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1. “A comparison of thermal stress response between Drosophila melanogaster and Drosophila pseudoobscura reveals differences between species and sexes”

   https://doi.org/10.1016/j.jinsphys.2024.104616  

   Rivera-Rincón, N; Altindag, UH; Amin, R; Graze, RM; Appel, AG; Stevison, LS (March 2024, Journal of Insect Physiology)

   The environment is changing faster than anticipated due to climate change, making species more vulnerable to its impacts. The level of vulnerability of species is influenced by factors such as the degree and duration of exposure, as well as the physiological sensitivity of organisms to changes in their environments, which has been shown to vary among species, populations, and individuals. Here, we compared physiological changes in fecundity, critical thermal maximum (CTmax), respiratory quotient (RQ), and DNA damage in ovaries in response to temperature stress in two species of fruit fly, Drosophila melanogaster (25 vs. 29.5 °C) and Drosophila pseudoobscura (20.5 vs. 25 °C). The fecundity of D. melanogaster was more affected by high temperatures when exposed during egg through adult development, while D. pseudoobscura was most significantly affected when exposed to high temperatures exclusively during egg through pupal development. Additionally, D. melanogaster males exhibited a decrease of CTmax under high temperatures, while females showed an increase of CTmax when exposed to high temperatures during egg through adult development. while D. pseudoobscura females and males showed an increased CTmax only when reared at high temperatures during egg through pupae development. Moreover, both species showed an acceleration in oogenesis and an increase in apoptosis due to heat stress. These changes can likely be attributed to key differences in the geographic range, thermal range, development time, and other different factors between these two systems. Through this comparison of variation in physiology and developmental response to thermal stress, we found important differences between species and sexes that suggest future work needs to account for these factors separately in understanding the effects of constant increased temperatures. 

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2. Changes in Aerosols, Meteorology, and Radiation in the Southeastern U.S. Warming Hole Region during 2000 to 2019

   https://doi.org/10.1175/JCLI-D-22-0073.1  

   Ghate, Virendra P; Carlton, Annmarie G; Surleta, Thomas; Burns, Alyssa Marie (December 2022, Journal of Climate)

   Simpson, Isla; Waugh, Darryn (Ed.)

   Abstract Surface air temperatures in the southeastern United States that did not change from the climatological mean from 1900 to 2000 have increased since the year 2000. Analyzed herein are factors modulating the surface air temperatures in the region for a 20-yr period (2000–19) using space- and surface-based observations, and output from a reanalysis model. The 20-yr period is segregated into two decades, 2000–09 and 2010–19, corresponding to different tropospheric chemical regimes. Changes in seasonal and decadal averages are examined. The later decade experienced higher average surface air temperatures with significant warming during summer and fall seasons. Decadal and seasonal averages of cloud properties, column water vapor, rain rates, and top-of-atmosphere outgoing longwave radiation did not exhibit statistically significant differences between the two decades. The region experienced strong warm and moist advection during the winter months and very weak advection during the summer months. The later decade exhibited higher low-level moisture advection during the winter months than the earlier decade with insignificant changes in the temperature advection between the two decades. The later decade had significantly lower aerosol dry and liquid water mass during all seasons, along with lower aerosol optical depth, higher single scattering albedo, and lower top-of-the-atmosphere outgoing shortwave radiation during cloud-free conditions in the summer season. Collectively, these results suggest that changes in the aerosol direct radiative forcing are responsible for warming during summer months that experience weak advection and highlight seasonal differences in the temperature controlling mechanisms in the region. 

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3. Phenotypic plasticity of male calls in two populations of the katydid Neoconocephalus triops (Insecta: Tettigoniidae)

   https://doi.org/10.3389/fevo.2023.1216463  

   Beckers, Oliver M.; Kijimoto, Teiya; Schul, Johannes (October 2023, Frontiers in Ecology and Evolution)

   David A. Gray (Ed.)

   The ability to respond to environmental changes plays a crucial role for coping with environmental stressors related to climate change. Substantial changes in environmental conditions can overcome developmental homeostasis, exposing cryptic genetic variation. The katydidNeoconocephalus triopsis a tropical species that extended its range to the more seasonal environment of North America where it has two reproductive generations per year. The harsher winter conditions required adults to diapause which resulted in substantially different mating calls of the diapausing winter animals compared to the non-overwintering summer animals in northern Florida. The summer call corresponds to that of tropical populations, whereas the winter call represents the alternative call phenotype. We quantified call plasticity in a tropical (Puerto Rico) and a temperate population ofN. triops(Florida) that differ in experiencing winter conditions in their geographic regions. We hypothesized that the plastic call traits, i.e., double-pulse rate and call structure, are regulated independently. Further, we hypothesized that phenotypic plasticity of double-pulse rate results in quantitative changes, whereas that of call structure in qualitative changes. We varied the photoperiod and duration of diapause during male juvenile and adult development during rearing and analyzed the double-pulse rate and call structure of the animals. Double-pulse rate changed in a quantitative fashion in both populations and significant changes appeared at different developmental points, i.e., the double-pulse rate slowed down during juvenile development in Florida, whereas during adult diapause in Puerto Rico. In the Florida population, both the number of males producing and the proportion of total call time covered by the alternative call structure (= continuous calls) increased with duration spent in diapause. In the Puerto Rico population, expression of the alternative call structure was extremely rare. Our results suggest that the expression of both pulse rate and call structure was quantitative and not categorical. Our systematic variation of environmental variables demonstrated a wide range of phenotypic variation that can be induced during development. Our study highlights the evolutionary potential of hidden genetic variation and phenotypic plasticity when confronted with rapidly changing environments and their potential role in providing variation necessary for communication systems to evolve. 

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4. State of the California Current 2019–2020: Back to the Future With Marine Heatwaves?

   https://doi.org/10.3389/fmars.2021.709454  

   Weber, Edward D.; Auth, Toby D.; Baumann-Pickering, Simone; Baumgartner, Timothy R.; Bjorkstedt, Eric P.; Bograd, Steven J.; Burke, Brian J.; Cadena-Ramírez, José L.; Daly, Elizabeth A.; de la Cruz, Martin; et al (August 2021, Frontiers in Marine Science)

   The California Current System (CCS) has experienced large fluctuations in environmental conditions in recent years that have dramatically affected the biological community. Here we synthesize remotely sensed, hydrographic, and biological survey data from throughout the CCS in 2019–2020 to evaluate how recent changes in environmental conditions have affected community dynamics at multiple trophic levels. A marine heatwave formed in the north Pacific in 2019 and reached the second greatest area ever recorded by the end of summer 2020. However, high atmospheric pressure in early 2020 drove relatively strong Ekman-driven coastal upwelling in the northern portion of the CCS and warm temperature anomalies remained far offshore. Upwelling and cooler temperatures in the northern CCS created relatively productive conditions in which the biomass of lipid-rich copepod species increased, adult krill size increased, and several seabird species experienced positive reproductive success. Despite these conditions, the composition of the fish community in the northern CCS remained a mixture of both warm- and cool-water-associated species. In the southern CCS, ocean temperatures remained above average for the seventh consecutive year. Abundances of juvenile fish species associated with productive conditions were relatively low, and the ichthyoplankton community was dominated by a mixture of oceanic warm-water and cosmopolitan species. Seabird species associated with warm water also occurred at greater densities than cool-water species in the southern CCS. The population of northern anchovy, which has been resurgent since 2017, continued to provide an important forage base for piscivorous fishes, offshore colonies of seabirds, and marine mammals throughout the CCS. Coastal upwelling in the north, and a longer-term trend in warming in the south, appeared to be controlling the community to a much greater extent than the marine heatwave itself. 

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5. Drivers of Speciation Using Genomic Analyses of Two Desert Brittlebush Species, Encelia farinosa and Encelia californica

   Baty, S; Singhal, S; Araya-Donoso, R; Fehlberg, S; Munguia-Vega, A; Wilder, B; Kusumi, K; Dolby, G (December 2021, American Geophysical Union)

   Reproductive isolation is necessary for population divergence to lead to the formation of separate species. This can occur due to physical isolation of populations, which drives allopatric speciation, or other methods of isolation, such as sympatric speciation where the diverging species are physically in the same range, but structural genomic changes or mutations cause the population to diverge into two different species. Parapatric speciation occurs when populations that are geographically adjacent to each other diverge, which can be driven by adaptations to environmental differences, even with ongoing gene flow. Two desert- adapted brittlebush species, Encelia farinosa and Encelia californica, diverged less than 1 million years ago (Singhal et al., 2020) and have a parapatric distribution, residing in different environments in the Mojave and Sonoran deserts. Encelia farinosa (Brittlebush) has unique silvery leaves that are covered in tiny hairs (leaf pubescence) to better control leaf temperature in the hot and arid conditions of the Sonoran Desert. Encelia californica (California Brittlebush) does not display leaf pubescence and is found in a smaller region of the Mediterranean-like environment of the west coast of North America. Encelia californica is exposed to more precipitation than most other Encelia species. Even with their different morphologies, these two species are still able to hybridize and create fertile offspring (Clark, 1998). Using PacBio sequencing and Hi-C scaffolding, we assembled and annotated reference genomes for both species to investigate the genomic basis of reproductive isolation in these two species. The scaffold N50/L50 are 10 scaffolds and 76.3 Mbp, and 12 scaffolds and 64.5 Mbp for E. farinosa and E. californica, respectively. Using comparative genomic analyses such as tests for differential adaptation and chromosomal translocations will help reveal whether the drivers of speciation in the Encelia radiation were external (e.g., geologic/climatic) or internal (e.g., genomic rearrangement). These analyses will also help answer how accumulated genomic differences can cause speciation in populations that are not geographically isolated. Analyses such as these are new, exciting sources of information for testing geogenomic and other Earth- life hypotheses. 

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