Adhesion patterning by a novel air-lock technique enables localization and in-situ real-time imaging of reprogramming events in one-to-one electrofused hybrids.

Although fusion of somatic cells with embryonic stem (ES) cells has been shown to induce reprogramming, single-cell level details of the transitory phenotypic changes that occur during fusion-based reprogramming are still lacking. Our group previously reported on the technique of one-to-one electrofusion via micro-slits in a microfluidic platform. In this study, we focused on developing a novel air-lock patterning technique for creating localized adhesion zones around the micro-slits for cell localization and real-time imaging of post fusion events with a single-cell resolution. Mouse embryonic fibroblasts (MEF) were fused individually with mouse ES cells using a polydimethylsiloxane (PDMS) fusion chip consisting of two feeder channels with a separating wall containing an array of micro-slits (slit width ∼3 µm) at a regular spacing. ES cells and MEFs were introduced separately into the channels, juxtaposed on the micro-slits by dielectrophoresis and fused one-to-one by a pulse voltage. To localize fused cells for on-chip culture and time-lapse microscopy, we implemented a two-step approach of air-lock bovine serum albumin patterning and Matrigel coating to create localized adhesion areas around the micro-slits. As a result of time-lapse imaging, we could determine that cell division occurs within 24 h after fusion, much earlier than the 2-3 days reported by earlier studies. Remarkably, Oct4-GFP (Green Fluorescent Protein) was confirmed after 25 h of fusion and thereafter stably expressed by daughter cells of fused cells. Thus, integrated into our high-yield electrofusion platform, the technique of air-lock assisted adhesion patterning enables a single-cell level tracking of fused cells to highlight cell-level dynamics during fusion-based reprogramming.

Microorifice-based high-yield cell fusion on microfluidic chip: electrofusion of selected pairs and fusant viability.

Microorifice-based fusion makes use of electric field constriction to assure high-yield one-to-one fusion of selected cell pairs. The aim of this paper is to verify feasibility of high-yield cell fusion on a microfluidic chip. This paper also examines viability of the fusant created on the chip. We fabricated a microfluidic chip to fuse selected cell pairs and to study postfusion behavior. We used a self-forming meniscus-based fabrication process to create microorifice with a diameter of 2-10 microm on the vertical walls in a microfluidic channel. When 1 MHz was applied to electrodes located on both sides of the microorifice, dielectrophoretic force attracted the cells toward microorifice to form a cell pair. Once the cells get into contact, fusion pulse was applied. Real time imaging of cells during fusion and cytoplasmic dye transfer between cells indicated success of cell fusion. We found that when high frequency voltage for dielectrophoresis was swept from 1 MHz to 10 kHz in 100 micros, cell fusion was initiated. The effective electric field strength was 0.1-0.2 kV/cm. We analyzed viability by imaging fusant going into cell division phase after 48 h of incubation. We conclude that fabricated microfluidic chip is suitable for high-yield one-to-one fusion and creation of viable fusants. This technology should be a useful tool to study fusion phenomena and viability of fusants, as it allows imaging of the cells during and after the fusion.

High-yield electrofusion of biological cells based on field tailoring by microfabricated structures.

The authors present the use of electric-field constriction created by a microfabricated structure to realise high-yield electrofusion of biological cells. The method uses an orifice on an electrically insulating wall (orifice plate) whose diameter is as small as that of the cells. Owing to the field constriction created by the orifice, we can induce the controlled magnitude of membrane voltage selectively around the contact point, regardless of the cell size. The field constriction also ensures 1:1 fusion even when more than two cells are forming a chain at the orifice. A device for electrofusion has been made with a standard SU-8 lithography and PDMS molding, and real-time observation of the electrofusion process is made. Experiments using plant protoplasts or mammalian cells show that the process is highly reproducible, and the yield higher than 90% is achieved.

Long-term use of mizoribine in rheumatoid arthritis patients on hemodialysis.

Abstract Small doses of mizoribine (MZR) were administered to five rheumatoid arthritis (RA) patients on hemodialysis (HD). A maintenance dose of 25 mg or less was administered either once per day or once following HD. The Lansbury activity index improved in all patients. The blood concentrations of MZR before and after HD were 0.33-1.79 µg/ml and 0-0.93 µg/ml, respectively. Hence, the rate of elimination by HD ranged from 50.3% to 83.4%. As far as side effects were concerned, alopecia was seen in two patients, and one patient developed shingles. However, the severity of these symptoms was mild and, after discontinuing or reducing the dose of MZR for a certain period of time, we were able to continue its administration. These findings suggest that the long-term administration of MZR is a useful treatment for RA patients on HD.

Direct measurement of DNA by means of AFM.

We have demonstrated that the electrostatic stretch-and-positioning method is useful for the analysis of a long DNA molecule by means of atomic force microscopy (AFM). DNA molecules were stretched parallel to the field line, and immobilized onto the aluminum electrodes patterned on a glass plate. Through AFM observation, we confirmed the immobilization of individual DNA molecules, not aggregate.

Visualization of single molecules of RNA polymerase sliding along DNA.

Transcription requires that RNA polymerase binds to promoters buried in nonspecific sites on DNA. The search for promoters may be facilitated if the polymerase slides along the molecule of DNA. Single molecules of Escherichia coli RNA polymerase were visualized, and their movements on immobilized bacteriophage lambda and T7 DNAs were examined. Deviating from drifts by bulk flow, about 40 percent of the enzyme molecules moved along the extended DNA. The results provide direct evidence for sliding as a mechanism for relocation of the enzyme on DNA.