Unraveling the genomic diversity of the Pseudomonas putida group: exploring taxonomy, core pangenome, and antibiotic resistance mechanisms

The genus Pseudomonas is characterized by its rich genetic diversity, with over 300 species been validly recognized. This reflects significant progress made through sequencing and computational methods. Pseudomonas putida group comprises highly adaptable species that thrive in diverse environments and play various ecological roles, from promoting plant growth to being pathogenic in immunocompromised individuals. By leveraging the GRUMPS computational pipeline, we scrutinized 26 363 genomes labeled as Pseudomonas in the NCBI GenBank, categorizing all Pseudomonas spp. genomes into 435 distinct species-level clusters or cliques. We identified 224 strains deposited under the taxonomic identifier "Pseudomonas putida" distributed within 31 of these species-level clusters, challenging prior classifications. Nine of these 31 cliques contained at least six genomes labeled as "Pseudomonas putida" and were analysed in depth, particularly clique_1 (P. alloputida) and clique_2 (P. putida). Pangenomic analysis of a set of 413 P. putida group strains revealed over 2.2 million proteins and more than 77 000 distinct protein families. The core genome of these 413 strains includes 2226 protein families involved in essential biological processes. Intraspecific genetic homogeneity was observed within each clique, each possessing a distinct genomic identity. These cliques exhibit distinct core genes and diverse subgroups, reflecting adaptation to specific environments. Contrary to traditional views, nosocomial infections by P. alloputida, P. putida, and P. monteilii have been reported, with strains showing varied antibiotic resistance profiles due to diverse mechanisms. This review enhances the taxonomic understanding of key P. putida group species using advanced population genomics approaches and provides a comprehensive understanding of their genetic diversity, ecological roles, interactions, and potential applications.

Coexistence of tmexCD3-toprJ1b tigecycline resistance genes with two novel bla VIM-2-carrying and bla OXA-10-carrying transposons in a Pseudomononas asiatica plasmid

Introduction

Tigecycline and carbapenems are considered the last line of defense against microbial infections. The co-occurrence of resistance genes conferring resistance to both tigecycline and carbapenems in Pseudomononas asiatica was not investigated.

Methods

P. asiatica A28 was isolated from hospital sewage. Antibiotic susceptibility testing showed resistance to carbapenem and tigecycline. WGS was performed to analyze the antimicrobial resistance genes and genetic characteristics. Plasmid transfer by conjugation was investigated. Plasmid fitness costs were evaluated in Pseudomonas aeruginosa transconjugants including a Galleria mellonella infection model.

Results

Meropenem and tigecycline resistant P. asiatica A28 carries a 199, 972 bp long plasmid PLA28.4 which harbors seven resistance genes. Sequence analysis showed that the 7113 bp transposon Tn7389 is made up of a class I integron without a 5'CS terminal and a complete tni module flanked by a pair of 25bp insertion repeats. Additionally, the Tn7493 transposon, 20.24 kp long, with a complete 38-bp Tn1403 IR and an incomplete 30-bp Tn1403 IR, is made up of partial skeleton of Tn1403, a class I integron harboring bla _OXA-10, and a Tn5563a transposon. Moreover, one tnfxB3-tmexC3.2-tmexD3b-toprJ1b cluster was found in the plasmid and another one in the the chromosome. Furthermore, plasmid PLA28.4 could be conjugated to P. aeruginosa PAO1, with high fitness cost.

Discussion

A multidrug-resistant plasmid carrying tmexCD3-toprJ1b and two novel transposons carrying bla _VIM-2 and bla _OXA-10 -resistant genes was found in hospital sewage, increasing the risk of transmission of antibiotic-resistant genes. These finding highlight the necessary of controlling the development and spread of medication resistance requires continuous monitoring and management of resistant microorganisms in hospital sewage.

Genomic Epidemiology of MBL-Producing Pseudomonas putida Group Isolates in Poland

Introduction

Pseudomonas putida group are described as low-incidence opportunistic pathogens, but also as a significant reservoir of antimicrobial resistance (AMR) genes, including those of metallo-β-lactamases (MBLs). Our objective was the molecular and genomic characterization of MBL-producing P. putida (MPPP) group isolates from Poland, focusing on population structures, successful genotypes and MBL-encoding integrons.

Methods

During a country-wide MBL surveillance in Pseudomonas spp., 59 non-duplicate MPPP isolates were collected from 36 hospitals in 23 towns from 2003 to 2016. All of the isolates were subjected to whole-genome sequencing (WGS), followed by species identification, multi-locus sequence typing (MLST), single-nucleotide polymorphism (SNP)-based phylogenetic/clonality analysis, resistome determination, and susceptibility testing.

Results

The study collection comprised 12 species, of which P. alloputida (n = 19), P. monteilii (n = 15), and P. asiatica (n = 11) prevailed, while the others were P. kurunegalensis, P. putida, P. soli, P. mosselii, P. juntendi, and four potentially new species. MLST classified the isolates into 23 sequence types (STs) of which 21 were new, with three main clones, namely P. alloputida ST69, P.monteilii ST95 and P. asiatica ST15. The isolates produced VIM-like MBLs only, largely VIM-2 (n = 40), encoded by 24 different class 1 integrons (ten new), a number of which occurred also in P. aeruginosa and/or Enterobacterales in Poland. The plasmid pool was dominated by IncP-9, IncP-2, and pMOS94-like types. Multiple isolates were extensively drug-resistant.

Conclusions

This study, being one of the most comprehensive analyses of MPPP so far, has shown high diversity of the isolates in general, with three apparently international lineages, each internally diversified by MBL-encoding structures.

Supplementary Information

The online version contains supplementary material available at 10.1007/s40121-022-00659-z.

Phylogenetic analysis and population structure of Pseudomonas alloputida

The Pseudomonas putida group comprises strains with biotechnological and clinical relevance. P. alloputida was proposed as a new species and highlighted the misclassification of P. putida. Nevertheless, the population structure of P. alloputida remained unexplored. We retrieved 11,025 Pseudomonas genomes and used P. alloputida Kh7^T to delineate the species. The P. alloputida population structure comprises at least 7 clonal complexes (CCs). Clinical isolates are mainly found in CC4 and acquired resistance genes are present at low frequency in plasmids. Virulence profiles support the potential of CC7 members to outcompete other plant or human pathogens through a type VI secretion system. Finally, we found that horizontal gene transfer had an important role in shaping the ability of P. alloputida to bioremediate aromatic compounds such as toluene. Our results provide the grounds to understand P. alloputida genetic diversity and its potential for biotechnological applications.

The Ever-Expanding Pseudomonas Genus: Description of 43 New Species and Partition of the Pseudomonas putida Group

The genus Pseudomonas hosts an extensive genetic diversity and is one of the largest genera among Gram-negative bacteria. Type strains of Pseudomonas are well known to represent only a small fraction of this diversity and the number of available Pseudomonas genome sequences is increasing rapidly. Consequently, new Pseudomonas species are regularly reported and the number of species within the genus is constantly evolving. In this study, whole genome sequencing enabled us to define 43 new Pseudomonas species and provide an update of the Pseudomonas evolutionary and taxonomic relationships. Phylogenies based on the rpoD gene and whole genome sequences, including, respectively, 316 and 313 type strains of Pseudomonas, revealed sixteen groups of Pseudomonas and, together with the distribution of cyclic lipopeptide biosynthesis gene clusters, enabled the partitioning of the P. putida group into fifteen subgroups. Pairwise average nucleotide identities were calculated between type strains and a selection of 60 genomes of non-type strains of Pseudomonas. Forty-one strains were incorrectly assigned at the species level and among these, 19 strains were shown to represent an additional 13 new Pseudomonas species that remain to be formally classified. This work pinpoints the importance of correct taxonomic assignment and phylogenetic classification in order to perform integrative studies linking genetic diversity, lifestyle, and metabolic potential of Pseudomonas spp.

Emergence of clinical isolates of Pseudomonas asiatica and Pseudomonas monteilii from Japan harbouring an acquired gene encoding a carbapenemase VIM-2

Pseudomonas asiatica and Pseudomonas monteilii, belonging to the Pseudomonas putida phylogenetic group, are occasionally isolated from clinical samples, partly because they are often misidentified as P. putida in clinical laboratories. There are five reports describing carbapenem-resistant clinical isolates of these species. Carbapenem-resistant strains of P. asiatica and P. monteilii were isolated from stool samples. These isolates were sequenced using Illumina MiSeq and reidentified using average nucleotide identity (ANI) based on comparisons of their whole-genome sequences using the OrthoANI algorithm. The clonal relatedness of the isolates was assessed by pulse-field gel electrophoresis (PFGE). The size of plasmids conveying bla _VIM-2 was examined by Southern blotting. A total of six carbapenem-resistant clinical isolates of P. asiatica (two isolates) and P. monteilii (four isolates) were obtained from stool samples from five patients in a Japanese hospital. All isolates harboured blaVIM-2. The two isolates of P. asiatica had a different pattern in the PFGE analysis, with both having a 23 kb plasmid. Of the four isolates of P. monteilii with similar patterns in the PFGE analysis, three had 320 kb plasmids and one had a 240 kb plasmid. The genetic environments of the 320/240 kb and 23 kb plasmids differed. The results strongly indicated that carbapenem-resistant P. asiatica and P. monteilii producing metallo-β-lactamase are emerging in Japan. This is the first report of carbapenem-resistant P. asiatica and P. monteilii in Japan.

Lipopeptide families at the interface between pathogenic and beneficial Pseudomonas-plant interactions

Lipopeptides (LPs) are a prominent class of molecules among the steadily growing spectrum of specialized metabolites retrieved from Pseudomonas, in particular soil-dwelling and plant-associated isolates. Among the multiple LP families, pioneering research focussed on phytotoxic and antimicrobial cyclic lipopeptides (CLPs) of the ubiquitous plant pathogen Pseudomonas syringae (syringomycin and syringopeptin). Their non-ribosomal peptide synthetases (NRPSs) are embedded in biosynthetic gene clusters (BGCs) that are tightly co-clustered on a pathogenicity island. Other members of the P. syringae group (Pseudomonas cichorii) and some species of the Pseudomonas asplenii group and Pseudomonas fluorescens complex have adopted these biosynthetic strategies to co-produce their own mycin and peptin variants, in some strains supplemented with an analogue of the P. syringae linear LP (LLP), syringafactin. This capacity is not confined to phytopathogens but also occurs in some biocontrol strains, which indicates that these LP families not solely function as general virulence factors. We address this issue by scrutinizing the structural diversity and bioactivities of LPs from the mycin, peptin, and factin families in a phylogenetic and evolutionary perspective. BGC functional organization (including associated regulatory and transport genes) and NRPS modular architectures in known and candidate LP producers were assessed by genome mining.

New combinations, synonymy and emendations can only be proposed based on names that were previously validly published

Recently, articles were published in this journal in which new combinations were published based on basonyms that were not validly published at the time of submission, or a name not yet validly published was proposed as a later heterotypic synonym of another name. We here wish to remind authors and editors of the relevant rules of the International Code of Nomenclature of Prokaryotes that regulate the procedure for valid publication of names and specifically, of the fact that names in online pre-publication articles in the journal’s website are not validly published.

Reliable Identification of Environmental Pseudomonas Isolates Using the rpoD Gene

The taxonomic affiliation of Pseudomonas isolates is currently assessed by using the 16S rRNA gene, MultiLocus Sequence Analysis (MLSA), or whole genome sequencing. Therefore, microbiologists are facing an arduous choice, either using the universal marker, knowing that these affiliations could be inaccurate, or engaging in more laborious and costly approaches. The rpoD gene, like the 16S rRNA gene, is included in most MLSA procedures and has already been suggested for the rapid identification of certain groups of Pseudomonas. However, a comprehensive overview of the rpoD-based phylogenetic relationships within the Pseudomonas genus is lacking. In this study, we present the rpoD-based phylogeny of 217 type strains of Pseudomonas and defined a cutoff value of 98% nucleotide identity to differentiate strains at the species level. To validate this approach, we sequenced the rpoD of 145 environmental isolates and complemented this analysis with whole genome sequencing. The rpoD sequence allowed us to accurately assign Pseudomonas isolates to 20 known species and represents an excellent first diagnostic tool to identify new Pseudomonas species. Finally, rpoD amplicon sequencing appears as a reliable and low-cost alternative, particularly in the case of large environmental studies with hundreds or thousands of isolates.