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1. Environmental parameters associated with incidence and transmission of pathogenic Vibrio spp .

   https://doi.org/10.1111/1462-2920.15716  

   Brumfield, Kyle D.; Usmani, Moiz; Chen, Kristine M.; Gangwar, Mayank; Jutla, Antarpreet S.; Huq, Anwar; Colwell, Rita R. (August 2021, Environmental Microbiology)
2. Novel Gloeobacterales spp. from Diverse Environments across the Globe

   https://doi.org/10.1128/mSphere.00061-21  

   Grettenberger, Christen L. (August 2021, mSphere)

   McMahon, Katherine (Ed.)

   ABSTRACT Photosynthetic Cyanobacteria and their descendants are the only known organisms capable of oxygenic photosynthesis. Their metabolism permanently changed the Earth’s surface and the evolutionary trajectory of life, but little is known about their evolutionary history. Genomes of the Gloeobacterales , an order of deeply divergent photosynthetic Cyanobacteria , may hold clues about the evolutionary process. However, there are only three published genomes within this order, and it is difficult to make broad inferences based on such little data. Here, I describe five species within the Gloeobacterales retrieved from publicly available databases and examine their photosynthetic gene content and the environments in which Gloeobacterales genomes and 16S rRNA gene sequences are found. The Gloeobacterales contain reduced photosystems and inhabit cold, wet-rock, and low-light environments. They are likely present in low abundances due to their low growth rate. Future searches for Gloeobacterales should target these environments, and samples should be deeply sequenced to capture the low-abundance taxa. Publicly available databases contain undescribed taxa within the Gloeobacterales . However, searching through all available data with current methods is computationally expensive. Therefore, new methods must be developed to search for these and other evolutionarily important taxa. Once identified, these novel photosynthetic Cyanobacteria will help illuminate the origin and evolution of oxygenic photosynthesis. IMPORTANCE Early branching photosynthetic Cyanobacteria such as the Gloeobacterales may provide clues into the evolutionary history of oxygenic photosynthesis, but there are few genomes or cultured taxa from this order. Five new metagenome-assembled genomes suggest that members of the Gloeobacterales all contain reduced photosystems and lack genes associated with thylakoids and circadian rhythms. Their distribution suggests that they may thrive in environments that are marginal for other species, including wet-rock and cold environments. These traits may aid in the discovery and cultivation of novel species in this clade. 

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3. Taxonomy, nomenclature, and identification of the giant hummingbirds ( Patagona spp.) (Aves: Trochilidae)

   https://doi.org/10.1093/zoolinnean/zlaf036  

   Williamson, Jessie L; Gadek, Chauncey R; Robinson, Bryce W; Bautista, Emil; Bauernfeind, Selina M; Baumann, Matthew J; Gyllenhaal, Ethan G; Marra, Peter P; Ricote, Natalia; Singh, Nadia D; et al (June 2025, Zoological Journal of the Linnean Society)

   Abstract Giant hummingbirds (Patagona spp.) are extraordinarily large hummingbirds whose taxonomy has been muddled for two centuries. Patagona systematics were recently redefined in a study of migration, physiology, and genomics, revealing two species: the Northern Giant Hummingbird and Southern Giant Hummingbird. Here, we re-evaluate taxonomy and nomenclature of the genus in light of its newly clarified biology and species limits, analysing data from 608 specimens and wild-caught individuals spanning 1864–2023. The forms gigas and peruviana were both described based on multiple syntypes. The possible syntypes for Patagona gigas are dubious, so we designate a neotype for this taxon. The genetic identity of the peruviana lectotype remains untested, but its plumage appears to match the northern species. We critically considered the identity and usage of gigas and peruviana, respectively, and examined identification challenges that fostered taxonomic uncertainty. We endorse the name Patagona gigas for the Southern Giant Hummingbird and Patagona peruviana for the Northern Giant Hummingbird. We found that ~33% of specimens (74 of 226) in major museum collections that are labeled peruviana are actually misidentified gigas and we include this full list to correct the historical record. Finally, to facilitate identification and future study of these two cryptic species, we provide comprehensive information on plumage, measurements, and seasonal ranges. 

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4. It’s a wormy world: Meta‐analysis reveals several decades of change in the global abundance of the parasitic nematodes Anisakis spp. and Pseudoterranova spp. in marine fishes and invertebrates

   https://doi.org/10.1111/gcb.15048  

   Fiorenza, Evan A.; Wendt, Catrin A.; Dobkowski, Katie A.; King, Teri L.; Pappaionou, Marguerite; Rabinowitz, Peter; Samhouri, Jameal F.; Wood, Chelsea L. (March 2020, Global Change Biology)

   Abstract The Anthropocene has brought substantial change to ocean ecosystems, but whether this age will bring more or less marine disease is unknown. In recent years, the accelerating tempo of epizootic and zoonotic disease events has made it seem as if disease is on the rise. Is this apparent increase in disease due to increased observation and sampling effort, or to an actual rise in the abundance of parasites and pathogens? We examined the literature to track long‐term change in the abundance of two parasitic nematode genera with zoonotic potential:Anisakisspp. andPseudoterranovaspp. These anisakid nematodes cause the disease anisakidosis and are transmitted to humans in undercooked and raw marine seafood. A total of 123 papers published between 1967 and 2017 met our criteria for inclusion, from which we extracted 755 host–parasite–location–year combinations. Of these, 69.7% concernedAnisakisspp. and 30.3% focused onPseudoterranovaspp. Meta‐regression revealed an increase inAnisakisspp. abundance (average number of worms/fish) over a 53 year period from 1962 to 2015 and no significant change inPseudoterranovaspp. abundance over a 37 year period from 1978 to 2015. Standardizing changes to the period of 1978–2015, so that results are comparable between genera, we detected a significant 283‐fold increase inAnisakisspp. abundance and no change in the abundance ofPseudoterranovaspp. This increase inAnisakisspp. abundance may have implications for human health, marine mammal health, and fisheries profitability. 

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5. Latitudinal variation in thermal performance of the common coral, Pocillopora spp

   https://doi.org/10.1242/jeb.247090  

   Edmunds, P J; Combosch, D; Torrado, H; Sakai, K; Sinniger, F; Burgess, S C (May 2024, Journal of Experimental Biology)

   Understanding how tropical corals respond to temperatures is important to evaluating their capacity to persist in a warmer future. We studied the common Pacific coral Pocillopora over 44° of latitude, and used populations at three islands with different thermal regimes to compare their responses to temperature using thermal performance curves (TPCs) for respiration and gross photosynthesis. Corals were sampled in the local autumn from Moorea, Guam, and Okinawa where mean (± s.d.) annual seawater temperature is 28.0±0.9°C, 28.9±0.7°C, and 25.1±3.4°C, respectively. TPCs for respiration were similar among latitudes, the thermal optimum (Topt) was above the local maximum temperature at all three islands, and maximum respiration was lowest at Okinawa. TPCs for gross photosynthesis were wider, implying greater thermal eurytopy, with a higher Topt in Moorea versus Guam and Okinawa. Topt was above the maximum temperature in Moorea, but was similar to daily temperatures over 13% of the year in Okinawa, and 53% of the year in Guam. There was greater annual variation in daily temperatures in Okinawa than Guam or Moorea, which translated to large variation in the supply of metabolic energy and photosynthetically fixed carbon at higher latitudes. Despite these trends, the differences in TPCs for Pocillopora were not profoundly different across latitudes, reducing the likelihood that populations of these corals could better match their phenotypes to future more extreme temperatures through migration. Any such response would place a premium on high metabolic plasticity and tolerance of large seasonal variations in energy budgets. 

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