Genomic characterization of invasive typhoidal and non-typhoidal Salmonella in southwestern Nigeria

Ikhimiukor, Odion O.; Oaikhena, Anderson O; Afolayan, Ayorinde O.; Fadeyi, Abayomi; Kehinde, Aderemi; Ogunleye, Veronica O.; Aboderin, AO; Oduyebo, OO; Elikwu, Charles John; Odih, Erkison Ewomazino; Komolafe, Ifeoluwa; Argimón, Silvia; Egwuenu, Abiodun; Adebiyi, Ini; Sadare, Oluwadamilola A.; Okwor, Tochi; Kekre, Mihir; Underwood, Anthony; Ihekweazu, Chikwe; Aanensen, David M.; Okeke, Iruka N.

doi:10.1371/journal.pntd.0010716

Cited by 20 publications

(23 citation statements)

References 64 publications

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“…However, overall, bla CTX-M-15 IncY plasmids were rare (n=1 to 4 genomes) in all genotype backgrounds except 4.3.1.1.P1 (total n=655), suggesting that the IncY bla CTX-M-15 plasmid has not been stably maintained in other Typhi lineages (see Table 3). IncY plasmids were also identified in a single genotype 2.3.3 organism isolated in the UK in 1989 associated with travel to Pakistan (carrying catA1, tetA(B)); and in a sublineage of IncHI1-negative 3.1.1 genomes from Nigeria carrying bla TEM-1D , dfrA14, sul2, tetA(A), as has been recently reported (Ikhimiukor et al, 2022a;International Typhoid Consortium et al, 2016). Other examples of ESBL carriage in Typhi genomes appear to represent isolated events (1 or 2 genomes per ESBL/plasmid or ESBL/genotype combination, see Table 3), except for a sublineage of 4.3.1.2.1 from India carrying bla SHV-12 in a IncX3 plasmid backbone.…”

Section: Ceftriaxone Resistant (Cefr)supporting

confidence: 72%

“…Most of these data come from the Typhoid Fever Surveillance in Africa Programme (TSAP) genomics report (Park et al, 2018) and a study of typhoid in Abuja and Kano in Nigeria (International Typhoid Consortium et al, 2016), which showed that in the period 2010-2013, 3.1.1 dominated in Nigeria and nearby Ghana and Burkina Faso, whereas 2.3.2 dominated in The Gambia and neighbouring Senegal and Guinea Bissau (Park et al, 2018). Here, we find that additional data from travel cases and recent Nigerian national surveillance (Ikhimiukor et al, 2022a) suggest that these patterns reflect long-established and persisting populations in the Western African region (see Figures S1b and S3): 3.1.1 was detected from Benin (2002Benin ( -2009n=4/4), Burkina Faso (2006-2013n=11/17), Cote d'Ivoire (2006n=4/4) -2014n=25/28), Ghana (2010n=25/28), Ghana ( -2018n=9/109), Guinea Bissau (2012-2013n=2/3), Mali (1999n=2/3), Mali ( -2018n=3/5), Niger (1990n=3/5), Niger ( -1999n=2/4), Nigeria (1984n=2/4), Nigeria ( -2002n=4/192) The Americas Strikingly, Central American isolates were dominated by 2.3.2 (55%, [95% CI, 45.2-64.8%] n= 55/100), which was also common in Western Africa (13.9%, [95% CI, 9.7-18.0%]; n=37/266) (Figure 1a). Little has been reported about Typhi populations from this region previously, and the genomes collated here were almost exclusively novel ones contributed via the US CDC and isolated between 2016 and 2019.…”

Section: Africamentioning

confidence: 52%

“…Overall, there were 36 countries with ≥20 genomes (total n=12,409 genomes, 95.7%) and 21 countries with ≥100 genomes (n=11,761 genomes, 90.7%) (see Table S4). Countries with the most genomes available (n≥100 each) were mainly those where local surveillance studies have utilised WGS for isolate characterisation (India (Britto et al, 2020;da Silva et al, 2022), Bangladesh (Rahman et al, 2020;da Silva et al, 2022), Nepal (Britto et al, 2018;Thanh et al, 2016a), Pakistan (da Silva et al, 2022, Cambodia (Kuijpers et al, 2017;Thanh et al, 2016b), Laos (Wong et al, 2015), Vietnam (Holt et al, 2011a), Kenya (Kariuki et al, 2021(Kariuki et al, , 2010, Malawi (Feasey et al, 2015), Zimbabwe (Mashe et al, 2020;Thilliez et al, 2022), Ghana (Park et al, 2018), Nigeria (Ikhimiukor et al, 2022a;International Typhoid Consortium et al, 2016), Chile (Maes et al, 2022), Samoa (Sikorski et al, 2022)); plus South Africa, the Philippines (Lagrada et al, 2022), United Kingdom and United States, where Typhi isolates are sequenced as part of national surveillance programmes.…”

Section: Overview Of Available Datamentioning

confidence: 99%

“…The genotyping framework, together with functionality for identifying AMR determinants and plasmid replicons, and generating clustering-based trees, is available within the online genomic epidemiology platform Typhi Pathogenwatch (Argimon et al, 2021). This system is designed to facilitate genomic surveillance and outbreak analysis for Typhi, including contextualisation with global public data, by public health and research laboratories (Argimón et al, 2021;Ikhimiukor et al, 2022a;Lagrada et al, 2022) without requiring major investment in computational infrastructure or specialist bioinformatics training.…”

Section: Introductionmentioning

confidence: 99%

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Global diversity and antimicrobial resistance of typhoid fever pathogens: insights from 13,000SalmonellaTyphi genomes

Carey

Dyson

Ingle

et al. 2022

Preprint

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The Global Typhoid Genomics Consortium was established to bring together the typhoid research community to aggregate and analyseSalmonella entericaserovar Typhi (Typhi) genomic data to inform public health action. This analysis, which marks twenty-one years since the publication of the first Typhi genome, represents the largest Typhi genome sequence collection to date (n=13,000), and provides a detailed overview of global genotype and antimicrobial resistance (AMR) distribution and temporal trends, generated using open analysis platforms (GenoTyphi and Pathogenwatch). Compared with previous global snapshots, the data highlight that genotype 4.3.1 (H58) has not spread beyond Asia and Eastern/Southern Africa; in other regions, distinct genotypes dominate and have independently evolved AMR. Data gaps remain in many parts of the world, and we show potential of travel-associated data to provide informal ″sentinel″ surveillance for such locations. The data indicate ciprofloxacin non-susceptibility (> 1 resistance determinant) is widespread across geographies and genotypes, with high-level resistance (≥3 determinants) reaching 20% prevalence in South Asia. Extensively drug-resistant (XDR) typhoid has become dominant in Pakistan (70% in 2020), but has not yet become established elsewhere. Ceftriaxone resistance has emerged in eight non-XDR genotypes, including a ciprofloxacin-resistant lineage (4.3.1.2.1) in India. Azithromycin resistance mutations were detected at low prevalence in South Asia, including in two common ciprofloxacin-resistant genotypes. The Consortium's aim is to encourage continued data sharing and collaboration to monitor the emergence and global spread of AMR Typhi, and to inform decision-making around the introduction of typhoid conjugate vaccines (TCVs) and other prevention and control strategies.

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Section: Ceftriaxone Resistant (Cefr)supporting

confidence: 72%

Section: Africamentioning

confidence: 52%

Section: Overview Of Available Datamentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Global diversity and antimicrobial resistance of typhoid fever pathogens: insights from 13,000SalmonellaTyphi genomes

Carey

Dyson

Ingle

et al. 2022

Preprint

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“…Moreover, our WGS surveillance found a sublineage of 3.1.1 strains that carry an IncY multi-drug resistance plasmid (Fig. 3) [45]. In addition to providing valuable information about Typhi epidemiology in Nigeria, genomic surveillance has made it possible to correctly subtype invasive non-typhoidal Salmonella, all of which are submitted by sentinels to the reference laboratory with no serovar information.…”

Section: Defining Transmission Patterns For Community-acquired Bacter...mentioning

confidence: 93%

Establishing a national reference laboratory for antimicrobial resistance using a whole-genome sequencing framework: Nigeria’s experience

et al. 2022

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Whole-genome sequencing (WGS) is finding important applications in the surveillance of antimicrobial resistance (AMR), providing the most granular data and broadening the scope of niches and locations that can be surveilled. A common but often overlooked application of WGS is to replace or augment reference laboratory services for AMR surveillance. WGS has supplanted traditional strain subtyping in many comprehensive reference laboratories and is now the gold standard for rapidly ruling isolates into or out of suspected outbreak clusters. These and other properties give WGS the potential to serve in AMR reference functioning where a reference laboratory did not hitherto exist. In this perspective, we describe how we have employed a WGS approach, and an academic–public health system collaboration, to provide AMR reference laboratory services in Nigeria, as a model for leapfrogging to national AMR surveillance.

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Confronting Multidrug Resistance with Antibiotics Incorporated with Silver Nanoparticles; A Case Study on MDR Salmonella

Orole,

Lamini

2024

Chemistry Africa

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Genomic characterization of invasive typhoidal and non-typhoidal Salmonella in southwestern Nigeria

Cited by 20 publications

References 64 publications

Global diversity and antimicrobial resistance of typhoid fever pathogens: insights from 13,000SalmonellaTyphi genomes

Global diversity and antimicrobial resistance of typhoid fever pathogens: insights from 13,000SalmonellaTyphi genomes

Establishing a national reference laboratory for antimicrobial resistance using a whole-genome sequencing framework: Nigeria’s experience

Confronting Multidrug Resistance with Antibiotics Incorporated with Silver Nanoparticles; A Case Study on MDR Salmonella

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