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1. Bioenergetics underlying single-cell migration on aligned nanofiber scaffolds

   https://doi.org/10.1152/ajpcell.00221.2019  

   Padhi, Abinash; Thomson, Alexander H.; Perry, Justin B.; Davis, Grace N.; McMillan, Ryan P.; Loesgen, Sandra; Kaweesa, Elizabeth N.; Kapania, Rakesh; Nain, Amrinder S.; Brown, David A. (March 2020, American Journal of Physiology-Cell Physiology)

   Cell migration is centrally involved in a myriad of physiological processes, including morphogenesis, wound healing, tissue repair, and metastatic growth. The bioenergetics that underlie migratory behavior are not fully understood, in part because of variations in cell culture media and utilization of experimental cell culture systems that do not model physiological connective extracellular fibrous networks. In this study, we evaluated the bioenergetics of C2C12 myoblast migration and force production on fibronectin-coated nanofiber scaffolds of controlled diameter and alignment, fabricated using a nonelectrospinning spinneret-based tunable engineered parameters (STEP) platform. The contribution of various metabolic pathways to cellular migration was determined using inhibitors of cellular respiration, ATP synthesis, glycolysis, or glucose uptake. Despite immediate effects on oxygen consumption, mitochondrial inhibition only modestly reduced cell migration velocity, whereas inhibitors of glycolysis and cellular glucose uptake led to striking decreases in migration. The migratory metabolic sensitivity was modifiable based on the substrates present in cell culture media. Cells cultured in galactose (instead of glucose) showed substantial migratory sensitivity to mitochondrial inhibition. We used nanonet force microscopy to determine the bioenergetic factors responsible for single-cell force production and observed that neither mitochondrial nor glycolytic inhibition altered single-cell force production. These data suggest that myoblast migration is heavily reliant on glycolysis in cells grown in conventional media. These studies have wide-ranging implications for the causes, consequences, and putative therapeutic treatments aimed at cellular migration. 

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2. Astrocytes drive divergent metabolic gene expression in humans and chimpanzees

   https://doi.org/10.1101/2020.11.09.374835  

   Zintel, T.M.; Pizzollo, J.; Claypool, C.G.; Babbitt, C.C. (November 2020, bioRxiv)

   null (Ed.)

   The human brain utilizes ~ 20% of all of the body’s metabolic resources, while chimpanzee brains use less than 10%. Although previous work shows significant differences in metabolic gene expression between the brains of primates, we have yet to fully resolve the contribution of distinct brain cell types. To investigate cell-type specific interspecies differences in brain gene expression, we conducted RNA-Seq on neural progenitor cells (NPCs), neurons, and astrocytes generated from induced pluripotent stem cells (iPSCs) from humans and chimpanzees. Interspecies differential expression (DE) analyses revealed that twice as many genes exhibit DE in astrocytes (12.2% of all genes expressed) than neurons (5.8%). Pathway enrichment analyses determined that astrocytes, rather than neurons, diverged in expression of glucose and lactate transmembrane transport, as well as pyruvate processing and oxidative phosphorylation. These findings suggest that astrocytes may have contributed significantly to the evolution of greater brain glucose metabolism with proximity to humans. 

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3. Astrocytes Drive Divergent Metabolic Gene Expression in Humans and Chimpanzees

   https://doi.org/10.1093/gbe/evad239  

   Zintel, Trisha M.; Pizzollo, Jason; Claypool, Christopher G.; Babbitt, Courtney C.; Satta, ed., Yoko (December 2023, Genome Biology and Evolution)

   Abstract The human brain utilizes ∼20% of all of the body's metabolic resources, while chimpanzee brains use <10%. Although previous work shows significant differences in metabolic gene expression between the brains of primates, we have yet to fully resolve the contribution of distinct brain cell types. To investigate cell type–specific interspecies differences in brain gene expression, we conducted RNA-seq on neural progenitor cells, neurons, and astrocytes generated from induced pluripotent stem cells from humans and chimpanzees. Interspecies differential expression analyses revealed that twice as many genes exhibit differential expression in astrocytes (12.2% of all genes expressed) than neurons (5.8%). Pathway enrichment analyses determined that astrocytes, rather than neurons, diverged in expression of glucose and lactate transmembrane transport, as well as pyruvate processing and oxidative phosphorylation. These findings suggest that astrocytes may have contributed significantly to the evolution of greater brain glucose metabolism with proximity to humans. 

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4. D-ꞵ -hydroxybutyrate stabilizes hippocampal CA3-CA1 circuit during acute insulin resistance

   https://doi.org/10.1093/pnasnexus/pgae196  

   Kula, Bartosz; Antal, Botond; Weistuch, Corey; Gackière, Florian; Barre, Alexander; Velado, Victor; Hubbard, Jeffrey M; Kukley, Maria; Mujica-Parodi, Lilianne R; Smith, Nathan A (May 2024, PNAS Nexus)

   The brain primarily relies on glycolysis for mitochondrial respiration but switches to alternative fuels such as ketone bodies (KBs) when less glucose is available. Neuronal KB uptake, which does not rely on glucose transporter 4 (GLUT4) or insulin, has shown promising clinical applicability in alleviating the neurological and cognitive effects of disorders with hypometabolic components. However, the specific mechanisms by which such interventions affect neuronal functions are poorly understood. In this study, we pharmacologically blocked GLUT4 to investigate the effects of exogenous KB D-ꞵ-hydroxybutyrate (D-ꞵHb) on mouse brain metabolism during acute insulin resistance (AIR). We found that both AIR and D-ꞵHb had distinct impacts across neuronal compartments: AIR decreased synaptic activity and long-term potentiation (LTP) and impaired axonal conduction, synchronization, and action potential (AP) properties, while D-ꞵHb rescued neuronal functions associated with axonal conduction, synchronization, and LTP. 

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5. Induced pluripotent stem cells can utilize lactate as a metabolic substrate to support proliferation

   https://doi.org/10.1002/btpr.3090  

   Odenwelder, Daniel_C; Lu, Xiaoming; Harcum, Sarah_W (November 2020, Biotechnology Progress)

   Abstract Human‐induced pluripotent stem cells (iPSCs) hold the promise to improve cell‐based therapies. Yet, to meet rising demands and become clinically impactful, sufficient high‐quality iPSCs in quantity must be generated, a task that exceeds current capabilities. In this study, K3 iPSCs cultures were examined using parallel‐labeling metabolic flux analysis (¹³C‐MFA) to quantify intracellular fluxes at relevant bioprocessing stages: glucose concentrations representative of initial media concentrations and high lactate concentrations representative of fed‐batch culture conditions, prior to and after bolus glucose feeds. The glucose and lactate concentrations are also representative of concentrations that might be encountered at different locations within 3D cell aggregates. Furthermore, a novel method was developed to allow the isotopic tracer [U‐¹³C₃] lactate to be used in the¹³C‐MFA model. The results indicated that high extracellular lactate concentrations decreased glucose consumption and lactate production, while glucose concentrations alone did not affect rates of aerobic glycolysis. Moreover, for the high lactate cultures, lactate was used as a metabolic substrate to support oxidative mitochondrial metabolism. These results demonstrate that iPSCs have metabolic flexibility and possess the capacity to metabolize lactate to support exponential growth, and that high lactate concentrations alone do not adversely impact iPSC proliferation. 

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