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Mixotroph

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A mixotroph is an organism that uses a mix of different sources of energy and carbon, instead of having a single trophic mode. Mixotrophs are situated somewhere on the continuum from complete autotrophy to complete heterotrophy. It is estimated that mixotrophs comprise more than half of all microscopic plankton.[1] There are two types of eukaryotic mixotrophs. There are those with their own chloroplasts – including those with endosymbionts providing the chloroplasts. And there are those that acquire them through kleptoplasty, or through symbiotic associations with prey, or through 'enslavement' of the prey's organelles.[2]

Possible combinations include photo- and chemotrophy, besides litho- and organotrophy, the latter including osmotrophy, phagotrophy and myzocytosis. Mixotrophs can be either eukaryotic or prokaryotic.[3] Mixotrophs can take advantage of different environmental conditions.[4]

A given trophic mode of a mixotroph organism is called obligate when it is indispensable for its growth and maintenance; a trophic mode is facultative when used as a supplemental source.[3] Some organisms have incomplete Calvin cycles, so that they are incapable of fixing carbon dioxide and must use organic carbon sources.

Obligate or facultative

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Organisms may employ mixotrophy obligately or facultatively.

A mixotrophic plant using mycorrhizal fungi to obtain photosynthesis products from other plants

Amongst plants, mixotrophy classically applies to carnivorous, hemi-parasitic and myco-heterotrophic species. However, this characterisation as mixotrophic could be extended to a higher number of clades as research demonstrates that organic forms of nitrogen and phosphorus—such as DNA, proteins, amino-acids or carbohydrates—are also part of the nutrient supplies of a number of plant species.[6]

Mycoheterotrophic plants form symbiotic relationships with mycorrhizal fungi, which provide them with organic carbon and nutrients from nearby photosynthetic plants or soil. They often lack chlorophyll or have reduced photosynthetic capacity. An example is Indian pipe, a white, non-photosynthetic plant that relies heavily on fungal networks for nutrients. Pinesap also taps into fungal networks for sustenance, similar to Indian pipe. Certain orchids, such as Corallorhiza, depend on fungi for carbon and nutrients while developing photosynthetic capabilities (especially in their early stages).

The leaf of a carnivorous plant, Drosera capensis, bending in response to the trapping of an insect
The floating fern Azolla filiculoides hosts a nitrogen-fixing cyanobacteria.

Carnivorous plants are plants that derive some or most of their nutrients from trapping and consuming animals[7] or protozoans, typically insects and other arthropods, and occasionally small mammals and birds. They have adapted to grow in waterlogged sunny places where the soil is thin or poor in nutrients, especially nitrogen, such as acidic bogs.[8]

Hemiparasitic plants are partially parasitic, attaching to the roots or stems of host plants to extract water, nutrients, or organic compounds while still performing photosynthesis. Examples are mistletoe (absorbs water and nutrients from host trees but also photosynthesizes), Indian paintbrush (connects to the roots of other plants for nutrients while maintaining photosynthetic leaves), and Yellow rattle (a root parasite that supplements its nutrition by tapping into host plants).

Some epiphytic plants, which are plants that grow on other plants, absorb organic matter, such as decaying debris or animal waste, through specialized structures while still photosynthesizing. For example, some bromeliads have tank-like leaf structures that collect water and organic debris, absorbing nutrients through their leaves. Also, some epiphytic orchids absorb nutrients from organic matter caught in their aerial roots.

Some plants incorporate algae or cyanobacteria, which provide photosynthetically derived carbon, while the plant also absorbs external nutrients. For example, Azolla filiculoides, is a floating fern that hosts the nitrogen-fixing cyanobacteria Anabaena in its leaves, supplementing nutrient intake while photosynthesizing. This has led to the plant being dubbed a "super-plant", as it can readily colonise areas of freshwater, and grow at great speed - doubling its biomass in as little as 1.9 days.[9]

Mixotrophy is less common among animals than among plants and microbes, but there are many examples of mixotrophic invertebrates and at least one example of a mixotrophic vertebrate.

Bacteria and archaea

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Classifying protists

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Traditional classification of mixotrophic protists

In this diagram, types in open boxes as proposed by Stoecker [21] have been aligned against groups in grey boxes as proposed by Jones.[22][23]
                              DIN = dissolved inorganic nutrients

Several categorization schemes have been suggested to characterize sub-domains within mixotrophy.

Phototrophy verses phagotrophy

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Consider the example of a marine protist with heterotrophic and photosynthetic capabilities: In the breakdown put forward by Jones,[22] there are four mixotrophic groups based on relative roles of phagotrophy and phototrophy.

An alternative scheme by Stoeker[21] also takes into account the role of nutrients and growth factors, and includes mixotrophs that have a photosynthetic symbiont or who retain chloroplasts from their prey. This scheme characterizes mixotrophs by their efficiency.

Constitutive mixotrophs

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Another scheme, proposed by Mitra et al., specifically classifies marine planktonic mixotrophs so that mixotrophy can be included in ecosystem modeling.[23] This scheme classified organisms as:

Pathways used by Mitra et al. to derive functional groups of planktonic protists [23]

Levels in complexity among those different types of protists, according to Mitra et al.[23]
(A) phagotrophic (no phototrophy); (B) phototrophic (no phagotrophy); (C) constitutive mixotroph, with innate capacity for phototrophy; (D) generalist non-constitutive mixotroph acquiring photosystems from different phototrophic prey; (E) specialist non-constitutive mixotroph acquiring plastids from a specific prey type; (F) specialist non-constitutive mixotroph acquiring photosystems from endosymbionts. DIM = dissolved inorganic material (ammonium, phosphate etc.).                               DOM = dissolved organic material

The red arrows indicate additional trophic interactions that can occur when mixotrophy is present

Mixotrophs are especially common in marine environments, where the levels of energy from the sun and nutrients in the water can vary greatly. For example, in nutrient-poor (oligotrophic) waters, mixotrophic phytoplankton supplement their diet by consuming bacteria.[25][26]

The effects of mixotrophy on organic and inorganic carbon pools introduce a metabolic plasticity which blurs the lines between producers and consumers.[27] Prior to the discovery of mixotrophs, it was thought that only organisms with chloroplasts were capable of photosynthesis and vice versa. This additional functional group of plankton, capable of both phototrophy and phagotrophy, provides a further boost in the biomass and energy transfer to higher trophic levels.[28]

Arctic food web with mixotrophy: Yellow arrows indicate flow of energy from the sun to photosynthetic organisms (autotrophs and mixotrophs).[29] Gray arrows indicate flow of carbon to heterotrophs; Green arrows indicate major pathways of carbon flow to or from mixotrophs. HCIL, Strictly heterotrophic ciliates; MCIL, Mixotrophic ciliates; HNF, Heterotrophic nanoflagellates; DOC, Dissolved organic carbon; HDIN, Heterotrophic dinoflagellates.
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  3. ^ a b Eiler A (December 2006). "Evidence for the Ubiquity of Mixotrophic Bacteria in the Upper Ocean: Implications and Consequences". Appl Environ Microbiol. 72 (12): 7431–7. Bibcode:2006ApEnM..72.7431E. doi:10.1128/AEM.01559-06. PMC 1694265. PMID 17028233.
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  5. ^ Schoonhoven, Erwin (January 19, 2000). "Ecophysiology of Mixotrophs" (PDF). Thesis.
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  7. ^ "Carnivorous Plants - Plant Biology". Southern Illinois University.
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