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1. Quantitative modeling of microalgae based sequestration of atmospheric CO ₂

   https://doi.org/10.1039/c7an01781b  

   Hasan, Mohammed F.; Vogt, Frank (January 2018, The Analyst)

   Marine microalgae have been identified as a considerable sink of atmospheric CO 2 . Since macroscopic ecosystems cannot be studied experimentally with the required microscopic spatial resolution, a novel modeling method is being presented to quantify this sequestration process. The presented modeling studies indicate that the fixation of carbon by microalgae is species-specific and depends on competition effects among multiple species. 

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2. Volatile Organic Compounds Modulate the Biological and Chemical Environment of the Phycosphere

   Padaki, Vaishnavi G (May 2025, ScholarsArchive@OSU)

   The ocean is a vast reservoir of bioavailable dissolved organic compounds (DOCs). Phytoplankton and bacterioplankton are the primary producers and consumers of these organic compounds, respectively, driving DOCs turnover on timescales of minutes to days. Volatile organic compounds (VOCs) make up about a third of DOCs, and their diffusivity and reactivity cause them to be important contributors to plankton carbon cycling and atmospheric chemistry. This research sought to describe plankton interactions mediated by VOCs. A model diatom, Phaeodactylum tricornutum, and five bacterial species known to be associated with the P. tricornutum phycosphere were studied in monocultures and co-cultures. Investigations evaluated the VOCs produced and consumed, temporal dynamics of VOC production and their roles in diatom metabolism, and physiological strategies of bacterial VOC consumers. P. tricornutum produced 78 VOCs during exponential growth. About 60% of these VOCs were hydrocarbons. In co-cultures with P. tricornutum, bacteria consumed different ranges of VOCs. The VOC specialists, Marinobacter and Roseibium, consumed the most, had hydrocarbon oxidation genes, and showed motility and physical attachment to the diatom. Rhodobacter and Stappia consumed fewer VOCs and were non-motile, while Yoonia consumed only acetaldehyde. Diatom gross carbon fixation was 29% higher in the presence of VOC specialists, suggesting rapid VOC consumption in the phycosphere impacts global gross carbon production. Temporal VOC production in P. tricornutum was monitored over a diel cycle. All VOCs were produced in higher concentrations during the day compared to night. Regression spline functions revealed six unique temporal production patterns associated with diel shifts in metabolism and the cell cycle. Physiological strategies for VOC uptake were studied in the VOC specialist Marinobacter. Marinobacter consumed some benzenoids at concentrations ranging from pM to μM and most increased cell densities compared to no VOC added controls and were not chemoattractants. Other VOCs that did not stimulate higher cell densities were strong chemoattractants. Thus, some VOCs are chemoattractants that guide motile cells toward co-emitted growth substrates. VOC discrimination may optimize spatial and temporal positioning in the phycosphere and enhance VOC uptake, sustaining the extremely low VOC concentrations in the surface ocean. This research revealed phytoplankton and ii bacterioplankton physiological processes that underlie the biological cycling of surface ocean VOCs and their potential for air-sea flux. This dissertation on microbiology in the phycosphere provided a foundation for exploring elements of science art that promote audience engagement through an exhibition that used scientific findings from the dissertation. Original art and audience surveys were used iteratively to increase science accessibility to general audiences. 

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3. Production of ice-nucleating particles (INPs) by fast-growing phytoplankton

   https://doi.org/10.5194/acp-23-12707-2023  

   Thornton, Daniel C_O; Brooks, Sarah D; Wilbourn, Elise K; Mirrielees, Jessica; Alsante, Alyssa N; Gold-Bouchot, Gerardo; Whitesell, Andrew; McFadden, Kiana (January 2023, Atmospheric Chemistry and Physics)

   Sea spray aerosol contains ice-nucleating particles (INPs), which affect the formation and properties of clouds. Here, we show that aerosols emitted from fast-growing marine phytoplankton produce effective immersion INPs, which nucleate at temperatures significantly warmer than the atmospheric homogeneous freezing (−38.0 ∘C) of pure water. Aerosol sampled over phytoplankton cultures grown in a Marine Aerosol Reference Tank (MART) induced nucleation and freezing at temperatures as high as −15.0 ∘C during exponential phytoplankton growth. This was observed in monospecific cultures representative of two major groups of phytoplankton, namely a cyanobacterium (Synechococcus elongatus) and a diatom (Thalassiosira weissflogii). Ice nucleation occurred at colder temperatures (−28.5 ∘C and below), which were not different from the freezing temperatures of procedural blanks, when the cultures were in the stationary or death phases of growth. Ice nucleation at warmer temperatures was associated with relatively high values of the maximum quantum yield of photosystem II (ΦPSII), an indicator of the physiological status of phytoplankton. High values of ΦPSII indicate the presence of cells with efficient photochemistry and greater potential for photosynthesis. For comparison, field measurements in the North Atlantic Ocean showed that high net growth rates of natural phytoplankton assemblages were associated with marine aerosol that acted as effective immersion INPs at relatively warm temperatures. Data were collected over 4 d at a sampling station maintained in the same water mass as the water column stabilized after deep mixing by a storm. Phytoplankton biomass and net phytoplankton growth rate (0.56 d−1) were greatest over the 24 h preceding the warmest mean ice nucleation temperature (−25.5 ∘C). Collectively, our laboratory and field observations indicate that phytoplankton physiological status is a useful predictor of effective INPs and more reliable than biomass or taxonomic affiliation. Ocean regions associated with fast phytoplankton growth, such as the North Atlantic during the annual spring bloom, may be significant sources of atmospheric INPs. 

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4. Production and cross-feeding of nitrite within Prochlorococcus populations

   https://doi.org/10.1128/mbio.01236-23  

   Berube, Paul M.; O'Keefe, Tyler J.; Rasmussen, Anna; LeMaster, Trent; Chisholm, Sallie W. (July 2023, mBio)

   Dubilier, Nicole (Ed.)

   ABSTRACT Prochlorococcusis an abundant photosynthetic bacterium in the open ocean, where nitrogen (N) often limits phytoplankton growth. In the low-light-adapted LLI clade ofProchlorococcus, nearly all cells can assimilate nitrite (NO₂⁻), with a subset capable of assimilating nitrate (NO₃⁻). LLI cells are maximally abundant near the primary NO₂⁻maximum layer, an oceanographic feature that may, in part, be due to incomplete assimilatory NO₃⁻reduction and subsequent NO₂⁻release by phytoplankton. We hypothesized that someProchlorococcusexhibit incomplete assimilatory NO₃⁻reduction and examined NO₂⁻accumulation in cultures of threeProchlorococcusstrains (MIT0915, MIT0917, and SB) and twoSynechococcusstrains (WH8102 and WH7803). Only MIT0917 and SB accumulated external NO₂⁻during growth on NO₃⁻. Approximately 20–30% of the NO₃⁻transported into the cell by MIT0917 was released as NO₂⁻, with the rest assimilated into biomass. We further observed that co-cultures using NO₃⁻as the sole N source could be established for MIT0917 andProchlorococcusstrain MIT1214 that can assimilate NO₂⁻but not NO₃⁻. In these co-cultures, the NO₂⁻released by MIT0917 is efficiently consumed by its partner strain, MIT1214. Our findings highlight the potential for emergent metabolic partnerships that are mediated by the production and consumption of N cycle intermediates withinProchlorococcuspopulations. IMPORTANCEEarth’s biogeochemical cycles are substantially driven by microorganisms and their interactions. Given that N often limits marine photosynthesis, we investigated the potential for N cross-feeding within populations ofProchlorococcus, the numerically dominant photosynthetic cell in the subtropical open ocean. In laboratory cultures, someProchlorococcuscells release extracellular NO₂⁻during growth on NO₃⁻. In the wild,Prochlorococcuspopulations are composed of multiple functional types, including those that cannot use NO₃⁻but can still assimilate NO₂⁻. We show that metabolic dependencies arise whenProchlorococcusstrains with complementary NO₂⁻production and consumption phenotypes are grown together on NO₃⁻. These findings demonstrate the potential for emergent metabolic partnerships, possibly modulating ocean nutrient gradients, that are mediated by cross-feeding of N cycle intermediates. 

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5. Nanoscale Interactions: Evaluating the Ecotoxicity of Engineered Nanoparticles on the Dynamics of Commercially Important Microalgal Strains

   Louime, Clifford J.; Diaz-Vazquez, Liz M.; Perez, Abner; Torres Díaz, Marielys.; Rojas-Perez, Arnulfo; Vázquez López, Juan C.; Davilla Aguer, Catalina; Malca Reyes, Carlos A. (January 2020, International journal of science and engineering investigations)

   null (Ed.)

   Society has long been exposed to naturally-occurring nanoparticles. Due to their ubiquitous nature, biological systems have adapted and built protection against their potential effects. However, for the past decades, there have been onslaughts of newly engineered nanoparticles being released in the environment with no known effects on ecosystems. Although these materials offer distinct advantages in manufacturing processes, such as odor-free fabric or controlled drug delivery, their fate in nature has yet to be thoroughly investigated. As the size of an already-large NPs market is expected to grow, due to advances in synthetic biology, it is vital that we increase our understanding of their impacts on human, food and natural ecosystems. Recent studies have shown that NPs affect phytoplankton biomass and diversity in the ocean, solely by regulating micronutrients bioavailability. These types of changes could ultimately impact several biogeochemical cycles, as phytoplankton are responsible for almost half of the primary production on earth. Consequently, this study was designed to evaluate the impact of various concentrations (0μM, 20μM, 40μM, 80μM and 100μM) of several manufactured nanoparticles (gold, carbon and iron) on the dynamics of four economically important microalgae strains. Responses, such as chlorophyll content, protein, lipid content, lipid profile, biomass and cell morphology were monitored over a period of two weeks. No significant acute toxicity was exhibited within the first 24 hours of exposure. However, after 4 days, a remarkably high mortality rate was detected with increasing NPs concentrations of Fe60, C80 and Au60. Iron suspensions were found to be more toxic to the microalgae strains tested than those of Gold and Carbon under comparable regimes. Further investigations with other, either positively or negatively charged nanoparticles, should provide a deeper understanding on the impacts on these engineered materials in our ecosystems. 

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