Subject Areas :
1 - ایستگاه تحقیقات نرمتنان خلیج فارس، پژوهشکده اکولوژی خلیج فارس و دریای عمان، موسسه تحقیقات علوم شیلاتی کشور، سازمان تحقیقات، آموزش و ترویج کشاورزی. بندرلنگه، ایران.
Keywords:
Abstract :
-حاجیان،ع.، کاظمی، ر.ا.، دژندیان، س.، جوردهی،ا.ی. 1394. مطالعه آسیبشناسی بافتی آبشش بچه تاسماهیان ایرانی (Acipenser persicus )صید شده در سواحل جنوبی دریای خزر. تغذیه و بیوشیمی آبزیان. سال دوم. ص 48–39.
2-حیدری، ب.، آورجه، س.، جلودار، ح.ت. 1394. اثر تغییرات تؤام تدریجی شوری و دما بر بافت آبشش و سلول های کلراید ماهی کپور معمولی(Cyprinus carpio) . زیست شناسی جانوری تجربی. سال چهارم. ص 35–25.
3-خواجه، م.ر.، عبدی،ر.، ذوالقرنین، ح.، صحافی، ه.ح.ز.، مروتی، ح. 1393. مطالعه اثر شوریهای مختلف بر فراوانی و مساحت سلولهای کلراید در آبشش بچه ماهی هامور معمولی(Epinephelus coioides). مجله علمی شیلات ایران. سال بیست و سوم. شماره دوم. ص 11-1.
4-نفیسی بهابادی، م.، سلطانی، م.، فلاحتی مروست، ع. 1390. بررسی تغییر شاخص های رشد و برخی از فاکتورهای بیوشیمایی خون ماهیان جوان قزل آلای رنگین کمان در شوریهای مختلف (Onchorhynchus mykiss). مجله تربیت معلم. سال نهم. شماره چهارم. ص 641- 625.
5.Caberoy, N.B., Quinitio, G.F. (2000). Changes in Na+,K+-ATPase activity and gill chloride cell morphology in the grouper Epinephelus coioides larvae and juveniles in response to salinity and temperature. Fish Physiol. Biochem, 23; 83–94.
6.Carmona, R., García-Gallego, M., Sanz, A., Domezaín, A., Ostos-Garrido, M. V. (2004). Chloride cells and pavement cells in gill epithelia of Acipenser naccarii: ultrastructural modifications in seawater-acclimated specimens. J.FishBiol,64; 553–566.
7.Evans, D.H., Piermarini, P., Choe, K. (2005). The multifunctional fish gill: dominant site of gas exchange, osmoregulation, acid-base regulation, and excretion of nitrogenous waste. Physiol. Rev, 85; 97–177.
8.Ferraris, R.P., Catacutan, M.R., Mabelin, R.L., Jazul, A.P. (1986). Digestibility in milkfish, Chanos chanos (Forsskal): Effects of protein source, fish size and salinity. Aquaculture, 59; 93–105.
9.Fielder, D.S., Allan, G.L., Pepperall, D., Pankhurst, P.M. (2007). The effects of changes in salinity on osmoregulation and chloride cell morphology of juvenile Australian snapper, Pagrus auratus. Aquaculture, 272; 656–666.
10.Ghahremanzadeh, Z., Namin, J.I., Bani, A., Hallajian, A. (2014). Cytological comparison of gill chloride cells and blood serum ion concentrations in kutum(Rutilus frisii kutum) spawners from brackish(Caspian Sea) and fresh water(Khoshkrood River) environments. Arch. Polish Fish, 22; 189–196.
11.Guner, Y., Ozden, O., Cagirgan, H., Altunok, M., Kizak, V., Papadakis, I.E., Varsamos, S. (2005). Effect of salinity on the Osmoregulatory functions of the gills in Nile Tilapia(Oreochromis niloticus). Turk. Vet. Anim. Sci, 29;1259–1266.
12.Hirai, N., Tagawa, M., Kaneko, T., Seikai,T., Tanaka, M. (1999). Distributional changes in branchial chloride cells during freshwater adaptation in Japanese sea bass(Lateolabrax japonicas). Zoolog. Sci, 16; 43–49.
13.Khodabandeh, S., Khoshnood, Z., Mosafer, S. (2009). Immunolocalization of Na+, K+-ATPase-rich cells in the gill and urinary system of Persian sturgeon, Acipenser persicus, fry. Aquac. Res, 40; 329–336.
14.King, J.A.C., Abel, D.C., DiBona, D.R. (1989). Effects of salinity on chloride cells in the euryhaline cyprinodontid fish Rivulus marmoratus. Cell Tissue Res, 257; 367–377.
15.Laiz-Carrion, R., Guerreiro, P.M., Fuentes, J., Canario, A.V.M., Martin Del Rio, M.P., Mancera, J.M. (2005). Branchial osmoregulatory response to salinity in the gilthead sea bream, Sparus auratus. J. Exp. Zool. A. Comp. Exp.Biol,303;563–576.
16.Lee, K.M., Kaneko, T., Katoh, F., Aida, K. (2006). Prolactin gene expression and gill chloride cell activity in fugu Takifugu rubripes exposed to a hypoosmotic environment. Gen. Comp. Endocrinol, 149; 285–293.
17.Lisboa, V., Barcarolli, I.F., Sampaio, L.A., Bianchini, A. (2015). Effect of salinity on survival, growth and biochemical parameters in juvenile Lebranch mullet Mugil liza(Perciformes: Mugilidae). Neotrop Ichthyol, 13; 447–452.
18.Mylonasy, C.C., Pavlidis, M., Papandroulakis, N., Zaiss, M.M., Tsafarakis, D., Papadakis, I.E., Varsamos, S. (2009). Growth performance and osmoregulation in the She drum(Umbrina cirrosa) adapted to diffrent environmental salinities. Aquaculture, 287; 203–210.
19.Neuraste, N., Setorki, M., Tehranifard, A., Moshfegh, A. (2017). Effects of salinity and plasma prolactin on chloride cells in the gill of Chalcalburnus chalcoides. Iran. J. Aquat. Anim. Heal, 3; 11–21.
20.Pereira, B.F., Caetano, F.H. (2009). Histochemical technique for the detection of chloride cells in fish. Micron, 40; 783–786.
21.Pourmozaffar, S., Hajimoradloo, A., Paknejad, H., Rameshi, H. (2019). Effect of dietary supplementation with apple cider vinegar and propionic acid on hemolymph chemistry , intestinal microbiota and histological structure of hepatopancreas in white shrimp, Litopenaeus vannamei. Fish Shell fish Immunol, 86; 900–905.
22.Pourmozaffar, S., Hajimoradloo, A., Miandare, H.K. (2017). Dietary effect of apple cider vinegar and propionic acid on immune related transcriptional responses and growth performance in white shrimp, Litopenaeus vannamei. Fish Shellfish Immunol, 60; 65–71.
23.Sterzelecki, F., Rodrigues, E., Fanta, E., Ribeiro, C. (2013). The effect of salinity on osmoregulation and development of the juvenile fat snook, Centropomus parallelus (POEY). Braz. J. Biol, 73; 609–615.
24.Uchida, K., Kaneko, T., Yamauchi, K., Hirano, T. (1996). Morphometrical analysis
chloride cell activity in the gill filaments and lamellae and changes in Na+, K+-ATPase activity during seawater adaptation in chum salmon fry. J. Exp. Zool, 276 (3); 193-200.
25.Zydlewski, J., McCormick, S.D. (2001). Developmental and environmental regulation of chloride cells in young American shad, Alosa sapidissima. J. Exp. Zool, 290;73–87.
