Investigating the role of water and sediment chemistry from two reservoirs in regulating the growth potential of Hydrilla verticillata (L.f.) Royle and Cabomba caroliniana A. Gray

Abstract

Knowledge of aquatic system physicochemical characteristics can inform managers into growth potential of submerged plants. In a mesotrophic central Texas reservoir, Lake Austin, the exotic invasive Hydrilla verticillata (L.f.) Royle thrived for over a decade until management efforts achieved recent control. However, in the immediate downriver eutrophic reservoir, Lady Bird Lake, H. verticillata has been unsuccessful despite repeated introductions. Instead, the native plant Cabomba caroliniana A. Gray has recently colonized and spread. In this study we established mesocosms approximating each reservoir and tracked plant growth metrics to test the role of water chemistry and sediment chemistry and composition in inhibiting or supporting two internationally important species. Lake Austin had a significantly higher pH and lower nitrate concentrations in the water and sandy sediments compared to the eutrophic, silty reservoir. We observed higher growth rates and greater biomass of H. verticillata and C. caroliniana in the eutrophic reservoir treatments; the former species growth contrary to expectations. Between species, H. verticillata relative growth rates were nearly 4× higher, lengths 5–10× longer, and dry weights 2–5× greater than those for C. caroliniana within a given treatment. Concurrent with rapid growth rates in the eutrophic reservoir treatments, tissue phosphorus contents for both species increased. Our findings suggest that H. verticillata growth in the eutrophic reservoir has not been significantly impaired by the water and sediment attributes measured in this study. Conversely, our initial evidence corroborates the reduced growth potential of C. caroliniana in systems of relatively low nutrients and pH over 8.