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The Effects of Feeding Fish Oil on Uterine Secretion of PGF2α, Milk Composition, and Metabolic ... PDF

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J. Dairy Sci. 87:921–932  American Dairy Science Association, 2004. The Effects of Feeding Fish Oil on Uterine Secretion of PGF , Milk 2α Composition, and Metabolic Status of Periparturient Holstein Cows R. Mattos,1 C. R. Staples,1 A. Arteche,1 M. C. Wiltbank,2 F. J. Diaz,2 T. C. Jenkins,3 and W. W. Thatcher1 1DepartmentofAnimalSciences,UniversityofFlorida, Gainesville32611-0920 2DepartmentofDairyScience,UniversityofWisconsin, Madison53706 3DepartmentofAnimal,Dairy,andVeterinarySciences, ClemsonUniversity,Clemson,SC29634 ABSTRACT (Key words: fish oil, prostaglandin, uterus, n-3 fatty acid) Theobjectivesweretodeterminetheeffectofdietary fishoil(FO)onuterinesecretionofPGF ,milkproduc- Abbreviation key: CLA = conjugated linoleic acid, 2α tion,milkcomposition,andmetabolicstatusduringthe DA = displaced abomasum, DHA = docosahexaenoic periparturientperiod.Holsteincowswereassignedran- acid, EPA = eicosapentaenoic acid, FO = fish oil, domly to diets containing FO (n = 13) or olive oil (OO, G3PDH=glyceraldehyde3-phosphatedehydrogenase, n=13).Cowswerefedprepartumandpostpartumdiets OO = olive oil, PGHS-2 = prostaglandin H synthase 2 that provided approximately 200 g/d from 21 d before 2, PGFM = 13, 14 dihydro, 15-keto PGF , PUN = 2α the expected parturition until 21 d after parturition. plasma urea nitrogen. The FO used contained 36% eicosapentaenoic acid (EPA,C20:5,n-3)and28%docosahexaenoicacid(DHA, INTRODUCTION C22:6, n-3). Blood samples were obtained from 14 d beforetheduedateuntild 21postpartum.Atotalof6 Fishoil(FO)containsrelativelyhighconcentrations FO and 8 OO cows without periparturient disorders of two polyunsaturated fatty acids of the n-3 family: wereusedinthestatisticalanalysesofPGF -metabo- eicosapentaenoic acid (EPA, C20:5) and docosahexae- 2α lite (PGFM) and metabolite concentrations. Length of noic acid (DHA, C22:6). These fatty acids can be sup- prepartumfeedingwithOOorFOdidnotdiffer.Propor- pliedonlybythedietbecauseEPAandDHAcannotbe tions of individual and total n-3 fatty acids were in- synthesizeddenovoinmammaliansystems.Eicosapen- creased in caruncular tissue and milk of cows fed FO. taenoicacidandDHAhaveinhibitedsecretionofPGF 2α The combined concentrations of EPA and DHA in ca- indifferent animalcell culturesystems (Achardet al., runcular tissue were correlated positively with the 1997),includingbovineendometrialcells(Mattosetal., number of days supplemented with FO. Cows fed FO 2001). Inhibiting uterine secretion of PGF in vivo by 2α had reduced concentrations of plasma PGFM during feeding EPA and DHA may reduce endometrial secre- the 60 h immediately after parturition compared with tionofPGF topossiblyinduceanantiluteolyticeffect 2α cows fed OO. Concentrations of prostaglandin H syn- duringearlypregnancyandincreasefertilityrates(Sta- thase-2 mRNA and protein in caruncular tissue were ples et al., 1998; Mattos et al., 2000). Several studies unaffected by diet. Production of milk and FCM were documented the effects of dietary marine products on similar between cows fed the two oil diets. However, PGF secretion. Feeding fish meal, which contained 2α cowsfedFOproducedlessmilkfat.FeedingFOreduced approximately8%FO(DMbasis),tolactatingmultipa- plasma concentrations of glucose. Dietary fatty acids rouscowsfor47to51dreducedthesecretionofPGF 2α given during the periparturient period can reduce the induced by estradiol and oxytocin injected on d 15 of uterine secretion of PGF in lactating dairy cows and a synchronized estrous cycle (Mattos et al., 2002). In 2α alter the fatty acid profile of milk fat. humans, consumption of large amounts of FO was re- portedtoprolonggestation(Olsenetal.,1992),possibly duetosuppressedsecretionofPGF delayingparturi- 2α tion. Also, infusing ewes with 3 mL/kg of BW per day ReceivedDecember19,2002. (i.v.) of an emulsion of FO containing 30% EPA and AcceptedAugust8,2003. 20%DHAblockedabetamethasone-inducedincreasein Corresponding author: William W. Thatcher; e-mail: thatcher@ animal.ufl.edu. plasmaconcentrationsofprostaglandinE2anddelayed 921 922 MATTOSETAL. Table1.Numberofexperimentalcowsandincidenceofhealthdisorders. Oliveoil Fishoil Total Animalsstartingtheexperiment Primiparous,n 5 4 9 Multiparous,n 8 9 17 Totalanimals,n 13 13 26 Animalsusedinstatisticalanalyses Primiparous,n 1 2 3 Multiparous,n 7 4 11 Totalanimals,n 8 6 14 Healthdisorders Dystocia,% 46(6/13) 38(5/13) 42(11/26) Stillborncalf,% 8(1/13) 15(2/13) 12(3/26) Retainedfetalmembranes,% 15(2/13) 15(2/13) 15(4/26) Toxicmetritis,% 15(2/13) 8(1/13) 12(3/26) Displacedabomasum,% 23(3/13) 38(5/13) 31(8/26) occurrenceofparturitioninsheep(Baguma-Nibasheka date until parturition. It was then replaced by rations et al., 1999). containingeitherFOorOO,whichwerefeduntilcows A very intense secretion of uterine PGF , as evi- reached21dpostpartum.Duringtheprepartumperiod, 2α denced by dramatic increases in concentration of cows were housed in sod-based pens and were moved plasmaPGF ,ischaracteristicoftheimmediatepost- toafree-stallbarnatcalving.Cows(n=6)andheifers 2α partum period in the cow (Guilbault et al., 1984a). (n=6)thathadmoderatetoseveredystocia,thatwere Plasmaconcentrationsof13,14dihydro,15-ketoPGF diagnosed with displaced abomasum (DA), that re- 2α (PGFM), the metabolite of PGF used to estimate tained fetal membranes, or that had toxic metritis 2α PGF secretion, peaked at concentrations >1 ng/mL within 10 d after parturition were removed from the 2α within1to3dafterparturitionanddecreasedprogres- analysesoftheeffectsofdietonplasmaconcentrations sively until d 15 postpartum (Guibault et al., 1984a, ofPGFM,PUN,glucose,BHBA,andNEFA.Therefore, 1985). This period of intense secretion of uterine atotalofthreeheifers(1OO,2FO)and11cows(7OO, PGF2αwasusedinthisexperimenttotestinhibitorsof 4 FO) were used in the statistical analyses because prostanoid synthesis. their health status likely did not interfere with the OurhypothesiswasthatfeedingEPAandDHAusing normal secretion of uterine PGF (Table 1). 2α dietaryFOwouldincreasetheproportionofthesefatty Rations were formulated to provide approximately acids in the uterine tissue of dairy cows and reduce 200 g/d of oil. Assumed average DMI were 10.2 and thespontaneoussecretionofuterinePGF2αduringthe 11.6kg/dfortheclose-upandearlypostpartumperiods, periparturientperiod.Ourobjectivesweretodetermine respectively. Because of anticipated lower DMI in the the effect of dietary FO on spontaneous secretion of close-upperiod,nonlactatingcowrationscontained2% PGF2α by the uterus during the periparturient period oil(DMbasis),whereaslactatingcowrationswerefor- and to evaluate the effect of diet on milk production, mulatedtocontain1.8%oil.TheFOselectedcontained milk composition, and indicators of metabolic status 36%EPAand28%DHA(Table2).Therefore,thecom- such as plasma concentrations of glucose, NEFA, binedintakeofEPA(72g)andDHA(56g)wasexpected BHBA, and plasma urea nitrogen (PUN). In addition, to be 128 g/d. Fish oil was fed at 1.8% of dietary DM theeffectof dietonfattyacid compositionandconcen- postpartum in this study in order to deliver approxi- trationsofprostaglandinH2synthase-2(PGHS-2)pro- mately50to60g/dofEPAplusDHA.Thiswasassum- teinandmRNAincarunculartissueweredetermined. ing a ruminal escape of biohydrogenation of 65% and an intestinal absorption of 70%. MATERIALS AND METHODS Ingredientandchemicalcompositionofthedietsare describedinTables3and4.Atparturition,rationswere Cows and Diets adjustedtosupplynutrientsrequiredduringearlylac- The study was conducted from January 31 to April tation. 7, 2001. Pregnant Holstein cows (n = 17) and heifers Theconcentrateportionsofthedietsweremixedand (n=9)wereassignedrandomlytodietscontainingFO stored in metal bins of 1.8-tonne capacity. Oils were (n=13)(AristaIndustries,Wilton,CT)oroliveoil(OO, premixed using ground corn as a carrier. Concentrate n = 13) (Classico, Bertolli, Italy). A ration containing mixturesandforagesourcesweremixedinaweighing theoilswassuppliedfrom21dbeforetheexpecteddue and mixing unit (American Calan, Inc.) and offered JournalofDairyScienceVol.87,No.4,2004 REPRODUCTIVEANDPRODUCTIONRESPONSESTOFISHOIL 923 Table2.Fattyacidprofileoffishoilandoliveoil. twice daily at 0700 and 1230 h to allow 5 to 10% orts Diet (as-fed basis). Orts from each diet were collected once dailyandweighed.Dailyortweightsforeachdietwere Fattyacid1 Oliveoil Fishoil subtracted from the ration offered and divided by the (g/100goffattyacids) numberofcowsfedtodeterminedailyaverageindivid- C14 0.00 0.41 ual cow intakes. The DM concentration of silage was C14:1 0.00 0.09 C15:0 0.00 0.26 monitoredonceweekly(55°Cfor48h)tomaintainthe C16:0 16.62 7.03 proper forage-to-concentrate ratio of diets. Samples of C16:1 1.86 6.33 forages and concentrate mixes were collected weekly, C18:0 2.70 1.00 tC18:1 0.00 1.44 compositedmonthly, andanalyzed forCP, NDF,ADF, C18:1,n9 61.28 4.46 ether extract, and minerals (Dairy One, DHIA Forage C18:2,n6 16.47 2.48 Testing Laboratory, Ithaca, NY) using wet chemistry. CLAt9t11 0.00 0.71 CLAc9t11 0.00 0.00 Cows were milked 3× d at 0500, 1200, and 1900 h. C18:3,n3 0.61 1.95 Calibrated electronic milk meters were used at each C20:0 0.46 0.56 milking to record milk weights. Body condition scores C21:0 0.00 6.36 C20:5,n3 0.00 35.81 and BW were determined at the introduction of diets, C22:0 0.00 0.24 calving, and at d 21 postpartum. C22:1 0.00 2.36 C22:6,n3 0.00 28.42 C24:0 0.00 0.09 Collection of Blood Samples 1Expressedasnumberofcarbons:doublebonds. Blood(10mL)wasobtainedoncedailyat1730hfrom 14 d before due date until parturition and from d 15 until d 21 postpartum.Between the day of parturition (d0)andd14postpartum,bloodsampleswerecollected Table 3. Ingredient composition of experimental diets containing 2× per day at 0800 and 1730 h. Blood was collected olive oil or fish oil fed to Holsteincows during late pregnancy and from the coccygeal vessels into evacuated blood tubes earlylactation. containingEDTAasananticoagulant(10.5mg,Mono- Feedstuff Nonlactating Lactating ject, Sherwood Medical, St. Louis, MO). Samples were %ofdietaryDM maintained in ice until plasma was separated by cen- Cornsilage 37.6 28.0 trifugation (2600 × g, 30 min) at 4°C within 1 h of Alfalfahay 6.3 11.9 Bermudahay 6.4 — collection and stored at −20°C until analyzed. Cottonseedhulls — 4.8 Groundcorn 23.4 22.4 Soybeanmeal 9.2 14.1 PGFM and Metabolite Assays Citruspulp 6.9 7.8 Oil 2.0 1.8 Samples collected between d 5 prepartum and d 21 Wholecottonseed 1.0 1.9 postpartumwereanalyzedforconcentrationsofPGFM Pro-Lak1 1.2 2.2 Mineralmix2 5.5 — using a modification of the radioimmunoassay proce- Mineralmix3 — 4.7 dure described by Mitchell et al. (1976). The PGFM Tracemineralizedsalt4 0.5 — standard solutions were made by serial dilutions in a Feedphos5 — 0.3 bufferofastocksolution(1µg/mLin10%ethanoland 1A marine and animal protein supplement containing 68% RUP 90%PBSbuffer)ofauthenticPGFM(Sigma,St.Louis, (H.J.Baker&Bro.,Inc.,Stamford,CT). MO).Standards(100µL)wereruninduplicatesatthe 2Mineralandvitaminmixcontaining22.8%CP,2.1%fat,22.89% Ca,0.16%P,2.77%Mg,0.75%Na,0.20%K,2.42%S,8.03%Cl,146.7 followingconcentrations:15.6,31.2,62.5,125,250,500, mg/kgofMn,95.0mg/kgofZn,26.6mg/kgofFe,112.5mg/kgofCu, 1000,2000,4000,and8000pg/mL.Thestandardcurve 10.7mg/kgofCo,7.9mg/kgofI,6.9mg/kgofSe,268,130IU/kgof included 100 µL of prostaglandin-free plasma, which vitaminA,40,000IU/kgofvitaminD,and1129IU/kgofvitaminE (DMbasis). wasobtainedfromacyclingnonlactatingbeefcowpre- 3Mineralandvitaminmixcontaining26.4%CP,1.74%fat,10.15% treated twice with flunixin meglumine (Banamine, Ca,0.90%P,3.1%Mg,8.6%Na,5.1%K,1.5%S,4.1%Cl,2231mg/ Schering-Plough,1g/i.m.injection),aPGHSinhibitor. kgofMn,1698mg/kgofZn,339mg/kgofFe,512mg/kgofCu,31 Injections were given 16 h apart. Blood was collected mg/kgofCo,26mg/kgofI,7.9mg/kgofSe,147,756IU/kgofvitamin A,43,750IU/kgofvitaminD,and787IU/kgofvitaminE(DMbasis). 4hafterthesecondinjection,andtheplasmawassepa- 4Minimumconcentrationsof40%Na,55%Cl,0.25%Mn,0.2%Fe, ratedbycentrifugation.Samplesofprostaglandin-free 0.033%Cu,0.007%I,0.005%Zn,and0.0025%Co(DMbasis)(Flint plasma had undetectable concentrations (<10 pg/mL) RiverMills,Inc.,Bainbridge,GA). of PGFM when assayed utilizing standard curves in 5Contains21%Pand15to18%Ca(SoutheasternMinerals,Inc., Bainbridge,GA). 0.05 M PBS buffer. The PBS buffer contained 2.3 g/L JournalofDairyScienceVol.87,No.4,2004 924 MATTOSETAL. Table4.ChemicalcompositionofexperimentaldietscontainingeitheroliveorfishoilfedtoHolsteincows duringlatepregnancyandearlylactation. Oliveoil Fishoil Oliveoil Fishoil Chemical nonlactating nonlactating lactating lactating CP,%ofDM 14.03 13.96 16.7 17.20 NE ,Mcal/kgofDM1 1.68 1.68 1.73 1.74 L NDF,%ofDM 31.17 30.85 30.49 28.40 ADF,%ofDM 19.39 19.11 19.43 18.75 Etherextract,%ofDM 5.32 4.77 5.28 5.36 NFC2 41.4 42.4 39.2 40.7 Ca,%ofDM 2.20 2.06 1.48 1.44 P,%ofDM 0.39 0.37 0.48 0.53 Mg,%ofDM 0.44 0.42 0.40 0.43 K,%ofDM 1.38 1.37 1.57 1.58 Na,%ofDM 0.26 0.27 0.41 0.48 S,%ofDM 0.27 0.28 0.22 0.24 Cl,%ofDM 1.22 1.18 0.42 0.42 Fe,ppmofDM 206 210 250 242 Zn,ppmofDM 65 64 112 114 Mn,ppmofDM 51 49 88 114 Cu,ppmofDM 16 12 25 38 1CalculatedbyDHIForageTestingLaboratory,Ithaca,NY. 2Calculatedas(%NFC=100%−%CP− %NDF−%fat−%ash). NaH PO H O, 4.76 g/L Na HPO 7H O, 1 g/L sodium inhibition curve (heterogeneity of regression, P > 0.1). 2 4 2 2 4 2 azide, and 8.41 g/L NaCl. The buffer pH was adjusted Inter-andintraassaycoefficients ofvariationwere9.8 to 7.5 with NaOH. and 11.9%, respectively. Activity and volume of radioactively labeled PGFM Plasma concentrations of NEFA and BHBA were (Amersham Pharmacia Biotech, Piscataway, NJ) used measured in samples collected on d −5, −3, −1, 1, 4, 7, were 18,000 dpm and 100 µL, respectively. For un- 10,13,16,and19,relativetothedayofparturition.A knownsamples,finalassayvolumewas400µL;itcom- kitassaywasusedtomeasureplasmaconcentrationsof prised100µLofsample,100µLofrabbitantiserumto BHBA(BHBA,kit310-A,SigmaDiagnostics,St.Louis, PGFM(1:10,000;Meyer etal.,1995),100 µLofbuffer, MO). Inter- and intraassay coefficients of variation and 100 µL of labeled PGFM. After a 12-h incubation were 7.3 and 17.6%, respectively. Plasma concentra- at 4°C, free PGFM was separated using 750 µL of a tionsofNEFAweremeasuredwiththeWakoNEFAC solution of charcoal-coated dextran (1.25% dextran test kit (Wako Chemicals USA, Richmond, VA). Inter- [Sigma, St. Louis, MO], 12.5% activated charcoal and intraassay coefficients of variation were 2.9 and [Sigma,St.Louis,MO]inaPBSbuffer).Aftercentrifu- 5.4%, respectively. gation for 20 min at 3565 × g, the supernatant was Concentrationsof plasmaglucose andurea nitrogen transferredtoscintillationvialsandmixedwith4.5mL weredetermineddaily fromd−5tod 21withanauto- of scintillation fluid (Scintiverse II, Fisher Scientific, matedcolorimetricprocedure,whichutilizedanautoa- Pittsburgh, PA). Activity was measured using a liquid nalyzer(AutoAnalyzerII,Bran+Luebbe,BuffaloGrove, scintillation counter (model LKB 1219, Wallac Inc., IL).Theglucoseprocedureisamodification(Technicon Gaithersburg, MD). Accuracy of the assay was deter- Industrial Method #339-19, Bran+Luebbe, Buffalo mined by determining known quantities of exogenous Grove, IL) of that described by Gochman and Schmitz PGFM previously added to prostaglandin-free cow (1972). The procedure for determination of urea nitro- plasma.Addedmassesachievedfinalconcentrationsof gen(IndustrialMethodUS-339-01,Bran+Luebbe,Buf- 125, 250, 500, and 1000 pg/mL. Recovery of added (X) faloGrove,IL)isamodificationofthecarbamido-diace- versus measured (Y) PGFM concentrations was de- tyl reaction procedure (Coulombe and Favreau, 1963). scribedbylinearregression(Y= 1.1957×−56.72,R2= 0.98). Sensitivity of the assay was established at 15.6 Milk Fat Isolation and Analysis pg/mL,becauseanantibodydilutionof1:10000andan assay volume of 100 µL of plasma permitted detection Milk samples for the determination of fat, protein, ofaminimummassof1.56pg.Dilutioninprostaglan- and somatic cells (Southeast Milk Inc., Belleview, FL) din-freeplasmaofahigh(826.6pg/mL)PGFMplasma were collected weekly from two consecutive milkings. sampleto100,50,and25%oforiginalvolumeresulted Milk fat and protein concentrations were analyzed by inaninhibitioncurvethatwasparalleltothestandard the mid-infrared spectroscopic method. Milk samples JournalofDairyScienceVol.87,No.4,2004 REPRODUCTIVEANDPRODUCTIONRESPONSESTOFISHOIL 925 also were collected during 2 consecutive milkings on Isolation of mRNA from Placentomes the last experimental day (d 21) for analysis of fatty Total RNA was isolated using the RNAgents total acids using GLC. Samples for fatty acid analysis were RNAisolationsystem(Promega,Madison,WI).Placen- refrigerated at 4°C and subsequently composited ac- tomesweregroundbrieflyinamortarandpestlecooled cordingtothemilkyieldrecordedforeachofthemilk- with liquid nitrogen. Approximately 30 mg of tissue ings.Milkfatwasextractedusingadetergentsolution was transferred to a fresh tube containing 900 µL of containing 3% Triton X-100 (wt/vol) and 7% sodium denaturing solution and homogenized for 20 s using a hexametaphosphateindistilledwater.Asampleofmilk polytrontissuegrinder.Next90µLof2M sodiumace- fatwasmethylatedin0.5Msodiummethoxideinmeth- tateand900µLofasolutioncontainingphenol,chloro- anol followed by a second methylation in acetyl chlo- form, and indole-3-acetic acid was added to the lysate ride:methanol (1:10, vol/vol) as described by Kramer and incubated on ice for 15 min. Samples were centri- et al. (1997). Fatty acid methyl esters in milk were fugedfor20minat14,000×ginarefrigeratedmicrocen- separatedbyGLC(HP5890,AgilentTechnologies,Palo trifuge. The supernatant was transferred to a fresh Alto,CA)ona30m×0.25mm×0.2µm-filmthickness tube and RNA was precipitated with an equal volume SP2380capillarycolumn(Supleco,Inc.,Bellefonte,PA). ofisopropanolandincubatedat−20°Cfor1h.Samples Thecolumnovenwasprogrammedtorise4°C/minfrom werethencentrifugedat14,000×gfor10mintopellet aninitialtemperatureof50°C(heldfor2min)toafinal RNA and washed with 1 ml of 70% ethanol. The RNA temperatureof250°C(heldfor15min).Temperatures pelletwasdriedandresuspendedin30µLofdiethylene of the injector (100:1 split) and detector (flame ioniza- pyrocarbonate-treated water. The RNA purity and tion)ovenswere250°and260°C,respectively.Helium quantity was measured by absorbance at 260/280 nm was the carrier gas (20 cm/s). in a spectrophotometer. Efficiency of transfer of EPA and DHA from diet to milkwascalculatedbydividingthemeanmassoffatty acidsecretedinmilkdaily(averagedailymilkproduc- Determination of PGHS-2 mRNA tion×averagemilkfatpercentage×averageproportion Concentrations in Placentomes of EPA or DHA in milk fat) by the mean mass of that Evaluation of PGHS-2 mRNA was accomplished fatty acid consumed daily with the diet (average daily using glyceraldehyde-3-phosphate dehydrogenase DMI × estimated concentration of EPA or DHA in the (G3PDH) mRNA as an internal control. Primers for diet). Milk fat and fish oil were corrected for glycerol, G3PDH were designed from the published sequences assuming 10% by weight. and yielded the expected 106-base pair product. The PGHS-2 primers yielded the expected 484-base pair Collection of Caruncles fragment and were designed as described previously (Tsaietal.,1996).Reversetranscriptionwascarriedout Caruncles were collected from 23 cows by manual with 19 µL of 1× master mix (1× reverse transcription extraction through the vagina within 12 h of parturi- buffer, 0.2 mM deoxynucleotides, 100 pmol random tion.Tominimizebacterialcontaminationoftherepro- primer,and40Uofreversetranscriptase)and1µLof ductivetract,theperinealareawaswashedwithadis- sample for 1.5 h at 37°C. For PCR, 4 µL of reverse infectant solution and dried with a paper towel. The transcriptionreactionwasaddedto1×PCRmastermix technician used a shoulder-length sleeve and sterile (1×thermophilicbuffersuppliedwithenzyme,1.5mM lubrication. After collection, caruncles were washed MgCl , 0.2 mM deoxynucleotides, 0.4 µM each of for- 2 with water, plunged in liquid nitrogen, and stored at ward and reverse primer pairs, and 1 U of Taq DNA −80°C. Subsamples of frozen caruncles were subse- polymerase) for 28 cycles (95°C for 30 s, 57°C for 30 s, quently used for total RNA extraction, preparation of and72°Cfor30s,followedbyafinalextensionat72°C tissue lysates for protein analyses, and determination for 5 min). Reaction products were separated on a 5% offattyacidcomposition.Approximately7gofcaruncu- PAGEgelandstainedwithethidiumbromide.Foreach lartissuewerefreeze-driedfor24husingalyophilizer sample,PGHS-2andG3PDHproductswerequantified (Labconco, Kansas City, MO) to obtain a final mass of usingtheCollageimagingsystem(FotodyneHartland, approximately1.5gofDM.Fattyacidsindrycaruncu- WI; Tsai et al., 1996). lartissueweremethylatedandseparatedbygaschro- matograph using the same techniques described for Determination of PGHS-2 Protein milk fatty acid composition. The only change was the Concentrations in Placentomes temperatureprogramofthegaschromatograph,which increased from 140°C (3 min) to 220°C (20 min) at The PGHS-2 protein was analyzed by immunoblot. 3.7°C/min. Frozenuterinetissue(~60mg)washomogenizedin400 JournalofDairyScienceVol.87,No.4,2004 926 MATTOSETAL. µLofcoldhomogenizationbuffer(50mMTris[pH7.4], within treatment × parity, and second-order interac- 150 mM NaCl, 1 mM sodium orthovanadate, 1 mM tions between treatment, parity, and time. phenylmethylsulfonyl fluoride, 1 mg/mL leupeptin, 1 Dataonmilkfattyacidprofilesandsteady-statelev- mg/mL aprotinin, 1% Triton X-100, and 0.25% deoxy- elsofPGHS-2mRNAandproteinincarunculartissue cholate) using a polytron tissue grinder. Lysate was were analyzed using the GLM procedure. The model centrifuged twice at 16,000 × g for 10 min to obtain a foranalysisofmilkfattyacidprofiles,PGHS-2mRNA, clear lysate.An equal volumeof 2× loadingbuffer was and PGHS-2protein included the effectsof treatment. added, and samples were steamed for 5 min. Samples The steady-state levels of G3PDH mRNA and β-actin (20 to 30 µL) and 6.25 to 100 ng of PGHS-2 standards protein were included as a covariate in the model for (Cayman Chemical, Ann Arbor, MI) were loaded on a analyses of PGHS-2 mRNA and PGHS-2 protein, re- 10%SDS-PAGEgelandproteinswereseparatedat120 spectively, to adjust for loading. Effects of treatment mA for 1.5 h. Proteins were transferred to polyvinyli- onthenumberofdaysinfeedprepartumandthediffer- dene fluoride membrane using the mini-protean II gel enceindaysbetweentheexpectedduedateandactual transfer system (Bio-Rad, Hercules, CA). Following calvingdatealsoweretestedusingtheGLMprocedure. transfer, blots were incubated in blocking buffer (10 Themodelincludedtheeffectoftreatmentonly.Dataon mM Tris, pH 7.4, 150 mM NaCl, 0.1% Tween 20, and differenceswereconsideredsignificantatthe5%level. 5%NDM)overnightat4°C.Immunoblottingproceeded by incubating blots with antiPGHS-2 antibody (Cay- RESULTS AND DISCUSSION man Chemical, Ann Arbor, MI) at 1:2000 dilution for 2 h at 25°C, followed by 3× washing (10 mM Tris, pH ThelengthofprepartumfeedingwithOO(22.5±2.8) 7.4,150mMNaCl,and0.1%Tween20).TheantiPGHS- or FO (21.8 ± 3.3) did not differ (P > 0.05). The range 2antibodydoesnotcross-reactwithPGHS-1.Antirab- ofdaysfedintheprepartumperiodwas10to39.Length bithorseradishperoxidase(SantaCruzBiotechnology, of feeding did not affect the PGFM response of experi- Santa Cruz, CA) was added at 1:5000 dilution for 1 h mental cows (P > 0.05). Concentrations of EPA and at25°C,followedby3×washing.Specificproteinswere DHA in caruncular tissue were increased in cows fed detected with enhanced chemiluminescent reagent FO (P < 0.01), indicating that the dietary fatty acids (NEN Life Science Products, Boston, MA). Blots were were incorporated into uterine tissue (Table 5). The exposed to X-ray film for 1 min and quantified using combined concentrations of caruncular EPA and DHA the Collage imaging system. The PGHS-2 standards werecorrelatedpositivelywiththenumberofdayssup- were used to generate a standard curve (Y = 2859X + plementedwithFO(r2=0.64,P<0.01),suggestingthat 24969, R2 = 0.99) to determine the amount of PGHS-2 introducingFObefored21beforetheexpectedduedate presentintheuterinesamples.Toverifyequalprotein couldhavefurtherincreasedtheconcentrationsofEPA loading, membranes were stripped and reprobed with andDHAintheuterus.Resultsfromotherstudiessup- anti-actin primary antibody (Sigma, St. Louis, MO) at port the concept that this period of feeding was suffi- 1:20,000 dilution and antimouse-Horseradish Peroxi- cient to allow incorporation of dietary EPA and DHA dase (Santa Cruz Biotechnology, Santa Cruz, CA) at intomembranephospholipidsoftheuterinecaruncles. 1:5000 following the same procedure as for PGHS-2. Intravenous infusion with n-3 fatty acids reduced plasma concentrations of prostaglandin E after 4 d 2 in sheep (Baguma-Nibasheka et al., 1999). In another Statistical Analyses study, feeding rats with a diet rich in n-3 fatty acids Plasma concentrations of PGFM, glucose, NEFA, for 3 wk resulted in a 50% replacement of the uterine BHBA, and PUN were analyzed using the repeated phospholipidpoolofn-6fattyacidswithn-3fattyacids. measuresanalysisofthemixedprocedureofSAS(Lit- Thereversewastruewhenthesupplyofn-3fattyacids telletal.,1996).Covariancestructurestestedincluded waslimited.Changesinuterinefattyacidcomposition compound symmetry, autoregressive 1, and unstruc- weredetected3wkaftertheintroductionoftreatment tured. The model included effects of treatment, cow diets (Howie et al., 1992). within treatment, time, and treatment × time interac- Cows fed FO had reduced concentrations of plasma tion. Differences among treatment means of the treat- PGFM during the period of maximum secretion in the ment×dayinteractionweretestedusingthesliceoption early postpartum period compared with cows fed OO. of the mixed procedure. Differences weresignificant (P< 0.05) at0, 0.5, 2,and Milkand4%FCMproduction,percentagesoffatand 2.5dpostpartum(Figure1).Thepatternofpostpartum proteininmilk,andyieldsofproteinandfatwereana- concentrations of plasma PGFM was similar to what lyzed using the mixed procedure of SAS. The model was previously reported. The inhibitory effects of FO included the effects of treatment, parity, time, cow on concentrations of plasma PGFM are in agreement JournalofDairyScienceVol.87,No.4,2004 REPRODUCTIVEANDPRODUCTIONRESPONSESTOFISHOIL 927 Table 5. Fatty acid profile of caruncles of Holstein cows fed diets containing olive or fish oil (% of total fattyacidintissue). Diet Fattyacid1 Oliveoil Fishoil SE Treatment (g/100goffattyacids) C14 1.30 1.24 0.10 0.69 C14:1 0.27 0.18 0.05 0.25 C15:0 0.41 0.47 0.06 0.50 C16:0 19.84 21.79 0.74 0.09 C16:1 1.11 1.10 0.11 0.91 C18:0 24.97 25.53 0.47 0.04 tC18:1 1.09 2.44 0.21 <0.01 C18:1,n9 19.92 20.18 0.77 0.81 C18:2,n6 12.22 9.30 0.46 <0.01 CLAt9t11 0.35 0.27 0.07 0.40 CLAc9t11 0.36 0.35 0.05 0.88 C18:3,n3 0.51 0.44 0.08 0.52 C20:0 1.10 0.89 0.05 <0.01 C20:5,n3 0.23 1.66 0.02 <0.01 C22:0 5.09 4.09 0.20 <0.01 C22:6,n3 0.59 3.11 0.37 <0.01 C24:0 0.70 0.63 0.08 0.53 1Expressedasnumberofcarbons:doublebonds. withthestudyofThatcheretal.(1997),whichdemon- concentration of plasma PGFM between parturition strated that feeding diets containing 5.4% fish meal and d 5 tended to be significant (r2 = −0.14, P < 0.09). (DM basis) attenuated the plasma PGFM response to A sustained difference in plasma PGFM concentra- injections of estradiol-17β and oxytocin given on d 15 tions between cows fed OO and FO was not observed of the estrous cycle of dairy cows. Mattos et al. (2002) throughout the experimental period. Plasma PGFM described similar effects of increasing concentrations concentrations of cows fed OO and FO converged at ofdietaryfishmeal(0,2.6,5.2,and7.8%ofdietaryDM) approximately d 5 and remained similar until the end onsecretionofuterinePGF2αinducedbyestradioland oftheexperiment.TheearlyreductioninplasmaPGFM oxytocin on d 15 of the estrous cycle. In the present concentrations could be explained by an FO-induced study, the increased concentrations of inhibitory EPA reductioninPGF syntheticactivityincarunculartis- 2α and DHA in caruncular tissue of cows fed FO suggest sue, which is a major source of PGF (Guilbault et 2α that these fatty acids may be the active components al., 1984a, 1984b). With the normal early shedding of reducing secretion of PGF2α. The correlation between caruncular tissue (Gier and Marion, 1968) in both caruncularconcentrationsofEPAandDHAandmean groups, the subsequent residual uterine production of PGF may not have been sufficient to detect possible 2α differences attributed to the diets. Diet did not affect the number of days between the expectedduedateandactualcalvingdate.Itwasantici- patedthatreduceduterinePGF secretioncouldresult 2α indelayedparturition.CowsfedOOandFOcalved3.4 ± 1.8 and 3.3 ± 2.1 d before the due date, respectively (P>0.05).However,correlationanalysisindicatedthat late calving was associated with increasing concentra- tions of EPA and DHA in caruncular tissue (r2 = 0.52, P < 0.01). Although it is tempting to speculate that increased EPA and DHA concentration in caruncular tissue cause delayed parturition, there is not a clear cause-effect relationship between the two variables. Late parturition due to causes unrelated to feeding Figure1.Pre-andpostpartumplasmaconcentrationsofprosta- could result in increased concentrations of EPA and glandinF metabolite(PGFM)ofcowsfedfishoil(▲,n=6)orolive 2α DHAduetoalongerfeedingperiodandyieldasignifi- oil((cid:1),n=8)(LSM+SE).ThePGFMconcentrationswerelowerin cowsfedfishoilat0,0.5,2,and2.5dafterparturition(*,P<0.05). cant correlation. JournalofDairyScienceVol.87,No.4,2004 928 MATTOSETAL. Table6.Dry matterintake,milkproductionand milkcompositionofHolsteincowsfed dietscontaining oliveoilorfishoil. Measurement Oliveoil Fishoil SE P Primiparous,n 1 2 Multiparous,n 7 4 DMI,prepartumkg/d 13.5 9.4 3.21 DMI,postpartumkg/d 12.7 10.4 4.01 Milk,kg/d 25.0 20.4 3.4 0.37 Milkfat,% 5.20 4.35 0.5 0.22 Milkprotein,% 3.51 3.27 0.2 0.49 4%FCM,kg/d 26.1 20.1 3.6 0.27 Milkfat,kg/d 1.27 0.81 0.13 0.03 Milkprotein,kg/d 0.86 0.63 0.11 0.18 1StandardDeviation. Feeding FO attenuated the rise in plasma PGFM and FO cows, respectively (P = 0.19). This is in concentrations that occurs in the postpartum period. agreement with the findings described by Mattos et ThemechanismbywhichdietaryEPAandDHAinhibit al. (2001), which indicated that polyunsaturated fatty secretion of uterine prostanoids likely requires their acidssuchasEPAandDHAdidnotaffectsteady-state absorption from the intestinal lumen and subsequent levels of PGHS-2 mRNA in bovine endometrial cells. incorporation into cellular lipid pools of the endome- Inaddition,concentrationsofPGHS-2proteinincarun- trium.Inthisexperiment,absorptionofEPAandDHA culartissuewereunaffectedbydiet(16.8±5.3vs.16.4 from the diet was demonstrated by the increased con- ±5.5ng/mgtissueforcowsfedOOorFO,respectively, centrationsofthesefattyacidsinmilkfat.Inaddition, P = 0.93). supplemental FOincreased the concentrationsof EPA In addition to competitive and inhibitory mecha- and DHA in caruncular tissue. Similarly, feeding fish nisms, a lower efficiency of conversion of EPA to mealincreasedtheproportionofEPAandDHAinendo- prostanoids of the 3 series may result in reduced total metriallipidsofbeefcows(Burnsetal.,2000),indicat- prostanoid synthesis. The PGHS-2 converts EPA into ingthatdietarychangescanalterthefattyacidcompo- prostanoidsofthe3seriesinalesstime-efficientman- sition of the uterus. ner than it converts arachidonic acid into prostanoids Synthesis of PGF involves cleavage of fatty acids of the 2 series (Kulmacz et al., 1994). 2α from plasma membrane phospholipids. These cleaved Daily DMI was reduced by 30.3 and 18.1% in the fattyacids generallyare unsaturatedand includeara- prepartumandpostpartumperiods,respectively,when chidonic acid and EPA, which can be converted to FOreplacedOOinthediet(Table6).Inpreviousstudies prostanoidsofthe2and3series,respectively.Increased (AbuGhazalehetal.,2002;Whitlocketal.,2002),FOfed availability of EPA in membrane phospholipids as a at2%ofdietaryDMwasdetrimentaltoDMI,whereasa result of feeding FO could displace arachidonic acid, similar intake of oil from extruded soybeans was not leading to increased synthesis of prostanoids of the 3 detrimental. seriesattheexpenseofprostanoidsofthe2series,such Averagemilkproductionbetween0and21dpostpar- asPGF .Prostanoidsofthe3seriesarelessbioactive tum was unaffected (P > 0.05) by diet although least 2α (Needleman et al., 1979), and there appears to be no squaremeansweredifferentby4.6kg/d(Table6).These evidence for their role in ruminant luteolysis. Prosta- results agree with those of AbuGhazaleh et al. (2002), glandinF hasonly25%affinityfortheovinelutealFP Donovan et al. (2000), and Whitlock et al. (2002), who 3α receptor comparedwith PGF (Balapure etal., 1989). also reported no effect of feeding FO at 2% of dietary 2α Docosahexaenoicacidmayactinadifferentmanner DM.Milkproteinandfatconcentrationsalsowereunaf- and reduce expression of the PGHS enzymes (Achard fected(P>0.05)bydiet(Table6).Othershavereported et al., 1997), which could make these enzymes less no effect of feeding FO at 2% of dietary DM on milk availableandfurtherreduceprostanoidsynthesis.Do- protein concentration, but milk fat concentration has cosahexaenoic acid is not a substrate for the PGHS been reduced (Donovan et al., 2000; AbuGhazaleh et enzymes,butitisastrongcompetitiveinhibitoroftheir al.,2002;Whitlocketal.,2002).Productionof4%FCM activity (Corey et al., 1983). and milk protein was not affected, whereas milk fat However,concentrationsofPGHS-2mRNAincarun- production was less by cows fed FO than by cows fed clescollectedwithin12hofparturitionwereunaffected OO(P<0.05).Parity×treatmentinteractionswerenot bydiet.Thesteady-statelevelsofPGHS-2were37080 significant for each of these measurements. Changes ± 6569 and 46597 ± 6094 densitometric units for OO inBW inthe prepartumand postpartumperiods were JournalofDairyScienceVol.87,No.4,2004 REPRODUCTIVEANDPRODUCTIONRESPONSESTOFISHOIL 929 Table 7.Milk fattyacid profile ofHolstein cows feddiets containingolive oil orfish oil(% of totalfatty acidinmilk). Diet Normal Treatment Fattyacid1 Oliveoil Fishoil Milk2 SE P (g/100goffattyacids) C4:0 2.01 1.85 3.29 0.13 0.40 C6:0 1.45 1.25 1.80 0.21 0.52 C8:0 0.69 0.61 1.20 0.13 0.66 C10:0 1.37 1.22 2.40 0.26 0.69 C12:0 1.45 1.30 2.69 0.25 0.67 C14:0 6.25 5.51 10.18 0.72 0.48 C14:1 0.59 0.53 — 0.04 0.31 C16:0 25.95 25.07 26.35 0.70 0.40 C16:1 1.61 1.79 2.40 0.12 0.30 C18:0 14.88 11.38 11.98 0.95 0.03 C18:1,n9 27.41 28.99 25.15 4.05 0.79 C18:2,n6 1.42 0.16 2.40 0.57 0.15 CLAt9t11 0.011 0.100 — 0.01 <0.01 CLAc9t11 0.46 0.68 — 0.09 0.12 CLAt10c12 0.00 0.021 — 0.009 0.12 TotalCLA3 0.469 0.799 — 0.10 0.04 C18:3,n3 0.084 0.162 1.50 0.005 <0.01 C20:1,n9 0.343 0.346 — 0.012 0.87 C20:5,n3 0.003 0.422 — 0.06 <0.01 C22:6,n3 0.013 0.467 — 0.08 <0.01 Other 6.68 10.75 — 0.75 <0.01 Totaln-34 0.100 1.050 — 0.15 0.01 Totaln-65 1.422 0.163 — 0.57 0.15 Totaln-96 33.50 34.84 — 1.66 0.59 Saturated 55.45 49.92 — 1.57 0.03 Unsaturated 37.69 39.18 — 1.84 0.59 1Expressedasnumberofcarbons:doublebonds. 2NationalDairyCouncil,1993. 3TotalCLA:cis-9,trans-11C18:2+trans-9,trans-11C18:2+cis-10,trans-12C18:2. 4n-3fattyacids:C18:3+C20:5+C22:6. 5n-6fattyacids:C18:2. 6n-9fattyacids:trans-C18:1+cis-C18:1+C20:1+C22:1. not affected by diet (P > 0.05), suggesting that energy FeedingFOincreasedtheconcentrationsoftotalcon- status was similar between the two groups. jugatedlinoleicacids(CLA)(P<0.01).Increasedtotal Feeding FO increased the proportion of individual CLAconcentrationsasaresultoffeedingn-3fattyacids and total n-3 fatty acids (linolenic, EPA, and DHA) in alsohavebeenreported(Cantetal.,1997;Franklinet milk when compared to cows fed OO (P < 0.01, Table al.,1999;Donovanetal.,2000).Anincreasedconversion 7). These results agree with previous reports (Cant et of dietary linoleic and linolenic acids to CLA caused al., 1997; Donovan et al., 2000). The rates of transfer by FO may explain the higher concentrations of CLA fromdiettomilkforEPAandDHAinthisstudywere observed (Whitlock et al., 2002). 5.4and7.6%,respectively.Transferefficiencyhasbeen Plasma concentrations of NEFA were not affected reported to be greater for DHA (16.2%) than for EPA by diet (P > 0.05, Figure 2). Concentrations of NEFA (9.3%) (Cant et al., 1997). The increase in concentra- increased during the week before parturition, sug- tions of n-3 fatty acids in milk from cows fed FO oc- gesting increased fat mobilization and a decreasing curredinconcertwithdecreasedconcentrationsofsatu- DMI. After parturition, NEFA concentrations de- rated fatty acids (P = 0.03). This reduction is largely creasedslowlyfrom900to600µEq/Lbyd21postpar- due to a reduction in concentrations of C18:0 in milk tum. This profile of periparturient NEFA concentra- fat from cows fed FO. Similar effects of FO on total tionsissimilartothatreportedbyGarcia-Bojaliletal. saturatedfattyacidsandonC18:0havebeenreported (1998).PlasmaconcentrationsofBHBAincreasedwith (Franklinetal.,1999;Donovanetal.,2000).Thepropor- increasing days postpartum (P < 0.02, Figure 3). Con- tion of total long-chain fatty acids (> 18 carbons) was centrations of BHBA tended to be greater in cows fed not affected by diet (P > 0.05). FO(P=0.08,diet×dayinteraction).Pairwisecompari- JournalofDairyScienceVol.87,No.4,2004 930 MATTOSETAL. Figure2.Pre-andpostpartumplasmaconcentrationsofNEFA of cows fed fish oil (▲, n = 6) or olive oil ((cid:1), n = 8) (LSM ± SE). Figure4.Profilesofplasmaglucoseconcentrationsofperipartur- Concentrationswerenotaffectedbydiet(P>0.05). ientcowsfeddietscontainingfishoil(▲,n=6)oroliveoil((cid:1),n= 8)(LSM+SE).(**,P≤0.05;*P≤0.1).Themaineffectofthediet issignificant(P=0.03). sons of treatment means indicated differences on d 10 (P = 0.05) and 13 (P = 0.10). The timing of peak and rangeofBHBAconcentrationsofthisstudyweresimi- gluconeogenesis and therefore reduced plasma glu- lar to those reported by Vazquez-An˜on et al. (1997). cose concentrations. FeedingFOreducedplasmaconcentrationsofglucose Concentrations of PUN were greater in the prepar- (P=0.03,Figure4).Concentrationspeakedat1dbefore tumperiodincowsfedFO,asdeterminedbydifferences parturitionand declinedprogressivelyuntild 13to15 detectedond−5andd−3(P<0.1,Figure5).Postpartum postpartum.Duffieldetal.(1998)reportedsimilarpro- PUN concentrations were similar to those reported by files of postpartum glucose concentrations. The effect Roseler et al. (1993) for rations supplying 100% of the of FO on glucose concentrations could be due to the requirements of degradable intake protein and unde- reduced DMIassociated with that diet.Another possi- gradedintakeproteinforlactatingdairycows(National bleexplanationinvolvestheinhibitionofgluconeogenic Research Council, 2001). enzymes by components of FO. Eicosapentaenoic acid The incidence of postpartum health disorders was inhibited the expression of phosphoenolpyruvate car- unaffectedbydiet(Table1).TheincidenceofDA(31%, boxykinaseinrathepatomacells(Murataetal.,2001). 8/26)wasconsiderablygreaterthanwhatisconsidered This enzyme catalyzes the conversion of oxaloacetate normal for high producing herds. A survey of 61 high- tophosphoenolpyruvate,whichisarequiredstepinthe conversion of propionic acid to glucose. It is possible that EPA supplied in the FO diet may have inhibited Figure3.Pre-andpostpartumplasmaconcentrationsofBHBA Figure5.Profilesofplasmaureanitrogenofperiparturientcows of cows fed fish oil (▲, n = 6) or olive oil ((cid:1), n = 8) (LSM ± SE). feddietscontainingfishoil(▲,n=6)oroliveoil((cid:1),n=8)(LSM+ ConcentrationsofBHBAweregreaterincowsfedfishoilat10and SE).SignificantdifferencesweredetectedatDay−5andDay−3.(**, 13dafterparturition(*,P<0.10;**,P=0.05). P≤0.05;*P≤0.1). JournalofDairyScienceVol.87,No.4,2004

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Feeding fish meal, which contained .. 10% SDS-PAGE gel and proteins were separated at 120. mA for 1.5 h. Proteins .. tions of menhaden fish meal. J. Dairy
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