Nutrient regulation of bacterial production and ectoenzyme activities in the subtropical North Pacific Ocean

Interactions between Bacteria and dissolved organic matter (DOM) in the open ocean are poorly understood. While it is likely that particular compounds may disproportionately regulate heterotrophic activity, very little is known about the underlying processes. Through 10 cruises between December 1996 and April 1998 we investigated how heterotrophic (non-pigmented) Bacteria cell production, per cell alpha- and beta -glucosidase and leucine aminopeptidase (LAPase) activities, and (14)C-glucose uptake in 0.8 mum filtered seawater (fsw) cultures at Station ALOHA (22 degrees 45 'N, 158 degreesW) responded to organic and inorganic nutrient additions (glucose, single amino acids, NH(4)(+), NO(3)(-)). Bacterial cell production did not change significantly in fsw with glucose (1 muM) or single exogenous N sources (1 muM N) compared to that in fsw alone. Furthermore, there was no significant difference in heterotrophic bacterial cell production in fsw amended with organic or inorganic N, nor between that in fsw with organic N and glucose, or inorganic N and glucose. Cell production did increase significantly, however, in fsw with exogenous glucose (0.38 muM) plus 1 muM inorganic N (NH(4)(+)) relative to that in fsw only, in fsw with glucose, and in fsw with 1 muM N as amino acids (His, Tyr, Leu). There was no significant difference between heterotrophic bacterial cell production in fsw with glucose, glucose plus amino acids, and that in fsw alone. Cell-specific LAPase activity increased significantly relative to that in unamended fsw when exogenous glucose plus NH(4)(+) or NO(3)(-) were provided, but amino acids, glucose, NH(4)(+) or NO(3)(-) alone had little or no effect. alpha -Glucosidase activity tended to increase with exogenous His and Tyr additions. Our results suggest that heterotrophic activity at Station ALOHA can be regulated by the abundance of particular compounds, regardless of their total concentrations. It appears that auxotrophy and de novo synthesis of cell protein from glucose may coexist among Bacteria at Station ALOHA, and that regulation of ectoenzyme expression is independent of product availability. (C) 2001 Elsevier Science Ltd. All rights reserved.