Draft Genome Sequence of Bacillus sp. Strain NSP2.1, a Nonhalophilic Bacterium Isolated from the Salt Marsh of the Great Rann of Kutch, India

The 5.52-Mbp draft genome sequence of Bacillus sp. strain NSP2.1, a nonhalophilic bacterium isolated from the salt marsh of the Great Rann of Kutch, India, is reported here. An analysis of the genome of this organism will facilitate the understanding of its survival in the salt marsh.

Little Rann and Great Rann of Kutch, India, have been sequenced recently with the aim of understanding their mechanism(s) of osmotolerance (1)(2)(3). Bacillus sp. strain NSP2.1 (16S rRNA GenBank accession no. JF802192), a nonhalophilic and endospore-forming bacterium isolated from the salt marsh of the Great Rann of Kutch, India, grows optimally without NaCl in the growth medium (NaCl range, 0 to 4.5%), at 37°C, and a pH 7.5. The genome of Bacillus sp. NSP2.1 was sequenced with the aim of understanding its survival mechanism(s) in the salt marsh.
The whole genome of NSP2.1 was sequenced by both shotgun and mate-paired library sequencing using the Roche 454 genome sequencer (GS FLX) at Macrogen Inc., South Korea, through Sequencher Tech Pvt. Ltd., Ahmedabad, India. In shotgun sequencing, 769,707 reads of 347,675,293 bases were obtained (average read length, 451 bp). The sequencing of mate-paired libraries generated 140,804 reads of 63,691,257 bp (average read length, 452 bp) and 140,783 reads of 64,402,285 bp (average read length, 457 bp).
We used the GS de novo assembler version 2.6 (4) for assembling the reads, with a coverage of 85-fold. The genome assembly of Bacillus sp. NSP2.1 (GϩC content of 53.99%) contains 25 scaffolds and 107 contigs of 5,521,528 bp and 5,426,897 bp, respectively, with average lengths of 220,861 bp and 50,710 bp, respectively. An N 50 scaffold length of 376,716 bp (smallest, 1,808 bp; largest, 1,854,053 bp), and an N 50 contig length of 90,389 bp (smallest, 775 bp; largest, 380,501 bp) were obtained. All assembly data were deposited in the DDBJ/EMBL/GenBank nucleotide sequence database.
Using the different softwares, we predicted 5,425 coding se-quences (CDSs), with 4,655,526 bp in the CDSs. There are 126 RNA-encoding genes (124 tRNA and 2 rRNA genes), 420 subsystems, and 329 signal peptides. Among the CDSs, 3,459 are not in the subsystem (1,405 nonhypothetical, 2,054 hypothetical), whereas 1,966 CDSs (1,871 nonhypothetical, 95 hypothetical) are in the subsystem. RAST annotation also revealed the involvement of 103 genes in stress responses: 10 in osmotic stress (1 in osmoregulation, 9 in choline and betaine uptake), 36 in oxidative stress (5 in protection from reactive oxygen species, 18 in oxidative stress, 2 in glutathione:nonredox reactions, 7 in redox-dependent regulation of nucleus processes, 1 in the glutathione:redox cycle, 2 in glutaredoxins, and 1 in glutathionylspermidine and trypanothione), 5 in cold shock, 15 in heat shock, 15 in detoxification, and 22 in no subcategory. A number of genes associated with ABC transporters (map02010), including osmoprotectants (OpuBC, OpuBB, and OpuBA), glycerol-3-phosphate uptake, and that of two-component systems (map02020), such as those involved in the response to K ϩ -limitation and K ϩ -transport, and salt stressdegrading enzymes, have been mapped. Our laboratory is exploring the genome of Bacillus sp. NSP2.1 further to know the mechanisms of survival for this nonhalophilic bacterium in salty settings.
Nucleotide sequence accession numbers. This whole-genome shotgun project has been deposited at DDBJ/EMBL/GenBank under the accession no. AVBJ00000000. The version described in this paper is version AVBJ01000000.

ACKNOWLEDGMENTS
The work was carried out in the subproject "Diversity analysis of Bacillus and other pre-dominant genera in extreme environments and its utilization in agriculture" of the National Agricultural Innovation Project (NAIP) and the Application of Microorganisms in Agriculture and Allied Sectors (AMAAS) of the Indian Council of Agricultural Research (ICAR). We thank ICAR for funding through NAIP and AMAAS.
We also thank the national director and coordinators, NAIP, and the