Hippospongia communis

Last updated

Hippospongia communis
Scientific classification Red Pencil Icon.png
Kingdom: Animalia
Phylum: Porifera
Class: Demospongiae
Order: Dictyoceratida
Family: Spongiidae
Genus: Hippospongia
Species:
H. communis
Binomial name
Hippospongia communis
(Lamarck, 1814)

Hippospongia communis also known as the honeycomb bath sponge, is a marine sponge in the phylum Porifera.

Contents

Hippospongia communis is a brown or darker color [1] and very porous, due to its many oscules, and is commonly found in shallow waters of the Mediterranean. Throughout history, H. communis has been used for cleaning, medicine, and cooking. Along with being used for domestic purposes, the bath sponge has been used in many scientific studies.

Environment

The most common areas that Hippospongia communis inhabit are marine waters, mostly in the Western Mediterranean [2] or the South Aegean Sea. [3] Specifically in the Mediterranean, the Hippospongia communis is the most common sponge. [4] The sponge settles on rocky or muddy bottoms and it is common to find them in ocean caves. Hippospongia communis like being in shallow water, around 15 m deep. The few individual H. communis that are found at the deeper depths are typically older. [1] [5]

History

Hippospongia communis has many oscules that are scattered and grouped along the top of the sponge. Its porous structure and spongey exterior made it perfect for people throughout history, as far back as 1900 BC, to use it as a household item. In particular, the honeycomb bath sponge was used for things like cleaning, hygiene, cooking and agriculture in Rome.

In Greek civilization, having the Hippospongia communis was an important status symbol. They included it in their pottery and literature.

The Egyptians also used the Hippospongia communis many ways. They used the sponge to create texture on walls when painting.

Other ways that Hippospongia communis was put to use were in medicine. H. communis was used for contraception, surgery and waking people from anesthesia. H. communis was also used in cosmetics.

Due to its popularity, the sponge community was threatened due to fisheries harvesting these sponges. Fishermen overfishing these sponges were causing harmful diseases to their populations. They were fished to the point of extinction, and the waters of the Mediterranean are still feeling the repercussions. [6]

Characteristics

Hippospongia communis is usually a large, rounded sponge that has a yellowish brown color. The size of the bath sponge varies but the larger they are, the more expensive they can be. H.communis has a skeleton that is made out of elements such as O, I, Al, Cl, and Si. [7] It has many oscules, making the sponge very porous. It is likely that the H. communis sponges have other organisms living within these oscules. Many organism such as crustaceans and worms are typical organisms found within the sponge. [8] These sponges are a great habitats to sustain other kinds of life.

Hippospongia communis has a bioactive compound that makes it anti-fungal. This is due to untensopongin B, making the sponge perfect for its uses in old medicine. [2] [6]

Reproduction

Hippospongia communis sexually reproduces year round. The sponge is also hermaphroditic, [9] meaning it has both male and female reproductive organs at the same time.

It has been found that during its sexual reproduction, regardless of the location, the Hippospongia communis eggs will fertilize at the same time. The bath sponge reproduction times are all synced throughout different locations that the H. communis inhabit. The larva has a planktonic, free-living stage then the sponge larvae eventually adjusts on the sea floor, usually on rough surfaces. Many times, the larvae does not survive these first few stages. [10]

Research

Because of the abundance and absorbency of these sponges, Hippospongia communis has been used on a variety of different studies. One study looked how the sponge was able to immobilize laccase due to ocean pollution. It is very important that the spongin in the Hippospongia communis could do this and not degrade, like other materials had. [11]

Related Research Articles

<span class="mw-page-title-main">Sponge</span> Animals of the phylum Porifera

Sponges, the members of the phylum Porifera, are a basal animal clade as a sister of the diploblasts. They are multicellular organisms that have bodies full of pores and channels allowing water to circulate through them, consisting of jelly-like mesohyl sandwiched between two thin layers of cells.

Fragmentation in multicellular or colonial organisms is a form of asexual reproduction or cloning, where an organism is split into fragments. Each of these fragments develops into mature, fully grown individuals that are clones of the original organism.

Spongin, a modified type of collagen protein, forms the fibrous skeleton of most organisms among the phylum Porifera, the sponges. It is secreted by sponge cells known as spongocytes.

<span class="mw-page-title-main">Sponge reef</span>

Sponge reefs are reefs formed by Hexactinellid sponges, which have a skeleton made of silica, and are often referred to as glass sponges. Such reefs are now very rare, and found only in waters off the coast of British Columbia, Washington and southern Alaska. Recently sponge reefs were identified within the strait of Georgia and Howe sound close to Vancouver. Although common in the late Jurassic period, reef-building sponges were believed to have gone extinct during or shortly after the Cretaceous period, until the existing reefs were discovered Queen Charlotte sound in 1987–1988 – hence these sometimes being dubbed living fossils.

<span class="mw-page-title-main">Sponge diving</span> Diving to gather natural sponges

Sponge diving is underwater diving to collect soft natural sponges for human use.

<i>Spongia officinalis</i> Species of sponge

Spongia officinalis, better known as a variety of bath sponge, is a commercially used sea sponge. Individuals grow in large lobes with small openings and are formed by a mesh of primary and secondary fibers. It is light grey to black in color. It is found throughout the Mediterranean Sea up to 100 meters deep on rocky or sandy surfaces.

<i>Callyspongia aculeata</i> Species of sponge

Callyspongia (Cladochalina) aculeata, commonly known as the branching vase sponge is a species of Porifora, meaning sea sponge, in the family Callyspongiidae. Poriferans are typically characterized by ostia, pores that filter out plankton, with an osculum as the opening which water leaves through, and choanocytes trap food particles.

<i>Myxilla incrustans</i> Species of sponge

Myxilla incrustans is a species of demosponge. It is an encrusting species and is usually yellow.

Sea sponge aquaculture is the process of farming sea sponges under controlled conditions. It has been conducted in the world's oceans for centuries using a number of aquaculture techniques. There are many factors such as light, salinity, pH, dissolved oxygen and the accumulation of waste products that influence the growth rate of sponges. The benefits of sea sponge aquaculture are realised as a result of its ease of establishment, minimum infrastructure requirements and the potential to be used as a source of income for populations living in developing countries. Sea sponges are produced on a commercial scale to be used as bath sponges or to extract biologically active compounds which are found in certain sponge species. Techniques such as the rope and mesh bag method are used to culture sponges independently or within an integrated multi-trophic aquaculture system setting. One of the only true sustainable sea sponges cultivated in the world occur in the region of Micronesia, with a number of growing and production methods used to ensure and maintain the continued sustainability of these farmed species.

<i>Sphaerechinus granularis</i> Species of sea urchin

Sphaerechinus granularis is a species of sea urchin in the family Toxopneustidae, commonly known as the violet sea urchin, or sometimes the purple sea urchin. Its range includes the Mediterranean Sea and eastern Atlantic Ocean.

<i>Sterechinus neumayeri</i> Species of sea urchin

Sterechinus neumayeri, the Antarctic sea urchin, is a species of sea urchin in the family Echinidae. It is found living on the seabed in the waters around Antarctica. It has been used as a model organism in the fields of reproductive biology, embryology, ecology, physiology and toxicology.

<i>Callyspongia truncata</i> Species of sponge

Callyspongia truncata is a species of marine sea sponge. Like all marine sponges, C. truncata is a member of phylum Porifera and is defined by its filter-feeding lifestyle and flagellated choanocytes, or collar cells, that allow for water movement and feeding. It is a species of demosponge and a member of Demospongiae, the largest class of sponges as well as the family Callyspongiidae. C. truncata is most well known for being the organism from which the polyketide Callystatin A was identified. Callystatin A is a polyketide natural product from the leptomycin family of antibiotics. It was first isolated in 1997 from this organism, which was collected from the Goto Islands in the Nagasaki Prefecture of Japan by the Kobayashi group. Recent studies have revealed numerous other bioactive compounds that have been found in this species.

Oscarella carmela, commonly known as the slime sponge, is a species of sponge in the order Homosclerophorida that was first described in 2004 by G. Muricy and J.S. Pearse. It is believed to be native to intertidal waters in the north east temperate Pacific Ocean and was first found in seawater aquaria in that region. It is used as a model organism in evolutionary biology.

<i>Spicara maena</i> Species of fish

Spicara maena, the blotched picarel, is a species of ray-finned fish native to the eastern Atlantic Ocean, the Mediterranean Sea and the Black Sea. The male grows to a maximum length of about 25 cm (10 in), and the female reaches 21 cm (8 in). This fish is fished commercially in some areas.

<i>Callyspongia crassa</i> Species of sponge

Callyspongia crassa, commonly known as prickly tube-sponge, is a species of sponge found from the Red Sea to the Seychelles. Its wide flexible brown tube with exterior protuberances can appear as a single tube or as clusters of tubes and can reach up to 50 centimeters in size. Like many other sea sponges, it is primarily used for marine drugs as they have many bioactive components and properties. They also play an important role in marine reef and benthic communities, as they constantly filter water and act as habitats for smaller organisms. As sea sponges, they have the ability to reproduce both sexually and asexually.

<i>Geodia barretti</i> Species of sponge

Geodia barretti is a massive deep-sea sponge species found in the boreal waters of the North Atlantic Ocean, and is fairly common on the coasts of Norway and Sweden. It is a dominant species in boreal sponge grounds. Supported by morphology and molecular data, this species is classified in the family Geodiidae.

<i>Aquilonastra burtoni</i> Species of starfish

Aquilonastra burtoni is a species of small sea star from the family Asterinidae from the Red Sea which has colonised the eastern Mediterranean by Lessepsian migration through the Suez Canal, although the Mediterranean populations are clonal reproducing through fissiparous asexual reproduction. It was originally described in 1840 by the English zoologist and philatelist John Edward Gray.

<i>Aplysina cavernicola</i> Species of sponge

Aplysina cavernicola is a species of sponge in the family Aplysinidae. It is native to the Mediterranean Sea where it grows in caves and under overhangs.

Calcifibrospongiidae is a family of sponges belonging to the order Haplosclerida. The order Haplosclerida is distinguished by isodictyal skeleton. In general, Porifera are basal animals with bodies full of pores and channels. Calcifibrospongiidae includes the species Calcifibrospongia actinostromarioides. There have only been ten recorded occurrences of this species: in Hogsty Reef and San Salvador, as well as in the subtropics of the Bahamas.

Oopsacas minuta is a glass sponge that is a member of the Hexactinellida. Oopsacas minuta is found in submarine caves in the Mediterranean. It is reproductive year-round. This species is a part of a class that are usually bathyal and abyssal. Meaning they grow at a depth over 200 meters. At this depth the temperature is low and constant, so silica metabolism is optimized. However, this species has been observed in shallow water. O. minuta have only been observed by exploring caves that trap cold water. The shape of the sponge is elongated, cylindrical and a little flared. It is between a few millimeters and 3.5 centimeters. O. minuta are white are held up with a siliceous skeleton. The spicules of the skeleton intersect in an intricate network. These spindles partially block the top of the sponge. There are no obvious oscules. The sponge is anchored or suspended from the cave by silica fibers. This class of sponge is different from the three other classes of Porifera. It differs in tissue organization, ecology, development and physiology. O. minuta belongs to the order Lyssacinosida. Lyssacinosida are characterized by the parenchymal spicules mostly being unconnected; this is unlike other sponges in the subclass where the spicules form a connected skeleton. The genome of O. minuta are one of the smallest of all the animal genomes that have been sequenced so far. Its genome contains 24 noncoding genes and 14 protein-encoding genes. The spindles of O. minuta have three axes and six points. This species does not have pinacocytes, which are the cells that form the outer layer in other sponges. Instead of true choanocytes it has frill structures that bud from the syncytium.

References

  1. 1 2 Castritsi-Catharios, J.; Miliou, H.; Pantelis, J. (2005). "Experimental sponge fishery in Egypt during recovery from sponge disease". Aquatic Conservation: Marine and Freshwater Ecosystems. 15 (2): 109–116. doi:10.1002/aqc.658.
  2. 1 2 De Caralt, Sònia; Otjens, Henri; Uriz, María J.; Wijffels, René H. (2007). "Cultivation of Sponge Larvae: Settlement, Survival, and Growth of Juveniles". Marine Biotechnology. 9 (5): 592–605. doi:10.1007/s10126-007-9013-5. PMID   17624577. S2CID   12603409.
  3. Castritsi-Catharios, J.; Miliou, H.; Kapiris, K.; Kefalas, E. (2011). "Recovery of the commercial sponges in the central and southeastern Aegean Sea (NE Mediterranean) after an outbreak of sponge disease". Mediterranean Marine Science. 12: 5. doi: 10.12681/mms.50 .
  4. Castritsi-Catharios, J.; Zaoutsos, S.P.; Berillis, P.; Zouganelis, G.D.; Ekonomou, G.; Kefalas, E.; Pantelis, J. (2017). "Kalymnos, the island which made history in sponge fishery. Data on physical parameters, elemental composition and DNA barcode preliminary results of the most common bath sponge species in Aegean Sea". Regional Studies in Marine Science. 13: 71–79. doi:10.1016/j.rsma.2017.04.002.
  5. "Hippospongia communis (Lamarck 1814)." Global Biodiversity Information Society. https://www.gbif.org/species/2238339. Accessed 25 March 2019.
  6. 1 2 Pronzato, Roberto; Manconi, Renata (2008). "Mediterranean commercial sponges: Over 5000 years of natural history and cultural heritage". Marine Ecology. 29 (2): 146–166. Bibcode:2008MarEc..29..146P. doi: 10.1111/j.1439-0485.2008.00235.x .
  7. Norman, Małgorzata; Bartczak, Przemysław; Zdarta, Jakub; Ehrlich, Hermann; Jesionowski, Teofil (2016). "Anthocyanin dye conjugated with Hippospongia communis marine demosponge skeleton and its antiradical activity". Dyes and Pigments. 134: 541–552. doi:10.1016/j.dyepig.2016.08.019.
  8. "11 Representative types of sponges." Biology Discussion. http://www.biologydiscussion.com/invertebrate-zoology/sponges/11-representative-types-of-sponges/28552. Accessed 25 March 2019.
  9. "Hippospongia communis (Lamarch 1813)." Sea Life Base. https://www.sealifebase.ca/summary/Hippospongia-communis.html. Accessed 25 March 2019.
  10. Zarrouk, Souad; Ereskovsky, Alexander V.; Mustapha, Karim Ben; Abed, Amor El; Pérez, Thierry (2013). "Sexual reproduction of Hippospongia communis(Lamarck, 1814) (Dictyoceratida, Demospongiae): Comparison of two populations living under contrasting environmental conditions" (PDF). Marine Ecology. 34 (4): 432–442. Bibcode:2013MarEc..34..432Z. doi:10.1111/maec.12043.
  11. Zdarta, Jakub; Antecka, Katarzyna; Frankowski, Robert; Zgoła-Grześkowiak, Agnieszka; Ehrlich, Hermann; Jesionowski, Teofil (2018). "The effect of operational parameters on the biodegradation of bisphenols by Trametes versicolor laccase immobilized on Hippospongia communis spongin scaffolds". Science of the Total Environment. 615: 784–795. Bibcode:2018ScTEn.615..784Z. doi:10.1016/j.scitotenv.2017.09.213. PMID   28992503.
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.