User:ZachRumley/Stomiidae/Bibliography

Bibliography- dragonfish lure

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-Herring, Peter J., & Cope, Celia (2005). “Red bioluminescence in fishes: on the suborbital photophores of Malacosteus, Pachystomias and Aristostomias.” Marine Biology, Volume 148, pp 383-394. https://doi.org/10.1007/s00227-005-0085-3

-Kenaley, Christopher P., DeVaney, Shannon C., & Fjeran, Taylor T (2013).  “The Complex Evolutionary History of Seeing Red: Molecular Phylogeny And The Evolution of an Adaptive Visual System in Deep-sea Dragonfishes (Stomiiformes: Stomiidae).” Evolution, Volume 68 (Issue 4), pp 996-1013.  https://doi.org/10.1111/evo.12322

-Mallefet, Jerome, et al. (2019). “Luminescence control of Stomiidae photophores.” Acta Histochemica, Volume 121 (Issue 1), pp 7-15. https://doi.org/10.1016/j.acthis.2018.10.001

-McClintock, Jack (2004). “Splendor in the Dark.” Discover, Volume 25 (Issue 5). https://www.drtulsian.com/interestingReading/biology/splendor_in_the_dark.pdf

-Velasco-Hogan, Audrey, et al. (2019). “On the Nature of the Transparent Teeth of the Deep-Sea Dragonfish, Aristostomias scintillans. Matter, Volume 1 (Issue 1), pp 235-249. https://doi.org/10.1016/j.matt.2019.05.010

Bibliography - Evolution of Sensory Organs

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Douglas, R. H., Mullineaux, C. W., & Partridge, J. C. (2000). Long-wave sensitivity in deep-sea stomiid dragonfish with far-red bioluminescence: evidence for a dietary origin of the chlorophyll-derived retinal

photosensitizer of Malacosteus niger. Philosophical transactions of the Royal Society of London. Series B, Biological sciences, 355(1401), 1269–1272. https://doi.org/10.1098/rstb.2000.0681


Eastman, J. T., & Lannoo, M. J. (2003). Diversification of brain and sense organ morphology in Antarctic dragonfishes (Perciformes: Notothenioidei: Bathydraconidae). Journal of morphology, 258(2), 130–150. https://doi.org/10.1002/jmor.10140


Kenaley, C. P. (n.d.). The complex evolutionary history of seeing red ... - wordpress.com. The Complex Evolutionary History of seeing Red: Molecular Phylogeny and the Evolution of an Adaptive Visual System in Deep-sea Dragonfish (Stomiiformes:Stomiidae). Retrieved March 3, 2023, from https://kenaleylabcom.files.wordpress.com/2017/09/kenaley_2014_rhoevolution.pdf


University of Rhode Island. (2016, August 19). New discovery about sensory system of deep-sea fish. ScienceDaily. Retrieved March 3, 2023 from www.sciencedaily.com/releases/2016/08/160819162350.htm


Wagner, Hans-Joachim. "Localisation and origin of the bacteriochlorophyll-derived photosensitizer in the retina of the deep-sea dragon fish Malacosteus niger."

Bibliography: Jaw Morphology

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  1. Kenaley, C.P. 2012. Exploring feeding behaviour in deep-sea dragonfishes (Teleostei: Stomiidae): jaw biomechanics and functional significance of a loosejaw. Biological Journal of the Linnean Society, 106(1),224–240. doi:10.1111/j.1095-8312.2012.01854.x
    • The jaw morphology of deep-sea dragonfish is adapted to capture large prey; being long with large fang like teeth. The function of the “loose jaw” was examined to look at its mechanical properties and it was found that forces that resist lower jaw adduction was greater in fish with shorter jaws. As such dragonfish were found to attain fast adduction velocities due to a drastic reduction in resistive forces. Additionally, adductor mass is decreased as not as much mass is needed to achieve such high velocity. This adaptation, the loosejaw, allows for dragonfish to be more competitive when hunting for prey. This all is very interesting as it makes sense for a deep sea organism to exhibit decreased muscle mass in order to reduce metabolic expenditures. This article will be good to start in terms of talking about the jaw of dragonfish and how it has evolved morphologically to survive in the deep sea.
  2. Velasco-Hogan, A., Deheyn, D. D., Koch, M., Nothdurft, B., Arzt, E., & Meyers, M. A. (2019). On the nature of the transparent teeth of the deep-sea dragonfish, Aristostomias Scintillans. Matter, 1(1), 235–249. doi:10.1016/j.matt.2019.05.010
    • Many deep sea dragonfish exhibit transparent teeth. This paper finds that the transparent teeth is due to a mixture of nanocrystalline and amorphous phases. It contributes to reduced light scattering leading to what is seen as transparent teeth. This allows them to thrive in the aphotic zone as they do not appear to have teeth/ be a threat. Their teeth is also really hard and stiff (more than piranhas and great white sharks. This article highlights the evolutionary adaptation of the dragonfish teeth in order to make them efficient predators who are able to thrive in regions of low food availability. Having knowledge of both jaw structure and teeth makeup is important to understand and infer the feeding behaviors of these fish and how they hunt for their prey in zones of the ocean that are very scarce in food.
  3. Walker, Y., Walker, Y., & Zanger, K. (2009). On the structure of teeth in the viperfish Chauliodus sloani Bloch & Schneider, 1801 (Stomiidae)*. Bulletin of Fish Biology, 11, 87–98. doi:10.1016/j.matt.2019.06.015
    • This article looks at the structure of teeth of specific species of dragonfish. It looks at the specific materials that make up the teeth and includes imaging of the structure of the teeth. Looking at the teeth as the means through which dragonfish feed on their prey, the article highlights the length and rigidity of the teeth and the need to open its mouth very wide. This connects well with the Kenaley article that looks at the biomechanics of the jaw and how it is able to open it so wide. The article also talks about the attachment of teeth to the jaw which is interesting to examine in terms of jaw morphology. Understanding the attachment of teeth to the jaw can highlight the functionality of attachment. Different articles show slightly altered attachment of the teeth to the jaw which allows for questions to be brought up about the advantages and disadvantages that such attachment style will concur.
  4. Germain, D., Schnell, N. K., & Meunier, F. J. (2019). Histological data on bone and teeth in two dragonfishes (Stomiidae; Stomiiformes): Borostomias panamensis Regan & Trewavas, 1929 and Stomias boa Reinhardt, 1842. Cybium, 43, 103-107. https://www.researchgate.net/profile/Damien-Germain/publication/332253739_Histological_data_on_bone_and_teeth_in_two_dragonfishes_Stomiidae_Stomiiformes_Borostomiaspanamensis_Regan_Trewavas_1929_and_Stomias_boa_Reinhardt_1842/links/5cde782592851c4eaba6ad3b/Histological-data-on-bone-and-teeth-in-two-dragonfishes-Stomiidae-Stomiiformes-Borostomiaspanamensis-Regan-Trewavas-1929-and-Stomias-boa-Reinhardt-1842.pdf
    • This article examines both the bone and teeth makeup of two species of stomiidae. It found that the species have long and sharp teeth as supported by other articles as well as elongated jaw bones. Also found the teeth to be partially hinged and incompletely fused to their bony support with unmineralized ligament that connects the tooth to the jaw. This article provides another source that looks at both the teeth and jaw of dragonfish and how it allows them to feed on large prey and survive. Focusing on a specific species of dragonfish provides additional insight into how stomiidae have evolved to have such interesting adaptations. The article gives specific examples of bone and teeth makeup which is important as it allows for the narrowing down of the topic of interest from broad to specific.
  5. Schnell, N. K., & Johnson, G. D. (2017). Evolution of a functional head joint in deep-sea fishes (Stomiidae). PLoS One, 12(2), e0170224. doi: 10.1371/journal.pone.0170224
    • This article looks at the head joint of deep-sea dragonfish (stomiidae). Stomiidae have their pectoral girdle separated from the skull as well as a flexible connection between the occiput and the first vertebra (notochordal occipito-vertebral gap). The article discusses the functional relevance of such formations which contribute to the dragonfish’s ability to consume such large prey. This is an interesting article as it provides additional information on the way the jaw has adapted in order to allow stomiidae to survive in the deep sea. However, unlinke the other articles, this one focuses on the head joint and how that in conjunction with the long, partially unhinged jaw allow the dragonfish to prey on larger organisms and effectively hunt them to survive.
  6. Schnell, N. K., Britz, R., & Johnson, G. D. (2010). New insights into the complex structure and ontogeny of the occipito‐vertebral gap in barbeled dragonfishes (Stomiidae, Teleostei). Journal of Morphology, 271(8), 1006-1022.
    • This is another source that looks into the flexible head joint of members of the stomiidae family.
  7. Gilbert, P. U., & Stifler, C. A. (2019). See-Through Teeth, Clearly. Matter, 1(1), 27-29

Bibliography

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Dragonfish Behavior

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  1. Christopher P. Kenaley, Shannon C. DeVaney, Taylor T. Fjeran, THE COMPLEX EVOLUTIONARY HISTORY OF SEEING RED: MOLECULAR PHYLOGENY AND THE EVOLUTION OF AN ADAPTIVE VISUAL SYSTEM IN DEEP‐SEA DRAGONFISHES (STOMIIFORMES: STOMIIDAE), Evolution, Volume 68, Issue 4, 1 April 2014, Pages 996–1013, https://doi.org/10.1111/evo.12322
  2. Douglas, R., Partridge, J., Dulai, K. et al. Dragon fish see using chlorophyll. Nature 393, 423–424 (1998). https://doi.org/10.1038/30871
  3. EVANS, C., CZIKO, P., CHENG, C., & DEVRIES, A. (2005). Spawning behaviour and early development in the naked dragonfish Gymnodraco acuticeps. Antarctic Science, 17(3), 319-327. doi:10.1017/S0954102005002749
  4. Jens Hellinger, Peter Jägers, Marcel Donner, Franziska Sutt, Melanie D. Mark, Budiono Senen, Ralph Tollrian, Stefan Herlitze. The Flashlight Fish Anomalops katoptron Uses Bioluminescent Light to Detect Prey in the Dark. (2017). https://doi.org/10.1371/journal.pone.0170489
  5. Marshall, N. J. "Communication Behavior: Visual Signals." https://ecovis.org.au/wp-content/uploads/2019/02/2011_Rosenthal__Marshall_Encyclopedia_Fish_Physiology.pdf

Bibliography- Habitats

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Coad, B. & Reist, J. (2017). Marine Fishes of Arctic Canada. Toronto: University of Toronto Press. https://doi.org/10.3138/9781442667297

Cochran, & Yager, Patricia L., editor. (2019). Encyclopedia of ocean sciences (Third edition..). Academic Press. https://doi.org/10.1016/B978-0-12-409548-9.11212-6

Desvignes, T., Postlethwait, J. H., & Konstantinidis, P. (2020). Biogeography of the antarctic dragonfishes Acanthodraco dewitti and Psilodraco breviceps with re-description of  Acanthodraco dewitti (Notothenioidei: Bathydraconidae). Polar Biology, 43(5), 565-572. doi:https://doi.org/10.1007/s00300-020-02661-y

Eduardo, L. N., Lucena-Frédou, F., Mincarone, M. M., Soares, A., Le Loc'h, F., Frédou, T., Ménard, F., & Bertrand, A. (2020). Trophic ecology, habitat, and migratory behaviour of the viperfish Chauliodus sloani reveal a key mesopelagic player. Scientific Reports, 10(1), 20996. https://doi.org/10.1038/s41598-020-77222-8

Gibbs, R. H., & Smithsonian Institution. (1969). Taxonomy, sexual dimorphism, vertical distribution, and evolutionary zoogeography of the bathypelagic fish genus Stomias (Stomiatidae) Ser. Smithsonian contributions to zoology, no. 31. Smithsonian Institution