Reinforcing Interdisciplinary Collaborations to Unravel the Astrocyte "Calcium Code"

Impact of masticatory activity and rehabilitation on astrocyte morphology across the molecular layer of the dentate gyrus: Insights from the outer, medial, and inner sublayers and their relationship with spatial learning and memory

The dentate gyrus plays a crucial role in learning and spatial memory, particularly in its middle third molecular layer, which receives the primary afferent input via the medial perforant path. Interestingly, changes in masticatory activity are described to affect this region with visible astrogliosis, release of pro-inflammatory cytokines and oxidative stress, affecting synaptic physiology, and cognition. This study aimed to investigate the impact of altered masticatory activity on spatial memory in young Swiss albino mice, correlating these effects with morphological changes in astrocytes. The mice were divided into three groups: Hard diet with pellets (HD), hard diet/soft diet (HD/SD, reduced masticatory activity), and HD/SD/HD (rehabilitated). The Morris water maze test was used to measure escape latency, while three-dimensional microscopic reconstruction methods provided morphometric data on the astrocytes. Hierarchical clustering analysis validated the existence of four morphological subtypes with decreasing complexity (AST1, AST2, AST3, and AST4), in the outer, middle, and inner thirds of the dentate gyrus molecular layer. Changes in masticatory activity affected the number and distribution of astrocytes subtypes excepting AST3 in the middle third layer. Canonical discriminant function analysis indicated that complexity was the variable most influencing cluster formation. Correlation tests between complexity and escape latency for each animal group showed a significant correlation with a large effect size of 60 % [Pearson's R: 0.605, p < 0.001] in the HD group in the middle third, which was disrupted by altered masticatory activity. AST3 morphotype in the middle third showed a linear correlation with learning and spatial memory functions in the HD group [Pearson's R: 0.624, p < 0.001] that disappeared with a reduction in masticatory activity, and nor restored by diet rehabilitation. This finding was not observed for inner and outer layers, supporting the contribution of middle third AST3 to learning and spatial memory. Group comparison tests also revealed that diet differentially impacts astrocyte subpopulations on each third of the dentate gyrus molecular layer. Data validate the influence of the masticatory activity on astrocyte complexity and suggest the existence of AST3 association with spatial memory and learning tasks in young female mice. Further research on the underlying mechanisms of these relationships is essential to identify potential therapeutic targets for cognitive disorders and to develop effective interventions to preserve cognitive function.

Deciphering the Calcium Code: A Review of Calcium Activity Analysis Methods Employed to Identify Meaningful Activity in Early Neural Development

The intracellular and intercellular flux of calcium ions represents an ancient and universal mode of signaling that regulates an extensive array of cellular processes. Evidence for the central role of calcium signaling includes various techniques that allow the visualization of calcium activity in living cells. While extensively investigated in mature cells, calcium activity is equally important in developing cells, particularly the embryonic nervous system where it has been implicated in a wide variety array of determinative events. However, unlike in mature cells, where the calcium dynamics display regular, predictable patterns, calcium activity in developing systems is far more sporadic, irregular, and diverse. This renders the ability to assess calcium activity in a consistent manner extremely challenging, challenges reflected in the diversity of methods employed to analyze calcium activity in neural development. Here we review the wide array of calcium detection and analysis methods used across studies, limiting the extent to which they can be comparatively analyzed. The goal is to provide investigators not only with an overview of calcium activity analysis techniques currently available, but also to offer suggestions for future work and standardization to enable informative comparative evaluations of this fundamental and important process in neural development.

Astrocytes: new evidence, new models, new roles

Astrocytes have been in the limelight of active research for about 3 decades now. Over this period, ideas about their function and role in the nervous system have evolved from simple assistance in energy supply and homeostasis maintenance to a complex informational and metabolic hub that integrates data on local neuronal activity, sensory and arousal context, and orchestrates many crucial processes in the brain. Rapid progress in experimental techniques and data analysis produces a growing body of data, which can be used as a foundation for formulation of new hypotheses, building new refined mathematical models, and ultimately should lead to a new level of understanding of the contribution of astrocytes to the cognitive tasks performed by the brain. Here, we highlight recent progress in astrocyte research, which we believe expands our understanding of how low-level signaling at a cellular level builds up to processes at the level of the whole brain and animal behavior. We start our review with revisiting data on the role of noradrenaline-mediated astrocytic signaling in locomotion, arousal, sensory integration, memory, and sleep. We then briefly review astrocyte contribution to the regulation of cerebral blood flow regulation, which is followed by a discussion of biophysical mechanisms underlying astrocyte effects on different brain processes. The experimental section is closed by an overview of recent experimental techniques available for modulation and visualization of astrocyte dynamics. We then evaluate how the new data can be potentially incorporated into the new mathematical models or where and how it already has been done. Finally, we discuss an interesting prospect that astrocytes may be key players in important processes such as the switching between sleep and wakefulness and the removal of toxic metabolites from the brain milieu.

Analysis of Network Models with Neuron-Astrocyte Interactions

Neural networks, composed of many neurons and governed by complex interactions between them, are a widely accepted formalism for modeling and exploring global dynamics and emergent properties in brain systems. In the past decades, experimental evidence of computationally relevant neuron-astrocyte interactions, as well as the astrocytic modulation of global neural dynamics, have accumulated. These findings motivated advances in computational glioscience and inspired several models integrating mechanisms of neuron-astrocyte interactions into the standard neural network formalism. These models were developed to study, for example, synchronization, information transfer, synaptic plasticity, and hyperexcitability, as well as classification tasks and hardware implementations. We here focus on network models of at least two neurons interacting bidirectionally with at least two astrocytes that include explicitly modeled astrocytic calcium dynamics. In this study, we analyze the evolution of these models and the biophysical, biochemical, cellular, and network mechanisms used to construct them. Based on our analysis, we propose how to systematically describe and categorize interaction schemes between cells in neuron-astrocyte networks. We additionally study the models in view of the existing experimental data and present future perspectives. Our analysis is an important first step towards understanding astrocytic contribution to brain functions. However, more advances are needed to collect comprehensive data about astrocyte morphology and physiology in vivo and to better integrate them in data-driven computational models. Broadening the discussion about theoretical approaches and expanding the computational tools is necessary to better understand astrocytes' roles in brain functions.

Looking to the stars for answers: Strategies for determining how astrocytes influence neuronal activity

Astrocytes are critical components of neural circuits positioned in close proximity to the synapse, allowing them to rapidly sense and respond to neuronal activity. One repeatedly observed biomarker of astroglial activation is an increase in intracellular Ca²⁺ levels. These astroglial Ca²⁺ signals are often observed spreading throughout various cellular compartments from perisynaptic astroglial processes, to major astrocytic branches and on to the soma or cell body. Here we review recent evidence demonstrating that astrocytic Ca²⁺ events are remarkably heterogeneous in both form and function, propagate through the astroglial syncytia, and are directly linked to the ability of astroglia to influence local neuronal activity. As many of the cellular functions of astroglia can be linked to intracellular Ca²⁺ signaling, and the diversity and heterogeneity of these events becomes more apparent, there is an increasing need for novel experimental strategies designed to better understand the how these signals evolve in parallel with neuronal activity. Here we review the recent advances that enable the characterization of both subcellular and population-wide astrocytic Ca²⁺ dynamics. Additionally, we also outline the experimental design required for simultaneous in vivo Ca²⁺ imaging in the context of neuronal or astroglial manipulation, highlighting new experimental strategies made possible by recent advances in viral vector, imaging, and quantification technologies. Through combined usage of these reagents and methodologies, we provide a conceptual framework to study how astrocytes functionally integrate into neural circuits and to what extent they influence and direct the synaptic activity underlying behavioral responses.