Abstract
Specialist and generalist pathogens may exert different costs on their hosts; thereby altering the way hosts cope with environmental variation. We examined how pathogen-challenge alters the environmental conditions that maximize host performance by simultaneously varying temperature and nutrition (protein to carbohydrate ratio; P:C) after exposure to two baculoviruses; one that is specific to the cabbage looper, Trichoplusia ni (TnSNPV) and another that has a broad host range (AcMNPV). Virus-challenged larvae performed better on more protein-biased diets, primarily due to higher survival, whereas unchallenged larvae performed best on a balanced diet. The environmental conditions that maximized host performance differed with virus identity because TnSNPV-challenge inflicted fitness costs (reduced pupal weight and prolonged development) whereas AcMNPV-challenge did not. The performance of TnSNPV-challenged larvae rose with increasing P:C across all temperatures, whereas temperature modulated the optimal P:C in AcMNPV-challenged larvae (slightly protein-biased at 16 °C to increasingly higher P:C as temperature increased). Increasing temperature reduced pupal size, but only at more balanced P:C ratios, indicating that nutrition moderates the temperature-size rule. Our findings highlight the complex environmental interactions that can alter host performance after exposure to pathogens, which could impact the role of entomopathogens as regulators of insect populations in a changing climate.
Highlights
In ectotherms, temperature and nutrition individually play powerful roles in host-pathogen interactions
We examined the effects of temperature and dietary nutrients on the survival and development of the cabbage looper Trichoplusia ni (Hübner) after exposure to one of two ecologically relevant species of baculovirus, Trichoplusia ni single nucleopolyhedrovirus (TnSNPV) and Autographa californica multiple NPV (AcMNPV)
The present study focused on the effects of P:C ratio and temperature post-pathogen challenge, since host resistance to baculoviruses increases with dietary P:C ratio consumed after infection[6,24]
Summary
Temperature and nutrition individually play powerful roles in host-pathogen interactions. There is a need for more complex studies using ecologically relevant pathogens and their effects on host survival and other fitness traits To further complicate these interactions, hosts are often susceptible to a large number of diverse parasites[10]. The present study focused on the effects of P:C ratio and temperature post-pathogen challenge, since host resistance to baculoviruses increases with dietary P:C ratio consumed after infection[6,24]. Whether this effect is influenced by temperature and/or virus identity is not known. The influence of temperature on insect performance may depend on its effects on development and interaction with dietary P:C ratio
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