علوم و فنون شیلات

علوم و فنون شیلات

ارزیابی رشد, ترکیب بدن, شاخص های فیزیولوژیکی و ایمنی تاسماهی سیبری (Acipenser baerii) تغذیه شده با مکملهای غذایی اسید لاکتیک و پروبیوتیک پروتکسین

نوع مقاله : پژوهشی اصیل

نویسندگان
رسول زارع
عبدالمحمد عابدیان کناری
تربیت مدرس
چکیده
استفاده از پروبیوتیک ها و اسیدهای آلی یک راه ایده آل و جایگزین مناسب برای آنتی بیوتیک ها در آبزی پروری است. در حال حاضر شناخت کافی از عملکرد مجزا و ترکیبی این افزودنی ها در غذای ماهیان خاویاری وجود ندارد. هدف از پژوهش حاضر ارزیابی استفاده از مکمل های اسید لاکتیک و پروبیوتیک (پروتکسین) و ترکیب این دو در تغذیه تاسماهی سیبری (Acipenser baerii) است. از اینرو 160 قطعه ماهی سالم با میانگین وزن بدن36/0 ± 85/54 گرم به طور تصادفی به 4 گروه آزمایشی در 3 تکرار تقسیم شدند. ماهیان با چهار جیره غذایی شامل جیره غذایی شاهد یا بدون افزودنی (جیره 1)، جیره غذایی شاهد همراه با 2٪ اسید لاکتیک (جیره 2)، جیره شاهد همراه با ترکیب 2٪ اسید لاکتیک و 01/0 ٪ پروتکسین (جیره 3) و جیره غذایی شاهد همراه با 01/0 ٪ پروتکسین (جیره 4) تغذیه شدند. ماهی ها به مدت 9 هفته و سه بار در روز تا حد سیری تغذیه شدند. در پایان آزمایش، پارامترهای رشد، فیزیولوژی و ایمنی ماهی سنجش شد. نتایج نشان داد اسید لاکتیک به تنهایی و هم در ترکیب با پروتکسین موجب افزایش وزن بدن و ضریب رشد ویژه شد. ضریب تبدیل غذایی در تیمارهایی که اسید لاکتیک بصورت مجزا یا در ترکیب با پروتکسین استفاده شده بود کاهش یافت (05/0P <). میزان تلفات در تمام تیمارها در طول دوره آزمایش صفر بود. پروتئین لاشه تاسماهی سیبری در تیمارهای تغذیه شده با ترکیب اسید لاکتیک و پروتکسین نسبت به گروه های دیگر بهبود معنی داری داشت. (05/0P <). افزودن اسید و پروتکسین هم بطور مجزا و هم در ترکیب با هم موجب کاهش چربی لاشه شد (05/0P <). کمترین pH روده در تیمار تغذیه شده با اسید لاکتیک توام با پروتکسین و بیشترین آن در گروه شاهد مشاهده شد. همچنین، تعداد کل باکتری های اسیدلاکتیک موجود در روده ماهیان تغذیه شده با اسیدلاکتیک به همراه پروتکسین در مقایسه با باقی تیمارها افزایش معنی داری نشان داد (05/0P <). افزودن توام اسید لاکتیک با پروتکسین فعالیت لیزوزیم و کمپلمان خون ماهی را بطور معناداری افزایش داد (05/0P <). به طور کلی استفاده مجزا و ترکیبی اسید لاکتیک (2 درصد) با پروتکسین (01/0 %) در غذای ماهی سیبری موجب بهبود عملکرد این ماهی گردید.
کلیدواژه‌ها
اسیدهای آلی
باکتری های مفید
رشد
تاس ماهی سیبری
ایمنی

موضوعات

[1] Matyar F, Dincers S, Kaya A, Colak O. Prevalence and resistance to antibiotics in Gram negative bacteria isolated from retial fish in Turkey. Annals of microbiology. 2004, 54(5) 151-160.
[2] Cabello FC, Godfrey HP, Tomova A, Ivanova L, Dolz H, Millanao A, Buschmann AH. Antimicrobial use in aquaculture re-examined: its relevance to antimicrobial resistance and to animal and human health. Environ. Microbiology. 2013,15(1) 1917–1942.
[3] Pathak SP, Gopal K. Occurrence of antibiotic and metal resistance in bacteria from organs of river fish. Environmental Research. 2005, 98(8) 100-103.
[4] Castanon, JIR. History of the Use of Antibiotic as Growth Promoters in European Poultry Feeds. Poultry Science. 2007, 86(11) 2466-2471.
[5] Luckstadt C. The use of acidifiers in fish nutrition. CAB Rev 2008, 3:1–8
[6] Ng WK, Koh CB, Sudesh K, Siti-Zahrah A. Effects of dietary organic acids on growth, nutrient digestibility and gut microflora of red hybrid tilapia, Oreochromis sp., and subsequent survival during a challenge test with Streptococcus agalactiae. Aquacalt Res. 2009, 40:1490–1500.
[7] Van Dam H. Organic acids and their salts. Feed Mix. 2006, 14:28–31.
[8] Kumar P, Jain KK, Sardar P, Sahu NP, Gupta S. Dietary supplementation of acidifier: effect on growth performance and haemato-biochemical parameters in the diet of Cirrhinus mrigala juvenile. Aquacult Int. 2017, 25: 2101–2116.
[9] Merrifield DL, Bradley G, Baker RTM, Davies SJ. Probiotic applications for rainbow trout (Oncorhynchus mykiss Walbaum). Effects on growth performance, feed utilization, intestinal microbiota and related health criteria post antibiotic treatment. Aquacalt Nutr. 2010,16:496–503
[10] Ng WK, Ling LC, Romano N, Kua BC. Dietary short-chain organic acids enhanced resistance to bacterial infection and hepatopancreatic structural integrity of the giant freshwater pawn, Macrobrachium rosenbergii. Int aquat res. 2017, 9:293–302.
[11] Ashouri G, Soofiani NM, Hoseinifar SH, Jalali SAH, Morshedie V, Valinassab T, Bagheri D, Doanh HV, Mozanzadeh MT, Carnevali O. Influence of dietary sodium alginate and Pediococcus acidilactici on liver antioxidant status, intestinal lysozyme gene expression, histomorphology, microbiota, and digestive enzymes activity, in Asian sea bass (Lates calcarifer) juveniles. Aquaculture. 2020, 518:734638.
[12] Lazado C, Caipang CMA, Brinchmann MF, Kiron V. In vitro adherence of two candidate probiotics from Atlantic cod and their interference with the adhesion of two pathogenic bacteria. VetMicrobiol. 2011, 148:252–259.
[13] Alishahi M, Tulaby Dezfuly Z, Mohammadian T, Mesbah M. Effects of two probiotics, Lactobacillus plantarum and Lactobacillus bulgaricus on growth performance and intestinal lactic acid bacteria of Cyprinus Carpio. Iran J Vet Med. 2018, 12:207–218.
[14] Dawood MAO, Magouz FI, Salem MFI, AbdelDaim HA. Modulation of digestive enzyme activity, blood health, oxidative responses and growth related gene expression in GIFT by heat-killed Lactobacillus plantarum (L-137). Aquaculture. 2019, 505:127–136.
[15] Ringø E. Effects of dietary lactate and propionate on growth and digesta in Arctic charr, Salvelinus alpinus (L.). Aquaculture. 1991, 96:321–333.
[16] Gislason G, Olsen RE, Ringø E. Lack of growth-stimulating effect of lactate on Atlantic salmon, Salmo salar L. Aquaculture and Fisheries Management. 1994, 25: 861–2.
[17] Vielma J, Lall SP. Dietary formic acid enhances apparent digestibility of minerals in rainbow trout, Oncorhynchus mykiss (Walbaum). Aquaculture Nutrition. 1997, 3:265–8.
[18] Vielma, J., Ruohonen, K., Lall, SP. 1999. Supplemental citric acid and particle size of fish bone-meal influence the availability of minerals in rainbow trout Oncorhynchus mykiss (Walbaum). Aquaculture Nutrition, 5:65–71.
[19] Matani Bour HA, Esmaeili M, Abedian Kenari A. Growth performance, muscle and liver composition, blood traits, digestibility and gut bacteria of beluga (Huso huso) juvenile fed different levels of soybean meal and lactic acid. Aquacult Nutr. 2018, 24:1361–1368.
[20] Khoshhava M.B, Abedian Kenari A, Mirzakhani M. K. The effects of concurrent of citric acid and soybean based diets on growth performance, body composition, haemobiochemical indices, digestibility and fatty acid profile in juvenile rainbow trout, Oncorhynchus mykiss. Aquaculture Nutrition. 2021, 27: 1671–1682.
[21] Zare R, Abedian Kenari A, Yazdani Sadati M. Influence of dietary acetic acid, protexin (probiotic), and their combination on growth performance, intestinal microbiota, digestive enzymes, immunological parameters, and fatty acids composition in Siberian sturgeon (Acipenser baerii, Brandt, 1869). Aquaculture international. 2021, 29: 891-910.
[22] Firouzbakhsh F, Noori F, Khalesi MK, Jani-Khalili K. Effects of a probiotic, protexin, on the growth performance and hematological parameters in the Oscar (Astronotus ocellatus) fingerlings. Fish Physioogy and Biochemistry. 2011, 37(4) 833-842.
[23] El–Gohary MS, Diab AM. Some Studies on the Effect of Protexin on Immune Status of Cultured Seabass Fingerlings. Alexandria Journal of Veterinary Sciences. 2014, 41(3) 109-119.
[24] Merrifield D, Bradley G, Harper G, Baker R., Munn C, Davies S. Assessment of the effects of vegetative and lyophilized Pediococcus acidilacticion on growth, feed utilization, intestinal colonization and health parameters of rainbow trout (Oncorhynchus mykiss, Walbaum). Aquacalture Nutrition. 2011, 17(5) 73-79.
[25] Ashouri G, Soofiani NM, Hoseinifar SH, Jalali SAH, Morshedie V, Valinassab T, Bagheri D, Doanh HV, Mozanzadeh MT. Combined effects of dietary low molecular weight sodium alginate and Pediococcus acidilactici on growth performance, haematological and innate immune responses of Asian sea bass (Lates calcalifer) juveniles. Fish and Shellfish Immunollogy. 2018, 79(6) 34-41.
[26] AOAC. 1995. Official methods of analysis of the association official analytical chemists, In: Cunnil, PA., ed. 16th ed. Arlington, USA: AOAC International.
[27] Wuertz S, Lutz I, Gessner J, Loeschau P, Hogans B, Kirschbaum F, Kloas W. The influence of rearing density as environmental stressor on cortisol response of shortnose sturgeon (Acipenser brevirostrum.( Appllied Ichthyology. 2006, 22(3) 269-273.
[28] Yano T. Assays of Hemolytic Complement Activity. In: Stolen, JS., Fletcher, TC., Anderson, DP., Kaattari, SL., Rowley, AF, eds. Techniques in Fish Immunology. S.O.S Publication, Fair Haven:NJ. 1992, 131–141.
[29] Mahious AS, Gatesoupe FJ, Hervi M, Metailler R, Ollevier F. Effect of dietary inulin and oligosaccharides as prebiotics for weaning turbot (Psetta maxima). Aquaculture International. 2006, 14(5) 219–229.
[30] Baruah K, Pal AK, Sahu NP, Jain KK, Mukherjee S.C, Debnath D. Dietary protein level, microbial phytase, citric acid and their interactions on bone mineralization of Labeo rohita (Hamilton) juveniles. Aquaculture Research. 2005, 36(6) 803–812.
[31] De Wet L. Organic acids as performance enhancers. Aqua Feeds: Formulation and Beyond. 2005, 2(2) 12–14.
[32] Khajepour F, Hosseini SA. Citric acid improves growth performance and phosphorus digestibility in Beluga (Huso huso) fed diets where soybean meal partly replaced fish meal. Animal Feed Sciences and Technology. 2012, 171(11) 68–73.
[33]Hossain MA, Pandey A, Satoh S. Effects of organic acids on growth and phosphorus in red sea bream Pagrus major. Fisheries Sciences. 2007, 73(6) 1309–1317.
[34] Tabrizi JM, Barzeghar A, Farzampour S, Mirzaii H, Safarmashaei S. Study of the effect of prebiotic (Saccharomyces cerevisiae) and acidifier on growth parameters in grower's rainbow trout (Oncorhynchus mykiss). Annuls Biology Research. 2012, 3(4) 2053-2057.
[35] Najdegerami EH, Baruah K, Shiri A, Rekecki A, Broeck WVD, Sorgeloos P, Boon N, Bossier P, De Schryver P. Siberian sturgeon (Acipenser baerii) larvae fed Artemia nauplii enriched with poly-b-hydroxybutyrate (PHB): effect on growth performance, body composition, digestive enzymes, gut microbial community, gut histology and stress tests. Aquacult Research. 2013, 46(4) 801-812.
[36] Alizade H, Ouraji H, Falahatkar B, Efatpanah I. Effect of dietary Malic acid on growth performance and body composition of juvenile Siberian sturgeon (Acipenser baerii Brandt, 1869). Journal Iranian Scientific Fisheries Journal. 2018, 27(7) 1-12.
[37] Kalantarian SH, Mirzargar SS, Rahmati-Holasoo H, Sadeghinezha DJ, Mohammadian T. Effects of oral administration of acidifier and probiotic on growth performance, digestive enzymes activities and intestinal histomorphology in Salmo trutta caspius (Kessler, 1877). Iranian Journal of Fisheries Sciences. 2020, 19(3) 1532-1555.
[38] Luckstadt C. The use of acidifiers in fish nutrition. CAB Revews. 2008, 3(3) 1–8.
[39] Mahmoudi K, Zamini AA, Yazdsni MA, Kazemi R, Jalilipour J. Effect of protexin probiotic product on some growth parameters and body composition of the cultured Siberian (Acipenser baeri). Fisheries. 2012, 5(5) 39-48.
[40] Asadian M, Shahsavani D, Kazerani HR. Growth promoting effects of a multi-strain probiotic on common carp (Cyprinus carpio) fingerlings. Iran Journal Veternery Sciences and Technology. 2015, 7(7) 63-74.
[41] Ahmed HA,Sadek KM. Impact of Dietary Supplementation of Sodium Butyrate and/or Protexin on the Growth Performance, Some Blood Parameters, and Immune Response of Oreochromis Niloticus. International Journal of Agricalcural Researches. 2014, 3(5) 985-991.
[42] Wang YB, Tian ZQ, Yao JT, Li WF. Effect of probiotics, Enteroccus faecium, on tilapia (Oreochromis niloticus) growth performance and immune response. Aquaculture. 2008, 277(7) 203–207.
[43] Hooshyar Y, Abedian Kenari A, Paknejad H, Gandomi H. Effects of Lactobacillus rhamnosus ATCC 7469 on Different Parameters Related to Health Status of Rainbow Trout (Oncorhynchus mykiss) and the protection Against Yersinia ruckeri. Probiotics and Antimicrobial Proteins. 2020, 12 (3) 1370–1384.
[44] Abdel-Tawwab M, Adeshina I, Jenyo-Oni A, Ajani E.K, Emikp B.O. Growth, physiological, antioxidants, and immune response of African catfish, Clarias gariepinus (B.), to dietary clove basil, Ocimum gratissimum, leaf extract and its susceptibility to Listeria monocytogenes infection. Fish and Shellfish Immunology. 2018, 78(1) 346–354.
[45] Neissi G, Rafiee M, Nematollahi M, Safari O. The effect of Pediococcus acidilactici bacteria used as probiotic supplement on the growth and non-specific immune responses of green terror, Aequidens rivulatus, Fish and Shellfish Immunology. 2013, 35(5) 1976–1980.
[46] Hassaan MS, Soltan MA, Jarmołowicz S, Abdo HS. Combined effects of dietary malic acid and Bacillus subtilis on growth, gut microbiota and blood parameters of Nile tilapia (Oreochromis niloticus). Aquaculture Nutrition. 2016, pp1–11.
[47] Hai NV. The use of probiotics in aquaculture. Appllied Microbiology. 2015, 119(9) 917-93.
[48] Fazio F, Marafioti S, Arfuso F, Piccione G, Faggio C. Influence of different salinity on haematological and biochemical parameters of the widely cultured mullet Mugil cephalus. Marine and Freshwater Behaviour and Physiology. 2013, 46(6) 211-218.
[49] Ahmed HA,Sadek KM. Impact of Dietary Supplementation of Sodium Butyrate and/or Protexin on the Growth Performance, Some Blood Parameters, and Immune Response of Oreochromis Niloticus. International Journal of Agricalcural Researches. 2014, 3(5) 985-991.
[50] Jami MJ, Abedian Kenari A, Paknejad H, Mohseni M. Effects of dietary b-glucan, mannan oligosaccharide, Lactobacillus plantarum and their combinations on growth performance, immunity and immune related gene expression of Caspian trout, Salmo trutta caspius (Kessler, 1877). Fish and Shellfish Immunollogy. 2019, 91(5) 202-208.
[51] Freitag M. Organic acids and salts promote performance and health in animal husbandry. In: Luckstadt, C., ed. Acidifiers in Animal Nutrition; A Guide for Feed Preservation and Acidification to Promote Animal Performance. 1st ed, Nottingham University Press, Nottingham, UK. 2007, pp: 1–11.
[52] Sugiura SH, Roy PK, Ferraris RP. Dietary acidification enhances phosphorus digestibility but decreases H+ /K+ ATPase expression in rainbow trout. Experimental Bioloy. 2006, 209(9) 3719–3728.
[53] Castillo S, Rosales M, Pohlenz C, Delbert M. Effects of organic acids on growth performance and digestive enzyme activities of juvenile red drum Sciaenops ocellatus. Aquaculture. 2014, 433(3) 6–12.
[54] Ma C, Cho Y, Oh KH. Removal of pathogenic bacteria and nitrogens by Lactobacillus spp. JK8 and JK-11. Aquaculture. 2009, 287(7) 266–270.
[55] Jafarnodeh A, Tukmechi A, Najd Grami E.H, Hajimoradlo A.M, Noori F. Study of synergistic Effects of potassium- sorbate and Lactobacillus casei on The activity of digestive enzymes, intestinal Histomorphology and resistance against pathogenic bacteria (Yersinia ruckeri) in rainbow trout fry (Oncorhynchus mykiss). JAIR. 2020, 8 (2) :51-59.