Metabolic pathway prediction of core microbiome based on enterotype and orotype.

Introduction: Identification of key microbiome components has been suggested to help address the maintenance of oral and intestinal health in humans. The core microbiome is similar in all individuals, whereas the diverse microbiome varies across individuals, based on their unique lifestyles and phenotypic and genotypic determinants. In this study, we aimed to predict the metabolism of core microorganisms in the gut and oral environment based on enterotyping and orotyping. Materials and methods: Gut and oral samples were collected from 83 Korean women aged 50 years or older. The extracted DNA was subjected to next-generation sequencing analysis of 16S rRNA hypervariable regions V3-V4. Results: Gut bacteria were clustered into three enterotypes, while oral bacteria were clustered into three orotypes. Sixty-three of the core microbiome between the gut and oral population were correlated, and different metabolic pathways were predicted for each type. Eubacterium_g11, Actinomyces, Atopobium, and Enterococcus were significantly positively correlated between the gut and oral abundance. The four bacteria were classified as type 3 in orotype and type 2 in enterotype. Conclusion: Overall, the study suggested that collapsing the human body's multidimensional microbiome into a few categories may help characterize the microbiomes better and address health issues more deeply.

Hemoglobin subunit beta protein as a novel marker for time since deposition of bloodstains at crime scenes.

Dried bloodstains at crime scenes provide abundant information for analyzing criminal identity of victims or suspects, morphological characteristics, and biological and chemical compounds. Therefore, they are considered important evidence by investigators at crime scenes. Moreover, the age of bloodstains can be used to determine the timeline of incidents at crime scenes; Inappropriately handled bloodstains may cause degradation of blood components. In this study, we identified a novel marker, hemoglobin subunit beta protein, as an internal standard to determine the age of bloodstains at crime scenes. We found that the target spot between 20 and 30 kDa in two-dimensional electrophoresis gradually increased in size. The hemoglobin subunit beta protein was identified from this spot using liquid chromatography-tandem mass spectrometry and verified using western blotting. Sample bloodstains were exposed to various environmental conditions (humidity: 30%, 60%, 90% at room temperature [RT]). Furthermore, the hemoglobin subunit protein extracted from the sample bloodstains at various time points (0 h to 30 d) was dissolved in our newly developed buffer solution and in deionized or distilled water. We also analyzed the expression levels of the protein in the sample bloodstains, dried at RT and under various humidity over time, using western blotting. In addition, we evaluated the protein extraction capacity of deionized or distilled water and the newly developed buffer from the sample bloodstains over time. At RT and 60% humidity, using the newly developed buffer, the hemoglobin subunit beta protein levels showed a gradually increasing pattern. Finally, we quantitated human hemoglobin subunit beta protein using western blotting and enzyme-linked immunosorbent assay, which revealed significant differences among the samples. In particular, the time points from 36 h to 30 days were considered for analysis. Thus, the hemoglobin subunit beta protein dried at RT and 60% humidity and further dissolved in the newly developed buffer solution can be used to determine the age of bloodstains at crime scenes.

Next-Generation Sequencing Results Vary Between Cultured and Uncultured Microbes.

Next-generation sequencing (NGS) technology has led to innovations in environmental metagenomics and investigations involving humans and microbes. However, it is necessary to analyze the components that will affect analysis of the method upon processing a large amount of information. In particular, the processing method after sample collection affects the NGS results, and it is necessary to check for inaccurate results. Here, we show that the microbial communities obtained from fingertip samples differ from those obtained from fingertips remaining on mobile phones and desks, when cultured or not for 24 h. We also confirmed changes in microbial communities in fingertip samples from desks incubated for 2, 4, 8, 16, and 24 h. Samples of prints from mobile phones that are considerably vulnerable to external factors were not analyzed. Ratios of Firmicutes and Bacillus were, respectively, increased in cultures at the phylum and species levels. Collectively, we identified bacterial species that can aid in determining whether a sample has been cultured. In addition, although microbial communities differed depending on sample types, we confirmed changes after culture for 4 and 8 h. However, since this study is a sample limited to three types, it is necessary to analyze other types of samples in the same way and check whether they are applicable to all types. This strategy can verify the suitability of samples for deriving informative results from cultured or uncultured bacterial communities.

Discovery of donor age markers from bloodstain by LC-MS/MS using a metabolic approach.

Bloodstains are frequently encountered at crime scenes and they provide important evidence about the incident, such as information about the victim or suspect and the time of death or other events. Efforts have been made to identify the age of the bloodstain's donor through genomic approaches, but there are some limitations, such as the availability of databases and the quality dependence of DNA. There is a need for the development of a tool that can obtain information at once from a small blood sample. The aim of this study is to identify bloodstain metabolite candidates that can be used to determine donor age. We prepared bloodstain samples and analyzed metabolites using high-performance liquid chromatography-tandem mass spectrometry (LC-MS/MS). Eighteen molecular features (MFs) were selected as candidates using volcano plots and multivariate analysis. Based on the MS/MS spectrum of the MFs, the following nine metabolites were identified from the METaboliteLINk database: Δ2-cis eicosenoic acid, ergothioneine, adenosine 5'-monophosphate, benzaldehyde, phenacylamine, myristic acid ethyl ester, p-coumaric acid, niacinamide, and N-arachidonoyl-L-alanine. These nine age markers at high or low abundances could be used to estimate the age of a bloodstain's donor. This study was the first to develop metabolite age markers that can be used to analyze crime scene bloodstains.

Microbial analyses of blood spot surfaces collected from a laboratory and the bathroom of a female single-person household under different environmental conditions.

Many people spend most of their time indoors, thereby exposing themselves to indoor environmental microbial communities that might interact with the human microbiota. These potential interactions have only been considered for personal identification; however, accumulating evidence indicates that these microbial interactions are potentially implicated with the identification of human interactions and location-specific factors including time and seasonal variations in the microbial community. To augment the potential of metagenomics-based forensic tools, we compared the composition of microbial communities in blood spot surfaces from healthy adults placed in different environments, such as in the bathroom of a female single-person household and on a laboratory, which were sampled across seasons and time points. The laboratory samples showed more changes in the bacterial community over time owing to the higher number of individuals using the laboratory, whereas the microbial communities in the bathroom samples remained relatively stable over time. Moreover, the two locations could be distinguished according to their specific bacterial community compositions. Variations were also observed related to changes in temperature and humidity, allowing for prediction of season-based microbial community. These findings offer a new perspective regarding the use of microbial community analysis in forensic science.

Enhanced detection of cell-free DNA (cfDNA) enables its use as a reliable biomarker for diagnosis and prognosis of gastric cancer.

Although circulating cell-free DNA (cfDNA) is a promising biomarker for the diagnosis and prognosis of various tumors, clinical correlation of cfDNA with gastric cancer has not been fully understood. To address this, we developed a highly sensitive cfDNA capture system by integrating polydopamine (PDA) and silica. PDA-silica hybrids incorporated different molecular interactions to a single system, enhancing cfDNA capture by 1.34-fold compared to the conventional silica-based approach (p = 0.001), which was confirmed using cell culture supernatants. A clinical study using human plasma samples revealed that the diagnostic accuracy of the new system to be superior than the commercially available cfDNA kit, as well as other serum antigen tests. Among the cancer patients, plasma cfDNA levels exhibited a good correlation with the size of a tumor. cfDNA was also predicative of distant metastasis, as the median cfDNA levels of metastatic cancer patients were ~60-fold higher than those without metastasis (p = 0.008). Furthermore, high concordance between tissue biopsy and cfDNA genomic analysis was found, as HER2 expression in cfDNA demonstrated an area under ROC curve (AUC) of 0.976 (p <0.001) for detecting patients with HER2-positive tumors. The new system also revealed high prognostic capability of cfDNA, as the concentration of cfDNA was highly associated with the survival outcomes. Our novel technology demonstrates the potential to achieve efficient detection of cfDNA that may serve as a reliable biomarker for gastric tumor.

Development of novel extraction reagents for analyzing dried blood spots from crime scenes.

Evidence of dried blood is very valuable in forensic science. Since the discovery of luminescence with Luminol and dried blood spots (DBSs) in 1928, interest and research on blood have continued to date. One of the most important factor that DBSs have is genes. However, the current use of distilled water (DDW) to collect and extract blood samples has disadvantages related to DNA stability. Therefore, this study aimed to develop an extraction reagent that is most suitable for gene extraction from DBSs. Blood was collected from 45 healthy adult men and women in vacuum blood containers without coagulants or anticoagulants. The collected blood was dried in various settings to check the performance of the extraction reagent. Extraction with Tris-EDTA (TE) and phosphate-buffered saline (PBS) was found more suitable in terms of gene interference effects compared with DDW; their performance was also compared with those of the newly developed extraction reagents. Upon comparing the results of polymerase chain reaction for human genomic DNA samples using glyceraldehyde 3-phosphate dehydrogenase (GAPDH) gene as the target, the performance of the newly developed extraction reagents, modified TE and PBS, was found to be relatively good. To determine the optimal composition of the developed extraction reagents, 12 new extraction reagents were developed with different pH and sodium concentrations. Among them, the best results were found when the DNA was extracted using extraction reagent No. 3 with pH 8.0 and containing 1 M NaCl. Next, the four extraction reagents, DDW, TE, PBS, and No. 3 were compared under nine different temperature and humidity conditions. Similarly, under various environmental conditions, extraction reagent No. 3 performed better than other reagents. It is proposed that modified TE and PBS mixed extraction reagents are the most suitable for collecting and preserving crime site samples. The proposed composition for a DNA extraction reagent can contribute greatly to crime scene reconstruction.

Association between Altered Blood Parameters and Gut Microbiota after Synbiotic Intake in Healthy, Elderly Korean Women.

Synbiotics intake can alter the composition of intestinal microbes beneficially. We aimed to detect the changes in the intestinal microbiomes of 37 healthy elderly Korean women after the intake of a synbiotic drink. This was a longitudinal study controlled with a temporal series, including a control period of 3 weeks before intake, synbiotic intake for 3 weeks, and a washout period of 3 weeks. Fecal microbiota composition was analyzed by sequencing the V3-V4 hypervariable regions of 16S rRNA. Physical fecal activity increased with improvement in fecal shape. Thirty intestinal bacterial taxa were observed to change only after the intake period. In particular, Ellagibacter appeared only after ingestion. In addition, the abundance of Terrisporobacter showed a positive correlation with C-reactive protein, triglyceride. Lachnospiraceae_uc, Eubacterium_g5, and Blautia had a positive correlation with creatinine, whereas PAC001100_g had a negative correlation with creatinine. Short-term (3 weeks) intake of symbiotic organisms changes the composition of the gut microbiota in healthy elderly Korean women.

OmpA of Klebsiella pneumoniae ATCC 13883 induces pyroptosis in HEp-2 cells, leading to cell-cycle arrest and apoptosis.

Klebsiella pneumoniae is an opportunistic pathogenic bacterium that commonly causes pneumonia in elderly people. OmpA, a toxin that is highly expressed in the outer membrane of the bacterium, is one of the primary factors implicated in the pulmonary pathogenesis of K. pneumoniae. To evaluate the associated pyroptosis mechanism of infection, the ompA gene was cloned, and the protein was expressed, extracted, and used to treat human larynx epithelial cells. We observed that OmpA induces reactive oxygen species production and cell-cycle arrest in the G2/M phase in host cells, leading to subsequent apoptosis. Moreover, OmpA was found to induce IL-1ß and IL-18 production in host cells, resulting in caspase-1 activation, which simultaneously stimulated pyroptosis, thus leading to the death of the host cells. We next sought to examine differential gene expression via RNA sequencing to better elucidate the mechanisms associated with these cellular changes, and found that genes associated with these pathways were more highly expressed in OmpA-treated cells than in K. pneumoniae-infected cells. Thus, cell-cycle arrest, apoptosis, and pyroptosis may serve as the primary defenses employed by host cells against OmpA. These results provide novel insights into the host defense against K. pneumoniae infection.

Comparison of Swabbing Solution Volume and gDNA Extraction Kits on DNA Recovery from Rigid Surface.

For bacteria sampling studies, various collection methods have been used to identify bacteria. To obtain accurate information about bacteria, high quality samples should be obtained. In order to obtain a high quality sample, a stable and large number of DNA copies must be collected. This study compared the efficiency of different methods of bacterial gDNA extraction and bacteria collection according to swabbing solution volumes and types. The efficiency of bacterial genomic DNA extraction was compared using a AccuPrep® Genomic DNA Extraction kit, a QIAamp® DNA Mini kit, and a MOBIO® DNeasy PowerSoil kit. The DNA Mini kit was shown to extract the highest amount of gDNA, and sub-experiments were conducted using this kit. Phosphate-buffered saline and phosphate-buffered saline with 0.1% Tween 20 were used as collection solutions of various volumes (0, 40, 50, 60, 70, 80, 90, 100, 110, and 120 µL) using cotton swabs. Bacteria collection efficiency was highest when 70 µL PBS was used. The target strains collected in this experiment were Staphylococcus aureus and Escherichia coli, and these were quantified using the number of colony-forming units, DNA concentrations, and the number of DNA copies. These results can be used to efficiently bacterial collection for experiments in various fields.

Development of a novel DsRed-NLS vector with a monopartite classical nuclear localization signal.

The nuclear localization signal (NLS) marks proteins for transport to the nucleus and is used in various applications in many fields. NLSs are used to achieve efficient and stable transport of biomolecules. Previously, commercial vectors used in NLS studies contained three iterations of the NLS sequence, but these sequences can affect experimental results and alter protein function. Here, we investigated a new vector using a single classical NLS sequence with a mutation in pDsRed2-C1-wt to reduce experimental artifacts. In the newly constructed pDsRed2-C1-1NLS vector, the NLS sequence is placed near the multiple cloning sites of pDsRed2-C1-wt, and the multiple cloning site region was designed to facilitate insertion of the desired gene by site-directed mutagenesis. Fluorescent protein expression in the nucleus can be visually confirmed. The results show that the fluorescent protein was bound to the transport protein. The constructed vector had a cell survival rate of 89-95% and a transfection efficiency of 39-56% when introduced into animal cells, which are similar to those of other NLS vectors. Additionally, the constructed NLS vector can be used to demonstrate complementary binding between target proteins, and that the target protein is transported by the NLS transport system. Especially, we show that the vector can be useful for experiments involving the S100A10 gene. In addition, the constructed vector is useful for studies of genes and proteins that show potential for gene therapy or drug delivery applications.

Influence of swabbing solution and swab type on DNA recovery from rigid environmental surfaces.

Determination of the metagenome has become an important component of forensic identification, which requires efficient environmental sampling techniques. Therefore, in this study, we compared the efficiency of sample collection using swabbing with cotton swabs and three types of medical swabs (S7, S22, S24) along with three different solutions: phosphate-buffered saline (PBS), 1% Tween 20 + 1% glycerol in PBS (TG), and GS commercial solution (Noble Bio, Hwaseong, Republic of Korea). Combinations of the three solutions with the three types of swabs were tested at different volumes (cotton swab, S7: 0, 30, 50, 70 µL; S22, S24: 0, 70, 100, 130 µL). Escherichia coli and Staphylococcus aureus were selected as representative environmental microbial samples, and the number of colony-forming units (CFUs), DNA concentration, and DNA copy numbers were compared across groups. The sampling process had a clear effect on the efficiency of extraction, which allowed for determination of a more efficient sample sampling method. In particular, cotton swabs showed 2-10-fold greater CFUs of both species than the medical swabs, and resulted in significantly greater amounts of extracted DNA. TG was found to be the most efficient solution for bacterial DNA extraction, with higher CFUs and DNA obtained than with the other three solutions at all volumes tested. This study highlights the need for a standardized sampling method that can be applied to all environmental samples, especially for microbial quantification, and provides valuable reference data for the efficient collection of environmental samples for metagenomic analyses in microbial-based forensic assessments.

Changes in Gene Expression in Human Epithelial and Mast Cells in Response to Vesicles from Klebsiella pneumonia ATCC 13883.

We investigated alterations in the expression of immune-related genes in epithelial cells and mast cells treated with outer membrane vesicles (OMVs) derived from Klebsiella pneumoniae (KpOMVs). Previous studies have shown that OMVs contain substances that enable their delivery to host cells and induce an immune response. Our results indicate an increase in expression of genes such as IL-8, IL-1b, MIP-1α, HMOX1, HSPA1A, and IL-24 in epithelial cells and mast cells treated with KpOMVs. The pathogenicity of KpOMVs was confirmed by measuring the changes in the expression of these immune-related genes.

Internal standard metabolites for obtaining absolute quantitative information on the components of bloodstains by standardization of samples.

Analysis of the components of bloodstains found at crime scenes can provide important information for solving the crime. However, components of blood and bloodstains vary with volume and various other unpredictable factors. Therefore, it is necessary to specify the volume of the initial liquid blood droplet and standardize the analysis. In this study, internal standard metabolites that remained constant in a certain amount of bloodstain, long after deposition of the stain, were identified. Liquid chromatography-electrospray ionization-tandem mass spectrometry of the metabolites extracted from the bloodstain samples at various time points (0, 7, 14, 21, and 28 days) was performed. The coefficient of variation (CV) of the obtained molecular features was calculated for each criterion: time point, subject, and all data (time and subject, triplicate of each). Five molecular features with average CVs of less than or equal to 5% were selected as candidates. Partial least squares discriminant analysis and principal component analysis showed that the effect on the candidates was very low over time. The fold-change value of abundances was confirmed according to time. Stigmasterol exhibited the most stable pattern; l-methionine remained stable until day 14 and after day 21. This study was the first attempt to identify internal standard metabolites that were maintained at a constant level in a bloodstain for a sufficiently long time. Analysis of internal standard metabolites in bloodstains will facilitate determination of the initial blood volume from which the bloodstain was made. Moreover, this method will provide an approach for standardization of bloodstains to obtain absolute quantitative information of bloodstain components at crime scenes.

Estimation of Age of Bloodstains by Mass-Spectrometry: A Metabolomic Approach.

Bloodstains are common evidence in crime scenes, containing significant information, including genetic information. Although efforts have been made to reliably determine the time of incident by analyzing the elapsed time of the bloodstain, there has been limited success. To identify candidate metabolites in bloodstains over time, we prepared bloodstain samples using filter paper and analyzed the metabolites by high-performance liquid chromatography-mass spectrometry (HPLC-MS)/MS over a 21-day period. Using Venn diagrams and by multivariate analysis, we selected 62 candidate molecular features. We found by partial least-squares discriminant analysis (PLS-DA) that the group can be classified with an accuracy of 75.0%, and the R2 and Q2 values were 0.7513 and 0.6998, respectively. Five metabolites were successfully identified based on candidate molecular features. The level of two metabolites, l-tryptophan and ergothioneine, decreased with time. The concentration of candidate metabolites that we propose reliably increased or decreased with time, thus, enabling the measurement of elapsed time of the bloodstain. This study is the first to identify markers used to analyze the elapsed time of bloodstains through metabolomics analysis.

Sub-lethal hyperthermia promotes epithelial-to-mesenchymal-like transition of breast cancer cells: implication of the synergy between hyperthermia and chemotherapy.

Thermotherapy has demonstrated a potential to be an effective non-surgical technique to treat breast cancer. Despite its advantages, including low toxicity and high repeatability, thermotherapy is typically required to be applied in combination with other treatments since the residual tumor cells that survive after hyperthermal treatment often cause recurrence. In this study, we confirmed that breast cancer cells tolerate temperature of up to 47 °C by synthesizing a large amount of heat shock proteins. Further changes in the molecular properties of the heat-exposed cells were investigated using western blotting, quantitative reverse transcription polymerase chain reaction, and immunocytochemistry. We found that low-temperature hyperthermia promoted epithelial-to-mesenchymal-like transition (EMT), as observed by the increased mesenchymal marker expression levels while decreasing epithelial markers. Moreover, cell morphology changed from cobblestone-like to a more spindle-like appearance, in addition to significantly enhanced cell motility upon heat treatment. These results all support that sub-lethal hyperthermal stress induces EMT. In addition, we examined changes in the chemo-sensitivity of the heat-treated cells. Addition of a chemo-drugs caused increased cytotoxicity of the heat-treated cells compared to the cells that were not co-treated with heat. Our study demonstrates that thermotherapy alone may cause undesirable EMT, which could be well overcome through a synergistic effect when applied with chemotherapy.

Prediction of bacterial proteins carrying a nuclear localization signal and nuclear targeting of HsdM from Klebsiella pneumoniae.

Nuclear targeting of bacterial proteins is an emerging pathogenic mechanism whereby bacterial proteins can interact with nuclear molecules and alter the physiology of host cells. The fully sequenced bacterial genome can predict proteins that target the nuclei of host cells based on the presence of nuclear localization signal (NLS). In the present study, we predicted bacterial proteins with the NLS sequences from Klebsiella pneumoniae by bioinformatic analysis, and 13 proteins were identified as carrying putative NLS sequences. Among them, HsdM, a subunit of KpnAl that is a type I restriction-modification system found in K. pneumoniae, was selected for the experimental proof of nuclear targeting in host cells. HsdM carried the NLS sequences, (7)KKAKAKK(13), in the N-terminus. A transient expression of HsdM-EGFP in COS-1 cells exhibited exclusively a nuclear localization of the fusion proteins, whereas the fusion proteins of HsdM with substitutions in residues lysine to alanine in the NLS sequences, (7)AAAKAAA(13), were localized in the cytoplasm. HsdM was co-localized with importin o in the nuclei of host cells. Recombinant HsdM alone methylated the eukaryotic DNA in vitro assay. Although HsdM tested in this study has not been considered to be a virulence factor, the prediction of NLS motifs from the full sequenced genome of bacteria extends our knowledge of functional genomics to understand subcellular targeting of bacterial proteins.

Solubilization of water-insoluble beta-glucan isolated from Ganoderma lucidum.

The fungal beta-D-glucan is a biological response modifier (BRM), but a major obstacle to the clinical utilization of beta-glucan BRMs is thei relative lack of solubility in aqueous media. Water insoluble fungal glucans extracted by alkali from the mycelia of Ganoderma lucidum were sulfated to yield their corresponding water-soluble derivatives. Insoluble glucan is dissolved in methyl sulfoxide and urea, and is partially sulfated with sulfuric acid. The sulfated glucan (SGL) yield prepared from insoluble glucan (IGL) was 85%, the sulfation degree of SGL was about 14.9%, and the solubility of SGL was above 95% in water. The monosugar SGL content was 34.9% alpha-glucose and 35.9% beta-glucose. The mean molecular weight (MW) of SGL was shown as a single peak on Sepharose CL-4B column chromatography, and their MW was approximately 9.3 kDa. The 13C NMR spectrum analysis shows that SGL has a high similarity with the beta-(1-->3)-linked triple-helical control.

Nuclear translocation and DNAse I-like enzymatic activity of Acinetobacter baumannii outer membrane protein A.

Acinetobacter baumannii outer membrane protein A (AbOmpA) is a potential virulence factor that induces host cell death. Based on previous findings that AbOmpA translocated into the nuclei of host cells, the cell-death mechanism of AbOmpA through the nuclear targeting was investigated. Acinetobacter baumannii secreted AbOmpA in in vitro culture. The recombinant AbOmpA (rAbOmpA) was internalized by the host cells. The intracellular rAbOmpA was degraded into several forms of subfragments in the cytosol and then two subfragments of rAbOmpA translocated into the nuclei. The rAbOmpA exhibited the divalent cation-dependent endonuclease activity. In an in vivo assay with microinjection of rAbOmpA into the nucleus of fertilized Xenopus laevis eggs, rAbOmpA degraded chromosomal DNA with the characteristic DNA ladders and induced degeneration of the embryos. These results suggest that AbOmpA translocates into the nuclei of host cells and degrades chromosomal DNA by DNAse I-like enzymatic activity, which is a new pathogenic strategy of A. baumannii.