Abstract
Deterioration of aquatic ecosystems, as a consequence of human-induced disturbances, is a critical global concern. To fully understand the responses of aquatic systems to anthropogenic impacts, it is crucial to assess long-term changes in lakes. The water quality of Jili Lake, a large water body in northwest China, has deteriorated recently, owing to the growing impacts of regional warming and human activities. Thus, Jili Lake was a prime candidate for evaluation of historical multi-stressor impacts. Meteorological data, historical documents, and assemblages of cladoceran microfossils in the sediments of Jili Lake were employed to investigate changes in the cladoceran community over the past century, and to evaluate the response of that aquatic community to human activities. From the 1920s to the 1950s, species richness of the cladoceran community was high, which reflected conditions of relatively low human impact. From the 1960s to 1970s, a sharp decrease in Bosmina longirostris, a planktonic cladoceran species, suggested a decrease in water level as a result of dam construction and intensified water exploitation. Since the 1980s, the water level in the lake has been restored, but increased fish farming and construction of a water storage facility caused salinisation and eutrophication of Jili Lake. Accordingly, the cladoceran community displayed distinct signs of a regime shift, with a gradual transition to dominance of B. longirostris and a sharp decrease in littoral species (e.g. Leydigia leydigi, L. acanthocercoides, Alona quadrangularis, Alona affinis). Our results suggest that human-induced disturbances were the main factor that drove changes in the cladoceran community since about the mid-20th century.
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References
Adamczuk M (2016) Past, present, and future roles of small cladoceran Bosmina longirostris (O.F. Müller, 1785) in aquatic ecosystems. Hydrobiologia 767:1–11
Aladin NV (1991) Salinity tolerance and morphology of the osmoregulation organs in Cladocera with special reference to Cladocera from the Aral Sea. Hydrobiologia 225:291–299
Aladin NV, Potts WTW (1992) Changes in the Aral Sea ecosystems during the period 1960–1990. Hydrobiologia 237:67–79
Alam A, Khan AA (1998) On the record of cladoceran Leydigia acanthocericoides (Chydoridae) from Aligarh, Uttar pradesh, India. J Bombay Nat Hist Soc 95:143–144
Amoros C, Urk GV (1989) Paleoecological analyses of large rivers: some principles and methods. In: Petts G (ed) Historical change of Large Alluvial Rivers. Wiley, New York, pp 143–157
Amsinck SL, Jeppesen E, Ryves D (2003) Cladoceran stratigraphy in two shallow brackish lakes with special reference to changes in salinity, macrophyte abundance and fish predation. J Paleolimnol 29:495–507
Amsinck SL, Jeppesen E, Landkildchus F (2005) Relationships between environmental variables and zooplankton subfossils in the surface sediments of 36 shallow coastal brackish lakes with special emphasis on the role of fish. J Paleolimnol 33:39–51
Appleby PG (2001) Chronostratigraphic techniques in recent sediments. In: Last WM, Smol JP (eds) Tracking environmental changes using lake sediments, vol 1. Kluwer Academic Publishers, Boston, pp 171–203
Appleby PG, Oldfield F (1978) The calculation of 210Pb dates assuming a constant rate of supply of unsupported 210Pb to sediment. Catena 5:1–8
Appleby PG, Nolan PJ, Battarbee DW (1986) 210Pb dating by low background gamma counting. Hydrobiologia 141:21–27
Appleby PG, Richardson N, Nolan PJ (1991) 241Am dating of lake sediments. Hydrobiologia 214:35–42
Barker T, Irfanullah H, Moss B (2010) Micro-scale structure in the chemistry and biology of a shallow lake. Freshwater Biol 55:1145–1163
Bennett K (1996) Determination of the number of zones in a biostratigraphical sequence. New Phytol 132:155–170
Birks HJB, Gordon AD (1985) Numerical methods in quaternary pollen analysis. Academic Press, London
Bjerring R, Becares E, Declerck S et al (2009) Subfossil cladocera in relation to contemporary environmental variables in 54 Pan-European lakes. Freshwater Biol 11:2401–2417
Bos DG, Cumming BF, Smol JP (1999) Cladocera and anostraca from the interior plateau of British Columbia, Canada, as paleolimnological indicators of salinity and lake level. Hydrobiologia 392:129–141
Brodersen KP, Whiteside MC, Lindegaard C (1998) Reconstruction of trophic state in Danish lakes using subfossil chydorid (Cladocera) assemblages. Can J Fish Aquat Sci 55:1093–1103
Brucet S, Boix D, Gascón S et al (2009) Species richeness of crustacean zooplankton and trophic structure of brackish lagoons in contrasting climate zones: north temperature Denmark and Mediterranean Catalonia (Spain). Ecography 32:692–702
Chen G, Dalton C, Tylor D (2010) Cladocera as indicators of trophic state in Irish lakes. J Paleolimnol 44:465–481
Cheng LJ, Yao SC, Xue B et al (2019) Long-term change of the assemblages and abundance of cladocerans in different ecotypes of Lake Taihu (in Chinese with English Abstract). J Lake Sci 31:1670–1684
Cheng Y, Li S, Mengubieke E (2016) Changes of water and salt characteristic of Ulungur Lake and the corresponding cause analysis (in Chinese with English Abstract). Environ Protect Xinjiang 38:1–7
Daufresne M, Lengfellner K, Sommer U (2009) Global warming benefits the small in aquatic ecosystems. Proc Natl Acad Sci USA 106:12788–12793
Davidson TA, Sayer CD, Perrow MR et al (2007) Are the controls of species composition similar for contemporary and sub-fossil cladoceran assemblages? A study of 39 shallow lakes of contrasting trophic status. J Paleolimnol 38:117–134
Dong Y, Jiang M, Liu QG (2008) Research on water quality and trophic level in Wulungu Lake (in Chinese with English Abstract). J Shanghai Fish Univ 17:564–569
Downing AL, Brown BL, Leibold MA (2014) Multiple diversity-stability mechanisms enhance population and communities stability in aquatic food webs. Ecology 95:173–184
Fan ZL (1984) Recent changes in the lakes of Xinjiang. Geogr Res 1:80–89
Folke C, Carpenter S, Walker B et al (2004) Regime shifts, resilience, and biodiversity in ecosystem management. Annu Rev Ecol Evol Syst 35:557–581
Frey DG (1986) Cladocera analysis. In: Berglund BE (ed) Handbook of holocene palaeoecology and palaecohydrology. Wiley, New York, pp 667–692
Frey DG (1993) The penetration of Cladocerans into saline waters. Hydrobiologia 267:233–248
Gasiorowski M, Szeroczysnka K (2004) Abrupt changes in Bosmina (Cladocera, Crustacea) assemblages during the history of the Ostrowite Lake (northern Poland). Hydrobiologia 526:137–144
Grimm EC (2011) TILIA software version 1.7.16. Illinois State Museum, Research and Collection Center. Springfield USA
Hammer UT (1986) Saline lake ecosystems of the world. Dr W. Junk Publishers, Dordrecht, p 616
Hofmann W (1996) Empirical relationships between cladoceran fauna and trophic state in thirteen northern German lakes: analysis of surficial sediments. Hydrobiologia 318:195–201
Hofmann W (1998) Cladocerans and chironomids as indicators of lake level changes in north temperate lakes. J Paleolimnol 19:55–62
Jeff CH, Michalak AM, Pahlevan N (2019) Widespread global increase in intense lake phytoplankton blooms since the 1980s. Nature 574:1–1
Jeppesen E, Søndergaard M, Kanstrup E et al (1994) Does the impact of nutrients on the biological structure and function of brackish and freshwater lakes differ? Hydrobiologia 275:15–30
Jeppesen E, Madsen EA, Jensen JP et al (1996) Reconstructing the past density of planktivorous fish and trophic structure from sedimentary zooplankton fossils: a surface sediment calibration data set from 30 predominantly shallow lakes. Freshwater Biol 36:115–127
Jeppesen E, Jensen JP, Skovgaard H et al (2001a) Changes in the abundance of planktivorousfifish in lake Skanderborg during the last two centuries-a palaeoecological approach. Palaeogeogr Palaeocl 172:143–152
Jeppesen E, Leavitt P, De Meester L (2001b) Functional ecology and palaeolimnology: using cladoceran remains to reconstruct antropogenic impact. Trends Ecol Evol 16:191–198
Ji FF, Shen JZ, Ma XF et al (2018) Changes in water quality and analysis of underlying causes in Ulungur Lake (in Chinese with English Abstract). J Hydroecol 39:61–66
Jiang QF, Shen J, Liu XQ et al (2010) Environmental changes recorded by lake sediments from Lake Jili, Xinjiang during the past 2500 years (in Chinese with English Abstract). J Lake Sci 22:119–126
Jiang XZ, Du N (1979) Fauna sinica: freshwater cladocera. Science Press, Beijing
Korhola A, Rautio M (2001) Cladocera and other branchipod crustaceans. In: Smol JP, Birks HJB, Last WM (eds) Tracking environmental change using lake sediments: zoological indicators, vol 4, 665th edn. Kluwer, Dordrecht, pp 5–41
Korhola A, Tikkanen M, Weckström J (2005) Quantification of Holocene lake-level changes in Finnish Lapland using a cladocera – lake depth transfer model. J Paleolimnol 34:175–190
Lampert W (1997) Zooplankton research: the contribution of limnology to general ecological paradigms. Aquat Ecol 31:19–27
Leppänen J (2018) An overview of Cladoceran studies conducted in mine water impacted lakes. Int Aquat Res 10:207–221
Liang LL, Wang F, Wang DX et al (2011) Research on the lowest ecological water level and ecological water quantity of Ulungur Lake. Adv Water Sci 04:26–34
Liu GM, Chen FZ, Liu ZW (2008) Preliminary study on cladoceran microfossils in the sediments of Lake Taihu (in Chinese with English Abstract). J Lake Sci 4:470–476
Liu GM, Liu ZW, Chen FZ et al (2013) Response of the cladoceran communities to eutrophication, fish introductions and degradation of the macrophyte vegetation in Lake Dianchi, a large, shallow plateau lake in southwestern China. Limnology 14:159–166
Liu GM, Liu ZW, Gu BH et al (2014) How important are trophic state, macrophyte and fish population effects on cladoceran communities? A study in Lake Erhai. Hydrobiologia 736:189–204
Liu JJ (2015) Analysis on the water amount flowing into Ulungur Lake (in Chinese with English Abstract). Energy Energy Conserv 5:103–105
Lotter AF, Birks JB, Hofmann W, Marchetto A (1998) Modern diatom, cladocera, chironomid, and chrysophyte cyst assemblages as quantitative indicators for the reconstruction of past environmental conditions in the Alps. II. Nutrients. J Paleolimnol 19:443–463
Ma GZ (1985) Study on the ecological balance of Ulungur Lake and its relationship with fishery (in Chinese). Arid Zone Res 1:42–46
Ren ML (1990) Fisheries of Jili Lake in Xinjiang. Heilongjiang Science and Technology Press, Harbin
Sarmaja-Korjonen K, Alhonen P (1999) Cladoceran and diatom evidence of lake-level fluctuation from a Finnish lake and the effect of aquatic-moss layers on microfossil assemblages. J Paleolimnol 22:277–290
Sarvala J, Halsinaho S (1990) Crustacean zooplankton of Finnish forest lakes in relation to acidity and other environmental factors. In: Kauppi P, Anttila P, Kenttamies K (eds) Acidification in Finland. Springer, Berlin, pp 1009–1027
Shi HB, Chen GJ, Lu HB et al (2016) Regional pattern of Bosmina responses to fish introduction and eutrophication in four large lakes from Southwest China. J Plankton Res 38:443–455
Szeroczynska K (2002) Human impact on lakes recorded in the remains of Cladocera (Crustacea). Quatern Int 95:165–174
Szeroczynska K, Sarmaja-Korjonen K (2007) Atlas of subfossil cladocera from central and northern Europe. Friends of Lower Vistula Society, Poland
Tang FJ, Jiang ZF, Liu FMH (2009) Zoobenthos and its changes in Xinjiang Jili Lake (in Chinese with English Abstract). Chin J Fish 4:42–45
Whiteside MC (1970) Danish chydoridcladocera: modern ecology and core studies. Ecol Monographs 40:79–118
Wolfram G, Donabaum K, Schagerl M et al (1999) The zoobenthic communities of shallow salt pans in Austria -preliminary results on phenology and the impact of salinity on benthic invertebrates. Hydrobiologia 408/409:193–202
Wu J, Gagan MK, Jiang X et al (2004) Sedimentary geochemical evidence for recent eutrophication of Lake Chenghai, Yunnan, China. J Paleolimnol 32:85–94
Wu J, Schleser GH, Lücke A, Li S (2007) A stable isotope record from freshwater lake shells of the eastern Tibetan Plateau, China, during the past two centuries. Boreas 36:38–46
Wu JL, Ma L, Abundauwaili J (2009) Lake surface change of the Aral Sea and its environmental effects in the arid region of the central Asia (in Chinese with English Abstract). Arid Land Geogr 32:418–422
Wu JL, Ma L (2011) Lake evolution and climatic and hydrological changes in arid zone of Xinjiang (in Chinese with English Abstract). Marine Geol Quat Geol 31:135–143
Wu JL, Ma L, Zeng HA (2013) Water quality and quantity characteristics and its evolution in Lake Bosten, Xinjiang over the past 50 Years (in Chinese with English Abstract). Sci Geogr Sin 33:231–237
Yang J, Zhou J, Qin BQ et al (2020) Long-term Variation Characteristics of Zooplankton Communities Structure in Meiliang Bay, Lake Taihu. Environ Sci 41:1246–1255
Zhang YL, Jeppesen E, Liu XH et al (2017) Global loss of aquatic vegetation in lakes. Earth-Sci Rev 173:259–265
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This research was supported by the National Key R&D Program of China (grant 2017YFA0603402).
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Hu, L., Li, Y., Leppänen, J.J. et al. Human impacts on the cladoceran community of Jili Lake, arid NW China, over the past century. J Paleolimnol 68, 59–70 (2022). https://doi.org/10.1007/s10933-021-00186-w
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DOI: https://doi.org/10.1007/s10933-021-00186-w