The formation and functional consequences of heterogeneous mitochondrial distributions in skeletal muscle

Pathi, B.; Kinsey, Stephen T.; Howdeshell, M. E.; Priester, Carolina; McNeill, R. S.; Locke, Bruce R.

doi:10.1242/jeb.067207

Cited by 19 publications

(33 citation statements)

References 80 publications

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“…Further support for our hypothesis comes from the small size of the Type I fibers (~39μm), which are much smaller than the Type I fibers of other deep-diving mammals (Kanatous et al, 2002;Williams and Noren, 2011;Kielhorn et al, 2013) and more similar in size to those of a mouse (Pathi et al, 2012). The small size of these fibers likely decreases the diffusion distance for oxygen as it moves from the Type II fibers to the mitochondria within the Type I fibers, where it is utilized during a dive.…”

Section: Locomotor Muscle Morphology Of Extreme Deep Divers Beaked Whsupporting

confidence: 62%

Novel locomotor muscle design in extreme deep-diving whales

Velten

Dillaman

Kinsey

et al. 2013

Journal of Experimental Biology

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SUMMARYMost marine mammals are hypothesized to routinely dive within their aerobic dive limit (ADL). Mammals that regularly perform deep, long-duration dives have locomotor muscles with elevated myoglobin concentrations that are composed of predominantly large, slow-twitch (Type I) fibers with low mitochondrial volume densities (V mt ). These features contribute to extending ADL by increasing oxygen stores and decreasing metabolic rate. Recent tagging studies, however, have challenged the view that two groups of extreme deep-diving cetaceans dive within their ADLs. Beaked whales (including Ziphius cavirostris and Mesoplodon densirostris) routinely perform the deepest and longest average dives of any air-breathing vertebrate, and short-finned pilot whales (Globicephala macrorhynchus) perform high-speed sprints at depth. We investigated the locomotor muscle morphology and estimated total body oxygen stores of several species within these two groups of cetaceans to determine whether they (1) shared muscle design features with other deep divers and (2) performed dives within their calculated ADLs. Muscle of both cetaceans displayed high myoglobin concentrations and large fibers, as predicted, but novel fiber profiles for diving mammals. Beaked whales possessed a sprinterʼs fiber-type profile, composed of ~80% fast-twitch (Type II) fibers with low V mt . Approximately one-third of the muscle fibers of short-finned pilot whales were slow-twitch, oxidative, glycolytic fibers, a rare fiber type for any mammal. The muscle morphology of beaked whales likely decreases the energetic cost of diving, while that of short-finned pilot whales supports high activity events. Calculated ADLs indicate that, at low metabolic rates, both beaked and short-finned pilot whales carry sufficient onboard oxygen to aerobically support their dives. Supplementary material available online at

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Section: Locomotor Muscle Morphology Of Extreme Deep Divers Beaked Whsupporting

confidence: 62%

Novel locomotor muscle design in extreme deep-diving whales

Velten

Dillaman

Kinsey

et al. 2013

Journal of Experimental Biology

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“…; Pathi et al . ). Interestingly, the oxidative fibres of high‐altitude deer mice are larger in size (Lui et al .…”

Section: Discussionmentioning

confidence: 97%

Evolved changes in the intracellular distribution and physiology of muscle mitochondria in high‐altitude native deer mice

Mahalingam

McClelland

Scott

2017

The Journal of Physiology

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High-altitude natives that have evolved to live in hypoxic environments provide a compelling system to understand how animals can overcome impairments in oxygen availability. We examined whether these include changes in mitochondrial physiology or intracellular distribution that contribute to hypoxia resistance in high-altitude deer mice (Peromyscus maniculatus). Mice from populations native to high and low altitudes were born and raised in captivity, and as adults were acclimated to normoxia or hypobaric hypoxia (equivalent to 4300 m elevation). We found that highlanders had higher respiratory capacities in the gastrocnemius (but not soleus) muscle than lowlanders (assessed using permeabilized fibres with single or multiple inputs to the electron transport system), due in large part to higher mitochondrial volume densities in the gastrocnemius. The latter was attributed to an increased abundance of subsarcolemmal (but not intermyofibrillar) mitochondria, such that more mitochondria were situated near the cell membrane and adjacent to capillaries. Hypoxia acclimation had no significant effect on these population differences, but it did increase mitochondrial cristae surface densities of mitochondria in both populations. Hypoxia acclimation also altered the physiology of isolated mitochondria by affecting respiratory capacities and cytochrome c oxidase activities in population-specific manners. Chronic hypoxia decreased the release of reactive oxygen species by isolated mitochondria in both populations. There were subtle differences in O kinetics between populations, with highlanders exhibiting increased mitochondrial O affinity or catalytic efficiency in some conditions. Our results suggest that evolved changes in mitochondrial physiology in high-altitude natives are distinct from the effects of hypoxia acclimation, and probably provide a better indication of adaptive traits that improve performance and hypoxia resistance at high altitudes.

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“…Indeed, our expectation that the MitoP/MitoB ratio would be the same within subsamples of a tissue was only partly met, since MitoP/MitoB ratios were consistent between subsamples of liver but not muscle. Muscle tissues usually display heterogeneity in their mitochondrial types and distribution even within a muscle type3536, likely leading to local differences in the functioning of the mitochondria and consequently their ROS production. This is also supported by the study of Kuznetsov et al 37.…”

Section: Discussionmentioning

confidence: 99%

Using the MitoB method to assess levels of reactive oxygen species in ecological studies of oxidative stress

Salin

Auer

Villasevil

et al. 2017

Sci Rep

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In recent years evolutionary ecologists have become increasingly interested in the effects of reactive oxygen species (ROS) on the life-histories of animals. ROS levels have mostly been inferred indirectly due to the limitations of estimating ROS from in vitro methods. However, measuring ROS (hydrogen peroxide, H2O2) content in vivo is now possible using the MitoB probe. Here, we extend and refine the MitoB method to make it suitable for ecological studies of oxidative stress using the brown trout Salmo trutta as model. The MitoB method allows an evaluation of H2O2 levels in living organisms over a timescale from hours to days. The method is flexible with regard to the duration of exposure and initial concentration of the MitoB probe, and there is no transfer of the MitoB probe between fish. H2O2 levels were consistent across subsamples of the same liver but differed between muscle subsamples and between tissues of the same animal. The MitoB method provides a convenient method for measuring ROS levels in living animals over a significant period of time. Given its wide range of possible applications, it opens the opportunity to study the role of ROS in mediating life history trade-offs in ecological settings.

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The formation and functional consequences of heterogeneous mitochondrial distributions in skeletal muscle

Cited by 19 publications

References 80 publications

Novel locomotor muscle design in extreme deep-diving whales

Novel locomotor muscle design in extreme deep-diving whales

Evolved changes in the intracellular distribution and physiology of muscle mitochondria in high‐altitude native deer mice

Using the MitoB method to assess levels of reactive oxygen species in ecological studies of oxidative stress

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