Digital imaging of mitochondrial potential in single rat cardiomyocytes revealed transient depolarizations of mitochondria discretely localized within the cell, a phenomenon that we shall call “flicker.” These events were usually highly localized and could be restricted to single mitochondria, but they could also be more widely distributed within the cell. Contractile waves, either spontaneous or in response to depolarization with 50 mM K+, were associated with propagating waves of mitochondrial depolarization, suggesting that propagating calcium waves are associated with mitochondrial calcium uptake and consequent depolarization. Here we demonstrate that the mitochondrial flicker was directly related to the focal release of calcium from sarcoplasmic reticular (SR) calcium stores and consequent uptake of calcium by local mitochondria. Thus, the events were dramatically reduced by (a) depletion of SR calcium stores after long-term incubation in EGTA or thapsigargin (500 nM); (b) buffering intracellular calcium using BAPTA-AM loading; (c) blockade of SR calcium release with ryanodine (30 μM); and (d) blockade of mitochondrial calcium uptake by microinjection of diaminopentane pentammine cobalt (DAPPAC), a novel inhibitor of the mitochondrial calcium uniporter. These observations demonstrate that focal SR calcium release results in calcium microdomains sufficient to promote local mitochondrial calcium uptake, suggesting a tight coupling of calcium signaling between SR release sites and nearby mitochondria.
1. As ATP has a higher affinity for Mg2+ than ADP, the cytosolic magnesium concentration rises upon ATP hydrolysis. We have therefore used the Mg2+-sensitive fluorescent indicator Magnesium Green (MgG)
Instillations of low pH lactate buffer, a high glucose concentration and glucose degradation products contribute differently and often cumulatively to peritoneal injury in vivo.
In the present study evidence is given for the presence of an electrogenic, vacuolar type ATPase (V type ATPase) in the apical membrane of malpighian tubules of Formica. Barium (6 mM), the metabolic inhibitor monoiodo-acetic acid (MIA; 5 10-4M) and two inhibitors of V type proton ATPases, i.e. bafilomycin A1 (Baf-A1; 5·10-6M) and N-ethylmaleimide (NEM; 5 10–4M), all inhibited fluid secretion significantly (p < 0.05). This is in agreement with the hypothesis that K enters passively via K channels in the basolateral membrane and that a V type ATPase is involved in the active transport step at the apical membrane. Also MIA, NEM and Baf-A1 slightly depolarized the apical membrane potential, Vap, by 16, 17 and 30 mV, respectively, whereas they had virtually no effect on the basolateral membrane potential (Vm). The mild effect on Vap, in contrast with the pronounced effect on fluid secretion, can be explained by the high apical over basolateral membrane resistance: the voltage divider ratio, VDR, was 47 ± 9 (n = 6). As a consequence the basolateral membrane will impose its value on the other barriers. VDR was decreased to 1.4 ± 0.2 (n = 19) by Ba. Ba also caused a strong and reversible hyperpolarization of both Vb1 and Vap (from – 16 ± 1 to – 84 ± 4 (n = 8) and from -51 ± 4 to-96 ± 6 mV, respectively). As expected MIA, NEM and Baf-Al now had a much more pronounced depolarizing effect, i.e. they drastically reduced the Ba-induced hyperpolarization of both Vap and Vb1 The reduction in Vap was 67, 67 and 54 mV, respectively. Vb1depolarized from -73 ± 4to-15 ± 4mV (n = 7), from-72 ± 10 to 13 ± 2mV(n≈5)and from – 78 ± 3 to – 30 ± 5 mV (n = 12) in the presence of Ba and MIA, NEM or Baf-A1, respectively. From cable analysis and total transepithelial resistance in the absence and presence of barium it was also possible to make an estimate of the resistances across the different barriers: total basolateral resistance = 10 Ω·cm2, total apical resistance = 475 Ω·cm2, total shunt resistance = 228 Ω·cm2. It was concluded that in malpighian tubules of Formica an H pump of the V type is present in the apical membrane. As suggested in other epithelia this pump can be the prime mover in active K transport: the proton concentration gradient built up across the apical membrane can drive a K/H exchanger.
Diverse modes of heparin administration have been used in animal models of chronic peritoneal dialysate exposure to maintain catheter patency and prevent fibrinous adhesions. Heparin has biological actions independent of its well-known anticoagulant activity, including the ability to modulate extracellular matrix synthesis, cellular proliferation, angiogenesis, and inflammation. These actions may interfere with peritoneal membrane homeostasis. The present study evaluated the influence of the mode of heparin administration on technique survival and infection rate in a rat model of chronic dialysate exposure. Further, the incorporation of heparin in the peritoneal membrane was examined. A 3.86% glucose dialysate was injected twice daily into Wistar rats with a heparin-coated catheter (group A1), or with a standard catheter with heparin injections during the entire exposure time (group A2) or only during 1 week (group A3). Sham manipulations were performed in a fourth group and a fifth group was left untreated. Technique survival was 80% in group A1, 60% in group A2, and 40% in group A3. The rate of infection was highest in group A1 and lowest in group A2. Intraperitoneally administered heparin accumulated in the peritoneal membrane, whereas dextran, with a molecular weight similar to that of heparin, was not incorporated in the peritoneum. In conclusion, intraperitoneal heparin reduced the incidence of infection in an animal model of chronic dialysate exposure. The best technique survival was, however, obtained using a heparin-coated catheter. Heparin is incorporated in the peritoneal membrane, where it may exert diverse biological actions and thus bias study results. The use of a heparin-coated catheter in combination with antibiotics may be the optimal approach to obtaining peritoneal access in animal models of chronic dialysate exposure.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.