Literature DB >> 29567732

Genome Sequences of 15 Klebsiella sp. Isolates from Sugarcane Fields in Colombia's Cauca Valley.

Luz K Medina-Cordoba^1,2, Aroon T Chande^1,2,3, Lavanya Rishishwar^2,3, Leonard W Mayer^2,3, Leonardo Mariño-Ramírez^2,4, Lina C Valderrama-Aguirre^5,6, Augusto Valderrama-Aguirre^2,7, Joel E Kostka^1,2, I King Jordan^8,2,3.

Abstract

Members of the Klebsiella genus promote plant growth. We report here draft whole-genome sequences for 15 Klebsiella sp. isolates from sugarcane fields in the Cauca Valley of Colombia. The genomes of these isolates were characterized as part of a broader effort to evaluate their utility as endemic plant growth-promoting biofertilizers.

Entities: Chemical Disease Species

Year: 2018 PMID： 29567732 PMCID： PMC5864951 DOI： 10.1128/genomeA.00104-18

Source DB: PubMed Journal: Genome Announc

GENOME ANNOUNCEMENT

The genus Klebsiella belongs to the family Enterobacteriaceae and includes nonmotile rod-shaped Gram-negative bacteria with polysaccharide capsules. Members of the Klebsiella genus are exceptionally widespread in nature; Klebsiella spp. inhabit both water and soil environments, and they are associated with numerous plant and animal species (1). Klebsiella spp. are known to promote plant growth by colonizing plant tissues (roots) and providing essential nutrients to their plant hosts (2). For example, Klebsiella spp. encode the biochemical capacity to fix nitrogen, i.e., to convert molecular nitrogen to organic nitrogen in the form of ammonium (3). Plant growth promotion can also be facilitated via a number of other mechanisms, including phosphate solubilization, the production of phytohormones, an increase in nutritional uptake, and control of environmental stress (4, 5). The aim of this project was to use the analysis of Klebsiella sp. isolate genome sequences to evaluate their potential as biofertilizers. Given the fact that some Klebsiella spp. are known (opportunistic) pathogens, genome sequence analysis can also be used to mitigate the potential risk they pose to human populations if included as part of a bioinoculum. The 15 Klebsiella sp. isolates characterized here were isolated from INCAUCA sugarcane fields, either from plants’ root zones or directly from plant tissue. All isolates were grown overnight on LB medium (Difco) at 37°C. Genomic DNA was isolated using the E.Z.N.A. bacterial DNA kit (Omega Bio-tek), and paired-end fragment libraries were constructed using the Nextera XT DNA library preparation kit (Illumina), with a fragment length of 1,000 bp. Libraries were sequenced on an Illumina MiSeq platform using V3 chemistry, yielding approximately 400,000 paired-end 300-bp sequence reads per sample. Sequence read quality control was performed using the program FastQC version 0.11.5 (6). Adapter/primer sequences and low-quality bases and reads (Q < 20) were removed using Trimmomatic version 0.35 (7). The 15 Klebsiella sp. isolate genomes were assembled using the de novo assembler SPAdes version 3.6 (8). The summary statistics for the resulting assemblies indicate the completeness of the work. The genome coverages range from 50× to 88×, with an average of 64× coverage, which is more than sufficient to produce reliable assemblies. Accordingly, the genome assembly metrics are robust; N50 values range from 65,329 bp to 614,324 bp, with an average N50 of 290,406 bp, and L50 values range from 3 to 29, with an average value of 8.9. Finally, the genome size and GC content values inferred from the assemblies are consistent with what is expected for Klebsiella species. Assembled genome sizes range from 5.46 Mb to 6.09 Mb, with an average size of 5.64 Mb, and the GC content values range from 56.7% to 57.5%, with an average GC content of 57.1%. Isolate genome sequences were annotated using the Rapid Annotations using Subsystems Technology (RAST) Web server (9–11). Functional predictions will be used to prioritize strains that are simultaneously enriched for nitrogen fixing and other plant growth-promoting genes while containing minimal antibiotic resistance genes and virulence factors.

Accession number(s).

This whole-genome shotgun project has been deposited at DDBJ/ENA/GenBank under the accession numbers shown in Table 1.

Table 1

Strains obtained from Saccharum hybrid cultivars in 2014 from Colombia and sequenced in this study

Strain	GenBank accession no.
A-Nf5	PIOG00000000
B-Nf7	PIOH00000000
C-Nf10	PIOJ00000000
C1-16S-Nf17	PIOI00000000
D-Nf1	PIOK00000000
E-Nf3	PIOL00000000
F-Nf9	PIOM00000000
G-Nf4	PION00000000
G2-16S-Nf13	PIOO00000000
H-Nf2	PIBL00000000
I-Nf8	PIBM00000000
J-Nf11	PJDI00000000
K-Nf6	PIBN00000000
T11	PJDJ00000000
X1-16S-Nf21	PJDK00000000

Strains obtained from Saccharum hybrid cultivars in 2014 from Colombia and sequenced in this study

8 in total

1. SPAdes: a new genome assembly algorithm and its applications to single-cell sequencing.

Authors: Anton Bankevich; Sergey Nurk; Dmitry Antipov; Alexey A Gurevich; Mikhail Dvorkin; Alexander S Kulikov; Valery M Lesin; Sergey I Nikolenko; Son Pham; Andrey D Prjibelski; Alexey V Pyshkin; Alexander V Sirotkin; Nikolay Vyahhi; Glenn Tesler; Max A Alekseyev; Pavel A Pevzner
Journal: J Comput Biol Date: 2012-04-16 Impact factor: 1.479

Review 2. Habitat association of Klebsiella species.

Authors: S T Bagley
Journal: Infect Control Date: 1985-02

3. Genome Sequence of the Banana Plant Growth-Promoting Rhizobacterium Pseudomonas fluorescens PS006.

Authors: Rocío M Gamez; Fernando Rodríguez; Sandra Ramírez; Yolanda Gómez; Richa Agarwala; David Landsman; Leonardo Mariño-Ramírez
Journal: Genome Announc Date: 2016-05-05

4. The RAST Server: rapid annotations using subsystems technology.

Authors: Ramy K Aziz; Daniela Bartels; Aaron A Best; Matthew DeJongh; Terrence Disz; Robert A Edwards; Kevin Formsma; Svetlana Gerdes; Elizabeth M Glass; Michael Kubal; Folker Meyer; Gary J Olsen; Robert Olson; Andrei L Osterman; Ross A Overbeek; Leslie K McNeil; Daniel Paarmann; Tobias Paczian; Bruce Parrello; Gordon D Pusch; Claudia Reich; Rick Stevens; Olga Vassieva; Veronika Vonstein; Andreas Wilke; Olga Zagnitko
Journal: BMC Genomics Date: 2008-02-08 Impact factor: 3.969

5. The SEED and the Rapid Annotation of microbial genomes using Subsystems Technology (RAST).

Authors: Ross Overbeek; Robert Olson; Gordon D Pusch; Gary J Olsen; James J Davis; Terry Disz; Robert A Edwards; Svetlana Gerdes; Bruce Parrello; Maulik Shukla; Veronika Vonstein; Alice R Wattam; Fangfang Xia; Rick Stevens
Journal: Nucleic Acids Res Date: 2013-11-29 Impact factor: 16.971

6. PATRIC, the bacterial bioinformatics database and analysis resource.

Authors: Alice R Wattam; David Abraham; Oral Dalay; Terry L Disz; Timothy Driscoll; Joseph L Gabbard; Joseph J Gillespie; Roger Gough; Deborah Hix; Ronald Kenyon; Dustin Machi; Chunhong Mao; Eric K Nordberg; Robert Olson; Ross Overbeek; Gordon D Pusch; Maulik Shukla; Julie Schulman; Rick L Stevens; Daniel E Sullivan; Veronika Vonstein; Andrew Warren; Rebecca Will; Meredith J C Wilson; Hyun Seung Yoo; Chengdong Zhang; Yan Zhang; Bruno W Sobral
Journal: Nucleic Acids Res Date: 2013-11-12 Impact factor: 16.971

7. Trimmomatic: a flexible trimmer for Illumina sequence data.

Authors: Anthony M Bolger; Marc Lohse; Bjoern Usadel
Journal: Bioinformatics Date: 2014-04-01 Impact factor: 6.937

8. Genome Sequence of the Banana Plant Growth-Promoting Rhizobacterium Bacillus amyloliquefaciens BS006.

Authors: Rocío M Gamez; Fernando Rodríguez; Johan F Bernal; Richa Agarwala; David Landsman; Leonardo Mariño-Ramírez
Journal: Genome Announc Date: 2015-11-25

8 in total

1 in total

1. Genomic characterization and computational phenotyping of nitrogen-fixing bacteria isolated from Colombian sugarcane fields.

Authors: Luz K Medina-Cordoba; Aroon T Chande; Lavanya Rishishwar; Leonard W Mayer; Lina C Valderrama-Aguirre; Augusto Valderrama-Aguirre; John Christian Gaby; Joel E Kostka; I King Jordan
Journal: Sci Rep Date: 2021-04-28 Impact factor: 4.379

1 in total