Can the foliar nitrogen concentration of upland vegetation be used for predicting atmospheric nitrogen deposition? Evidence from field surveys

The deposition of atmospheric nitrogen can be enhanced at high altitude sites as a consequence of cloud droplet deposition and orographic enhancement of wet deposition on hills. The degree to which the increased deposition of nitrogen influences foliar nitrogen concentration in a range of upland plant species was studied in a series of field surveys in northern Britain. A range of upland plant species sampled along altitudinal transects at sites of known atmospheric nitrogen deposition showed marked increases in foliar nitrogen concentration with increasing nitrogen deposition and altitude (and hence with decreasing temperature). For Nardus stricta L., Deschampsia flexuosa (L.) Trin., Calluna vulgaris (L.) Hull, Erica cinerea L. and Hylocomium splendens (Hedw.) Br. Eur. on an unpolluted hill, foliar nitrogen increased by 0.07, 0.12, 0.15, 0.08 and 0.04% dry weight respectively for each 1 kg ha(-1) year(-1) increase in nitrogen deposition. Most species showed an approximately linear relationship between foliar nitrogen concentration and altitude but no trend with altitude for foliar phosphorus concentration. This provided evidence that the tissue nutrient status of upland plants reflects nutrient availability rather than the direct effects of climate on growth. However, differences in the relationship between foliar nitrogen concentration and atmospheric nitrogen deposition for N. stricta sampled on hills in contrasting pollution climates show that the possibility of temperature-mediated growth effects on foliar nitrogen concentration should not be ignored. Thus, there is potential to use upland plant species as biomonitors of nitrogen deposition, but the response of different species to nitrogen addition, in combination with climatic effects on growth, must be well characterised.     

Toxicological and ecological implications of biotransformation enzymes in the tropical teleost Chaetodon capistratus

Hepatic cytochromes P450 (phase I monooxygenases) and glutathione transferases (phase II conjugating enzymes) were investigated in Chaetodon capistratus (Linnaeus) collected in Florida and Belize in June and December 1991, respectively. These biotransformation enzymes play major roles in the detoxification of xenobiotics by converting lipophilic chemicals to more hydrophilic, readily excretable metabolites. Content of total microsomal P450 (0.501 to 0.821 nmol mg^-1 microsomal protein) and rates of NADPH-cytochrome c (P450) reductase (270.7 to 330.2 nmol min^-1 mg^-1 microsomal protein) and glutathione transferase (2.81 to 3.12 g min^-1 mg^-1 cytosolic protein) in these fish were greater than in most untreated fish species, i.e., fish that have not been exposed to PAHs (polycyclic aromatic hydrocarbons) or PCBs (polycyclic biphenyls). Ethoxyresorufin O-deethylase (EROD) rates (0.029 to 0.171 nmol min^-1 mg^-1) were also comparable to those in most untreated marine fish. Immunoblot analysis with monoclonal antibody (MAb) 1-12-3 to scup P450E (the EROD catalyst and a teleost representative of the PAH-inducible CYP1A gene subfamily) showed slight amounts of cross-reacting protein in C. capistratus liver microsomes. Hepatic CYP1A content and EROD activity did not differ significantly between fish collected in Florida and Belize, suggesting that the two sites differed little in contamination by CYP1A inducers. Immunochemical analyses with polyclonal antibodies to scup P450B (a teleost representative of the CYP2B subfamily) and human CYP3A4 cross-reacted strongly with C. capistratus hepatic proteins. The CYP2B and CYP3A subfamilies in mammals are believed to have partially evolved in response to toxic dietary allelochemicals. C. capistratus regularly feeds on terpenoid-rich gorgonian corals, suggesting that biotransformation enzymes may be involved in the metabolism of dietary allelochemicals as well as anthropogenic xenobiotics in this species.     

Biochemical responses of the striped mullet Mugil cephalus to oil exposure I. Acute responses—Interrenal activations and secondary stress responses

Acute single exposures to the water-soluble fraction (WSF) of a No. 2 fuel oil influences several biochemical parameters in juveniles of Mugil cephalus Linnaeus. Plasma cortisol and glucose concentrations were measured at 1 and 3 h after exposure to 1, 5, 10 or 20% WSF. No elevation of plasma cortisol or glucose levels occurred in fish exposed to the lowest concentration of oil, whereas a dose-response relationship was observed at higher doses. The dynamics of plasma corticosteroid, glucose and cholesterol concentrations and osmolality as well as accumulation of naphthalenes in the fish tissues were monitored during exposure to 20% WSF. Circulating cortisol concentrations rose rapidly to 5 times normal values 1h after exposure to oil and subsequently declined to control levels 6 h after oil addition. A smaller secondary rise occurred at 12 h, but cortisol had returned to basal levels 12 h later. In contrast, plasma glucose, cholesterol and osmolality rose more slowly to reach maximum values between 3 and 4 h after oil addition. By 24 h plasma cholesterol and osmolality had returned to normal values whereas the hyperglycemia persisted. However, 72 h after the addition of WSF all biochemical parameters had returned to control levels. At this time considerable accumulation of total naphthalenes had occurred in several fish tissues, whilst the concentration of total naphthalenes in the exposure tanks had declined to background levels. When freshly prepared 20% WSF was added to the exposure tanks during this period, all biochemical parameters were again elevated. The results suggest that the volatile components of fuel oil in the water trigger the biochemical changes described in a dosedependent manner. The possible ecological significance of these changes and the potential use of these parameters as sublethal indicators of environmental contamination are discussed.