Ultrastructure of pedal muscle as a function of temperature in nacellid limpets

Lurman, Glenn; Blaser, Till; Lamare, Miles D.; Tan, Koh-Siang; Poertner, Hans; Peck, Lloyd S.; Morley, Simon A.

doi:10.1007/s00227-010-1444-2

Cited by 6 publications

(6 citation statements)

References 37 publications

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“…This metabolic response is in line with that observed in the congeneric Modiolus modiolus (Lesser & Kruse 2004) dria found in tissues of cold-acclimated active marine invertebrates (Sommer & Pörtner 2002). During coldinduced hypoxia, the level of oxidative stress may rise, causing a compensatory expression of antioxidant enzymes (Viarengo et al 1995, Abele et al 2002, Lesser & Kruse 2004, Lurman et al 2010. These processes are known to stimulate the expression of Hsps (Kassahn et al 2009).…”

Section: Discussionsupporting

confidence: 73%

Field studies and projections of climate change effects on the bearded horse mussel Modiolus barbatus in the Gulf of Thermaikos, Greece

Katsikatsou¹,

Anestis²,

Pörtner³

et al. 2012

Mar. Ecol. Prog. Ser.

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The role of thermal stress phenomena in setting stratified distribution limits was investigated in the bearded horse mussel Modiolus barbatus in response to the seasonal temperature regime in the field. Mussels were transplanted from their natural depth range at ca. 20 m to 3 m depth, where they then experienced enhanced variability of ambient conditions. In specimens from both depths, thermal stress was assessed from the inducible heat shock response (HSR), the accumulation of irreversibly damaged proteins, and from metabolic characters including the putative shift from aerobic to anaerobic metabolism. During both winter and summer, the HSR became involved more at shallow depths than at 20 m depth. The accumulation of succinate during summer indicates transition to anaerobiosis. The results suggest that the development of anaerobic conditions and the exploitation of the HSR are closely intertwined. The field data corroborate that glycolytic capacity, the level of energy turnover, and also protection from protein damage play a role in setting passive tolerance to extremes in environmental temperature. We suggest that limits to vertical distribution of M. barbatus are set by the time and degree of exploitation of the mechanisms sustaining passive thermal tolerance and the avoidance of protein damage in the warmth. KEY WORDS: Bivalves · Modiolus barbatus · Environmental warming · Physiological patterns · Heat shock response · HSR Resale or republication not permitted without written consent of the publisherMar Ecol Prog Ser 449: [183][184][185][186][187][188][189][190][191][192][193][194][195][196] 2012 warming at ecosystem level will build on speciesspecific responses (Pörtner 2001, Somero 2010. For reliable projections of future changes it is important to develop a mechanism-based cause-and-effect understanding. The latter must be integrative and encompass effects of climate change at various levels of biological organization, from molecular, cellular, organismal, population, and community-ecosystem.Many laboratory studies have defined the thermal limits and thermotolerance of bivalves by studying the expression of heat shock proteins (Hsps) (Hofmann & Somero 1995, Buckley et al. 2001. Hsps may co-define extreme thermal limits, and it has been hypothesized that they are related to species boundaries in intertidal ecosystems (Hofmann 2005, To manek 2010. Moreover, physiological processes such as heart functioning or metabolic adaptations setting aerobic scope through regulated capacities of glycolytic and mitochondrial metabolism, including the respiratory chain and the tricarboxylic acid cycle, appear equally important and may even take priority in determining the thermal windows of species, and thereby biogeographical limits. Their limited capacity at thermal limits may also be crucial in initiating the heat shock response (HSR) (Pörtner 2001, Braby & Somero 2006, Anestis et al. 2007, Somero 2010. Following the principles of the concept of oxygen and capacity limited thermal tolerance (OCLTT), the ...

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Section: Discussionsupporting

confidence: 73%

Field studies and projections of climate change effects on the bearded horse mussel Modiolus barbatus in the Gulf of Thermaikos, Greece

Katsikatsou¹,

Anestis²,

Pörtner³

et al. 2012

Mar. Ecol. Prog. Ser.

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“…Mitochondria generally proliferate in the cold either in response to reduced oxygen delivery (Guderley 2004) or in response to a reduced efficiency of mitochondria to produce ATP (Pörtner et al 2000). It has been shown, however, that rather than a proliferation in mitochondria (commonly seen in ectothermic vertebrates), the likely predominant mechanism in invertebrates is to change the surface density of mitochondrial cristae in response to cold acclimation (Lurman et al 2010). We found an overall effect of thermal acclimation on the metabolic rates of tail and chelae muscle (independent of mass), such that these tissues were 1.8-fold higher in animals acclimated to 16ЊC compared with animals acclimated to 25ЊC when measured at 21ЊC.…”

Section: Discussionmentioning

confidence: 99%

“…As such, when measured at the same temperature, organisms from cold environments tend to have higher metabolic rates than those from warm environments (Addo-Bediako et al 2002). This observation has been dubbed metabolic cold adaptation (MCA); it has been evidenced as an evolutionary response in insects (Addo-Bediako et al 2002), and although there is some empirical evidence for its existence in aquatic arthropods (e.g., Rastrick and Whiteley 2011;Whiteley et al 2011), its existence in aquatic animals in general is heavily debated (Holeton 1974;Clarke 1993;Steffensen 2002;Lurman et al 2010;White et al 2012a).…”

Section: Effect Of Thermal Acclimation On Organ Mass Tissue Respiratmentioning

confidence: 99%

“…Temperature acclimation involves alteration of rates of chemical and enzymatic reactions, rates of diffusion, and changes in protein structure (e.g., Kleckner and Sidell 1985;Lucassen et al 2003;Lurman et al 2010;Whiteley et al 2011). When exposed to the cold, ectothermic animals have to compensate for the slowing effect of temperature on these processes and uphold functional equilibrium between adenosine triphosphate (ATP) demand and ATP formation.…”

Section: Effect Of Thermal Acclimation On Organ Mass Tissue Respiratmentioning

confidence: 99%

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Effect of Thermal Acclimation on Organ Mass, Tissue Respiration, and Allometry in Leichhardtian River PrawnsMacrobrachium tolmerum(Riek, 1951)

Crispin

White

2013

Physiological and Biochemical Zoology

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JSTOR is a not-for-profit service that helps scholars, researchers, and students discover, use, and build upon a wide range of content in a trusted digital archive. We use information technology and tools to increase productivity and facilitate new forms of scholarship. For more information about JSTOR, please contact support@jstor.org.. The University of Chicago Press ABSTRACTChanges to an animal's abiotic environment-and consequent changes in the allometry of metabolic rate in the whole animal and its constituent parts-has considerable potential to reveal important patterns in both intraspecific and interindividual variation of metabolic rates. This study demonstrates that, after 6 wk of thermal acclimation at replicate treatments of 16Њ, 21Њ, and 25ЊC, standard metabolic rate (SMR) scales allometrically in Leichhardtian river prawns Macrobrachium tolmerum ( ) and that the scaling exponent mean scaling exponent p 0.61 and normalization constant of the relationship between SMR and body mass is not significantly different among acclimation treatments when measured at 21ЊC. There is, however, significant variation among individuals in whole-animal metabolic rate. We hypothesized that these observations may arise because of changes in the metabolic rate and allometry of metabolic rate or mass of organ tissues within the animal. To investigate this hypothesis, rates of oxygen consumption in a range of tissues (gills, gonads, hepatopancreas, chelae muscle, tail muscle) were measured at 21ЊC and related to the body mass (M) and whole-animal SMR of individual prawns. We demonstrate that thermal acclimation had no effect on organ and tissue mass, that most organ and tissue (gills, gonads, hepatopancreas) respiration rates do not change with acclimation temperature, and that residual variation in the allometry of M. tolmerum SMR is not explained by differences in organ and tissue mass and respiration rates. These results suggest that body size and ambient temperature may independently affect metabolic rate in this species. Both chelae and tail muscle, however, exhibited a reduction in respiration rate in animals acclimated to 25Њ relative to those acclimated to 16Њ and 21ЊC. This reduction in respiration rates of muscle at higher temperatures is evidence of a tissue-specific acclimation response that was not detectable at the whole-animal level.

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“…Lipids and glycogen are the primary energetic source for gametogenesis in gastropods, including limpets (Blackmore 1969;Simpson 1982;Gabbott 1983;Lurman et al 2010), so it is not surprising that limpets in the winter trial displayed depleted glycogen levels. Additional research is needed to better understand the potential trade-offs in thermal physiology and reproduction of L. digitalis during the winter.…”

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confidence: 99%

Role of sequential low-tide-period conditions on the thermal physiology of summer and winter laboratory-acclimated fingered limpets, Lottia digitalis

2016

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exposure of 25-35 °C (summer) and 20 °C (winter) had greater upper critical thermal limits of cardiac performance as determined by final breakpoint temperature (~1.5-6 °C increase) and flatline temperature (~1-2 °C increase) than limpets with no previous exposure. The magnitude of temperature increase that conferred significant increases in thermal tolerance differed in summer and winter, reflecting seasonal differences in the thermal environment in nature. Fingered limpets' upper thermal tolerance is plastic and likely modulated by the previous day's low-tide exposure, demonstrating the importance of incorporating the repeated nature of stress into thermal physiology research in intertidal organisms.

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Ultrastructure of pedal muscle as a function of temperature in nacellid limpets

Cited by 6 publications

References 37 publications

Field studies and projections of climate change effects on the bearded horse mussel Modiolus barbatus in the Gulf of Thermaikos, Greece

Field studies and projections of climate change effects on the bearded horse mussel Modiolus barbatus in the Gulf of Thermaikos, Greece

Effect of Thermal Acclimation on Organ Mass, Tissue Respiration, and Allometry in Leichhardtian River PrawnsMacrobrachium tolmerum(Riek, 1951)

Role of sequential low-tide-period conditions on the thermal physiology of summer and winter laboratory-acclimated fingered limpets, Lottia digitalis

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