Regulatory T-cells (Tregs) are important modulators of the immune system through their intrinsic suppressive functions. Systemic adoptive transfer of ex vivo expanded Tregs has been extensively investigated for allogeneic transplantation. Due to the time-consuming and costly expansion protocols of Tregs, more targeted approaches could be beneficial. The encapsulation of human natural and induced Tregs for localized immunosuppression is described for the first time. Tregs encapsulated in alginate-gelatin methacryloyl hydrogel remain viable, phenotypically stable, functional, and confined in the structure. Supplementation of the hydrogel with the Treg-specific bioactive factors interleukin-2 and chemokine ligand 1 improves Treg viability, suppressive phenotype, and function, and attracts to the structure CCR8 + T-cells enriched with anti-inflammatory subpopulations, including Tregs, from human peripheral blood. Furthermore, these findings are applicable to 3D bioprinting. Co-axial printing of murine pancreatic islets with human natural and induced Tregs protects the islets from xenoresponse upon co-culture with human peripheral blood mononuclear cells. This establishes the co-encapsulation of Tregs by co-axial 3D bioprinting as a valid option for providing local immune protection to allogeneic cellular transplants such as pancreatic islets.
The higher-order structural organization and dynamics of the chromosomes play a central role in gene regulation. To explore this structure-function relationship, it is necessary to directly visualize genomic elements in living cells. Genome imaging based on the CRISPR system is a powerful approach but has limited applicability due to background signals and nonspecific aggregation of fluorophores within nuclei. To address this issue, we developed a novel visualization scheme combining tripartite fluorescent proteins with the SunTag system and demonstrated that it strongly suppressed background fluorescence and amplified locus-specific signals, allowing long-term tracking of genomic loci. We integrated the multicomponent CRISPR system into stable cell lines to allow quantitative and reliable analysis of dynamic behaviors of genomic loci. Due to the greatly elevated signal-to-background ratio, target loci with only small numbers of sequence repeats could be successfully tracked, even under a conventional fluorescence microscope. This feature enables the application of CRISPR-based imaging to loci throughout the genome and opens up new possibilities for the study of nuclear processes in living cells.
The foremost event of bacteriophage infection is the ejection of genomic DNA into the host bacterium after virus binding to surface receptor sites. The DNA ejection triggering mechanism is yet largely unknown. We investigated the role of mechanical force in triggering DNA ejection of the T7 bacteriophage.
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