Angular Dependences of Perpendicular and Parallel Mode Electron Paramagnetic Resonance of Oxidized Beef Heart Cytochrome c Oxidase

Hunter, Dominic J. B.; Oganesyan, Vasily S.; Salerno, John C.; Butler, Catherine; Ingledew, W. John; Thomson, Andrew J.

doi:10.1016/s0006-3495(00)76606-9

Cited by 16 publications

(11 citation statements)

References 40 publications

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“…The experiments were performed with a home-built confocal microscope that has excellent spatial resolution. The values of FWHM of the microscope's point-spread function, 0.21 μm in x and y and 0.51 μm in z, are smaller than those from previous spark studies in frog cut skeletal fibers, 0.4–0.5 μm in x and y and 0.8–1.4 μm in z (Jiang et al 1999; Ríos et al 1999; Klein 2000). Good spatial resolution is obviously advantageous for resolving fluo-3 signals with a narrow spatial extent.…”

Section: Discussioncontrasting

confidence: 63%

Calcium Sparks in Intact Skeletal Muscle Fibers of the Frog

Hollingworth

Peet

Chandler

et al. 2001

The Journal of General Physiology

135

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Calcium sparks were studied in frog intact skeletal muscle fibers using a home-built confocal scanner whose point-spread function was estimated to be ∼0.21 μm in x and y and ∼0.51 μm in z. Observations were made at 17–20°C on fibers from Rana pipiens and Rana temporaria. Fibers were studied in two external solutions: normal Ringer's ([K+] = 2.5 mM; estimated membrane potential, −80 to −90 mV) and elevated [K+] Ringer's (most frequently, [K+] = 13 mM; estimated membrane potential, −60 to −65 mV). The frequency of sparks was 0.04–0.05 sarcomere−1 s−1 in normal Ringer's; the frequency increased approximately tenfold in 13 mM [K+] Ringer's. Spark properties in each solution were similar for the two species; they were also similar when scanned in the x and the y directions. From fits of standard functional forms to the temporal and spatial profiles of the sparks, the following mean values were estimated for the morphological parameters: rise time, ∼4 ms; peak amplitude, ∼1 ΔF/F (change in fluorescence divided by resting fluorescence); decay time constant, ∼5 ms; full duration at half maximum (FDHM), ∼6 ms; late offset, ∼0.01 ΔF/F; full width at half maximum (FWHM), ∼1.0 μm; mass (calculated as amplitude × 1.206 × FWHM3), 1.3–1.9 μm3. Although the rise time is similar to that measured previously in frog cut fibers (5–6 ms; 17–23°C), cut fiber sparks have a longer duration (FDHM, 9–15 ms), a wider extent (FWHM, 1.3–2.3 μm), and a strikingly larger mass (by 3–10-fold). Possible explanations for the increase in mass in cut fibers are a reduction in the Ca2+ buffering power of myoplasm in cut fibers and an increase in the flux of Ca2+ during release.

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Section: Discussioncontrasting

confidence: 63%

Calcium Sparks in Intact Skeletal Muscle Fibers of the Frog

Hollingworth

Peet

Chandler

et al. 2001

The Journal of General Physiology

135

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“…7 cm -1 . This weak exchange coupling is actually in excellent agreement with the most recent experimental observations [Oganesyan et al, 1998;Hunter et al, 2000;Cheesman et al, 2004], which suggest, in contrast to previous belief, that the magnetic coupling in the fully oxidised relaxed state of the heme-copper oxidases is very weak, of the order of ~1 cm -1 . Interestingly, this is also in line with the extent of magnetic coupling of ca.…”

Section: Ho-cu[ii]supporting

confidence: 91%

Cytochrome c Oxidase — Remaining Questions About the Catalytic Mechanism

Wikström

Sharma

2019

Oxygen Production and Reduction in Artificial and Natural Systems

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Cytochrome c oxidase harnesses dioxygen (O 2 ) as the terminal electron acceptor in the respiratory chains of mitochondria and many aerobic bacteria, and was appropriately named The Respiratory Enzyme (Das Atmungsferment) by Otto Warburg. Its catalytic activity completes the oxygen cycle in biology, which starts by the water-splitting reaction of photosynthesis, amply covered elsewhere in this volume. The mechanism of catalysis of cytochrome c oxidase is largely known today, but some uncertainty remains with respect to the ferric/cupric intermediate of the binuclear heme iron/copper centre, which is to be discussed here. b3485 Oxygen Production and Reduction in Artificial and Natural Systems 1st Reading 9.61"x6.69" b3485 Oxygen Production and Reduction in Artificial and Natural Systems 1st Reading 9.61"x6.69"

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“…In the process of transfer, a proton motive force is established by pumping the protons through the inner mitochondrial membrane to the intermembrane space. Complex V (ATP synthase) depends on this process to generate ATP by phosphorylating ADP [24,25].…”

Section: Mitochondrial Structure and Functionmentioning

confidence: 99%

Mitochondria as a target for neuroprotection: role of methylene blue and photobiomodulation

Yang

Youngblood

et al. 2020

Transl Neurodegener

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Mitochondrial dysfunction plays a central role in the formation of neuroinflammation and oxidative stress, which are important factors contributing to the development of brain disease. Ample evidence suggests mitochondria are a promising target for neuroprotection. Recently, methods targeting mitochondria have been considered as potential approaches for treatment of brain disease through the inhibition of inflammation and oxidative injury. This review will discuss two widely studied approaches for the improvement of brain mitochondrial respiration, methylene blue (MB) and photobiomodulation (PBM). MB is a widely studied drug with potential beneficial effects in animal models of brain disease, as well as limited human studies. Similarly, PBM is a non-invasive treatment that promotes energy production and reduces both oxidative stress and inflammation, and has garnered increasing attention in recent years. MB and PBM have similar beneficial effects on mitochondrial function, oxidative damage, inflammation, and subsequent behavioral symptoms. However, the mechanisms underlying the energy enhancing, antioxidant, and anti-inflammatory effects of MB and PBM differ. This review will focus on mitochondrial dysfunction in several different brain diseases and the pathological improvements following MB and PBM treatment.

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Angular Dependences of Perpendicular and Parallel Mode Electron Paramagnetic Resonance of Oxidized Beef Heart Cytochrome c Oxidase

Cited by 16 publications

References 40 publications

Calcium Sparks in Intact Skeletal Muscle Fibers of the Frog

Calcium Sparks in Intact Skeletal Muscle Fibers of the Frog

Cytochrome c Oxidase — Remaining Questions About the Catalytic Mechanism

Mitochondria as a target for neuroprotection: role of methylene blue and photobiomodulation

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