Methodological tests of a heterotrophy index for aquatic ecosystems

• Published in: Brazilian journal of biology Vol. 63; no. 3; pp. 373 - 380
• Main Authors: Antonio, R M, Bianchini Júnior, I
• Format: Journal Article
• Language: English; Portuguese
• Published: Brazil Instituto Internacional de Ecologia 01.08.2003
• Subjects: aerobic and anaerobic kinetics; Aerobiosis; Anaerobiosis; Biodegradation, Environmental; BIOLOGY; Carbon Dioxide - metabolism; decomposition; Ecosystem; Fresh Water; Glucose - analysis; heterotrophic capacity; Hydrogen-Ion Concentration; Kinetics; mineralization; Models, Biological; Oxygen Consumption; Water Microbiology; Brazil; mineralization; decomposição; heterotrophic capacity; aerobic and anaerobic kinetics; mineralização; decomposition; capacidade heterotrófica; cinética aeróbia e anaeróbia
• ISSN: 1519-6984; 1678-4375; 1519-6984
• DOI: 10.1590/S1519-69842003000300003

Experiments in glucose mineralization were carried out to investigate the effects caused by natural forcing functions on both the decomposition rates and heterotrophy capacity of aquatic ecosystems. In addition, the methodology used could show connections between mineralization rates measured in both laboratory and field work with those measured in aquatic ecosystems. Water samples from Infernão lagoon (21 degrees 35'S and 47 degrees 51'W) were collected, filtered, enriched with glucose, and incubated under aerobic and anaerobic conditions. The glucose concentration variation, dissolved oxygen (DO) consumption, pH, electric conductivity, and total CO2 amount in the water were determined for sixteen days. In the period with intense oxygen consumption there was also an evident glucose demand and the dissolved oxygen consumption rate was approximately the same as that for glucose mineralization. The process in the aerobic chambers was 2.2 times faster than that in the anaerobic chambers. An initial acidification of the water samples, probably due to microbial carbonic acid liberation, was noted. A rise in pH values was also observed at the end of the process. The electric conductivity was low for both aerobic and anaerobic chambers, indicating a probable ion uptake by microbial organisms due to the presence of carbon sources. The glucose content variations corresponded to both CO2 formation and dissolved oxygen consumption. It was estimated that 19.4% of the initial glucose content turned into CO2 and the remaining 80.6% into humic compounds and microbial biomass. This experiment showed that glucose can be used as a substrate indicating the heterotrophy of a given aquatic ecosystem.