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1. Respirometry reveals major lineage-based differences in the energetics of osmoregulation in aquatic invertebrates

   https://doi.org/10.1242/jeb.246376  

   Cochran, J.K.; Banks, C.; Buchwalter, D.B. (September 2023, Journal of experimental biology)

   All freshwater organisms are challenged to control their internal balance of water and ions in strongly hypotonic environments. We compared the influence of external salinity on the oxygen consumption rates (M O2) of three species of freshwater insects, one snail and two crustaceans. Consistent with available literature, we found a clear decrease in M O2 with increasing salinity in the snail Elimia sp. and crustaceans Hyalella azteca and Gammarus pulex (r5=−0.90, P=0.03). However, we show here for the first time that metabolic rate was unchanged by salinity in the aquatic insects, whereas ion transport rates were positively correlated with higher salinities. In contrast, when we examined the ionic influx rates in the freshwater snail and crustaceans, we found that Ca uptake rates were highest under the most dilute conditions, while Na uptake rates increased with salinity. In G. pulex exposed to a serially diluted ion matrix, Ca uptake rates were positively associated with M O2 (r5=−0.93, P=0.02). This positive association between Ca uptake rate and M O2 was also observed when conductivity was held constant but Ca concentration was manipulated (1.7–17.3 mg Ca l−1) (r5=0.94, P=0.05). This finding potentially implicates the cost of calcium uptake as a driver of increased metabolic rate under dilute conditions in organisms with calcified exoskeletons and suggests major phyletic differences in osmoregulatory physiology. Freshwater insects may be energetically challenged by higher salinities, while lower salinities may be more challenging for other freshwater taxa. 

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2. Acute heat priming promotes short-term climate resilience of early life stages in a model sea anemone

   https://doi.org/10.7717/peerj.16574  

   Glass, Benjamin H.; Jones, Katelyn G.; Ye, Angela C.; Dworetzky, Anna G.; Barott, Katie L. (January 2023, PeerJ)

   Across diverse taxa, sublethal exposure to abiotic stressors early in life can lead to benefits such as increased stress tolerance upon repeat exposure. This phenomenon, known as hormetic priming, is largely unexplored in early life stages of marine invertebrates, which are increasingly threatened by anthropogenic climate change. To investigate this phenomenon, larvae of the sea anemone and model marine invertebrateNematostella vectensiswere exposed to control (18 °C) or elevated (24 °C, 30 °C, 35 °C, or 39 °C) temperatures for 1 h at 3 days post-fertilization (DPF), followed by return to control temperatures (18 °C). The animals were then assessed for growth, development, metabolic rates, and heat tolerance at 4, 7, and 11 DPF. Priming at intermediately elevated temperatures (24 °C, 30 °C, or 35 °C) augmented growth and development compared to controls or priming at 39 °C. Indeed, priming at 39 °C hampered developmental progression, with around 40% of larvae still in the planula stage at 11 DPF, in contrast to 0% for all other groups. Total protein content, a proxy for biomass, and respiration rates were not significantly affected by priming, suggesting metabolic resilience. Heat tolerance was quantified with acute heat stress exposures, and was significantly higher for animals primed at intermediate temperatures (24 °C, 30 °C, or 35 °C) compared to controls or those primed at 39 °C at all time points. To investigate a possible molecular mechanism for the observed changes in heat tolerance, the expression of heat shock protein 70 (HSP70) was quantified at 11 DPF. Expression of HSP70 significantly increased with increasing priming temperature, with the presence of a doublet band for larvae primed at 39 °C, suggesting persistent negative effects of priming on protein homeostasis. Interestingly, primed larvae in a second cohort cultured to 6 weeks post-fertilization continued to display hormetic growth responses, whereas benefits for heat tolerance were lost; in contrast, negative effects of short-term exposure to extreme heat stress (39 °C) persisted. These results demonstrate that some dose-dependent effects of priming waned over time while others persisted, resulting in heterogeneity in organismal performance across ontogeny following priming. Overall, these findings suggest that heat priming may augment the climate resilience of marine invertebrate early life stagesviathe modulation of key developmental and physiological phenotypes, while also affirming the need to limit further anthropogenic ocean warming. 

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3. Egg translocation across a local range boundary reduces hatch rates in a trailing-edge population of a migratory songbird, Setophaga caerulescens (Black-throated Blue Warbler)

   https://doi.org/10.1093/ornithology/ukaf007  

   Merker, Samuel_A; Sillett, T_Scott; Freeman, Benjamin_G; Cooper, Robert_J; Chandler, Richard_B (April 2025, Ornithology)

   Abstract The abiotic range limitation hypothesis states that species distributions are shaped by physiological constraints imposed by temperature and precipitation. To test this hypothesis, we assessed the impacts of climate on hatch rates by reciprocally translocating complete clutches of both Setophaga caerulescens (Black-throated Blue Warbler) and S. citrina (Hooded Warblers) across a local range boundary of S. caerulescens in the southern Appalachian Mountains. The S. caerulescens population occurs at the trailing edge of its breeding range, whereas the S. citrina population occurs near the core of its range. The hatching probability of S. caerulescens eggs declined from 0.93 ± 0.02 to 0.60 ± 0.07 when moved to S. citrina nests in warmer conditions. Translocation, however, had little effect on hatching probability of S. citrina eggs when moved to S. caerulescens nests in cooler environments. Thirteen reciprocal clutch translocations were performed; 17 clutches were moved as controls; and 49 nests were not manipulated. We monitored species-specific incubation behavior, measured microclimate conditions inside and outside nests using hygrochron iButtons, and examined the effects of temperature and humidity on nestling growth rates. Higher ambient temperatures had a greater effect on hatching probability than did humidity, but we were unable to determine if reduced hatching was caused by changes in temperature, humidity, or their interaction. We suggest that, in warmer conditions, S. caerulescens eggs in S. citrina nests may have been unable to cool sufficiently to avoid excessive water loss due to higher ambient temperatures but not a difference in relative humidity. Our finding that hatch rates of S. caerulescens declined when translocated to warmer conditions supports the hypothesis that distributions of trailing-edge populations are limited in part by climate effects on reproductive rates. 

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4. The Impacts of Osmotic Stress During the Critical Window of Development on Protein and Histone PTM Alterations in California grunion

   https://doi.org/10.1152/physiol.2024.39.S1.1004  

   Corona, Meranda; Kültz, Dietmar (May 2024, Physiology)

   The California Grunion, Leuresthes tenuis, can experience a broad range of salinities during their early life stages, with their nursery grounds measuring salinities of 21 to 42ppt under normal conditions. Due to the unique subterrestrial incubation of their eggs within the sand of California beaches, it is not unlikely for this marine fish to hatch in non-seawater conditions, whereafter the larvae may transition to relatively diluted estuaries or concentrated harbors to develop as juveniles for several months. Consequently, they are an ideal system to study the impacts of ecologically relevant salinity stress on the alteration of proteins and histone post-translational modifications (PTMs) during early development. The study of the relationship between the critical window of development (CWD), in which sexual bipotential is lost, and the longevity of protein landscape and histone PTM changes has not been widely explored. The CWD is of interest as this is when the gametes of this species become set. Therefore, we hypothesize that histone PTM changes that occur during this time may thus be a form of heritable epigenetics. Thus, hypo-and-hyperosmotic exposures of L. tenuis hatchlings during this window, and past it, attempt to identify if the CWD is relevant to the presence and persistence of protein and histone PTM changes under salinity stress. We hypothesize that exposure to osmotic stress during the CWD will result in induced compensatory mechanisms in the protein landscape of the California grunion larvae, as well as persistent alterations in the histone PTMs in the larvae. To elucidate the relationship between these factors, California grunion larvae were exposed in replicate to one of three chronic salinity treatments (16ppt, 32ppt, or 40ppt) for the duration of their CWD (68dph), with 16ppt and 40ppt inducing hypoosmotic and hyperosmotic stress respectively. Chronic post-CWD exposures and recovery times until 98dph were used to determine whether the CWD or prolonged salinity exposures were key to alterations in the histone PTM and protein landscape of the larvae. After each timepoint, L. tenuis were culled and processed for histone PTM enrichment and proteomic analysis. At the time of culling, there were no significant differences in survivorship between replicates and experimental groups, with statistically significant different deaths between groups occurring only shortly after hatching. Skyline and MSstats were used in the analysis of the statistical significance of differential regulation of proteins and histone PTMs under stress conditions versus the controls. Of special interest is the osmoregulatory mechanisms involved in the myo-inositol biosynthesis pathway, with analysis focusing on the abundance of histone acetylation, amidation, ubiquitylation, and 4-hydroxynonelation in histone PTMs, as the accumulations of these have been found to be correlated with osmotic stress in some fish tissues. Funding provided by NSF IOS-2209383 and NSF GRFP. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process. 

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5. Projected ocean temperatures impair key proteins used in vision of octopus hatchlings

   https://doi.org/10.1111/gcb.17255  

   Hua, Qiaz_Q_H; Kültz, Dietmar; Wiltshire, Kathryn; Doubleday, Zoe_A; Gillanders, Bronwyn_M (April 2024, Global Change Biology)

   Abstract Global warming is one of the most significant and widespread effects of climate change. While early life stages are particularly vulnerable to increasing temperatures, little is known about the molecular processes that underpin their capacity to adapt to temperature change during early development. Using a quantitative proteomics approach, we investigated the effects of thermal stress on octopus embryos. We exposedOctopus berrimaembryos to different temperature treatments (control 19°C, current summer temperature 22°C, or future projected summer temperature 25°C) until hatching. By comparing their protein expression levels, we found that future projected temperatures significantly reduced levels of key eye proteins such as S‐crystallin and retinol dehydrogenase 12, suggesting the embryonic octopuses had impaired vision at elevated temperature. We also found that this was coupled with a cellular stress response that included a significant elevation of proteins involved in molecular chaperoning and redox regulation. Energy resources were also redirected away from non‐essential processes such as growth and digestion. These findings, taken together with the high embryonic mortality observed under the highest temperature, identify critical physiological functions of embryonic octopuses that may be impaired under future warming conditions. Our findings demonstrate the severity of the thermal impacts on the early life stages of octopuses as demonstrated by quantitative proteome changes that affect vision, protein chaperoning, redox regulation and energy metabolism as critical physiological functions that underlie the responses to thermal stress. 

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