Reactivation of Epstein-Barr virus by a dual-responsive fluorescent EBNA1-targeting agent with Zn2+-chelating function.

Epstein-Barr nuclear antigen 1 (EBNA1) plays a vital role in the maintenance of the viral genome and is the only viral protein expressed in nearly all forms of Epstein-Barr virus (EBV) latency and EBV-associated diseases, including numerous cancer types. To our knowledge, no specific agent against EBV genes or proteins has been established to target EBV lytic reactivation. Here we report an EBNA1- and Zn2+-responsive probe (ZRL5P4) which alone could reactivate the EBV lytic cycle through specific disruption of EBNA1. We have utilized the Zn2+ chelator to further interfere with the higher order of EBNA1 self-association. The bioprobe ZRL5P4 can respond independently to its interactions with Zn2+ and EBNA1 with different fluorescence changes. It can selectively enter the nuclei of EBV-positive cells and disrupt the oligomerization and oriP-enhanced transactivation of EBNA1. ZRL5P4 can also specifically enhance Dicer1 and PML expression, molecular events which had been reported to occur after the depletion of EBNA1 expression. Importantly, we found that treatment with ZRL5P4 alone could reactivate EBV lytic induction by expressing the early and late EBV lytic genes/proteins. Lytic induction is likely mediated by disruption of EBNA1 oligomerization and the subsequent change of Dicer1 expression. Our probe ZRL5P4 is an EBV protein-specific agent that potently reactivates EBV from latency, leading to the shrinkage of EBV-positive tumors, and our study also suggests the association of EBNA1 oligomerization with the maintenance of EBV latency.

A CRISP(e)R view on kidney organoids allows generation of an induced pluripotent stem cell-derived kidney model for drug discovery.

Development of physiologically relevant cellular models with strong translatability to human pathophysiology is critical for identification and validation of novel therapeutic targets. Herein we describe a detailed protocol for generation of an advanced 3-dimensional kidney cellular model using induced pluripotent stem cells, where differentiation and maturation of kidney progenitors and podocytes can be monitored in live cells due to CRISPR/Cas9-mediated fluorescent tagging of kidney lineage markers (SIX2 and NPHS1). Utilizing these cell lines, we have refined the previously published procedures to generate a new, higher throughput protocol suitable for drug discovery. Using paraffin-embedded sectioning and whole-mount immunostaining, we demonstrated that organoids grown in suspension culture express key markers of kidney biology (WT1, ECAD, LTL, nephrin) and vasculature (CD31) within renal cortical structures with microvilli, tight junctions and podocyte foot processes visualized by electron microscopy. Additionally, the organoids resemble the adult kidney transcriptomics profile, thereby strengthening the translatability of our in vitro model. Thus, development of human nephron-like structures in vitro fills a major gap in our ability to assess the effect of potential treatment on key kidney structures, opening up a wide range of possibilities to improve clinical translation.

The aldehyde dehydrogenase cord blood potency assay excludes early apoptotic cells.

BACKGROUND: Cord blood units (CBUs) are processed, frozen, and thawed before use in hematopoietic stem cell (HSC) transplantation. The manipulations affect HSC functionality, that is, induce apoptosis and reduce viability. HSC content, commonly expressed as CBU potency, that is, the expected ability of a CBU to restore hematopoiesis, is traditionally approximated through viable CD34+ cells and the colony-forming unit (CFU) cell cultivation assay. Alternative approaches, for example, the aldehyde dehydrogenase (ALDH) enzyme-based assay, are also forthcoming. We hypothesized that the ALDH assay might exclude apoptotic cells since it is based on enzyme activity. To investigate this, we designed a protocol for simultaneous staining of viable and apoptotic CD34+ and ALDH+ cells using 7-aminoactinomycin (7-AAD) and annexin V, in frozen-thawed CBUs. Results were correlated with results from the colony-forming unit-granulocyte/macrophage (CFU-GM) assay. STUDY DESIGN AND METHODS: Samples from 57 CBUs were thawed and simultaneously analyzed for CD34+ cells, ALDH+ cells, viability (7-AAD), and apoptosis (annexin V) using flow cytometry. Enumeration of CFUs was also performed. RESULTS: No nonviable and few apoptotic cells (mean 0.7%) were identified in the ALDH+ population compared to the viable CD34+ population (mean 3.6%). The total number of ALDH+ cells correlated better than viable CD34+ cells (r = 0. 72 vs. r = 0.66; p < 0.0001) with the results of the CFU assay. CONCLUSION: The ALDH assay excludes nonviable and apoptotic cells, and therefore correlates better with CFU enumeration compared to the number of viable CD34+ cells. We propose that the ALDH assay might replace the CFU-GM method in CBU potency measurements.

Amyloid precursor protein expression and processing are differentially regulated during cortical neuron differentiation.

Amyloid precursor protein (APP) and its cleavage product amyloid ß (Aß) have been thoroughly studied in Alzheimer's disease. However, APP also appears to be important for neuronal development. Differentiation of induced pluripotent stem cells (iPSCs) towards cortical neurons enables in vitro mechanistic studies on human neuronal development. Here, we investigated expression and proteolytic processing of APP during differentiation of human iPSCs towards cortical neurons over a 100-day period. APP expression remained stable during neuronal differentiation, whereas APP processing changed. α-Cleaved soluble APP (sAPPα) was secreted early during differentiation, from neuronal progenitors, while ß-cleaved soluble APP (sAPPß) was first secreted after deep-layer neurons had formed. Short Aß peptides, including Aß1-15/16, peaked during the progenitor stage, while processing shifted towards longer peptides, such as Aß1-40/42, when post-mitotic neurons appeared. This indicates that APP processing is regulated throughout differentiation of cortical neurons and that amyloidogenic APP processing, as reflected by Aß1-40/42, is associated with mature neuronal phenotypes.

Exploring the heterogeneity of the hematopoietic stem and progenitor cell pool in cord blood: simultaneous staining for side population, aldehyde dehydrogenase activity, and CD34 expression.

BACKGROUND: The stem cell content in cord blood (CB) units is routinely assessed regarding nucleated cells, CD34+ cell count, and number of colony-forming units (CFUs). Efforts are made toward finding better ways of defining stemness of CB units. Side population (SP) phenotype and activity of aldehyde dehydrogenase (ALDH) are functional markers of stemness that can be assayed using flow cytometry. STUDY DESIGN AND METHODS: We have developed a protocol for simultaneous determination of CD34+, SP, and ALDH+ populations in relation to immature white blood cells (CD45dim) in CB. Viable nucleated cells were consecutively stained for SP and ALDH activity and with antibodies against the CD45, CD34, and CD117 antigens. RESULTS: The SP and ALDH+ populations could reliably be measured simultaneously. The median sizes of the SP and the ALDH+ populations were 0.85 and 3.3% of CD45dim cells, respectively. There was no overlap between the SP and ALDH+ populations. Cells that were ALDH+ expressed CD34 and CD117, but SP cells were negative for these markers. The ALDH+ cell content correlated with CD34+ cell content (p < 0.001) and with CFU-granulocyte-macrophage (GM; p = 0.03) but not with total CFUs. SP did not correlate with CD34+, CFU-GM, or total CFU. CONCLUSIONS: We show that simultaneous detection of the CD34, SP, and ALDH+ cells is clearly feasible using only small amounts of CB. In CB, ALDH+, and CD34+ cells are overlapping populations distinctly separated from the SP population. The difference in relation to the capacity for colony growth between ALDH+ and SP underlines that they define different cell populations.

Footprint-free human induced pluripotent stem cells from articular cartilage with redifferentiation capacity: a first step toward a clinical-grade cell source.

Human induced pluripotent stem cells (iPSCs) are potential cell sources for regenerative medicine; however, clinical applications of iPSCs are restricted because of undesired genomic modifications associated with most reprogramming protocols. We show, for the first time, that chondrocytes from autologous chondrocyte implantation (ACI) donors can be efficiently reprogrammed into iPSCs using a nonintegrating method based on mRNA delivery, resulting in footprint-free iPSCs (no genome-sequence modifications), devoid of viral factors or remaining reprogramming molecules. The search for universal allogeneic cell sources for the ACI regenerative treatment has been difficult because making chondrocytes with high matrix-forming capacity from pluripotent human embryonic stem cells has proven challenging and human mesenchymal stem cells have a predisposition to form hypertrophic cartilage and bone. We show that chondrocyte-derived iPSCs can be redifferentiated in vitro into cartilage matrix-producing cells better than fibroblast-derived iPSCs and on par with the donor chondrocytes, suggesting the existence of a differentiation bias toward the somatic cell origin and making chondrocyte-derived iPSCs a promising candidate universal cell source for ACI. Whole-genome single nucleotide polymorphism array and karyotyping were used to verify the genomic integrity and stability of the established iPSC lines. Our results suggest that RNA-based technology eliminates the risk of genomic integrations or aberrations, an important step toward a clinical-grade cell source for regenerative medicine such as treatment of cartilage defects and osteoarthritis.

Evaluation of an in vitro faecal degradation method for early assessment of the impact of colonic degradation on colonic absorption in humans.

The objective of this study was to develop and evaluate an in vitro method to investigate bacterial-mediated luminal degradation of drugs in colon in humans. This would be a valuable tool for the assessment of drug candidates during early drug development, especially for compounds intended to be developed as oral extended release formulations. Freshly prepared faecal homogenate from healthy human volunteers (n=3-18), dog (n=6) and rat (colon and caecal content, n=3) was homogenised with 3.8 parts (w/w) physiological saline under anaerobical conditions. Four model compounds (almokalant, budesonide, ximelagatran and metoprolol) were then incubated (n=3-18) separately in the human faecal homogenate for up to 120min at 37°C. In addition, ximelagatran was also incubated in the faecal or colonic content from dog and rat. The mean (±SD) in vitro half-life for almokalant, budesonide and ximelagatran was 39±1, 68±21 and 26±12min, respectively, in the human faecal homogenate. Metoprolol was found to be stable in the in vitro model. The in vitro degradation data was then compared to literature data on fraction absorbed after direct colon administration in humans. The percentage of drug remaining after 60min of in vitro incubation correlated (R(2)=0.90) with the fraction absorbed from colon in humans. The mean in vitro half-life of ximelagatran was similar in human faeces (26±12min) and rat colon content (34±31min), but significantly (p<0.05) longer in rat caecum content (50±11min) and dog faeces (126±17min). The in vitro method is in vivo relevant both qualitatively as all the model drugs that undergoes colonic degradation in vivo was rapidly degraded in the faecal homogenates as well as quantitatively since a correlation was established between percentage degraded in vitro at 60min and fraction absorbed in the colon for the model drugs, which have no other absorption limiting properties. Also, the method is easy to use from a technical point of view, which suggests that the method is suitable for use in early assessment of colonic absorption of extended release formulation candidates. Further improvement of the confidence in the use of the method would either require an extension of the correlation, which most likely will require more human regional absorption studies, or by including colonic degradation rate as an input in a physiological mechanistic absorption model and evaluate if the prediction of the plasma exposure after colonic administration of the present model drugs is improved.

E2F1, ARID3A/Bright and Oct-2 factors bind to the Epstein-Barr virus C promoter, EBNA1 and oriP, participating in long-distance promoter-enhancer interactions.

The Epstein-Barr virus (EBV) C promoter (Cp) regulates several genes required for B-cell proliferation in latent EBV infection. The family of repeats (FR) region of the latent origin of plasmid replication (oriP) functions as an Epstein-Barr nuclear antigen 1 (EBNA1)-dependent distant enhancer of Cp activity, and the enhancer-promoter interaction is mediated by a higher-order multi-protein complex containing several copies of EBNA1. Using DNA-affinity purification with a 170 bp region of the Cp in combination with mass spectrometry, we identified the cell cycle-regulatory protein E2F1, the E2F-binding protein ARID3A, and the B-cell-specific transcription factor Oct-2 as components of this multi-protein complex. Binding of the three factors to the FR region of oriP was determined by DNA-affinity and immunoblot analysis. Co-immunoprecipitation and proximity ligation analysis revealed that the three factors, E2F1, ARID3A and Oct-2, interact with each other as well as with EBNA1 in the nuclei of EBV-positive cells. Using the chromatin immunoprecipitation assay, we showed that E2F1 and Oct-2 interacted with the FR part of oriP and the Cp, but the ARID3A interaction was, however, only detected at the Cp. Our findings support the hypothesis that EBNA1 initiates transcription at the Cp via interactions between multiple EBNA1 homodimers and cellular transcription factors in a large molecular machinery that forms a dynamic interaction between Cp and FR.

Multiple EBNA1-binding sites within oriPI are required for EBNA1-dependent transactivation of the Epstein-Barr virus C promoter.

The transactivating function of the oriPI-EBNA1 complex is essential for activation of the Epstein-Barr virus (EBV) C promoter (Cp) in lymphoblastoid cell lines expressing the viral growth programme. Furthermore, the oriPI-EBNA1 complex is believed to play an important role during promoter switching upon primary infection of B-lymphocytes and establishment of latent infection in vivo. Previously, it was shown that six EBNA1-binding sites within oriPI were required for transactivation of the heterologous thymidine kinase promoter. Here, we define the number of EBNA1-binding sites within oriPI necessary for its biological function as EBNA1-dependent Cp enhancer. We show that four EBNA1-binding sites within oriPI lead to significant upregulation of Cp in response to EBNA1 and eight or more to full activation. Thus, multiple EBNA1 homodimers at oriPI are required for the formation of a transcriptionally active Cp complex, a process that involves EBNA1-induced changes in the chromatin structure including DNA looping and nucleosome destabilization.

Functional interaction of nuclear factor y and sp1 is required for activation of the epstein-barr virus C promoter.

Two Epstein-Barr virus (EBV) latent cycle promoters, Wp and Cp, are activated sequentially during virus-induced transformation of primary B lymphocytes. Immediately postinfection, viral transcription initiates from Wp, leading to expression of EBV nuclear antigen 2 (EBNA2) and EBNA5. Within 36 h, there is a switch in promoter usage from Wp to the upstream Cp, which leads to expression of EBNA1 to EBNA6. EBNA2 appears to be required for the Wp-to-Cp switch, but the switching mechanism is not fully understood at the molecular level. In a previous investigation we showed that there is an EBNA2-independent activity of reporter constructs containing deletion fragments of Cp in B-lymphoid cell lines, and we demonstrated that Cp activity is highly dependent on several cellular transcription factors, including nuclear factor Y (NF-Y) and Sp1. In the present work, we analyzed the effect of NF-Y on Cp activity in greater detail. We demonstrate that (i) a dominant negative analogue of NF-Y abolishes Cp activity, (ii) NF-Y and Sp1 costimulate Cp, and (iii) the oriPI-EBNA1-induced transactivation of Cp requires concomitant expression of NF-Y and Sp1, although additional factors seem necessary for optimal activation. Furthermore, using the lymphoblastoid cell line EREB2-5, in which EBNA2 function is regulated by estrogen, we demonstrate that inactivation of EBNA2 results in decreased expression of NF-Y and down-regulation of Cp. On reconstitution of the EBNA2 function, the cells enter the cell cycle, NF-Y levels increase, and a concomitant Wp-to-Cp switch occurs. Taken together, our results suggest that NF-Y is essential for Cp activation and that up-regulation of NF-Y may contribute to a successful Wp-to-Cp switch during B-cell transformation.