Genomic revisitation and reclassification of the genus Providencia.

Members of Providencia, although typically opportunistic, can cause severe infections in immunocompromised hosts. Recent advances in genome sequencing provide an opportunity for more precise study of this genus. In this study, we first identified and characterized a novel species named Providencia zhijiangensis sp. nov. It has ≤88.23% average nucleotide identity (ANI) and ≤31.8% in silico DNA-DNA hybridization (dDDH) values with all known Providencia species, which fall significantly below the species-defining thresholds. Interestingly, we found that Providencia stuartii and Providencia thailandensis actually fall under the same species, evidenced by an ANI of 98.59% and a dDDH value of 90.4%. By fusing ANI with phylogeny, we have reclassified 545 genomes within this genus into 20 species, including seven unnamed taxa (provisionally titled Taxon 1-7), which can be further subdivided into 23 lineages. Pangenomic analysis identified 1,550 genus-core genes in Providencia, with coenzymes being the predominant category at 10.56%, suggesting significant intermediate metabolism activity. Resistance analysis revealed that most lineages of the genus (82.61%, 19/23) carry a high number of antibiotic-resistance genes (ARGs) and display diverse resistance profiles. Notably, the majority of ARGs are located on plasmids, underscoring the significant role of plasmids in the resistance evolution within this genus. Three species or lineages (P. stuartii, Taxon 3, and Providencia hangzhouensis L12) that possess the highest number of carbapenem-resistance genes suggest their potential influence on clinical treatment. These findings underscore the need for continued surveillance and study of this genus, particularly due to their role in harboring antibiotic-resistance genes. IMPORTANCE: The Providencia genus, known to harbor opportunistic pathogens, has been a subject of interest due to its potential to cause severe infections, particularly in vulnerable individuals. Our research offers groundbreaking insights into this genus, unveiling a novel species, Providencia zhijiangensis sp. nov., and highlighting the need for a re-evaluation of existing classifications. Our comprehensive genomic assessment offers a detailed classification of 545 genomes into distinct species and lineages, revealing the rich biodiversity and intricate species diversity within the genus. The substantial presence of antibiotic-resistance genes in the Providencia genus underscores potential challenges for public health and clinical treatments. Our study highlights the pressing need for increased surveillance and research, enriching our understanding of antibiotic resistance in this realm.

Monitoring the long-term spatiotemporal transmission dynamics and ecological surveillance of multidrug-resistant Salmonella enterica serovar Goldcoast: A multicenter genomic epidemiology study.

The emergence of multidrug-resistant Salmonella enterica serovar Goldcoast poses a significant threat to the effective treatment and control of salmonellosis within the ecological environment. Here, we conducted a genomic epidemiological study delineate the global dissemination scenarios of the multidrug-resistant S. Goldcoast originated from 11 countries for over 20 years. The population structure and evolutionary history of multidrug-resistant S. Goldcoast was investigated through phylogenomic and long-term spatiotemporal transmission dynamic analysis. ST358 and ST2529 are the predominant lineages of S. Goldcoast. Multidrug-resistant S. Goldcoast strains have mainly been identified in the ST358 lineage from human and the ST2529 lineage from livestock. ST358 S. Goldcoast was estimated to have emerged in the United Kingdom in 1969, and then spread to China, with both countries serve as centers for the global dissemination of the ST358 lineage. After its emergence and subsequent spread in Chinese clinical and environmental samples, occasional instances of this lineage have been reported in Canada, the United Kingdom, and Ireland. Clonal transmission of ST358 and ST2529 S. Goldcoast have occurred not only on an international and intercontinental scale but also among clinical, environmental and livestock samples. These data indicated that international circulation and local transmission of S. Goldcoast have occurred for over a decade. Continued surveillance of multidrug-resistant S. Goldcoast from a global "One Health" perspective is urgently needed to facilitate monitoring the spread of the antimicrobial resistant high-risk clones.

Global Phylogeography and Genomic Epidemiology of Carbapenem-Resistant blaOXA-232-Carrying Klebsiella pneumoniae Sequence Type 15 Lineage.

Prevalence of carbapenem-resistant Klebsiella pneumoniae (CRKP) has compromised antimicrobial efficacy against severe infections worldwide. To monitor global spread, we conducted a comprehensive genomic epidemiologic study comparing sequences from 21 blaOXA-232-carrying CRKP isolates from China with K. pneumoniae sequence type (ST) 15 strains from 68 countries available in GenBank. Phylogenetic and phylogeographic analyses revealed all blaOXA-232-carrying CRKP isolates belonged to ST15 lineage and exhibited multidrug resistance. Analysis grouped 330 global blaOXA-232-carrying ST15 CRKP strains into 5 clades, indicating clonal transmission with small genetic distances among multiple strains. The lineage originated in the United States, then spread to Europe, Asia, Oceania, and Africa. Most recent common ancestor was traced back to 2000; mutations averaged ≈1.7 per year per genome. Our research helps identify key forces driving global spread of blaOXA-232-carrying CRKP ST15 lineage and emphasizes the importance of ongoing surveillance of epidemic CRKP.

Global population structure and genomic surveillance framework of carbapenem-resistant Salmonella enterica.

Due to the frequent international and intercontinental transmission of multidrug-resistant bacteria, it is imperative to understand the epidemiology, phylogeography, and population structure of carbapenem-resistant Salmonella enterica (CRSE) across the globe. During the period of 2015-2022, two blaNDM-carrying S. enterica strains were recovered from 3695 Salmonella strains in four hospitals in China. The global phylogenetic framework and geographical distribution of CRSE were defined by our recently updated bacterial whole genome sequence typing and source tracking database BacWGSTdb 2.0 to measure the diversity and evolutionary relatedness in context with epidemiological metadata. Phylogeny for all carbapenemase gene-harboring plasmids in S. enterica based on the pairwise Mash differences was also constructed to evaluate the potential transmission of these plasmids in a global context. A large-scale phylogenetic analysis grouped global CRSE into nine distinct clades. The small genetic distance (< 20 SNPs) between 198 pairs of CRSE suggested the presence of clonal transmission. Global CRSE have significant geographical variations, which was associated with the clonal lineages and carbapenemase genes. Carbapenemase gene-carrying plasmids with a high degree of similarity have surfaced in various hosts and countries. The widespread of multiple-replicon plasmids that offer a great capacity to accommodate multiple antimicrobial resistance genes is continuously enhancing the potential risk of CRSE isolates to propagate globally. Both clonal spread of strains and horizontal transfer of carbapenemase gene-harboring plasmids contribute to the global dissemination of CRSE. Our findings on the worldwide spread and transmission dynamics of this emerging bacterium has increased the knowledge of its global epidemics. Continued epidemiological surveillance is necessary to prevent global outbreak of multidrug-resistant Salmonella infections.

Toward accurate diagnosis and surveillance of bacterial infections using enhanced strain-level metagenomic next-generation sequencing of infected body fluids.

Metagenomic next-generation sequencing (mNGS) enables comprehensive pathogen detection and has become increasingly popular in clinical diagnosis. The distinct pathogenic traits between strains require mNGS to achieve a strain-level resolution, but an equivocal concept of 'strain' as well as the low pathogen loads in most clinical specimens hinders such strain awareness. Here we introduce a metagenomic intra-species typing (MIST) tool (https://github.com/pandafengye/MIST), which hierarchically organizes reference genomes based on average nucleotide identity (ANI) and performs maximum likelihood estimation to infer the strain-level compositional abundance. In silico analysis using synthetic datasets showed that MIST accurately predicted the strain composition at a 99.9% average nucleotide identity (ANI) resolution with a merely 0.001× sequencing depth. When applying MIST on 359 culture-positive and 359 culture-negative real-world specimens of infected body fluids, we found the presence of multiple-strain reached considerable frequencies (30.39%-93.22%), which were otherwise underestimated by current diagnostic techniques due to their limited resolution. Several high-risk clones were identified to be prevalent across samples, including Acinetobacter baumannii sequence type (ST)208/ST195, Staphylococcus aureus ST22/ST398 and Klebsiella pneumoniae ST11/ST15, indicating potential outbreak events occurring in the clinical settings. Interestingly, contaminations caused by the engineered Escherichia coli strain K-12 and BL21 throughout the mNGS datasets were also identified by MIST instead of the statistical decontamination approach. Our study systemically characterized the infected body fluids at the strain level for the first time. Extension of mNGS testing to the strain level can greatly benefit clinical diagnosis of bacterial infections, including the identification of multi-strain infection, decontamination and infection control surveillance.

Functional Nanomaterials for the Detection and Control of Bacterial Infections.

Infections with multidrug-resistant bacteria that are difficult to treat with commonly used antibiotics have spread globally, raising serious public health concerns. Conventional bacterial detection techniques are time-consuming, which may delay treatment for critically ill patients past the optimal time. There is an urgent need for rapid and sensitive diagnosis and effective treatments for multidrug-resistant pathogenic bacterial infections. Advances in nanotechnology have made it possible to design and build nanomaterials with therapeutic and diagnostic capabilities. Functional nanomaterials that can specifically interact with bacteria offer additional options for the diagnosis and treatment of infections due to their unique physical and chemical properties. Here, we summarize the recent advances related to the preparation of nanomaterials and their applications for the detection and treatment of bacterial infection. We pay particular attention to the toxicity of therapeutic nanoparticles based on both in vitro and in vivo assays. In addition, the major challenges that require further research and future perspectives are briefly discussed.

Unravelling the genome sequence of a pandrug-resistant Klebsiella pneumoniae isolate with sequence type 11 and capsular serotype KL64 from China.

OBJECTIVES: Klebsiella pneumoniae has emerged worldwide as a major cause of severe infections owing to the rising prevalence of multidrug-resistant strains in clinical settings. This study aimed to investigate the genomic features of pandrug-resistant K. pneumoniae strain KP2 with high colistin and tigecycline resistance isolated from a patient in China. METHODS: The antimicrobial susceptibility of K. pneumoniae KP2 was determined by microdilution broth assay. Whole genomic DNA was extracted and was sequenced using an Illumina HiSeq X10 platform. De novo genome assembly was performed using Unicycler, and the draft genome was annotated using the NCBI Prokaryotic Genome Annotation Pipeline (PGAP). The sequence type (ST), capsular type, antimicrobial resistance and virulence-related genes were identified from the genome sequence. Core genome multilocus sequence typing (cgMLST) analysis was performed by BacWGSTdb server. RESULTS: Klebsiella pneumoniae KP2 was resistant to all antimicrobial agents tested, including colistin and tigecycline. The genome size was calculated as 5 729 339bp, with 5772 protein-coding sequences and a G+C content of 57.0%. The isolate was assigned to ST11 with capsular serotype KL64. Several antimicrobial resistance genes and virulence genes as well as genomic islands and multiple insertion sequences were identified in the genome sequence. The closest relative of K. pneumoniae KP2 was another isolate from Hangzhou that differed by only 45 cgMLST loci. CONCLUSION: The genome sequence data presented in this study can serve as an important reference sequence for further understanding of the antimicrobial resistance mechanisms and virulence potential of this bacterial species.

Genomic characterisation of a clinical Acinetobacter baumannii ST1928 isolate carrying a new ampC allelic variant blaADC-196 gene from China.

OBJECTIVES: The prevalence of multidrug-resistant Acinetobacter baumannii is of serious concern in hospital settings. Here we report the genome sequence and genomic characterisation of a clinical A. baumannii isolate from China belonging to a novel sequence type (ST) harbouring blaOXA-383 and a new ampC allelic variant blaADC-196 simultaneously. METHODS: Whole genomic DNA from A. baumannii A42 was extracted and sequenced using an Illumina HiSeq X10 platform. De novo genome assembly was performed using Unicycler, and the draft genome was annotated using the NCBI Prokaryotic Genome Annotation Pipeline. Genomic analyses were performed through various bioinformatics web servers from the Center for Genomic Epidemiology as well as BacWGSTdb. RESULTS: The genome size was calculated as 3 800 237bp, with 3610 protein-coding sequences and a GC content of 38.9%. A. baumannii A42 belongs to a rare sporadic clone ST1928. The resistome contains genes encoding resistance to ß-lactams (blaOXA-383 and a new ampC allelic variant blaADC-196). Virulence factor genes encoding biofilm-associated protein (bap), acinetobactin biosynthesis protein (basA-J), penicillin-binding protein (pbpG) and biofilm synthesis N-glycosyltransferase (pgaA-D) as well as 16 genomic islands and multiple insertion sequences were also identified in the genome of A. baumannii A42. CONCLUSION: This is the first report of the genome sequence of an A. baumannii ST1928 clinical isolate carrying a novel class C ß-lactamase gene from China. The genome sequence data can be used as a reference sequence for comparative studies and would facilitate further understanding of the antimicrobial resistance mechanisms of A. baumannii at the genomic level.

Emerging challenges of whole-genome-sequencing-powered epidemiological surveillance of globally distributed clonal groups of bacterial infections, giving Acinetobacter baumannii ST195 as an example.

Whole-genome sequencing (WGS) has revolutionized the genotyping of bacterial pathogens and is expected to become the new gold standard for tracing the transmissions of bacterial infectious diseases for public health purposes. However, it is still unexpectedly demanding to employ WGS for global epidemiological surveillance because of the high degree of similarity between the genomes of intercontinental isolates. The aim of this study was to utilize genomically derived bioinformatics analysis to identify globally distributed A. baumannii ST195 lineage and differentiation outbreaks to address this issue. The genomic sequences and their related epidemiological metadata of 2850 A. baumannii isolates were recruited from NCBI Genbank database. Assignment into sequence type (Oxford scheme) and lineage (global clone 2/CC92) were performed. A total of 91 ST195 A. baumannii isolates were subsequently classified to perform the bacterial source tracking analysis by implementing both core genome MLST (cgMLST) and core genome SNP (cgSNP) strategy that were integrated in our recently updated BacWGSTdb 2.0 server. Antibiotic resistance genes were identified using the ResFinder database. The ST195 A. baumannii isolates distributed widely in eight countries and harboured multiple antimicrobial resistance genes simultaneously. In most cases, the bacterial isolates recovered from geographically distant sources may present less genomic sequence similarity, i.e., the phylogenetic relationship between these ST195 isolates worldwide was roughly congruent with their country of isolation. However, a few isolates collected from distant geographic regions were revealed to possess smaller genetic distances (less than 8 loci or 20 SNPs) than the threshold without an observable epidemiological link. Our study highlights the emerging challenges entailed in the WGS-powered epidemiological surveillance of globally distributed clonal groups. Standardization is urgently required before WGS can be routinely applied to infectious diseases outbreak investigations.

Characterization of a small plasmid carrying the carbapenem resistance gene bla OXA-72 from community-acquired Acinetobacter baumannii sequence type 880 in China.

BACKGROUND: Acinetobacter baumannii has emerged as an important pathogen associated with hospital- and community-acquired infections. Community-acquired A. baumannii pneumonia is characterized by a fulminant course and high mortality rates. In this study, we report the identification of a community-acquired carbapenem-resistant A. baumannii strain carrying the bla OXA-72 gene. METHODS: This A. baumannii isolate was recovered from a male patient diagnosed with community-acquired pneumonia, septic shock, and respiratory failure. Antimicrobial susceptibility testing were performed and the minimum inhibitory concentrations were determined by the broth microdilution method. Whole-genome sequencing was performed using both long-read MinION and short-read Illumina platforms to fully characterize the bla OXA-72-carrying plasmid of the A. baumannii A52. The in silico multilocus sequence typing and genomic epidemiological analysis of the closely related isolates were further elucidated by our recently updated BacWGSTdb server. RESULTS: The isolate was resistant to meropenem and remained susceptible to several other antimicrobial agents. Whole-genome sequencing and bioinformatics analysis indicated that this A. baumannii isolate belonged to the rare sporadic clone sequence type 880 and the bla OXA-72 gene was located on the 8,493-bp plasmid pA52-OXA-72. This plasmid exhibited only partial similarity to different OXA-72-encoding plasmids (size range: 8,771-12,056 bp) in various Acinetobacter spp. recovered from patients and other reservoirs in different countries. CONCLUSION: This study described the first case of fulminant carbapenem-resistant community-acquired A. baumannii pneumonia caused by a rare sporadic clone in China. Adequate surveillance is warranted to monitor the emergence of A. baumannii as a community pathogen.