The complete genome of the ammonia-oxidizing bacterium Nitrosospira multiformis (ATCC 25196 T ) consists of a circular chromosome and three small plasmids totaling 3,234,309 bp and encoding 2,827 putative proteins. Of the 2,827 putative proteins, 2,026 proteins have predicted functions and 801 are without conserved functional domains, yet 747 of these have similarity to other predicted proteins in databases. Gene homologs from Nitrosomonas europaea and Nitrosomonas eutropha were the best match for 42% of the predicted genes in N. multiformis. The N. multiformis genome contains three nearly identical copies of amo and hao gene clusters as large repeats. The features of N. multiformis that distinguish it from N. europaea include the presence of gene clusters encoding urease and hydrogenase, a ribulose-bisphosphate carboxylase/oxygenase-encoding operon of distinctive structure and phylogeny, and a relatively small complement of genes related to Fe acquisition. Systems for synthesis of a pyoverdine-like siderophore and for acyl-homoserine lactone were unique to N. multiformis among the sequenced genomes of ammonia-oxidizing bacteria. Gene clusters encoding proteins associated with outer membrane and cell envelope functions, including transporters, porins, exopolysaccharide synthesis, capsule formation, and protein sorting/export, were abundant. Numerous sensory transduction and response regulator gene systems directed toward sensing of the extracellular environment are described. Gene clusters for glycogen, polyphosphate, and cyanophycin storage and utilization were identified, providing mechanisms for meeting energy requirements under substrate-limited conditions. The genome of N. multiformis encodes the core pathways for chemolithoautotrophy along with adaptations for surface growth and survival in soil environments.Nitrification is a key process in the nitrogen cycle of terrestrial, wastewater, and marine systems. The first step in the aerobic process is the oxidation of ammonia, mediated by ammonia-oxidizing bacteria (AOB) or ammonia-oxidizing archaea. Because we are particularly interested in the genetic complement adaptive for ammonia-based chemolithotrophy in the soil environment, we completed the genome sequence of the soil AOB Nitrosospira multiformis (ATCC 25196 T ). Obtaining the N. multiformis genome sequence offers a unique opportunity for comparison to the available genomes of other betaproteobacterial AOB (beta-AOB), Nitrosomonas europaea (16), and Nitrosomonas eutropha (63). The AOB isolated or detected by noncultural methods in aerobic surface soils all have been members of the Betaproteobacteria (order Nitrosomonadales, family Nitrosomonadaceae). Recent evidence suggests that Crenarchaeota may also contribute to ammonia oxidation in soils (43).The sequenced AOB, Nitrosospira multiformis ATCC 25196 T , was isolated from soil near Paramaribo, Surinam, by enrichment culturing, followed by serial dilution to extinction (71). Originally, this isolate was the type strain for Nitrosolobus multiformis, wit...
