Your search keyword '"Tobias E. Hector"' showing total 9 results

1. Thermal limits in the face of infectious disease: How important are pathogens?

Author

Carla M. Sgrò, Matthew D. Hall, and Tobias E. Hector

Subjects

Global and Planetary Change, Ecology, Host (biology), Transmission (medicine), Ecology (disciplines), Vulnerability, Outbreak, Disease, Biology, Communicable Diseases, Infectious disease (medical specialty), Humans, Environmental Chemistry, General Environmental Science

Abstract

The frequency and severity of both extreme thermal events and disease outbreaks are predicted to continue to shift as a consequence of global change. As a result, species persistence will likely be increasingly dependent on the interaction between thermal stress and pathogen exposure. Missing from the intersection between studies of infectious disease and thermal ecology, however, is the capacity for pathogen exposure to directly disrupt a host's ability to cope with thermal stress. Common sources of variation in host thermal performance, which are likely to interact with infection, are also often unaccounted for when assessing either the vulnerability of species or the potential for disease spread during extreme thermal events. Here, we describe how infection can directly alter host thermal limits, to a degree that exceeds the level of variation commonly seen across species large geographic distributions and that equals the detrimental impact of other ecologically relevant stressors. We then discuss various sources of heterogeneity within and between populations that are likely to be important in mediating the impact that infection has on variation in host thermal limits. In doing so we highlight how infection is a widespread and important source of variation in host thermal performance, which will have implications for both the persistence and vulnerability of species and the dynamics and transmission of disease in a more thermally extreme world.

Published

2021

2. Thermal acclimation to warmer temperatures can protect host populations from both further heat stress and the potential invasion of pathogens

Author

Tobias E. Hector, Marta S. Shocket, Carla M. Sgrò, and Matthew D. Hall

Abstract

Phenotypic plasticity in response to shifts in temperature, known as thermal acclimation, is an essential component of the ability of a species to cope with environmental change. Not only does this process potentially improve an individual’s thermal tolerance, it will also act simultaneously on various fitness related traits that determine whether a population increases or decreases in size. In light of global change, thermal acclimation therefore has consequences for population persistence that extend beyond simply coping with heat stress. This particularly important when we consider the additional threat of parasitism associated with global change, as the ability of a pathogen to invade a host population depends on both its capacity to proliferate within a host and spread between hosts, and thus the supply of new susceptible hosts in a population. Here, we use the host Daphnia magna and its bacterial pathogen Pasteuria ramosa to investigate how thermal acclimation may impact various aspects of host and pathogen performance at the scale of both an individual and the population. We independently test the effect of maternal thermal acclimation and direct thermal acclimation on host thermal tolerance, measured as knockdown times, as well as host fecundity and lifespan, and pathogen infection success and spore production. We find that direct thermal acclimation enhances host thermal tolerance and intrinsic rates of population growth, despite a decline observed for host fecundity and lifespan. Pathogens, on the other hand, faired consistently worse at warmer temperatures at the within-host scale, and also in their potential to invade a host population. Our results suggest that hosts could benefit more from warming than their pathogens, but highlight that considering both within- and between-host thermal performance, including thermal tolerance and fitness traits, is needed to fully appreciate how increasing thermal variability will impact host and pathogen populations.

Published

2022

3. Pathogen exposure reduces sexual dimorphism in a host’s upper thermal limits

Author

Carla M. Sgrò, Tobias E. Hector, Matthew Hall, and Tess Laidlaw

Subjects

0106 biological sciences, sex differences, static heat stress, aquatic ectotherm, Offspring, Population, Daphnia magna, Zoology, Biology, 010603 evolutionary biology, 01 natural sciences, Daphnia, thermal tolerance, 03 medical and health sciences, host–parasite interactions, Population growth, education, Parental investment, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Nature and Landscape Conservation, Original Research, 0303 health sciences, education.field_of_study, Ecology, Host (biology), Stressor, biology.organism_classification, Sexual dimorphism, Pasteuria ramosa, population persistence

Abstract

The climate is warming at an unprecedented rate, pushing many species toward and beyond the upper temperatures at which they can survive. Global change is also leading to dramatic shifts in the distribution of pathogens. As a result, upper thermal limits and susceptibility to infection should be key determinants of whether populations continue to persist, or instead go extinct. Within a population, however, individuals vary in both their resistance to both heat stress and infection, and their contributions to vital growth rates. No more so is this true than for males and females. Each sex often varies in their response to pathogen exposure, thermal tolerances, and particularly their influence on population growth, owing to the higher parental investment that females typically make in their offspring. To date, the interplay between host sex, infection, and upper thermal limits has been neglected. Here, we explore the response of male and female Daphnia to bacterial infection and static heat stress. We find that female Daphnia, when uninfected, are much more resistant to static heat stress than males, but that infection negates any advantage that females are afforded. We discuss how the capacity of a population to cope with multiple stressors may be underestimated unless both sexes are considered simultaneously., Within a population, individuals vary in both their resistance to both heat stress and infection, and their contributions to vital growth rates. No more so is this true than for males and females. Each sex often varies in their response to pathogen exposure, upper thermal limits, and particularly their influence on population growth. We find that females, when uninfected, are much more resistant to static heat stress than males, but that infection negates any advantage that females are afforded.

Published

2020

4. The influence of immune activation on thermal tolerance along a latitudinal cline

Author

Carla M. Sgrò, Tobias E. Hector, and Matthew Hall

Subjects

Thermotolerance, 0106 biological sciences, 0301 basic medicine, education.field_of_study, Host (biology), Climate, Population, Australia, Cline (biology), Biology, 010603 evolutionary biology, 01 natural sciences, Cell biology, Fight-or-flight response, Geographic distribution, 03 medical and health sciences, Drosophila melanogaster, 030104 developmental biology, Immune system, Animals, Female, education, Ecology, Evolution, Behavior and Systematics, Local adaptation, Immune activation

Abstract

Global change is shifting both temperature patterns and the geographic distribution of pathogens, and infection has already been shown to substantially reduce host thermal performance, potentially placing populations at greater risk that previously thought. But what about individuals that are able to successfully clear an infection? Whilst the direct damage a pathogen causes will likely lead to reductions in host's thermal tolerance, the response to infection often shares many underlying pathways with the general stress response, potentially acting as a buffer against subsequent thermal stress. Here, by exposing Drosophila melanogaster to heat-killed bacterial pathogens, we investigate how activation of a host's immune system can modify any response to both heat and cold temperature stress. In a single focal population, we find that immune activation can improve a host's knockdown times during heat shock, potentially offsetting some of the damage that would subsequently arise as an infection progresses. Conversely, immune activation had a detrimental effect on CTmax and did not influence lower thermal tolerance as measured by chill-coma recovery time. However, we also find that the influence of immune activation on heat knockdown times is not generalizable across an entire cline of locally adapted populations. Instead, immune activation led to signals of local adaptation to temperature being lost, erasing the previous advantage that populations in warmer regions had when challenged with heat stress. Our results suggest that activation of the immune system may help buffer individuals against the detrimental impact of infection on thermal tolerance; however, any response will be population specific and potentially not easily predicted across larger geographic scales, and dependent on the form of thermal stress faced by a host.

Published

2020

5. Temperature and pathogen exposure act independently to drive host phenotypic trajectories

Author

Matthew Hall, Carla M. Sgrò, and Tobias E. Hector

Subjects

0106 biological sciences, phenotypic trajectory, infectious disease, Daphnia magna, Population, medicine.disease_cause, 010603 evolutionary biology, 01 natural sciences, 03 medical and health sciences, stress, medicine, Animals, education, Pathogen, Pace of life, Research Articles, 030304 developmental biology, Genetics, 0303 health sciences, education.field_of_study, biology, Host (biology), life-history, Pasteuria ramosa, Temperature, Global Change Biology, biology.organism_classification, Fecundity, Agricultural and Biological Sciences (miscellaneous), Phenotype, Pasteuria, Daphnia, Host-Pathogen Interactions, General Agricultural and Biological Sciences, pathogen

Abstract

Natural populations are experiencing an increase in the occurrence of both thermal stress and disease outbreaks. How these two common stressors interact to determine host phenotypic shifts will be important for population persistence, yet a myriad of different traits and pathways are a target of both stressors, making generalizable predictions difficult to obtain. Here, using the host Daphnia magna and its bacterial pathogen Pasteuria ramosa , we tested how temperature and pathogen exposure interact to drive shifts in multivariate host phenotypes. We found that these two stressors acted mostly independently to shape host phenotypic trajectories, with temperature driving a faster pace of life by favouring early development and increased intrinsic population growth rates, while pathogen exposure impacted reproductive potential through reductions in lifetime fecundity. Studies focussed on extreme thermal stress are increasingly showing how pathogen exposure can severely hamper the thermal tolerance of a host. However, our results suggest that under milder thermal stress, and in terms of life-history traits, increases in temperature might not exacerbate the impact of pathogen exposure on host performance, and vice versa.

Published

2021

6. Author response for 'The influence of immune activation on thermal tolerance along a latitudinal cline'

Author

null Tobias E. Hector, null Carla M. Sgrò, and null Matthew D. Hall

Published

2020

7. Author response for 'The influence of immune activation on thermal tolerance along a latitudinal cline'

Author

Carla M. Sgrò, Tobias E. Hector, and Matthew Hall

Subjects

Evolutionary biology, Biology, Cline (hydrology), Immune activation

Published

2020

8. Pathogen exposure disrupts an organism's ability to cope with thermal stress

Author

Carla M. Sgrò, Matthew Hall, and Tobias E. Hector

Subjects

0106 biological sciences, 010504 meteorology & atmospheric sciences, Genotype, Acclimatization, Climate Change, Population, Biology, medicine.disease_cause, 010603 evolutionary biology, 01 natural sciences, medicine, Environmental Chemistry, Animals, Genetic variability, education, Pathogen, Organism, Coevolution, 0105 earth and related environmental sciences, General Environmental Science, Global and Planetary Change, education.field_of_study, Ecology, Obligate, Pasteuria ramosa, Pasteuria, Daphnia

Abstract

As a result of global climate change, species are experiencing an escalation in the severity and regularity of extreme thermal events. With patterns of disease distribution and transmission predicted to undergo considerable shifts in the coming years, the interplay between temperature and pathogen exposure will likely determine the capacity of a population to persist under the dual threat of global change and infectious disease. In this study, we investigated how exposure to a pathogen affects an individual's ability to cope with extreme temperatures. Using experimental infections of Daphnia magna with its obligate bacterial pathogen Pasteuria ramosa, we measured upper thermal limits of multiple host and pathogen genotype combinations across the dynamic process of infection and under various forms (static and ramping) of thermal stress. We find that pathogens substantially limit the thermal tolerance of their host, with the reduction in upper thermal limits on par with the breadth of variation seen across similar species entire geographical ranges. The precise magnitude of any reduction, however, was specific to the host and pathogen genotype combination. In addition, as thermal ramping rate slowed, upper thermal limits of both healthy and infected individuals were reduced. Our results suggest that the capacity of a population to evolve new thermal limits, when also faced with the threat of infection, will depend not only on a host's genetic variability in warmer environments, but also on the frequency of host and pathogen genotypes. We suggest that pathogen-induced alterations of host thermal performance should be taken into account when assessing the resilience of any population and its potential for adaptation to global change.

Published

2019

9. Digest: Little evidence exists for a virulence‐transmission trade‐off*

Author

Tobias E. Hector and Isobel Booksmythe

Subjects

0106 biological sciences, 0301 basic medicine, Transmission rate, Virulence, Biology, Trade-off, 010603 evolutionary biology, 01 natural sciences, 03 medical and health sciences, 030104 developmental biology, Evolutionary biology, Infectious disease (medical specialty), Genetics, General Agricultural and Biological Sciences, Empirical evidence, Pathogen, Ecology, Evolution, Behavior and Systematics

Abstract

Research predicting the impact and spread of infectious disease has been heavily influenced by the idea of an evolutionary trade-off between a pathogen's virulence and its transmission rate. In a meta-analysis of the key underlying relationships, Acevedo et al. (2019) highlight the surprising lack of empirical evidence for this influential hypothesis.

Published

2019