Attomol-level ATP bioluminometer for detecting single bacterium.

We have developed an automated high-sensitive ATP bioluminometer for detecting single bacterium. The apparatus consists of a tube rack for setting reagents and samples, two washing baths for preventing sample carry-over from dispenser nozzle, and x-, y-, z- actuators for moving the dispenser, and an high-sensitive optical system. The reaction tube was selected to reduce the background signal intensities for the ATP bioluminescence measurement. The background signal intensity of the reaction tube was 18 RLU, which is almost the same as the dark counts of the photomultiplier (16 RLU). The ATP calibration curve was linear from 0 to 5 amol (its slope = 22.4 RLU/amol and 3.3 SD of the blank sample signal = 17.9 RLU), and the detection limit of 0.8 amol was obtained. The relationship between intracellular ATP and CFU in Escherichia coli (ATCC25922) was kept linearity from 0 to 20 CFU, and the intracellular ATP (amol) per CFU was calculated to be 3.3 amol/CFU (R2 = 0.9713). Moreover, the relationship between intracellular ATP and CFU in Staphylococcus aureus (ATCC25923) was also kept linearity from 0 to 30 CFU, and the amol/CFU was calculated to be 1.6 amol/CFU (R2 = 0.9847). The automated ATP bioluminometer has ultra-high sensitivity and will be a powerful tool for measuring ATP luminescence derived from small number of bacteria.

Facile bead-to-bead cell-transfer method for serial subculture and large-scale expansion of human mesenchymal stem cells in bioreactors.

The conventional planar culture of adherent cells is inefficient for large-scale manufacturing of cell and gene therapy products. We developed a facile and efficient bead-to-bead cell-transfer method for serial subculture and large-scale expansion of human mesenchymal stem cells (hMSCs) with microcarriers in bioreactors. We first compared culture medium with and without nucleosides and found the former maintained the expression of surface markers of hMSCs during their prolonged culture and enabled faster cell proliferation. Subsequently, we developed our bead-to-bead cell transfer method to subculture hMSCs and found that intermittent agitation after adding fresh microcarriers to cell-populated microcarriers could promote spontaneous cell migration to fresh microcarriers, reduce microcarrier aggregation, and improve cell yield. This method enabled serial subculture of hMSCs in spinner flasks from passage 4 to passage 9 without using proteolytic enzymes, which showed faster cell proliferation than the serial planar cultures undergoing multiple enzyme treatment. Finally, we used the medium containing nucleosides and our bead-to-bead cell transfer method for cell culture scale-up from 4- to 50-L cultures in single-use bioreactors. We achieved a 242-fold increase in the number of cells to 1.45 × 1010 after 27-day culture and found that the cells harvested from the bioreactors maintained proliferation ability, expression of their surface markers, tri-lineage differentiation potential and immunomodulatory property. This study shows the promotive effect of nucleosides on hMSC expansion and the potential of using our bead-to-bead transfer method for larger-scale manufacturing of hMSCs for cell therapy.

Nuclear transplantation between allogeneic cells through topological reconnection of plasma membrane in a microfluidic system.

Previous studies have demonstrated that somatic cells fused with pluripotent stem cells can be reprogrammed on the basis of reprogramming factors acquired from the latter. However, fusion-reprogrammed cells are deemed unsuitable for therapeutic applications mainly because conventional fusion techniques often yield tetraploid fusants that contain exogenous genes acquired from the fusion partners. Here, we present a novel cell-cell topological reconnection technique and demonstrate its application to nuclear transplantation between a somatic cell and a stem cell without nuclei mixing. As a proof of concept, a microfluidic fusion chip embodied with a microslit (4 µm in width) to prevent nuclei mixing was developed and used to perform one-to-one electrofusion of a target somatic cell (Jurkat cell) with an induced pluripotent stem (iPS) cell. To extract its cytoplasm, the target cell was first topologically connected to a sacrificial iPS cell by electrofusion via a microslit, followed by shear flow removal of the latter to obtain a cytoplasm-depleted nucleus of the target cell. Then, to replace the lost cytoplasm, topological reconnection to a second iPS cell was performed similarly by electrofusion, followed by shear flow separation of the target cell to enable it acquire most of the iPS cytoplasm, but without nuclei mixing. Microscopic observation of target cells harvested and cultured post hoc in a microwell confirmed that they manifested cell division. Taken together, these results demonstrate the potential application of the cell-cell topological reconnection technique to somatic cell nuclear transplantation for the generation of autologous pluripotent stem cells.

Diamines prevent thermal aggregation and inactivation of lysozyme.

Protein aggregation is a major obstacle in both biological applications and biomedical fields involving proteins. In this study, we investigated the essential structure of small additives that function as chemical chaperones. Aggregation-suppressing competent additives were 1,3-diaminopropane, 1,4-diaminobutane, and 1,5-diaminopentane, which suppressed aggregation in the given order; whereas no diols or monoamines prevented the thermal aggregation and the inactivation of lysozyme. The heat-inactivation rate of lysozyme with 1,3-diaminopropane was almost identical to that of lysozyme with spermine and arginine ethylester, which are the most prominent additives reported yet.

Equilibrium and kinetic stability of a hyperthermophilic protein, O6-methylguanine-DNA methyltransferase under various extreme conditions.

In this work we have studied the equilibrium and kinetic stability of a hyperthermophilic protein, O(6)-methylguanine-DNA methyltransferase (Tk-MGMT), and its mesophilic counterpart AdaC, in various chemical solutions. In an unfolding experiment using guanidine hydrochloride (GdnHCl), the unfolding free-energy change of Tk-MGMT at 30 degrees C was 42.0 kJ mol(-1), and the half time for unfolding was 4.5 x 10(6) s, which is much slower than that of AdaC and representative mesophilic proteins. In unfolding experiments using methanol, ethanol, 2-propanol, trifluoroethanol (TFE), and sodium dodecyl sulfate (SDS), Tk-MGMT retained its native structure at high concentrations, despite the fact that these chemical solutions affect protein conformations in a number of different ways. Kinetic studies using TFE and SDS indicate that the unfolding rates of Tk-MGMT in these solutions are slow as in GdnHCl. Further, the results of a mutational experiment suggest that an ion-pair network plays a key role in this slow unfolding. This slow rate of unfolding under extreme conditions is a significant property that distinguishes Tk-MGMT from mesophilic proteins.