Genomic insights into Leminorella grimontii and its chromosomal class A GRI ß-lactamase.

Leminorella grimontii strain LG-KP-E1-2-T0 was isolated from Zophobas morio larvae. It showed a susceptibility phenotype compatible with the expression of an inducible extended-spectrum ß-lactamase. The presence of a chromosomal bla gene encoding for the class A GRI-1 ß-lactamase was revealed by whole-genome sequencing. GRI-1 shared the highest amino acid identity with RIC-1 and OXY-type ß-lactamases (76-80%). Analysis of six further publicly-available L. grimontii draft genomes deposited in NCBI revealed that blaGRI-1 was always present. Core-genome analysis indicated that LG-KP-E1-2-T0 was unique from other strains. We provided the first complete genome of L. grimontii and new insights on its chromosomal ß-lactamases.

A new OCH ß-lactamase from a Brucella pseudintermedia (Ochrobactrum pseudintermedium) strain isolated from Zophobas morio larvae.

OBJECTIVES: OCH class C ß-lactamases have been reported in several species belonging to the Brucella genus that were formerly known as Ochrobactrum. Moreover, only one complete genome of Brucella pseudintermedia has been published. In this work, we describe the genome of a B. pseudintermedia strain possessing a new blaOCH gene that was isolated from Zophobas morio larvae. METHODS: Hybrid whole-genome sequencing analysis (Illumina and Nanopore) was used to identify and characterise the strain (Ops-OCH-23). Phylogenetic analyses based on the 16S rRNA gene sequence and a core-genome alignment were performed to study the relationships among Ops-OCH-23 and deposited genomes. Moreover, all deposited blaOCH genes were compared to the one found in Ops-OCH-23. RESULTS: Ops-OCH-23 showed a susceptibility profile consistent with the production of AmpC ß-lactamase(s). Its genome consisted of two chromosomes, of which one carried the blaOCH gene. Such gene encoded a new class C OCH ß-lactamase among the fifteen so far reported. Two plasmids (120-Kb and 59-Kb) without any associated antimicrobial resistance genes were also found. Analysis of 16S rRNA revealed that Ops-OCH-23 shared 100% homology with four deposited B. pseudintermedia strains. Moreover, the core-genome analysis indicated that the closest match (279 ΔSNVs) to Ops-OCH-23 was strain CTOTU49018 isolated from an urban environment in Germany in 2013. CONCLUSION: We described the second complete genome of a B. pseudintermedia that also encoded a new OCH ß-lactamase variant. Overall, this report expands our knowledge regarding this rarely isolated Brucella species that have been reported so far only a few times in human sources.

Complete genome sequence of Pseudomonas canadensis strain Pcan-CK-23 isolated from Zophobas morio larvae.

We present the complete genome sequence of Pseudomonas canadensis. The strain (Pcan-CK-23) was isolated from Zophobas morio (superworm) larvae. The genome consisted of a 6,424,469 bp chromosome with a GC content of 60.3% and 5,973 genes. Pcan-CK-23 can be used as a reference genome for further studies with P. canadensis.

A new in vivo model of intestinal colonization using Zophobas morio larvae: testing hyperepidemic ESBL- and carbapenemase-producing Escherichia coli clones.

Finding strategies for decolonizing gut carriers of multidrug-resistant Escherichia coli (MDR-Ec) is a public-health priority. In this context, novel approaches should be validated in preclinical in vivo gut colonization models before being translated to humans. However, the use of mice presents limitations. Here, we used for the first time Zophobas morio larvae to design a new model of intestinal colonization (28-days duration, T28). Three hyperepidemic MDR-Ec producing extended-spectrum ß-lactamases (ESBLs) or carbapenemases were administered via contaminated food to larvae for the first 7 days (T7): Ec-4901.28 (ST131, CTX-M-15), Ec-042 (ST410, OXA-181) and Ec-050 (ST167, NDM-5). Growth curve analyses showed that larvae became rapidly colonized with all strains (T7, ~106-7 CFU/mL), but bacterial load remained high after the removal of contaminated food only in Ec-4901.28 and Ec-042 (T28, ~103-4 CFU/mL). Moreover, larvae receiving a force-feeding treatment with INTESTI bacteriophage cocktail (on T7 and T10 via gauge needle) were decolonized by Ec-4901.28 (INTESTI-susceptible); however, Ec-042 and Ec-050 (INTESTI-resistant) did not. Initial microbiota (before administering contaminated food) was very rich of bacterial genera (e.g., Lactococcus, Enterococcus, Spiroplasma), but patterns were heterogeneous (Shannon diversity index: range 1.1-2.7) and diverse to each other (Bray-Curtis dissimilarity index ≥30%). However, when larvae were challenged with the MDR-Ec with or without administering bacteriophages the microbiota showed a non-significant reduction of the diversity during the 28-day experiments. In conclusion, the Z. morio larvae model promises to be a feasible and high-throughput approach to study novel gut decolonization strategies for MDR-Ec reducing the number of subsequent confirmatory mammalian experiments.