Effects of unionised ammonia on tropical freshwater organisms

Implications on temperate-to-tropic extrapolation and water quality guidelines
Zhen Wang, Kenneth M.Y. Leung
The Swire Institute of Marine Science and School of Biological Sciences, The University of Hong Kong, Pokfulam, Hong Kong, China

https://www.sciencedirect.com/science/article/abs/pii/S0269749115002821

Suscptability to Ammonia in Temperate versus Tropical Organisms

Unionised ammonia (NH3) is highly toxic to freshwater organisms. Yet, most of the available toxicity data on NH3 were predominantly generated from temperate regions, while toxicity data on NH3 derived from tropical species were limited. To address this issue, we first conducted standard acute toxicity tests on NH3 using ten tropical freshwater species. Subsequently, we constructed a tropical species sensitivity distribution (SSD) using these newly generated toxicity data and available tropical toxicity data of NH3, which was then compared with the corresponding temperate SSD constructed from documented temperate acute toxicity data. Our results showed that tropical species were generally more sensitive to NH3 than their temperate counterparts. Based on the ratio between temperate and tropical hazardous concentration 10% values, we recommend an extrapolation factor of four to be applied when surrogate temperate toxicity data or temperate water quality guidelines of NH3 are used for protecting tropical freshwater ecosystems.


Towards more Robust data on Tropical Species

Ammonia is considered as one of the most important pollutants in the freshwater environment. It can enter natural aquatic systems through direct means such as municipal sewage effluent discharges and excretion of nitrogenous wastes from animals, and indirect means such as natural nitrogenous organic matter breakdown in contaminated sediments (Thurston and Russo, 1986). In freshwater aqueous solution, unionised ammonia (NH3) exists in an equilibrium with ionised ammonia (NH4), in which the concentration of NH3 is positively correlated with water temperature and pH (Emerson et al., 1975). Harmful effects of ammonia on aquatic organisms have been extensively studied. In fish, for instance, ammonia can disrupt the normal functions of internal organs such as damage to the gill epithelium (Lang et al., 1987) and disruption of normal metabolic functioning of the liver and kidneys (Arillo et al., 1981).

To better control the release of ammonia and protect freshwater organisms from the toxicity of ammonia, a number of guidelines or criteria for ammonia have been established around the globe

To date, most of the documented acute toxicity test results for ammonia were primarily generated from temperate species in North America and Europe (Kwok et al., 2007). Acute toxicity data on ammonia derived from tropical species are limited except for two taxonomic groups of species namely, amphibians and fishes. Most tropical WQGs and ecological risk assessment (ERA) studies rely on extrapolation from temperate information, despite this the regulatory standards are widely thought to be geographic-specific (Kwok et al., 2007; Wang et al., 2014). However, there is a high uncertainty on whether or not such an extrapolation from the temperate information to generate tropical WQGs can adequately protect tropical ecosystems. This practice remains controversial and debatable in the tropics With limited acute toxicity data in terms of NH3 toxicity obtained from tropical freshwater animals (n = 9 species), Kwok et al. (2007) revealed that these tropical species were generally more sensitive to NH3 than their temperate counterparts (n = 31 species). Nonetheless, the results of their comparison of ammonia sensitivity between tropical and temperate species remained uncertain, since their tropical dataset was dominated by tropical fishes, and other taxonomic groups such as crustaceans, molluscs, insects and worms were underrepresented or missing. There is a need to generate more tropical toxicity data of NH3 from a wider array of taxa, allowing a sound comparison between the two geographical groups, and derivation of tropical WQG for ammonia and an ammonia-specific temperate-to-tropic safety extrapolation factor. There were three main objectives in this study. First, we aimed to determine the acute toxicity of NH3 on ten selected tropical freshwater organisms. Second, we systematically compared the potential differences in sensitivities of NH3 between temperate and tropical freshwater species by comparing their species sensitivity distributions (SSDs). Third, this study was also aimed at deriving interim acute and chronic predicted no-effect concentrations (PNECs) of NH3 for protecting tropical freshwater ecosystems using the tropical SSD generated in this study and available temperate acute-to-chronic ratios (ACRs), and determining a temperate-totropic safety extrapolation factor for tropical countries or regions which would borrow temperate information to derive WQGs of NH3


Invertibrates, fish and algae: Susceptibility to Ammonium Chloride solution

The test tropical freshwater species included two algae (Chlorella vulgaris and Pseudokirchneriella subcapitata), three fishes (Cheirodon axclrodi, Danio rerio and Oryzias sp.) and five invertebrates consisting of two crustaceans (Daphnia magna and Moina macrocopa), two molluscs (Pomacea lineata and Sulcospira hainanesis) and one insect (Chironomus sp.). The source and culture conditions of each test species are summarised in Table 2.


Invertibrates, Fish and Algae were Increasingly Tolerant to Ammonia

Experimental dissolved oxygen, pH and conductivity remained stable for each treatment throughout the test duration (i.e., at the beginning, the prior to test solution renewal and the termination). No differences in dissolved oxygen and pH were detected among controls and treatments for each test, while an increase in electric conductivity (ANOVA, p < 0.05) was noted with increasing NH4 concentrations of each test (Table S1). The concentration-response relationships of NH3 on the ten test species are shown in Fig. 1. Across all test species, molluscs P. lineata and S. hainanesis and insect Chironomus sp. were sensitive to NH3, in which S. hainanesis was the most sensitive one (Table 4). Fishes and crustaceans were intermediately sensitivity to NH3, while algae were the least sensitive organisms tested (Table 4).


Toxicity of NH3 Used in this Study Differed Greatly Among Ttest Species

The results of the short-term toxicity tests showed that the acute toxicity of NH3 used in this study differed greatly among test species, with almost a 32-fold difference between S. hainanesis (the most sensitive species) and C. vulgaris (the most tolerant species). Molluscs were found to be highly sensitive to NH3, and these findings were similar to several studies showing high toxicities of NH3 to temperate snails (Helisoma trivolvis, Lymnaea stagnalis and Potamopyrgus jenkinsi; Table S2). The tropical insect larva Chironomus sp. was found to be more sensitive than its temperate counterparts (e.g., Chironomus riparius: 2610 mg L1 NH3 and Chironomus tentans: 3090 mg L1 NH3; Table S2). The test fishes and crustaceans were intermediate in terms of sensitivities towards NH3. In contrast to other test species, the algae were the most tolerant group partly due to the fact that NH3 is an essential nutrient, and readily available and energy-efficient source of nitrogen to the aquatic plants, although NH3 can be toxic to the algae through inhibiting their photosynthesis when it presents at high concentrations (Kallqvista and Svenson, 2003).


Based on the Current Results, Concentrations of 15 mg L-1 NH3 and 1.5 mg L-1 NH3 at pH 7.0 and 25 C are recommended as interim acute and chronic PNECs for tropical areas, respectively.

Through comparative comparison of tropical SSDs constructed from our newly generated toxicity data and documented tropical toxicity data of NH3 with the corresponding temperate SSD constructed from temperate NH3 toxicity data, we found that tropical species are generally more sensitive to NH3. Based on the ratio between temperate and tropical HC10 values, an extrapolation factor of four is recommended when using temperate information of NH3 and related WQG as a conservative surrogate for protecting freshwater ecosystems in tropical regions. Based on the current results, concentrations of 15 mg L1 NH3 and 1.5 mg L1 NH3 at pH 7.0 and 25 C are recommended as interim acute and chronic PNECs for tropical areas, respectively.