Your search keyword '"endothermy"' showing total 595 results

1. Does intestine length explain digesta retention times in birds and mammals?

Author

Duque-Correa, María J., Clauss, Marcus, Meloro, Carlo, and Abraham, Andrew J.

Published

2025

2. Changes in physiological and behavioral thermoregulation in juvenile yellowfin tuna, Thunnus albacares, with increasing body size.

Author

Hino, Haruhiko, Kitagawa, Takashi, Matsumoto, Takayuki, Aoki, Yoshinori, and Kimura, Shingo

Abstract

The aim of this study was to investigate changes in the thermoregulatory mechanisms of juvenile yellowfin tuna, Thunnus albacares, with increasing body size by using archival tag data from 28 fish released in Japanese waters (fork length [FL] 35–92 cm). Fish with a body size of 35 cm FL remaining within the surface waters had lower thermal excess (0.4 °C), and fish with a body size of 40–60 cm FL undertaking brief diving at depths > 100 m had higher thermal excess (0.5–1.0 °C). However, the thermal excess did not consistently increase with body size, as has been reported for bigeye tuna. Heat budget models indicated inconsistent trends of decreased or increased heat production with body size. Yellowfin tuna regulate body temperatures by controlling the whole-body heat-transfer coefficient (λ) by 1.2–2.0 fold during descents and ascents, independent of body size, restricting λ for thermo-conservation during descent and increasing λ to absorb ambient heat during ascent. Compared with bigeye tuna, the vertical distributions of juvenile yellowfin tuna were limited to surface waters because of less efficient physiological thermoregulatory mechanisms. However, deep dives exceeding 1000 m, probably for predator avoidance, accompanied by rest in surface waters to recover from unusually higher behavioral activity, and vertical behavior similar to bigeye tuna "characteristic behavior" were observed. Compared to the thermoregulatory mechanisms of other tunas, those of juvenile yellowfin tuna are considered to be adaptive to tropical and subtropical shallower waters. [ABSTRACT FROM AUTHOR]

Published

2025

3. Using metabolic data to investigate the role of brood size in the development of endothermy.

Author

Engert, Elana Rae, Andreasson, Fredrik, Nord, Andreas, and Nilsson, Jan‐Åke

Subjects

*ANIMAL clutches, *EXTREME weather, *BODY temperature, *LIFE history theory, *ECOPHYSIOLOGY, *BLUE tit

Abstract

Altricial songbirds transform themselves from naked poikilotherms to fully feathered endothermic homeotherms over a matter of days from hatching to fledging. The ontogeny of endothermy is a developmental milestone for birds that not only face warmer average temperatures, but also increasingly frequent cold snaps and extreme weather. The timing of development of endothermy has been studied in altricial birds for over half a century. However, the determinants and constraints of the onset of endothermy are not yet fully understood. We experimentally investigated whether brood size influences the ontogeny of endothermic heat production in 4–8 day‐old nestling blue tits Cyanistes caeruleus in southern Sweden. The thermogenic response to a cooling challenge (15°C) increased with age overall. We found that 8‐day‐old nestlings from reduced broods had a slightly increased capacity for endothermic heat production compared to enlarged broods. This difference cannot be explained by body mass because this trait did not differ between brood size categories. Although a metabolic response was present in most nestlings by day 6, it was brief, not lasting more than a few minutes, and not sufficient to maintain a stable body temperature in any age group. Our study shows that incipient endothermy is present at an early age in nestling blue tits and may advance faster in reduced broods, but that individual nestlings lack sufficient insulation and thermogenic performance to maintain homeothermy independently during the first week of life. [ABSTRACT FROM AUTHOR]

Published

2024

4. Thought for food: the endothermic brain hypothesis.

Author

Osvath, Mathias, Němec, Pavel, Brusatte, Stephen L., and Witmer, Lawrence M.

Subjects

*COMPARATIVE psychology, *BRAIN anatomy, *COGNITIVE maps (Psychology), *WARM-blooded animals, *COLD-blooded animals

Abstract

Endotherms have 20–75 times more brain neurons than similarly sized ectotherms, marking one of the greatest transformations in brain history. Costly neurons no longer stand in strong competition with somatic processes, but pay for themselves and help meet the 20 times higher energy requirement of endothermy. A major difference between ectotherms and endotherms is the latter's extreme reliance on food. To secure necessary amounts, new foraging strategies are required. Birds and mammals evolved similar neurocognitive functions, absent in ectotherms, providing cognitive maps for highly efficient foraging. We argue for studies of cognition and brain anatomy in extant ectotherms and endotherms to identify key differences. Additionally, we call for studies of dinosaur brains, informed by the findings in the extant species, to trace the cognitive transition related to the evolution of endothermy. The evolution of whole-body endothermy occurred independently in dinosaurs and mammals and was associated with some of the most significant neurocognitive shifts in life's history. These included a 20-fold increase in neurons and the evolution of new brain structures, supporting similar functions in both lineages. We propose the endothermic brain hypothesis, which holds that elaborations in endotherm brains were geared towards increasing caloric intake through efficient foraging. The hypothesis is grounded in the intrinsic coupling of cognition and organismic self-maintenance. We argue that coevolution of increased metabolism and new forms of cognition should be jointly investigated in comparative studies of behaviors and brain anatomy, along with studies of fossil species. We suggest avenues for such research and highlight critical open questions. [ABSTRACT FROM AUTHOR]

Published

2024

5. Preparation of phosphinimide and its adsorption of uranium in aqueous solution.

Author

Liu, Zengcheng, Wang, Zhongchao, and Wang, Yanfei

Subjects

*URANIUM, *AQUEOUS solutions, *RADIOACTIVE elements, *LANGMUIR isotherms, *METAL ions, *SORBENTS

Abstract

The phosphinimide materials described in this paper were synthesized by polymerization precipitation. The properties of complexes coordinated with metal ions can be used as adsorbents for the adsorption of radioactive elements by using ligands such as imide and phosphorus groups. Then, the synthetic phosphinimide was characterized in detail by FT-IR, SEM, EDS and XPS, and its morphology and structural changes were studied. In addition, the effects of the material on the removal of uranium(VI) from aqueous solutions at different pH, sorbent doses, contact times, initial concentrations, and temperatures were studied. The experimental data shows that the adsorption process can fit the pseudo-second-order kinetic model well, which is in line with the Langmuir isotherm model. The thermodynamic study of adsorption shows that the adsorption process is a spontaneous endothermic process. In addition, at a temperature of 303.15 K and pH = 6, the maximum adsorption of uranium(VI) by phosphinimide in 25 min can reach 234.6 mg g−1, and a removal rate of 97.75%. [ABSTRACT FROM AUTHOR]

Published

2024

6. Thermal Adaptations in Animals: Genes, Development, and Evolution

Author

Agata, Ako, Nomura, Tadashi, Crusio, Wim E., Series Editor, Dong, Haidong, Series Editor, Radeke, Heinfried H., Series Editor, Rezaei, Nima, Series Editor, Steinlein, Ortrud, Series Editor, Xiao, Junjie, Series Editor, Rosenhouse-Dantsker, Avia, Editorial Board Member, Tominaga, Makoto, editor, and Takagi, Masahiro, editor

Published

2024

7. Fungal thermotolerance revisited and why climate change is unlikely to be supercharging pathogenic fungi (yet).

Author

Money, Nicholas P.

Subjects

*PATHOGENIC fungi, *AERODYNAMIC heating, *GLOBAL warming, *MYCOSES, *BODY temperature

Abstract

Thermotolerance has been viewed as an uncommon characteristic among the fungi and one of the reasons that less than 1% of the described species operate as opportunistic pathogens of humans. Growth at 37°C is certainly a requirement for a fungus that invades the body core, but tens of thousands of nonpathogenic species are also able to grow at this temperature. Ergo, body temperature does not serve as a thermal barrier to the development of infections by many harmless fungi. The absence of other virulence factors must be more demanding. This observation raises questions about the hypothetical links between climate change and the increasing number of life-threatening human mycoses. Given the widespread distribution of fungal thermotolerance and the 1°C (2°F) increase in global temperature over the last 140 years it seems unlikely that the warming climate has driven the evolution of more virulent strains of fungi. More compelling explanations for the changes in the behavior of fungi as disease agents include their adaptation to the widening use of azole antifungals in hospitals and the wholesale application of millions of tons of the same class of heterocyclic chemicals in agriculture. On the other hand, climate change is having a significant effect on the spread of human mycoses by extending the geographical range of pathogenic fungi. A related increase in fungal asthma caused by spore inhalation is another likely consequence of planetary change. • Growth at 37 °C has been viewed as a definitive feature of fungi that infect humans. • However, tens of thousands of nonpathogenic species can grow at this temperature. • Ergo, body temperature seems unlikely to serve as a thermal barrier to the evolution of pathogens. • These observations contradict a putative link between climate change and the increasing number of human mycoses. [ABSTRACT FROM AUTHOR]

Published

2024

8. Direct measurement of cruising and burst swimming speeds of the shortfin mako shark (Isurus oxyrinchus) with estimates of field metabolic rate.

Author

Waller, Matt J., Queiroz, Nuno, da Costa, Ivo, Cidade, Tiago, Loureiro, Bruno, Womersley, Freya C., Fontes, Jorge, Afonso, Pedro, Macena, Bruno C. L., Loveridge, Alexandra, Humphries, Nicolas E., Southall, Emily J., and Sims, David W.

Subjects

*SHARKS, *FISH locomotion, *SWIMMING, *MARINE fishes, *SPEED measurements, *SPEED

Abstract

The shortfin mako shark is a large‐bodied pursuit predator thought to be capable of the highest swimming speeds of any elasmobranch and potentially one of the highest energetic demands of any marine fish. Nonetheless, few direct speed measurements have been reported for this species. Here, animal‐borne bio‐loggers attached to two mako sharks were used to provide direct measurements of swimming speeds, kinematics and thermal physiology. Mean sustained (cruising) speed was 0.90 m s−1 (±0.07 s.d.) with a mean tail‐beat frequency (TBF) of 0.51 Hz (±0.16 s.d.). The maximum burst speed recorded was 5.02 m s−1 (TBFmax = 3.65 Hz) from a 2 m long female. Burst swimming was sustained for 14 s (mean speed = 2.38 m s−1), leading to a 0.24°C increase in white muscle temperature in the 12.5 min after the burst. Routine field metabolic rate was estimated at 185.2 mg O2 kg−1 h−1 (at 18°C ambient temperature). Gliding behaviour (zero TBF) was more frequently observed after periods of high activity, especially after capture when internal (white muscle) temperature approached 21°C (ambient temperature: 18.3°C), indicating gliding probably functions as an energy recovery mechanism and limits further metabolic heat production. The results show shortfin mako sharks generally cruise at speeds similar to other endothermic fish – but faster than ectothermic sharks – with the maximum recorded burst speed being among the highest so far directly measured among sharks, tunas and billfishes. This newly recorded high‐oxygen‐demand performance of mako sharks suggests it may be particularly vulnerable to habitat loss due to climate‐driven ocean deoxygenation. [ABSTRACT FROM AUTHOR]

Published

2023

9. Distinct and shared endothermic strategies in the heat producing tissues of tuna and other teleosts.

Author

Wu, Baosheng, Gao, Xueli, Hu, Mingling, Hu, Jing, Lan, Tianming, Xue, Tingfeng, Xu, Wenjie, Zhu, Chenglong, Yuan, Yuan, Zheng, Jiangmin, Qin, Tao, Xin, Peidong, Li, Ye, Gong, Li, Feng, Chenguang, He, Shunping, Liu, Huan, Li, Haimeng, Wang, Qing, and Ma, Zhenhua

Abstract

Although most fishes are ectothermic, some, including tuna and billfish, achieve endothermy through specialized heat producing tissues that are modified muscles. How these heat producing tissues evolved, and whether they share convergent molecular mechanisms, remain unresolved. Here, we generated a high-quality genome from the mackerel tuna (Euthynnus affinis) and investigated the heat producing tissues of this fish by single-nucleus and bulk RNA sequencing. Compared with other teleosts, tuna-specific genetic variation is strongly associated with muscle differentiation. Single-nucleus RNA-seq revealed a high proportion of specific slow skeletal muscle cell subtypes in the heat producing tissues of tuna. Marker genes of this cell subtype are associated with the relative sliding of actin and myosin, suggesting that tuna endothermy is mainly based on shivering thermogenesis. In contrast, cross-species transcriptome analysis indicated that endothermy in billfish relies mainly on non-shivering thermogenesis. Nevertheless, the heat producing tissues of the different species do share some tissue-specific genes, including vascular-related and mitochondrial genes. Overall, although tunas and billfishes differ in their thermogenic strategies, they share similar expression patterns in some respects, highlighting the complexity of convergent evolution. [ABSTRACT FROM AUTHOR]

Published

2023

10. Muted responses to heat in a nocturnal tropical rodent.

Author

Breit, Ana M., Kleinhause‐Goldman Gedalyahou, Tal, Ikhwan, Awang Khairul, Isaac, Marcellinus, Tuen, Andrew Alek, and Levesque, Danielle L.

Subjects

RODENTS, BASAL metabolism, BODY temperature, WATER temperature, CLIMATE change

Abstract

Copyright of Biotropica is the property of Wiley-Blackwell and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

11. Vertebrate cardiac regeneration: evolutionary and developmental perspectives

Author

Cutie, Stephen and Huang, Guo N

Subjects

Medical Biotechnology, Biomedical and Clinical Sciences, Cardiovascular, Regenerative Medicine, Heart Disease, 1.1 Normal biological development and functioning, Underpinning research, Cardiomyocyte proliferation, Cell cycle arrest, Development, Endothermy, Evolution, Heart, Inflammation, Polyploidization, Regeneration, Medical biotechnology

Abstract

Cardiac regeneration is an ancestral trait in vertebrates that is lost both as more recent vertebrate lineages evolved to adapt to new environments and selective pressures, and as members of certain species developmentally progress towards their adult forms. While higher vertebrates like humans and rodents resolve cardiac injury with permanent fibrosis and loss of cardiac output as adults, neonates of these same species can fully regenerate heart structure and function after injury - as can adult lower vertebrates like many teleost fish and urodele amphibians. Recent research has elucidated several broad factors hypothesized to contribute to this loss of cardiac regenerative potential both evolutionarily and developmentally: an oxygen-rich environment, vertebrate thermogenesis, a complex adaptive immune system, and cancer risk trade-offs. In this review, we discuss the evidence for these hypotheses as well as the cellular participators and molecular regulators by which they act to govern heart regeneration in vertebrates.

Published

2021

12. Universal metabolic constraints shape the evolutionary ecology of diving in animals.

Author

Verberk, Wilco, Calosi, Piero, Brischoux, François, Spicer, John, Garland, Theodore, and Bilton, David

Subjects

allometry, ectothermy, endothermy, evolutionary physiology, palaeophysiology, scaling, Animals, Biological Evolution, Diving, Ecology, Oxygen, Oxygen Consumption

Abstract

Diving as a lifestyle has evolved on multiple occasions when air-breathing terrestrial animals invaded the aquatic realm, and diving performance shapes the ecology and behaviour of all air-breathing aquatic taxa, from small insects to great whales. Using the largest dataset yet assembled, we show that maximum dive duration increases predictably with body mass in both ectotherms and endotherms. Compared to endotherms, ectotherms can remain submerged for longer, but the mass scaling relationship for dive duration is much steeper in endotherms than in ectotherms. These differences in diving allometry can be fully explained by inherent differences between the two groups in their metabolic rate and how metabolism scales with body mass and temperature. Therefore, we suggest that similar constraints on oxygen storage and usage have shaped the evolutionary ecology of diving in all air-breathing animals, irrespective of their evolutionary history and metabolic mode. The steeper scaling relationship between body mass and dive duration in endotherms not only helps explain why the largest extant vertebrate divers are endothermic rather than ectothermic, but also fits well with the emerging consensus that large extinct tetrapod divers (e.g. plesiosaurs, ichthyosaurs and mosasaurs) were endothermic.

Published

2020

13. Phylogenetic and Evolutionary Comparison of Mitogenomes Reveal Adaptive Radiation of Lampriform Fishes.

Author

Wang, Jin-fang, Yu, Hai-yan, Ma, Shao-bo, Lin, Qiang, Wang, Da-zhi, and Wang, Xin

Subjects

*ADAPTIVE radiation, *TRANSFER RNA, *BIOLOGICAL evolution, *MITOCHONDRIAL DNA, *MARINE fishes, *DEEP-sea fishes, *PHYLOGENY, *OSTEICHTHYES

Abstract

Lampriform fishes (Lampriformes), which primarily inhabit deep-sea environments, are large marine fishes varying from the whole-body endothermic opah to the world's longest bony fish-giant oarfish, with species morphologies varying from long and thin to deep and compressed, making them an ideal model for studying the adaptive radiation of teleost fishes. Moreover, this group is important from a phylogenetic perspective owing to their ancient origins among teleosts. However, knowledge about the group is limited, which is, at least partially, due to the dearth of recorded molecular data. This study is the first to analyze the mitochondrial genomes of three lampriform species (Lampris incognitus, Trachipterus ishikawae, and Regalecus russelii) and infer a time-calibrated phylogeny, including 68 species among 29 orders. Our phylomitogenomic analyses support the classification of Lampriformes as monophyletic and sister to Acanthopterygii; hence, addressing the longstanding controversy regarding the phylogenetic status of Lampriformes among teleosts. Comparative mitogenomic analyses indicate that tRNA losses existed in at least five Lampriformes species, which may reveal the mitogenomic structure variation associated with adaptive radiation. However, codon usage in Lampriformes did not change significantly, and it is hypothesized that the nucleus transported the corresponding tRNA, which led to function substitutions. The positive selection analysis revealed that atp8 and cox3 were positively selected in opah, which might have co-evolved with the endothermic trait. This study provides important insights into the systematic taxonomy and adaptive evolution studies of Lampriformes species. [ABSTRACT FROM AUTHOR]

Published

2023

14. Reappraising the exteriorization of the mammalian testes through evolutionary physiology

Author

Miller, William B and Torday, John S

Subjects

Biological Sciences, Evolutionary Biology, Urologic Diseases, balanced ecological hypothesis, endothermy, exteriorization of the testes, gubernaculum, scrotum, Biochemistry and Cell Biology, Developmental Biology, Bioinformatics and computational biology

Abstract

A number of theories have been proposed to explain the exteriorization of the testicles in most mammalian species. None of these provide a consistent account for the wide variety of testicular locations found across the animal kingdom. It is proposed that testicular location is the result of coordinate action of testicular tissue ecologies to sustain preferential states of homeostatic equipoise throughout evolutionary development in response to the advent of endothermy.

Published

2019

15. Evolutionary process toward avian-like cephalic thermoregulation system in Theropoda elucidated based on nasal structures

Author

Seishiro Tada, Takanobu Tsuihiji, Ryoko Matsumoto, Tomoya Hanai, Yasuko Iwami, Naoki Tomita, Hideaki Sato, and Khishigjav Tsogtbaatar

Subjects

amniota, Theropoda, Velociraptor, respiratory turbinate, selective brain cooling, endothermy, Science

Abstract

It has long been discussed whether non-avian dinosaurs were physiologically closer to ectotherms or endotherms, with the internal nasal structure called the respiratory turbinate present in extant endotherms having been regarded as an important clue for this conundrum. However, the physiological function and relevance of this structure for dinosaur physiology are still controversial. Here, we found that the size of the nasal cavity relative to the head size of extant endotherms is larger than those of extant ectotherms, with that of the dromaeosaurid Velociraptor being below the extant endotherms level. The result suggests that a large nasal cavity accommodating a well-developed respiratory turbinate is primarily important as a thermoregulation apparatus for large brains characteristic of endothermic birds and mammals, and the nasal cavity of Velociraptor was apparently not large enough to carry out this role required for an endothermic-sized brain. In addition, a hypothesis that the enlargement of the nasal cavity for brain cooling has been associated with the skull modification in the theropod lineage toward modern birds is proposed herein. In particular, the reduction of the maxilla in derived avialans may have coincided with acquisition of the avian-like cephalic thermoregulation system.

Published

2023

16. Body forms of extant lamniform sharks (Elasmobranchii: Lamniformes), and comments on the morphology of the extinct megatooth shark, Otodus megalodon, and the evolution of lamniform thermophysiology.

Author

Sternes, Phillip C., Wood, Jake J., and Shimada, Kenshu

Subjects

*CHONDRICHTHYES, *SHARKS, *PRINCIPAL components analysis, *MORPHOLOGY, *HUMAN body

Abstract

The megatooth shark, Otodus megalodon, is an iconic Neogene lamniform shark known only from its teeth and vertebrae. Its thermophysiology is previously inferred to have been regionally endothermic, like the extant lamnids that are active predatory lamniforms. By considering the entire Lamnidae as the ecological and physiological analogue to O. megalodon, a recent study proposed inferred body dimensions of O. megalodon based on morphometric analyses on body forms of extant lamnids. Here, we reassessed the recent study by testing whether a two-dimensional approach used in the study can actually tease out the difference between ectothermic and endothermic fishes in the first place. Morphometric comparisons of the whole body and different body parts (e.g. head, different fins, and precaudal body with and without fins) among the 15 extant species of Lamniformes were conducted using principal component analyses and simple clustering methods. Our study strongly indicates that, two-dimensionally, there is no relationship between thermophysiology and body form in lamniforms. The reality is that there are presently no scientific means to support or refute the accuracy of any of the previously published body forms of O. megalodon. We also clarify that regional endothermy likely evolved in multiple clades independently through lamniform phylogeny. [ABSTRACT FROM AUTHOR]

Published

2023

17. Avian cardiomyocyte architecture and what it reveals about the evolution of the vertebrate heart.

Author

Shiels, Holly A.

Abstract

Bird cardiomyocytes are long, thin and lack transverse (t)-tubules, which is akin to the cardiomyocyte morphology of ectothermic non-avian reptiles, who are typified by low maximum heart rates and low pressure development. However, birds can achieve greater contractile rates and developed pressures than mammals, whose wide cardiomyocytes contain a dense t-tubular network allowing for uniform excitation–contraction coupling and strong contractile force. To address this apparent paradox, this paper functionally links recent electrophysiological studies on bird cardiomyocytes with decades of ultrastructure measurements. It shows that it is the strong transsarcolemmal Ca2+ influx via the L-type Ca2+ current (ICaL) and the high gain of Ca2+-induced Ca2+ release from the sarcoplasmic reticulum (SR), coupled with an internal SR Ca2+ release relay system, that facilitates the strong fast contractions in the long thin bird cardiomyocytes, without the need for t-tubules. The maintenance of an elongated myocyte morphology following the post-hatch transition from ectothermy to endothermy in birds is discussed in relation to cardiac load, myocyte ploidy, and cardiac regeneration potential in adult cardiomyocytes. Overall, the paper shows how little we know about cellular Ca2+ dynamics in the bird heart and suggests how increased research efforts in this area would provide vital information in our quest to understand the role of myocyte architecture in the evolution of the vertebrate heart. This article is part of the theme issue 'The cardiomyocyte: new revelations on the interplay between architecture and function in growth, health, and disease'. Please see glossary at the end of the paper for definitions of specialized terms. [ABSTRACT FROM AUTHOR]

Published

2022

18. Pseudosuchian thermometabolism: A review of the past two decades.

Author

Faure-Brac MG

Abstract

Pseudosuchia, one of the two main clades of Archosauria, is today only represented by some 20 extant species, the crocodilians, representing only a fraction of its extinct diversity. Extant crocodilians are ectotherms but present morphological and anatomical features usually associated with endothermy. In 2004, it was proposed that pseudosuchians were ancestrally endothermic and the features observed in extant crocodilians are the remains of this lost legacy. This contribution has two parts: the first part covers 20 years of studies on this subject, first exploring the evidence for a loss of endothermy in extant crocodilians, before covering the variety of proxies used to infer the thermophymetabolic regime of extinct pseudosuchians. In the second part, the quantitative results of these previous studies are integrated into a comprehensive ancestral state reconstruction to discuss a potential scenario for the evolution of thermometabolism. Pseudosuchian endothermy would then have been lost close to the node Crocodylomorpha. The end-Triassic mass extinction is proposed to have played the role of a filter, leading to the extinction of endothermic pseudosuchians and the survival of ectothermic ones. This difference in survival in Pseudosuchia is compared to those of dinosaurs, and difference in their metabolism is also considered. Pseudosuchian endothermy might have been of a different level than the dinosaurian one and more studies are expected to clarify this question., (© 2024 The Author(s). The Anatomical Record published by Wiley Periodicals LLC on behalf of American Association for Anatomy.)

Published

2024

19. Manipulating plasma thyroid hormone levels alters development of endothermy and ventilation in nestling red-winged blackbirds

Author

Tushar S. Sirsat, Sarah K. G. Sirsat, Edwan R. Price, Megan Pineda, and Edward M. Dzialowski

Subjects

endothermy, thyroid hormone, ventilation, metabolic rate, altricial bird, Agelaius phoeniceus, Physiology, QP1-981

Abstract

Thyroid hormones are key regulators of development and metabolism in vertebrates. During the nestling period, young of altricial species transition from an ectothermic phenotype to an endothermic phenotype. Red-winged blackbirds are an altricial species that exhibit an increase in plasma 3,3’, 5-triiodo-L-thyronine (T3) levels during the first 5 days post-hatch (dph), begin to develop endothermic metabolic responses by 7 dph, and fledge within 10 days of hatching. We propose that thyroid hormones play an important role in regulating development of endothermy during the nestling period in altricial birds. To better understand the effects of thyroid hormones on endothermic metabolic development in an altricial species, we treated nestling red-winged blackbirds on 2, 3, and 5 dph with either methimazole (MMI) to induce hypothyroidism or supplemental T3 to induce hyperthyroidism. We then measured on 5, 7, and 9 dph morphology and whole animal O2 consumption (V˙o2) and ventilation in the thermal neutral zone and during gradual cooling. Treatment of nestlings with MMI resulted in lower plasma T3 levels on 5 dph that recovered by 7 dph, while supplementing with T3 did not affect plasma T3 levels on 5, 7 and 9 dph. Treatment with MMI resulted in smaller nestlings with smaller hearts and structural characters such as wing chord and femur length, but larger lungs and kidneys. Treatment with T3 produced smaller nestlings with smaller body masses and shorter femur and tarsus lengths. The development of V˙o2 and ventilation endothermic responses to gradual cooling in MMI treated nestlings were delayed when compared with control nestlings. In 9 dph nestlings, hypothyroidism resulted in alterations in the responses of ventilation frequency and tidal volume to cooling when compared with the control nestlings. Supplemental T3 had no effect on the development of V˙o2 and ventilation in the thermal neutral zone or in response to cooling. Our data suggest plasma thyroid hormone levels play an active role in the systemic development of endothermic capacity and the development of ventilatory control. In the nestling avian, multiple systems develop in concert to produce an endothermic phenotype, but reduced thyroid hormone delays maturation of endothermic capacity.

Published

2022

20. The thermal performance curve for aerobic metabolism of a flying endotherm.

Author

Glass, Jordan R. and Harrison, Jon F.

Subjects

*BODY temperature, *AEROBIC metabolism, *AEROBIC capacity, *ATMOSPHERIC temperature, *MAMMAL evolution, *HONEYBEES, *INSECTS, *BEES

Abstract

Performance benefits of stable, warm muscles are believed to be important for the evolution of endothermy in mammals, birds and flying insects. However, thermal performance curves have never been measured for a free-flying endotherm, as it is challenging to vary body temperatures of these animals, and maximal flight performance is difficult to elicit. We varied air temperatures and gas densities to manipulate thoracic temperatures of flying honeybees from 29°C to 44°C, with low air densities used to increase flight metabolic rates to maximal values. Honeybees showed a clear thermal performance curve with an optimal temperature of 39°C. Maximal flight metabolic rates increased by approximately 2% per 1°C increase in thoracic temperature at suboptimal thoracic temperatures, but decreased approximately 5% per 1°C increase as the bees continued to heat up. This study provides the first quantification of the maximal metabolic performance benefit of thermoregulation in an endotherm. These data directly support aerobic capacity models for benefits of thermoregulation in honeybees, and suggest that improved aerobic capacity probably contributes to the multiple origins of endothermic heterothermy in bees and other insects. [ABSTRACT FROM AUTHOR]

Published

2022

21. Anatomy of the heart of the leatherback turtle.

Author

Jensen, Bjarke, Lauridsen, Henrik, Webb, Grahame J. W., and Wang, Tobias

Subjects

*LEATHERBACK turtle, *ANATOMY, *HEART ventricles, *SYSTOLIC blood pressure, *HEART, *HYPERTENSION

Abstract

Non‐crocodylian reptiles have hearts with a single ventricle, which is partially separated by a muscular ridge that provides some separation of blood flows. An exceptional situation exists in monitor lizards and pythons, where the ventricular left side generates a much higher systolic blood pressure than the right side, thus resembling mammals and birds. This functional division of the ventricle depends on a large muscular ridge and may relate to high metabolic demand. The large leatherback turtle (<1000 kg), with its extensive migrations and elevated body temperatures, may have similar adaptations. We report on the anatomy of the hearts of two leatherback turtles. One stranded in Ballum, Denmark in 2020, and was examined in detail, supplemented by observations and photos of an additional stranding specimen from Canada. The external morphology of the leatherback heart resembles that of other turtles, but it is large. We made morphometric measurements of the Ballum heart and created an interactive 3D model using high‐resolution MRI. The volume of the ventricle was 950 ml, from a turtle of 300 kg, which is proportionally almost twice as large as in other reptiles. The Ballum heart was compared to MRI scans of the hearts of a tortoise, a python, and a monitor lizard. Internally, the leatherback heart is typical of non‐crocodylian reptiles and did not contain the well‐developed septation found in pythons and monitor lizards. We conclude that if leatherback turtles have exceptional circulation needs, they are sustained with a relatively large but otherwise typical non‐crocodylian reptile heart. [ABSTRACT FROM AUTHOR]

Published

2022

22. Large‐scale evolution of body temperatures in land vertebrates

Author

Matthew O. Moreira, Yan‐Fu Qu, and John J. Wiens

Subjects

Body temperature, diel activity, endothermy, evolution, niche conservatism, phylogeny, Evolution, QH359-425

Abstract

Abstract Body temperature is a crucial variable in animals that affects nearly every aspect of their lives. Here we analyze for the first time largescale patterns in the evolution of body temperatures across terrestrial vertebrates (tetrapods: including amphibians, mammals, birds and other reptiles). Despite the traditional view that endotherms (birds and mammals) have higher body temperatures than ectotherms, we find they are not significantly different. However, rates of body‐temperature evolution are significantly different, with lower rates in endotherms than ectotherms, and the highest rates in amphibians. We find that body temperatures show strong phylogenetic signal and conservatism over 350 million years of evolutionary history in tetrapods, and some lineages appear to have retained similar body temperatures over time for hundreds of millions of years. Although body temperatures are often unrelated to climate in tetrapods, we find that body temperatures are significantly related to day‐night activity patterns. Specifically, body temperatures are generally higher in diurnal species than nocturnal species, both across ectotherms and, surprisingly, across endotherms also. Overall, our results suggest that body temperatures are significantly linked to phylogeny and diel‐activity patterns within and among tetrapod groups, rather than just climate and the endotherm‐ectotherm divide.

Published

2021

23. Relative sarcolipin (SLN) and sarcoplasmic reticulum Ca2+ ATPase (SERCA1) transcripts levels in closely related endothermic and ectothermic scombrid fishes: Implications for molecular basis of futile calcium cycle non-shivering thermogenesis (NST).

Author

Robinson, Sean, Wegner, Nicholas C., Sepulveda, Chugey A., and Franck, Jens P.C.

Subjects

*SARCOPLASMIC reticulum, *SWORDFISH, *SKIPJACK tuna, *CALCIUM ions, *YELLOWFIN tuna, *ADENOSINE triphosphatase, *RYANODINE receptors

Abstract

Regional endothermy is the ability of an animal to elevate the temperature of specific regions of the body above that of the surrounding environment and has evolved independently among several fish lineages. Sarcolipin (SLN) is a small transmembrane protein that uncouples the sarcoplasmic reticulum calcium ATPase pump (SERCA1b) resulting in futile Ca2+ cycling and is thought to play a role in non-shivering thermogenesis (NST) in cold-challenged mammals and possibly some fishes. This study investigated the relative expression of sln and serca1 transcripts in three regionally-endothermic fishes (the skipjack, Katsuwonus pelamis , and yellowfin tuna, Thunnus albacares , both of which elevate the temperatures of their slow-twitch red skeletal muscle (RM) and extraocular muscles (EM), as well as the cranial endothermic swordfish, Xiphias gladius), and closely related ectothermic scombrids (the Eastern Pacific bonito, Sarda chiliensis, and Pacific chub mackerel, Scomber japonicus). Using Reverse Transcription quantitative PCR (RT-qPCR) and species-specific primers, relative sln expression trended higher in both the RM and EM for all four scombrid species compared to white muscle. In addition, relative serca1 expression was found to be higher in RM of skipjack and yellowfin tuna in comparison to white muscle. However, neither sln nor serca1 transcripts were higher in swordfish RM, EM or cranial heater tissue in comparison to white muscle. A key phosphorylation site in sarcolipin, threonine 5, is conserved in the swordfish, but is mutated to alanine or valine in tunas and the endothermic smalleye Pacific opah, Lampris incognitus , which should result in increased uncoupling of the SERCA pump. Our results support the role of potential SLN-NST in endothermic tunas and the lack thereof for swordfish. [Display omitted] • Quantified sarcolipin and calcium ATPase transcript levels in endothermic scombrid and closely related ectothermic fish species. • Sln and serca1 increased in eye and red muscle tissues of endothermic species compared to ectothermic species. • Sln and serca1 transcripts not increased in eye, red, white or heater organ tissues of swordfish. • Increase in sln and serca1 in red muscle and eye muscle is consistent with previous studies by ourselves and others. • Swordfish heater organ may exploit a "leaky" ryanodine receptor 1a (RyR1a) calcium channel for the futile calcium cycle. [ABSTRACT FROM AUTHOR]

Published

2024

24. Networking from the Cell to Quantum Mechanics as Consciousness

Author

Torday, John, Miller Jr., William, Torday, John, and Miller Jr., William

Published

2020

25. Conclusion

Author

Torday, John, Miller Jr., William, Torday, John, and Miller Jr., William

Published

2020

26. Mice selected for a high basal metabolic rate evolved larger guts but not more efficient mitochondria.

Author

Brzęk, Paweł, Roussel, Damien, and Konarzewski, Marek

Subjects

*BASAL metabolism, *LIVER mitochondria, *LABORATORY mice, *OXIDATIVE phosphorylation, *MICE

Abstract

Intra-specific variation in both the basal metabolic rate (BMR) and mitochondrial efficiency (the amount of ATP produced per unit of oxygen consumed) has profound evolutionary and ecological consequences. However, the functional mechanisms responsible for this variation are not fully understood. Mitochondrial efficiency is negatively correlated with BMR at the interspecific level but it is positively correlated with performance capacity at the intra-specific level. This discrepancy is surprising, as theories explaining the evolution of endothermy assume a positive correlation between BMR and performance capacity. Here, we quantified mitochondrial oxidative phosphorylation activity and efficiency in two lines of laboratory mice divergently selected for either high (H-BMR) or low (L-BMR) levels of BMR. H-BMR mice had larger livers and kidneys (organs that are important predictors of BMR). H-BMR mice also showed higher oxidative phosphorylation activity in liver mitochondria but this difference can be hypothesized to be a direct effect of selection only if the heritability of this trait is low. However, mitochondrial efficiency in all studied organs did not differ between the two lines. We conclude that the rapid evolution of BMR can reflect changes in organ size rather than mitochondrial properties, and does not need to be accompanied obligatorily by changes in mitochondrial efficiency. [ABSTRACT FROM AUTHOR]

Published

2022

27. Gigantic genomes of salamanders indicate that body temperature, not genome size, is the driver of global methylation and 5‐methylcytosine deamination in vertebrates.

Author

Adams, Alexander Nichols, Denton, Robert Daniel, and Mueller, Rachel Lockridge

Subjects

*GENOME size, *SALAMANDERS, *METHYLCYTOSINE, *BODY temperature, *METHYLATION

Abstract

Transposable elements (TEs) are sequences that replicate and move throughout genomes, and they can be silenced through methylation of cytosines at CpG dinucleotides. TE abundance contributes to genome size, but TE silencing variation across genomes of different sizes remains underexplored. Salamanders include most of the largest C‐values – 9 to 120 Gb. We measured CpG methylation levels in salamanders with genomes ranging from 2N = ∼58 Gb to 4N = ∼116 Gb. We compared these levels to results from endo‐ and ectothermic vertebrates with more typical genomes. Salamander methylation levels are approximately 90%, higher than all endotherms. However, salamander methylation does not differ from other ectotherms, despite an approximately 100‐fold difference in nuclear DNA content. Because methylation affects the nucleotide compositional landscape through 5‐methylcytosine deamination to thymine, we quantified salamander CpG dinucleotide levels and compared them to other vertebrates. Salamanders and other ectotherms have comparable CpG levels, and ectotherm levels are higher than endotherms. These data show no shift in global methylation at the base of salamanders, despite a dramatic increase in TE load and genome size. This result is reconcilable with previous studies that considered endothermy and ectothermy, which may be more important drivers of methylation in vertebrates than genome size. [ABSTRACT FROM AUTHOR]

Published

2022

28. Factors affecting gestation periods in elasmobranch fishes

Author

Soma Tokunaga, Yuuki Y. Watanabe, Mai Kawano, and Yuuki Kawabata

Subjects

endothermy, metabolism, phylogenetic analysis, scaling, viviparity, Science, Biology (General), QH301-705.5

Abstract

Gestation periods vary greatly across elasmobranch species. Differences in body size and body temperature (i.e. major determinants of metabolic rates) might explain such variation. Although temperature effects have been demonstrated for captive animals, body size effects remain undocumented. Moreover, whether metabolic rates of mothers or those of embryos affect gestation periods remains unclear. Because biological times generally scale with mass1−β, where β is metabolic scaling exponent (0.8–0.9 in fishes), we hypothesized that elasmobranch gestation periods would scale with mass0.1–0.2. We also hypothesized that regionally endothermic species with elevated metabolic rates should have shorter gestation periods than similar-sized ectothermic species if the metabolic rates of mothers are responsible. We compiled data on gestation periods for 36 elasmobranch species to show that gestation periods scale with M0.11 and m0.17, where M and m are adult female mass and birth mass, respectively. Litter size and body temperature also affected gestation periods. Our findings suggest that the body-mass dependence of metabolic rate explains some variations in elasmobranch gestation periods. Unexpectedly, regionally endothermic sharks did not have shorter gestation periods than their ectothermic counterparts, suggesting that the metabolic rates of embryos, which are likely ectothermic in all elasmobranch species, may be responsible. This article has an associated First Person interview with the first author of the paper.

Published

2022

29. Why bears hibernate? Redefining the scaling energetics of hibernation.

Author

Nespolo, Roberto F., Mejias, Carlos, and Bozinovic, Francisco

Subjects

*HIBERNATION, *BATS, *BLACK bear, *METABOLISM, *HYPOXEMIA, *MAMMALS, *CELL metabolism, *ALLOMETRY

Abstract

Hibernation is a natural state of suspended animation that many mammals experience and has been interpreted as an adaptive strategy for saving energy. However, the actual amount of savings that hibernation represents, and particularly its dependence on body mass (the 'scaling') has not been calculated properly. Here, we estimated the scaling of daily energy expenditure of hibernation (DEEH), covering a range of five orders of magnitude in mass. We found that DEEH scales isometrically with mass, which means that a gram of hibernating bat has a similar metabolism to that of a gram of bear, 20 000 times larger. Given that metabolic rate of active animals scales allometrically, the point where these scaling curves intersect with DEEH represents the mass where energy savings by hibernation are zero. For BMR, these zero savings are attained for a relatively small bear (approx. 75 kg). Calculated on a per cell basis, the cellular metabolic power of hibernation was estimated to be 1.3 × 10−12 ± 2.6 × 10−13 W cell−1, which is lower than the minimum metabolism of isolated mammalian cells. This supports the idea of the existence of a minimum metabolism that permits cells to survive under a combination of cold and hypoxia. [ABSTRACT FROM AUTHOR]

Published

2022

30. New tools suggest a middle Jurassic origin for mammalian endothermy: Advances in state‐of‐the‐art techniques uncover new insights on the evolutionary patterns of mammalian endothermy through time.

Author

Newham, Elis, Gill, Pamela G., and Corfe, Ian J.

Subjects

*FOSSIL mammals, *MAMMAL evolution, *FOSSILS, *GENEALOGY, *BODY temperature regulation

Abstract

We suggest that mammalian endothermy was established amongst Middle Jurassic crown mammals, through reviewing state‐of‐the‐art fossil and living mammal studies. This is considerably later than the prevailing paradigm, and has important ramifications for the causes, pattern, and pace of physiological evolution amongst synapsids. Most hypotheses argue that selection for either enhanced aerobic activity, or thermoregulation was the primary driver for synapsid physiological evolution, based on a range of fossil characters that have been linked to endothermy. We argue that, rather than either alternative being the primary selective force for the entirety of endothermic evolution, these characters evolved quite independently through time, and across the mammal family tree, principally as a response to shifting environmental pressures and ecological opportunities. Our interpretations can be tested using closely linked proxies for both factors, derived from study of fossils of a range of Jurassic and Cretaceous mammaliaforms and early mammals. [ABSTRACT FROM AUTHOR]

Published

2022

31. Skeletal muscle and cardiac transcriptomics of a regionally endothermic fish, the Pacific bluefin tuna, Thunnus orientalis

Author

Adam Ciezarek, Luke Gardner, Vincent Savolainen, and Barbara Block

Subjects

Tuna, Endothermy, Atrium, Thermogenesis, Muscle, Calcium cycling, Biotechnology, TP248.13-248.65, Genetics, QH426-470

Abstract

Abstract Background The Pacific bluefin tuna (Thunnus orientalis) is a regionally endothermic fish that maintains temperatures in their swimming musculature, eyes, brain and viscera above that of the ambient water. Within their skeletal muscle, a thermal gradient exists, with deep muscles, close to the backbone, operating at elevated temperatures compared to superficial muscles near the skin. Their heart, by contrast, operates at ambient temperature, which in bluefin tunas can range widely. Cardiac function in tunas reduces in cold waters, yet the heart must continue to supply blood for metabolically demanding endothermic tissues. Physiological studies indicate Pacific bluefin tuna have an elevated cardiac capacity and increased cold-tolerance compared to warm-water tuna species, primarily enabled by increased capacity for sarcoplasmic reticulum calcium cycling within the cardiac muscles. Results Here, we compare tissue-specific gene-expression profiles of different cardiac and skeletal muscle tissues in Pacific bluefin tuna. There was little difference in the overall expression of calcium-cycling and cardiac contraction pathways between atrium and ventricle. However, expression of a key sarcoplasmic reticulum calcium-cycling gene, SERCA2b, which plays a key role maintaining intracellular calcium stores, was higher in atrium than ventricle. Expression of genes involved in aerobic metabolism and cardiac contraction were higher in the ventricle than atrium. The two morphologically distinct tissues that derive the ventricle, spongy and compact myocardium, had near-identical levels of gene expression. More genes had higher expression in the cool, superficial muscle than in the warm, deep muscle in both the aerobic red muscle (slow-twitch) and anaerobic white muscle (fast-twitch), suggesting thermal compensation. Conclusions We find evidence of widespread transcriptomic differences between the Pacific tuna ventricle and atrium, with potentially higher rates of calcium cycling in the atrium associated with the higher expression of SERCA2b compared to the ventricle. We find no evidence that genes associated with thermogenesis are upregulated in the deep, warm muscle compared to superficial, cool muscle. Heat generation may be enabled by by the high aerobic capacity of bluefin tuna red muscle.

Published

2020

32. On the Evolution of the Mammalian Brain

Author

Torday, John S and Miller, William B

Subjects

Biochemistry and Cell Biology, Biological Sciences, Neurosciences, Underpinning research, 1.1 Normal biological development and functioning, evolution, brain, entropy, lipids, endothermy, skin-brain, exaptation, self-organization, Physiology, Medical Physiology, Biochemistry and cell biology, Zoology

Abstract

Hobson and Friston have hypothesized that the brain must actively dissipate heat in order to process information (Hobson et al., 2014). This physiologic trait is functionally homologous with the first instantation of life formed by lipids suspended in water forming micelles- allowing the reduction in entropy (heat dissipation). This circumvents the Second Law of Thermodynamics permitting the transfer of information between living entities, enabling them to perpetually glean information from the environment, that is felt by many to correspond to evolution per se. The next evolutionary milestone was the advent of cholesterol, embedded in the cell membranes of primordial eukaryotes, facilitating metabolism, oxygenation and locomotion, the triadic basis for vertebrate evolution. Lipids were key to homeostatic regulation of calcium, forming calcium channels. Cell membrane cholesterol also fostered metazoan evolution by forming lipid rafts for receptor-mediated cell-cell signaling, the origin of the endocrine system. The eukaryotic cell membrane exapted to all complex physiologic traits, including the lung and brain, which are molecularly homologous through the function of neuregulin, mediating both lung development and myelinization of neurons. That cooption later exapted as endothermy during the water-land transition (Torday, 2015a), perhaps being the functional homolog for brain heat dissipation and conscious/mindful information processing. The skin and brain similarly share molecular homologies through the "skin-brain" hypothesis, giving insight to the cellular-molecular "arc" of consciousness from its unicellular origins to integrated physiology. This perspective on the evolution of the central nervous system clarifies self-organization, reconciling thermodynamic and informational definitions of the underlying biophysical mechanisms, thereby elucidating relations between the predictive capabilities of the brain and self-organizational processes.

Published

2016

33. Genomic basis of evolutionary adaptation in a warm-blooded fish

Author

Xin Wang, Meng Qu, Yali Liu, Ralf F. Schneider, Yue Song, Zelin Chen, Hao Zhang, Yanhong Zhang, Haiyan Yu, Suyu Zhang, Dongxu Li, Geng Qin, Shaobo Ma, Jia Zhong, Jianping Yin, Shuaishuai Liu, Guangyi Fan, Axel Meyer, Dazhi Wang, and Qiang Lin

Subjects

endothermy, opah, whole-genome sequencing, convergent evolution, thermogenesis, Science (General), Q1-390

Abstract

Few fishes have evolved elevated body temperatures compared with ambient temperatures, and only in opah (Lampris spp) is the entire body affected. To understand the molecular basis of endothermy, we analyzed the opah genome and identified 23 genes with convergent amino acid substitutions across fish, birds, and mammals, including slc8b1, which encodes the mitochondrial Na+/Ca2+ exchanger and is essential for heart function and metabolic heat production. Among endothermic fishes, 44 convergent genes with suggestive metabolic functions were identified, such as glrx3, encoding a crucial protein for hemoglobin maturation. Numerous genes involved in the production and retention of metabolic heat were also found to be under positive selection. Analyses of opah's unique inner-heat-producing pectoral muscle layer (PMI), an evolutionary key innovation, revealed that many proteins were co-opted from dorsal swimming muscles for thermogenesis and oxidative phosphorylation. Thus, the opah genome provides valuable resources and opportunities to uncover the genetic basis of thermal adaptations in fish. Public summary: • Endothermy has evolved multiple times in fishes (teleosts and chondrichthyans) • Opah genome explaining genetic changes in heat production and the sensory and immune system • Convergent evolution of genes in endothermic vertebrate lineages was investigated • Analyses of the pectoral muscle of opah revealed numerous highly expressed genes for thermogenesis

Published

2022

34. The origin of endothermy in synapsids and archosaurs and arms races in the Triassic.

Author

Benton, Michael J.

Abstract

Birds and mammals are key elements of modern ecosystems, and many biologists explain their great success by their endothermy, or warm-bloodedness. New palaeontological discoveries point to the origins of endothermy in the Triassic, and that birds (archosaurs) and mammals (synapsids) likely acquired endothermy in parallel. Here, a further case is made, that the emergence of endothermy in a stepwise manner began in the Late Permian but accelerated in the Early Triassic. The trigger was the profound destruction wrought by the Permian-Triassic mass extinction (PTME). In the oceans, this was the beginning of the Mesozoic Marine Revolution (MMR), and a similar revolution occurred on land, termed here the Triassic Terrestrial Revolution (TTR). Among tetrapods, both synapsids and archosaurs survived into the Triassic, but numbers were heavily depleted. However, the survivors were marked by the acquisition of endothermy, as shown by bone histology, isotopic analyses, and the acquisition of insulating pelage. Both groups before the PTME had been sprawlers; after the event they adopted parasagittal (erect) gait. The new posture and the new physiology enabled both groups to compete in their ecosystems at a faster rate than before the PTME. The new world of the Triassic was characterised by a fast-paced arms race between synapsids and archosauromorphs in which the latter, as both dinosaurs and pterosaurs, initially prevailed. [Display omitted] • Birds and mammals likely acquired endothermy (warm-bloodedness) at the same time • This time was the Early Triassic, as suggested by phylogenetic macroevolutionary studies of both archosaurs and synapsids • Life remodelled itself most significantly in the aftermath of the devastating end-Permian mass extinction • The switchover happened in parallel with a shift in posture from sprawling to parasagittal in both major lineages • Cynodonts and avemetatarsalian archosaurs engaged in arms races through the Triassic, as their metabolic rates speeded up [ABSTRACT FROM AUTHOR]

Published

2021

35. Pros and cons for the evidence of adaptive non-shivering thermogenesis in marsupials.

Author

Jastroch, Martin, Polymeropoulos, Elias T., and Gaudry, Michael J.

Subjects

*MARSUPIALS, *BODY temperature regulation, *BROWN adipose tissue, *UNCOUPLING proteins, *MITOCHONDRIAL proteins

Abstract

The thermogenic mechanisms supporting endothermy are still not fully understood in all major mammalian subgroups. In placental mammals, brown adipose tissue currently represents the most accepted source of adaptive non-shivering thermogenesis. Its mitochondrial protein UCP1 (uncoupling protein 1) catalyzes heat production, but the conservation of this mechanism is unclear in non-placental mammals and lost in some placentals. Here, we review the evidence for and against adaptive non-shivering thermogenesis in marsupials, which diverged from placentals about 120–160 million years ago. We critically discuss potential mechanisms that may be involved in the heat-generating process among marsupials. [ABSTRACT FROM AUTHOR]

Published

2021

36. Modelling the Efficacy of Febrile Heating in Infected Endotherms

Author

Gregory Lewis and Michael B. Bonsall

Subjects

fever, endothermy, coevolution, infection, immunity, Evolution, QH359-425, Ecology, QH540-549.5

Abstract

Fever is a response to infection characterised by an increase in body temperature. The adaptive value of this body temperature increase for endotherms is unclear, given the relatively small absolute temperature increases associated with endotherm fever, its substantial metabolic costs, and the plausibility for pathogens to adapt to higher temperatures. We consider three thermal mechanisms for fever's antimicrobial effect: (1) direct growth inhibition by elevating temperature above the pathogens optimal growth temperature; (2) further differentiating the host body from the wider environment; and (3) through increasing thermal instability of the pathogen environment. We assess these by modelling their effects pathogen on temperature dependent growth, finding thermal effects can vary from highly to minimally effective depending on pathogen species. We also find, depending on the specification of a simple physical model, intermittent heating can inhibit pathogen growth more effectively than continuous heating with an energy constraint.

Published

2021

37. Large‐scale evolution of body temperatures in land vertebrates.

Author

Moreira, Matthew O., Qu, Yan‐Fu, and Wiens, John J.

Subjects

BODY temperature, LAND surface temperature, VERTEBRATES, WARM-blooded animals, COLD-blooded animals, TETRAPODS

Abstract

Body temperature is a crucial variable in animals that affects nearly every aspect of their lives. Here we analyze for the first time largescale patterns in the evolution of body temperatures across terrestrial vertebrates (tetrapods: including amphibians, mammals, birds and other reptiles). Despite the traditional view that endotherms (birds and mammals) have higher body temperatures than ectotherms, we find they are not significantly different. However, rates of body‐temperature evolution are significantly different, with lower rates in endotherms than ectotherms, and the highest rates in amphibians. We find that body temperatures show strong phylogenetic signal and conservatism over 350 million years of evolutionary history in tetrapods, and some lineages appear to have retained similar body temperatures over time for hundreds of millions of years. Although body temperatures are often unrelated to climate in tetrapods, we find that body temperatures are significantly related to day‐night activity patterns. Specifically, body temperatures are generally higher in diurnal species than nocturnal species, both across ectotherms and, surprisingly, across endotherms also. Overall, our results suggest that body temperatures are significantly linked to phylogeny and diel‐activity patterns within and among tetrapod groups, rather than just climate and the endotherm‐ectotherm divide. [ABSTRACT FROM AUTHOR]

Published

2021

38. Life‐cycle complexity in helminths: What are the benefits?

Author

Benesh, Daniel P., Parker, Geoff, and Chubb, James C.

Subjects

*LONGEVITY, *PARASITES, *ADULTS, *TAPEWORMS, *WARM-blooded animals, *PREDATION, *HELMINTHS

Abstract

Parasitic worms (i.e., helminths) commonly infect multiple hosts in succession. With every transmission step, they risk not infecting the next host and thus dying before reproducing. Given this risk, what are the benefits of complex life cycles? Using a dataset for 973 species of trophically transmitted acanthocephalans, cestodes, and nematodes, we tested whether hosts at the start of a life cycle increase transmission and whether hosts at the end of a life cycle enable growth to larger, more fecund sizes. Helminths with longer life cycles, that is, more successive hosts, infected conspicuously smaller first hosts, slightly larger final hosts, and exploited trophic links with lower predator–prey mass ratios. Smaller first hosts likely facilitate transmission because of their higher abundance and because parasite propagules were the size of their normal food. Bigger definitive hosts likely increase fecundity because parasites grew larger in big hosts, particularly endotherms. Helminths with long life cycles attained larger adult sizes through later maturation, not faster growth. Our results indicate that complex helminth life cycles are ubiquitous because growth and reproduction are highest in large, endothermic hosts that are typically only accessible via small intermediate hosts, that is, the best hosts for growth and transmission are not the same. [ABSTRACT FROM AUTHOR]

Published

2021

39. Energetic constraints on mammalian distribution areas.

Subjects

*CALORIC expenditure, *BASAL metabolism, *AEROBIC capacity, *SPECIES distribution, *AEROBIC exercises, *MAINTENANCE costs, *COMPARATIVE method

Abstract

Energy is a universal resource essential for all life functions. The rate of transformation of energy into an organism, and the energetic investment into reproduction, determines population and ecological‐level processes.Several hypotheses predicted that the ecological expansion and size of the geographic distribution of a species are shaped by, among other factors, metabolic performance. However, how organismal energetic characteristics contribute to species geographic range size is poorly understood.With phylogenetic comparative methods whether energetic maintenance costs (basal metabolic rate, BMR), aerobic capacity (maximum exercise metabolic rate, VO2max), summit thermoregulation (summit metabolic rate, VO2sum) and the ability to sustain energy provisioning (daily energy expenditure, DEE) determine the distribution of mammalian species range sizes was tested.Both basal and maximum exercise metabolic rates (accounting for body mass), but not summit thermogenic metabolic rate, were positively associated with species range sizes. Furthermore, daily energy expenditure (accounting for body mass) was positively associated with species ranges. Body mass (accounting for energetic maintenance) was negatively related to range sizes.High aerobic exercise capacity, aiding mobility such as running and dispersal, and high sustained energy provisioning, aiding reproductive effort such as pregnancy, lactation and natal dispersal, can facilitate the establishment of large mammalian geographic ranges. Consequently, the pace of organismal physiological processes can shape important ecological and biodiversity patterns by setting limits to species' range sizes. [ABSTRACT FROM AUTHOR]

Published

2021

40. What We Talk About When We Talk About Evolution

Author

Torday, John S

Subjects

Lung, 1.1 Normal biological development and functioning, Underpinning research, endothermy, evolution, paracrine growth factor, parathyroid hormone-related protein, pituitary adrenal axis

Abstract

Currently, the biologic sciences are a Tower of Babel, having become so highly specialized that one discipline cannot effectively communicate with another. A mechanism for evolution that integrates development and physiologic homeostasis phylogenetically has been identified-cell-cell interactions. By reducing this process to ligand-receptor interactions and their intermediate down-stream signaling partners, it is possible, for example, to envision the functional homologies between such seemingly disparate structures and functions as the lung alveolus and kidney glomerulus, the skin and brain, or the skin and lung. For example, by showing the continuum of the lung phenotype for gas exchange at the cell-molecular level, being selected for increased surface area by augmenting lung surfactant production and function in lowering surface tension, we have determined an unprecedented structural-functional continuum from proximate to ultimate causation in evolution. It is maintained that tracing the changes in structure and function that have occurred over both the short-term history of the organism (as ontogeny), and the long-term history of the organism (as phylogeny), and how the mechanisms shared in common can account for both biologic stability and novelty, will provide the key to understanding the mechanisms of evolution. We need to better understand evolution from its unicellular origins as the Big Bang of biology.

Published

2015

41. The Genomes of Two Billfishes Provide Insights into the Evolution of Endothermy in Teleosts.

Author

Wu, Baosheng, Feng, Chenguang, Zhu, Chenglong, Xu, Wenjie, Yuan, Yuan, Hu, Mingliang, Yuan, Ke, Li, Yongxin, Ren, Yandong, Zhou, Yang, Jiang, Haifeng, Qiu, Qiang, Wang, Wen, He, Shunping, and Wang, Kun

Subjects

WARM-blooded animals, BODY temperature regulation, PROTEINS, BILLFISH fishing, OSTEICHTHYES

Abstract

Endothermy is a typical convergent phenomenon which has evolved independently at least eight times in vertebrates, and is of significant advantage to organisms in extending their niches. However, how vertebrates other than mammals or birds, especially teleosts, achieve endothermy has not previously been fully understood. In this study, we sequenced the genomes of two billfishes (swordfish and sailfish), members of a representative lineage of endothermic teleosts. Convergent amino acid replacements were observed in proteins related to heat production and the visual system in two endothermic teleost lineages, billfishes and tunas. The billfish-specific genetic innovations were found to be associated with heat exchange, thermoregulation, and the specialized morphology, including elongated bill, enlarged dorsal fin in sailfish and loss of the pelvic fin in swordfish. [ABSTRACT FROM AUTHOR]

Published

2021

42. Ancestral and developmental cold alter brown adipose tissue function and adult thermal acclimation in Peromyscus.

Author

Robertson, Cayleih E. and McClelland, Grant B.

Subjects

*BROWN adipose tissue, *ACCLIMATIZATION, *PHENOTYPIC plasticity, *TISSUE remodeling, *ADULTS

Abstract

Small, non-hibernating endotherms increase their thermogenic capacity to survive seasonal cold, through adult phenotypic flexibility. In mammals, this response is primarily driven by remodeling of brown adipose tissue (BAT), which matures postnatally in altricial species. In many regions, ambient temperatures can vary dramatically throughout the breeding season. We used second-generation lab-born Peromyscus leucopus, cold exposed during two critical developmental windows, to test the hypothesis that adult phenotypic flexibility to cold is influenced by rearing temperature. We found that cold exposure during the postnatal period (14 °C, birth to 30 days) accelerated BAT maturation and permanently remodeled this tissue. As adults, these mice had increased BAT activity and thermogenic capacity relative to controls. However, they also had a blunted acclimation response when subsequently cold exposed as adults (5 °C for 6 weeks). Mice born to cold-exposed mothers (14 °C, entire pregnancy) also showed limited capacity for flexibility as adults, demonstrating that maternal cold stress programs the offspring thermal acclimation response. In contrast, for P. maniculatus adapted to the cold high alpine, BAT maturation rate was unaffected by rearing temperature. However, both postnatal and prenatal cold exposure limited the thermal acclimation response in these cold specialists. Our results suggest a complex interaction between developmental and adult environment, influenced strongly by ancestry, drives thermogenic capacity in the wild. [ABSTRACT FROM AUTHOR]

Published

2021

43. Development of behavioral and physiological thermoregulatory mechanisms with body size in juvenile bigeye tuna Thunnus obesus.

Author

Hino, Haruhiko, Kitagawa, Takashi, Matsumoto, Takayuki, Aoki, Yoshinori, and Kimura, Shingo

Subjects

*BIGEYE tuna, *BODY size, *HEAT transfer coefficient, *ELECTRIC power consumption, *BODY temperature, *BOOK sales & prices

Abstract

Changes in the thermoregulatory mechanisms of juvenile bigeye tuna (Thunnus obesus) as body size increases were investigated by comparing associative (fish associated with floating objects) and characteristic (non‐associative) behaviors using archival tag data from 15 fish released in Japanese waters [49–72 cm fork length (FL) at release, 3–503 days]. The thermal excess (body temperature minus ambient temperature) during characteristic behavior was about 0.7–2.3°C higher than that during associative behavior in equally sized fish, and both increased with body size. Heat budget models indicated that the increases in the thermal excess of both behaviors could be attributed to decreases in the whole‐body heat transfer coefficient (λ) while descending. Thermoregulatory mechanisms appear to develop with body size by controlling λ during descents and ascents, especially in characteristic behavior (associative: 50 cm FL, 2.6‐fold; 95 cm FL, 6.4‐fold; characteristic: 55 cm FL, 5.5‐fold; 95 cm FL, 15.8‐fold). The λ increases while ascending to allow rapid body temperature recovery by absorbing the ambient heat in warmer, shallower water and is restricted for thermoconservation while descending to deeper, cooler water. The heat production results and calculated body temperatures for both behaviors suggest that associative behavior is the inactive state, so physiological thermoregulatory energy may be less necessary than during characteristic behavior. As body bulk λ decreased with body size, it appears that physiological thermoregulation, by controlling arterial blood flow and/or vasoconstriction, develops to adapt to deeper, offshore waters for better exploitation of prey, in turn supporting the increasing energy demands of larger fish. [ABSTRACT FROM AUTHOR]

Published

2021

44. Horizontal and Vertical Movement Patterns and Habitat Use of Juvenile Porbeagles (Lamna nasus) in the Western North Atlantic

Author

Gregory Skomal, Heather Marshall, Benjamin Galuardi, Lisa Natanson, Camrin D. Braun, and Diego Bernal

Subjects

porbeagle movements, diving behavior, Western North Atlantic Ocean, Gulf Stream, endothermy, Science, General. Including nature conservation, geographical distribution, QH1-199.5

Abstract

The porbeagle (Lamna nasus) is a large, highly migratory endothermic shark broadly distributed in the higher latitudes of the Atlantic, South Pacific, and Indian Oceans. In the North Atlantic, the porbeagle has a long history of fisheries exploitation and current assessments indicate that this stock is severely overfished. Although much is known of the life history of this species, there is little fisheries-independent information about habitat preferences and ecology. To examine migratory routes, vertical behavior, and environmental associations in the western North Atlantic, we deployed pop-up satellite archival transmitting tags on 20 porbeagles in late November, 2006. The sharks, ten males and ten females ranging from 128 to 154 cm fork length, were tagged and released from a commercial longline fishing vessel on the northwestern edge of Georges Bank, about 150 km east of Cape Cod, MA. The tags were programmed to release in March (n = 7), July (n = 7), and November (n = 6) of 2007, and 17 (85%) successfully reported. Based on known and derived geopositions, the porbeagles exhibited broad seasonally-dependent horizontal and vertical movements ranging from minimum linear distances of 937 to 3,310 km and from the surface to 1,300 m, respectively. All of the sharks remained in the western North Atlantic from the Gulf of Maine, the Scotian Shelf, on George's Bank, and in the deep, oceanic waters off the continental shelf along the edge of, and within, the Gulf Stream. In general, the population appears to be shelf-oriented during the summer and early fall with more expansive offshore radiation in the winter and spring. Although sharks moved through temperatures ranging from 2 to 26°C, the bulk of their time (97%) was spent in 6-20°C. In the summer months, most of the sharks were associated with the continental shelf moving between the surface and the bottom and remaining < 200 m deep. In the late fall and winter months, the porbeagles moved into pelagic habitat and exhibited two behavioral patterns linked with the thermal features of the Gulf Stream: “non-divers” (n = 7) largely remained at epipelagic depths and “divers” (n = 10) made frequent dives into and remained at mesopelagic depths (200–1000 m). These data demonstrate that juvenile porbeagles are physiologically capable of exploiting the cool temperate waters of the western North Atlantic as well as the mesopelagic depths of the Gulf Stream, possibly allowing exploitation of prey not available to other predators.

Published

2021

45. Reappraising the exteriorization of the mammalian testes through evolutionary physiology

Author

William B. Miller, Jr and John S. Torday

Subjects

endothermy, balanced ecological hypothesis, exteriorization of the testes, scrotum, gubernaculum, Biology (General), QH301-705.5

Abstract

A number of theories have been proposed to explain the exteriorization of the testicles in most mammalian species. None of these provide a consistent account for the wide variety of testicular locations found across the animal kingdom. It is proposed that testicular location is the result of coordinate action of testicular tissue ecologies to sustain preferential states of homeostatic equipoise throughout evolutionary development in response to the advent of endothermy.

Published

2019

46. The Origins of the Bird Brain: Multiple Pulses of Cerebral Expansion in Evolution

Author

Shimizu, Toru, Shinozuka, Kazutaka, Uysal, Ahmet K., Leilani Kellogg, S., Okano, Hideyuki, Series editor, Iriki, Atsushi, Series editor, Watanabe, Shigeru, editor, Hofman, Michel A, editor, and Shimizu, Toru, editor

Published

2017

47. Determinate growth is predominant and likely ancestral in squamate reptiles.

Author

Frýdlová, Petra, Mrzílková, Jana, Šeremeta, Martin, Křemen, Jan, Dudák, Jan, Žemlička, Jan, Minnich, Bernd, Kverková, Kristina, Němec, Pavel, Zach, Petr, and Frynta, Daniel

Subjects

*SQUAMATA, *GROWTH plate, *REPTILES, *WARM-blooded animals, *LIZARDS, *COLD-blooded animals, *TREE growth

Abstract

Body growth is typically thought to be indeterminate in ectothermic vertebrates. Indeed, until recently, this growth pattern was considered to be ubiquitous in ectotherms. Our recent observations of a complete growth plate cartilage (GPC) resorption, a reliable indicator of arrested skeletal growth, in many species of lizards clearly reject the ubiquity of indeterminate growth in reptiles and raise the question about the ancestral state of the growth pattern. Using X-ray micro-computed tomography (µCT), here we examined GPCs of long bones in three basally branching clades of squamate reptiles, namely in Gekkota, Scincoidea and Lacertoidea. A complete loss of GPC, indicating skeletal growth arrest, was the predominant finding. Using a dataset of 164 species representing all major clades of lizards and the tuataras, we traced the evolution of determinate growth on the phylogenetic tree of Lepidosauria. The reconstruction of character states suggests that determinate growth is ancestral for the squamate reptiles (Squamata) and remains common in the majority of lizard lineages, while extended (potentially indeterminate) adult growth evolved several times within squamates. Although traditionally associated with endotherms, determinate growth is coupled with ectothermy in this lineage. These findings combined with existing literature suggest that determinate growth predominates in both extant and extinct amniotes. [ABSTRACT FROM AUTHOR]

Published

2020

48. No evidence of homeostatic regulation of leaf temperature in Eucalyptus parramattensis trees: integration of CO2 flux and oxygen isotope methodologies.

Author

Drake, John E., Harwood, Richard, Vårhammar, Angelica, Barbour, Margaret M., Reich, Peter B., Barton, Craig V. M., and Tjoelker, Mark G.

Subjects

*LEAF temperature, *TEMPERATURE control, *OXYGEN isotopes, *EUCALYPTUS, *ATMOSPHERIC temperature, *VAPOR pressure

Abstract

Summary: Thermoregulation of leaf temperature (Tleaf) may foster metabolic homeostasis in plants, but the degree to which Tleaf is moderated, and under what environmental contexts, is a topic of debate. Isotopic studies inferred the temperature of photosynthetic carbon assimilation to be a constant value of c. 20°C; by contrast, leaf biophysical theory suggests a strong dependence of Tleaf on environmental drivers. Can this apparent disparity be reconciled?We continuously measured Tleaf and whole‐crown net CO2 uptake for Eucalyptus parramattensis trees growing in field conditions in whole‐tree chambers under ambient and +3°C warming conditions, and calculated assimilation‐weighted leaf temperature (TL‐AW) across 265 d, varying in air temperature (Tair) from −1 to 45°C. We compared these data to TL‐AW derived from wood cellulose δ18O.Tleaf exhibited substantial variation driven by Tair, light intensity, and vapor pressure deficit, and Tleaf was strongly linearly correlated with Tair with a slope of c. 1.0. TL‐AW values calculated from cellulose δ18O vs crown fluxes were remarkably consistent; both varied seasonally and in response to the warming treatment, tracking variation in Tair.The leaves studied here were nearly poikilothermic, with no evidence of thermoregulation of Tleaf towards a homeostatic value. Importantly, this work supports the use of cellulose δ18O to infer TL‐AW, but does not support the concept of strong homeothermic regulation of Tleaf See also the Commentary on this article by Cavaleri, 228: 1455–1457. [ABSTRACT FROM AUTHOR]

Published

2020

49. Key Steps in the Evolution of Mammalian Movement: A Prolegomenal Essay.

Author

Brownstone, Robert M.

Subjects

*SYMPATHETIC nervous system, *CARDIOVASCULAR system, *MUSCULOSKELETAL system, *SPINAL cord, *NERVOUS system

Abstract

• Several evolutionary steps led to the emergence of vertebrate movement needed for social behaviour. • Descending systems rely on diverse spinal cord neurons to produce a rich repertoire of movement syllables. • The notochord and ventricular zone led to this diversity of neuronal types. • The sympathetic nervous system provided the substrate for homeothermic endothermy. • Homeothermic endothermy is a necessary building block for power, speed, and endurance. Rich repertoires of movements underlie the complex social interactions of mammals. The building blocks, or syllables, of these movements are produced by spinal cord circuits that are comprised of diverse neuronal types that control musculoskeletal systems comprised of multi-segmented limbs. Together, these systems provide mammals with the evolutionary advantages of power, speed, and endurance. Here, I propose that the key steps in chordate evolution that led to these traits began with the development of the notochord and a proliferative ventricular zone (with associated Notch signalling). This step led to the production of diverse neuronal types that included the development of a sympathetic nervous system that could regulate the evolving cardiovascular system. And the sympathetic nervous system in turn led to the development of homeothermic endothermy, a requirement for motor systems to produce a combination of power, speed, and endurance. Furthermore, the evolution of the continuous structure of the spinal cord led not only to a structure fit for cartesian signalling molecules, but also to one with high processing power in which circuits for effecting movement syllables formed. These syllables are harnessed by higher regions of nervous systems to produce the complex movements required for interactions with others and with the surrounding environment. [ABSTRACT FROM AUTHOR]

Published

2020

50. Body temperature, heart rate, and activity patterns of two boreal homeotherms in winter: Homeostasis, allostasis, and ecological coexistence.

Author

Menzies, Allyson K., Studd, Emily K., Majchrzak, Yasmine N., Peers, Michael J. L., Boutin, Stan, Dantzer, Ben, Lane, Jeffrey E., McAdam, Andrew G., Humphries, Murray M., and White, Craig

Subjects

*BODY temperature, *HEART beat, *WARM-blooded animals, *TAMIASCIURUS, *HOMEOSTASIS, *COEXISTENCE of species, *TANTALUM

Abstract

Organisms survive environmental variation by combining homeostatic regulation of critical states with allostatic variation of other traits, and species differences in these responses can contribute to coexistence in temporally variable environments.In this paper, we simultaneously record variation in three functional traits—body temperature (Tb), heart rate and activity—in relation to three forms of environmental variation—air temperature (Ta), photoperiod and experimentally manipulated resource levels—in free‐ranging snowshoe hares and North American red squirrels to characterize distinctions in homeotherm responses to the extreme conditions of northern boreal winters.Hares and squirrels differed in the level and precision of Tb regulation, but also in the allostatic pathways necessary to maintain thermal homeostasis. Hares demonstrated a stronger metabolic pathway (through heart rate variation reflective of the thermogenesis), while squirrels demonstrated a stronger behavioural pathway (through activity variation that minimizes cold exposure).As intermediate‐sized, winter‐active homeotherms, hares and squirrels share many functional attributes, yet, through the integrated monitoring of multiple functional traits in response to shared environmental variation, our study reveals many pairwise species differences in homeostatic and allostatic traits, that both define and are defined by the natural history, functional niches and coexistence of sympatric species. A free Plain Language Summary can be found within the Supporting Information of this article. [ABSTRACT FROM AUTHOR]

Published

2020