The highly efficient holding function of the mollusc ‘catch’ muscle is not based on decelerated myosin head cross-bridge cycles

Galler, Stefan; Litzlbauer, Julia; Kröss, Markus; Grassberger, Herbert

doi:10.1098/rspb.2009.1618

Cited by 19 publications

(15 citation statements)

References 32 publications

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“…The limpet foot is a complicated muscular structure which is not as functionally reliant on aerobic metabolism as cardiac muscle. The limpet foot mechanism uses energetically economic smooth muscles to lock into the 'catch' state, which clamps the foot into suction with the substrate (Frescura & Hodgson 1990, Smith 1991, Galler et al 2010. Compared to cardiac tissue, limpet foot muscles have low mitochondrial density and high anaerobic capacities (Marshall & McQuaid 1989, Morley et al 2009, Suda et al 2015).…”

Section: Differences In Heat Tolerance Of Foot and Heart Muscle Diffementioning

confidence: 99%

Plasticity of foot muscle and cardiac thermal limits in the limpet Lottia limatula from locations with differing temperatures

Wang¹,

Tanner²,

Armstrong³

et al. 2019

Aquat. Biol.

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Species distributions are shifting in response to increased habitat temperatures as a result of ongoing climate change. Understanding variation in physiological plasticity among species and populations is important for predicting these distribution shifts. Interspecific variation in intertidal ectotherms' short-term thermal plasticity has been well established. However, intraspecific variation among populations from differing thermal habitats remains a question pertinent to understanding the effects of climate change on species' ranges. In this study, we explored upper thermal tolerance limits and plasticity of those limits using a foot muscle metric and 2 cardiac metrics (Arrhenius breakpoint temperature, ABT, and flatline temperature, FLT) in adult file limpets Lottia limatula. Limpets were collected from thermally different coastal and inland-estuarine habitats and held for 2 wk at 13, 17 or 21°C prior to thermal performance assays. Compared to limpets from the warm estuary site, limpets from the cold outer coast site had similar foot muscle critical thermal maxima (CT max ; 35.2 vs. 35.6°C) but lower cardiac thermal tolerances (ABT: 30.5 vs. 35.1°C). Limpets from the cold coast site had higher acclimation responses in foot muscle CT max (0.22°C per 1°C rise in acclimation) than those of the warm estuary site (0.07°C per 1°C rise in acclimation), but lower acclimation responses in cardiac thermal tolerance (ABT: −0.85°C per 1°C rise in acclimation) than those of the estuary site (ABT: 0.10°C per 1°C rise in acclimation). Since outer coast populations had lower cardiac plasticity and higher mortalities in the warm acclimation, we predict L. limatula from colder habitats will be more susceptible to rising temperatures. Our findings illustrate the importance of population-specific variation in short-term thermal plasticity when considering the effects of climate change on ectotherms.

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Section: Differences In Heat Tolerance Of Foot and Heart Muscle Diffementioning

confidence: 99%

Plasticity of foot muscle and cardiac thermal limits in the limpet Lottia limatula from locations with differing temperatures

Wang¹,

Tanner²,

Armstrong³

et al. 2019

Aquat. Biol.

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show abstract

“…While these postures may at first appear associated with energetically-costly muscular activity, it is also possible that in some species they consume little if any extra energy. Certain smooth muscles, known as catch muscles, are able to reduce energy consumptions when holding fixed postures 28 . Catch muscles have not, to our knowledge, been found in lepidopteran larvae, and little is known about their use in maintaining defensive postures.…”

Section: Discussionmentioning

confidence: 99%

“…While there is only limited empirical evidence that postural camouflage has an antipredator benefit, intraspecific variation in this behavior has received even less attention. If postural camouflage is associated with energetic costs (which is not necessarily the case 28 , but seems to be true of other forms of defensive posture 29 ), then we might expect posture to be influenced by environmental conditions that impact an individual’s state. Here we exploit natural variation in the tendency of American peppered moth larvae to utilize twig-like postures (see SI experiment 2 ) to test whether naïve avian predators take longer to find and attack larvae when they are in these postures than when they are not (i.e., whether they benefit from postural camouflage).…”

Section: Introductionmentioning

confidence: 99%

The antipredator benefits of postural camouflage in peppered moth caterpillars

Rowland

Burriss

Stachurski

2020

Sci Rep

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Camouflage is the most common form of antipredator defense, and is a textbook example of natural selection. How animals’ appearances prevent detection or recognition is well studied, but the role of prey behavior has received much less attention. Here we report a series of experiments with twig-mimicking larvae of the American peppered moth Biston betularia that test the long-held view that prey have evolved postures that enhance their camouflage, and establish how food availability and ambient temperature affect these postures. We found that predators took longer to attack larvae that were resting in a twig-like posture than larvae resting flat against a branch. Larvae that were chilled or food restricted (manipulations intended to energetically stress larvae) adopted a less twig-like posture than larvae that were fed ad libitum. Our findings provide clear evidence that animals gain antipredator benefits from postural camouflage, and suggest that benefits may come at an energetic cost that animals are unwilling or unable to pay under some conditions.

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“…Ultrastructural evidence that muscles from barnacles share these catch-like properties has been documented previously (Hoyle, 1987). If this is also true for (Cohen, 1982;Galler et al, 2010). The giant muscle cells of B. nubilus may therefore represent a highly functional, primeval mash-up of both striated and smooth muscle, which may confer their impressive contractile abilities in the face of low oxygen availability.…”

Section: Muscle Characterizationmentioning

confidence: 71%

“…All of these characteristics suggest that contraction in these fibers is powered aerobically, which is paradoxical given the fact that they remain contracted for long-periods of time while the scutal and tergal plates are closed, and oxygen levels are presumably low. This sustained opercular closure ability under potential hypoxia may be explained by the use of a 'catch' state in giant barnacle fibers, similar to that seen in molluscan muscles and to a lesser extent in vertebrate smooth muscle (Southwood, 1983;Galler et al, 2010).…”

Section: Muscle Characterizationmentioning

confidence: 84%

Effect of Oxygen-Limiting Tidal Conditions on Muscle Metabolism and Structure in the Giant Acorn Barnacle, Balanus nubilus

Grady¹

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Crustacean muscle fibers are some of the largest cells in the animal kingdom, with fiber diameters in the giant acorn barnacle (Balanus nubilus) exceeding 3 mm. Sessile animals with extreme muscle sizes and that live in the hypoxiainducing intertidal zone -like B. nubilus -represent ideal models for probing the effects of oxygen limitation on muscle cells. We investigated changes in metabolism and structure of B. nubilus muscle in response to: normoxic immersion, anoxic immersion, or air emersion, for acute (6h) or chronic (6h exposures twice daily for 2wks) time periods. Following exposure, we immediately measured hemolymph pO 2 , pCO 2 , pH, Na + , Cl -, K + , and Ca + then excised tergal depressor (TD) and scutal adductor (SA) muscles to determine citrate synthase (CS) activity, lactate dehydrogenase (LDH) activity, and Dlactate levels. We also prepared a subset of SA and TD muscles from the chronic barnacles for histological analysis of fiber diameter (Feret's), cross-sectional area (CSA), mitochondrial distribution and relative density, as well as nuclear distribution and myonuclear domain size. There was a significant decrease in hemolymph pO 2 and pCO 2 following acute and chronic anoxic immersion, whereas air emersion pO 2 and pCO 2 was comparable to normoxic levels. Fiber CSA and diameter did not change significantly in either tissue, while myonuclear domain size in SA muscle was significantly lower in the anoxic and emersion groups than the normoxic control. Neither CS, nor LDH activity, showed any significant treatment effect in either tissue, whereas both muscles had significantly higher D-lactate levels after air emersion following acute (though not chronic) exposure. Thus far, our findings indicate that B. nubilus experience a general reduction in aerobic metabolism under anoxia, emersion is only mildly oxygen-limiting, and that muscle plasticity is occurring during chronic emersion and anoxia.

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The highly efficient holding function of the mollusc ‘catch’ muscle is not based on decelerated myosin head cross-bridge cycles

Cited by 19 publications

References 32 publications

Plasticity of foot muscle and cardiac thermal limits in the limpet Lottia limatula from locations with differing temperatures

Plasticity of foot muscle and cardiac thermal limits in the limpet Lottia limatula from locations with differing temperatures

The antipredator benefits of postural camouflage in peppered moth caterpillars

Effect of Oxygen-Limiting Tidal Conditions on Muscle Metabolism and Structure in the Giant Acorn Barnacle, Balanus nubilus

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