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. 2017 Nov 7;10:578. doi: 10.1186/s13104-017-2878-0

Phage typing or CRISPR typing for epidemiological surveillance of Salmonella Typhimurium?

Manal Mohammed 1,
PMCID: PMC5678594  PMID: 29115982

Abstract

Objective

Salmonella Typhimurium is the most dominant Salmonella serovar around the world. It is associated with foodborne gastroenteritis outbreaks but has recently been associated with invasive illness and deaths. Characterization of S. Typhimurium is therefore very crucial for epidemiological surveillance. Phage typing has been used for decades for subtyping of S. Typhimurium to determine the epidemiological relation among isolates. Recent studies however have suggested that high throughput clustered regular interspaced short palindromic repeats (CRISPR) typing has the potential to replace phage typing. This study aimed to determine the efficacy of high-throughput CRISPR typing over conventional phage typing in epidemiological surveillance and outbreak investigation of S. Typhimurium.

Results

In silico analysis of whole genome sequences (WGS) of well-documented phage types of S. Typhimurium reveals the presence of different CRISPR type among strains belong to the same phage type. Furthermore, different phage types of S. Typhimurium share identical CRISPR type. Interestingly, identical spacers were detected among outbreak and non-outbreak associated DT8 strains of S. Typhimurium. Therefore, CRISPR typing is not useful for the epidemiological surveillance and outbreak investigation of S. Typhimurium and phage typing, until it is replaced by WGS, is still the gold standard method for epidemiological surveillance of S. Typhimurium.

Electronic supplementary material

The online version of this article (10.1186/s13104-017-2878-0) contains supplementary material, which is available to authorized users.

Keywords: Salmonella Typhimurium, CRISPR typing, Phage typing, Surveillance, Outbreaks

Introduction

Salmonellosis is one of the most common causes of foodborne disease worldwide. Nontyphoidal salmonellosis (NTS) is a zoonotic disease transmitted from animals to humans through consumption of contaminated food. Worldwide, Salmonella enterica serovar Typhimurium (S. Typhimurium) accounts for most human infection of NTS and has been associated with foodborne outbreaks in developing and developed countries resulting in high morbidity and mortality [1]. Furthermore, the recent emergence of the multidrug-resistant (MDR) S. Typhimurium variant of a distinct Sequence Type ST313 in sub-Saharan Africa represents a major public health concern as it is associated with invasive illness and deaths [2]. An efficient laboratory system for epidemiological surveillance and outbreak investigation of Salmonella Typhimurium is therefore very crucial.

Phage typing system is a phenotypical method that has been used for decades for subtyping of S. Typhimurium to determine the epidemiological relation among isolates [3]. Phage typing is a rapid and low cost approach for the epidemiological surveillance and outbreak investigation of S. Typhimurium. The system distinguishes more than 300 definitive phage types (DT) of S. Typhimurium based on their patterns of lysis to a unique collection of Salmonella phages but it has shown some limitations including the maintenance of typing phages by the reference laboratory and the updating of the system furthermore it depends entirely on the experience of the individual laboratory for interpretation of the results [4].

Recent studies have suggested that high throughput clustered regular interspaced short palindromic repeats (CRISPRs) typing and the microbead-based CRISPOL assay have the potential to replace traditional bacterial typing and subtyping systems including phage typing [5, 6]. CRISPRs consist of direct repeats (DRs) separated by variable spacer sequences that are derived from foreign phages or plasmids [7] while CRISPOL is a bead-based liquid hybridization assay for CRISPR polymorphism [5].

A recent study reported identical CRISPRs between two different phage types of S. Typhimurium; DT8 and DT30 [8] which reveals the limitations of CRISPR typing for epidemiological surveillance of S. Typhimurium.

This study aimed to analyze the CRISPR/CRISPOL type of well-documented phage types of S. Typhimurium in order to determine the efficacy of high-throughput CRISPR and CRISPOL typing over conventional phage typing in epidemiological surveillance of S. Typhimurium.

Main text

Methods

Whole genome sequence of different phage types of S. Typhimurium

The whole genome sequence of well-documented phage types of S. Typhimurium (Tables 1, 2) were obtained from Enterobase (https://enterobase.warwick.ac.uk/). Furthermore, a set of different phage types of S. Typhimurium that are used as control in Anderson phage typing scheme (Tables 1, 2) were selected for whole genome sequencing (WGS). Genomic DNA was extracted using QIAamp DNA Mini Kit (Qiagen) according to manufacturer’s instructions and submitted for WGS using an Illumina MiSeq on 250 bp paired-end (PE) libraries. The quality of PE data was evaluated using FastQC toolkit (http://www.bioinformatics.babraham.ac.uk/projects/fastqc/). Adapter sequences were removed using ea-utils package (https://expressionanalysis.github.io/ea-utils/). PE reads for each isolate were de novo assembled using velvet [9]. The best assembly with the highest N50 value was obtained. Raw sequence data of control phage types of S. Typhimurium have been submitted to the European Nucleotide Archive (ENA) under study Accession No.: PRJEB18673 (http://www.ebi.ac.uk/ena/data/view/PRJEB18673) and also available via Enterobase (https://enterobase.warwick.ac.uk/).

Table 1.

Salmonella Typhimurium strains belonging to the same phage type show different CRISPR/CRISPOL type

Phage type Isolate ID (source) Lab Accession Number CRISPR type CRISPOL type References
DT1 DT1 (Clinical isolate) Wellcome Trust Sanger Institute aTraces-0ajzxba (ERS007598) 8579 430 [2]
TM 68-619 (Clinical isolate) Institut Pasteur Traces-0MviFiU 2536 54 Enterobase
TM 65-111 (Clinical isolate) Institut Pasteur Traces-0BvXZSr 7387 90 Enterobase
DT10 MS34 (Control DT10) NSSLRL bTraces-0eeFHtx (PRJEB18673) 9509 1629 This study
S81-784 (Clinical isolate) Institut Pasteur Traces-0bXCHix 9913 1688 Enterobase
DT15a MS41 (Control DT15a) NSSLRL bTraces-0FVsVub (PRJEB18673) 9517 1634 This study
S81-798 (Clinical isolate) Institut Pasteur Traces-0QWCSHz 9916 1756 Enterobase
DT41 M11-2004 (Control DT41) NSSLRL bTraces-0hioJez (PRJEB18673) 9513 1630 This study
CQ 41 (Clinical isolate) Institut Pasteur Traces-0BkvapO 7434 223 Enterobase
S02-0321 (Clinical isolate) Institut Pasteur Traces-0JWTeTs 9929 1766 Enterobase
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aAccession Numbers in Enterobase of clinical isolates of S. Typhimurium used in this study. The Accession Number in ENA for each isolate is also provided

bAccession Numbers in Enterobase of control phage types of S. Typhimurium sequenced in this study. The Accession Number in ENA is also provided

Table 2.

Salmonella Typhimurium strains belonging to different phage types show identical CRISPR/CRISPOL type

Phage type Isolate ID (source) Lab Accession Number CRISPR type CRISPOL type Reference
CRISPR/CRISPOL type among phage types DT8 and DT30 of S. Typhimurium
DT8 M18-2003 (Control DT8) NSSLRL aTraces-0jdDfGp (PRJEB18673) 1069 6 This study
DT8 DT8 (Clinical isolate) Wellcome Trust Sanger Institute bTraces-0CerOby (ERS007592) 1069 6 [2]
DT8 S81-848 (Veterinary isolate) Institut Pasteur Traces-0PArkjM 1069 6 Enterobase
DT8 MS150057 (Clinical isolate) NSSLRL Traces-0xVpmwI 2260 708 Enterobase
DT30 MS57 (Control DT30) NSSLRL aTraces-0aYyWix (ERS640854) 812 250 [8]
DT8 M12-2001 (Control DT8) NSSLRL aTraces-0Jyulvx (PRJEB18673) 812 250 This study
DT8 M15-2006 (Control DT8) NSSLRL aTraces-0WxCKWi (PRJEB18673) 812 250 This study
DT8 MS32 (Control DT8) NSSLRL aTraces-0dPdGho (PRJEB18673) 812 250 This study
CRISPR/CRISPOL type among phage types DT104, DT104b and U302 of S. Typhimurium
DT104b MS130531 (Control DT104b) NSSLRL aTraces-0ptnSId (PRJEB18673) 12 21 This study
U302 M18-2006 (Control U302) NSSLRL aTraces-0rRUdtU (PRJEB18673) 12 21 This study
DT104 TM75-339 (No data) Institut Pasteur Traces-0dpLsNp 12 21 Enterobase
DT104 MS150098 (Clinical isolate) NSSLRL Traces-0VNfjhC 12 21 Enterobase
DT104 MS150095 (Clinical isolate) NSSLRL Traces-0ohRXMQ 12 21 Enterobase
DT104b MS150159 (Clinical isolate) NSSLRL Traces-0mdEaBO 12 21 Enterobase
DT104b MS150253 (Clinical isolate) NSSLRL Traces-0VfHkWp 7556 315 Enterobase
DT104 MS150005 (Clinical isolate) NSSLRL Traces-0ehJIGG 5000 168 Enterobase
CRISPR/CRISPOL type among phage types DT99, DT56, U319 and DT40 of S. Typhimurium
DT99 DT99 (Clinical isolate) Wellcome Trust Sanger Institute bTraces-0fQeupq (ERS007596) 7433 14 [2]
DT56 DT56 (Clinical isolate) Wellcome Trust Sanger Institute bTraces-0WirVGQ (ERS007588) 7433 14 [2]
U319 U319 (Clinical isolate) Wellcome Trust Sanger Institute bTraces-0nXusuL (ERS007613) 7433 14 [2]
DT40 S05-2864 (Clinical isolate) Institut Pasteur Traces-0PxGcXB 7433 14 Enterobase
DT40 M20-2006 (Control isolate) NSSLRL aTraces-0rGCwUc (PRJEB18673) 9520 1637 This study
DT40 M19-2003 (Control isolate) NSSLRL aTraces-0nxmoMB (PRJEB18673) 9519 1636 This study
DT40 CQ 40 Institut Pasteur Traces-0LSHwEV 745 18 Enterobase
CRISPR/CRISPOL type among phage types DT120, DT7a, DT193 and untypable strains of S. Typhimurium
DT120 S02-3776 (Clinical isolate) Institut Pasteur Traces-0yQDdlW 9921 1759 Enterobase
DT120 07_2198 (No Data) Institut Pasteur Traces-0pKTfCi 9911 1753 Enterobase
DT120 M16-2000 (Control DT120) NSSLRL aTraces-0fEcWgz (PRJEB18673) 9510 1428 Enterobase
DT7a MS120840 (Control DT7a) NSSLRL aTraces-0psYyDm (PRJEB18673) 9510 1428 Enterobase
DT120 S/20160374 (Clinical isolate) SSSCDRL Traces-0CeRVgg 322 1 Enterobase
DT120 S/20160407 (Clinical isolate) SSSCDRL Traces-0agMeAc 322 1 Enterobase
DT20a MS150110 (Clinical isolate) NSSLRL Traces-0isgxxB 322 1 Enterobase
Untypable MS150097 (Clinical isolate) NSSLRL Traces-0VSlIab 322 1 Enterobase
DT193 MS150007 (Clinical isolate) NSSLRL Traces-0vpTyIh 322 1 Enterobase
DT193 MS150252 (Clinical isolate) NSSLRL Traces-0WAKQQZ 317 2 Enterobase
CRISPR/CRISPOL type among phage types DT12, DT3 and DT193a of S. Typhimurium
DT12 DT12 (Clinical isolate) Wellcome Trust Sanger Institute bTraces-0kmZJki (ERS007564) 5268 19 [2]
DT12 S02-2651 (Clinical isolate) Institut Pasteur Traces-0FbQprS 774 46 Enterobase
DT3 S81-482 (Clinical isolate) Institut Pasteur Traces-0pUCktc 5268 19 Enterobase
DT3 S81-531 (Veterinary isolate) Institut Pasteur Traces-0pGWuNa 539 13 Enterobase
DT193a MS120454 (Clinical isolate) NSSLRL Traces-0hfCzzz 774 46 Enterobase
CRISPR/CRISPOL type among phage types DT135, DT191a and RDNC strains of S. Typhimurium
DT135 DT135 (Clinical isolate) Wellcome Trust Sanger Institute bTraces-0xEkcLV
ERS007567		 5753 396 [2]
DT135 MS150100 (Clinical isolate) NSSLRL Traces-0fqzVBN 3247 66 Enterobase
DT135 MS150112 (Clinical isolate) NSSLRL Traces-0TpmttL 91 4 Enterobase
DT135 MS150180 (Clinical isolate) NSSLRL Traces-0FksMUv 91 4 Enterobase
DT191a DT191a (Clinical isolate) Wellcome Trust Sanger Institute bTraces-0KhAoGt
ERS007574		 91 4 [2]
RDNC MS150102 (Clinical isolate) NSSLRL Traces-0bmnIRV 91 4 Enterobase
RDNC MS150230 (Clinical isolate) NSSLRL Traces-0vTHNcg 91 4 Enterobase
RDNC MS150009 (Clinical isolate) NSSLRL Traces-0Zipaoz 9404 1614 Enterobase
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aAccession Numbers in Enterobase of control phage types of S. Typhimurium sequenced in this study. The Accession Number in ENA is also provided

bAccession Numbers in Enterobase of clinical isolates of S. Typhimurium used in this study. The Accession Number in ENA is also provided

In silico CRISPR and CRISPOL analysis

PE reads of different phage types of S. Typhimurium were also assembled using Enterobase (https://enterobase.warwick.ac.uk/) where CRISPRs and CRISPOL were called directly from the raw reads rather than the assembly.

Enterobase was used to determine the CRISPR type and CRISPOL type of all phage types of S. Typhimurium. In Enterobase, each phage type of S. Typhimurium was assigned unique accession number (Tables 1, 2).

Previously, sequenced CRISPR loci of different phage types of S. Typhimurium using polymerase chain reaction (PCR) [5] were also included in this study (Table 3).

Table 3.

CRISPOL type among different phage types of S. Typhimurium

Phage type Isolate ID (source) Lab Accession number
CRISPR1 locus CRISPR2 locus		 *CRISPOL type
DT104 02-1540 (Clinical isolate) Institut Pasteur JF724217 JF724959 30
DT104 05-2975 (Clinical isolate) Institut Pasteur JF724458 JF725631 31
DT104 02-8319 (Clinical isolate) Institut Pasteur JF724357 JF725099 24
DT104 02-4467 (Clinical isolate) Institut Pasteur JF724278 JF725020 23
DT104 02-4217 (Clinical isolate) Institut Pasteur JF724270 JF725012 20
DT104 02-3830 (Clinical isolate) Institut Pasteur JF724255 JF724997 22
DT104 02-3169 (Clinical isolate) Institut Pasteur JF724237 JF724979 21
DT120 02-5783 (Clinical isolate) Institut Pasteur JF724308 JF725050 21
DT120 02-4908 (Clinical isolate) Institut Pasteur JF724290 JF725032 34
U302 02-3709 (Clinical isolate) Institut Pasteur JF724252 JF724994 21
U302 02-5064 (Clinical isolate) Institut Pasteur JF724292 JF725034 25
DT2 81-506 (Veterinary isolate) Institut Pasteur JF724622 JF725354 54
DT2 01-1639 (Veterinary isolate) Institut Pasteur JF724170 JF724912 55
RDNC 81-748 (Clinical isolate) Institut Pasteur JF724624 JF725356 33
RDNC DK19 (Clinical isolate) Institut Pasteur JF724652 JF725384 12
RDNC 07-4489 (Clinical isolate) Institut Pasteur JF724524 JF725256 53
DT1 02-0915 (Clinical isolate) Institut Pasteur JF724204 JF724946 14
DT40 05-2864 (Clinical isolate) Institut Pasteur JF724454 JF725196 14
DT1 81-481 (ND) Institut Pasteur JF724620 JF725352 11
DT74 DK24 (Clinical isolate) Institut Pasteur JF724648 JF725380 11
DT1 1000-7816-1 (Veterinary isolate) Institut Pasteur JF724578 JF725310 46
DT186 02-1015 (Clinical isolate) Institut Pasteur JF724205 JF724947 46
DT12 02-2651 (Clinical isolate) Institut Pasteur JF724232 JF724974 46
DT42 1000-7810-1 (Veterinary isolate) Institut Pasteur JF724577 JF725309 46
DT7 07-2537 (Clinical isolate) Institut Pasteur JF724521 JF725253 1
DT193 07-7741 (Clinical isolate) Institut Pasteur JF724531 JF725263 1
U311 07-8113 (Clinical isolate) Institut Pasteur JF724532 JF725264 1
DT41 07-5354 (Clinical isolate) Institut Pasteur JF724527 JF725259 1
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CRISPR type was not determined as the whole genome sequence is not available for these strains

*CRISPOL type was determined by Fabre et al. [5]

PE reads of S. Typhimurium phage type DT8 associated with a foodborne outbreak in the summer of 2013 in the States of Jersey [10] were downloaded from ENA; study Accession Number PRJNA248792 (http://www.ebi.ac.uk/ena/data/view/PRJNA248792) and assembled by Enterobase. CRISPR and CRISPOL types were determined for all outbreak strains using Enterobase (Additional file 1: Table S1).

Spacers sequence within the assembled genomes of outbreak and non-outbreak associated DT8 strains were also characterized using CRISPRFinder (http://crispr.i2bc.paris-saclay.fr/Server/) (Additional file 1: Table S1).

Results

In silico analysis of genome sequences of control and well documented phage types of S. Typhimurium revealed two CRISPR loci, CRISPR-1 and CRISPR-2, within all phage types of S. Typhimurium. Although DRs are almost identical among all phage types of S. Typhimurium spacers sequences within the CRISPR loci are not unique to the phage type as strains belong to the same phage type have different spacers and subsequently different CRISPR/CRISPOL type (Table 1) furthermore, different phage types have identical spacers and same CRISPR/CRISPOL type (Table 2).

Different CRISPR/CRISPOL type within the same phage type of S. Typhimurium

In Table 1, three strains of S. Typhimurium that belong to phage type DT1 including strains DT1, TM 68-619 and TM 65-111 have different spacers and subsequently show different CRISPR/CRISPOL type; 8579/430, 2536/54 and 7387/90 respectively. Two strains belong to phage type DT10 have different CRISPR/CRISPOL type; MS34 (9509/1629) and S81-784 (9913/1688). Two strains belong to phage type DT15a have different CRISPR/CRISPOL type; 9517/1634 in isolate MS41 and 9916/1756 in isolate S81-798. Moreover, three strains belong to DT41 have different CRISPR/CRISPOL type; 9513/1630 in isolate M11-2004, 7434/223 in isolate CQ 41 and 9929/1766 in isolate S02-0321.

Identical CRISPR/CRISPOL type within different phage types of S. Typhimurium

CRISPR/CRISPOL type among phage types DT8 and DT30

Identical spacers were detected among different phage types of S. Typhimurium. For example, three strains of DT8 including M12-2001, M15-2006 and MS32 have the same CRISPR/CRISPOL type (812/250) as a strain belongs to phage type DT30 (MS57). Moreover, different strains belong to phage type DT8 have different CRISPR/CRISPOL type; M18-2003 (1069/6) and MS150057 (2260/708) (Table 2).

Interestingly, S. Typhimurium DT8 strains associated with the foodborne outbreak in the summer of 2013 in the States of Jersey [10] showed identical CRISPR/CRISPOL type (1069/6) however, the same CRISPR/CRISPOL type were reported in other DT8 strains that do not belong to the outbreak as confirmed by WGS [10]. Identical spacers were detected among outbreak associated and non-outbreak associated DT8 strains (Additional file 1: Table S1).

CRISPR/CRISPOL type among phage types DT104, DT104b and U302

Variations in the CRISPR/CRISPOL type among strains of the same phage type such as DT104 and DT104b have been also noticed (Table 2). Although three strains of S. Typhimurium phage type DT104 including TM75-339, MS150098 and MS150095, have identical spacer sequences and CRISPR/CRISPOL type (12/21) the same CRISPR/CRISPOL type is present in different phage types including U302 (M18-2006; 12/21) and DT104b (MS130531; 12/21).

CRISPR/CRISPOL type among phage types DT40, DT56, DT99 and U319

Strains of S. Typhimurium belong to different phage types such as DT99, DT56, U319 and DT40 (S05-2864) have identical spacer sequences and identical CRISPR/CRISPOL type (7433/14). Moreover, several strains belong to phage type DT40 including S05-2864, M20-2006, M19-2003 and CQ 40 have different CRISPR/CRISPOL type; 7433/14, 9520/1637, 9519/1636 and 745/18 respectively (Table 2).

CRISPR/CRISPOL type among phage types DT7a, DT20a, DT120, DT193 and untypable strains

In Table 2, strains of S. Typhimurium belong to phage type DT120 have different spacers and subsequently different CRISPR/CRISPOL type including S02-3776 (9921/1759), 07_2198 (9911/1753), M16-2000 (9510/1428), and S/20160374 (322/1).

Interestingly, a strains of phage type DT120 (M16-2000) has identical spacers and CRISPR/CRISPOL type (9510/1428) as another strain belongs to phage type DT7a (MS120840). Moreover, some strains belong to phage types DT120 (S/20160374 and S/20160407), DT20a (MS150110), DT193 (MS150007) and untypable strain (MS150097) have identical spacers and therefore share the same CRISPR/CRISPOL type (322/1). Different strains belong to phage type DT193 have different spacers and CRISPR/CRISPOL type; MS150007 (322/1) and MS150252 (317/2).

CRISPR/CRISPOL type among phage types DT3, DT12 and DT193a

Some strains of phage types DT12 (DT12) and DT3 (S81-482) have identical spacers and identical CRISPR/CRISPOL type; 5268/19. Moreover, a strain belongs to DT12 (S02-2651) has identical CRISPR/CRISPOL type, 774/46, as a strain belongs to phage type DT193a (MS120454) (Table 2).

CRISPR/CRISPOL type among phage types DT135, DT191a and RDNC

Identical spacer sequences and CRISPR/CRISPOL type (91/4) were detected in different phage types of S. Typhimurium including DT135 (MS150112 and MS150180), DT191a (DT19a) and strains that react with phages but do not confirm to recognized pattern (RDNC) (MS150102 and MS150230). Furthermore, other strains belong to phage type DT135 show different spacers and subsequently different CRISPR/CRISPOL type; 5753/396 in DT135 and 3247/66 in MS150100 (Table 2).

CRISPOL assay confirms the no relation among phage type and CRISPRs

CRISPOL assay developed by Fabre et al. [5] when carried out on representative phage types of S. Typhimurium it reveals that there is no relation among the phage type and the CRISPOL type as strains belong to the same phage type have different CRISPOL type as seen in DT104 strains (Table 3). On the other hand, different phage types including DT7, DT193, U311, DT41 showed identical CRISPOL type as ‘1’ (Table 3).

Discussion

Salmonella Typhimurium is the most dominant Salmonella serovar around the world and has been associated with foodborne outbreaks in both developing and high-income countries [1, 11] and infection can result in bacteraemia and invasive disease [12, 13]. Epidemiological characterization of S. Typhimurium is therefore very crucial for the surveillance and outbreak investigation.

Phage typing system [3] has been a very useful phenotypical, definitive method for epidemiological characterization of S. Typhimurium and identification of the source of infection [1417]. Although it has been suggested that the high throughput CRISPR typing and subtyping have the potential to replace traditional phage typing [5] this study demonstrates that It is impossible for CRISPR typing and CRISPOl assay to replace phage typing for epidemiological characterization of S. Typhimurium as there is no correlation between the phage type and the CRISPR/CRISPOL type.

Interestingly, S. Typhimurium DT8 strains associated with the foodborne outbreak in the summer of 2013 in the States of Jersey [10] showed identical CRISPR/CRISPOL type however, the same CRISPR/CRISPOL type were reported in other DT8 strains that do not belong to the outbreak as confirmed by WGS [10]. Detection of identical spacers among outbreak associated and non-outbreak associated DT8 strains reveals the limitation of CRISPR typing and subtyping in investigation of outbreaks.

The MDR DT104 strain of S. Typhimurium has been associated with foodborne outbreaks all over the world and phage typing was very successful in epidemiological characterization of the outbreak and identification of the source [1820] however in this study strains belong to DT104 showed different spacers and subsequently different CRISPR/CRISPOL type therefore CRISPR typing and CRISPOL assay cannot be used in public health laboratories to determine the epidemiological relation among S. Typhimurium isolates.

The presence of CRISPR/CRISPOL type within the same phage type and the presence of identical spacers among different phage types of S. Typhimurium confirms the limitations of CRISPR typing and subtyping for the epidemiological surveillance and outbreak investigation of S. Typhimurium.

There is no doubt that rapid WGS will shape the future of diagnostic microbiology as it has the potential to replace the routine typing and subtyping methods including Anderson phage typing system for the surveillance of outbreaks caused by different Salmonella serovars in real-time [10, 21, 22]. However, in the meantime, traditional phage typing scheme of S. Typhimurium remains the gold standard method for subtyping of S. Typhimurium for laboratory surveillance and outbreak investigation despite its technical limitations. Furthermore, it represents an ideal model for studying the complex dynamics of phage-host interaction [8].

In conclusion, high throughput CRISPR/CRISPOL typing might be useful for the discrimination among different Salmonella serovars however it is not useful for the epidemiological surveillance and outbreak investigation of S. Typhimurium and phage typing, until it is replaced by WGS, is still the gold standard method for epidemiological surveillance of S. Typhimurium.

Limitations

More outbreaks of S. Typhimurium caused by phage types other than DT8 can be included to confirm the unsuitability of CRISPR typing in epidemiological surveillance and outbreak investigation of S. Typhimurium.

Acknowledgements

Not applicable.

Competing interests

The author no competing interests.

Availability of data and materials

Raw sequence data of control phage types of S. Typhimurium will be publically available via ENA under study Accession No.: PRJEB18673 (http://www.ebi.ac.uk/ena/data/view/PRJEB18673) and also available via Enterobase (https://enterobase.warwick.ac.uk/). All sequencing data is available on request.

Consent to publish

Not applicable.

Ethical approval and consent

Not applicable.

Funding

Not applicable.

Publisher’s Note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Abbreviations

CRISPR

clustered regular interspaced short palindromic repeats

DT

phage type

MDR

multidrug resistant

NSSLRL

National Salmonella Shigella Listeria Reference Laboratory

NTS

nontyphoidal salmonella

PE

paired end

PCR

polymerase chain reaction

RDNC

strains that react with phages but do not confirm to recognized pattern

SSSCDRL

Scottish Salmonella, Shigella and Clostridium difficile Reference Laboratory

S. Typhimurium

Salmonella Typhimurium

WGS

whole genome sequencing

Additional file

13104_2017_2878_MOESM1_ESM.docx (43.1KB, docx)

Additional file 1: Table S1. CRISPR and CRISPOL types of outbreak and non-outbreak associated DT8 strains of S. Typhimurium. Identical CRISPR and CRISPOL types were detected among outbreak and non-outbreak strains.

Footnotes

Electronic supplementary material

The online version of this article (10.1186/s13104-017-2878-0) contains supplementary material, which is available to authorized users.

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Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Data Availability Statement

Raw sequence data of control phage types of S. Typhimurium will be publically available via ENA under study Accession No.: PRJEB18673 (http://www.ebi.ac.uk/ena/data/view/PRJEB18673) and also available via Enterobase (https://enterobase.warwick.ac.uk/). All sequencing data is available on request.

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