Therefore, it cannot be excluded that the fluorescent clusters stem from an aggregation of HupS–GFP, or proteins targeted for localized degradation in bacterial-type proteasomes. However, to resolve the subcellular location of the functional uptake hydrogenase in N. punctiforme and to investigate the possible presence of proteasomes in cyanobacteria, more research is required. This work was kindly supported selleck products by the Swedish Energy Agency, the Knut and Alice Wallenberg Foundation, the Nordic Energy Research Program (project BioH2), the EU/Energy FP7 project SOLAR-H2 (contract
# 212508), and the Magnus Bergvall Foundation. The plasmid pSB1A2 carrying part BBa_I13504 was
kindly distributed by the Registry of Standard Biological Parts (MIT). Appendix S1. Construction of the gfp-modified hup-operon. Fig. S1. SDS-PAGE/Western blot using GFP antibodies. Fig. S2. Transmission electron micrographs of isolated heterocysts from Nostoc punctiforme: see more (a) strain SHG, harbouring the vector pSHG expressing the HupS–GFP fusion protein and (b) WT. Please note: Wiley-Blackwell is not responsible for the content or functionality of any supporting materials supplied by the authors. Any queries (other than missing material) should be selleck screening library directed to the corresponding author for the article. “
“Magnetotactic bacteria (MTB), which
can mineralize nanosized magnetite or greigite crystals within cells, play important roles in biogeochemical processes, for example iron and sulfur cycling, and depositional remanent magnetization acquisitions. Despite decades of research, the knowledge of MTB distribution and ecology is still limited. In the present study, we investigated the temporal variation of MTB communities in freshwater sediment microcosms based on 16S rRNA genes and unifrac analyses. Two microcosms (MY8 and MY11) collected from two separate sites in Lake Miyun (Beijing, China) were analyzed. The majority of retrieved sequences belonged to alphaproteobacterial magnetotactic cocci in both microcosms (representing 64.29% of clones from MY8 and 100% of clones from MY11), whereas so-called ‘Magnetobacterium bavaricum’-like MTB affiliated within Nitrospira phylum were exclusively found in microcosm MY8. Over a 3-month period, the temporal variation of MTB communities was evident in both microcosms. In addition, the phylogenetic discrepancy of MTB communities between two microcosms is more prominent than that of the same microcosm at different times, implying adaptation of MTB phylogenetic lineages to specific microenvironments.