A protocol was developed to extract, fractionate, and quantitatively analyze periphyton extracellular polymeric substances (EPS), which obtains both information on the molecular weight (M r) distribution and protein and polysaccharide content. The EPS were extracted from freshwater periphyton between July and December 2011. Organic carbon (OC) compounds from different EPS extracts were analyzed using liquid chromatography-organic carbon detection-organic nitrogen detection (LC-OCD-OND), and total protein and polysaccharide content were quantified. Four distinct OC fractions, on the basis of M r, were identified in all extracts, corresponding to high M r biopolymers (≥80-4 kDa), degradation products of humic substances (M r not available), low M r acids (10-0.7 kDa), and small amphiphilic/neutral compounds (3-0.5 kDa). Low C/N ratios (4.3 ± 0.8) were calculated for the biopolymer fractions, which represented 16-38 % of the measured dissolved organic carbon (DOC), indicating a significant presence of high M r proteins in the EPS. Protein and polysaccharide represented the two major components of EPS and, when combined, accounted for the measured DOC in extracts. Differences in specific OC fractions of EPS extracts over the course of the study could be quantified using this method. This study suggests that LC-OCD-OND is a new valuable tool in EPS characterization of periphyton.
A protocol was developed to extract, fractionate, and quantitatively analyze periphyton extracellular polymeric substances (EPS), which obtains both information on the molen class="Chemical">cular weight (M r) distribution and protein and polysaccharide content. The EPS were extracted from freshwater periphyton between July and December 2011. Organic carbon (OC) compounds from different EPS extracts were analyzed using liquid chromatography-organic carbon detection-organic nitrogen detection (LC-OCD-OND), and total protein and polysaccharide content were quantified. Four distinct OC fractions, on the basis of M r, were identified in all extracts, corresponding to high M r biopolymers (≥80-4 kDa), degradation products of humic substances (M r not available), low M r acids (10-0.7 kDa), and small amphiphilic/neutral compounds (3-0.5 kDa). Low C/N ratios (4.3 ± 0.8) were calculated for the biopolymer fractions, which represented 16-38 % of the measured dissolved organic carbon (DOC), indicating a significant presence of high M r proteins in the EPS. Protein and polysaccharide represented the two major components of EPS and, when combined, accounted for the measured DOC in extracts. Differences in specific OC fractions of EPS extracts over the course of the study could be quantified using this method. This study suggests that LC-OCD-OND is a new valuable tool in EPS characterization of periphyton.
Authors: Monique Ras; Dominique Lefebvre; Nicolas Derlon; Etienne Paul; Elisabeth Girbal-Neuhauser Journal: Water Res Date: 2010-11-24 Impact factor: 11.236
Authors: Alexandra Kroll; Marianne Matzke; Marcus Rybicki; Patrick Obert-Rauser; Corinna Burkart; Kerstin Jurkschat; Rudo Verweij; Linn Sgier; Dirk Jungmann; Thomas Backhaus; Claus Svendsen Journal: Environ Sci Pollut Res Int Date: 2015-06-28 Impact factor: 4.223
Authors: Daniel Graeber; Iola G Boëchat; Francisco Encina-Montoya; Carlos Esse; Jörg Gelbrecht; Guillermo Goyenola; Björn Gücker; Marlen Heinz; Brian Kronvang; Mariana Meerhoff; Jorge Nimptsch; Martin T Pusch; Ricky C S Silva; Daniel von Schiller; Elke Zwirnmann Journal: Sci Rep Date: 2015-11-06 Impact factor: 4.379