Body mass, temperature, and pathogen intensity differentially affect critical thermal maxima and their population-level variation in a solitary bee

Laura J Jones; Douglas A Miller; Rudolf J Schilder; Margarita M López-Uribe

doi:10.1002/ece3.10945

Body mass, temperature, and pathogen intensity differentially affect critical thermal maxima and their population-level variation in a solitary bee

Ecol Evol. 2024 Feb 15;14(2):e10945. doi: 10.1002/ece3.10945. eCollection 2024 Feb.

Authors

Laura J Jones^{1

2}, Douglas A Miller³, Rudolf J Schilder^{1

2

4}, Margarita M López-Uribe^{1

2}

Affiliations

¹ Intercollege Graduate Degree Program in Ecology The Pennsylvania State University University Park Pennsylvania USA.
² Department of Entomology, Center for Pollinator Research The Pennsylvania State University University Park Pennsylvania USA.
³ Earth and Environmental Systems Institute The Pennsylvania State University University Park Pennsylvania USA.
⁴ Department of Biology The Pennsylvania State University University Park Pennsylvania USA.

Abstract

Climate change presents a major threat to species distribution and persistence. Understanding what abiotic or biotic factors influence the thermal tolerances of natural populations is critical to assessing their vulnerability under rapidly changing thermal regimes. This study evaluates how body mass, local climate, and pathogen intensity influence heat tolerance and its population-level variation (SD) among individuals of the solitary bee Xenoglossa pruinosa. We assess the sex-specific relationships between these factors and heat tolerance given the differences in size between sexes and the ground-nesting behavior of the females. We collected X. pruinosa individuals from 14 sites across Pennsylvania, USA, that varied in mean temperature, precipitation, and soil texture. We measured the critical thermal maxima (CT_max) of X. pruinosa individuals as our proxy for heat tolerance and used quantitative PCR to determine relative intensities of three parasite groups-trypanosomes, Spiroplasma apis (mollicute bacteria), and Vairimorpha apis (microsporidian). While there was no difference in CT_max between the sexes, we found that CT_max increased significantly with body mass and that this relationship was stronger for males than for females. Air temperature, precipitation, and soil texture did not predict mean CT_max for either sex. However, population-level variation in CT_max was strongly and negatively correlated with air temperature, which suggests that temperature is acting as an environmental filter. Of the parasites screened, only trypanosome intensity correlated with heat tolerance. Specifically, trypanosome intensity negatively correlated with the CT_max of female X. pruinosa but not males. Our results highlight the importance of considering size, sex, and infection status when evaluating thermal tolerance traits. Importantly, this study reveals the need to evaluate trends in the variation of heat tolerance within and between populations and consider implications of reduced variation in heat tolerance for the persistence of ectotherms in future climate conditions.

Keywords: climate; critical thermal maxima; heat tolerance; parasite; sex.

Associated data

Dryad/10.5061/dryad.hhmgqnkp9