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1. Integrated overview of stramenopile ecology, taxonomy, and heterotrophic origin

   https://doi.org/10.1093/ismejo/wrae150  

   Jirsová, Dagmar; Wideman, Jeremy_G (July 2024, The ISME Journal)

   Abstract Stramenopiles represent a significant proportion of aquatic and terrestrial biota. Most biologists can name a few, but these are limited to the phototrophic (e.g. diatoms and kelp) or parasitic species (e.g. oomycetes, Blastocystis), with free-living heterotrophs largely overlooked. Though our attention is slowly turning towards heterotrophs, we have only a limited understanding of their biology due to a lack of cultured models. Recent metagenomic and single-cell investigations have revealed the species richness and ecological importance of stramenopiles—especially heterotrophs. However, our lack of knowledge of the cell biology and behaviour of these organisms leads to our inability to match species to their particular ecological functions. Because photosynthetic stramenopiles are studied independently of their heterotrophic relatives, they are often treated separately in the literature. Here, we present stramenopiles as a unified group with shared synapomorphies and evolutionary history. We introduce the main lineages, describe their important biological and ecological traits, and provide a concise update on the origin of the ochrophyte plastid. We highlight the crucial role of heterotrophs and mixotrophs in our understanding of stramenopiles with the goal of inspiring future investigations in taxonomy and life history. To understand each of the many diversifications within stramenopiles—towards autotrophy, osmotrophy, or parasitism—we must understand the ancestral heterotrophic flagellate from which they each evolved. We hope the following will serve as a primer for new stramenopile researchers or as an integrative refresher to those already in the field. 

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2. Bacterial diketopiperazines stimulate diatom growth and lipid accumulation

   https://doi.org/10.1093/plphys/kiab080  

   Sittmann, John; Bae, Munhyung; Mevers, Emily; Li, Muzi; Quinn, Andrew; Sriram, Ganesh; Clardy, Jon; Liu, Zhongchi (February 2021, Plant Physiology)

   null (Ed.)

   Abstract Diatoms are photosynthetic microalgae that fix a significant fraction of the world’s carbon. Because of their photosynthetic efficiency and high-lipid content, diatoms are priority candidates for biofuel production. Here, we report that sporulating Bacillus thuringiensis and other members of the Bacillus cereus group, when in co-culture with the marine diatom Phaeodactylum tricornutum, significantly increase diatom cell count. Bioassay-guided purification of the mother cell lysate of B. thuringiensis led to the identification of two diketopiperazines (DKPs) that stimulate both P. tricornutum growth and increase its lipid content. These findings may be exploited to enhance P. tricornutum growth and microalgae-based biofuel production. As increasing numbers of DKPs are isolated from marine microbes, the work gives potential clues to bacterial-produced growth factors for marine microalgae. 

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3. Non-disruptive matrix turnover is a conserved feature of biofilm aggregate growth in paradigm pathogenic species

   https://doi.org/10.1128/mbio.03935-24  

   Reichhardt, Courtney; Matwichuk, Michael L; Lewerke, Lincoln T; Jacobs, Holly M; Yan, Jing; Parsek, Matthew R (February 2025, mBio)

   Whiteley, Marvin (Ed.)

   ABSTRACT Bacteria form multicellular aggregates called biofilms. A crucial component of these aggregates is a protective matrix that holds the community together. Biofilm matrix composition varies depending upon bacterial species but typically includes exopolysaccharides (EPS), proteins, and extracellular DNA.Pseudomonas aeruginosais a model organism for the study of biofilms, and in non-mucoid biofilms, it uses the structurally distinct EPS Psl and Pel, the EPS-binding protein CdrA, and eDNA as key matrix components. An interesting phenomenon that we and others have observed is that the periphery of a biofilm aggregate can be EPS-rich and contain very few cells. In this study, we investigated two possible models of assembly and dynamics of this EPS-rich peripheral region: (i) newly synthesized EPS is inserted and incorporated into the existing EPS-rich region at the periphery during biofilm aggregate growth or (ii) EPS is continuously turned over and newly synthesized EPS is deposited at the outermost edge of the aggregate. Our results support the latter model. Specifically, we observed that new EPS is continually deposited at the aggregate periphery, which is necessary for continued aggregate growth but not aggregate stability. We made similar observations in another paradigm biofilm-forming species,Vibrio cholerae. This pattern of deposition raises the question of how EPS is retained. Specifically, forP. aeruginosabiofilms, the matrix adhesin CdrA is thought to retain EPS. However, current thinking is that cell-associated CdrA is responsible for this retention, and it is not clear how CdrA might function in the relatively cell-free aggregate periphery. We observed that CdrA is enzymatically degraded during aggregate growth without negatively impacting biofilm stability and that cell-free CdrA can partially maintain aggregation and Psl retention. Overall, this study shows that the matrix ofP. aeruginosabiofilms undergoes both continuous synthesis of matrix material and matrix turnover to accommodate biofilm aggregate growth and that cell-free matrix can at least partially maintain biofilm aggregation and EPS localization. Furthermore, our similar observations forV. choleraebiofilms suggest that our findings may represent basic principles of aggregate assembly in bacteria. IMPORTANCEHere, we show that, to accommodate growing cellular biomass, newly produced Psl is deposited over existing Psl at the periphery of biofilm aggregates. We demonstrated thatV. choleraeemploys a similar mechanism with its biofilm matrix EPS, VPS. In addition, we found that the protease LasB is present in the biofilm matrix, resulting in degradation of CdrA to lower molecular weight cell-free forms. We then show that the released forms of CdrA are retained in the matrix and remain functional. Together, our findings support that theP. aeruginosabiofilm matrix is dynamic during the course of aggregate growth and that other species may employ similar mechanisms to remodel their matrix. 

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4. Characterization of the metalloproteome of Pseudoalteromonas (BB2-AT2): biogeochemical underpinnings for zinc, manganese, cobalt, and nickel cycling in a ubiquitous marine heterotroph

   https://doi.org/10.1093/mtomcs/mfab060  

   Mazzotta, Michael G; McIlvin, Matthew R; Moran, Dawn M; Wang, David T; Bidle, Kay D; Lamborg, Carl H; Saito, Mak A (December 2021, Metallomics)

   Abstract Pseudoalteromonas (BB2-AT2) is a ubiquitous marine heterotroph, often associated with labile organic carbon sources in the ocean (e.g. phytoplankton blooms and sinking particles). Heterotrophs hydrolyze exported photosynthetic materials, components of the biological carbon pump, with the use of diverse metalloenzymes containing zinc (Zn), manganese (Mn), cobalt (Co), and nickel (Ni). Studies on the metal requirements and cytosolic utilization of metals for marine heterotrophs are scarce, despite their relevance to global carbon cycling. Here, we characterized the Zn, Mn, Co, and Ni metallome of BB2-AT2. We found that the Zn metallome is complex and cytosolic Zn is associated with numerous proteins for transcription (47.2% of the metallome, obtained from singular value decomposition of the metalloproteomic data), translation (33.5%), proteolysis (12.8%), and alkaline phosphatase activity (6.4%). Numerous proteolytic enzymes also appear to be putatively associated with Mn, and to a lesser extent, Co. Putative identification of the Ni-associated proteins, phosphoglucomutase and a protein in the cupin superfamily, provides new insights for Ni utilization in marine heterotrophs. BB2-AT2 relies on numerous transition metals for proteolytic and phosphatase activities, inferring an adaptative potential to metal limitation. Our field observations of increased alkaline phosphatase activity upon addition of Zn in field incubations suggest that such metal limitation operates in sinking particulate material collected from sediment traps. Taken together, this study improves our understanding of the Zn, Mn, Co, and Ni metallome of marine heterotrophic bacteria and provides novel and mechanistic frameworks for understanding the influence of nutrient limitation on biogeochemical cycling. 

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5. Distinct iron acquisition strategies in oceanic and coastal variants of the mixotrophic dinoflagellate Karlodinium

   https://doi.org/10.1093/ismejo/wraf099  

   Jang, Se_Hyeon; Lin, YuanYu; Marchetti, Adrian (May 2025, The ISME Journal)

   Abstract The availability of the micronutrient iron is important in regulating phytoplankton growth across much of the world’s oceans, particularly in the high-nutrient, low-chlorophyll regions. Compared to known mechanisms of iron acquisition and conservation in autotrophic protists (e.g. diatoms), those of dinoflagellates remain unclear, despite their frequent presence in offshore iron-limited waters. Here, we investigate the strategies of an ecologically important mixotrophic dinoflagellate to coping with low iron conditions. Coupled gene expression and physiological responses as a function of iron availability were examined in oceanic and coastal strains of the dinoflagellate Karlodinium. Under iron-replete conditions, grazing was only detected in coastal variants, resulting in faster growth rates compared to when grown autotrophically. Under iron-limited conditions, all isolates exhibited slower growth rates, reduced photosynthetic efficiencies, and lower cellular iron quotas than in iron-replete conditions. However, oceanic isolates exhibited higher relative growth rates compared to coastal isolates under similar low iron concentrations, suggesting they are better adapted to coping under iron limitation. Yet the oceanic isolates did not exhibit the ability to appreciably reduce cell volume or increase iron-use efficiencies compared to the coastal isolates to cope with iron limitation, as often observed in oceanic diatoms. Rather, molecular pathway analysis and corresponding gene expression patterns suggest that oceanic Karlodinium utilizes a high-affinity iron uptake system when iron is low. Our findings reveal cellular mechanisms by which dinoflagellates have adapted to low iron conditions, further shedding light on how they potentially survive in variable iron regions of the world’s oceans. 

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