FOXM1 Drives Epithelial-Mesenchymal Transition Program Through E-Cadherin Promoter Biding Ability in Non-Small-Cell Lung Cancer Cells

Background: Forkhead box (FOX) gene family plays a critical role in regulating Epithelial-mesenchymal transition (EMT) program, and in which, FOXM1 can mediate multiple malignant process in many type of tumor cells. However, the modulate functions of FOXM1 on EMT in non-small-cell lung cancer (NSCLC) cells, especially the transcriptional function on E-cadherin coding gene CDH1 remains unclear. This article mainly focuses on FOXM1, exploring its mechanism in regulating EMT of NSCLC cells, and FOXM1 inhibitor thiostrepton’s effects in EMT intervention. Methods: Morphological changes of overexpressed cells were observed by HE staining. The effects of scratch test, Transwell chamber test and Western-blot analysis on cell migration and invasion ability and the expression of EMT-related markers were analyzed. Dual luciferin reporter enzyme assay and nuclear transcription factor immunoprecipitation assay (ChIP, immunofluorescence) revealed the transcriptional regulation of FOXM1 on EMT markers. MTT assay and clone formation assay were used to determine the effect of thiomycin on the viability of NSCLC cells and the ability of cell clone formation.Rusults: After overexpression of FOXM1, the cells showed intermediate epithelial-mesenchymal morphology, but not complete mesenchymal morphology, and their migration and invasion abilities were enhanced. The protein expression levels of N-cadherin,Snail1 and Vimentin were increased, while the expression levels of E-cadherin were decreased. On the contrary, knockdown of FOXM1 expression showed the opposite result. The double luciferin reporter enzyme assay showed that FOXM1 inhibited the luciferin reporter vector CDH1-2000-promoter. ChIP results confirmed that FOXM1 could bind endogenous to CDH1 gene promoter. In cells overexpressing FOXM1, knockdown of Snail further promotes FOXM1-mediated CDH1 transcription. MTT results and clone formation experiments showed that thiomycin had inhibitory effect on the proliferation of NSCLC cells. Morphological observation, cell migration assay and Transwell chamber assay showed that streptotin inhibited TGF-β1-induced enhanced cell migration and invasion. Western-blot analysis showed that thiomycin down-regulated the expression of FOXM1, N-cadherin, Snail, and Vimentin induced by TGF-β1, while blocking the expression of E-cadherin induced by TGF-β1 decreased.Conclusion: FOXM1 can directly bind to the promoter of E-cadherin encoding gene, and can indirectly inhibit E-cadherin expression by stimulating Snail. Overexpression of FOXM1 can promote EMT progression in NSCLC cells. Therefore, down-regulation of FOXM1 can inhibit this process. In addition, thiostrepton, a FOXM1 inhibitor, blocked proliferation, colony formation, and EMT progression in NSCLC cells.

Co-culturing experiments reveal the uptake of myo-inositol phosphate synthase (EC 5.5.1.4) in an inositol auxotroph of Saccharomyces cerevisiae

Background Myo-Inositol Phosphate Synthase (MIP) catalyzes the conversion of glucose 6- phosphate into inositol phosphate, an essential nutrient and cell signaling molecule. Data obtained, first in bovine brain and later in plants, established MIP expression in organelles and in extracellular environments. A physiological role for secreted MIP has remained elusive since its first detection in intercellular space. To provide further insight into the role of MIP in intercellular milieus, we tested the hypothesis that MIP may function as a growth factor, synthesizing inositol phosphate in intercellular locations requiring, but lacking ability to produce or transport adequate quantities of the cell–cell communicator. This idea was experimentally challenged, utilizing a Saccharomyces cerevisiae inositol auxotroph with no MIP enzyme, permeable membranes with a 0.4 µm pore size, and cellular supernatants as external sources of inositol isolated from S. cerevisiae cells containing either wild-type enzyme (Wt-MIP), no MIP enzyme, auxotroph (Aux), or a green fluorescent protein (GFP) tagged reporter enzyme (MIP- GFP) in co- culturing experiments. Results Resulting cell densities and microscopic studies with corroborating biochemical and molecular analyses, documented sustained growth of Aux cells in cellular supernatant, concomitant with the uptakeof MIP, detected as MIP-GFP reporter enzyme. These findings revealed previously unknown functions, suggesting that the enzyme can: (1) move into and out of intercellular space, (2) traverse cell walls, and (3) act as a growth factor to promote cellular proliferation of an inositol requiring cell. Conclusions Co-culturing experiments, designed to test a probable function for MIP secreted in extracellular vesicles, uncovered previously unknown functions for the enzyme and advanced current knowledge concerning spatial control of inositol phosphate biosynthesis. Most importantly, resulting data identified an extracellular vesicle (a non-viral vector) that is capable of synthesizing and transporting inositol phosphate, a biological activity that can be used to enhance specificity of current inositol phosphate therapeutics.

Point-of-care analyte quantification and digital readout via lysate-based cell-free biosensors interfaced with personal glucose monitors

Field-deployable diagnostics based on cell-free systems have advanced greatly, but on-site quantification of target analytes remains a challenge. Here we demonstrate that Escherichia coli lysate-based cell-free biosensors coupled to a personal glucose monitor (PGM) can enable on-site analyte quantification, with the potential for straightforward reconfigurability to diverse types of analytes. We show that analyte-responsive regulators of transcription and translation can modulate production of the reporter enzyme β-galactosidase, which in turn converts lactose into glucose for PGM quantification. Because glycolysis is active in the lysate and would readily deplete converted glucose, we decoupled enzyme production and glucose conversion to increase endpoint signal output. This lysate metabolism did, however, allow for one-pot removal of glucose present in complex samples (like human serum) without confounding target quantification. Taken together, we show that integrating lysate-based cell-free biosensors with PGMs enables accessible target detection and quantification at the point of need.

A Novel Assay for Phosphoserine Phosphatase Exploiting Serine Acetyltransferase as the Coupling Enzyme

Phosphoserine phosphatase (PSP) catalyzes the final step of de novo L-serine biosynthesis—the hydrolysis of phosphoserine to serine and inorganic phosphate—in humans, bacteria, and plants. In published works, the reaction is typically monitored through the discontinuous malachite green phosphate assay or, more rarely, through a continuous assay that couples phosphate release to the phosphorolysis of a chromogenic nucleoside by the enzyme purine nucleoside phosphorylase (PNP). These assays suffer from numerous drawbacks, and both rely on the detection of phosphate. We describe a new continuous assay that monitors the release of serine by exploiting bacterial serine acetyltransferase (SAT) as a reporter enzyme. SAT acetylates serine, consuming acetyl-CoA and releasing CoA-SH. CoA-SH spontaneously reacts with Ellman’s reagent to produce a chromophore that absorbs light at 412 nm. The catalytic parameters estimated through the SAT-coupled assay are fully consistent with those obtained with the published methods, but the new assay exhibits several advantages. Particularly, it depletes L-serine, thus allowing more prolonged linearity in the kinetics. Moreover, as the SAT-coupled assay does not rely on phosphate detection, it can be used to investigate the inhibitory effect of phosphate on PSP.

A platform for multiplexed colorimetric microRNA detection using shape-encoded hydrogel particles

Shape-encoded hydrogel particles enable multiplexed, colorimetric microRNA detection with a cell-phone by utilizing a reporter enzyme, which produces a chromogenic precipitate.

Phage-based biosensors: in vivo analysis of native T4 phage promoters to enhance reporter enzyme expression

Phage-based biosensors have shown significant promise in meeting the present needs of the food and agricultural industries due to a combination of sufficient portability, speed, ease of use, sensitivity, and low production cost.

Transmembrane signaling on a protocell: Creation of receptor-enzyme chimeras for immunodetection of specific antibodies and antigens

It is known that digital counting of fluorescent signals generated in many small compartments can significantly improve the detection sensitivity of the enzyme-linked immunosorbent assay (ELISA). However, the reported digital ELISA systems need extensive washing steps to remove background signal, which hampers their performance. To tackle this problem, we developed a vesicle (Protocell) array wherein binding of an external protein analyte is coupled to signal amplification and intra-vesicular fluorescence readout. We chose β-glucuronidase (GUS) as a reporter enzyme as its function requires assembly of four subunits through dimerization of a pair of dimers that can be inhibited by a set of interface mutations. Using a thermostabilized GUS mutant IV-5, we screened out an interface mutant (M516K, F517W) to create IV5m - a mutant with high thermostability and activity conditional on induced dimerization. After tethering a short N-terminal tag and transmembrane (TM) sequences, the fusion protein was expressed by cell-free protein synthesis inside protocells. When a corresponding tag-specific antibody was applied outside of the protocells, a clear increase in GUS activity was observed inside vesicles by adding fluorescent substrate, probably due to spontaneous integration of the tagged TM protein into the vesicles and dimerization by the antibody bound to the displayed tag. Furthermore, using flow cytometry, quantitative digital read out was obtained by counting fluorescent protocells exposed to varying concentrations of external antibodies that included Trastuzumab. Additionally, through use of an anti-caffeine VHH-SpyCatcher fusion protein, caffeine could be detected using SpyTag-fused TM-IV5m protein expressed in protocells, suggesting utility of this platform for detection of diverse antigen types.

A modular steroid-inducible gene expression system for use in rice

Background Chemically inducible systems that provide both spatial and temporal control of gene expression are essential tools, with many applications in plant biology, yet they have not been extensively tested in monocotyledonous species. Results Using Golden Gate modular cloning, we have created a monocot-optimized dexamethasone (DEX)-inducible pOp6/LhGR system and tested its efficacy in rice using the reporter enzyme β-glucuronidase (GUS). The system is tightly regulated and highly sensitive to DEX application, with 6 h of induction sufficient to induce high levels of GUS activity in transgenic callus. In seedlings, GUS activity was detectable in the root after in vitro application of just 0.01 μM DEX. However, transgenic plants manifested severe developmental perturbations when grown on higher concentrations of DEX. The direct cause of these growth defects is not known, but the rice genome contains sequences with high similarity to the LhGR target sequence lacO, suggesting non-specific activation of endogenous genes by DEX induction. These off-target effects can be minimized by quenching with isopropyl β-D-1-thiogalactopyranoside (IPTG). Conclusions Our results demonstrate that the system is suitable for general use in rice, when the method of DEX application and relevant controls are tailored appropriately for each specific application.

Rapid Tuberculosis Diagnosis Using Reporter Enzyme Fluorescence

ABSTRACT Tuberculosis is the most frequent cause of death in humans from a single infectious agent. Due to low numbers of bacteria present in sputum during early infection, diagnosis does not usually occur until >3 to 4 months after symptoms develop. We created a new more sensitive diagnostic that can be carried out in 10 min with no processing or technical expertise. This assay utilizes the Mycobacterium tuberculosis-specific biomarker BlaC in reporter enzyme fluorescence (REF) that has been optimized for clinical samples, designated REFtb, along with a more specific fluorogenic substrate, CDG-3. We report the first evaluation of clinical specimens with REFtb assays in comparison to the gold standards for tuberculosis diagnosis, culture and smear microscopy. REFtb assays allowed diagnosis of 160 patients from 16 different countries with a sensitivity of 89% for smear-positive, culture-positive samples and 88% for smear-negative, culture-positive samples with a specificity of 82%. The negative predictive value of REFtb for tuberculosis infection is 93%, and the positive predictive value is 79%. Overall, these data point toward the need for larger accuracy studies by third parties using a commercially available REFtb kit to determine whether incorporation of REFtb into the clinical toolbox for suspected tuberculosis patients would improve case identification. If results similar to our own can be obtained by all diagnostic laboratories, REFtb would allow proper treatment of more than 85% of patients that would be missed during their initial visit to a clinic using current diagnostic strategies, reducing the potential for further spread of disease.

Beta-Glucuronidase (GusA) reporter enzyme assay for Escherichia coli

The beta-Glucuronidase (GusA) is a long-known reporter enzyme for many different species [1]. The E. coli gusA gene is often used in plant research because plants lack an endogenous gusA gene. In E. coli, the transcript of the gusA gene is more stable than that of the highly used reporter gene beta-galactosidase (lacZ) [2]. The GusA activity can be determined using the artificial substrate p-nitrophenyl-β-D-glucopyranosid (pNPG). pNPG is converted to glucoronic acid and para-nitrophenol (pNP), which can be quantified spectrometrically at 405 nm. To avoid background, it is best to use an E. coli strain with a deletion of the chromosomal gusA gene, which is available e.g. at the Keio collection [3]. The gusA gene can be used for transcriptional fusions, e.g. to characterize promoters, and also for translational fusions, e.g. to study translational regulation. The assay was adapted to the microtiter plate format to enable the parallel handling of a large number of samples. The “procedure” (see below) describes an application with the gusA gene in a translational fusion with the gene of interest cloned under the control of the inducible arabinose promoter PBAD.