PARTICULARITIES OF THE ANATOMICAL BODY OF CRUCIAN CARP
Abstract
The fish reach the kingdom of creatures, aquatic ridge creatures, a number of bark-like creatures, the birthplace of the bark, the species of crucian carp is extraordinary. The skeleton of fish consists of the axial skeleton of the body, the skeleton of the organs of the swimmers (skeleton of the swimmers), and the skull. The axial skeleton of the crucian carp bears two species: a tulub and a caudal one. Its basis is made up of a spinal column consisting of ridges that are connected to each other, and in the tubular section there are ribs that are spread out on the sides and protect the internal organs of the fish. As a result of our investigations, the specificity of the body shape of the common crucian carp was established. In this case, a complex of standard morphological research methods was put in place. Comprehensive classical morphological and anatomical methods of experimental investigation were used, which included: external examination of the object under investigation, dissection of organs, their outline (color, consistency, shape), identified topography The details of the description of the organism along its contours were photographed, which in the end The bag made it possible to carry out a detailed macroscopic investigation of the somatic system in crucian carp. The body of the crucian carp is usually bilaterally symmetrical and for the description of other organs we have a vicoristic trimeric vimir, then there are three planes. The body of the crucian carp has a flattened head section, a back with a slight ridge, a flattened ventral part of the body and a flattened tail. The color of crucian carp ranges from silver-yellow to bronze depending on the genus. The color is darker in the dorsal part and lower in the ventral part. The crucian carp has its head, body and tail. At the head of the crucian carp, the mouth, nose openings, and eyes are opened. The body and tail of the crucian carp are covered with a brush, which tightly fits one to the other, and ventrally behind the head section a larger plate is formed from the fish from the pectoral swimmers lateromedially. On the body of crucian carp one can see a continuous skin fold along the medial line dorsally along the dorsum, and then it goes ventrally to the anal opening and creates unpaired swimmers. From the anal opening, the male swimmers are ventrally expanded. The main function of swimmers is to regulate the movement of the fish in the singing order and directly, maintaining the balance of the water. The swimmers of crucian carp are dorsal, caudal and anal, and gypsy are thoracic and ventral. On the back of the dorsal part there is an unpaired dorsal swimmer, a long, garneous apology and changes to the side of the tail, whose first exchanges are hard and the first may have serrations on the caudal edge. The tail swimmer looks like a wrapped trapezoid, has two blades, and the tail section ends with it. The paired pectoral swimmer extends caudally from the zebra openings on the sides, and behind it the ventral swimmers protrude ventrally and lie horizontally. The anal swimmer grows ventrally between the body and tail, changing the alignment. On the front of the head, caudally on the sides, a pair of zyabrova slit on the right and left is rotated. It is sculpted vertically and its lower end reaches just below the lip, and is shaped aborally between the body and head. It is covered by a yellow cap, which forms the bulging surface of the head.
References
2. Baxter D, Cohen KE, Donatelli CM, Tytell ED. Internal vertebral morphology of bony fishes matches the mechanical demands of different environments. Ecol Evol. 2022 Nov 18;12(11):e9499. doi: 10.1002/ece3.9499. PMID: 36415873; PMCID: PMC9674476.
3. Bilodeau SM, Schwartz AWH, Xu B, Paúl Pauca V, Silman MR. A low-cost, long-term underwater camera trap network coupled with deep residual learning image analysis. PLoS One. 2022 Feb 2;17(2):e0263377. doi: 10.1371/journal.pone.0263377. PMID: 35108340; PMCID: PMC8809566.
4. Blanton JM, Peoples LM, Gerringer ME, Iacuaniello CM, Gallo ND, Linley TD, Jamieson AJ, Drazen JC, Bartlett DH, Allen EE. Microbiomes of Hadal Fishes across Trench Habitats Contain Similar Taxa and Known Piezophiles. mSphere. 2022 Apr 27;7(2):e0003222. doi: 10.1128/msphere.00032-22. Epub 2022 Mar 21. PMID: 35306867; PMCID: PMC9044967.
5. Colombano DD, Carlson SM, Hobbs JA, Ruhi A. Four decades of climatic fluctuations and fish recruitment stability across a marine-freshwater gradient. Glob Chang Biol. 2022 Sep;28(17):5104-5120. doi: 10.1111/gcb.16266. Epub 2022 Jun 16. PMID: 35583053; PMCID: PMC9545339.
6. Gu H, Wang H, Zhu S, Yuan D, Dai X, Wang Z. Interspecific differences and ecological correlations between scale number and skin structure in freshwater fishes. Curr Zool. 2022 Aug 10;69(4):491-500. doi: 10.1093/cz/zoac059. PMID: 37614923; PMCID: PMC10443616.
7. Gu H, Wang Y, Wang H, He Y, Deng S, He X, Wu Y, Xing K, Gao X, He X, Wang Z. Contrasting ecological niches lead to great postzygotic ecological isolation: a case of hybridization between carnivorous and herbivorous cyprinid fishes. Front Zool. 2021 Apr 21;18(1):18. doi: 10.1186/s12983-021-00401-4. PMID: 33882942; PMCID: PMC8059018.
8. Chiarello M, Auguet JC, Bettarel Y, Bouvier C, Claverie T, Graham NAJ, Rieuvilleneuve F, Sucré E, Bouvier T, Villéger S. Skin microbiome of coral reef fish is highly variable and driven by host phylogeny and diet. Microbiome. 2018 Aug 24;6(1):147. doi: 10.1186/s40168-018-0530-4. PMID: 30143055; PMCID: PMC6109317.
9. Holmes MJ, Venables B, Lewis RJ. Critical Review and Conceptual and Quantitative Models for the Transfer and Depuration of Ciguatoxins in Fishes. Toxins (Basel). 2021 Jul 23;13(8):515. doi: 10.3390/toxins13080515. PMID: 34437386; PMCID: PMC8402393.
10. Herrera MJ, Heras J, German DP. Comparative transcriptomics reveal tissue level specialization towards diet in prickleback fishes. J Comp Physiol B. 2022 Mar;192(2):275-295. doi: 10.1007/s00360-021-01426-1. Epub 2022 Jan 25. PMID: 35076747; PMCID: PMC8894155.
11. Kukuła K, Bylak A. Barrier removal and dynamics of intermittent stream habitat regulate persistence and structure of fish community. Sci Rep. 2022 Jan 27;12(1):1512. doi: 10.1038/s41598-022-05636-7. PMID: 35087139; PMCID: PMC8795198.
12. Langlois J, Guilhaumon F, Baletaud F, Casajus N, De Almeida Braga C, Fleuré V, Kulbicki M, Loiseau N, Mouillot D, Renoult JP, Stahl A, Stuart Smith RD, Tribot AS, Mouquet N. The aesthetic value of reef fishes is globally mismatched to their conservation priorities. PLoS Biol. 2022 Jun 7;20(6):e3001640. doi: 10.1371/journal.pbio.3001640. PMID: 35671265; PMCID: PMC9173608.
13. Lennox RJ, Westrelin S, Souza AT, Šmejkal M, Říha M, Prchalová M, Nathan R, Koeck B, Killen S, Jarić I, Gjelland K, Hollins J, Hellstrom G, Hansen H, Cooke SJ, Boukal D, Brooks JL, Brodin T, Baktoft H, Adam T, Arlinghaus R. A role for lakes in revealing the nature of animal movement using high dimensional telemetry systems. Mov Ecol. 2021 Jul 28;9(1):40. doi: 10.1186/s40462-021-00244-y. Erratum in: Mov Ecol. 2021 Oct 20;9(1):52. PMID: 34321114; PMCID: PMC8320048.
14. Li G, Liu H, Müller UK, Voesenek CJ, van Leeuwen JL. Fishes regulate tail-beat kinematics to minimize speedspecific cost of transport. Proc Biol Sci. 2021 Dec 8;288(1964):20211601. doi: 10.1098/rspb.2021.1601. Epub 2021 Dec 1. PMID: 34847768; PMCID: PMC8634626.
15. Madkour FA, Abdellatif AM, Osman YA, Kandyel RM. Histological and ultrastructural characterization of the dorsoventral skin of the juvenile and the adult starry puffer fish (Arothron stellatus, Anonymous 1798). BMC Vet Res. 2023 Oct 24;19(1):221. doi: 10.1186/s12917-023-03784-0. PMID: 37875870; PMCID: PMC10598996.
16. Minich JJ, Härer A, Vechinski J, Frable BW, Skelton ZR, Kunselman E, Shane MA, Perry DS, Gonzalez A, McDonald D, Knight R, Michael TP, Allen EE. Host biology, ecology and the environment influence microbial biomass and diversity in 101 marine fish species. Nat Commun. 2022 Nov 17;13(1):6978. doi: 10.1038/s41467-022-34557-2. PMID: 36396943; PMCID: PMC9671965.
17. Monk CT, Bekkevold D, Klefoth T, Pagel T, Palmer M, Arlinghaus R. The battle between harvest and natural selection creates small and shy fish. Proc Natl Acad Sci U S A. 2021 Mar 2;118(9):e2009451118. doi: 10.1073/pnas.2009451118. PMID: 33619086; PMCID: PMC7936276.
18. Pennock CA, Ahrens ZT, McKinstry MC, Budy P, Gido KB. Trophic niches of native and nonnative fishes along a river-reservoir continuum. Sci Rep. 2021 Jun 9;11(1):12140. doi: 10.1038/s41598-021-91730-1. PMID: 34108584; PMCID: PMC8190098.
19. Popper AN, Hawkins AD. An overview of fish bioacoustics and the impacts of anthropogenic sounds on fishes. J Fish Biol. 2019 May;94(5):692-713. doi: 10.1111/jfb.13948. Epub 2019 Apr 5. PMID: 30864159; PMCID: PMC6849755.
20. Oakley-Cogan A, Tebbett SB, Bellwood DR. Habitat zonation on coral reefs: Structural complexity, nutritional resources and herbivorous fish distributions. PLoS One. 2020 Jun 4;15(6):e0233498. doi: 10.1371/journal.pone.0233498. PMID: 32497043; PMCID: PMC7272040.
21. Soh M, Tay YC, Lee CS, Low A, Orban L, Jaafar Z, Seedorf H. The intestinal digesta microbiota of tropical marine fish is largely uncultured and distinct from surrounding water microbiota. NPJ Biofilms Microbiomes. 2024 Feb 19;10(1):11. doi: 10.1038/s41522-024-00484-x. PMID: 38374184; PMCID: PMC10876542.
22. Segner H, Bailey C, Tafalla C, Bo J. Immunotoxicity of Xenobiotics in Fish: A Role for the Aryl Hydrocarbon Receptor (AhR)? Int J Mol Sci. 2021 Aug 31;22(17):9460. doi: 10.3390/ijms22179460. PMID: 34502366; PMCID: PMC8430475.
23. Tang SL, Liang XF, He S, Li L, Alam MS, Wu J. Comparative Study of the Molecular Characterization, Evolution, and Structure Modeling of Digestive Lipase Genes Reveals the Different Evolutionary Selection Between Mammals and Fishes. Front Genet. 2022 Aug 4;13:909091. doi: 10.3389/fgene.2022.909091. PMID: 35991544; PMCID: PMC9386070.
24. Torgersen KT, Bouton BJ, Hebert AR, Kleyla NJ, Plasencia X 2nd, Rolfe GL, Tagliacollo VA, Albert JS. Phylogenetic structure of body shape in a diverse inland ichthyofauna. Sci Rep. 2023 Nov 25;13(1):20758. doi: 10.1038/s41598-023-48086-5. PMID: 38007528; PMCID: PMC10676429.
25. Xu L, Xiang P, Zhang B, Yang K, Liu F, Wang Z, Jin Y, Deng L, Gan W, Song Z. Host Species Influence the Gut Microbiota of Endemic Cold-Water Fish in Upper Yangtze River. Front Microbiol. 2022 Jul 18;13:906299. doi: 10.3389/fmicb.2022.906299. PMID: 35923412; PMCID: PMC9339683.
26. Verberk WCEP, Sandker JF, van de Pol ILE, Urbina MA, Wilson RW, McKenzie DJ, Leiva FP. Body mass and cell size shape the tolerance of fishes to low oxygen in a temperature-dependent manner. Glob Chang Biol. 2022 Oct;28(19):5695-5707. doi: 10.1111/gcb.16319. Epub 2022 Jul 25. PMID: 35876025; PMCID: PMC9542040.
27. Ziarati M, Zorriehzahra MJ, Hassantabar F, Mehrabi Z, Dhawan M, Sharun K, Emran TB, Dhama K, Chaicumpa W, Shamsi S. Zoonotic diseases of fish and their prevention and control. Vet Q. 2022 Dec;42(1):95-118. doi: 10.1080/01652176.2022.2080298. PMID: 35635057; PMCID: PMC9397527.
28. Zhang Y, Lauder GV. Energy conservation by collective movement in schooling fish. Elife. 2024 Feb 20;12:RP90352. doi: 10.7554/eLife.90352. PMID: 38375853; PMCID: PMC10942612.
29. Wen CKC, Chen KS, Tung WC, Chao A, Wang CW, Liu SL, Ho MJ. The influence of tourism-based provisioning on fish behavior and benthic composition. Ambio. 2019 Jul;48(7):779-789. doi: 10.1007/s13280-018-1112-1. Epub 2018 Nov 3. PMID: 30390226; PMCID: PMC6509303.
30. Wei F, Ito K, Sakata K, Asakura T, Date Y, Kikuchi J. Fish ecotyping based on machine learning and inferred network analysis of chemical and physical properties. Sci Rep. 2021 Feb 12;11(1):3766. doi: 10.1038/s41598-021-83194-0. PMID: 33580151; PMCID: PMC7881121.
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