A tale of two mixotrophic chrysophytes: Insights into the metabolisms of two Ochromonas species (Chrysophyceae) through a comparison of gene expression

Lie, Alle A. Y.; Liu, Zhenfeng; Terrado, Ramón; Tatters, Avery O.; Heidelberg, Karla B.; Caron, David A.

doi:10.1371/journal.pone.0192439

Cited by 44 publications

(57 citation statements)

References 48 publications

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“…In contrast, in our study, the mixotroph may competitively exclude the phytoplankter even when, in monoculture, its I Ã out is greater, because it is also able to feed on the phytoplankter (Appendix S1: Fig. 3), other studies have shown that prey can enhance mixotroph photosynthetic capacity, perhaps by providing nutrients inaccessible in the culture media (Sanders et al 2001, Lie et al 2018. Because competition for light is mediated by standing stock biomass rather than production of new biomass, the competitive interactions between mixotrophs and phytoplankton mimic interference competition.…”

Section: Discussioncontrasting

confidence: 76%

“…3). These results highlight the complexities of real mixotroph physiology, wherein different taxa may derive different forms and degrees of benefit from ingesting prey (Mitra et al 2016, Lie et al 2018. S5).…”

Section: Discussionmentioning

confidence: 84%

“…Second, carrying capacity increased with increasing light availability (Fig. However, transcriptomic data suggest that Ochromonas strain CCMP 1393 may not be capable of using nitrate (Lie et al 2018), which was the most abundant source of inorganic nitrogen in our culture medium (Appendix S1: Table S1). S6).…”

Section: Discussionmentioning

confidence: 99%

“…For Ochromonas, we included data in which Micromonas prey were initially available but were ultimately eliminated by grazing, because some Ochromonas strains have been shown to have grazing-enhanced phototrophy (Lie et al 2018). As part of our main experiment (details below) we measured carrying capacity as the maximum population size achieved by each taxon at each light level over a period of 20 (100 lmol quanta Á m À2 Á s À1 ), or 40 d (20 lmol quanta Á m À2 Á s À1 ).…”

Section: Empirical Comparisonmentioning

confidence: 99%

“…As part of our main experiment (details below) we measured carrying capacity as the maximum population size achieved by each taxon at each light level over a period of 20 (100 lmol quanta Á m À2 Á s À1 ), or 40 d (20 lmol quanta Á m À2 Á s À1 ). For Ochromonas, we included data in which Micromonas prey were initially available but were ultimately eliminated by grazing, because some Ochromonas strains have been shown to have grazing-enhanced phototrophy (Lie et al 2018). Indeed, we observed that two of our Ochromonas strains (CCMP 1393 and CCMP 2951) achieved higher population sizes when prey were available (Appendix S1: Fig.…”

Section: Empirical Comparisonmentioning

confidence: 99%

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Intraguild predation enables coexistence of competing phytoplankton in a well‐mixed water column

Moeller

Neubert

Johnson

2019

Ecology

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Citation: Moeller, H. V., M. G. Neubert, and M. D. Johnson. 2019. Intraguild predation enables coexistence of competing phytoplankton in a well-mixed water column. Ecology 100(12):Abstract. Resource competition theory predicts that when two species compete for a single, finite resource, the better competitor should exclude the other. However, in some cases, weaker competitors can persist through intraguild predation, that is, by eating their stronger competitor. Mixotrophs, species that meet their carbon demand by combining photosynthesis and phagotrophic heterotrophy, may function as intraguild predators when they consume the phototrophs with which they compete for light. Thus, theory predicts that mixotrophy may allow for coexistence of two species on a single limiting resource. We tested this prediction by developing a new mathematical model for a unicellular mixotroph and phytoplankter that compete for light, and comparing the model's predictions with a laboratory experimental system. We find that, like other intraguild predators, mixotrophs can persist when an ecosystem is sufficiently productive (i.e., the supply of the limiting resource, light, is relatively high), or when species interactions are strong (i.e., attack rates and conversion efficiencies are high). Both our mathematical and laboratory models show that, depending upon the environment and species traits, a variety of equilibrium outcomes, ranging from competitive exclusion to coexistence, are possible. W Varied December 2019 MIXOTROPHY IN PLANKTONIC COMMUNITIES Article e02874; page 3 FIG. 4. Dependence of mathematical model predicted dynamics on surface light I in and attack rate a. Legends and notation as in Fig. 1. As available light increases, the system transitions from competitive exclusion by prey, to alternate competitive exclusion states or coexistence, to bistability of coexistence and competitive exclusion by the mixotroph, and finally to competitive exclusion by the mixotroph. Nullclines are shown for increasing values of I in at a fixed value of a = 1 9 10 À7 (right column); Roman numerals are used to indicate specific parameter values and are chosen for consistency with Roman numerals in Fig. 1. Note that the basins of attraction for the bistable equilibria shift. For example, as I in increases, the basin of attraction for the coexistence equilibrium (purple square) shrinks (nullclines corresponding to locations IVa and IVb). Parameters are as listed in Table 1, with p m = 0.3, h m = 250, ' m = 0.1, k m = 5 9 10 À7 , and b = 0.005.

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Section: Discussioncontrasting

confidence: 76%

Section: Discussionmentioning

confidence: 84%

Section: Discussionmentioning

confidence: 99%

Section: Empirical Comparisonmentioning

confidence: 99%

Section: Empirical Comparisonmentioning

confidence: 99%

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Intraguild predation enables coexistence of competing phytoplankton in a well‐mixed water column

Moeller

Neubert

Johnson

2019

Ecology

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Importance of integrating mixoplankton into marine ecosystem policy and management—Examples from the Marine Strategy Framework Directive

Anschütz,

Maselli,

Traboni

et al. 2024

Integr Envir Assess & Manag

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Marine plankton capable of photosynthesis and predation (“mixoplankton”) comprise up to 50% of protist plankton and include many harmful species. However, marine environmental management policies, including the European Union Marine Strategy Framework Directive (MSFD) and the USEPA, assume a strict dichotomy between autotrophic phytoplankton and heterotrophic zooplankton. Mixoplankton often differ significantly from these two categories in their response to environmental pressures and affect the marine environment in ways we are only beginning to understand. While the management policies may conceptually provide scope for incorporating mixoplankton, such action is rarely implemented. We suggest that the effectiveness of monitoring and management programs could benefit from explicit implementations regarding the ecological roles and impact of mixoplankton. Taking the MSFD as an example of marine management guidelines, we propose appropriate methods to explicitly include mixoplankton in monitoring and marine management. Integr Environ Assess Manag 2024;00:1–18. © 2024 The Authors. Integrated Environmental Assessment and Management published by Wiley Periodicals LLC on behalf of Society of Environmental Toxicology & Chemistry (SETAC).

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A Revised Interpretation of Marine Primary Productivity in the Indian Ocean: The Role of Mixoplankton

Mitra,

Leles

2023

Dynamics of Planktonic Primary Productivity in the Indian Ocean

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Traditional interpretations of marine plankton ecology, such as that in the Indian Ocean, mirror the plant-animal dichotomy of terrestrial ecology. Thus, single-celled phytoplankton produce food consumed by single-celled zooplankton, and these are in turn consumed by larger zooplankton through to higher trophic levels. Our routine monitoring surveys, research, models, and water management protocols all reflect this interpretation. The last decade has witnessed the development of an important revision of that traditional vision. We now know that the phytoplankton-zooplankton dichotomy represents, at best, a gross simplification. A significant proportion of the protist plankton at the base of the oceanic food-web can photosynthesise (make food ‘like plants’) and ingest food (eat ‘like animals’), thus contributing to both primary and secondary production simultaneously in the same cell. These protists are termed ‘mixoplankton’, and include many species traditionally labelled as ‘phytoplankton’ (a term now reserved for phototrophic microbes that are incapable of phagocytosis) or labelled as ‘protist zooplankton’ (now reserved for protist plankton incapable of phototrophy). Mixoplankton include various harmful algal species, most likely all the phototrophic dinoflagellates, and even iconic exemplar ‘phytoplankton’ such as coccolithophorids (which can consume bacteria). Like all significant revisions to ecology, the mixoplankton paradigm will take time to mature but to ignore it means that we fail to properly represent plankton ecology in teaching, science, management, and policy. This chapter introduces the mixoplankton functional groups and provides the first insight into the biogeography of these organisms in the Indian Ocean. A first attempt to consider the implications of the mixoplankton paradigm on marine primary productivity and ecology in the Indian Ocean is also given.

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A tale of two mixotrophic chrysophytes: Insights into the metabolisms of two Ochromonas species (Chrysophyceae) through a comparison of gene expression

Cited by 44 publications

References 48 publications

Intraguild predation enables coexistence of competing phytoplankton in a well‐mixed water column

Intraguild predation enables coexistence of competing phytoplankton in a well‐mixed water column

Importance of integrating mixoplankton into marine ecosystem policy and management—Examples from the Marine Strategy Framework Directive

A Revised Interpretation of Marine Primary Productivity in the Indian Ocean: The Role of Mixoplankton

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