Application Settings versus Fixed Photomultiplier Tube Voltages for Optimal Cytometer Stability over Time, and Effect on Reusing a Compensation Matrix.

In flow cytometry, a compensation matrix is commonly reused over time, especially in clinical laboratories, to save time and reagents. However, generating a same-day compensation matrix is considered the best practice by many experts. BD Biosciences developed Cytometer Setup and Tracking software to deliver proper instrument characterization, performance tracking, and stability. BD's "Application Settings" enable daily cytometer adjustments of photomultiplier tube (PMT) settings to correct for day-to-day variations in instrument performance. Here, we investigated if using Application Settings would improve data stability over time, including the impact on data stability when reusing a compensation matrix. We consecutively analyzed peripheral blood mononuclear cell (PBMC) aliquots from a single healthy donor together with 8-peak Rainbow beads and daily compensation controls (22 runs in total over 6.5 months). We found larger variation within both PBMC subset quantifications and median fluorescence intensity (MFI) levels when using Application Settings (i.e., daily adjusted PMTs) compared to fixed PMT voltages (both with the same Day 0 compensation matrix applied). This larger variation was partly due to errors in compensation, but was also seen for Rainbow beads MFI data (not impacted by compensation), and thus likely produced by imprecise adjustments of PMTs by Applications Settings. Notably, the larger variation observed with Application Settings was most pronounced on a few days of the experiment with very large deviations, whereas on most days Application Settings and Fixed PMTs performed similar. The present results call for caution in using Application Settings in longitudinal studies, especially if also reusing a compensation matrix. In contrast, reusing a compensation matrix over time with fixed PMT voltages yielded stable results comparable with running same-day compensation controls. © 2020 International Society for Advancement of Cytometry.

Improved microRNA suppression by WPRE-linked tough decoy microRNA sponges.

Our genes are post-transcriptionally regulated by microRNAs (miRNAs) inducing translational suppression and degradation of targeted mRNAs. Strategies to inhibit miRNAs in a spatiotemporal manner in a desired cell type or tissue, or at a desired developmental stage, can be crucial for understanding miRNA function and for pushing forward miRNA suppression as a feasible rationale for genetic treatment of disease. For such purposes, RNA polymerase II (RNA Pol II)-transcribed tough decoy (TuD) miRNA inhibitors are particularly attractive. Here, we demonstrate augmented miRNA suppression capacity of TuD RNA hairpins linked to the Woodchuck hepatitis virus post-transcriptional regulatory element (WPRE). This effect is position-dependent and evident only when the WPRE is positioned upstream of the TuD. In accordance, inclusion of the WPRE does not change nuclear export, translation, total levels of TuD-containing RNA transcripts, or cytoplasmic P-body localization, suggesting that previously reported WPRE functions are negligible for improved TuD function. Notably, deletion analysis of TuD-fused WPRE unveils truncated WPRE variants resulting in optimized miRNA suppression. Together, our findings add to the guidelines for production of WPRE-supported anti-miRNA TuDs.

Practicalities of Cell Sorting.

Cell sorting is a technique commonly used in academic and biotechnology laboratories in order to separate out cells or particles of interest from heterogeneous populations. Cell sorters use the same principles as flow cytometry analyzers, but instead of cell populations passing to the waste of the instrument, they can be collected for further studies including DNA sequencing as well as other genomic, in vitro and in vivo experiments. This chapter aims to give an overview of cell sorting, the different types of cell sorters, details on how a cell sorter works, as well as protocols that are useful when embarking on a journey with cell sorting.

Interleukin-21 restrains tumor growth and induces a substantial increase in the number of circulating tumor-specific T cells in a murine model of malignant melanoma.

New strategies of immunotherapy are currently being evaluated, and the combination of chemo- and immunotherapy has shown promising results. The cytokine interleukin-21 (IL-21) is known to enhance immune function, and in this study we have investigated its ability to boost the efficacy of chemoimmunotherapy-cyclophosphamide and adoptive cell transfer (ACT)-in the B16-OVA/OT-I murine model of malignant melanoma. Subcutaneous B16-OVA tumors were established in C57BL/6J mice 8 days before adoptive transfer of tumor-specific OT-I T cells. In addition to cyclophosphamide and ACT, one group of mice received daily injections of murine IL-21 (mIL-21). Mice treated with mIL-21 had more tumor-specific T cells in the circulation 4 and 7 days following ACT (P=0.004 and P=0.002, respectively). Importantly, mIL-21 and ACT controlled tumor growth instantly and more effectively than ACT alone (P=0.001, day 4)-an effect that persisted up to 5 days after the last mIL-21 injection. We conclude that mIL-21 enhances chemoimmunotherapy: it amplifies the number of tumor-specific T cells in the circulation and also stunts early tumor growth.

Boron nanoparticles inhibit tumour growth by boron neutron capture therapy in the murine B16-OVA model.

BACKGROUND: Boron neutron capture therapy usually relies on soluble, rather than particulate, boron compounds. This study evaluated the use of a novel boron nanoparticle for boron neutron capture therapy. MATERIALS AND METHODS: Two hundred and fifty thousand B16-OVA tumour cells, pre-incubated with boron nanoparticles for 12 hours, were injected subcutaneously into C57BL/6J mice. The tumour sites were exposed to different doses of neutron radiation one, four, or eight days after tumour cell inoculation. RESULTS: When the tumour site was irradiated with thermal neutrons one day after injection, tumour growth was delayed and the treated mice survived longer than untreated controls (median survival time 20 days (N = 8) compared with 10 days (N = 7) for untreated mice). CONCLUSION: Boron nanoparticles significantly delay the growth of an aggressive B16-OVA tumour in vivo by boron neutron capture therapy.

The B1-cell subpopulation is diminished in patients with relapsing-remitting multiple sclerosis.

B cell subsets in newly diagnosed untreated, relapsing-remitting multiple sclerosis (MS) patients were examined. The fraction of CD20(+) B cells was significantly increased in MS. Among subsets of B cells, MS patients had increased frequency of naïve cells, but reduced frequency of memory and B1 cells. The frequencies of B1 cells were inversely correlated with the time since last attack. B1 cells resembled the phenotype of either lymphocytes (CD11b(-) B1 cells) or monocytes (CD11b(+) B1 cells) and a small fraction of cells was CD3(+)CD20(+) by confocal microscopy.

A simple method for deriving functional MSCs and applied for osteogenesis in 3D scaffolds.

We describe a simple method for bone engineering using biodegradable scaffolds with mesenchymal stem cells derived from human induced-pluripotent stem cells (hiPS-MSCs). The hiPS-MSCs expressed mesenchymal markers (CD90, CD73, and CD105), possessed multipotency characterized by tri-lineages differentiation: osteogenic, adipogenic, and chondrogenic, and lost pluripotency - as seen with the loss of markers OCT3/4 and TRA-1-81 - and tumorigenicity. However, these iPS-MSCs are still positive for marker NANOG. We further explored the osteogenic potential of the hiPS-MSCs in synthetic polymer polycaprolactone (PCL) scaffolds or PCL scaffolds functionalized with natural polymer hyaluronan and ceramic TCP (PHT) both in vitro and in vivo. Our results showed that these iPS-MSCs are functionally compatible with the two 3D scaffolds tested and formed typically calcified structure in the scaffolds. Overall, our results suggest the iPS-MSCs derived by this simple method retain fully osteogenic function and provide a new solution towards personalized orthopedic therapy in the future.