The Energetic Demand of Low Tide Stress on Balanus glandula Under Varying Thermal Conditions

Hendrix, Alicia M

01 January 2012

Like all intertidal species, the barnacle Balanus glandula must cope with temperature and desiccation stress during daily low tide exposure. The increase in temperature at low tide leads to both increased metabolic rate and the potential for increased ATP demand. With its additional inhibition of oxygen intake, low tide thus has an energetic cost that is often reflected in an increase in oxygen consumption following resubmersion. As anthropogenically induced global climate change increases air and water temperatures, its cost might increase. B. glandula individuals were exposed to 4‑hour low tides with maximal temperatures of 18, 30, 35, and 38°C, and their oxygen consumption rates and behaviors were recorded for 4 hours upon resubmersion. It was found that aerial respiration could be measured, though aerial rates were only a fraction of aquatic rates. It was further found that relative aquatic oxygen consumption rates were not elevated following low tide for any temperatures. However, B. glandula individuals exposed to 35 and 38°C low tides remained active a significantly greater portion of time through the first and second hours of recovery, respectively. This indicates that a low tide stress effect is evident in B. glandula, but that it manifests not as an increase in the respiration rate when active, but rather as an increase in the overall activity time. Thus, with increasing global temperatures B. glandula will likely have increased energy needs. This might lead to range relocations, a drive to find new energy sources, and/or reallocations of energy budgets.

Balanus glandula

barnacle

intertidal

low tide

coastal

thermal stress

environment

Marine Biology

Life history and reproductive ecology of an intertidal isopod Dynoides dentisinus (Crustacea: Peracarida: Isopoda) / 岩礁潮間帯性甲殻類シリケンウミセミ (軟甲綱：フクロエビ上目：等脚目) の生活史と繁殖生態

Nakamachi, Takeru

25 March 2019

京都大学 / 0048 / 新制・課程博士 / 博士(理学) / 甲第21605号 / 理博第4512号 / 新制||理||1647(附属図書館) / 京都大学大学院理学研究科生物科学専攻 / (主査)教授 朝倉 彰, 准教授 下村 通誉, 教授 中務 真人 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM

Isopoda

Dynoides dentisinus

Sexual dimorphism

Sexual selection

Barnacle shell

Poloygyny

400

The Effects of Thermal Stress on Balanus glandula

Walker, Breanna E

01 April 2013

Global climate change has become an increasing source of concern due to the recent build-up of greenhouses gases in the atmosphere. The rocky intertidal zone, as the interface between land and sea, is particularly vulnerable to climate change. Many inhabitants of the intertidal zone are sessile and thus experience both terrestrial and aquatic lifestyles at low and high tides, respectively. When emersed at low tide, organisms experience a number of abiotic stresses including heat stress, desiccation stress, and low oxygen availability. Most intertidal organisms have evolved from marine animals and respire most efficiently in water. Barnacles are one such type of intertidal organism. At low tide barnacles face a tradeoff between access to oxygen and loss of water through evaporation. In this study, individuals of the species Balanus glandula, a common intertidal barnacle, were exposed to temperatures of 16°C, 24°C, 30°C, and 35°C for four hours in simulated low tide to determine when aerial respiration occurred. Oxygen levels were measured over the four hours of the exposure and oxygen consumption rates were calculated. Oxygen consumption occurred at all temperatures studied, but the rates at different temperatures were not significantly different from each other. The results showed that barnacles can conduct aerial respiration over the entire course of the low tide exposure despite the risk of desiccation. This indicates that ATP demand remains substantial throughout the low tide and that resorting to anaerobic respiration is not sufficient to meet metabolic needs during low tide exposure.

intertidal

climate change

barnacle

invetrebrate

respiration

aerial respiration

heat

Biology

Other Ecology and Evolutionary Biology

Terrestrial and Aquatic Ecology

Effects of Intertidal Position on Metabolism and Behavior in the Acorn Barnacle, Balanus glandula

Horn, Kali

01 November 2019

The intertidal zone is characterized by persistent, tidally-driven fluctuations in both abiotic (e.g., temperature, [O2], salinity) and biotic (e.g., food availability, predation) conditions, which makes this a very physiologically challenging habitat for resident organisms. The magnitude and degree of variability of these environmental stressors differs between intertidal zones, with the most extreme physiological stress often being experienced by organisms in the high intertidal. Given that many of the fluctuating conditions in this environment are primary drivers of metabolic rate (e.g., temperature, [O2], food availability), we hypothesized that sessile conspecifics residing in different tidal zones would exhibit distinct ‘metabolic phenotypes,’ a term we use to collectively describe the organisms’ baseline metabolic performance and capacity. To investigate this hypothesis, we collected acorn barnacles (Balanus glandula) from low, mid, and high intertidal positions in San Luis Obispo Bay, CA and measured a suite of biochemical (whole-animal citrate synthase (CS) and lactate dehydrogenase (LDH) activity, aerial [lactate]), physiological (O2 consumption rates), morphological (body size), and behavioral (e.g., cirri beat frequency, % time operculum open) indices of metabolism. We found tidal zone-dependent differences in B. glandula metabolism that primarily related to anaerobic capacity, feeding behaviors and body size. Barnacles from the low intertidal tended to have a greater capacity for anaerobic metabolism (i.e., increased LDH activity), feed less when submerged, and be smaller in size compared to conspecifics in the high intertidal. We did not, however, see differences between barnacles from different tidal heights in whole-animal [lactate] following 24h of air exposure, which indicates that the enhanced capacity of low intertidal barnacles for anaerobic metabolism may have evolved to support metabolism during more prolonged episodes of emersion (>>24h) or during events other than emersion (e.g., coastal hypoxia, predation). There were also no significant differences in CS activity or baseline oxygen consumption rates (in air or seawater at 14˚C) across tidal heights, which implies that aerobic metabolic capacity may not be as sensitive to tidal position as anaerobic processes. Understanding how individuals occupying different shore heights differ in their metabolic capacity becomes increasingly interesting in the context of global climate change, given that the intertidal zone is predicted to experience even greater extremes in abiotic stress.

Balanus Glandula

Acorn Barnacle

Intertidal Zone

Metabolism

Lactate Dehydrogenase

Citrate Synthase

Biology

Integrative Biology

Marine Biology

Physiology

Effects Of Intertidal Position On The Response To Oxygen And Desiccation Stress In The Common Acorn Barnacle, Balanus Glandula

Dotterweich, Megan M

01 June 2023

Sessile invertebrates in the rocky intertidal experience intermittent periods of air exposure due to tidal flux, presenting risks of temperature extremes, hypoxia, nutrient limitation, and most dangerously, desiccation. Microscale variation in severity and frequency of these risks is widely dependent on vertical position within the intertidal zone. Common acorn barnacles (Balanus glandula) have a wide vertical distribution in the intertidal, creating large differences in microhabitat between the highest and lowest individuals in the population. This study set out to explore whether tidal position dependent differences exist in the response to oxygen and desiccation stress in B. glandula. We hypothesized that B. glandula from relatively high tidal heights, which are exposed to the air for a greater duration, will be better suited to tolerate anoxic and desiccation stress than conspecifics from lower tidal heights. To explore this, we compared responses of B. glandula collected from high and low intertidal positions to A) anoxia (0 mg O2/L) and hypoxia (≤ 2 mg O2/L) on survival, behavior (closed opercular plates, cirral beating, pneumostome formation), enzyme activity (lactate dehydrogenase (LDH), superoxide dismutase (SOD)), and tissue-lactate accumulation, in addition to B) the effects of humid (98% RH) and dry (32% RH) air emersion (at 17˚C) on survival, opercular behavior (open/closed), evaporative water loss (EWL) rates, and tissue-lactate accumulation. Relative to barnacles from the low intertidal, we found that barnacles from the high intertidal survive longer during anoxia and air emersion stress, close their operculum sooner in dry air, lose more water during air exposure at any humidity level, and tend to accumulate less D-lactate. We suspect that high intertidal B. glandula can survive desiccation longer by ejecting stores of mantle cavity fluid, thereby creating a moist lung-like, air-filled internal environment, then remaining largely closed and metabolically inactive when in air to avoid drying out and becoming anoxic. These differences may reflect plasticity or selective pressure in response to environmental stress during development and highlight the potential importance of microscale stress heterogeneity in influencing species climate change tolerance and potential distribution patterns.

Barnacle

Intertidal

Zonation

Oxygen Stress

Desiccation

San Luis Obispo Bay

Integrative Biology

Laboratory and Basic Science Research

Marine Biology

Systems and Integrative Physiology

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

Grady, Katie O

01 December 2016

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 hypoxia-inducing 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 pO2, pCO2, 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 D-lactate 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 pO2 and pCO2 following acute and chronic anoxic immersion, whereas air emersion pO2 and pCO2 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.

Balanus nubilus

giant barnacle

anoxia

hypoxia

giant muscle cells

intertidal

metabolism

muscle plasticity

histology

Behavior and Ethology

Cell Biology

Cellular and Molecular Physiology

Comparative and Evolutionary Physiology

Developmental Biology

Integrative Biology

Marine Biology

Hyperflora

Koenig, Paige Elizabeth

24 June 2020

No description available.

Fine Arts

Metallurgy

Metaphysics

jewelry

art

adornment

textiles

metalsmith

video games

fashion

armor

grief

coping

healing

tarot

witchcraft

depression

moss

fungi

mushroom

barnacle

nature

plants

garden

mysticism

jewelry artist

depression

loss

identity

introvert

Ocean acidification effects on marine organisms : a study of Littorina littorea and Balanus improvisus

Domeij Hilliges, Isak, Stendahl, Cecilia

January 2011

The world’s oceans are becoming more acid in a process called ocean acidification. The pH of the ocean have already decreased by 0.1 units from pre-industrial time until today. Scientists predict that by the year of 2100 the pH will decrease by as much as 0.4 units. This is a big potential problem to many marine species, because they have developed in such a stable environment that has not changed for millions of years. It is difficult to predict how they might be affected by such a decrease in pH during a relatively short time period. Several studies have been made on marine species exposed to decreased pH-levels, the results showed changes in their physiology but it is hard to predict how these changes will affect the organism in a long-term scale and if this might change ecosystem dynamics. Our study measured the activity of Littorina littorea and Balanus improvisus when exposed to lower pH, the results of our study showed an increase in activity for the lower pH (pH 6.0-7.5) when compared to the control (~pH8). The area of ocean acidification is a field that requires further studies to fully understand its effects on the marine ecosystems and the species within it.

ocean accidification

accidification

pH

sea

marine organism

marine

littorina littorea

balanus improvisus

periwinkle

barnacle

CO2

acid

ecosystem

activity

cirral movement

calcium carbonate system

buffering

low pH

havsförsurning

försurning

pH

hav

marina organismer

marin

littorina littorea

balanus improvisus

havstulpan

strandsnäcka

CO2

surt

ekosystem

aktivitet

cirrala rörelser

buffrande

lågt pH