Authors: Matthew D Hall, Ben L Phillips, Craig R White, and Dustin J. Marshall
Published in:Functional Ecology
Abstract
Exposure to a pathogen is predicted to lead to increased energy use as hosts attempt to activate a costly immune system and repair damaged tissue. To meet this demand, metabolic rates, which capture the rate at which a host can use, transform and expend energy, are expected to increase. Yet for many host–pathogen systems, metabolic rates after encountering a pathogen are just as likely to decrease as increase, suggesting that increased energy expenditure may not always be best for fighting infection.
Diverging metabolic trajectories have been previously attributed to the different pathways that specific pathogen classes, such as bacteria or viruses, induce in a host. Here, we test how the magnitude and direction of metabolic change following pathogen exposure might also depend on whether a host has cleared infection or is instead fighting to reduce pathogen burden, as well as interactions between host and pathogen genotypes of a single host–pathogen system.
Using a model system, Daphnia magna and its bacterial pathogen, we quantified changes in mass-independent metabolic rates over a 30-day period for multiple host and pathogen genotypes. We found that the metabolic trajectory of an exposed host diverged quickly during the infection process. For hosts that were exposed to a pathogen and resisted infection, their mass-independent metabolic rates remained suppressed long after exposure, leading to a sustained reduction in total energy use compared to unexposed animals. The reverse was true for hosts in which the pathogen was able to establish an infection.
Underlying these changes were differences in the energetic burden that each pathogen genotype imposed on its host, as well as changes in the way host genotype and the outcome of infection shaped underlying scaling relationships between host body mass and metabolic rates. Our results demonstrate how variation in an organism’s metabolic rate and overall energy use can arise from within a single host–pathogen encounter and depend on the likelihood of pathogen clearance, as well as the within-species genetic variability of both hosts and pathogens.
Hall MD, Phillips BL, White CR, Marshall DJ (2024) The hidden costs of resistance: Contrasting the energetics of successfully and unsuccessfully fighting infection. Functional EcologyPDFDOI
Published in:Philosophical Transactions of the Royal Society B: Biological Sciences
Abstract
As physiologists seek to better understand how and why metabolism varies, they have focused on how metabolic rate covaries with fitness—that is, selection.
Evolutionary biologists have developed a sophisticated framework for exploring selection, but there are particular challenges associated with estimating selection on metabolic rate owing to its allometric relationship with body mass. Most researchers estimate selection on mass and absolute metabolic rate; or selection on mass and mass-independent metabolic rate (MIMR)—the residuals generated from a nonlinear regression. These approaches are sometimes treated as synonymous: their coefficients are often interpreted in the same way.
Here, we show that these approaches are not equivalent because absolute metabolic rate and MIMR are different traits. We also show that it is difficult to make sound biological inferences about selection on absolute metabolic rate because its causal relationship with mass is enigmatic. By contrast, MIMR requires less-desirable statistical practices (i.e. residuals as a predictor), but provides clearer causal pathways. Moreover, we argue that estimates of selection on MIMR have more meaningful interpretations for physiologists interested in the drivers of variation in metabolic allometry.
Cameron H, Marshall D (2024) Estimating the relationship between fitness and metabolic rate: which rate should we use? Philosophical Transactions of the Royal Society B: Biological SciencesPDFDOI
Animals vary dramatically in size and biologists have long been fascinated with how other traits change along with size. Metabolism is one of those traits. Metabolic rates increase with size but not proportionally, and the struggle to describe and understand this non-proportional or allometric scaling relationship has a long history.
In their review of the subject, Craig White and Dustin Marshall initially return to the 1830s where physical properties that governed heat exchange were thought to dictate how metabolic rates scale with size. By the 1900s scientists had moved to disputing the exact nature of the ‘scaling’ relationship between size and metabolism.
After more than a century of study, the most reliable finding is that metabolism almost always scales hypo-allometrically with body mass, that is: metabolism increases with size but at a less than 1:1 ratio. A scaling exponent less than 1. So yes, elephants have faster metabolic rates than mice but not as much as you might expect — as body size increases, relative energy use decreases.
More recently, scientists have focused not only on how — but also why — does metabolism scale with body size? Debating this question has resulted in two polarised schools of thought.
The first, which includes Sarrus and Rameaux’s 1830s prediction around heat exchange, is that physical properties constrain the metabolic rate. So, the surface area of an organism can constrain metabolism through regulating heat dissipation, or the network of vessels delivering (usually) oxygen (e.g. blood vessels, trachea or gills), dictates the scaling of metabolic rate through physical constraints to the rate at which resources can be delivered.
The second school of thought takes an evolutionary approach where life history optimisation considers the combination of traits that maximises fitness. Craig and Dustin align with this philosophy. Their recent publication in Science proposed a life history optimisation model which predicts that animals most successful at reproducing are those that exhibit precisely the kind of disproportionate scaling of metabolism with size that we see in real life. And for Craig and Dustin, their work highlights a vital issue — the strong connection between metabolic traits and fitness components: changing one changes them all.
Craig and Dustin used a research weaving approach to understand the connections between the different theories. They identified the core ‘seed’ publications for each theory and then looked at papers that cited these seed publications. A paper was coded to a theory if it cited the seed papers for that theory and no others. Panels A to D are word clouds associated with papers citing each theory and E show the citation network for the papers, coloured by theory base.
To demonstrate how polarised these two approaches have become, Craig and Dustin took a ‘research weaving’ approach. They found that papers based on the latest theories around the importance of physical constraints in metabolic scaling with body mass, (Dynamic Equilibrium Theory and Metabolic Theory of Ecology) did not cite or consider the other main theory base (Life History Optimisation and Pace of Life theory) and vice versa.
So where to next? Craig and Dustin think that constraint driven models would benefit from including optimisation and that examining how optimisation changes in the face of absolute constraints (e.g. organisms cannot be infinitely large or small or quick, and metabolic rates cannot be zero or infinitely high) would add some necessary limits to their own work.
Importantly they also provide some examples of how we can test these theories. They focus on the long-standing traditions of quantitative genetics to simplify conceptual arguments about how metabolic rate (co)varies with other traits and fitness and predict its evolution.
For Craig and Dustin, the crux of changing to a more pluralistic approach based on life history optimisation is that we may better understand how metabolic rate evolves in response to global change or anthropogenic pressures.
Authors: Dustin J Marshall, Hayley E Cameron, and Michel Loreau
Published in:The ISME (International Society for Microbial Ecology) Journal
Introduction
In their simplest form, the dynamics of populations are described in terms of two parameters: r, the intrinsic rate of increase; and K, the carrying capacity of the population. These two parameters are fundamental to population ecology and have a long history of empirical and theoretical study. From an evolutionary perspective, r and K were used to define and describe different modes of life: r-strategists were thought to have fast population growth rates at the expense of poor competitive abilities; K-strategists were thought to have slow-growing populations but be superior competitors, or at least more efficient with regards to resources.
These concepts have strongly influenced microbial ecologists and evolutionary biologists — r and K are often expected to trade off against each other across genotypes, strains or species. Since then, the classification of r– and K-strategists has been adapted by microbiologists to describe copiotrophic and oligotrophic species of microorganisms, respectively.
The idea that it is difficult to have both fast growth and be efficient in the use of resources has intuitive appeal: multiple mechanistic models attempt to explain how and why we might observe trade-offs between r and K. However, empirical studies struggle to detect trade-offs between r and K at multiple levels of biological organisation and instead sometimes even detect ‘trade-ups’ where r and K positively covary. Even within the same microbial strains, different r-K relationships can be observed depending on environmental quality. Similarly, comparisons across species fail to reveal simple oligotrophy and copiotrophy (or r-K strategist) dichotomies — instead species often fall on a continuum between these two extremes. In fact, expectations about how r and K covary with each other are based on an unfortunate quirk of scientific fate…
Marshall DJ, Cameron HE, Loreau M (2023) Relationships between intrinsic population growth rate, carrying capacity and metabolism in microbial populations. The ISME Journal PDFDOI
Most explanations for the relationship between body size and metabolism invoke physical constraints; such explanations are evolutionarily inert, limiting their predictive capacity. Contemporary approaches to metabolic rate and life history lack the pluralism of foundational work.
Here, we call for reforging of the lost links between optimization approaches and physiology.
White CR, Marshall DJ (2023) How and why does metabolism scale with body mass? PhysiologyPDFDOI
As this year’s winner of the Mike Cullen Research Fellow Award, Lesley Alton was awarded $5000 in research funds for her publication with Vanessa Kellerman that appeared in Nature Climate Change in 2023.
Professor Mike Cullen was Chair of Zoology at Monash from 1976 to 1992. He was a passionate advocate for early career researchers and also instrumental in bringing a more rigorous and quantitative approach to the behavioural sciences. The awards committee felt that Lesley and Vanessa’s publication was strongly aligned with Mike Cullen’s values.
But of course, science doesn’t just happen overnight and, in the Mike Cullen Lecture, Lesley detailed the trajectory of her research interests and how they led her to this point.
Lesley started her PhD at the University of Queensland in 2007 just after the first global assessment of amphibians had taken place. The assessment confirmed a global decline in amphibians including from seemingly pristine habitats. One of the competing hypotheses for amphibian declines was increased exposure to UV-B radiation associated with human-induced stratospheric ozone depletion. Lesley already knew that UV-B could have adverse effects on amphibian development when she started her PhD, but in nature, animals face many challenges, and so Lesley wanted to know if other sources of environmental stress interact with UV-B to have compounding negative effects on amphibians.
Lesley was not surprised to find that UV-B decreased survival in tadpoles but she was surprised to find that exposure to UV-B in combination with predatory cues decreased tadpole survival even further. She wondered if simultaneous exposure to these two stressors carried a greater metabolic cost than exposure to either of these stressors in isolation. By studying both the metabolic and behavioural responses of tadpoles to these stressors, Lesley found evidence that being exposed to UV-B is more energetically costly for tadpoles when they live with predators: tadpoles exposed to both stressors were less active, yet their metabolic rates remained elevated suggesting they were under more physiological stress than those exposed only to UV-B.
Lesley’s interests in the effects of UV-B continued when she took up her first postdoctoral position at Monash University, but this time she was interested in how it might affect mosquitoes. With UV-B predicted to increase in the tropics by the end of the century, Lesley wondered how this might affect the ability of mosquitoes to transmit pathogens like dengue virus, which is a growing threat to human populations living in tropical and subtropical regions. To study the effects of UV-B on mosquitoes, Lesley exposed developing mosquito larvae to very low doses of UV-B every day to determine if early-life exposure to UV-B could have long lasting effects on adult immune function and fitness. Worryingly, Lesley found that a UV-B dose that is 10–30 lower than what is currently observed in the tropics made female mosquitoes much more likely to become infected with dengue virus, but it also reduced their survival and fecundity – an unexpected bonus for tropical regions?
Lesley found that exposure to UVBR during a mosquitos development resulted in slower development, higher dengue infection but lower fecundity and higher mortality.
In addition to her work on UV-B, Lesley also developed an interest in the effect of temperature on the metabolic rates of cold-blooded animals (ectotherms), which rely on the thermal conditions of their environment to regulate their body temperature. This interest began while working as a research assistant at the University of Queensland when she received a Journal of Experimental Biology Travelling Award to visit a lab group in the USA. This group were looking at the effects of temperature on the evolution of traits in fruit flies. So, another change of model species, but the trip allowed Lesley to use her expertise in measuring metabolic rates to test the century-old Metabolic Cold Adaptation Hypothesis. This hypothesis predicts that animals evolved at cold temperatures will have higher metabolic rates than those evolved at hot temperatures when measured together at the same temperature. This counter-intuitive effect of temperature on the evolution of metabolic rate is predicted to arise as a consequence of natural selection counteracting the slowing down of metabolic rate that occurs at colder temperatures by favouring those individuals with higher metabolic rates. However, because patterns consistent with the Metabolic Cold Adaptation Hypothesis are not always evident in nature, the hypothesis remains highly controversial.
By measuring the metabolic rates of flies that had evolved experimentally in the lab at different temperatures, Lesley conducted a robust test of the Metabolic Cold Adaptation Hypothesis, but did not find support for the hypothesis. Lesley is now investigating whether the Metabolic Cold Adaptation Hypothesis is borne out if flies evolve at different temperatures under conditions where food is more limited, a scenario that more accurately reflects nature.
We will have to wait and see whether temperature and nutrition interact to shape the evolution of metabolic rate in fruit flies. Lesley has also examined whether environmental factors influence the capacity of ectotherms to respond to climate warming through acclimation which, unlike evolution, occurs within an animal’s lifetime. While ectotherms are expected to have higher energy demands in a warmer world, many ectotherms can acclimate to higher temperatures by reducing the thermal sensitivity of their metabolic rates to offset these energy requirements to some extent. However, Lesley and Vanessa’s research in fruit flies has shown that nutritionally poor diets and species interactions can erode the energetic benefits of thermal acclimation.
Lesley and Vanessa reared the larvae of three Drosophila species in single-species or two-species cultures with limited food to promote competition.
A more in-depth summary of the award-winning publication on the effect of species interactions on the metabolic costs of climate warming demonstrates that to improve our understanding of the threat of climate warming to species we must study animal responses to temperature in combination with other environmental stressors.
After adult flies emerged from our cultures, the team measured the metabolic rate and activity of nearly 400 adult female flies using a multi-channel flow-through respirometry system and Drosophila activity monitors.
Yes, external fertilisers are bigger than internal fertilisers and probably quite a bit bigger. A recent study by George Jarvis and Dustin Marshall has found that external fertilisers were 11 times larger than internal fertilisers in annelids, 5 times larger in echinoderms and 4.5 times in molluscs.
External fertilisers were bigger than internal fertilisers in each of the three phyla that George and Dustin looked at.
We know that body size is a driver of many patterns we see in biology. Knowing the association between body size and fertilisation mode means we may be able to predict much of a species life history and ecology from fertilisation mode alone. For example, within a group arising from a common ancestor we would expect a species with external fertilisation (and larger body size) to also have a lower population growth rate, lower carrying capacity and higher fecundity than a closely related internal fertiliser.
Internal fertilisation is an evolutionary innovation that has happened frequently and independently in snails, frogs, fishes and a host of other organisms. For internal fertilisers, fertilisation is relatively assured once mating has occurred, but there are still challenges. Competition between both sexes to copulate can be fierce and then sperm must compete in a race to the egg. Meanwhile external fertilisers can be lucky to achieve fertilisation at all with too few sperm reaching eggs (sperm limitation) or too many (polyspermy), severely reducing the chance of a successful fertilisation.
Because of these fertilisation constraints it is perhaps not surprising that we see other characteristics that vary alongside fertilisation mode. For example, in internal fertilisers males have smaller ejaculates, larger (perhaps more competitive sperm) and relatively small testes compared to external fertilisers.
While theory predicts that external fertilisers should be bigger than internal fertilisers this is difficult to test because we need to separate fertilisation mode and body size from other traits that vary alongside body size. So, in fish for example, most species that are external fertilisers are also egg laying, while many internal fertilisers bear live young. This makes it difficult to separate fertilisation mode and reproductive mode as they both change with body size.
PhD student George Jarvis and his supervisor Dustin Marshall have found a way to test the prediction that body size will vary with fertilisation mode. They have focused on marine invertebrates where internal fertilisation has evolved independently of reproductive mode many times, which allows them to access a ‘cleaner’ test of the relationship between body size and fertilisation mode.
George and Dustin compiled data on adult size, fertilisation mode and latitude for 1232 species of marine invertebrates across three phyla (annelids, echinoderms and molluscs). They analysed the data while accounting for how closely related the species were and the influence of a shared evolutionary history on patterns in body size − aphylogenetically-controlled analysis.
George and Dustin note that the patterns they observed are consistent with theory but from this type of correlative data they can’t conclude that body size drives fertilisation mode or vice versa. But they do speculate that a reduction in body size precedes the evolution of internal fertilisation. They think that the sequence of events proposed by evolutionary biologist Dr Jonathan Henshaw and colleagues in 2014 is likely correct. Henshaw et al. proposed that:
a reduction in body size results in smaller testes (and thus, lower sperm production), leading to sperm limitation
sperm limitation favours the production of larger eggs, which are larger targets for sperm
larger eggs (and thus, fewer of them) favours the retention of eggs to increase fertilisation success and egg survival
egg retention favours the development of anatomy and sperm traits required for internal fertilisation.
George and Dustin remain open to other possibilities but, in the meantime, they emphasise that the relationship between fertilisation mode and body size may be more fundamental and widespread than anticipated.
George and Dustin compiled data on the relatedness of species so they could account for that in their analysis. In this figure successive branches of the phylogenetic tree indicate species’ becoming less related. At the end of each branch a dot indicates fertilisation mode for that species and the black bar is an estimate of adult weight.
The evolution of internal fertilization has occurred repeatedly and independently across the tree of life. As it has evolved, internal fertilization has reshaped sexual selection and the covariances among sexual traits, such as testes size, and gamete traits. But it is unclear whether fertilization mode also shows evolutionary associations with traits other than primary sex traits. Theory predicts that fertilization mode and body size should covary, but formal tests with phylogenetic control are lacking.
We used a phylogenetically controlled approach to test the covariance between fertilization mode and adult body size (while accounting for latitude, offspring size, and offspring developmental mode) among 1,232 species of marine invertebrates from three phyla.
Within all phyla, external fertilizers are consistently larger than internal fertilizers: the consequences of fertilization mode extend to traits that are only indirectly related to reproduction.
We suspect that other traits may also coevolve with fertilization mode in ways that remain unexplored.
Jarvis GC, Marshall DJ (2023) Fertilization mode covaries with body size. The American NaturalistPDFDOI
For those that have been paying attention, you will be aware of our recent post on copepod evolution in high food and low food regimes. Despite the ongoing lockdowns, Alex Blake returned to the lab to follow individuals in a third generation of ‘common gardens’ throughout their whole life history. He measured growth, survival, probability of egg production, clutch size and egg size across the entire lifespan of individuals and used that data to compile population models.
Alongside his supervisor from Oxford University, Professor Tim Coulson, Alex wanted to know how food supply would affect population measures such as population growth rates, population size, age structure and size structure within populations. Alex and Tim compiled population models called Integral Projection Models; a mathematical modelling technique that essentially combines regression models of how traits change across the lifespan of individuals.
Copepods were subject to around 30 generations of evolution in high food or low food treatments. They were then put into ‘common gardens’. This piece summarises the intensive measurements of individuals throughout their life cycle after three generations in a common environment.
As with Alex’s previous work they did find differences between the food regimes. Copepods cultured in high food environments grew slightly faster to a smaller adult size, reached peak egg production younger and produced smaller eggs compared to copepods from low food environments. The high food copepods were also longer lived and had shorter generation times.
But Alex and Tim found these discrepancies didn’t translate to differences at the population level. Population growth rates, and age and size distributions within populations are projected to be similar at the different food supply regimes.
This is potentially good news for marine food webs; ocean productivity is expected to decline with climate change but Alex And Tim’s work suggests that even under lower food supply copepods will be able to evolve to deal with these harsher environments. But there could be costs. Changes in body size and reproductive outputs may have knock on effects for copepod consumers. Fish fry in particular, have been shown to be meticulous about the size of copepods they eat.
Alex and Tim emphasise that there is more work to be done. They were unable to untangle the effects of food supply from the effects of density; crowded environments could impact copepod life histories in a number of ways separate to the effects of food. They also suggest future work looks at whether life history evolution to food regimes is actually adaptive and not simply a result of non-adaptive forces such as drift. Reciprocal transplant experiments are the gold standard test for this question and Alex and Tim are keen to see them implemented.
Many of us are familiar with the idea that a bit of healthy competition can improve performance but can it affect metabolic rates, size and growth rates? Giulia Ghedini and Dustin Marshall asked this question for a single-celled alga and found that competition selects for smaller and more energy efficient cells.
Giulia and Dustin wanted to know whether predictions from the Metabolic theory of Ecology would hold true. Metabolic theory looks at the relationship between size and metabolic rate (rate of energy use) of individuals and makes predictions about population growth rates, maximum population size and maximum population biomass.
To test theoretical predictions Giulia and Dustin evolved populations of the green alga Dunaliella tertiolecta for 70 generations in three environments. They grew Dunaliella either on its own (no competition), with more Dunaliella(intraspecific competition) or with three other species of algae (interspecific competition). The focal populations of Dunaliella were inside dialysis bags so that they were physically isolated but still experienced changes to nutrient and light availability brought about by competition with other algae present outside the bags.
The experimental design
At 35 and 70 generations subsamples of the focal populations were moved into the same environment for several generations – a ‘common garden’. This allows researchers to distinguish between short term or ‘plastic’ responses to an environment from persistent ‘evolved’ changes.
Giulia and Dustin found that after 35 generations of evolution, cells that had evolved in the presence of competitors were smaller, reached greater population densities but got there more slowly (population growth rates were slower) than cells evolved without competitors. But after 70 generations, cells evolved in competitive environments had the same rates of population growth as cells evolved on their own and yet still managed to reach the same high maximum population densities.
Changes in the way cells were able to capture (photosynthesis) and use (respiration) energy in two different environments. When resources were abundant cells evolved in a competitive environment were able to gain and use resources more efficiently and when resources were scarce those same cells were better able to downregulate their energy use.
The evolution of greater metabolic flexibility appeared to be the key to enable cells grown in a competitive environment to reach these high population growth rates and densities. By measuring photosynthesis and respiration at two time points, (when cells were low in number versus when cell numbers were very high), Giulia and Dustin could see that when resources are abundant, competition-evolved cells increase metabolic rates more than cells evolved without competition. And the reverse was true; when resources are scarce, competition-evolved cells are able to downregulate energy-capture and use, better than cells evolved without competition.
The evolution of enhanced metabolic flexibility was not anticipated by any theory and Giulia and Dustin are keen to see further studies testing if competition drives metabolic plasticity in other systems.
Centre for Geometric Biology 