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Fixed orthodontic appliances are common and effective tools to treat malocclusion. Adverse effects of these appliances, such as dental caries and periodontitis, may be associated with alteration of the microbiome. This study investigated the impact of these appliances on the dynamics of the oral microbiome. Seventy-one patients were selected. Supragingival plaque samples were collected before placement (T0) and six months after placement (T1). Saliva samples were collected at T0 and T1, and then when appliance removal (T2). Microbial DNA was analyzed by 16S rRNA meta-sequencing. The diversity analysis indicated dynamic changes in the structure of the oral microbiome. Taxonomic analysis at phylum level showed a significant increase in Bacteroidetes and Saccharibacteria (formally TM7) and decrease in Proteobacteria and Actinobacteria over time, in both plaque and saliva. Genus level analysis of relative abundance indicated a significant increase in anaerobic and facultative anaerobes in both plaque and saliva. Fixed orthodontic appliances induced measurable changes in the oral microbiome. This was characterized by an increase in relative abundance of obligate anaerobes, including periodontal pathogens. It can be concluded that this dysbiosis induced by fixed orthodontic appliances is likely to represent a transitional stage in the shift in microbiome from healthy to periodontitis.

Streptococcus mutans produces bacteriocins that show antibacterial activity against several bacteria. However, comprehensive analysis of these bacteriocins has not been well done. In this study, we isolated 125 S. mutans strains from volunteers and determined their whole genome sequence. Based on the genome analysis, the distribution of each bacteriocin gene (mutacins I-IV, K8 and Smb) was investigated. We found 17, 5, and 2 strains showing 100% matches with mutacin I, mutacin II and mutacin III, respectively. Five mutacin III-positive strains had 2 mismatches compared to mature mutacin III. In 67 mutacin IV-positive strains, 38 strains showed 100% match with mutacin IV, while 29 strains showed some variations. In 23 mutacin K8- and 32 mutacin Smb-positive strains, all except one mutacin K8-positive strain showed 100% match with the mature peptides. Among 125 strains, 84 (65.1%), 26 (20.2%), and 5 (3.9%) strains were positive for one, two and three bacteriocin genes, respectively. Then, the antibacterial activity against oral streptococci and other oral bacterial species was investigated by using bacteriocin gene single-positive strains. Each bacteriocin gene-positive strain showed a different pattern of antibacterial activity. These results speculate that individual S. mutans strains may affect the bacterial composition of dental plaques.

Antimicrobial resistance is a global health concern; Enterobacterales resistant to third-generation cephalosporins (3GCs) and carbapenems are of the highest priority. Here, we conducted genome sequencing and standardized quantitative antimicrobial susceptibility testing of 4,195 isolates of Escherichia coli and Klebsiella pneumoniae resistant to 3GCs and Enterobacterales with reduced meropenem susceptibility collected across Japan. Our analyses provided a complete classification of 3GC resistance mechanisms. Analyses with complete reference plasmids revealed that among the bla CTX-M extended-spectrum β-lactamase genes, bla CTX-M-8 was typically encoded in highly similar plasmids. The two major AmpC β-lactamase genes were bla CMY-2 and bla DHA-1 . Long-read sequencing of representative plasmids revealed that approximately 60% and 40% of bla CMY-2 and bla DHA-1 were encoded by such plasmids, respectively. Our analyses identified strains positive for carbapenemase genes but phenotypically susceptible to carbapenems and undetectable by standard antimicrobial susceptibility testing. Systematic long-read sequencing enabled reconstruction of 183 complete plasmid sequences encoding three major carbapenemase genes and elucidation of their geographical distribution stratified by replicon types and species carrying the plasmids and potential plasmid transfer events. Overall, we provide a blueprint for a national genomic surveillance study that integrates standardized quantitative antimicrobial susceptibility testing and characterizes resistance determinants. Kayama et al . present a blueprint for a national genomic surveillance study that conducts genome sequencing of thousands of strains, integrates standardized quantitative antimicrobial susceptibility testing, and characterizes antimicrobial resistance determinants.

Preparing the genetically modified organisms have required much time and labor, making it the rate-limiting step but CRISPR/Cas9 technology appearance has changed this difficulty. Although reports on CRISPR/Cas9 technology such as genome editing and CRISPR interference (CRISPRi) in eukaryotes increased, those in prokaryotes especially in Staphylococci were limited. Thus, its potential in the bacteriology remains unexplored. This is attributed to ecological difference between eukaryotes and prokaryotes. Here, we constructed a novel CRISPRi plasmid vector, pBACi for Staphylococcus aureus. The transformation efficiency of S. aureus was ~104 CFU/μg DNA using a vector extracted from dcm negative, which encoded one of DNA modification genes, E. coli. Further, pBACi was introduced into various clinical isolates including that not accepting the conventional temperature-sensitive vector. dcas9 in the vector was expressed throughout the growth phases of S. aureus and this vector decreased various gene mRNA expressions based on the crRNA targeting sequences and altered the knockdown strains' phenotypes. The targeted genes included various virulence and antibiotic resistant genes. Bioinformatics suggest this vector can be introduced into wide range of low-GC Gram-positive bacteria. Because this new CRISPR/Cas9-based vector can easily prepare knockdown strains, we believe the novel vector will facilitate the characterization of the function of genes from S. aureus and other Gram-positive bacteria.

We describe a pediatric case of recurrent skin infections caused by a Panton-Valentine leukocidin and exfoliative toxin E double-positive methicillin-susceptible Staphylococcus aureus clonal complex 188 clone. Most of the patient's family members were infected with the same strain, and intrafamilial transmission was strongly suspected. Decolonization procedures were not effective.

Staphylococcus epidermidis is a commensal bacterium in humans. To persist in the bacterial flora of the host, some bacteria produce antibacterial factors such as the antimicrobial peptides known as bacteriocins. In this study, we tried to isolate bacteriocin-producing S . epidermidis strains. Among 150 S . epidermidis isolates from the oral cavities of 287 volunteers, we detected two bacteriocin-producing strains, KSE56 and KSE650. Complete genome sequences of the two strains confirmed that they carried the epidermin-harboring plasmid pEpi56 and the nukacin IVK45-like-harboring plasmid pNuk650. The amino acid sequence of epidermin from KSE56 was identical to the previously reported sequence, but the epidermin synthesis-related genes were partially different. The prepeptide amino acid sequences of nukacin KSE650 and nukacin IVK45 showed one mismatch, but both mature peptides were entirely similar. pNuk650 was larger and had an additional seven ORFs compared to pIVK45. We then investigated the antibacterial activity of the two strains against several skin and oral bacteria and found their different activity patterns. In conclusion, we report the complete sequences of 2 plasmids coding for bacteriocins from S . epidermidis , which were partially different from those previously reported. Furthermore, this is the first report to show the complete sequence of an epidermin-carrying plasmid, pEpi56.

Antimicrobial resistance is a global health concern, and methicillin-resistant Staphylococcus aureus (MRSA) is one of the highest-priority organisms exhibiting this phenotype. Here, we performed a national surveillance integrating patient clinical data of S. aureus isolated from bloodstream infections. We performed genome sequencing, standardized antimicrobial susceptibility testing, and collected clinical metadata of 580 S. aureus isolates collected during 2019–2020. We focused on three predominant clonal complexes (CC1, CC5, and CC8) and assesses their microbiological and clinical significance, as well as their distribution across eastern and western Japan. Furthermore, we conducted a genomic comparison of the isolates of 2019–2000 with those of 1994–2000 and investigated the evolutionary trajectory of emerging clones from the three dominant clonal complexes. We revealed that the emerging MRSA ST764-SCC mec II showed the highest mortality rate within 30 days of hospitalization. This high-risk clone diverged from the New York/Japan clone (ST5-SCC mec II), which was inferred to have undergone repeated infections with phages carrying superantigen toxin genes and acquired antimicrobial resistance genes via mobile genetic elements, leading to its emergence around 1994. Overall, we provide a blueprint for a national genomic surveillance study that integrates clinical data and enables the identification and evolutionary characterization of a high-risk clone. Authors present results from a national surveillance in Japan that found MRSA strains causing bloodstream infections are predominantly from three clonal lineages. They also identified the emergence of highest 30-day-mortality MRSA clone ST764-SCC mec II and traced its evolutionary path.

Staphylococcus aureus is a common bacterium that sometimes causes various pyogenic diseases. Methicillin resistant S. aureus (MRSA) infections are particularly difficult to treat. Recently, MRSA has been spreading in the community, so it is important to determine the prevalence of MRSA in the community and to conduct epidemiological studies from genetic and statistical perspectives. In this study, S. aureus /MRSA was isolated from the oral and nasal cavities of 504 dental patients (65 inpatients and 439 outpatients). Sixty-two S. aureus strains and 9 MRSA strains were isolated from the oral cavity, and 112 S. aureus strains and 21 MRSA strains were isolated from the nasal cavity. Multi-locus sequence typing (MLST) analysis showed ST8 was high (18 isolates) among 30 MRSA isolates, whereas among 144 methicillin sensitive isolates, ST15 (25 isolates) and ST8 (20 isolates) were high. Statistical analysis of the patients’ clinical status revealed a correlation between oral S. aureus and denture use. Among the 34 patients from whom S. aureus was isolated from both sites, 25 had the same ST, and 23 showed below 40 single-nucleotide polymorphisms which are considered to be identical strains. Our study revealed various properties of S. aureus /MRSA in the oral and nasal cavities as commensals.

The environmental realm has been acknowledged as a pivotal arena for the emergence and propagation of antimicrobial resistance. To further explore insight into antimicrobial resistance dynamics beyond clinical and veterinary settings, we embarked on an environmental surveillance initiative targeting the prevalence of antibiotic-resistant bacteria within the bustling confines of an international airport in Japan. Our findings illuminate a high prevalence of methicillin-resistant staphylococci (46.3%) on frequently contacted surfaces in the public domain. Notably, Staphylococcus haemolyticus and S. epidermidis emerged as the preeminent carriers of the mec A gene. Intriguingly, we encountered a virulent strain of livestock-associated MRSA harboring a PVL-positive ST1232 clone, CC398 lineage. Further scrutiny unveiled a repertoire of resistance mechanisms, the methicillin-resistant isolates exhibited two or more resistance genes conferring resistance against different types of antibiotics, including beta-lactams, macrolides, lincosamides, aminoglycosides, chloramphenicol, and fosfomycin. Revealing multidrug-resistant CoNS and a LA-MRSA across various surfaces in urban public areas unearths a looming public health hazard. Thus, implementation of molecular surveillance is imperative, augmenting our capacity for early detection and mitigation of the insidious spread and potential transfer of antibiotic resistance genes and virulence factors amidst urban settings, notably within pivotal nodes such as airports.