+Advanced Search
Home > Archive>Volume 23, Issue 1, 2016 >90-103
PDF HTML XML Export Cite reminder
Histological studies on post-embryonic development of the digestive system in larval, juvenile, and young Liza haematocheila
CSTR:
[cstr]
Author:
Affiliation:

1. Key Laboratory of South China Sea Fishery Resources Exploitation & Utilization, Ministry of Agriculture; South China Sea Fisheries Research Institute, Chinese Academy of Fishery Sciences, Guangzhou 510300, China; 2. College of Fisheries and Life Scienc

Clc Number:

S917

  • Article
    • | |
  • Metrics
    • |
  • Reference [1]
    • |
  • Related [20]
    • |
  • Cited by [0]
    • | |
  • Comments
    Abstract:

    Liza haematocheila is a fish species with potential economic value; therefore, it is important to study the developmentof L. haematocheila larvae, juveniles, and young. In this study, the digestive system of Liza haematocheilafrom 1 to 39 days post-hatching (dph) was morphologically observed by light microscopy, and developmental characteristicswere described. The results showed that digestive tracts of the newly hatched larvae at 20–22℃ were composedof a single tube for digestion. At 4 dph, the upper and lower jaws appeared, and the yolk sac was absorbed. Thegastrointestinal tract was generated in coils by the digestive tract. The stomachic prototype came out of the first coils,and the following coils formed into the foregut and hindgut. At 7 dph, the yolk sac was completely absorbed, and the oilglobule were absorbed fairly well and disappeared; the post-larvae individuals obtained nutrition by exogenous feeding.At 8 dph, the digestive system was clearly differentiated into organs such as the esophagus, stomach, intestine, rectum,liver, and pancreas. At this time, nutritional requirements of the larvae gradually transitioned from endogenous to exogenous.Subsequently, with larval growth, the digestive tract changed to have increased wrinkles in the mucous layer,thickened walls, and a bigger cavity. From 15 dph to 18 dph, elongation of the digestive tract, deeper folds, and increasein the absorption surface were observed. At 18 dph, the pyloric caeca was formed, and gastric glands were observed,which indicates the beginning of digesting exogenous protein. Meanwhile, the intestinal epithelial cells further differentiated,the muscle continually thickened, and the intestines became segmented and circular. The larval feeding habitsbegan to change to herbivory. Subsequently, the digestive system gradually improved both functionally and structurally.As of 18 dph, the juveniles had rapid increase in body length by exogenous nutrition. These results showed that L.haematocheila digestive system development was consistent with functional improvement.

    Reference
    [1] Cahu C, Zambonino Infante J, Takeuchi T. Nutritionalcomponents affecting skeletal development in fish larvae[J].Aquaculture, 2003, 227(1-4): 245−258.
    [2] Battaglene S C, Cobcroft J M, Yellowtail kingfish juvenilequality: Identify timing and nature of jaw deformities inyellowtail kingfish and scope the likely causes of thiscondition[R]. Australian Seafood CRC, 2007: 1−150.
    [3] Hough C. Malformations in the Mediterranean and in coldwater productions[R]. FineFish Final Workshop - Improvingsustainability of European Aquaculture by control ofmalformations. Ghent, Belgium, September 9, 2009.
    [4] Zheng P L,Ma Z H,Guo H Y,et al. Ontogeneticdevelopment of caudal skeletons in Trachinotus ovatuslarvae[J]. South China Fisheries Science, 2014,10(5): 45−49.[郑攀龙, 马振华, 郭华阳, 等. 卵形鲳鲹尾部骨骼胚后发育研究[J]. 南方水产科学, 2014, 10(5): 45−49.]
    [5] Ma Z, Zheng P, Guo H, et al. Jaw malformation of hatcheryreared golden pompano Trachinotus ovatus (Linnaeus 1758)larvae[J]. Aquacult Res, 2014, doi: 10.1111/are.12569.
    [6] Kohno H, Ordonio-Aguilar R, Ohno A, et al. Osteologicaldevelopment of the feeding apparatus in early stage larvae ofthe seabass, Lates calcarifer[J]. Ichthyol Res, 1996, 43(1):1−9.
    [7] Laggis A, Sfakianakis D G, Divanach P, et al. Ontogeny ofthe body skeleton in Seriola dumerili (Risso, 1810)[J]. Ital JZool, 2010, 77(3): 303−315.
    [8] Kohno H. Osteological development of the caudal skeletonin the carangid, Seriola lalandi[J]. Ichthyol Res, 1997, 44(2):219−221.
    [9] Zheng P, Ma Z, Guo H, et al. Osteological ontogeny andmalformations in larval and juvenile golden pompanoTrachinotus ovatus (Linnaeu 1758)[J]. Aquacult Res, 2014,doi: 10.1111/are.12600.
    [10] Gavaia P J, Dinis M T, Cancela M L. Osteologicaldevelopment and abnormalities of the vertebral column andcaudal skeleton in larval and juvenile stages ofhatchery-reared Senegal sole (Solea senegalensis)[J].Aquaculture, 2002, 211(1–4): 305−323.
    [11] Koumoundouros G, Sfakianakis D G. Osteologicaldevelopment of the vertebral column and of the fins inDiplodus sargus (teleostei: Perciformes: Sparidae)[J]. MarBiol, 2001, 139: 853−862.
    [12] Kohno H, Ordonio-Aguilar R, Ohno A, et al. Morphologicalaspects of feeding and improvement in feeding ability inearly stage larvae of the milkfish, Chanos chanos[J].Ichthyol Res, 1996, 43: 133−140.
    [13] Koumoundouros G, Gagliardi F, Divanach P, et al. Normaland abnormal osteological development of caudal fin inSparus aurata L. fry[J]. Aquaculture, 1997, 149: 215−226.
    [14] Koumoundouros G, Divanach P, Kentouri M. The effect ofrearing conditions on development of saddleback syndromeand caudal fin deformities in Dentex dentex (L.)[J].Aquaculture, 2001, 200: 285−304.
    [15] Hosoya K, Kawamura K. Skeletal formation andabnormalities in the caudal complex of the JapaneseFlounder, Paralichthys olivaceus (Temminck & Schlegel)[J].Bull Natl Res Ins Fish Sci, 1998, 12: 97−110.
    [16] Chen Y G, Xia D, Zhong J S, et al. Development of thevertebral column and the appendicular skeleton in the larvaeand juveniles of Coilia nasus[J]. J Shanghai Ocean Univ,2011, 20(2): 217−223.
    [17] Langille R M, Hall B K. Development of the head skeletonof the Japanese medaka, Oryzias latipes (Teleostei)[J]. JMorphol, 1987, 193(2): 135−158.
    [18] Hilton E J, Johnson G D. When two equals three:developmental osteology and homology of the caudalskeleton in carangid fishes (Perciformes: Carangidae)[J].Evol Dev, 2007, 9(2): 178−189.
    [19] Ma Z, Zheng P, Guo H, et al. Jaw malfromation of hatcheryreared golden pompano Trachinotus ovatus (Linnaeus 1758)larvae[J]. Aquacult Res, 2014, doi: 10.1111/are.12569.
    [20] Ma Z, Guo H, Zheng P, et al. Ontogenetic development ofdigestive functionality in golden pompano Trachinotusovatus (Linnaeus 1758)[J]. Fish Physiol Biochem, 2014, 40:1157−1167.
    [21] Cobcroft J M, Pankhurst P M, Sadler J, et al. Jawdevelopment and malformation in cultured striped trumpeterLatris lineata[J]. Aquaculture, 2001, 199: 267−282.
    [22] Cobcroft J M, Battaglene S C. Skeletal malformations inAustralian marine finfish hatcheries[J]. Aquaculture, 2013,396−399: 51−58.
    [23] Cobcroft J M, Pankhurst P M, Poortenaar C, et al. Jawmalformation in cultured yellowtail kingfish (Seriola lalandi)larvae[J]. New Zeal J Mar Fresh, 2004, 38(1): 67−71.
    [24] Morrison C M, MacDonald C A. Normal and abnormal jawdevelopment of the yolk-sac larva of Atlantic halibutHippoglossus hippoglossus[J]. Dis Aqua Organ, 1995, 22(3):173−184.
    [25] Fraser M, Nys D. The morphology and occurrence ofjaw and operculum deformities in cultured barramundi(Lates calcarifer) larvae[J]. Aquaculture, 2005, 250(1-2):496−503.
    [26] Cobcroft J, Shu-chien A, Kuah M, et al. The effects of tankcolour, live food enrichment and greenwater on the earlyonset of jaw malformation in striped trumpeter larvae[J].Aquaculture, 2012, 356-357: 61−72.
    [27] Negm R K, Cobcroft J M, Brown M R, et al. The effects ofdietary vitamin A in rotifers on the performance and skeletalabnormality of striped trumpeter Latris lineata larvae andpost larvae[J]. Aquaculture, 2013, 404-405: 105−115.
    Comments
    Comments
    分享到微博
    Submit
Get Citation

聂广锋,李加儿,区又君,汤清亮,吴水清,王鹏飞,温久福. 梭鱼仔、稚、幼鱼消化系统胚后发育的组织学观察[J]. Jounal of Fishery Sciences of China, 2016,[volume_no](1):90-103

Copy
Share
Article Metrics
  • Abstract:5079
  • PDF: 1677
  • HTML: 0
  • Cited by: 0
History
  • Online: January 14,2016
Article QR Code
You are the 23993 visitor.
Sponsor:Ministry of Agriculture and Rural Affairs of People’s Republic of China
Organizer:Chinese Academy of Fishery Sciences The China Society of Fisheries Science Press
Address:No150, Qingtacun, Beijing 100141, China
Fax:86-10-68673931 Tel:86-10-68673921
Journal of Fishery Sciences of China ® 2025 All Rights Reserved