Environmental Effects on Gross Production and Respiration in a Facultative Oxidation Pond

Oxygen exchange by effluent samples taken at weekly intervals from a facultative oxidation pond was investigated over a 7 month period. Concentrations of ammonia, nitrate, nitrite, total and reactive phosphorus, alkalinity, total inorganic carbon, and free CO2 were measured over 12 months. Gross daily oxygen production within the community compensation depth ranged from 8 gO_2 m^-2 in winter to 43 gO_2 m^-2 in summer. The corresponding range for dark respiration was 5-17.5 gO_2 m^-2 d^-1. On average, light saturated rates of net oxygen production and total net production extended to the upper 2 and 15% of the 1.3 m mean depth profile respectively. Community respiration to gross production ratios ranged from 1.58-7.14. Light saturated rates of net oxygen production and dark rates of oxygen consumption increased with seasonal rise in pond temperature as did net production per unit detectable pigment. However, the most important factor affecting the rate of oxygen production was the concentration of detectable pigment. In laboratory studies, oxygen exchange rates were optimal at pH 5-8, but rates declined rapidly as the pH was increased from 8.0-8.5. Pond pH varied between 6.7 and 7.8 throughout the year. Net CO2 uptake under saturating irradiance (at pH 4.5) was maximal at 30 microM CO2 and compensation was reached at about 5 microM CO2. The minimum concentration of free CO2 observed in the pond was 190 microM

Adaptive Traits Are Maintained on Steep Selective Gradients despite Gene Flow and Hybridization in the Intertidal Zone

Gene flow among hybridizing species with incomplete reproductive barriers blurs species boundaries, while selection under heterogeneous local ecological conditions or along strong gradients may counteract this tendency. Congeneric, externally-fertilizing fucoid brown algae occur as distinct morphotypes along intertidal exposure gradients despite gene flow. Combining analyses of genetic and phenotypic traits, we investigate the potential for physiological resilience to emersion stressors to act as an isolating mechanism in the face of gene flow. Along vertical exposure gradients in the intertidal zone of Northern Portugal and Northwest France, the mid-low shore species Fucus vesiculosus, the upper shore species Fucus spiralis, and an intermediate distinctive morphotype of F. spiralis var. platycarpus were morphologically characterized. Two diagnostic microsatellite loci recovered 3 genetic clusters consistent with prior morphological assignment. Phylogenetic analysis based on single nucleotide polymorphisms in 14 protein coding regions unambiguously resolved 3 clades; sympatric F. vesiculosus, F. spiralis, and the allopatric (in southern Iberia) population of F. spiralis var. platycarpus. In contrast, the sympatric F. spiralis var. platycarpus (from Northern Portugal) was distributed across the 3 clades, strongly suggesting hybridization/introgression with both other entities. Common garden experiments showed that physiological resilience following exposure to desiccation/heat stress differed significantly between the 3 sympatric genetic taxa; consistent with their respective vertical distribution on steep environmental clines in exposure time. Phylogenetic analyses indicate that F. spiralis var. platycarpus is a distinct entity in allopatry, but that extensive gene flow occurs with both higher and lower shore species in sympatry. Experimental results suggest that strong selection on physiological traits across steep intertidal exposure gradients acts to maintain the 3 distinct genetic and morphological taxa within their preferred vertical distribution ranges. On the strength of distributional, genetic, physiological and morphological differences, we propose elevation of F. spiralis var. platycarpus from variety to species level, as F. guiryi