Simultaneous detection and differentiation of Mycobacterium tuberculosis and nontuberculous mycobacteria coexisting in patients with pulmonary tuberculosis by single-tube multiplex PCR.

Background and Objectives: In clinical diagnostics, molecular methods are used to detect Mycobacterium tuberculosis bacilli (MTB) and to distinguish them from non-tuberculous mycobacteria (NTM). They are also used to make the right treatment decision for the patient as soon as possible. The aim of this study was to establish a rapid and novel multiplex PCR (mPCR) assay for the detection and differentiation of MTB and NTM in a single tube. Materials and Methods: 100 sputum samples positive for acid-fast bacilli (AFB) were included in this study. Mycobacterial culture, biochemical tests, and antibiotic susceptibility testing were performed on samples. After alkaline decontamination, total DNA was extracted from the samples. A primer pair targeting the rpoB gene, encoding the beta-subunit of RNA polymerase, was used to detect MTB and NTM, amplifying a 235-bp fragment of MTB and a 136-bp sequence of NTM. A pair of primers targeting a 190-bp fragment of the IS6110 region of MTB was also used to confirm the results. The sensitivity and specificity of the mPCR assay were evaluated using DNA extracted from standard strains. The amplified products were then analyzed by conventional agarose gel electrophoresis. Results: Of 100 AFB smear-positive sputum samples, 92 MTB DNA, 7 NTM DNA, and one mixed-infection sample were identified in a single tube using mPCR assay. There was no correlation between the AFB degree of smear positivity and PCR results. Of seven NTM isolates, 6 (86%) were resistant to rifampin, isoniazid, and ethambutol, the three first-line anti-tuberculosis drugs. Conclusion: A single-tube mPCR assay based on the rpoB gene provides a rapid and reliable means of detecting and differentiating MTB and NTM in sputum specimens.

Genetically engineered E. coli invade epithelial cells and transfer their genetic cargo into the cells: an approach to a gene delivery system.

PURPOSE: Despite advances in gene therapy, the lack of safe and efficient gene delivery systems limited the clinical effectiveness of gene therapy. Due to the inherent potential of bacteria, they can be considered as a good option for the gene transfer system. This study aimed to create a genetically engineered bacterium capable of entering epithelial cells and transferring its genetic cargo to the cell's cytoplasm, eventually expressing the gene of interest in the cell. METHODS: The invasin (inv) gene from Yersinia pseudotuberculosis and the listeriolysin (hlyA) gene from Listeria monocytogenes were isolated by PCR assay and inserted into a pACYCDuet-1 vector. The recombinant plasmid was then transformed into E. coli strain BL21. Subsequently, pEGFP-C1 plasmids containing a CMV promoter were transformed into the engineered bacteria. Finally, the engineered bacteria containing the reporter genes were incubated with the HeLa and LNCaP cell lines. Fluorescence microscopy, flow cytometry, and TEM were used to monitor bacterial entry into the cells and gene expression. We used native E. coli strain BL21 as a control. RESULTS: A fluorescence microscope showed that, in contrast to the control group, the manipulated E. coli were able to penetrate the cells and transport the plasmid pEGFP-C1 to the target cells. Flow cytometry also showed fluorescence intensity of 54.7% in HeLa cells and 71% in LNCaP cells, respectively. In addition, electron micrographs revealed the presence of bacteria in the cell endosomes and in the cytoplasm of the cells. CONCLUSION: This study shows that genetically engineered E. coli can enter cells, transport cargo into cells, and induce gene expression in the target cell. In addition, flow cytometry shows that the gene transfer efficiency was sufficient for protein expression.

The molecular characteristics of colorectal cancer: Impact of Ibuprofen and hyperthermia.

Despite various treatment options available for colorectal cancer, the survival rates for patients remain low. This study investigated the effects of hyperthermia and Ibuprofen on human colorectal adenocarcinoma cells (HT-29) viability, proliferation, and gene expression related to tumor suppression, Wnt signaling pathways, proliferation, and apoptosis The cells were exposed to hyperthermia at 42 or 43°C for 3 hours or Ibuprofen at different concentrations (700-1500 µM), and the effects were analyzed through MTT assay, trypan blue staining, and quantitative Real-time PCR. The study used quantitative Real-time PCR (qRT-PCR) to evaluate the effect of hyperthermia and Ibuprofen on the expression of various genes associated with tumor suppression, proliferation, Wnt signaling pathway, and apoptosis. The results revealed that hyperthermia caused a minor reduction in the viability and proliferation of HT-29 cells, but the decrease was not statistically significant (P<0.05). On the other hand, Ibuprofen caused a concentration-dependent decrease in the viability and proliferation of HT-29 cells. Both hyperthermia and Ibuprofen reduced the expression of WNT1, CTNNB1, BCL2, and PCNA genes, and increased the expression of KLF4, P53, and BAX genes. However, the changes in gene expression were not statistically significant in cells treated with hyperthermia. The findings suggest that Ibuprofen is more effective in reducing cancer cell proliferation by promoting apoptosis and inhibiting the Wnt signaling pathway than hyperthermia, which had some impact but was not statistically significant. The study highlights the potential of Ibuprofen as a targeted therapy for colorectal cancer.

Effects of labeling human mesenchymal stem cells with superparamagnetic zinc-nickel ferrite nanoparticles on cellular characteristics and adipogenesis/osteogenesis differentiation.

OBJECTIVE: An attractive cell source for stem cell-based therapy are WJ-MSCs. Hence, tracking WJ-MSCs using non-invasive imaging procedures (such as MRI) and contrast agents (Zn0.5Ni0.5Fe2O4, NFNPs) are required to evaluate cell distribution, migration, and differentiation. RESULTS: Results showed that the bare and dextrin-coated NFNPs were internalized inside the WJ-MSCs and had no effect on the cell viability, proliferation, apoptosis, karyotyping, and morphology of WJ-MSCs up to 125 µg/mL. Besides, treated WJ-MSCs were differentiated into osteo/adipocyte-like cells. The expression of RUNX 2, SPP 1 (P < 0.05), and OCN (P > 0.05) genes in the WJ-MSCs treated with dextrin-coated NFNPs was higher than the untreated WJ-MSCs; and the expression of CFD, LPL, and PPAR-γ genes was reduced in WJ-MSCs treated with both NFNPs in comparison with the untreated WJ-MSCs (P > 0.05). CONCLUSION: Overall, results showed that dextrin-coated NFNPs had no adverse effect on the cellular characteristics, proliferation, and differentiation of WJ-MSCs, and suggesting their potential clinical efficacy.

A Single Tube Overlap Extension PCR Method for Splicing of Multiple DNA Fragments.

BACKGROUND: Despite the ease of conventional splicing by overlap-extension (SOEing) PCR technique in theory, when splicing more than two fragments, and especially if one of the complementary sequences is A-T rich, the attachment of the fragments would be challenging. A new rapid and highly efficient SOEing PCR assay was developed for simultaneous splicing of multiple DNA fragments and induction of site-directed mutagenesis in a single tube. METHODS: The method was adapted for splicing human beta-globin UTRs to OCT4, SOX2, KLF4, C-MYC, LIN28A, and destabilized GFP for the construction of chimeric DNA fragments for in vitro transcription. In addition, the native Kozak sequence of beta-globin (K1) was replaced by the strongest Kozak sequence (K2) using site-directed mutagenesis to enhance the expression of target genes. RESULTS: ChimericGFPd2/K1, GFPd2/K2, OCT4, and KLF4 were created by the optimized conventional SOEing PCR. The single tube method was able to create the chimeric SOX2, C-MYC, and LIN28A in high quality and quantity in comparison with the conventional SOEing PCR. Moreover, using single tube SOEing PCR, the reaction time and materials that are required in the conventional SOEing PCR were significantly reduced. Fluorescent microscopy and flow cytometry examinations indicated highly efficient translation of K2 sequence in comparison with the K1sequence. CONCLUSION: Single tube SOEing PCR is a valuable method to construct more multiple fragments with high yield. The method can successfully be applied for construction of various kinds of complex chimeric genes.

Improved translation efficiency of therapeutic mRNA.

Recent developments in the field of the messenger RNA and its advantages versus DNA have led to a renewed interest in mRNA-based technologies. Despite its advantages, mRNA therapy has a number of drawbacks including low amount of mRNA production, short-term existence of mRNA and mRNA-mediated protein within the cell, severe mRNA cytotoxicity, and immune response activation following mRNA transfection. Here, we applied untranslated regions of human beta-globin to increase the stability and translation efficiency of a destabilized GFP mRNA. In order to suppress the innate immune response, which is the main barrier of mRNA therapy, we used the vaccinia virus derived capping enzyme and substituted standard nucleotides with modified nucleotides. At the end, the Kozak sequence of human beta-globin was replaced with the strongest sequence for the further improvement of mRNA translation. Overall, these modifications with native Kozak (K1) sequence of human beta-globin enhanced the stability of destabilized GFP mRNA up to 48 h and no increase in the level of interferon-α and -ß was found. The GFP expression of mRNA with modified Kozak (K2) sequence initiated earlier than mRNA and plasmid DNA with K1 sequence. In contrast to mRNA with K1 sequence, the cells containing mRNA with K2 sequence remained positive for GFP expression up to 72 h post-transfection. Interestingly, transfection efficiency and mean fluorescence intensity (MFI) of mRNA with K2 sequence were higher than mRNA and plasmid DNA with K1 sequence. Taken together, these results provide valuable information for the optimization of mRNA stability and translation. Therefore, the methods used in the current study can successfully be applied for reprogramming, gene editing, trans-differentiation, tumour therapy, and gene therapy.