![Sample our Environment & Sustainability journals, sign in here to start your access, latest two full volumes FREE to you for 14 days]({"type":"image" , "src" : "/sda/5935/TOC-Subject-Sample-2021-Environment-Sustainability.jpg"})
SUMMARY
During the decomposition of plant detritus, complex microbial successions develop which are dominated in the early stages by a number of distinct bacterial morphotypes. The microheterotrophic community rapidly becomes heterogenous and may include cyanobacteria, fungi, yeasts and bactivorous protozoans.
Microheterotrophs in the marine environment may have a biomass comparable to that of all other heterotrophs and their significance as a resource to higher trophic orders, and in the regeneration of nutrients, particularly nitrogen, that support ‘regenerated’ primary production, has aroused both attention and controversy.
Soluble low molecular weight substrates (dissolved organic matter, or DOM) are for the most part rapidly turned over and readily taken up with a high growth efficiency by bacteria although detrital particulate organic material (POM) is turned over slowly and utilized with a low growth efficiency, owing to the structural complexity of the detritus. The presence of appropriate substrate-specific strains of bacteria Is important in the decomposition of both DOM and POM.
Estimates of the transfer of photosynthetically fixed carbon and nitrogen through the pelagic microbial community have recently become widespread. However, the quantification of C and N fluxes through bacteria and microzooplankton is very sensitive to accurate measures of microbial biomass, production, net growth yield, bacterial activity and bactivory by microzooplankton. These processes also vary significantly in both spatial and temporal dimensions during the development and decay of phytoplankton blooms.
Recent attempts to model decomposition processes and C and N fluxes In pelagic marine ecosystems are described. This review examines the most sensitive components and predictions of the models with particular reference to estimates of bacterial production, net growth yield and predictions of N cycling determined by 15N methodology.