Periphyton

Periphyton is a complex mixture of algae, cyanobacteria, heterotrophic microbes, and detritus that is attached to submerged surfaces in most aquatic ecosystems. The related term Aufwuchs (German "surface growth" or "overgrowth", pronounced [ˈaʊ̯fˌvuːks] ^ⓘ) refers to the collection of small animals and plants that adhere to open surfaces in aquatic environments, such as parts of rooted plants.

Periphyton serves as an important food source for invertebrates, tadpoles, and some fish. It can also absorb contaminants, removing them from the water column and limiting their movement through the environment. The periphyton is also an important indicator of water quality; responses of this community to pollutants can be measured at a variety of scales representing physiological to community-level changes. Periphyton has often been used as an experimental system in, e.g., pollution-induced community tolerance studies.

Composition

In both marine and freshwater environments, algae – particularly green algae and diatoms – make up the dominant component of surface growth communities. Small crustaceans, rotifers, and protozoans are also commonly found in fresh water and the sea, but insect larvae, oligochaetes and tardigrades are peculiar to freshwater aufwuchs faunas.^{[citation needed]}

Growth

Periphyton can contain species of cyanobacteria that are toxic to humans and other animals.^[1] In fresh water, excessive growth and subsequent death and decay of periphyton can have undesirable effects: depleting oxygen in the water, altering its pH, and clogging the space between gravel and sand (the hyporheic zone). These effects, known as eutrophication, can impair or kill fishes and other animals, reduce the quality of drinking water, and make waterways unappealing for recreation. Remediating the damage to biodiversity and ecosystems caused by excessive periphyton growth costs billions of doillars annually.^[2]

Conversely, periphyton can be damaged by urbanization: the increased turbidity levels associated with urban sprawl can smother periphyton, causing it to detach from the rocks on which it lives.

Uses

Periphyton communities are used in aquaculture food production systems for the removal of solid and dissolved pollutants. Their performance in filtration is established and their application as aquacultural feed is being researched. It can be important for the clearance of harmful chemicals and reducing turbidity.^{[citation needed]}

Water quality

Periphyton serves as an indicator of water quality^[3] because:

It has a naturally high number of species.
It has a fast response to changes.
It is easy to sample.
It is known for tolerance/sensitivity to change.

Food source

Many aquatic animals feed extensively on periphyton. The mbuna cichlids from Lake Malawi are particularly well known examples of fish adapted for feeding on periphyton. Examples include Labeotropheus trewavasae and Pseudotropheus zebra. They have scraper-like teeth that allow them to rasp the periphyton from rocks.^[4] In marine communities, periphyton food sources are important for animals such as limpets and sea urchins. ^{[citation needed]} Another amphibian that feasts on periphyton are spring peepers, small chorus frogs that occupy many ponds throughout Canada and the eastern United States.^[5]^[6] Spring peepers filter periphyton from the environmental surfaces of their habitat.^[5]

References

^ O’Neil, J. M.; Davis, T. W.; Burford, M. A.; Gobler, C. J. (2012-02-01). "The rise of harmful cyanobacteria blooms: The potential roles of eutrophication and climate change". Harmful Algae. Harmful Algae--The requirement for species-specific information. 14: 313–334. doi:10.1016/j.hal.2011.10.027. ISSN 1568-9883.
^ McDowell, R. W.; Noble, A.; Pletnyakov, P.; Haggard, B. E.; Mosley, L. M. (2020-02-27). "Global mapping of freshwater nutrient enrichment and periphyton growth potential". Scientific Reports. 10 (1): 3568. doi:10.1038/s41598-020-60279-w. ISSN 2045-2322.
^ [1], EPA - Periphyton Protocols
^ Aufwuchs
^ ^a ^b Skelly, David K. (1995). "Competition and the distribution of spring peeper larvae". Oecologia. 103 (2): 203–207. Bibcode:1995Oecol.103..203S. doi:10.1007/BF00329081. ISSN 0029-8549. PMID 28306774. S2CID 22425047.
^ "Northern Spring Peeper / Rainette Crucifère". Opinicon Natural History. 2009-09-17. Retrieved 2022-11-29.

External links

Marine Biological Laboratory Sustainable Aquaculture Initiative Developing plant-based fish diets and pond management protocols for the Comprehensive Development Project (CODEP) in L’Acul, Haiti^{[dead link]}
Macrophyte and Periphyton lab
Fishbase definition of aufwuchs

[1] O’Neil, J. M.; Davis, T. W.; Burford, M. A.; Gobler, C. J. (2012-02-01). "The rise of harmful cyanobacteria blooms: The potential roles of eutrophication and climate change". Harmful Algae. Harmful Algae--The requirement for species-specific information. 14: 313–334. doi:10.1016/j.hal.2011.10.027. ISSN 1568-9883.

[2] McDowell, R. W.; Noble, A.; Pletnyakov, P.; Haggard, B. E.; Mosley, L. M. (2020-02-27). "Global mapping of freshwater nutrient enrichment and periphyton growth potential". Scientific Reports. 10 (1): 3568. doi:10.1038/s41598-020-60279-w. ISSN 2045-2322.

[#1-3] [1], EPA - Periphyton Protocols

[4] Aufwuchs

[:0-5] Skelly, David K. (1995). "Competition and the distribution of spring peeper larvae". Oecologia. 103 (2): 203–207. Bibcode:1995Oecol.103..203S. doi:10.1007/BF00329081. ISSN 0029-8549. PMID 28306774. S2CID 22425047.

[6] "Northern Spring Peeper / Rainette Crucifère". Opinicon Natural History. 2009-09-17. Retrieved 2022-11-29.

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