Faithful expression of transgenes in cell cultures and mice is often challenged by locus dependent epigenetic silencing. We investigated silencing of Tet-controlled expression cassettes within the mouse ROSA26 locus. We observed pronounced DNA methylation of the Tet promoter concomitant with loss of expression in mES cells as well as in differentiated cells and transgenic animals. Strikingly, the ROSA26 promoter remains active and methylation free indicating that this silencing mechanism specifically affects the transgene, but does not spread to the host's chromosomal neighborhood. To reactivate Tet cassettes a synthetic fusion protein was constructed and expressed in silenced cells. This protein includes the enzymatic domains of ten eleven translocation methylcytosine dioxygenase 1 (TET-1) as well as the Tet repressor DNA binding domain. Expression of the synthetic fusion protein and Doxycycline treatment allowed targeted demethylation of the Tet promoter in the ROSA26 locus and in another genomic site, rescuing transgene expression in cells and transgenic mice. Thus, inducible, reversible and site-specific epigenetic modulation is a promising strategy for reactivation of silenced transgene expression, independent of the integration site.
Suppression of therapeutic transgene expression from retroviral gene therapy vectors by epigenetic defence mechanisms represents a problem that is particularly encountered in pluripotent stem cells (PSCs) and their differentiated progeny. Transgene expression in these cells, however, can be stabilised by CpG-rich ubiquitous chromatin opening elements (UCOEs). In this context we recently demonstrated profound anti-silencing properties for the small (679 bp) CBX3-UCO element and we now confirmed this observation in the context of the defined murine chromosomal loci ROSA26 and TIGRE. Moreover, since the structural basis for the anti-silencing activity of UCOEs has remained poorly defined, we interrogated various CBX3 subfragments in the context of lentiviral vectors and murine PSCs. We demonstrated marked though distinct anti-silencing activity in the pluripotent state and during PSC-differentiation for several of the CBX3 subfragments. This activity was significantly correlated with CpG content as well as endogenous transcriptional activity. Interestingly, also a scrambled CBX3 version with preserved CpG-sites retained the anti-silencing activity despite the lack of endogenous promoter activity. Our data therefore highlight the importance of CpG-sites and transcriptional activity for UCOE functionality and suggest contributions from different mechanisms to the overall anti-silencing function of the CBX3 element.
To date, no herpesvirus has been shown to latently persist in fibroblastic cells. Here, we show that murine cytomegalovirus, a β-herpesvirus, persists for the long term and across organs in PDGFRα-positive fibroblastic cells, with similar or higher genome loads than in the previously known sites of murine cytomegalovirus latency. Whereas murine cytomegalovirus gene transcription in PDGFRα-positive fibroblastic cells is almost completely silenced at 5 months post-infection, these cells give rise to reactivated virus ex vivo, arguing that they support latent murine cytomegalovirus infection. Notably, PDGFRα-positive fibroblastic cells also support productive virus replication during primary murine cytomegalovirus infection. Mechanistically, Stat1-deficiency promotes lytic infection but abolishes latent persistence of murine cytomegalovirus in PDGFRα-positive fibroblastic cells in vivo. In sum, fibroblastic cells have a dual role as a site of lytic murine cytomegalovirus replication and a reservoir of latent murine cytomegalovirus in vivo and STAT1 is required for murine cytomegalovirus latent persistence in vivo.
Mammalian first line of defense against viruses is accomplished by the interferon (IFN) system. Viruses have evolved numerous mechanisms to reduce the IFN action allowing them to invade the host and/or to establish latency. We generated an IFN responsive intracellular hub by integrating the synthetic transactivator tTA into the chromosomal Mx2 locus for IFN-based activation of tTA dependent expression modules. The additional implementation of a synthetic amplifier module with positive feedback even allowed for monitoring and reacting to infections of viruses that can antagonize the IFN system. Low and transient IFN amounts are sufficient to trigger these amplifier cells. This gives rise to higher and sustained—but optionally de-activatable—expression even when the initial stimulus has faded out. Amplification of the IFN response induced by IFN suppressing viruses is sufficient to protect cells from infection. Together, this interfaced sensor/actuator system provides a toolbox for robust sensing and counteracting viral infections.
The
expression of endogenous genes as well as transgenes depends
on regulatory elements within and surrounding genes as well as their
epigenetic modifications. Members of a cloned cell population often
show pronounced cell-to-cell heterogeneity with respect to the expression
of a certain gene. To investigate the heterogeneity of recombinant
protein expression we targeted cassettes into two preselected chromosomal
hot-spots in Chinese hamster ovary (CHO) cells. Depending on the gene
of interest and the design of the expression cassette, we found strong
expression variability that could be reduced by epigenetic modifiers,
but not by site-specific recruitment of the modulator dCas9-VPR. In
particular, the implementation of ubiquitous chromatin opening elements
(UCOEs) reduced cell-to-cell heterogeneity and concomitantly increased
expression. The application of this method to recombinant antibody
expression confirmed that rational design of cell lines for production
of transgenes with predictable and high titers is a promising approach.
Latent cytomegalovirus (CMV) infections affect most of the human population, yet our understanding of the cell types that carry latent CMV in vivo remains limited. Here, using the mouse model of latent CMV infection, we comprehensively assessed the prevalence of latent mouse CMV (MCMV) genomes in highly purified populations of fibroblasts, endothelial cells and tissue-resident macrophages across multiple organs upon two distinct infection routes. We describe organ-specific and infection route-specific patterns of viral genome distribution in tissue-resident cells. Strikingly, PDGFRα+ fibroblasts contained the highest MCMV genome load in most organs and conditions analysed. Lytic gene expression was almost completely silenced with only few stochastic transcripts, but the virus ex vivo reactivation from PDGFRα+ fibroblasts was consistent and reproducible, arguing that this cell type supports latent infection. Importantly, the same PDGFRα+ fibroblasts supported also the productive MCMV infection in vivo. In sum, these results reveal a role for non-hematopoietic fibroblastic cells as a common site of both lytic MCMV replication and latency in vivo.
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