in M-1 cells was mediated by cAMP accumulation, we raised intracellular cAMP levels using forskolin (10-7 mol/L). Forskolin treatment significantly increased renin mRNA and prorenin protein levels as compared to controls. Additionally, ddAVP increased phosphorylated CREB, while H89 blunted this effect. Finally, shRNA against CREB prevented the ddAVP-induced renin synthesis. We additionally confirmed the stimulatory effects of Ang II + ddAVP on renin synthesis in mpkccdc14 cell line, a mouse cortical line composed only by CD principal cells. Tolvaptan (V2R antagonist) reduced the additive effect of Ang II + ddAVP on renin expression. To achieve in vivo relevance we further measured renin mRNA levels in renal inner medullary tissues from mice subjected to 16 hours of water deprivation and controls. Mice water-deprived showed significantly greater renin mRNA levels in the renal inner medulla than controls. These results indicate that the activation of V2R stimulates renin mRNA synthesis and prorenin secretion in M-1 cells via cAMP/PKA/CREB pathway.

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