@article{camp_yun_chambers_haeba_leblanc_2020, title={Involvement of glutamate and serotonin transmitter systems in male sex determination in Daphnia pulex}, volume={121}, ISSN={["1879-1611"]}, DOI={10.1016/j.jinsphys.2020.104015}, abstractNote={Environmental sex determination occurs in many organisms, however the means by which environmental stimuli are translated into endocrine messages remains poorly understood. The N-methyl-ᴅ-aspartate receptor (NMDAR) was evaluated as a candidate neural sensor of environmental signals linking environmental cues to endocrine responses using the crustacean Daphnia pulex. NMDAR agonists, modulators, and antagonists were evaluated for their ability to impact D. pulex male sex determination during early stages of reproductive maturity under conditions that simulated seasonal change. The antagonists MK-801 and desipramine significantly increased male sex determination. Both chemicals are also modulators of serotonergic and noradrenergic systems, thus, we evaluated several modulators of monoamine neurotransmission in an effort to discern which signaling pathways might contribute to male sex determination. Compounds that altered serotonergic signaling also stimulated male sex determination. The involvement of the glutamate and monoamine signaling in male sex determination was supported by the increase in mRNA levels of related receptors and transporters under conditions that stimulate male sex determination. Further, mRNA levels of components of the terminal endocrine pathway responsible for male sex determination were also elevated under stimulatory conditions. Overall, we provide evidence that glutamatergic and serotonergic systems function upstream of the endocrine regulation of male sex determination in early life stage daphnids.}, journal={JOURNAL OF INSECT PHYSIOLOGY}, author={Camp, Allison A. and Yun, Jeonga and Chambers, Samantha A. and Haeba, Maher H. and LeBlanc, Gerald A.}, year={2020} }
 @article{camp_haeba_leblanc_2019, title={Complementary roles of photoperiod and temperature in environmental sex determination in Daphnia spp.}, volume={222}, ISSN={0022-0949 1477-9145}, url={http://dx.doi.org/10.1242/jeb.195289}, DOI={10.1242/jeb.195289}, abstractNote={ABSTRACT Daphnia spp., a keystone genus in freshwater lentic habitats, are subject to environmental sex determination wherein environmental conditions dictate offspring sex and whether they reproduce asexually or sexually. The introduction of males into a population denotes the first step in the switch from asexual parthenogenetic reproduction to sexual reproduction. We tested the hypothesis that photoperiod and temperature co-regulate male sex determination and that these environmental stimuli would activate elements of the male sex determination signaling cascade. The results revealed that photoperiod was a critical cue in creating permissive conditions for male production. Further, under photoperiod-induced permissive conditions, male sex determination was temperature dependent. The two daphnid species evaluated, Daphnia pulex and Daphnia magna, exhibited different temperature dependencies. Daphnia pulex produced fewer males with increasing temperatures between 16 and 22°C, and D. magna exhibited the opposite trend. We found consistent expression patterns of key genes along the male sex-determining signaling pathway in D. pulex independent of environmental stimuli. mRNA levels for the enzyme responsible for synthesis of the male sex-determining hormone, methyl farnesoate, were elevated early in the reproductive cycle, followed by increased mRNA levels of the methyl farnesoate receptor subunits Met and SRC. Environmental conditions that stimulated male offspring production significantly increased Met mRNA levels. The results indicate that male sex determination in daphnids is under the permissive control of photoperiod and the regulatory control of temperature. Further, these environmental cues may stimulate male sex determination by increasing levels of the Met subunit of the methyl farnesoate receptor. Summary: Male sex determination in daphnids is controlled by photoperiod and temperature, which may act by increasing levels of the Met subunit of the methyl farnesoate receptor.}, number={4}, journal={The Journal of Experimental Biology}, publisher={The Company of Biologists}, author={Camp, Allison A. and Haeba, Maher H. and LeBlanc, Gerald A.}, year={2019}, month={Jan}, pages={jeb195289} }
 @article{camp_buchwalter_2016, title={Can't take the heat: Temperature-enhanced toxicity in the mayfly Isonychia bicolor exposed to the neonicotinoid insecticide imidacloprid}, volume={178}, ISSN={["1879-1514"]}, DOI={10.1016/j.aquatox.2016.07.011}, abstractNote={Neonicotinoid insecticide usage has increased globally in recent decades. Neonicotinoids, such as imidacloprid, are potent insect neurotoxicants that may pose a threat to non-target aquatic organisms, such as aquatic insects. In nature, insects typically live in thermally fluctuating conditions, which may significantly alter both contaminant exposures and affects. Here we investigate the relationship between temperature and time-to-effect for imidacloprid toxicity with the aquatic insect Isonychia bicolor, a lotic mayfly. Additionally, we examined the mechanisms driving temperature-enhanced toxicity including metabolic rate, imidacloprid uptake rate, and tissue bioconcentration. Experiments included acute toxicity tests utilizing sublethal endpoints and mortality, as well as respirometry and radiotracer assays with [(14)C] imidacloprid. Further, we conducted additional uptake experiments with a suite of aquatic invertebrates (including I. bicolor, Neocloeon triangulifer, Macaffertium modestum, Pteronarcys proteus, Acroneuria carolinensis, and Pleuroceridae sp) to confirm and contextualize our findings from initial experiments. The 96h EC50 (immobility) for I. bicolor at 15°C was 5.81μg/L which was approximately 3.2 fold lower than concentrations associated with 50% mortality. Assays examining the impact of temperature were conducted at 15, 18, 21, and 24°C and demonstrated that time-to-effect for sublethal impairment and immobility was significantly decreased with increasing temperature. Uptake experiments with [(14)C] imidacloprid revealed that initial uptake rates were significantly increased with increasing temperature for I. bicolor, as were oxygen consumption rates. Further, in the separate experiment with multiple species across temperatures 15, 20, and 25°C, we found that all the aquatic insects tested had significantly increased imidacloprid uptake with increasing temperatures, with N. triangulifer accumulating the most imidacloprid on a mass-specific basis. Our acute toxicity results highlight the importance of evaluating sublethal endpoints, as profound impairments of motor function were evident far before mortality. Further, we demonstrate that temperature is a powerful modulator of sublethal toxicity within a range of environmentally relevant temperatures, impacting both uptake rates and metabolic rates of I. bicolor. Finally, we show that temperature alters imidacloprid uptake across a range of species, highlighting the physiological variation present within aquatic invertebrate communities and the challenge associated with relying solely on surrogate species. Taken together, this research points to the need to consider the role of temperature in toxicity assessments.}, journal={AQUATIC TOXICOLOGY}, author={Camp, A. A. and Buchwalter, D. B.}, year={2016}, month={Sep}, pages={49–57} }
 @article{camp_funk_buchwalter_2014, title={A stressful shortness of breath: molting disrupts breathing in the mayfly Cloeon dipterum}, volume={33}, ISSN={["2161-9565"]}, DOI={10.1086/677899}, abstractNote={Abstract: Molting is a stressful event in insect development. When an insect molts, the individual discards its exoskeleton and sheds and renews the interior lining of substantial portions of the respiratory (tracheal) system. We profiled for the first time the disruptive pattern of respiration during the molting process in larvae of the mayfly Cloeon dipterum (Ephemeroptera:Baetidae). Molting induces a precipitous drop in O2 consumption immediately followed by a surge in O2 consumption that appears to be compensatory in nature. Postmolt metabolic suppression is consistently observed during which O2 consumption rates lag relative to those of nonmolting larvae. Furthermore, the magnitude of respiratory disturbance during the molt increases as a function of temperature. Increasing temperatures increase molting frequency and the apparently stressful nature of the molt itself. Thus, the insect molt appears to be a previously unappreciated route by which warming conditions may affect aquatic insects.}, number={3}, journal={FRESHWATER SCIENCE}, author={Camp, A. A. and Funk, D. H. and Buchwalter, D. B.}, year={2014}, month={Sep}, pages={695–699} }