Dictyosphaeria Explained

Dictyosphaeria is a genus of green algae (class Ulvophyceae) in the family Siphonocladaceae.[1]

Taxonomy and nomenclature

The genus Dictyosphaeria belongs to the order of Cladophorales and family Siphonocladaceae. It comprises a total of 13 taxonomically recognized species.[2]

Below is a list of taxonomically accepted species from the genus Dictyosphearia:

General morphological description

Thalli

The thalli are composed of visibly hollow hexagonal or polygonal cells; and are monostromatic or polystromatic depending on species. They can be solid or button-shaped at around 1–5 cm; and spherical and club-shaped at 1 cm or more. The size of each cells are around 300 - 500 μm in diameter. Complex rhizoidal system is absent, however, basal cells are firmly attached to the substratum.[3]

The coloration of the macroalgae varies from grass green to bluish.[4]

Cells

Cells are visible to the naked eye. They are minutely determinate, simple or furcate, and tenacular that are structurally cushioned together. Occasionally, tenacular cells may also function as adventitious rhizoids.

Cells are multinucleated and have numerous discoid chloroplasts. Chloroplasts bear single pyrenoid surrounded by starch sheath and divided to two or more portions by traversing thylakoids.

Life history

The life cycle of Dictyosphaeria exhibits both biphasic and isomorphic alternation of generation. This involves quadriflagellate zoospores, as well as isogamous and biflagellate gametes. Asexual reproduction through thalli fragmentation and possible parthenogenesis of gametes which result in smooth surface thalli textures.

In addition, since this macroalgae is a large cell unit, mitotic division and cytokinesis were observed in the development of the zoospores. The unique process of cell division in this genus is observed in a study by Hori and Enomoto (1978). The mitotic spindle is placed centrally at the early course of the zooid differentiation. Prophase nuclei with centrioles were observed to be present during this stage only. Other mitotic stages are observed together in the network cytoplasm [5]

Distribution and habitat

The genus Dictyosphaeria is widely found in the tropical region. Its habitat varies from shallow intertidal to subtidal areas, growing on coral or rocky rubbles in reef flats where they can be the dominant macroalgae. They are commonly found attached to rocky substrate either air-exposed, or submerged in water exposed in waves.[6]

Economic use and natural products

The genus Dictyosphaeria, particularly the species D. cavernosa is used for fish bait and animal feed.[7]

Natural products such as the novel metabolite dictyosphaerin, a bicyclic lipid compound were extracted from Dictyosphaeria, particularly Dictyosphaeria sericea. This compound is being studied for its potential application in both scientific and medical applications.[8] In addition, Dictyosphearia also harbors microorganisms such as the fungal species that belong to the genus Penicillium. A study by Bugni et al. (2008), has shown that isolated fungal specimens from the species Dictyosphaeria versluysii were found to produce novel metabolites including the polyketides dictyosphaeric acids A and B, and the anthraquinone carviolin.[9]

Ecological and anthropogenic impacts

In the Kāne'ohe Bay in Hawai'i, USA, Dictyosphaeria cavernosa are considered as invasive species resulting from continuous discharge of nutrient wastes from coastal communities, as well as reduction in herbivore pressures (such as from fish) in the area.[10] As early as the year 1970, reduced coral cover and increased spatial expansion of Dictyosphaeria cavernosa were already documented in the Kaneohe bay area.[11] Invasion of the macroalgae could be attributed to the simultaneous population growth and watershed development as early as the 1960s, including the phase shift on the bay's reef systems.

In a following study, after a steady increase in abundance of Dictyosphaeria cavernosa for more than 40 years in the Kāne'ohe Bay, the population suddenly experience a tremendous decrease in cover (Year 2006). This depletion in algal cover appears to be the result of an unusually prolonged cloudy and rainy period. Reduction in irradiance may have caused a decrease in biomass of D. cavernosa in the area. However, coral cover remains to be low due to the physical structure of the reef (unstable rocky substrate) which can be difficult for coral larvae recruits to settle.[12]

Bacterioplankton community structure were also found to be influence by Dictyosphaeria genus, specifically, Dictyosphaeria ocellata. When exposed to the macroalgae, the bacterial community structures changes: seven (7) bacterial phylotypes were eliminated, while five (5) phylotypes persisted. Moreover, in the laboratory setting, extracts from D. ocellata where observed to influence the difference in growth rates of bacteria in culture.[13]

External links

  1. https://www.algaebase.org/search/genus/detail/?genus_id=35942
  2. https://www.hawaii.edu/reefalgae/invasive_algae/chloro/dictyosphaeria_cavernosa.htm

Notes and References

  1. See the NCBI webpage on Dictyosphaeria. Data extracted from the Web site: NCBI taxonomy resources . . 2007-03-19.
  2. Web site: Algaebase :: Listing the World's Algae. 2021-12-03. www.algaebase.org.
  3. Web site: Algaebase :: Listing the World's Algae. 2021-12-01. www.algaebase.org.
  4. Web site: Dictyosphaeria cavernosa. 2021-12-03. www.hawaii.edu.
  5. Hori, T., and Enomoto, S.. 1978. Developmental Cytology of Dictyosphaeria cavernosa. II. Nuclear Division during Zooid Formation. Botanica Marina. 21. 8 . 477–481. 10.1515/botm.1978.21.8.477 . 85025487 . De Gruyter.
  6. Book: Coppejans, E., Prathep, A., Leliaert, F., Lewmanomont, K., and De Clerek, O.. Seaweeds of Mu Ko Tha Lae Tai (SE Thailand) Methodologies and field guide to the dominant species. Biodiversity Research and Training Program. 2010. Bangkok 10400, Thailand. 116 and 118. English.
  7. Book: Trono Jr., Gavino C.. Field Guide & Atlas of the Seaweed Resources of the Philippines. Bookmark Inc.. 1997. 971-569-252-4. Makati City, Philippines. English.
  8. Rochfort, S.J., Watson, R., and Capon, R.J.. 1996. Dictyosphaerin: A Novel Bicyclic Lipid from a Southern Australia Marine Green Algae, Dictyosphaeria sericea.. Journal of Natural Products. 59. 12 . 1154–1156. 10.1021/np9605347 . ASC Publication.
  9. Bugni, T.S., Janso, J.E., Williamson, R.T., Feng, X., Bernan, V.S., Greenstein, M., Carter, G.T., Maiese, W.M., and Ireland, C.M.. 2004. Dictyospaeric Acids A and B: New Decalactones from an Undescribed Penicillium sp. Obtained from the Alga Dictyosphaeria versluysii. Journal of Natural Products. 67. 8 . 1396–1399. 10.1021/np049973t . 15332862 . ACS Publication.
  10. Stimson, J., Larned, S.T., and Conklin, E.. 2001. Effects of herbivory, nutrient levels, and introduced algae on the distribution and abundance of the invasive macroalga Dictyosphaeria cavernosa in Kanoehe Bay, Hawaii. Coral Reefs. 19. 4 . 343–357. 10.1007/s003380000123 . 2001CorRe..19..343S . 22961199 . Springer Link.
  11. Book: Banner, A.H., and Bailey, J.. Technical Report 50: The effects of urban pollution upon a coral reef system, a preliminary report.. Hawaii Institute of Marine Biology. 1970. Honolulu. 66.
  12. Stimson, J., and Conklin, E.. 2008. Potential reversal of a phase shift: the rapid decrease in the cover of the invasive green macroalga Dictyosphaeria cavernosa Forsskål on coral reefs in Kåne'ohe Bay, Oahu, Hawai'i. Coral Reefs. 27. 4 . 717–726. 10.1007/s00338-008-0409-0 . 2008CorRe..27..717S . 21555350 .
  13. Sneed, J.M., and Pohnert, G.. 2011. The green macroalga Dictyosphaeria ocellata influences the structure of the bacterioplankton community through differential effects on individual bacterial phylotypes. FEMS Microbiology Ecology. 75. 2 . 242–254. 10.1111/j.1574-6941.2010.01005.x . 21155850 . 2011FEMME..75..242S . free.