, 2008) despite the leucine requirement for all proteins. The data presented suggest that the LNA bacterioplankton, but not Prochlorococcus, benefited metabolically from dust leachate additions. This differential result was hidden when observing the community response as a whole, which suggested no stimulation or suppression of bacterial metabolism. The varying degree of stimulation of LNA bacterioplankton by leachate within the four incubations was presumably due to the variation in the ambient methionine uptake rates, as indicated by 35S-Met
bioassays that were conducted in parallel (4.2–17.7 pmol L−1 h−1, P. G. Hill unpublished data). In agreement with previous DAPT observations, the SAR11 clade of Alphaproteobacteria dominated the LNA bacterioplankton, and yet was not identified within the
HNA bacterioplankton. This coverage of 72±15% LNA selleck kinase inhibitor prokaryotes is similar to that achieved in one previous study (Schattenhofer, 2009), but higher than others (Mary et al., 2006; Zubkov et al., 2007), probably because the cells were more metabolically active, allowing more hybridizations to occur. The remaining fraction of LNA bacterioplankton cells could be identified as Bacteria, while they could not be affiliated to other groups, including Gammaproteobacteria and Prochlorococcus. The difficulty in identifying the LNA group in open ocean samples (Mary et al., 2006; Schattenhofer, 2009) suggests that they could belong to the SAR11 clade, but differ in their cellular ribosomal content. Dust may introduce organic carbon (Duarte et al., 2006; Pulido-Villena et al., 2008b), which could benefit heterotrophic SAR11 cells more than phototrophic Prochlorococcus cells. It may also alleviate the limitation of microbial growth by inorganic N or P (Rivkin & Anderson, 1997; Caron et al., 2000); Prochlorococcus cells can assimilate these inorganic nutrients (Casey et al., 2007). Indeed, a strain of Prochlorococcus found in the Red Sea, which is relatively insensitive to metal toxicity compared with strains from the Atlantic, has been
shown to increase in abundance following inorganic nutrient and Saharan dust additions (Paytan et al., 2009). However, the majority Carnitine dehydrogenase of Prochlorococcus cells in samples from the present study belonged to the HLII (Table 1), which are well adapted to oligotrophic environments (West et al., 2001; Johnson et al., 2006; Zubkov et al., 2007; Zwirglmaier et al., 2007). No more than 2% of HNA prokaryotes were identified as HLI, which has a relatively high nutrient requirement compared with HLII (Johnson et al., 2006). Given that the study region was dominated by HLII, it seems unlikely that the Prochlorococcus population would have benefited from dust-derived nutrients. Ecotypes of both Prochlorococcus and SAR11 have maximized their ability to take up nutrients efficiently at very low nutrient concentrations.