Microbial metabolism and temperature : comparative studies in the Southern Ocean and a temperate coastal ecosystem

Blight, Stephen Paul

January 1996

Bacterial abundances and production, and the size distribution of oxygen metabolism and chlorophyll a concentration were followed through two seasonal cycles in the Menai Strait (North Wales, U. K. ) and during austral summer in the Southern Ocean. In the Menai Strait, spring blooms were characterised by a diatom to Phaeocystis succession. In both the Menai Strait and the Southern Ocean, meso- and microphytoplankton dominated phytoplankton production and biomass during diatom blooms. Nanophytoplankton predominated when production and biomass were low, i. e. during the summer in the Menai Strait, in waters near the Polar Front, and in some samples from the Weddell Sea. In both ecosystems substantial respiration resided in the bacterial (< 0.8 gm) size-fraction. Consequently during the Menai Strait temporal study, phasing of respiration in relation to photosynthesis was strongly influenced by bacterial metabolism and abundance changes. The respiration maximum occurred 1-2 weeks after the Phaeocystis abundance maximum. An explanation for this temporal lag was sought by considering the time scales of flow of organic material between the phytoplankton and the bacteria. The observations were consistent with routes via a slowly cycling pool, such as polymeric organic material. This pool would function as a reservoir and result in microheterotrophic respiration persisting after the decline of photosynthesis, causing a positive to negative temporal sequence in net community production. There was no evidence for differences in any measure of microbial biomass between the Southern Ocean and the Menai Strait. General relationships could be derived for both ecosystems: (a) the biomass quotient (< 20 µm phytoplankton / unfractionated phytoplankton) generally increased sharply as unfractionated phytoplankton biomass decreased, (b) bacterial biomass generally increased as phytoplankton biomass increased, (c) the biomass quotient of bacteria to unfractionated phytoplankton increased sharply as unfractionated phytoplankton biomass decreased. Different relationships were derived for the oxygen fluxes in terms of phytoplankton biomass for the Southern Ocean and Menai Strait observations. In these relationships, the oxygen fluxes were generally relatively (relative to the explanatory variable: phytoplankton biomass) higher in the Menai Strait. In contrast, a single relationship for DCR in terms of GCP was fitted for both data sets. This difference is consistent with a temperature effect on the oxygen fluxes, with GCP and DCR similarly suppressed at lower temperatures.

577

Plankton; Bacterial abundance

NITRIFYING BACTERIAL ABUNDANCE IN RELATION TO NITROGEN AND PHOSPHORUS COMPOUNDS IN WETLANDS

Jones, Nicole Jean

01 May 2012

Floodplain lakes are wetlands which receive flood waters from nearby rivers or other sources. Water samples were taken from floodplain lakes near the Illinois River, the Mississippi River, and the Cache River in Southern Illinois. Fluorescence in situ hybridization (FISH), spectrophotometry, and gene probes were used to investigate the effect of nutrient and chemical concentrations on the abundance of nitrifying bacteria; specifically ammonia-oxidizing Nitrosococcus and Nitrosomonadales and nitrite-oxidizing Nitrospira and Nitrobacter. Nitrosococcus was the dominant ammonia-oxidizing bacteria at each river system. Nitrospira and Nitrobacter had similar average abundances. Nitrosococcus abundances showed a significant positive correlation with nitrate (NO3-) (R2= 0.247, P=0.05, 95% confidence R2≥0.199) and a positive trend with nitrite (NO2-) (R2= 0.194, P=0.10, 90% confidence R2≥0.125). Nitrosomonadales abundance positively correlated with temperature (R2= 0.530, P=0.05, 95% confidence R2≥0.510). Nitrospira abundances positively correlated with ammonium (NH4+) (R2= 0.265, P=0.05, 95% confidence R2≥0.199), NO2- (R2= 0.372, P=0.05, 95% confidence R2≥0.199), and NO3- (R2= 0.482, P=0.05, 95% confidence R2≥0.199). None of the target bacterial abundances significantly correlated with pH or dissolved inorganic phosphate.

ammonia-oxidizing bacteria

Bacterial abundance

Illinois

Nitrification

nitrite-oxidizing bacteria

wetlands

Analysis of Bacterial Abundance and Species Diversity in Various Soils

Roth, McKenzie L.

January 2012

No description available.

Microbiology

Soil nutrients

soil bacteria

soil microbes

bacterial abundance

microbial abundance

compost

manure

topsoil

potting soil

forest soil

16S rDNA

Relating spatial patterns of denitrification and bacterial community structure to environmental conditions in streams

Baxter, Alyssa M.

18 October 2010

No description available.

Ecology

Environmental Science

Microbiology

Molecular Biology

denitrification

bacteria

bacterial community structure

TRFLP

nosZ

bacterial abundance

stream

land use

agriculture

macroinvertebrate

nitrogen