Ectocarpus siliculosus: Difference between revisions
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{{Short description|Species of brown alga}} |
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| regnum = [[Chromalveolata]] |
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| image = Ectocarpus_siliculosus.jpg |
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| divisio = [[Heterokontophyta]] |
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'''''Ectocarpus siliculosus''''' is a filamentous [[brown alga]] ([[Heterokontophyta]]).<ref>{{cite journal | last1 = Charrier | first1 = B | last2 = Coelho | first2 = SM | last3 = Le Bail | first3 = A | last4 = Tonon | first4 = T | last5 = Michel | first5 = G | last6 = Potin | first6 = P | last7 = Kloareg | first7 = B | last8 = Boyen | first8 = C | last9 = Peters | first9 = AF | title = Development and physiology of the brown alga Ectocarpus siliculosus: two centuries of research | url = | journal = The New phytologist | volume = 177 | issue = 2 | pages = 319–32 | year = 2008| pmid = 18181960 | doi = 10.1111/j.1469-8137.2007.02304.x }}</ref> Its genome was the first brown macroalgal genome to be sequenced,<ref>{{cite doi|10.1038/nature09016}}</ref> with the expectation that ''E. siliculosus'' will serve as a genetic and genomic model for brown macroalgae.<ref>[http://www.genoscope.cns.fr/spip/Ectocarpus-siliculosus,740.html Genoscope - ''Ectocarpus'' genome project] at [[genoscope]] |
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'''''Ectocarpus siliculosus''''' is a filamentous [[brown alga]].<ref name="Charrier_2008">{{cite journal | vauthors = Charrier B, Coelho SM, Le Bail A, Tonon T, Michel G, Potin P, Kloareg B, Boyen C, Peters AF, Cock JM | display-authors = 6 | title = Development and physiology of the brown alga Ectocarpus siliculosus: two centuries of research | journal = The New Phytologist | volume = 177 | issue = 2 | pages = 319–332 | date = January 2008 | pmid = 18181960 | doi = 10.1111/j.1469-8137.2007.02304.x | url = https://hal.archives-ouvertes.fr/hal-01806426/file/Charrier%20et%20al.%2C%20submitted%20version.pdf }}</ref> Its genome was the first brown macroalgal genome to be sequenced,<ref name="Cock_2010">{{cite journal | vauthors = Cock JM, Sterck L, Rouzé P, Scornet D, Allen AE, Amoutzias G, Anthouard V, Artiguenave F, Aury JM, Badger JH, Beszteri B, Billiau K, Bonnet E, Bothwell JH, Bowler C, Boyen C, Brownlee C, Carrano CJ, Charrier B, Cho GY, Coelho SM, Collén J, Corre E, Da Silva C, Delage L, Delaroque N, Dittami SM, Doulbeau S, Elias M, Farnham G, Gachon CM, Gschloessl B, Heesch S, Jabbari K, Jubin C, Kawai H, Kimura K, Kloareg B, Küpper FC, Lang D, Le Bail A, Leblanc C, Lerouge P, Lohr M, Lopez PJ, Martens C, Maumus F, Michel G, Miranda-Saavedra D, Morales J, Moreau H, Motomura T, Nagasato C, Napoli CA, Nelson DR, Nyvall-Collén P, Peters AF, Pommier C, Potin P, Poulain J, Quesneville H, Read B, Rensing SA, Ritter A, Rousvoal S, Samanta M, Samson G, Schroeder DC, Ségurens B, Strittmatter M, Tonon T, Tregear JW, Valentin K, von Dassow P, Yamagishi T, Van de Peer Y, Wincker P | display-authors = 6 | title = The Ectocarpus genome and the independent evolution of multicellularity in brown algae | journal = Nature | volume = 465 | issue = 7298 | pages = 617–21 | date = June 2010 | pmid = 20520714 | doi = 10.1038/nature09016 | bibcode = 2010Natur.465..617C | s2cid = 4329490 | doi-access = free }}</ref> with the expectation that ''E. siliculosus'' will serve as a genetic and genomic model for brown macroalgae.<ref name="CEA">{{Cite web|last=CEA|date=2020-10-01|title=Genoscope - National Center of Sequencing|url=https://www.cea.fr/drf/ifrancoisjacob/english/Pages/Departments/Genoscope.aspx|access-date=2021-04-20|website=CEA/François Jacob Institute of biology|language=en}}</ref> |
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The alga is unbranched and filamentous; it forms soft beards on larger plants or other firm substrata and grows up to 2 feet long.<ref>Gosner, Kenneth L., Atlantic Seashore: A field guide to sponges, jellyfish, sea urchins, and more; Houghton Mifflin Co.</ref> |
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! colspan="2" |[[Taxonomy (biology)|Scientific classification]] |
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|[[SAR supergroup|SAR]] |
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|[[Ochrophyta]] |
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|Species: |
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|'''''E. siliculosus''''' |
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! colspan="2" |[[Binomial nomenclature|Binomial name]] |
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([[Lewis Weston Dillwyn|Dillwyn]]) [[Hans Christian Lyngbye|Lyngbye]] 1819 |
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[[File:Ectocarpus_siliculosus_sur_Ulva.jpg|thumb|A close up image of ''E. siliculosus'' that shows its many filaments]] |
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== Ecology == |
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Plants tufted, often only one to a few cm tall, but in exceptional cases up to 20 cm. Axes freely branched, main axis not distinguishable. Filaments up to 30μm in diameter, tapering toward the apices. sometimes forming terminal pseudohairs. Distribution: Cosmopolitan.<ref>Stegenga, H. Bolton, J.J. and Anderson, R.J. Seaweeds of the South African West Coast; Contributions from the Bolus Herbarium Number 18, 1997.</ref> |
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The brown algae are members of the [[Stramenopile|stramenopiles]] (along with organisms such as [[diatoms]] and [[Oomycete|oomycetes]]).<ref name="Coelho_2012">{{cite journal | vauthors = Coelho SM, Scornet D, Rousvoal S, Peters NT, Dartevelle L, Peters AF, Cock JM | title = Ectocarpus: a model organism for the brown algae | journal = Cold Spring Harbor Protocols | volume = 2012 | issue = 2 | pages = 193–8 | date = February 2012 | pmid = 22301644 | doi = 10.1101/pdb.emo065821 | doi-access = free }}</ref> The stramenopiles diverged from other major eukaryotic groups such as the [[Opisthokont|opisthokonts]] (animals and fungi) and the [[archaeplastida]] (which includes land plants) over a billion years ago.<ref name="Charrier_2008" /> The brown algae are also important because they are one of only a small number of eukaryotic groups that have evolved complex multicellularity.<ref name="Coelho_2012" /> |
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The alga is unbranched and filamentous;<ref name="Coelho_2012" /> it forms soft beards on larger plants or other firm substrata and grows up to 2 feet long.<ref name="Le_Bail_2010">{{cite journal | vauthors = Le Bail A, Billoud B, Kowalczyk N, Kowalczyk M, Gicquel M, Le Panse S, Stewart S, Scornet D, Cock JM, Ljung K, Charrier B | display-authors = 6 | title = Auxin metabolism and function in the multicellular brown alga Ectocarpus siliculosus | journal = Plant Physiology | volume = 153 | issue = 1 | pages = 128–44 | date = May 2010 | pmid = 20200071 | pmc = 2862433 | doi = 10.1104/pp.109.149708 }}</ref> Its [[thallus]] is filamentous, initially organized as a main primary filament composed of elongated cells and round cells, from which branches differentiate.<ref name="Le_Bail_2010" /> E. siliculosus is a tufted plant, often only one to a few cm tall, but in exceptional cases up to 20 cm.<ref name="Charrier_2008" /> It has axes that are freely branched, and the main axis is not distinguishable.<ref name="Cock_2015">{{cite book | vauthors = Cock JM | chapter = Emergence of Ectocarpus as a Model System to Study the Evolution of Complex Multicellularity in the Brown Algae|date=2015 | title = Evolutionary Transitions to Multicellular Life| series = Advances in Marine Genomics|volume=2|pages=153–162| veditors = Ruiz-Trillo I, Nedelcu AM, Godfroy O, Strittmatter M, Scornet D, Uji T, Farnham G, Peters AF, Coelho SM |place=Dordrecht|publisher=Springer Netherlands|doi=10.1007/978-94-017-9642-2_8|isbn=978-94-017-9641-5 }}</ref> Filaments on E. siliculosus can grow up to 30μm in diameter, tapering toward the apices and sometimes forming terminal pseudo hairs.<ref name="Cock_2015" /> |
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== Reproduction == |
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E. siliculosus reproduction and growth involves two different patterns of early development, which begin with either a symmetric or an asymmetric division of the initial cell.<ref name="Luthringer_2014" /> Symmetric division leads to the development of a prostrate, basal structure before the erect thallus is formed.<ref name="Cock_2010" /> Asymmetric division leads to the immediate development of an erect thallus without the formation of a prostrate, basal structure (immediate differentiation).<ref name="Peters_2008">{{cite journal | vauthors = Peters AF, Scornet D, Ratin M, Charrier B, Monnier A, Merrien Y, Corre E, Coelho SM, Cock JM | display-authors = 6 | title = Life-cycle-generation-specific developmental processes are modified in the immediate upright mutant of the brown alga Ectocarpus siliculosus | journal = Development | volume = 135 | issue = 8 | pages = 1503–12 | date = April 2008 | pmid = 18339673 | doi = 10.1242/dev.016303 | s2cid = 207151096 | doi-access = free }}</ref> E. siliculosus alternates between two generational life cycles that differ in either being [[Sporophyte|sporophytes]] ( produce few laterals and develop from a branched prostrate base) or [[gametophytes]] ( richly branched and devoid of a prostrate base).<ref name="Peters_2008" /> E. siliculosus gametophytes have an asymmetric initial cell division and immediate differentiation of an erect thallus. The alternation of the two different generations in E. siliculosus therefore alternates between symmetric and asymmetric cell divisions as well.<ref name="Peters_2008" /> |
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* [http://www.algaebase.org/search/species/detail/?species_id=1368 ''E. siliculosus'' on algaebase.org] |
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E. siliculosus develops uniseriate filaments. It has a sporophyte body which is made up of the prostrate body and the upright body.<ref name="Peters_2008" /> The prostrate body is in turn composed of crawling filaments ( crawling filaments are made of Elongated (E) cells and Round (R) cells) which is a filament with E cells on the edges and R cells in the center.<ref name="Peters_2008" /> Then, there is a period of secondary growth in which axes develop in the center of the primary filament and on the R cells.<ref name="Peters_2008" /> The upright filaments will grow from the prostrate body and differentiate into [[Sporangium|sporangia]].<ref name="Le_Bail_2010" /> |
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== E. siliculosus in Research == |
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Brown algae have many unique characteristics in terms of their metabolism and cell biology. Ergo, brown algae and in particular, E. siliculosus, are often used for explorative research. Its genome was the first brown macroalgal genome to be sequenced, with the expectation that E. siliculosus will serve as a genetic and genomic model for brown macroalgae.<ref name="Luthringer_2014" /> In 2004, many laboratories, including the Station Biologique in Roscoff and Genoscope, began to sequence the genome of E. siliculosus.<ref name="Charrier_2008" /> |
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Ectocarpus has been used by researchers to study the evolution of complex multicellularity in brown algae. With the study of Ectocarpus came the discovery of multiple genetic and genomic resources that apply to all species of brown algae. Before, the lack of both the proper tools to study genome data and genome data itself halted the progress of understanding brown algal developmental processes at the molecular level.<ref name="Cock_2015" /> However, due to Ectocarpus being less complex, it is easier to study.<ref name="Cock_2015" /> |
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{{Phaeophyceae-stub}} |
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== Iron Storage and Bonding == |
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E. siliculosus is able to accumulate high concentrations of iodide from seawater.<ref name="CEA" /> The carbon storage system of brown algae is unusual, involving the accumulation of reserves of [[mannitol]] and the β-1,3-glucan laminarin rather than α-1,4-glucans such as starch or glycogen.<ref name="Coelho_2012" /> The mannitol pathway was probably most likely a speciation event in the brown algal lineage via a horizontal transfer event from [[Actinomycetota|actinobacteria]], along with another key metabolic pathway in brown algae, alginate biosynthesis.<ref name="Coelho_2012" /> |
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[[fr:Ectocarpus siliculosus]] |
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[[ja:シオミドロ]] |
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This species of Ectocarpus has been shown to bind iron on its cells with non-specificity.<ref name="Luthringer_2014">{{Cite journal| vauthors = Luthringer R, Cormier A, Ahmed S, Peters AF, Cock JM |date=2014-06-01|title=Sexual dimorphism in the brown algae|url=http://www.schweizerbart.de/papers/pip/detail/1/83012/Sexual_dimorphism_in_the_brown_algae?af=crossref|journal=Perspectives in Phycology|language=en|volume=1|issue=1|pages=11–25|doi=10.1127/2198-011X/2014/0002|issn=2198-011X}}</ref> This iron ion shell allows the algae to store and have a constant source of iron regardless of the conditions of the surrounding environment. This adaptation is important because this method of iron uptake is similar to that of terrestrial organisms and differs from the methods typically used in the marine environment such as [[Siderophore|siderophores]].<ref name="Luthringer_2014" /> |
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[[pl:Ectocarpus siliculosus]] |
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== Sexual Characteristics == |
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Ectocarpus is a species known for its evolution of sex-based gene expression. It has also been found to have a low level of phenotypic [[sexual dimorphism]].<ref name="Luthringer_2014" /> Having a low level of sexual dimorphism means that two sexes of a species do not have different characteristics. This has been backed up by the findings that Ectocarpus has female genes that evolve as rapidly as their male genes.<ref name="Luthringer_2014" /> This is also backed up by the findings that the consistency in the patterns that scientists found with its sexual systems relating to UV haploid systems.<ref name="Luthringer_2014" /> |
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{{Taxonbar|from=Q2703732}} |
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Latest revision as of 00:35, 6 April 2022
| Ectocarpus siliculosus | |
|---|---|
| |
| E. siliculosus, from the Brockhaus and Efron Encyclopedic Dictionary (1890-1907) | |
Scientific classification 
| |
| Domain: | Eukaryota |
| Clade: | Diaphoretickes |
| Clade: | SAR |
| Clade: | Stramenopiles |
| Phylum: | Gyrista |
| Subphylum: | Ochrophytina |
| Class: | Phaeophyceae |
| Order: | Ectocarpales |
| Family: | Ectocarpaceae |
| Genus: | Ectocarpus |
| Species: | E. siliculosus
|
| Binomial name | |
| Ectocarpus siliculosus | |
Ectocarpus siliculosus is a filamentous brown alga.[1] Its genome was the first brown macroalgal genome to be sequenced,[2] with the expectation that E. siliculosus will serve as a genetic and genomic model for brown macroalgae.[3]
| Scientific classification | |
|---|---|
| Clade: | SAR |
| Phylum: | Ochrophyta |
| Class: | Phaeophyceae |
| Order: | Ectocarpales |
| Family: | Ectocarpaceae |
| Genus: | Ectocarpus |
| Species: | E. siliculosus |
| Binomial name | |
| Ectocarpus siliculosus | |
Ecology[edit]
The brown algae are members of the stramenopiles (along with organisms such as diatoms and oomycetes).[4] The stramenopiles diverged from other major eukaryotic groups such as the opisthokonts (animals and fungi) and the archaeplastida (which includes land plants) over a billion years ago.[1] The brown algae are also important because they are one of only a small number of eukaryotic groups that have evolved complex multicellularity.[4]
The alga is unbranched and filamentous;[4] it forms soft beards on larger plants or other firm substrata and grows up to 2 feet long.[5] Its thallus is filamentous, initially organized as a main primary filament composed of elongated cells and round cells, from which branches differentiate.[5] E. siliculosus is a tufted plant, often only one to a few cm tall, but in exceptional cases up to 20 cm.[1] It has axes that are freely branched, and the main axis is not distinguishable.[6] Filaments on E. siliculosus can grow up to 30μm in diameter, tapering toward the apices and sometimes forming terminal pseudo hairs.[6]
Reproduction[edit]
E. siliculosus reproduction and growth involves two different patterns of early development, which begin with either a symmetric or an asymmetric division of the initial cell.[7] Symmetric division leads to the development of a prostrate, basal structure before the erect thallus is formed.[2] Asymmetric division leads to the immediate development of an erect thallus without the formation of a prostrate, basal structure (immediate differentiation).[8] E. siliculosus alternates between two generational life cycles that differ in either being sporophytes ( produce few laterals and develop from a branched prostrate base) or gametophytes ( richly branched and devoid of a prostrate base).[8] E. siliculosus gametophytes have an asymmetric initial cell division and immediate differentiation of an erect thallus. The alternation of the two different generations in E. siliculosus therefore alternates between symmetric and asymmetric cell divisions as well.[8]
E. siliculosus develops uniseriate filaments. It has a sporophyte body which is made up of the prostrate body and the upright body.[8] The prostrate body is in turn composed of crawling filaments ( crawling filaments are made of Elongated (E) cells and Round (R) cells) which is a filament with E cells on the edges and R cells in the center.[8] Then, there is a period of secondary growth in which axes develop in the center of the primary filament and on the R cells.[8] The upright filaments will grow from the prostrate body and differentiate into sporangia.[5]
E. siliculosus in Research[edit]
Brown algae have many unique characteristics in terms of their metabolism and cell biology. Ergo, brown algae and in particular, E. siliculosus, are often used for explorative research. Its genome was the first brown macroalgal genome to be sequenced, with the expectation that E. siliculosus will serve as a genetic and genomic model for brown macroalgae.[7] In 2004, many laboratories, including the Station Biologique in Roscoff and Genoscope, began to sequence the genome of E. siliculosus.[1]
Ectocarpus has been used by researchers to study the evolution of complex multicellularity in brown algae. With the study of Ectocarpus came the discovery of multiple genetic and genomic resources that apply to all species of brown algae. Before, the lack of both the proper tools to study genome data and genome data itself halted the progress of understanding brown algal developmental processes at the molecular level.[6] However, due to Ectocarpus being less complex, it is easier to study.[6]
Iron Storage and Bonding[edit]
E. siliculosus is able to accumulate high concentrations of iodide from seawater.[3] The carbon storage system of brown algae is unusual, involving the accumulation of reserves of mannitol and the β-1,3-glucan laminarin rather than α-1,4-glucans such as starch or glycogen.[4] The mannitol pathway was probably most likely a speciation event in the brown algal lineage via a horizontal transfer event from actinobacteria, along with another key metabolic pathway in brown algae, alginate biosynthesis.[4]
This species of Ectocarpus has been shown to bind iron on its cells with non-specificity.[7] This iron ion shell allows the algae to store and have a constant source of iron regardless of the conditions of the surrounding environment. This adaptation is important because this method of iron uptake is similar to that of terrestrial organisms and differs from the methods typically used in the marine environment such as siderophores.[7]
Sexual Characteristics[edit]
Ectocarpus is a species known for its evolution of sex-based gene expression. It has also been found to have a low level of phenotypic sexual dimorphism.[7] Having a low level of sexual dimorphism means that two sexes of a species do not have different characteristics. This has been backed up by the findings that Ectocarpus has female genes that evolve as rapidly as their male genes.[7] This is also backed up by the findings that the consistency in the patterns that scientists found with its sexual systems relating to UV haploid systems.[7]
References[edit]
- ^ a b c d Charrier B, Coelho SM, Le Bail A, Tonon T, Michel G, Potin P, et al. (January 2008). "Development and physiology of the brown alga Ectocarpus siliculosus: two centuries of research" (PDF). The New Phytologist. 177 (2): 319–332. doi:10.1111/j.1469-8137.2007.02304.x. PMID 18181960.
- ^ a b Cock JM, Sterck L, Rouzé P, Scornet D, Allen AE, Amoutzias G, et al. (June 2010). "The Ectocarpus genome and the independent evolution of multicellularity in brown algae". Nature. 465 (7298): 617–21. Bibcode:2010Natur.465..617C. doi:10.1038/nature09016. PMID 20520714. S2CID 4329490.
- ^ a b CEA (2020-10-01). "Genoscope - National Center of Sequencing". CEA/François Jacob Institute of biology. Retrieved 2021-04-20.
- ^ a b c d e Coelho SM, Scornet D, Rousvoal S, Peters NT, Dartevelle L, Peters AF, Cock JM (February 2012). "Ectocarpus: a model organism for the brown algae". Cold Spring Harbor Protocols. 2012 (2): 193–8. doi:10.1101/pdb.emo065821. PMID 22301644.
- ^ a b c Le Bail A, Billoud B, Kowalczyk N, Kowalczyk M, Gicquel M, Le Panse S, et al. (May 2010). "Auxin metabolism and function in the multicellular brown alga Ectocarpus siliculosus". Plant Physiology. 153 (1): 128–44. doi:10.1104/pp.109.149708. PMC 2862433. PMID 20200071.
- ^ a b c d Cock JM (2015). "Emergence of Ectocarpus as a Model System to Study the Evolution of Complex Multicellularity in the Brown Algae". In Ruiz-Trillo I, Nedelcu AM, Godfroy O, Strittmatter M, Scornet D, Uji T, Farnham G, Peters AF, Coelho SM (eds.). Evolutionary Transitions to Multicellular Life. Advances in Marine Genomics. Vol. 2. Dordrecht: Springer Netherlands. pp. 153–162. doi:10.1007/978-94-017-9642-2_8. ISBN 978-94-017-9641-5.
- ^ a b c d e f g Luthringer R, Cormier A, Ahmed S, Peters AF, Cock JM (2014-06-01). "Sexual dimorphism in the brown algae". Perspectives in Phycology. 1 (1): 11–25. doi:10.1127/2198-011X/2014/0002. ISSN 2198-011X.
- ^ a b c d e f Peters AF, Scornet D, Ratin M, Charrier B, Monnier A, Merrien Y, et al. (April 2008). "Life-cycle-generation-specific developmental processes are modified in the immediate upright mutant of the brown alga Ectocarpus siliculosus". Development. 135 (8): 1503–12. doi:10.1242/dev.016303. PMID 18339673. S2CID 207151096.