Lucinidae Explained

Lucinidae, common name hatchet shells, is a family of saltwater clams, marine bivalve molluscs.

These bivalves are remarkable for their endosymbiosis with sulphide-oxidizing bacteria.[1]

Characteristics

The members of this family have a worldwide distribution. They are found in muddy sand or gravel at or below low tide mark. But they can also be found at bathyal depths. They have characteristically rounded shells with forward-facing projections. The shell is predominantly white and buff and is often thin-shelled. The shells are equivalve with unequal sides. The umbones (the apical part of each valve) are just anterior to mid-line. The adductor scars are unequal: the anterior are narrower and somewhat longer than the posterior. They are partly or largely separated from the pallial line. The valves are flattened and etched with concentric or radial rings. Each valve bears two cardinal and two plate-like lateral teeth. These molluscs do not have siphons but the extremely long foot makes a channel which is then lined with slime and serves for the intake and expulsion of water. The ligament is external and is often deeply inset. The pallial line lacks a sinus.[2]

Fossil record

An Eocene species Superlucina megameris was the largest lucinid ever recorded, with shell size up to high, over wide and thick.[3]

Symbiosis

Lucinids host their sulfur-oxidizing symbionts in specialized gill cells called bacteriocytes.[4] Lucinids are burrowing bivalves that live in environments with sulfide-rich sediments.[5] The bivalve will pump sulfide-rich water over its gills from the inhalant siphon in order to provide symbionts with sulfur and oxygen. The endosymbionts then use these substrates to fix carbon into organic compounds, which are then transferred to the host as nutrients.[6] During periods of starvation, lucinids may harvest and digest their symbionts as food.

Symbionts are acquired via phagocytosis of bacteria by bacterioctyes.[7] Symbiont transmission occurs horizontally, where juvenile lucinids are aposymbiotic and acquire their symbionts from the environment in each generation.[8] Lucinids maintain their symbiont population by reacquiring sulfur-oxidizing bacteria throughout their lifetime.[9] Although process of symbiont acquisition is not entirely characterized, it likely involves the use of the binding protein, codakine, isolated from the lucinid bivalve, Codakia orbicularis.[10] It is also known that symbionts do not replicate within bacteriocytes because of inhibition by the host. However, this mechanism is not well understood.

Lucinid bivalves originated in the Silurian; however, they did not diversify until the late Cretaceous, along with the evolution of seagrass meadows and mangrove swamps.[11] Lucinids were able to colonize these sulfide rich sediments because they already maintained a population of sulfide-oxidizing symbionts. In modern environments, seagrass, lucinid bivalves, and the sulfur-oxidizing symbionts constitute a three-way symbiosis. Because of the lack of oxygen in coastal marine sediments, dense seagrass meadows produce sulfide-rich sediments by trapping organic matter that is later decomposed by sulfate-reducing bacteria.[12] The lucinid-symbiont holobiont removes toxic sulfide from the sediment, and the seagrass roots provide oxygen to the bivalve-symbiont system.

The symbionts from at least two species of lucinid clams, Codakia orbicularis and Loripes lucinalis, are able to fix nitrogen gas into organic nitrogen.[13] [14]

Genera

The following genera are recognised in the family Lucinidae:[15]

Subfamily Codakiinae Iredale, 1937
Subfamily Fimbriinae Nicol, 1950
Subfamily Leucosphaerinae J. D. Taylor & Glover, 2011
Subfamily Lucininae J. Fleming, 1828
Subfamily Milthinae Chavan, 1969
Subfamily Monitilorinae J. D. Taylor & Glover, 2011
Subfamily Myrteinae Chavan, 1969
Subfamily Pegophyseminae J. D. Taylor & Glover, 2011
Incertae sedis (Subfamily not yet assigned)

References

Notes and References

  1. Taylor. J. D.. Glover. E. A.. Lucinidae (Bivalvia) - the most diverse group of chemosymbiotic molluscs. Zoological Journal of the Linnean Society. 148. 3. 2006-11-24. 421–438. 0024-4082. 10.1111/j.1096-3642.2006.00261.x. free.
  2. Barrett, J. H. and C. M. Yonge, 1958. Collins Pocket Guide to the Sea Shore. P. 161. Collins, London
  3. Book: Convergent Evolution on Earth. Lessons for the Search for Extraterrestrial Life. MIT Press. 2019. 2022-08-23. 67–68. George R. McGhee Jr.. 978-0-262-35418-9.
  4. On the evolutionary ecology of symbioses between chemosynthetic bacteria and bivalves. Applied Microbiology and Biotechnology. 2012-02-22. 0175-7598. 3304057. 22354364. 1–10. 94. 1. 10.1007/s00253-011-3819-9. en. Guus. Roeselers. Irene L. G.. Newton.
  5. Aberrations in bivalve evolution related to photo- and chemosymbiosis. Historical Biology. 1990-01-01. 0891-2963. 289–311. 3. 4. 10.1080/08912969009386528. Adolf. Seilacher. 1990HBio....3..289S .
  6. Thioautotrophic bacterial endosymbionts are degraded by enzymatic digestion during starvation: Case study of two lucinids Codakia orbicularis and C. orbiculata. Microscopy Research and Technique. 2015-02-01. 1097-0029. 173–179. 78. 2. 10.1002/jemt.22458. 25429862. en. Sten. König. Hervé. Le Guyader. Olivier. Gros. 24772017.
  7. Cell proliferation and apoptosis in gill filaments of the lucinid Codakia orbiculata (Montagu, 1808) (Mollusca: Bivalvia) during bacterial decolonization and recolonization. Microscopy Research and Technique. 2012-08-01. 1097-0029. 1136–1146. 75. 8. 10.1002/jemt.22041. 22438018. en. Nathalie H.. Elisabeth. Sylvie D.D.. Gustave. Olivier. Gros. 7250847.
  8. A complex journey: transmission of microbial symbionts. Nature Reviews Microbiology. 2010-03-01. 1740-1526. 2967712. 20157340. 218–230. 8. 3. 10.1038/nrmicro2262. en. Monika. Bright. Silvia. Bulgheresi.
  9. Plasticity of symbiont acquisition throughout the life cycle of the shallow-water tropical lucinid Codakia orbiculata (Mollusca: Bivalvia). Environmental Microbiology. 2012-06-01. 1462-2920. 1584–1595. 14. 6. 10.1111/j.1462-2920.2012.02748.x. en. Olivier. Gros. Nathalie H.. Elisabeth. Sylvie D. D.. Gustave. Audrey. Caro. Nicole. Dubilier. 22672589. 2012EnvMi..14.1584G .
  10. Analysis of a cDNA-derived sequence of a novel mannose-binding lectin, codakine, from the tropical clam Codakia orbicularis. Fish & Shellfish Immunology. 2007-05-01. 498–509. 22. 5. 10.1016/j.fsi.2006.06.013. 17169576. Jean-Philippe. Gourdine. Emilie Juliette. Smith-Ravin.
  11. Evolutionary radiation of shallow-water Lucinidae (Bivalvia with endosymbionts) as a result of the rise of seagrasses and mangroves. Geology. 803–806. 42. 9. 10.1130/g35942.1. S. M.. Stanley. 2014. 2014Geo....42..803S.
  12. A Three-Stage Symbiosis Forms the Foundation of Seagrass Ecosystems. Science. 2012-06-15. 0036-8075. 22700927. 1432–1434. 336. 6087. 10.1126/science.1219973. en. Tjisse van der. Heide. Laura L.. Govers. Jimmy de. Fouw. Han. Olff. Matthijs van der. Geest. Marieke M. van. Katwijk. Theunis. Piersma. Johan van de. Koppel. Brian R.. Silliman. 2012Sci...336.1432V. 27806510. 11370/23625acb-7ec0-4480-98d7-fad737d7d4fe. free.
  13. Petersen. Jillian M.. Kemper. Anna. Gruber-Vodicka. Harald. Cardini. Ulisse. Geest. Matthijs van der. Kleiner. Manuel. Bulgheresi. Silvia. Mußmann. Marc. Herbold. Craig. 2016-10-24. Chemosynthetic symbionts of marine invertebrate animals are capable of nitrogen fixation. Nature Microbiology. en. 2. 1. 16195. 10.1038/nmicrobiol.2016.195. 27775707. 6872982. 2058-5276.
  14. König. Sten. Gros. Olivier. Heiden. Stefan E.. Hinzke. Tjorven. Thürmer. Andrea. Poehlein. Anja. Meyer. Susann. Vatin. Magalie. Mbéguié-A-Mbéguié. Didier. 2016-10-24. Nitrogen fixation in a chemoautotrophic lucinid symbiosis. Nature Microbiology. en. 2. 1. 16193. 10.1038/nmicrobiol.2016.193. 27775698. 2058-5276. free.
  15. Web site: WoRMS - World Register of Marine Species - Lucinidae J. Fleming, 1828 . 2022-11-24 . www.marinespecies.org . en.