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1. K ATP channel activity and slow oscillations in pancreatic beta cells are regulated by mitochondrial ATP production

   https://doi.org/10.1113/JP284982  

   Corradi, Jeremías ; Thompson, Benjamin ; Fletcher, Patrick A. ; Bertram, Richard ; Sherman, Arthur S. ; Satin, Leslie S. ( November 2023 , The Journal of Physiology)

   Pancreatic beta cells secrete insulin in response to plasma glucose. The ATP‐sensitive potassium channel (K_ATP) links glucose metabolism to islet electrical activity in these cells by responding to increased cytosolic [ATP]/[ADP]. It was recently proposed that pyruvate kinase (PK) in close proximity to beta cell K_ATPlocally produces the ATP that inhibits K_ATPactivity. This proposal was largely based on the observation that applying phosphoenolpyruvate (PEP) and ADP to the cytoplasmic side of excised inside‐out patches inhibited K_ATP. To test the relative contributions of local vs. mitochondrial ATP production, we recorded K_ATPactivity using mouse beta cells and INS‐1 832/13 cells. In contrast to prior reports, we could not replicate inhibition of K_ATPactivity by PEP + ADP. However, when the pH of the PEP solutions was not corrected for the addition of PEP, strong channel inhibition was observed as a result of the well‐known action of protons to inhibit K_ATP. In cell‐attached recordings, perifusing either a PK activator or an inhibitor had little or no effect on K_ATPchannel closure by glucose, further suggesting that PK is not an important regulator of K_ATP. In contrast, addition of mitochondrial inhibitors robustly increased K_ATPactivity. Finally, by measuring the [ATP]/[ADP] responses to imposed calcium oscillations in mouse beta cells, we found that oxidative phosphorylation could raise [ATP]/[ADP] even when ADP was at its nadir during the burst silent phase, in agreement with our mathematical model. These results indicate that ATP produced by mitochondrial oxidative phosphorylation is the primary controller of K_ATPin pancreatic beta cells.image

   Phosphoenolpyruvate (PEP) plus adenosine diphosphate does not inhibit K_ATPactivity in excised patches. PEP solutions only inhibit K_ATPactivity if the pH is unbalanced.

   Modulating pyruvate kinase has minimal effects on K_ATPactivity.

   Mitochondrial inhibition, in contrast, robustly potentiates K_ATPactivity in cell‐attached patches.

   Although the ADP level falls during the silent phase of calcium oscillations, mitochondria can still produce enough ATP via oxidative phosphorylation to close K_ATP.

   Mitochondrial oxidative phosphorylation is therefore the main source of the ATP that inhibits the K_ATPactivity of pancreatic beta cells.

    

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2. Ca 2+ release or Ca 2+ entry, that is the question: what governs Ca 2+ oscillations in pancreatic β cells?

   https://doi.org/10.1152/ajpendo.00030.2023  

   Fletcher, Patrick A. ; Thompson, Ben ; Liu, Chanté ; Bertram, Richard ; Satin, Leslie S. ; Sherman, Arthur S. ( June 2023 , American Journal of Physiology-Endocrinology and Metabolism)

   The standard model for Ca 2+ oscillations in insulin-secreting pancreatic β cells centers on Ca 2+ entry through voltage-activated Ca 2+ channels. These work in combination with ATP-dependent K + channels, which are the bridge between the metabolic state of the cells and plasma membrane potential. This partnership underlies the ability of the β cells to secrete insulin appropriately on a minute-to-minute time scale to control whole body plasma glucose. Though this model, developed over more than 40 years through many cycles of experimentation and mathematical modeling, has been very successful, it has been challenged by a hypothesis that calcium-induced calcium release from the endoplasmic reticulum through ryanodine or inositol trisphosphate (IP3) receptors is instead the key driver of islet oscillations. We show here that the alternative model is in fact incompatible with a large body of established experimental data and that the new observations offered in support of it can be better explained by the standard model. 

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3. Symbiosis of Electrical and Metabolic Oscillations in Pancreatic β-Cells

   https://doi.org/10.3389/fphys.2021.781581  

   Marinelli, Isabella ; Fletcher, Patrick A. ; Sherman, Arthur S. ; Satin, Leslie S. ; Bertram, Richard ( December 2021 , Frontiers in Physiology)

   Insulin is secreted in a pulsatile pattern, with important physiological ramifications. In pancreatic β-cells, which are the cells that synthesize insulin, insulin exocytosis is elicited by pulses of elevated intracellular Ca 2+ initiated by bursts of electrical activity. In parallel with these electrical and Ca 2+ oscillations are oscillations in metabolism, and the periods of all of these oscillatory processes are similar. A key question that remains unresolved is whether the electrical oscillations are responsible for the metabolic oscillations via the effects of Ca 2+ , or whether the metabolic oscillations are responsible for the electrical oscillations due to the effects of ATP on ATP-sensitive ion channels? Mathematical modeling is a useful tool for addressing this and related questions as modeling can aid in the design of well-focused experiments that can test the predictions of particular models and subsequently be used to improve the models in an iterative fashion. In this article, we discuss a recent mathematical model, the Integrated Oscillator Model (IOM), that was the product of many years of development. We use the model to demonstrate that the relationship between calcium and metabolism in beta cells is symbiotic: in some contexts, the electrical oscillations drive the metabolic oscillations, while in other contexts it is the opposite. We provide new insights regarding these results and illustrate that what might at first appear to be contradictory data are actually compatible when viewed holistically with the IOM. 

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4. Hydrogel Alginate Considerations for Improved 3D Matrix Stability and Cell Graft Viability and Function in Studying Type 1 Diabetes In Vitro

   https://doi.org/10.1002/adbi.202300502  

   Quiroz, Victor M. ; Wang, Yuanjia ; Rakoski, Amanda I. ; Kasinathan, Devi ; Neshat, Sarah Y. ; Hollister‐Lock, Jennifer ; Doloff, Joshua C. ( January 2024 , Advanced Biology)

   Biomedical devices such as islet‐encapsulating systems are used for treatment of type 1 diabetes (T1D). Despite recent strides in preventing biomaterial fibrosis, challenges remain for biomaterial scaffolds due to limitations on cells contained within. The study demonstrates that proliferation and function of insulinoma (INS‐1) cells as well as pancreatic rat islets may be improved in alginate hydrogels with optimized gel%, crosslinking, and stiffness. Quantitative polymerase chain reaction (qPCR)‐based graft phenotyping of encapsulated INS‐1 cells and pancreatic islets identified a hydrogel stiffness range between 600 and 1000 Pa that improved insulin Ins and Pdx1 gene expression as well as glucose‐sensitive insulin‐secretion. Barium chloride (BaCl₂) crosslinking time is also optimized due to toxicity of extended exposure. Despite possible benefits to cell viability, calcium chloride (CaCl₂)‐crosslinked hydrogels exhibited a sharp storage modulus loss in vitro. Despite improved stability, BaCl₂‐crosslinked hydrogels also exhibited stiffness losses over the same timeframe. It is believed that this is due to ion exchange with other species in culture media, as hydrogels incubated in dIH₂O exhibited significantly improved stability. To maintain cell viability and function while increasing 3D matrix stability, a range of useful media:dIH₂O dilution ratios for use are identified. Such findings have importance to carry out characterization and optimization of cell microphysiological systems with high fidelity in vitro.

    

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5. Cellular and molecular responses to acute cocaine treatment in neuronal-like N2a cells: potential mechanism for its resistance in cell death

   https://doi.org/10.1038/s41420-018-0078-x  

   Badisa, Ramesh B. ; Wi, Sungsool ; Jones, Zachary ; Mazzio, Elizabeth ; Zhou, Yi ; Rosenberg, Jens T. ; Latinwo, Lekan M. ; Grant, Samuel C. ; Goodman, Carl B. ( July 2018 , Cell Death Discovery)

   Cocaine is a highly abused drug that causes psychiatric and neurological problems. Its entry into neurons could alter cell-biochemistry and contribute in the manifestation of early pathological symptoms. We have previously shown the acute cocaine effects in rat C6 astroglia-like cells and found that these cells were highly sensitive to cocaine in terms of manifesting certain pathologies known to underlie psychological disorders. The present study was aimed to discern acute cocaine effects on the early onset of various changes in Neuro-2a (N2a) cells. Whole-cell patch-clamp recording of differentiated cells displayed the functional voltage-gated Na⁺and K⁺channels, which demonstrated the neuronal characteristics of the cells. Treatment of these cells with acute cocaine (1 h) at in vivo (nM to μM) and in vitro (mM) concentrations revealed that the cells remained almost 100% viable. Cocaine administration at 6.25 μM or 4 mM doses significantly reduced the inward currents but had no significant effect on outward currents, indicating the Na⁺channel-blocking activity of cocaine. While no morphological change was observed at in vivo doses, treatment at in vitro doses altered the morphology, damaged the neurites, and induced cytoplasmic vacuoles; furthermore, general mitochondrial activity and membrane potential were significantly decreased. Mitochondrial dysfunction enabled the cells switch to anaerobic glycolysis, evidenced by dose-dependent increases in lactate and H₂S, resulting unaltered ATP level in the cells. Further investigation on the mechanism of action unfolded that the cell’s resistance to cocaine was through the activation of nuclear factor E2-related factor-2 (Nrf-2) gene and subsequent increase of antioxidants (glutathione [GSH], catalase and GSH peroxidase [GPx]). The data clearly indicate that the cells employed a detoxifying strategy against cocaine. On a broader perspective, we envision that extrapolating the knowledge of neuronal resistance to central nervous system (CNS) diseases could delay their onset or progression.

    

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