Influence of fisheries and shoreline management on limnological characteristics of three Missouri reservoirs

References

• Battaglin WA, Meyer MT, Kuivila KM, Dietze JE. 2014. Glyphosate and its degradation product AMPA occur frequently and widely in U.S. soils, surface water, groundwater, and precipitation. J Am Water Resour As. 50(2):275–290.
   Web of Science ®Google Scholar
• Benbrook CM. 2016. Trends in glyphosate herbicide use in the United States and globally. Environ Sci Eur. 28(1):1–15.
   Google Scholar
• Brêda-Alves F, de Oliveira Fernandes V, Chia MA. 2021. Understanding the environmental roles of herbicides on cyanobacteria, cyanotoxins, and cyanoHABs. Aquat Ecol. 55:347–361.
   Google Scholar
• Brêda-Alves F, Militão FP, de Alvarenga BF, Miranda PF, de Oliveira Fernandes V, Cordeiro-Araújo MK, Chia MA. 2020. Clethodim (herbicide) alters the growth and toxins content of Microcystis aeruginosa and Raphidiopsis raciborskii. Chemosphere. 243:125318.
   Google Scholar
• Canfield DE, Hoyer MV, Bachmann RW, Bigham Stephens D, Ruiz-Bernard I. 2016. Water quality changes at an outstanding Florida water: influence of stochastic events and climate variability. Lake Reserv Manage. 32(3):297–313.
   Web of Science ®Google Scholar
• Canfield DE, Langeland KA, Maceina MJ, Haller WT, Shireman JV, Jones JR. 1983. Trophic state classification of lakes with aquatic macrophytes. Can J Fish Aquat Sci. 40:1713–1718.
   Web of Science ®Google Scholar
• Carlson RE. 1977. A trophic state index for lakes. Limnol Oceanogr. 22:361–369.
   Web of Science ®Google Scholar
• Carlson RE, Havens KE. 2005. Simple graphical methods for the interpretation of relationships between trophic state variables. Lake Reserv Manage. 21(1):107–118.
   Web of Science ®Google Scholar
• Carper GL, Bachmann RW. 1984. Wind resuspension of sediments in a prairie lake. Can J Fish Aquat Sci. 41(12):1763–1767.
   Web of Science ®Google Scholar
• Chapman AD, Foss AJ. 2019. GreenWater laboratories potentially toxigenic (PTOX) cyanobacteria list. https://www.researchgate.net/publication/332079468_GreenWater_Laboratories_Potentially_Toxigenic_PTOX_Cyanobacteria_List
   Google Scholar
• Cudmore B, Jones LA, Mandrak NE, Dettmers JM, Chapman DC, Kolar CS, Conover G. 2017. Ecological risk assessment of grass carp (Ctenopharyngodon idella) for the Great Lakes basin. Ottawa (ON): Canadian Science Advisory Secretariat (CSAS).
   Google Scholar
• Dibble ED, Kovalenko K. 2009. Ecological impact of grass carp: a review of the available data. J Aquat Plant Manag. 47(1):1–15.
   Google Scholar
• Edmondson WT. 1961. Changes in Lake Washington following an increase in the nutrient income. Verh Internat Verein Limnol. 14:167–175.
   Google Scholar
• Graham JL, Loftin KA, Ziegler AC, Meyer MT. 2008. Cyanobacteria in lakes and reservoirs: toxin and taste-and-odor sampling guidelines. US Geological Survey Techniques of Water-Resources Investigations. Book 9, chapter A7, section 7.5.
   Google Scholar
• Guildford SJ, Hecky RE. 2000. Total nitrogen, total phosphorus and nutrient limitation in lakes and oceans: Is there a common relationship? Limnol Oceanogr. 45(6):1213–1223.
   Web of Science ®Google Scholar
• Hamilton DP, Mitchell SF. 1988. Effects of wind on nitrogen, phosphorus, and chlorophyll in a shallow New Zealand Lake. Verh Internat Verein Limnol. 23:624–628.
   Google Scholar
• Hanlon SG, Hoyer M V, Cichra CE, Canfield DE. 2000. Evaluation of macrophyte control in 38 Florida lakes using triploid grass carp. J Aquat Plant Manage. 38(1):48–54.
   Google Scholar
• Harris GP. 1980. Temporal and spatial scales in phytoplankton ecology. Mechanisms, methods, models and management. Can J Fish Aquat Sci. 37:877–900.
   Web of Science ®Google Scholar
• Harris TD, Smith VH. 2016. Do persistent organic pollutants stimulate cyanobacterial blooms? Inland Waters. 6(2):124–130.
   Web of Science ®Google Scholar
• Hébert MP, Fugère V, Gonzalez A. 2019. The overlooked impact of rising glyphosate use on phosphorus loading in agricultural watersheds. Front Ecol Environ. 17(1):48–56.
   Google Scholar
• Hoyer MV, Jones JR. 1983. Factors affecting the relation between phosphorus and chlorophyll a in Midwestern reservoirs. Can J Fish Aquat Sci. 40:192–199.
   Web of Science ®Google Scholar
• Huser BJ, Bajer PG, Chizinski CJ, Sorensen PW. 2016. Effects of common carp (Cyprinus carpio) on sediment mixing depth and mobile phosphorus mass in the active sediment layer of a shallow lake. Hydrobiologia. 763(1):23–33.
   Web of Science ®Google Scholar
• Isles PDF. 2020. The misuse of ratios in ecological stoichiometry. Ecology. 101(11):1–7.
   Google Scholar
• James W, Barko JW. 1994. Macrophyte influences on sediment resuspension and export in a shallow impoundment. Lake Reserv Manage. 10:95–102.
   Google Scholar
• Jones JR, Knowlton MF. 1993. Limnology of Missouri reservoirs. Lake Reserv Manage. 8:17–30.
   Google Scholar
• Jones JR, Knowlton MF. 2005. Suspended solids in Missouri reservoirs in relation to catchment features and internal processes. Water Res. 39(15):3629–3635.
   Google Scholar
• Jones J, Knowlton M, Obrecht D. 2008a. Role of land cover and hydrology in determining nutrients in mid-continent reservoirs: implications for nutrient criteria and management. Lake Reserv Manage. 24:1–9.
   Web of Science ®Google Scholar
• Jones JR, Knowlton MF, Obrecht DV, Thorpe AP, Harlan JD. 2009. Role of contemporary and historic vegetation on nutrients in Missouri reservoirs: implications for developing nutrient criteria. Lake Reserv Manage. 25(1):111–118.
   Web of Science ®Google Scholar
• Jones J, Obrecht D, Perkins B, Knowlton M, Thorpe A, Watanabe S, Bacon R. 2008b. Nutrients, seston, and transparency of Missouri reservoirs and oxbow lakes: an analysis of regional limnology. Lake Reserv Manag. 24(1):155–180.
   Google Scholar
• Jones JR, Pollard C, Obrecht DV. 2020a. Factors influencing phosphorus in midcontinent impoundments (USA) and challenges for detecting abatement. Inland Waters. doi.org/10.1080/20442041.2020.1816802
   Google Scholar
• Jones JR, Thorpe AP, Obrecht DV. 2020b. Limnological characteristics of Missouri reservoirs: synthesis of a long-term assessment. Lake Reserv Manage. 36(4):412–422.
   Google Scholar
• Kasinak JME, Bishop CJ, Wright RA, Wilson AE. 2015. Grass carp do not consume the nuisance benthic cyanobacterium, Lyngbya wollei. J Aquat Plant Manag. 53:74–80.
   Google Scholar
• Knoll LB, Hagenbuch EJ, Stevens MH, Vanni MJ, Renwick WH, Denlinger JC, Scott Hale R, González MJ. 2015. Predicting eutrophication status in reservoirs at large spatial scales using landscape and morphometric variables. Inland Waters. 5(3):203–214.
   Web of Science ®Google Scholar
• Knoll LB, Vanni MJ, Renwick WH. 2003. Phytoplankton primary production and photosynthetic parameters in reservoirs along a gradient of watershed land use. Limnol Oceanogr. 48(2):608–617.
   Web of Science ®Google Scholar
• Knowlton MF, Hoyer MV, Jones JR. 1984. Sources of variability in phosphorus and chlorophyll and their effects on us of lake survey data. Water Res Bull. 20:397–408.
   Google Scholar
• Knowlton MF, Jones JR. 2000. Non-algal seston, light, nutrients and chlorophyll in Missouri reservoirs. Lake Reserv Manage. 16(4):322–332.
   Google Scholar
• Knowlton MF, Jones JR. 2006a. Natural variability in lakes and reservoirs should be recognized in setting nutrient criteria. Lake Reserv Manage. 22:161–166.
   Web of Science ®Google Scholar
• Knowlton MF, Jones JR. 2006b. Temporal variation and assessment of trophic state indicators in Missouri reservoirs: implication for lake monitoring and management. Lake Reserv Manage. 22:262–271.
   Web of Science ®Google Scholar
• Lin Q, Chen Q, Peng L, Xiao L, Lei L, Jeppesen E. 2020. Do bigheaded carp act as a phosphorus source for phytoplankton in (sub)tropical Chinese reservoirs? Water Res. 180:115841.
   Google Scholar
• Liu X, Li YA, Liu BG, Qian KM, Chen YW, Gao JF. 2016. Cyanobacteria in the complex river-connected Poyang Lake: horizontal distribution and transport. Hydrobiologia. 768(1):95–110.
   Google Scholar
• Maceina MJ, Cichra MF, Betsill RK, Bettoli PW. 1992. Limnological changes in a large reservoir following vegetation removal by grass carp. J Freshwater Ecol. 7(1):81–95.
   Web of Science ®Google Scholar
• Mishra AK, Pandey AB. 1989. Toxicity of three herbicides to some nitrogen-fixing cyanobacteria. Ecotoxicol Environ Saf. 17(2): 236–246.
   Google Scholar
• Opuszynski K, Shireman JV. 1995. Herbivorous fishes: culture and use for weed management. Boca Raton (FL): CRC Press.
   Google Scholar
• Orihel DM, Baulch HM, Casson NJ, North RL, Parsons CT, Seckar DCM, Venkiteswaran JJ. 2017. Internal phosphorus loading in Canadian fresh waters: a critical review and data analysis. Can J Fish Aquat Sci. 74:2005–2029.
   Google Scholar
• Orihel DM, Hadas O, Pinkas R, Viner-Mozzini Y, Sukenik A. 2013. Internal nutrient loading may increase microcystin concentrations in freshwater lakes by promoting growth of Microcystis populations. Ann Limnol J Limnol. 49(3):225–235.
   Google Scholar
• Pérez GL, Torremorell A, Mugni H, Rodríguez P, Solange Vera M, Do Nascimento M, Allende L, Bustingorry J, Escaray R, Ferraro M, et al. 2007. Effects of the herbicide roundup on freshwater microbial communities: a mesocosm study. Ecol Appl. 17(8):2310–2322.
   Google Scholar
• Peters RH, Cattaneo A. 1984. The effects of turbulence on phosphorus supply in a shallow bay of Lake Memphremagog. Verh Int Verein Limnol. 22:185–189.
   Google Scholar
• Petty EL, Obrecht DV, North RL. 2020. Filling in the flyover zone: high phosphorus in Midwestern (USA) reservoirs results in high phytoplankton biomass but not high primary productivity. Front Environ Sci. 8: 111.
   Google Scholar
• Rodionov S, Overland JE. 2005. Application of a sequential regime shift detection method to the Bering Sea ecosystem. ICES J Mar Sci. 62(3):328–332.
   Web of Science ®Google Scholar
• Savino JF, Stein RA. 1982. Predator–prey interaction between largemouth bass and bluegills as influenced by simulated, submersed vegetation. T Am Fish Soc. 111:255–266.
   Web of Science ®Google Scholar
• Saxton MA, Morrow EA, Bourbonniere RA, Wilhelm SW. 2011. Glyphosate influence on phytoplankton community structure in Lake Erie. J Great Lakes Res. 37(4):683–690.
   Google Scholar
• Scheffer M. 2001. Alternative attractors of shallow lakes. Sci World J. 1:254–263.
   Google Scholar
• Scheffer M, Hosper SH, Meijer ML, Moss B, Jeppesen E. 1993. Alternative equilibria in shallow lakes. Trends Ecol Evol. 8(8):275–279.
   PubMed Web of Science ®Google Scholar
• [USEPA] US Environmental Protection Agency. 2019. Recommended human health recreational ambient water quality criteria or swimming advisories for microcystins and cylindrospermopsin. https://www.epa.gov/wqc/draft-technical-support-document-implementing-2019-recommended-human-health-recreational-ambient
   Google Scholar
• Vollenweider RA. 1975. Input-output models: with special reference to the phosphorus loading concept in limnology. Schweiz Z Hydrol. 37:53–84.
   Google Scholar
• Whitledge GW, Chapman DC, Farver JR, Herbst SJ, Mandrak NE, Miner JG, Pangle KL, Kočovský PM. 2021. Identifying sources and year classes contributing to invasive grass carp in the Laurentian Great Lakes. J Great Lakes Res. 47(1):14–28.
   Google Scholar
• Wu L, Qiu Z, Zhou Y, Du Y, Liu C, Ye J, Hu X. 2016. Physiological effects of the herbicide glyphosate on the cyanobacterium Microcystis aeruginosa. Aquat Toxicol. 178:72–79.
   Google Scholar
• Zambrano L, Scheffer M, Martínez-Ramos M. 2001. Catastrophic response of lakes to benthivorous fish introduction. Oikos. 94(2):344–350.
   Web of Science ®Google Scholar
• Zanchett G, Oliveira-Filho EC. 2013. Cyanobacteria and cyanotoxins: from impacts on aquatic ecosystems and human health to anticarcinogenic effects. Toxins. 5(10):1896–1917.
   PubMedGoogle Scholar