The Transcriptome and Metabolic Gene Signature of Protoplasmic Astrocytes in the Adult Murine Cortex

Lovatt, Ditte; Sonnewald, Ursula; Waagepetersen, Helle S.; Schousboe, Arne; He, Wei; Lin, Jane H.-C.; Han, Xiaoning; Takano, Takahiro; Wang, Su; Sim, Fraser J.; Goldman, Steven A.

doi:10.1523/jneurosci.3404-07.2007

Cited by 437 publications

(461 citation statements)

References 52 publications

(65 reference statements)

Supporting

Mentioning

417

Contrasting

Unclassified

Order By: Relevance

“…The astrocytic filopodial processes that surround and interact with synaptic structures contain mitochondria (Lovatt et al, 2007;Pardo et al, 2011;Lavialle et al, 2011) and have the potential to oxidize glucose, glycogen, and glutamate during activation. If brain activation stimulated only glycolysis in astrocytes, it would be reasonable to assign the ATP derived from this pathway toward the energetics of glutamate uptake.…”

Section: Brain Activation In Vivo Activates Glycogenolysis and Oxidatmentioning

confidence: 99%

Brain Lactate Metabolism: The Discoveries and the Controversies

Dienel

2011

J Cereb Blood Flow Metab

416

434

View full text Add to dashboard Cite

Potential roles for lactate in the energetics of brain activation have changed radically during the past three decades, shifting from waste product to supplemental fuel and signaling molecule. Current models for lactate transport and metabolism involving cellular responses to excitatory neurotransmission are highly debated, owing, in part, to discordant results obtained in different experimental systems and conditions. Major conclusions drawn from tabular data summarizing results obtained in many laboratories are as follows: Glutamate-stimulated glycolysis is not an inherent property of all astrocyte cultures. Synaptosomes from the adult brain and many preparations of cultured neurons have high capacities to increase glucose transport, glycolysis, and glucose-supported respiration, and pathway rates are stimulated by glutamate and compounds that enhance metabolic demand. Lactate accumulation in activated tissue is a minor fraction of glucose metabolized and does not reflect pathway fluxes. Brain activation in subjects with low plasma lactate causes outward, brain-toblood lactate gradients, and lactate is quickly released in substantial amounts. Lactate utilization by the adult brain increases during lactate infusions and strenuous exercise that markedly increase blood lactate levels. Lactate can be an 'opportunistic', glucose-sparing substrate when present in high amounts, but most evidence supports glucose as the major fuel for normal, activated brain. Keywords: astrocyte; brain activation; glucose; lactate shuttling; metabolism; neuron Glucose is the major fuel for the brain, and its metabolism by different pathways has important functions related to energetics, neurotransmission, oxidation-reduction (redox) reactions, and biosynthesis of essential brain components (Figure 1). For many decades, lactate production in the brain was viewed as a consequence of inadequate oxygen delivery, disruption of oxidative metabolism, or mismatch between glycolytic and oxidative rates (Siesjö, 1978), but more recently, the conceptual role of lactate metabolism and function in the normal brain have undergone major changes, shifting from developmental fuel and glycolytic waste product to include its use as a supplemental fuel and signaling molecule. Starting in the 1970s to 1980s studies carried out in different laboratories with diverse experimental interests related to brain function brought attention to upregulation of glycolysis, lactate production, lactate release into the blood, the possibility of lactate shuttling among cell types within the brain, lactate fueling adult brain during exercise, and roles of lactate in the regulation of blood flow; some of these topics are controversial and highly debated. The experimental paradigm and physiologic status of subjects are critical for interpretation of data, and this review first presents a brief historical overview of studies related to brain lactate transport and metabolism, then compares sets of data to provide a perspective and context within which the consistency of simi...

show abstract

Section: Brain Activation In Vivo Activates Glycogenolysis and Oxidatmentioning

confidence: 99%

Brain Lactate Metabolism: The Discoveries and the Controversies

Dienel

2011

J Cereb Blood Flow Metab

416

434

View full text Add to dashboard Cite

show abstract

“…In contrast to the mixed distribution of GPR37, GPR37L1 is highly expressed in astrocytes, with in situ hybridization revealing greatest density of GPR37L1 within the Bergmann glia of the cerebellum (Valdenaire et al, 1998). Microarray studies reported more than 100 times higher expression of GPR37L1 in rat and mice astrocytes compared with neurons (Cahoy et al, 2008; Lovatt et al, 2007; Zhang et al, 2014). GPR37L1 is also expressed in oligodendrocytes (Zhang et al, 2014).…”

Section: Potential Therapeutic Targets In Astrocytesmentioning

confidence: 99%

Astroglia as a cellular target for neuroprotection and treatment of neuro‐psychiatric disorders

Liu

Teschemacher

Kasparov

2017

Glia

View full text Add to dashboard Cite

Astrocytes are key homeostatic cells of the central nervous system. They cooperate with neurons at several levels, including ion and water homeostasis, chemical signal transmission, blood flow regulation, immune and oxidative stress defense, supply of metabolites and neurogenesis. Astroglia is also important for viability and maturation of stem‐cell derived neurons. Neurons critically depend on intrinsic protective and supportive properties of astrocytes. Conversely, all forms of pathogenic stimuli which disturb astrocytic functions compromise neuronal functionality and viability. Support of neuroprotective functions of astrocytes is thus an important strategy for enhancing neuronal survival and improving outcomes in disease states. In this review, we first briefly examine how astrocytic dysfunction contributes to major neurological disorders, which are traditionally associated with malfunctioning of processes residing in neurons. Possible molecular entities within astrocytes that could underpin the cause, initiation and/or progression of various disorders are outlined. In the second section, we explore opportunities enhancing neuroprotective function of astroglia. We consider targeting astrocyte‐specific molecular pathways which are involved in neuroprotection or could be expected to have a therapeutic value. Examples of those are oxidative stress defense mechanisms, glutamate uptake, purinergic signaling, water and ion homeostasis, connexin gap junctions, neurotrophic factors and the Nrf2‐ARE pathway. We propose that enhancing the neuroprotective capacity of astrocytes is a viable strategy for improving brain resilience and developing new therapeutic approaches.

show abstract

“…Primary cultures of astrocytes, which provide a seductive experimental simplicity, are not reliable indicators of the properties of astrocytes and how they behave in situ (Kimelberg, 1995;Kimelberg et al, 1997;Kimelberg, 2001;Lovatt et al, 2007;Cahoy et al, 2008). These alternative paths are (1) release by reversal of excitatory amino acid (EAA) transporters, which is only likely to occur under pathological conditions, (2) swelling activated anion channels and also hemi-channels, and (3) P2X receptors for ATP.…”

Section: Are There Widespread Consequences Of Alterations In Astrocytmentioning

confidence: 99%

“…Otherwise the energy requirements at the process ends would have to be met by glycolysis, which is much less efficient. However, a recent paper in which GFAP promoter-driven GFP was used to identify small astrocyte perisynaptic end-feet found that the number of mitochondria in the end-feet was either as great or greater than other profiles in the surrounding neuropil (Lovatt et al, 2007). However, Chao et al (2002) using electron microscopy and S100-immunoreactivity to identify the processes have noted previously that the fine lamellae and filipodia are devoid of organelles, unlike the astrocytic cell body and processes.…”

Section: A General Support Role For Astrocytesmentioning

confidence: 99%

Supportive or information-processing functions of the mature protoplasmic astrocyte in the mammalian CNS? A critical appraisal

Kimelberg

2007

Neuron Glia Biol.

View full text Add to dashboard Cite

It has been proposed that astrocytes should no longer be viewed purely as support cells for neurons, such as providing a constant environment and metabolic substrates, but that they should also be viewed as being involved in affecting synaptic activity in an active way and, therefore, an integral part of the information-processing properties of the brain. This essay discusses the possible differences between a support and an instructive role, and concludes that any distinction has to be blurred. In view of this, and a brief overview of the nature of the data, the new evidence seems insufficient to conclude that the physiological roles of mature astrocytes go beyond a general support role. I propose a model of mature protoplasmic astrocyte function that is drawn from the most recent data on their structure, the domain concept and their syncytial characteristics, of an independent rather than integrative functioning of the ends of each process where the activities that affect synaptic activity and blood vessel diameter will be concentrated.

show abstract

The Transcriptome and Metabolic Gene Signature of Protoplasmic Astrocytes in the Adult Murine Cortex

Cited by 437 publications

References 52 publications

Brain Lactate Metabolism: The Discoveries and the Controversies

Brain Lactate Metabolism: The Discoveries and the Controversies

Astroglia as a cellular target for neuroprotection and treatment of neuro‐psychiatric disorders

Supportive or information-processing functions of the mature protoplasmic astrocyte in the mammalian CNS? A critical appraisal

Contact Info

Product

Resources

About