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[Nanomia bijuga, originally named Physsophora bijuga, is a species of siphonophore in the family Agalmatidae[1]. The species was first described by Stefano Delle Chiaje in 1844. Nanomia bijuga is a marine invertebrate (Sherlock & Robison, 2000). They are able to swim hundreds of meters throughout the day (Costello et. al, 2015). Nanomia bijuga does not require extensive neurocircuitry for swimming due to its colonial structure (Sutherland et. al, 2019). The species is made up of nectophores, collective single unit organisms that caused Nanomia bijuga to be a colonial organism (Costello et. al, 2015).]

Edited section:

Nanomia bijuga, first described by Stefano Delle Chiaje in 1844 and originally named Physsophora bijuga, is a species of mesopelagic siphonophore in the family Agalmatidae[1]. As with all members of the siphonophorae order, it is a colonial organism comprised of individual zooids[2]. N. bijuga has a fairly broad distribution, and has been observed in the coastal waters off of North America and Europe[3]. The species has been found to occupy both epipelagic and mesopelagic depths[4]. The utilize specialized swimming zooids for both propulsion and escape behaviors[5]. Similar to other siphonophores, Nanomia bijuga employ stinging tentacles for hunting and defense[2]. They primarily feed on small crustaceans, especially krill[6][7].

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Anatomy and morphology

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Nanomia bijuga, like other siphonophores, is made up of genetically identical, but highly specialized, zooids[8]. The organism is comprised of two main body segments: the nectosome on the anterior end and the siphosome as the posterior. The nectosome contains a gas-filled pneumatophore at its end as well as nectophores, bell-shaped structures that assist in locomotion. The siphosome contains zooids specialized for feeding, digestion, reproduction, and protection. These zooids are organized in repeating sequences called cormidia[2]. Each cormidium contains one feeding zooid, the gastrozooid, with multiples of the other zooid types. Gonophores and gonodendrons, the male and female reproductive zooids respectively, occur together in pairs[8].

Each gastrozooid has its own tentillum, which is used to capture and subdue prey. These tentilla house nematocysts, stinging cells that deliver toxins into the prey organism[9]. There are four different types of nematocysts found within the tentilla. Heteronemes, the largest of the nematocysts, possess a wider stinging apparatus than the other types and are primarily found at the proximal end of the tentilla[9]. Haplonemes, the most abundant type, are smaller than heteronemes and structured similarly with open tips for stinging but no distinct spiny shaft[9]. The final two types are desmonemes and rhopalonemes which are both used for adhesion to prey in order to prevent it from escaping as the stinging cells perform their function[9].

A matured pneumatophore of N. bijuga contains five different tissues, two layers of ectoderm, two layers of endoderm, and a layer of ectodermal cells that are not connected to any basement membrane. One set of ectoderm/endoderm layers exists on the outside of the pneumatophore while the other set exists inside the external layer and acts as the gas chamber[2].

Distribution and habitat

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Nanomia bijuga is widely distributed across all major oceans of the world except the Antarctic Ocean[10]. A few of its sighted locations are the Monterey Bay[3][4], the Gulf of Mexico[11], the Sagami Bay of Japan[12], the Hansa Bay of Papua New Guinea[13], and the Bantry Bay of Ireland[14].

Nanomia bijuga is an epi/meso-pelagic species that can vertically migrate up to 1000 in depth, though it predominantly thrives at depths of 200-400m[4]. Their ability for long range vertical migration makes them key contributors to the deep scattering layer[15].

Their abundance is significantly correlated with seasonality and primary production[4]. Notably, sightings coincide at spring phytoplankton blooms in the Sagami Bay[12]. Similarly, collection rates of Nanomia bijuga in the Bantry Bay of Ireland heightened in the months of May-September, with peak density in May/June, which correlated with the annual phytoplankton blooms in the region[14].

Behavior

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Nanomia bijuga employs several strategies to evade predators such as medusas, which typically move linearly. This includes sweeping areas, changing direction, and pulsing rapidly [16]. This rapid escape is facilitated by their use of nectophore thrust [17], which are specialized swimming subunits aiding in propulsion[5]. At certain depths, Nanomia bijuga can change their body shape by retracting their tentacles when disturbed which can also assist in their rapid escape from predators. Another predator escape behavior that Nanomia bijuga use is diel vertical migration (DVM). It is thought that the shallow water and the amount of light may drive this pattern and is a method used to avoid predation [16].

In addition to their escape techniques, Nanomia bijuga exhibit hunting behaviors similar to their escape mechanisms. They are filter feeders that extend their tentacles and when they contact prey, the siphonophore begins its rapid movement and contracts its tentacles with nematocysts, specialized stinging cells, to capture the small organisms, like plankton, and bring them to their body [18]. Unlike many other siphonophores, Nanomia bijuga uses rapid swimming to extend their tentacles [7]. Furthermore, they frequently relocate every few minutes to seek out new prey[18].

Diet

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Some information is still unknown about how deep sea siphonophores consume food, with generally more being known about species that live in more shallow waters. For instance, in a study led by Purcell[7], it was discovered that distinct diets could be associated with 3 unique suborders of siphonophore: the Cystonectae, Physonectae, and Calycophorae.

An example of a deep sea siphonophore from the Physonectae subclass (Marrus orthocanna).

In comparison to the other suborders, organisms in the Physonectae have been shown to consume a larger volume of copepods than fish, ranging anywhere from 14% to 91% of their total diet [7]. Nanomia bijuga, or common siphonophore, is a member of the Phsyonectae suborder. Despite its small size these creatures can play a substantial ecological role in deep-sea food systems. According to MBARI, when there are robust populations of  Nanomia bijuga concentrated in one area, they can collectively eat more krill than several adult whales[6]. Aside from copepods, shrimps have also been documented to make up a large proportion of this siphonophore's diet, as well as decapod larvae and chaetognaths[7].

Taxonomy

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Nanomia bijuga, a species of siphonophore, was first scientifically documented by the French zoologist Félix Dujardin in 1843 [2]. Its initial description marked a significant milestone in the understanding of these colonial marine organisms, shedding light on their complex biology and ecological roles within oceanic ecosystems.[19]

Nanomia bijuga exhibits a distinctive morphology characterized by its elongated, slender colony structure. Comprising a succession of specialized zooids organized in a linear fashion, each component fulfills a specific function essential for the colony's survival[2]. These functions encompass prey capture, propulsion, and reproduction, all orchestrated within a translucent or transparent body, aiding in camouflage amidst its oceanic habitat.[20]

Over time, advancements in genetic analyses, morphological studies, and classification methodologies have prompted revisions in the taxonomy and nomenclature of siphonophores, including Nanomia bijuga[8]. These revisions reflect evolving understandings of their evolutionary relationships, genetic diversity, and ecological adaptations. Consequently, updates in nomenclature serve to refine our comprehension of the intricate relationships between species and their broader taxonomic contexts. [19]

Within the genus Nanomia, Nanomia bijuga maintains close kinship with its counterparts, such as Nanomia cara and Nanomia gracilis. These congeners share similarities in colonial structure and ecological niches, contributing collectively to the diversity and ecological dynamics of marine environments. Through genetic analyses, comparative morphology, and ecological studies, researchers elucidate the evolutionary trajectories and ecological interactions shaping the genus Nanomia, enriching our understanding of siphonophore diversity and marine ecosystem dynamics.[19]

Conservation Status

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As of January 2022, there is no specific information available regarding the conservation status of Nanomia bijuga on the IUCN Red List. Siphonophores, including Nanomia bijuga, are generally not individually assessed for conservation status due to their widespread distribution and lack of direct threats from human activities[20]. However, it's important to note that marine ecosystems, including those inhabited by Nanomia bijuga, face various threats such as habitat degradation, pollution, climate change, and overfishing. These threats can have indirect impacts on siphonophore populations by altering their habitats, disrupting food webs, and affecting oceanic conditions. Population changes in Nanomia bijuga would require specific scientific studies and monitoring efforts, which may be limited due to the challenges of studying and tracking marine organisms, particularly those with pelagic lifestyles like siphonophores. [21]

Conservation efforts aimed at protecting marine ecosystems, reducing pollution, mitigating climate change impacts, and implementing sustainable fishing practices indirectly benefit species like Nanomia bijuga.[22] However, targeted conservation efforts for this species are likely limited by the lack of specific data on its population status and distribution.

In summary, while Nanomia bijuga may not be individually assessed for conservation status, its well-being is intricately linked to the health of marine ecosystems. Conservation actions targeting broader marine conservation goals are essential for safeguarding the habitats and resources upon which Nanomia bijuga and other marine organisms depend.

References

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  1. ^ a b Berrill, N. J. (1930-05). "On the Occurrence and Habits of the Siphonophore, Stephanomia bijuga (Delle Chiaje)". Journal of the Marine Biological Association of the United Kingdom. 16 (3): 753–755. doi:10.1017/s0025315400073069. ISSN 0025-3154. {{cite journal}}: Check date values in: |date= (help)
  2. ^ a b c d e f Church, Samuel H.; Siebert, Stefan; Bhattacharyya, Pathikrit; Dunn, Casey W. (2015-07). "The histology of Nanomia bijuga (Hydrozoa: Siphonophora)". Journal of Experimental Zoology Part B: Molecular and Developmental Evolution. 324 (5): 435–449. doi:10.1002/jez.b.22629. ISSN 1552-5007. PMC 5032985. PMID 26036693. {{cite journal}}: Check date values in: |date= (help)CS1 maint: PMC format (link)
  3. ^ a b "WoRMS - World Register of Marine Species - Nanomia bijuga (Delle Chiaje, 1844)". www.marinespecies.org. Retrieved 2024-03-21.
  4. ^ a b c d Robison, Bruce H.; Reisenbichler, Kim R.; Sherlock, Rob E.; Silguero, Jessica M.B.; Chavez, Francisco P. (1998-08). "Seasonal abundance of the siphonophore, Nanomia bijuga, in Monterey Bay". Deep Sea Research Part II: Topical Studies in Oceanography. 45 (8–9): 1741–1751. doi:10.1016/S0967-0645(98)80015-5. {{cite journal}}: Check date values in: |date= (help)
  5. ^ a b Du Clos, Kevin T.; Gemmell, Brad J.; Colin, Sean P.; Costello, John H.; Dabiri, John O.; Sutherland, Kelly R. (2022-12-06). "Distributed propulsion enables fast and efficient swimming modes in physonect siphonophores". Proceedings of the National Academy of Sciences. 119 (49). doi:10.1073/pnas.2202494119. ISSN 0027-8424. PMC 9894174. PMID 36442124.{{cite journal}}: CS1 maint: PMC format (link)
  6. ^ a b "Common siphonophore • MBARI". MBARI. Retrieved 2024-03-15.
  7. ^ a b c d e Purcell, J. E. (1981-11-01). "Dietary composition and diel feeding patterns of epipelagic siphonophores". Marine Biology. 65 (1): 83–90. doi:10.1007/BF00397071. ISSN 1432-1793.
  8. ^ a b c Dunn, Casey W.; Wagner, Günter P. (2006-12-01). "The evolution of colony-level development in the Siphonophora (Cnidaria:Hydrozoa)". Development Genes and Evolution. 216 (12): 743–754. doi:10.1007/s00427-006-0101-8. ISSN 1432-041X.
  9. ^ a b c d Damian-Serrano, Alejandro; Haddock, Steven H. D.; Dunn, Casey W. (2020-04-02), Shaped to kill: The evolution of siphonophore tentilla for specialized prey capture in the open ocean, doi:10.1101/653345, retrieved 2024-04-04
  10. ^ PAGES, F., & GILI, J. M. Siphonophores (Cnidaria, Hydrozoa) collected during the “Magga Dan” Expedition (1966-67). Chicago
  11. ^ Dorado-Roncancio, Edgar Fernando; Medellín-Mora, Johanna; Mancera-Pineda, José Ernesto; Pizarro-Koch, Matías (2021-12). "Copepods of the off-shore waters of Caribbean Colombian Sea and their response to oceanographic regulators". Journal of the Marine Biological Association of the United Kingdom. 101 (8): 1129–1143. doi:10.1017/S0025315422000133. ISSN 0025-3154. {{cite journal}}: Check date values in: |date= (help)
  12. ^ a b Lindsay, D. J., Hunt, J. C., Hashimoto, J., Fujiwara, Y., Fujikura, K., Miyake, H., & Tsuchida, S. (2000). Submersible observations on the deep-sea fauna of the south-west Indian Ocean: preliminary results for the mesopelagic and near-bottom communities. JAMSTEC J Deep Sea Res, 16, 23-33. Chicago
  13. ^ Pagès, F., Gili, J. M., & Bouillon, J. (1989). The siphonophores (Cnidaria, Hydrozoa) of Hansa Bay, Papua New Guinea. Indo-Malayan Zool, 6, 133-140.
  14. ^ a b Damien Haberlin, Gillian Mapstone, Rob McAllen, Andrea J. McEvoy, & Thomas K. Doyle. (2016). Diversity and occurrence of siphonophores in Irish coastal waters. Biology and Environment: Proceedings of the Royal Irish Academy, 116B(2), 119–129. https://doi.org/10.3318/bioe.2016.12
  15. ^ Barham, Eric G. (1963-05-17). "Siphonophores and the Deep Scattering Layer". Science. 140 (3568): 826–828. doi:10.1126/science.140.3568.826. ISSN 0036-8075.
  16. ^ a b Hunt, James C; Lindsay, Dhugal J (1998). "Observations on behavior of Atolla (Scyphozoa: Coronatae) and Nanomia (Hydrozoa: Physonectae): use of the hypertrophied tentacle in prey capture" (PDF). Plankton Biology & Ecology. 45 (2): 239–242.
  17. ^ Raskoff, K. (2002-12-01). "Foraging, prey capture, and gut contents of the mesopelagic narcomedusa Solmissus spp. (Cnidaria: Hydrozoa)". Marine Biology. 141 (6): 1099–1107. doi:10.1007/s00227-002-0912-8. ISSN 1432-1793.
  18. ^ a b Robison, Bruce H (2004-03-31). "Deep pelagic biology". Journal of Experimental Marine Biology and Ecology. VOLUME 300 Special Issue. 300 (1): 253–272. doi:10.1016/j.jembe.2004.01.012. ISSN 0022-0981.
  19. ^ a b c Schoch CL, et al. NCBI Taxonomy: a comprehensive update on curation, resources and tools. Database (Oxford). 2020: baaa062. PubMed: 32761142 PMC: PMC7408187.https://www.ncbi.nlm.nih.gov/Taxonomy/Browser/wwwtax.cgi?id=168759
  20. ^ a b Church SH, Siebert S, Bhattacharyya P, Dunn CW. (2015). "The histology of Nanomia bijuga (Hydrozoa: Siphonophora)". J Exp Zool B Mol Dev Evol. doi: 10.1002/jez.b.22629. Epub 2015 Jun 2. PMID: 26036693; PMCID: PMC5032985. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5032985/
  21. ^ National Biodiversity Data Centre. (2015). "Taxonomy: Nanomia Bijuga". National Biodiversity Data Centre. https://species.biodiversityireland.ie/profile.php?taxonId=187147&keyword=Jellyfish#:~:text=Global%3A%20Not%20considered%20threatened.
  22. ^ Marine Conservation Society. (2024). "Jellyfish, Helping to Keep Our Ocean Full of Life". Marine Conservation Society United Kingdom. https://www.mcsuk.org/news/jellyfish-helping-to-keep-our-ocean-full-of-life/