Spatial assemblage and interference competition of introduced Brown Trout (Salmo trutta) in a Himalayan river network: Implications for native fish conservation
Keywords:
Snow Trout, Himalaya, invasion, assemblage, spatial overlapAbstract
Often regarded as a potential threat to the native fish fauna worldwide, the Brown Trout (Salmo trutta), has successfully established its population in the majority of the Himalayan rivers post its introduction dating back to the eighteenth century. Over the years, the species has gained infamy as a sport fish and is considered a profitable source of income to the locals ensuing a heightened propagule pressure due to lack of appropriate management actions. No comprehensive study has been conducted to date in order to understand the mechanism by which the Brown Trout poses threat to the native fish populations. Through the present study, we could assess its competition with the native Snow Trout (Schizothorax richardsonii) to understand the spatial assemblage of both the species across space in Tirthan, a pristine high-altitude river of the western Himalaya. River Tirthan is one of the major tributaries of River Beas traversing for most of its stretch within the protected boundaries of the Great Himalayan National Park Conservation Area. A total of 108 sampling points were chosen from confluence to origin of rivers/streams, ranging from 989 to 3677msl. A total of 28 explanatory variables were recorded at each point. Overall, the Brown Trout adults were found to be greater in relative abundance (66.1%) than the Snow Trout adults (33.9%). The fingerlings of Snow Trout on the other hand, were distinctively high in relative abundance (61.9%) than those of the invasive Brown Trout (38.1%). Non-native trout showed higher abundance in the higher stream orders i.e. in the main streams while natives mostly restricted themselves to the lower order streams. Redundancy analysis (RDA) for species and environmental covariates resulted in 40.75% of constrained variance with higher eigen values for Redundancy analysis1 and Redundancy analysis2. Ward’s minimum variance clustering of Hellinger transformed data revealed sites agglomerating into six reasonable distinct subgroups with respect to species abundances. Immature individuals of non-native and native trout used similar habitat conditions, but they differed in using habitats at adult stage. Our results show a competitive dominance of Brown Trout in terms of higher abundance and maximum space utilization that highlight an urgent action for preventing its introductions to new areas. We recommend a national policy of ‘The Indian Invasive Species Act’ and management level interventions to control overstocking in the areas of established population.
References
AllanJ.D., 2004. Landscapes and riverscapes: the influence of land use on stream ecosystems. Ann. Rev. Ecol. Evol. System. 35, 257–284.
BiggsJ., Von FumettiS. and Kelly-QuinnM., 2017. The importance of small waterbodies for biodiversity and ecosystem services: implications for policy makers. Hydrobiol. 793(1), 3-39.
BuissonL., BlancL., GrenouilletG., 2008. Modelling stream fish species distribution in a river network: the relative effects of temperature versus physical factors. Ecol. Freshw. Fish. 17, 244–257.
CatherineH., 2019. gclus: Clustering Graphics. R package version 1.3.2. https://CRAN.R-project.org/package=gclus
DeaconA.E., RamnarineI.W., MagurranA.E., 2011. How Reproductive Ecology Contributes to the Spread of a Globally Invasive Fish. PLoS ONE 6(9): e24416. doi:10.1371/journal.pone.0024416.
De’athG., 2014. mvpart: Multivariate partitioning. R package version 1.6-2. https://CRAN.R-project.org/package=mvpart
DietermanD.J., WalkerT.S., CochranP.A. and KonstiM., 2016. Reproductive traits of Brown Trout in two contrasting streams of southeast Minnesota. Nor. Am. J. Fish. Manag. 36(3), 465-476.
DubeyV.K., SarkarU.K., PandeyA., SaniR. and LakraW.S., 2012. The influence of habitat on the spatial variation in fish assemblage composition in an unimpacted tropical River of Ganga basin, India. Aquat. Ecol. 46(2),165-174.
ElliottJ.M., 1989. Wild Brown Trout Salmo trutta: an important national and international resource. Freshwat. Biol. 21, 1-5.
FauschK.D., 2008. A paradox of trout invasions in North America. Biol. Inv. 10(5), 685-701.
FauschK.D., WhiteR.J., 1986. Competition among juveniles of coho salmon, brook trout, and Brown Trout in a laboratory stream, and implications for Great Lakes tributaries. Trans. Am. Fish. Soc. 115(3), 363-381.
Fernández-ChacónA., GenovartM., ÁlvarezD., CanoJ.M., OjangurenA.F., Rodriguez-MuñozR. and NiciezaA.G., 2015. Neighbouring populations, opposite dynamics: influence of body size and environmental variation on the demography of stream-resident Brown Trout (Salmo trutta). Oecol. 178, 379-389.
FischerJ.R., PaukertC.P., 2008. Habitat relationships with fish assemblages in minimally disturbed Great Plains regions. Ecol. Fresh. Fish. 17(4), 597-609.
FroeseR., PaulyD. (Eds.), 2011. Some data on Salmo trutta trutta and S. trutta fario. FishBase. World Wide Web electronic publication. www.fishbase.org. version (08/2019) Accessed 2020 March 06.
GaliliT., 2015. dendextend: an R package for visualizing, adjusting, and comparing trees of hierarchical clustering. Bioinformatics. DOI: 10.1093/bioinformatics/btv428.
GerhardP., MoraesR., MolanderS., 2004. Stream fish communities and their associations to habitat variables in a rain forest reserve in southeastern Brazil. Environ. Biol. Fish. 71, 321–340.
GerigB.S., WeberD.N., ChalonerD.T., McGillL.M. and LambertiG.A., 2017. Interactive effects of introduced Pacific salmon and Brown Trout on native brook trout: an experimental and modeling approach. Can. J. Fish. Aquat. Scie. 999, 1-11.
GooderhamJ.P., BarmutaL.A. and DaviesP.E., 2007. Upstream heterogeneous zones: small stream systems structured by a lack of competence?. J. North Amer. Benth. Soc. 26(3), 365-374.
GrenouilletG., PontD., HẽrissẽC., 2004. Within-basin fish assemblage structure: the relative influence of habitat versus stream spatial position on local species richness. Can. J. Fish. Aquat. Scie. 61, 93–102.
HeinoJ., MykraH., HamalainenH., AroviitaJ., MuotkaT., 2007. Responses of taxonomic distinctness and species diversity indices to anthropogenic impacts and natural environmental gradients in stream macroinvertebrates. Freshwater. Biol. 52, 1846–1861.
HoraS.L., 1955. Tectonic history of India and its bearing on fish geography. J. Bom. Nat. Hist. Soc. 52, 692-701.
HoxmeierR.J.H. and DietermanD.J., 2013. Seasonal movement, growth and survival of brook trout in sympatry with Brown Trout in Midwestern US streams. Ecol. Freshwat. Fish. 22(4), 530-542.
JacksonD. A., Peres-NietoP. R., OldenJ. D., 2001. What controls who is where in freshwater fish communities— the roles of biotic, abiotic, and spatial factors. Can. J. Fish. Aquat. Sci. 58, 157–170.
KauffmanM.J., VarleyN., SmithD.W., StahlerD.R., MacNultyD.R. and BoyceM.S., 2007. Landscape heterogeneity shapes predation in a newly restored predator–prey system. Ecol. Let. 10(8), 690-700.
KautzaA., SullivanS.M.P., 2012. Relative effects of local-and landscape-scale environmental factors on stream fish assemblages: evidence from Idaho and Ohio, USA. Fund. Appl. Limnol. 180, 259–270
KirkM.A., RosswogA.N., ResselK.N. and WissingerS.A., 2018. Evaluating the Trade-Offs between Invasion and Isolation for Native Brook Trout and Nonnative Brown Trout in Pennsylvania Streams. Trans. Amer. Fisher. Soc. 147(5), 806-817.
LarsonG.L. and MooreS.E., 1985. Encroachment of exotic rainbow trout into stream populations of native brook trout in the southern Appalachian Mountains. Trans. Amer. Fisher. Soc. 114(2), 195-203.
LegendreP., LegendreL. (Eds.), 1998. Numerical ecology: 2nd edition. Developments in environmental modeling. Elsevier, New York (NY).
Lobón-CerviáJ., SanzN. (Eds.), 2017. Brown Trout: Biology, Ecology and Management. Hoboken, New Jersey, USA: John Wiley & Sons Ltd,
MaechlerM., RousseeuwP., StruyfA., HubertM., HornikK., 2019. cluster: Cluster Analysis Basics and Extensions. R package version 2.1.0.
Marsh-MatthewsE., MatthewsW.J., 2000. Geographic, terrestrial and aquatic factors: which most influence the structure of stream fish assemblages in the midwestern United States? Ecol. Fresh. Fish. 9, 9–21.
MatthewsW. J., 1998 (Eds.). Patterns in freshwater fish ecology. Chapman & Hall, Norwell.
McIntoshA.R., TownsendC.R. and CrowlT.A., 1992. Competition for space between introduced Brown Trout (Salmo trutta L.) and a native galaxiid (Galaxias vulgaris Stokell) in a New Zealand stream. J. Fish. Biol. 41(1), 63-81.
MenonA.G.K., 1962. A distributional list of fishes of the Himalayas. J. Zool. Soc. India. 14(1-2), 23-32.
MohanM., 2006. Age and growth of Snow Trout Schizothorax richardsonii from Kumon Hills. Uttar Pradesh Journal of Zoology, 26(2), 163.
MuhlfeldC.C., KovachR.P., Al-ChokhachyR., AmishS.J., KershnerJ.L., LearyR.F., LoweW.H., LuikartG., MatsonP., SchmetterlingD.A., ShepardB.B., 2017. Legacy introductions and climatic variation explain spatiotemporal patterns of invasive hybridization in a native trout. Glob. Chan. Biol. 23(11), 4663–4674.
NicolaG.G., AlmodóvarA., 2002. Reproductive traits of stream-dwelling Brown Trout Salmo trutta in contrasting neighbouring rivers of central Spain. Freshwat. Biol. 47(8), 1353-1365.
OksanenJ., 2015. Multivariate Analysis of Ecological Communities in R: Vegan Tutorial. http://cc.oulu.fi/~jarioksa/opetus/metodi/vegantutor.pdf. Accessed 26 August 2020.
PetrT. (Ed.), 1999. Fish and fisheries at higher altitudes: Asia (No. 385). Food & Agriculture Org., Rome
R Core Team, 2020. R: A language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria. URL https://www.R-project.org/.
RajputV., JohnsonJ.A., SivakumarK., 2013. Environmental effects on the morphology of the Snow Trout Schizothorax richardsonii (Gray, 1832). Taprobanica: The J. Asian Biodivers., 5(2).
SehgalK.L., 1999. Coldwater fish and fisheries in the Indian Himalayas: rivers and streams. Fish and fisheries at higher altitudes: Asia. Food and Agriculture Organization of the United Nations Technical Paper, 385, pp.41-63.
SharmaA., DubeyV.K., NautiyalP., JohnsonJ.A., RawalY.K., SivakumarK., 2019. When nature decides who stays and who goes: Priority effects extirpating the non-native Brown Trout Salmo trutta fario L. population from a Himalayan river. Curr. Scie. 117(2), 186.
SharmaA., DubeyV.K., JohnsonJ.A., RawalY.K. and SivakumarK., 2021. Introduced, invaded and forgotten: allopatric and sympatric native Snow Trout life-histories indicate Brown Trout invasion effects in the Himalayan hinterlands. Biol. Inv. https://doi.org/10.1007/s10530-020-02454-8
SharmaA.P., NaskarM., JoshiK.D., BhattacharjyaB.K., SahuS.K., DasS., SudheesanD., SrivastavaP.K., RejA. and DasM.K., 2014. Impact of climate variation on breeding of major fish species in inland waters (CIFRI Bulletin no. 185).
SharmaI., DhanzeR., 2010. Length-Weight Relationship of Schizothorax richardsonii (Gray) from Indus (Beas River System, Hp) India. Rec. Zool. Surv. India. 111(1), 63-70.
SharmaR.C., 1984. Tropic dynamics of snow-trout, Schizothorax richardsonii (Gray) of Garhwal, Himalayas. Indian J. An. Sci. 54(7), 66‒69.
VannoteR.L., MinshallG.W., CumminsK.W., SedellJ.R. and CushingC.E., 1980. The river continuum concept. Can. J. Fisher. Aquat. Scie. 37(1), 130-137.
WoodfordD.J., McIntoshA.R., 2010. Evidence of source–sink metapopulations in a vulnerable native galaxiid fish driven by introduced trout. Ecol. Appl. 20(4), 967-977.
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