Photosynthesis patterns in Chesapeake Bay phytoplankton: short- and long-term responses of P-l curve parameters to light

The contribution of picoplankton (0.2 to 3.0 pm) to phytoplankton biomass and production was examined in a tributary of the Chesapeake Bay, USA, during summer 1985. The water column in thls tributary oscillates with the spring-neap tidal cycle (homogeneously mixed and stratified, respectively) whlch permits observation of the effects of water column stabdity on phytoplankton dynamics. Picoplankton made up 7 4b of the seasonal autotrophic biomass, with a peak contribution of 10 to 14 % in the first half of July. Phycocyanin-rich chroococcoid cyanobacteria, visible only with fluorescence rnicroscopy using green light excitation (510 to 560 nm), numerically dominated the picophytoplankton. being 8 x more abundant than the phycoerythrin-containing cyanobacteria. Together these 2 cyanobacteria types represented 51 % of the picophytoplankton biomass, and exhibited a pronounced fortnightly cycle in abundance which coincided with the spring-neap tidal cycle. Picoplankton were responsible for 9 O/ O of the primary production at 293 pE m-2 S-' and 13 % at 28 to 43 pE m-2 S-', averaged over the study period. Chlorophyll-specific uptake rates by the larger autotrophs (seasonal mean, 5.2 pg C pg chl a-' h-') were significantly higher than the picoplankton (seasonal mean, 2.5 pg C kg chl a-' h-')at 293 pE m-' S-', but not at 28 to 43 pE m-' S-'. A simple model based on spring-neap, tidally-induced oscillations in mixed layer depth, and its regulation of light availablhty, produced cycles in cyanobacterial growth rates which could partially explain the observed cycles in abundance. These results emphasize the importance of physlcal processes occurring on time scales of days or weeks in regulating plankton biomass and primary production in estuarine environments.

Section: Carbon Uptakesupporting

confidence: 78%

“…Based on literature values (Harding et al 1985, Glover et al 1985a, it was presumed that 293 pE m-2 s -1 represents saturating light intensity for both fractions and that chlorophyll-specific uptake rates at this intensity represented P,,, (Fig. 6).…”

Section: Carbon Uptakementioning

confidence: 99%

Autotrophic picoplankton dynamics in a Chesapeake Bay sub-estuary

Ray¹,

Haas²,

Sieracki³

1989

“…(6) provides a physiological basis for the correlation between aB and PmB frequently observed (e.g. Harding et al 1985). Such a correlation was observed here (Fig.…”

Section: Photosynthetic Parameters and Species Compositionsupporting

confidence: 64%

Phytoplankton photosynthesis, productivity, and species composition in a eutrophic estuary: comparison of bloom and non-bloom assemblages

Gallegos¹

1992

ABSTRACT, During 2 periods in the late spring and early summer 1989, blooms in the Rhode River, Maryland, USA, were triggered by nutrient inputs from local and remote watersheds. Parameters of the photosynthesis-irradiance relationship increased in May when the bloom was dominated by Thalassiosira pseudonana, and decreased in June when the bloom was dominated by large dinoflagellates. Relative variability of quantum efficiency was a s great a s that of chlorophyll-specific absorption coefficient. Light-saturated photosynthetic rates were predictable based on species counts and previously published size-dependent, nutrient-saturated growth rates for diatoms and dinoflagellates.Dinoflagellate blooms occur in years of high hydrologic nutrient input, but, due to the reduced photosynthetic efficiency of the dinoflagellate blooms, carbon fixation in the system varies proportionately less than biomass.

“…Maximum estimates of P B m and α B in LIS, converted to units of carbon for comparison with 14 C, are 1.5 and 3 times the maximum measured in some other produc- tive systems such as the Chesapeake and Delaware Bays (Harding et al 1985(Harding et al , 1986 , even after removal of weakly fitted P-I curves and exclusion of out- ) was within the same order of magnitude as theory, but still higher. High measurements of α B have also been observed in other studies , Malone & Neale 1981, Kelly & Doering 1997 contrasts with that reported in diel (MacCaull & Platt 1977, Prézelin & Sweeney 1977, daily (Cote & Platt 1983) and seasonal ) P-I studies, where range factors of α B were similar to or less than P B m .…”

Section: Mid and Bottom Waterssupporting

confidence: 52%

Temporal and spatial variability of photosynthetic parameters and community respiration in Long Island Sound

Goebel

Kremer²

2007

Photosynthetic parameters and community respiration were measured throughout 3 seasons at 8 stations in central and western Long Island Sound during 2002 and 2003. Light-dark bottle oxygen change was measured in a photosynthesis-irradiance (P-I) series for water from the mixed layer, and respiration was measured for surface, pycnocline, and near bottom water. P-I curves were fitted numerically to calculate biomass-specific rates of maximum photosynthesis at light saturation (P B m ), photosynthetic efficiency at low irradiance (α B ) and plankton community respiration (R c ). The temporal and spatial variability of these fitted parameters, the derived parameter I k , and the concentration of phytoplankton pigments were described in relation to each other and to environmental factors. Concentrations of chlorophyll (chl) and phaeopigments (phaeo), and R c reached maxima in summer and significantly decreased seaward along the length of the Sound. Photosynthetic parameters also reached maxima in summer, however there was no significant spatial variability. In surface waters, the average (± SD) of P