UUnniivveerrssiittyy ooff NNeebbrraasskkaa -- LLiinnccoollnn DDiiggiittaallCCoommmmoonnss@@UUnniivveerrssiittyy ooff NNeebbrraasskkaa -- LLiinnccoollnn USGS Staff -- Published Research US Geological Survey 2009 EEccoollooggiiccaall eeffffeeccttss ooff lleeaadd mmiinniinngg oonn OOzzaarrkk ssttrreeaammss:: IInn--ssiittuu ttooxxiicciittyy ttoo wwooooddllaanndd ccrraayyfifisshh ((OOrrccoonneecctteess hhyyllaass)) Ann L. Allert United States Geological Survey, [email protected] James F. Fairchild United States Geological Survey, [email protected] Robert J. DiStefano Central Regional Office and Conservation Research Center C.J. Schmitt United States Geological Survey, [email protected] William G. Brumbaugh United States Geological Survey, [email protected] See next page for additional authors Follow this and additional works at: https://digitalcommons.unl.edu/usgsstaffpub Allert, Ann L.; Fairchild, James F.; DiStefano, Robert J.; Schmitt, C.J.; Brumbaugh, William G.; and Besser, J.M., "Ecological effects of lead mining on Ozark streams: In-situ toxicity to woodland crayfish (Orconectes hylas)" (2009). USGS Staff -- Published Research. 531. https://digitalcommons.unl.edu/usgsstaffpub/531 This Article is brought to you for free and open access by the US Geological Survey at DigitalCommons@University of Nebraska - Lincoln. It has been accepted for inclusion in USGS Staff -- Published Research by an authorized administrator of DigitalCommons@University of Nebraska - Lincoln. AAuutthhoorrss Ann L. Allert, James F. Fairchild, Robert J. DiStefano, C.J. Schmitt, William G. Brumbaugh, and J.M. Besser This article is available at DigitalCommons@University of Nebraska - Lincoln: https://digitalcommons.unl.edu/ usgsstaffpub/531 ARTICLE IN PRESS EcotoxicologyandEnvironmentalSafety72(2009)1207–1219 ContentslistsavailableatScienceDirect Ecotoxicology and Environmental Safety journal homepage: www.elsevier.com/locate/ecoenv Ecological effects of lead mining on Ozark streams: In-situ toxicity to woodland crayfish (Orconectes hylas) A.L. Allerta,(cid:2), J.F. Fairchilda, R.J. DiStefanob, C.J. Schmitta, W.G. Brumbaugha, J.M. Bessera aUSGeologicalSurvey,ColumbiaEnvironmentalResearchCenter(USGS/CERC),4200NewHavenRoad,Columbia,MO65201,USA bMissouriDepartmentofConservation,1110SouthCollegeAvenue,Columbia,MO65201,USA a r t i c l e i n f o a b s t r a c t Articlehistory: The Viburnum Trend mining district in southeast Missouri, USA is one of the largest producers of Received22April2008 lead–zincoreintheworld.Previousstreamsurveysfoundevidenceofincreasedmetalexposureand Receivedinrevisedform reducedpopulationdensitiesofcrayfishimmediatelydownstreamofminingsites.Weconductedanin- 28July2008 situ 28-d exposure to assess toxicity of mining-derived metals tothewoodland crayfish (Orconectes Accepted28August2008 hylas). Crayfish survival and biomass were significantly lower at mining sites than at reference and Availableonline20December2008 downstreamsites.Metalconcentrationsinwater,detritus,macroinvertebrates,fish,andcrayfishwere Keywords: significantlyhigheratminingsites,andwerenegativelycorrelatedwithcagedcrayfishsurvival.These Crayfish results support previous field and laboratory studies that showed mining-derived metals negatively Orconecteshylas affectO.hylaspopulationsinstreamsdrainingtheViburnumTrend,andthatin-situtoxicitytestingwas Lead–zincmining avaluabletoolforassessingtheimpactsofminingoncrayfishpopulations. Lead PublishedbyElsevierInc. Zinc Cadmium Nickel Cobalt In-situtoxicity 1. Introduction Wixson,1977)showedthatmetalexposurestoaquaticbiotahad occurred within the Viburnum Trend. Subsequent investigations Extensive deposits of lead (Pb) ore have been mined in have documented elevated metal concentrations in water, Missouriformorethanthreecenturies.MiningoftheViburnum stream sediments, and aquatic food chains (Besser et al., 2006; Trend in southeast Missouri, USA, which contains economi- Brumbaugh et al., 2007; Schmitt et al., 2007a,b), and the cally significant Pb–zinc (Zn) ores, began in the 1950s. By 1970, loss of biota including crayfish (Allert et al., 2008) and other the Viburnum Trend was the largest Pb-producing region in macroinvertebrates(unpublisheddata;B.Poulton,USGS, Colum- the world (Ryck and Whitley, 1974). Deposits within the bia, MO). In addition, sportfish including smallmouth bass Viburnum Trend also contain considerable quantities of copper- (Micropterus dolomieu), longear sunfish (Lepomis megalotis), and (Cu),cobalt-(Co),andnickel-(Ni)bearingminerals(Jessey,1981). suckers (Catostomidae) are known to contain Pb at concentra- Although the mining district remains a major producer of Pb, tions exceeding recommended human food consumption levels and a minor producer of Zn and Cu (Missouri Department of (MissouriDepartmentofHealthandSeniorServices,2005). Natural Resources, 2004), there is no commercial recovery Crayfish hold an intermediate trophic position and facilitate ofCoorNi(Kuck,2004;Shedd,2004).Weconductednoanalyses the flow of nutrients and energy in aquatic ecosystems (Lodge of copper because previous studies have indicated that it et al., 1995). Crayfish process a significant portion of organic is a minor component of metal contamination from mining matter in streams (Usio, 2000), breaking allocthonous and in the Viburnum Trend (Besser et al., 2008; Brumbaugh et al., autochthonousmaterialintosmallerparticlesthatareultimately 2007). consumedbyaquaticinsects,snails,and microbial fauna(Huryn Although modern mining practices incorporate efficient ex- andWallace,1987;Parkynetal.,2001).Crayfisharethedominant traction technologies and operate within environmental regula- invertebratebiomassinsomeOzarkstreams(Rabenietal.,1995) tions, early studies (Duchrow, 1983; Ryck and Whitley, 1974; and are the primary food source for several centrarchid fishes (WhitledgeandRabeni,1997).Crayfisharealsopreyformorethan 200speciesofinsects,arachnids,amphibians,fish,reptiles,birds, (cid:2)Correspondingauthor.Fax:+15738761896. and mammals in and around North American water bodies E-mailaddress:[email protected](A.L.Allert). (DiStefano,2005). 0147-6513/$-seefrontmatterPublishedbyElsevierInc. doi:10.1016/j.ecoenv.2008.08.005 ARTICLE IN PRESS 1208 A.L.Allertetal./EcotoxicologyandEnvironmentalSafety72(2009)1207–1219 The southern-most mines within the Viburnum Trend are exposure through aqueous and dietary pathways, and (2) to located in the headwaters of the Black River watershed (Fig.1). evaluate the effects of mining-derived metals on survival and Thewoodlandcrayfish(Orconecteshylas)isendemictotheBlack growthofO.hylas. River watershed (Pflieger, 1996) and occurs at high densities (25–37/m2) in riffle habitats of Ozark streams (DiStefano et al., 2002). Allert et al. (2008) reported reduced densities of O. hylas 2. Methods (0–2/m2) at sites immediately downstream of mining activities comparedwithdensities(15–20/m2)atsitesupstreamofmining 2.1. Studyarea oratsitesgreaterthan10kmdownstreamofminingareasinthe Black River watershed. These findings suggest that mining Crayfishcagesweredeployedfrom30Juneto28July2005atsevensitesin activities are adverselyaffecting crayfish populations. We there- three tributaries of the Black River (Table 1). Previously collected physical, chemicalandbiologicaldata(Allertetal.,2008;Besseretal.,2006;Brumbaugh fore conducted chronic in-situ exposures of O. hylas in two etal.,2007)wereusedtoidentifyreferencesites(sitesupstreamofknownmining tributaries of the Black River watershed with the following activities);miningsites(sitesimpactedbyminingactivity);anddownstreamsites, objectives: (1) to evaluate crayfish responses relative to metal where possible biological recovery may occur. Two sites were designated as Fig.1. MapofstudysitesintheBlackRiverwatershedofMissouri,USA. ARTICLE IN PRESS A.L.Allertetal./EcotoxicologyandEnvironmentalSafety72(2009)1207–1219 1209 Table1 SamplingsitesandcagelocationsinthreetributariesoftheBlackRiver. Site Stream Latitude,longitudea Prominentminingfeatureupstream Stream Streamdistance Typeof order fromtailingsor site mine(km) SC2 StrotherCreek 37136007.200,91101040.800 Effluentpond;Buicktailings 2 3.7 M WF1 WestFork 37130039.600,91109043.200 None 2 NA R WF3 WestFork 37129049.200,91105013.200 BrushyCreektailings;WestForktailings 2 2.2 M WF4 WestFork 37129013.200,91103003.600 BrushyCreektailings;WestForktailings 2 10.1 D BF1 BeeFork 37126043.400,91106029.400 None 1 NA R BF3 BeeFork 37126028.700,91105038.000 Fletcherclarificationdamandtailings 1 0.4 M BF5 BeeFork 37127036.000,91101030.000 Fletcherclarificationdamandtailings 2 7.4 D Latitude,longitudeasdeterminedbyglobalpositioningsystem(GPS)receiver.R¼referencesite;M¼miningsite;D¼downstreamsite;NA¼notapplicable. a(GPS;710m)basedontheWGS84geodeticdatum. Fig.2. Diagramofcage.Cageframeconsistsoflow-densitypolyethylene(LDPE)strips(0.635-cmwidth)heatweldedtostainless-steel-woven-wiremesh(2.7-mmdiagonal meshopening).Cageincludesahingeddoorwith6-mmnylonshockcordusedtosecuredoorbyfasteningaroundstainlesssteelmachinescrewsinstalledoncageframe andcagedoor.Thefeeding/stockingportconsistsofatwist-offpolyvinylchloride(PVC)cap.Polyethylenemeshpacks(1.27-cmdiagonalmeshopening)filledwithrolledup scourpads(forcrayfishrefuge),organicmaterial,andcobblewereinsertedintocagepriortostockingwithcrayfishandsecuredtobottomofcagewithstainless-steelwire. reference sites (WF1, BF1); three as mining sites (SC2, WF3, BF3); and two as 2.3. Toxicitytest downstream sites (WF4, BF5). Sites classified as mining sites were 0.4–3.7km downstreamofminingactivity,whereasthoseclassifiedasdownstreamsiteswere atleast7kmdownstreamofmining-relatedactivity. A28-din-situtoxicitytestwasconductedwithjuvenileO.hylas,atsevensites intheWestFork,BeeFork,andStrotherCreekoftheBlackRiverwatershed(Fig.1). Crayfishwereexposedinhemicylindrical(0.28-m2)cagesconstructedofstainless- 2.2. Crayfishcollectionandrearing steelwiremesh(2.7-mmdiagonalopening)andpolyethylene(LDPE)reinforcing strips(Fig.2).Wecollectedcobblesubstrates(2.5–7.5cm)andapproximately10-g Ovigerous O. hylas females were collected from the reference site on the organicmaterial (henceforthdetritus)fromeachsitetoprovidebothfoodand West Fork (WF1) in early April in 2005 and returned to the US Geological shelterforcagedcrayfish.Cobble,detritus,andthreepolyethylenescourpadswere Survey’s Columbia Environmental Research Center (CERC) located in Columbia, placedinthreepolyethylene-meshpacks(15-cmlength(cid:2)30-cmwidth;1.27-cm MO, USA. Sixteen females were held in individual 2-L flow-through aquaria diagonalopening),whichwereclosedusingplasticcabletiesandsecuredtothe withCERCwellwater(temperature181C,pH7.7,alkalinity254mg/LasCaCO3, bottomofeachcageusingstainless-steelwire.Priortoplacingorganicmaterial hardness 286mg/L as CaCO3) and fed frozen brine shrimp (San Francisco Bay intothemeshpacks,allpredatoryinsects(i.e.,OdonataandPlecopteralarvae) Brand,Inc.,SanFrancisco,CA,USA)adlibitumdaily.Uponhatchinganddetaching were removed. The bottom of the cages were buried 2–4-cm into the stream from the adult females, juvenile crayfish were placed in a fiberglass tank sedimenttoexposecrayfishtosub-surfacewaterandtoanchorthecages.Minced filled with CERC wellwater and fed flake food (Ziegler Brothers, Inc., Gardner, fish(largescalestonerollers,Campostomaoligolepis;henceforthstonerollers)from PA,USA)adlibitumdailyuntiltheirbodywidthwasgreaterthan2mm.Priorto eachsitewereaddedtoeachcageweeklyinincreasingincrementstomaintain stockingcrayfishintocages,asubsetofcrayfishavailableforstockingintocages dietary rations proportional to anticipated crayfish biomass (0.1, 0.1, 0.2, 0.4g (n¼88) was measured for mean carapace length (CL, from tip of rostrum to mincedfishinweeks1,2,3,and4,respectively).Tenjuvenilecrayfishwereplaced posterioredgeofthecephalothorax,tothenearest0.1mm)andweighed(tothe in each of the six cages at each site except at SC2, where seven cages were nearest0.01g). deployed. Three cages (n¼30 crayfish) were sampled on both day14 and 28, ARTICLE IN PRESS 1210 A.L.Allertetal./EcotoxicologyandEnvironmentalSafety72(2009)1207–1219 exceptatSC2,wherefourcagesweresampledonday28.Crayfishweremeasured macroinvertebrates,stonerollers,andcrayfisharelistedinTableS-2.Allmeasured (CL and wet weight) and frozen for metal analyses. Test endpoints included concentrationsexceededtheMLDs. survival and growth. Biomass (i.e., standing crop) at day 28 was estimated Recoveriesoftheelementsfromreferencematerials(fish,mussel,oyster,plant, bymultiplyingthenumberofsurvivorsbythemeanwetweightofsurvivorsat andplankton)rangedfrom87%to115%.Relativepercentdifferences(RPDs)for eachsite. replicateanalyseswereo26%forallelementsexceptforPbanalysesofonesample of detritus (50%) and one sample of macroinvertebrates (85%). Instrumental precision, estimated by determining the RPDs from the duplicate analysis of 2.4. Wildcrayfishcollections detritusandbiotadigestates,waso4%.Recoveriesofmethodspikesforallfive metalsin14separatespikedsamplesofallthesampletypesanalyzedaveraged Wildcrayfish(O.hylas)werecollectedondays0and28ofthetoxicitytestat 97%.Post-digestionoranalysisspikerecoveriesrangedfrom83%to104%.Asa eachsitetocompareCL,wetweight,andmetalconcentrationsofwildcrayfishto checkforpotentialinterferences,dilutionpercentdifferences(DPDs)basedon5X thosestockedincages.Crayfishwerecollectedbydisturbingsubstratedirectly dilutionsof detritus and biotasample digestateswere determined;DPDs were upstreamofasmallkickseine(1-mlength(cid:2)1.5-mheight)with3-mmdeltamesh o10%forallmetals.Blank-equivalentconcentrations(BECs)fordigestionblanks (FlindersandMagoulick,2005).Wildcrayfishwerecollectedwithin200mofcage werelessthancorrespondingMLDs;thereforesampleresultswerenotcorrected placement.Collectionsweremadeupstreamordownstreamofcageplacement, for BECs. Overall, quality assurance results indicated that the methods used dependingonthenearestavailableriffle,andnumberofkickseinesrequiredto providedacceptableaccuracyandprecision,thusnoneofthesampleresultswere collect30individuals.Allcrayfishcollectedwereidentifiedtospecies,measured corrected. (CLandwetweight)andfrozenformetalanalyses. 2.7. Statisticalanalysis 2.5. Watersamples StatisticalanalyseswereconductedusingStatisticalAnalysisSystem(SAS)for Surface water quality parameters (temperature, pH, conductivity, dissolved Windows(Release9.1;SASInstitute,Cary,NC,USA).Censoredvalues(oMLD) oxygen,andturbidity)weremeasuredin-situondays0,7,14,21,and28usinga were replaced with 50%of the MLD for statistical computations and graphing. Hydrolabs Quanta meter (Loveland, CO, USA). A sub-surface grab sample was Survivalandbiomassdataofcagedcrayfishonday28ofthetoxicitytestandthe collected in a pre-cleaned 4-L carboy at each site on days 0, 14, and 28 for overallmeans(e.g.,datafromdays0,7,14,21,and28)forwaterquality,nutrients, additionalwaterqualityandnutrientanalysesatCERC.Alkalinityandhardness andmetalconcentrationswereusedinthestatisticalanalyses.Nowildcrayfish weremeasuredbytitration(APHA,2005).Sulfatewasmeasuredbycolorimetric werecollectedwithin200mofourcagesatSC2,sooursearchwasexpandeduntil detectionwithaHachs2100spectrophotometer(Loveland,CO,USA).Recoveryof oneadultwildcrayfishwascollectedatadistancegreaterthan500mawayfrom referencestandardsusedaslaboratorycontrolsamplesforsurfacewaterquality thecages;thereforeitwasnotusedinthestatisticalanalysesofCLandwetweight parameters (pH, conductivity, dissolved oxygen, turbidity, alkalinity, hardness, ofwildcrayfish.However,datafromthisindividualispresentintablesandfigures andsulfate)rangedfrom90%to118%.Overall,detectionandrecoveriesofwater forcomparativepurposes.Alldataweretestedfornormalityandhomogeneityof qualityparameterswerewithinacceptablecriteria,thusnoneofthesampleresults variance using the PROC UNIVARIATE module in SAS. Data were not normally werecorrected. distributed, therefore rank transformation were used in statistical analyses. Samples for dissolved nutrient analyses were filtered through 0.4-mm Differences in caged crayfish survival and biomass among sites and groups of polycarbonatefiltersundervacuumpressurewithin4daysofcollection.Nutrients sitesweretestedusingnestedanalysis-of-variance(ANOVA;cagesnestedwithin were measured in surface water samples with a Technicons Autoanalyzer site), with site considered a fixed effect. Differences in caged crayfish survival (Tarrytown,NY,USA)usingcolorimetricdetection(APHA,2005).Totalammonia among groups of sites were tested as planned non-orthogonal contrasts using (NH3) was analyzed using a salicylate/nitroprusside colorimetric reaction. singledegree-of-freedomF-tests.Themeansquareforcagesurvivalwithinsite Dissolvednitrite/nitrate(NO2/NO3)wasmeasuredfollowingcadmiumreduction wasusedinalltests,whichwereconductedusingthePROCGLMmoduleinSAS. and measured using colorimetric reaction (APHA, 2005). Soluble reactive Differences in crayfish survival and biomass among individual sites were also phosphorus (SRP) was determined using the automated ascorbic acid method evaluatedwithDuncan’smultiplerangetest.Differencesinwildcrayfishgrowth, (APHA,2005).Samplesfortotalphosphorous(TP)andtotalnitrogen(TN)were waterquality,nutrient,andmetalconcentrationsamonggroupsofsiteswerealso digestedinsodiumhydroxideandpotassiumpersulfatethenanalyzedusingthe testedusingthesameprocedures.Differencesinmortality,sizeofcrayfish,water automated ascorbic acid and the automated cadmium reduction methods, quality, nutrient, and metal concentrations were tested on a stream-by-stream respectively(APHA,2005).Dissolvedorganiccarbon(DOC)wasanalyzedusinga basisusingtheKruskal–Wallistest.Resultsweresimilartothosethatincludedall persulfate/UVdigestionfollowedbycolorimetricanalysisofCO2.Methodlimitsof seven sites; therefore we list only exceptional results in Table S-3. Finally, detectionlimits(MLDs)fornutrientsarelistedinTableS-1.Recoveryofreference associationsamongcagedcrayfishsurvivalandbiomassonday28,wildcrayfish standardsusedaslaboratorycontrolsamplesfornutrientsrangedfrom100%to (excludingSC2)CLandwetweight,waterquality,nutrient,andmetalconcentra- 128%,exceptforonestandardforNH3(1mgN/L)thatwas145%.Overall,detection tionswereexaminedwithSpearman’scorrelationanalysis.Asignificancelevelof and recoveries of nutrients were within acceptable criteria and all measured Po0.05wasusedtojudgeallstatisticaltests. concentrationsexceededMLDs,thusnoneofthesampleresultswerecorrected forrecovery. 3. Results 2.6. Metalconcentrations 3.1. Toxicitytest Water samples were filtered for metal analyses using a polypropylene syringeandfiltercartridge(0.45-mmporesize)intoapre-cleanedpolyethylene Meanpercentsurvivalofcagedcrayfishonday28(henceforth bottle on-site, and placed on ice. Water samples were subsequently acidified survival)wassignificantlygreateratreferencesites(90%)thanat to1%(v/v)withnitricacid(J.T.BakerInc.,Phillipsburg,NJ,USA)within4days mining sites (39%; Table 2; Fig. 3), and decreased sharply with ofcollection. SurfacewatersampleswereanalyzedforPb,Zn,Cd,Ni,andCobyinductively- increasing metal concentrations in surface water (Fig. 4). When coupled plasma-mass spectrometry (ICP-MS) (Brumbaugh et al., 2007; May analyzedonastream-by-streambasis,survivalattheminingsite etal.,1997).Calibrationverification,methodlimitsofdetection,andrecoveries (BF3) in the Bee Fork was significantly lower; however, survival ofmetalsin referencesolutions,duplicates,andspikeswereallwithinaccept- wasnotsignificantlylowerattheminingsite(WF3)intheWest able criteria and all measured concentrations exceeded MLDs (Brumbaugh Fork(TableS-3). etal.,2007). Detritus, macroinvertebrates (i.e., Ephemeroptera, Odonata, Plecoptera, MeanCLandwetweightofcagedcrayfishatallsitesonday28 Megaloptera,Trichoptera,Diptera,andChirononmidae),stonerollers,andwhole were significantly greater than those on day 0 (n¼88; crayfishfromeachsitewereanalyzedforPb,Zn,Cd,Ni,andCobyICP-MS(Besser CL¼6.770.11; wet wt.¼0.0670.003), except meanwet weight etal.,2006;Brumbaughetal.,2005).Tissueswerelyophilizedandreducedtoa ofcrayfishatSC2(Table2).MeanCLandwetweightofcrayfishat coarsepowderbymechanicalcrushinginaglassvialwithaglassrod.Neither exoskeletonsnorgutcontentsofanyofthebiotawereremovedbeforeanalysis.A day 28 were significantly greater at downstream sites than drymassof0.25gfromeachcompositedsamplewasdigestedusingconcentrated at reference or mining sites; however, CL and weight were nitricacidandmicrowaveheating.Qualitycontrolmeasuresincorporatedatthe not significantly different among mining and reference sites digestionstageincludeddigestionblanks,certifiedreferencematerials,replicates, (Table2).Meanbiomassofcrayfishatreferenceanddownstream and spikes. A calibration blank and an independent calibration verification sites on day 28 was significantly greater than at mining sites standardwereanalyzedwithevery10samplestoconfirmthecalibrationstatus oftheICP-MSduringinstrumentalanalysesofdigestates.TheMLDsfordetritus, (Table2;Fig.3). ARTICLE IN PRESS A.L.Allertetal./EcotoxicologyandEnvironmentalSafety72(2009)1207–1219 1211 Table2 Number(n)oflivingcrayfish,percent(%)survival,carapacelength(CL),andwetweight(meanswithstandarderrorinparenthesis)ofcagedOrconecteshylas. Day/site n %Survival CL(mm) Wetwt.(g) Biomass(g/m2) Day14 Referencesites WF1a 24 83(3)b 9.3(0.19)b 0.17(0.01)c 4.3(0.7)ab BF1 28 93(7)a 8.5(0.22)c 0.13(0.01)d 5.3(0.8)ab Groupmean 88(4)A 8.9(0.16)C 0.15(0.01)B 4.7(0.5)A Miningsites SC2 23 84(9)b 8.4(0.24)c 0.12(0.01)d 3.3(0.4)b WF3b 27 90(6)a 9.7(0.21)b 0.20(0.01)bc 5.3(0.6)ab BF3 17 57(23)b 9.8(0.31)b 0.18(0.02)c 4.0(1.8)ab Groupmean 77(27)A 9.3(0.16)A 0.17(0.01)B 4.3(0.6)B Downstreamsites WF4 28 84(3)b 11.2(0.17)a 0.32(0.02)a 8.3(1.8)a BF5 29 97(3)a 9.8(0.23)b 0.23(0.02)b 6.0(1.8)ab Groupmean 92(8)A 10.5(0.01)B 0.27(0.01)A 7.3(1.3)A Day28 Referencesites WF1 27 90(6)a 10.5(0.33)bc 0.40(0.02)cd 1.2(3.3)c BF1 26 90(0)a 10.8(0.37)b 0.29(0.03)de 14.7(2.3)bc Groupmean 90(3)A 10.7(0.15)B 0.33(0.14)B 13.3(1.9)B Miningsites SC2c 3 7(3)d 9.2(0.03)c 0.17(0.03)e 0.3(0.2)d WF3 20 67(9)bc 11.3(0.47)b 0.37(0.05)cd 7.7(2.5)cd BF3 16 53(3)c 13.2(0.46)a 0.58(0.05)ab 7.7(3.5)cd Groupmean 39(9)B 11.9(0.36)B 0.44(0.04)B 4.7(1.6)C Downstreamsites WF4 26 87(3)ab 14.0(0.31)a 0.71(0.05)a 32.0(4.9)a BF5 25 77(13)ab 12.9(0.3)a 0.53(0.04)bc 22.7(5.2)ab Groupmean 82(16)A 13.4(1.6)A 0.61(0.03)A 27.3(3.8)A Siteswiththesamelowercaseletterandgroupsofsiteswiththesamecapitalletterarenotsignificantlydifferentforeachtestday(Po0.05).Initialstockingnumber¼30, unlessotherwisenoted. aStockingnumber¼29. bStockingnumber¼31. cStockingnumber¼40. 3.2. Wildcrayfishcollections therewerenosignificantdifferencesinTPconcentrationsamong reference, mining and downstream sites (Table 5). Dissolved Veryfewwildcrayfishwerecollectedatanyoftheminingsites organiccarbonwassignificantlyloweratdownstreamsitesthan oneitherday0or28,despitesignificantsamplingeffort(i.e.,415 referenceorminingsites(Table5). kickseines).Meanwetweightofwildcrayfishondays0and28 Analyses on a stream-by-stream basis produced slightly weresignificantlygreateratreferenceanddownstreamsitesthan differentresultsforseveralparameters.Therewerenosignificant mining sites; however, there was no significant difference in differencesindissolvedoxygenorDOCatsitesintheWestFork; CLamonggroupsofsitesonday28(Table3). however, there were at sites in the Bee Fork (Table S-3). There weresignificantdifferencesinalkalinityatsitesintheWestFork; however, alkalinity was not significantly different at sites in the 3.3. Waterquality Bee Fork. There was no significant difference in SRP or NH in 3 either the Bee Fork or West Fork, despite an overall significant Mean conductivity, hardness, and sulfate concentrations in differencewhenSC2wasincludedintheanalyses. surface water were significantly higher at mining and down- streamsitesthanreferencesites(Table4);whereasalkalinitywas significantly lower at downstream sites than at reference and 3.4. Metalconcentrations mining sites (Table 4). Reference sites had significantly higher turbidity(Table4);however,valueswerestillverylow.Dissolved Concentrations of metals in surface water were all below oxygen and pH at reference sites were significantly lower than surface water chronic criteria (WQC; USEPA, 2002; Table 6). mininganddownstreamsites(Table4);however,atallthesites, Cobalt concentrations in surface water were also all below a therangeindissolvedoxygenandpHreadingswerenarrow. proposed Canadian guideline for chronic exposure of 4mgCo/L Ammonia, NO /NO , and TN concentrations in surface water (Nagpal,2004). However, concentrations of Pb, Zn, Ni, and Co in 2 3 from mining sites were significantly higher than reference and surfacewatersweresignificantlyhigheratminingsitescompared downstream sites (Table 5). Soluble reactive phosphorous con- withreferenceordownstreamsites(Table6). centrationsinsurfacewatersfrommininganddownstreamsites Concentrations of all metals in detritus, macroinvertebrates, were significantly lower than reference sites (Table 5); however, stonerollers, and caged crayfish were significantly higher at ARTICLE IN PRESS 1212 A.L.Allertetal./EcotoxicologyandEnvironmentalSafety72(2009)1207–1219 100 A A A A B A Lead 100 80 al 60 80 v vi ur 40 S al % v 60 vi 20 ur S % 40 00.01 0.1 1 10 Surface water Pb (µg/L) 20 100 Zinc 80 0 al 60 40 viv Reference B C A Sur 40 Mining % Downstream 20 30 2) 0 m 1 10 100 s (g/ 20 A B A Surface water Zn (µg/L) s ma 100 o Cadmium Bi SC2 80 10 WF1 al 60 WF3 v urvi 40 WF4 S 0 % BF1 Day 14 Day 28 20 BF3 BF5 Fig.3. (a)Meanpercent(%)survivaland(b)meanbiomassofcagedOrconectes 0 hylaswithingroupsofsitesondays14and28.Groupsofsiteswiththesameletter 0.01 0.1 arenotsignificantlydifferent(Po0.05). Surface water Cd (µg/L) mining sites than at reference or downstream sites, with the 100 Nickel exceptionofCdconcentrationsinmacroinvertebrates,andstone- 80 rollers(Table7;Fig.5).MeanconcentrationofPbinwildcrayfish was significantly higher at mining sites than at reference or al 60 downstreamsites(Table7).MeanconcentrationsofZnandCoin vi vi allsampletypeswerehighestatSC2.LeadandNiconcentrations ur 40 S werehighestatSC2and/orBF3.Metalconcentrationsinsamples % at all mining sites were generally two to ten-fold higher in all 20 sample types compared with those at downstream or reference 0 sites.ConcentrationsofPb,Zn,andNiwerehighestindetritusand 0.01 0.1 1 10 100 were generally higher in macroinvertebrates compared with Surface water Ni (µg/L) stonerollers or crayfish. Metal concentrations in the West Fork weregenerallylowerthanthoseintheBeeFork.Concentrationsof 100 Pb and Cd in fish; Zn in invertebrates, and Zn in surface water Cobalt werenotsignificantlydifferentamongthethreegroupsofsitesin 80 theWestFork(TableS-3). al v 60 Mean concentrations of metals in crayfish at day 0 were: Pb vi ((06..1067700.4.2mmgg/g/gddrryy wweeiigghhtt)),, NZni ((48.017700..73mmgg//gg ddrryywweeigighhtt)),,aCndd % Sur 40 Co(2.070.4mg/gdryweight).Cagedcrayfishrapidlyaccumulated 20 all metals at all mining sites (Fig. 6). Metal concentrations in caged crayfish at SC2 continued to increase throughout the 0 exposure;however,theydidnotatWF3orBF3.Metalconcentra- 0.01 0.1 1 tions in caged crayfish on day 28 at reference and downstream Surface water Co (µg/L) sitesweregenerallylowerthanconcentrationsincrayfishstocked Fig.4. Relationshipbetweenmeanpercent(%)survivalofcagedOrconecteshylas intocagesonday0.Concentrationsofmetalsincagedcrayfishat on day 28 and mean metal concentrations in surface water at sampling sites: day 28 were comparable to those in wild crayfish at all sites (a)lead;(b)zinc;(c)cadmium;(d)nickel;and(e)cobalt.Dashedlinesaremean exceptatSC2,wheremetalconcentrationsincagedcrayfishwere chronicwaterqualitycriteriaforthesamplesites. greaterthanthesinglelargewildcrayfishcollectedatSC2. ARTICLE IN PRESS A.L.Allertetal./EcotoxicologyandEnvironmentalSafety72(2009)1207–1219 1213 3.5. Correlationanalyses were negatively correlated with SRP, and CL was negatively correlatedwithTP(TableS-5). Carapace length and wet weight of caged crayfish were Meanpercentsurvivalofcagedcrayfishwasnegativelycorre- negatively correlated with Zn concentrations in stonerollers lated with most metal concentrations in surface water, detritus, (Table S-4). Carapace length and wet weight of caged crayfish macroinvertebrates, stonerollers, and caged crayfish (Table 8). Biomass of caged crayfish was negatively correlated with Zn concentrations in stonerollers and Co concentrations in caged Table3 Number(n),carapacelength(CL),andwetweight(meanswithstandarderrorin crayfish.ConcentrationsofPb,Zn,Ni,andCoincagedcrayfishand parenthesis)ofwildOrconecteshylascollectedatsamplingsitesondays0and28 allenvironmentalmatrixeswerehighlyinter-correlated(Table8). ofthein-situexposure. Lead concentrations in caged crayfish were positively correlated withPb,Zn,andNiconcentrationsinwildcrayfish(Table8).Zinc Day/site n CL(mm) Wetwt.(g) concentrations in caged crayfish were positively correlated with Day0 Coconcentrationsinwildcrayfish.Survivalofcagedcrayfishwas Referencesites negatively correlated with NH , NO /NO , TN, conductivity, 3 2 3 WF1 30 10.1(0.3)a 0.26(0.03)a hardness, and sulfate (Table S-5). Biomass of caged crayfish was BF1 35 9.5(0.2)a 0.21(0.02)a negativelycorrelatedwithDOC(TableS-5). Groupmean 9.8(0.3)A 0.23(0.02)A WetweightofwildcrayfishwascorrelatedwithCoconcentra- tionsinwildcrayfish(TableS-4);however,CLandwetweightof Miningsites wild crayfish were not significantly correlated with any water SC2 0 – – WF3 1 5.4(–)a 0.03(–)a quality parameter or nutrient concentration (Table S-5). There BF3 32 9.2(0.3)a 0.18(0.01)a werefewersignificantcorrelationsbetweenmetalconcentrations Groupmean 7.3(1.9)B 0.11(0.08)B in wild crayfish and the other samples collected at the sites; however, concentrations of Pb in wild crayfish were signifi- Downstreamsites cantlycorrelated with most metals in all sample types analyzed WF4 30 9.4(0.3)a 0.22(0.03)a (Table 8). Zinc concentrations inwild crayfish were significantly BF5 43 7.1(0.2)a 0.08(0.01)a correlatedwithPb,Zn,andCdconcentrationsindetritus,andwith 8.2(0.1)A 0.15(0.07)A Znconcentrationsinmacroinvertebrates.Nickelconcentrationsin wild crayfish were correlated with Zn concentrations in macro- Day28 invertebrates,andPb,Zn,andCdconcentrationsindetritus. Referencesites Ammonia,NO /NO ,TN,conductivity,hardness,sulfate,andNi WF1 30 12.9(0.3)a 0.58(0.04)a 2 3 BF1 37 12.0(0.4)a 0.47(0.04)a concentrations in surface water were all significantly correlated Groupmean 12.5(0.4)A 0.53(0.05)A (Table S-6). Soluble reactive phosphorous (SRP) was negatively correlated with dissolved oxygen; dissolved organic carbon was Miningsites negatively correlated with pH; and temperature was negatively SC2 1 35.0(–) 12.1(–) correlatedwithCoconcentrationsinsurfacewater.Hardnesswas WF3 12 12.2(0.4)a 0.48(0.05)a alsosignificantlycorrelatedwithPb,Ni,andCoconcentrationsin BF3 2 12.3(0.2)b 0.34(0.05)a surface water. Lead concentrations in surface water were Groupmean 12.2(0.02)A 0.41(0.07)B significantly correlated with Co concentrations in surface water, aswereNiandCoconcentrationsinsurfacewater. Downstreamsites WF4 18 13.2(0.3)a 0.56(0.04)a BF5 30 12.3(0.3)a 0.53(0.05)a 4. Discussion Groupmean 12.7(0.5)A 0.55(0.02)A Siteswiththesamelowercaseletterandgroupsofsiteswiththesamecapital We documented decrease survival of caged crayfish at sites letterarenotsignificantlydifferentforeachtestday(Po0.05). directly downstream (0.4–3.7km) of mining sites. Survival and Table4 Waterquality(meanswithstandarderrorinparenthesis)ofsurfacewateratsamplingsites. Site Temp(1C) PH(SU) Cond(ms/cm) DO(mg/L) Alk(mg/LasCaCO3) Hard(mg/LasCaCO3) Turb(NTU) Sulfate(mg/L) Referencesites WF1 23.6(0.6)a 8.04(0.03)ab 344(5)e 7.8(0.5)a 182(3)a 183(3)d 0.60(0.04)a 0.3(0.2)e BF1 23.1(1.4)b 7.84(0.09)c 282(6)f 6.3(0.4)b 143(3)c 145(2)e 0.50(0.04)a 1(0.3)e Groupmean 23.4(0.7)A 7.94(0.06)B 313(11)C 7.1(0.4)B 162(8)A 164(7)C 0.55(0.03)B 0.6(0.2)C Miningsites SC2 25.8(0.5)a 7.94(0.04)bc 858(31)a 8.0(0.2)a 117(3)d 409(11)a 0.50(0.04)a 304(10)a WF3 24.6(0.9)a 8.09(0.03)a 418(7)cd 8.4(0.3)a 170(3)b 212(3)c 0.40(0.05)a 53(3)d BF3 24.2(0.9)a 8.01(0.05)ab 592(15)b 8.4(0.1)a 143(2)c 247(5)b 0.40(0.06)a 129(6)b Groupmean 24.9(0.5)A 8.01(0.03)A 623(42)A 8.3(0.1)A 143(7)A 289(26)A 0.45(0.03)A 162(32)A Downstreamsites WF4 24.3(0.4)a 8.10(0.04)a 395(2)d 8.3(0.1)a 165(2)b 198(1)c 0.50(0.12)a 42(1)d BF5 22.9(0.8)a 8.05(0.04)ab 446(4)c 8.2(0.1)a 141(1)c 199(1)c 0.40(0.02)a 80(1)c Groupmean 23.6(0.5)A 8.08(0.03)A 420(9)B 8.3(0.1)A 152(5)B 199(1)B 0.44(0.05)A 64(8)B Temp¼temperature;Cond¼conductivity;DO¼dissolvedoxygen;Alk¼alkalinity;Hard¼hardness;Turb¼turbidity.Siteswiththesamelowercaseletterandgroups ofsiteswiththesamecapitalletterarenotsignificantlydifferent(Po0.05). ARTICLE IN PRESS 1214 A.L.Allertetal./EcotoxicologyandEnvironmentalSafety72(2009)1207–1219 Table5 Nutrientconcentrations(meanswithstandarderrorinparenthesis)ofsurfacewatersatsamplingsites. Site NH3(mgN/L) SRP(mgP/L) NO2/NO3(mgN/L) DOC(mgC/L) TN(mgN/L) TP(mgP/L) Referencesites WF1 0.01(0.002)b 0.5(0.3)a 0.04(0.01)d 0.59(0.04)bc 0.10(0.01)c 3.7(0.6)ab BF1 0.01(0.002)b 0.8(0.4)a 0.07(0.01)d 0.90(0.07)a 0.20(0.01)c 2.4(0.5)ab Groupmean 0.01(0.002)B 0.6(0.3)A 0.06(0.01)C 0.75(0.06)A 0.12(0.01)B 2.9(0.4)A Miningsites SC2 0.06(0.01)a 0.3(0.2)a 1.2(0.09)a 0.91(0.06)a 1.30(0.08)a 4.4(0.4)a WF3 0.01(0.002)b 0.2(0.1)a 0.13(0.01)cd 0.60(0.02)bc 0.20(0.02)c 2.8(0.8)b BF3 0.01(0.003)b 0c 0.51(0.02)b 0.69(0.06)b 0.50(0.03)b 2.0(0.6)a Groupmean 0.03(0.01)A 0.1(0.1)B 0.61(0.10)A 0.73(0.04)A 0.68(0.10)A 3.1(0.4)A Downstreamsites WF4 0.01(0.003)b 0a 0.08(0.01)d 0.57(0.03)c 0.10(0.01)c 2.0(0.2)b BF5 0.01(0.003)b 0.2(0.2)a 0.19(0.01)c 0.50(0.04)c 0.20(0.01)c 2.6(1.2)ab Groupmean 0.01(0.001)B 0.1(0.1)B 0.14(0.02)B 0.53(0.03)B 0.17(0.02)B 3.1(0.4)A NH3¼ammonia;SRP¼solublereactivephosphorus;NO2/NO3¼nitrite/nitrate;DOC¼dissolvedorganiccarbon;TN¼totalnitrogen;TP¼totalphosphorous.Siteswith thesamelowercaseletterandgroupsofsiteswiththesamecapitalletterarenotsignificantlydifferent(Po0.05). Table6 Concentrations(mg/L;meanswithstandarderrorinparenthesis)ofmetalsmeasuredinsurfacewaters(WC)atsamplingsites,andsitehardness-adjustedchronicwater qualitycriteria(WQC). Site Lead Zinc Cadmium Nickel Cobalt WC WQC WC WQC WC WQC WC WQC WC Referencesites WF1 0.03(0)c 4.9 4.1(2)b 197 0.03(0)b 0.37 0.13(0)c 46 0.09(0.01)de BF1 0.03(0)c 3.8 2.5(0)b 162 0.03(0)b 0.32 0.13(0)c 38 0.14(0.01)d Groupmean 0.03(0)B 4.4 3.3(1)B 180 0.03(0)A 0.35 0.13(0)B 42 0.12(0.01)B Miningsites SC2 0.71(0.02)b 11.3 56(5)a 390 0.06(0.02)a 0.65 26(2)a 90 0.64(0.05)a WF3 0.12(0.01)c 5.7 2.5(0)b 223 0.03(0)b 0.41 1.9(0.01)c 52 0.39(0.02)b BF3 1.59(0.06)a 6.8 6.6(0.2)b 254 0.03(0)b 0.46 6.0(0.01)b 59 0.28(0.01)c Groupmean 0.86(0.18)A 7.9 20(7)A 289 0.03(0.01)A 0.51 11(3)A 67 0.43(0.05)A Downstreamsites WF4 0.04(0.01)c 5.3 2.5(0)b 211 0.03(0)b 0.40 0.40(0)c 49 0.15(0.01)d BF5 0.03(0)c 5.3 3.9(1)b 211 0.03(0)b 0.40 0.50(0)c 49 0.12(0.01)d Groupmean 0.04(0.01)B 5.3 3.3(1)B 211 0.03(0)A 0.40 0.46(0.02)B 49 0.13(0.01)B Siteswiththesamelowercaseletterandgroupsofsiteswiththesamecapitalletterarenotsignificantlydifferent(Po0.05). biomassofcagedcrayfishweresignificantlyloweratminingsites that absence of crayfishpopulations below mining siteswas the than reference ordownstream sites, and survival was negatively resultofmetalexposureasopposedtohabitatlossduetophysical correlated with metal concentrations in surface water, detritus, impairmentbyminewaste(e.g.,sedimentationbyminetailings). macroinvertebrates,stonerollers,andwholecrayfish.Survivalwas Although no toxicity studies have been conducted with alsonegativelycorrelatedwithseveralwaterqualityparameters. juvenileO.hylasinsingle-metalexposures,previousstudieshave Our study supports previous results which found reduced shown several species of crayfish to be relatively sensitive to densities of O. hylas populations in riffle habitats, and elevated metals, and that juvenile crayfish are more sensitive than adult metalsconcentrations(Pb,Zn,Cd,Ni,andCo)inO.hylasatsites crayfish. Wigginton and Birge (2007) calculated 96-h median directly downstream of mining in the Black River watershed lethal concentrations (LC ) of Cd to six species of crayfish 50 (Allertetal.,2008).Metalconcentrationsindetritusandbiotaat (Cambaridae)withameanLC of1510mgCd/Lforadultcrayfish 50 miningsitesinthisstudywerecomparabletothoseofBesseretal. and of 111mgCd/L for juvenile crayfish at a water hardness of (2006), and decreased with distance from mining sites. Alikhan approximately 45mg/L as CaCO . Other studies (Lindhjem and 3 et al. (1990) also reported an inverse relationship between Bennet-Chambers, 2002; Mirenda, 1986a,b; Naqvi and Howell, distancefromacontaminantsourceandmetalconcentrationsin 1993) have also reported lethal concentrations that are greater crayfish. Conductivity, hardness, sulfate, and nitrogen ions often than the metal concentrations measured in surface waters from are elevated below mining sites (Gray,1998; Tiwary, 2001), and ourstudystreams;however,theselaboratorystudieswereshort maybeusefulinindicatingtheextentofminingimpacts.Finally, in duration and conducted with different species and sizes of in-situtestingofcrayfishwasanimportanttoolfordemonstrating crayfish.Thorpetal.(1979)reportedthatlong-termexposureto5