Computational analysis of EBNA1 "druggability" suggests novel insights for Epstein-Barr virus inhibitor design.

The Epstein-Barr Nuclear Antigen 1 (EBNA1) is a critical protein encoded by the Epstein-Barr Virus (EBV). During latent infection, EBNA1 is essential for DNA replication and transcription initiation of viral and cellular genes and is necessary to immortalize primary B-lymphocytes. Nonetheless, the concept of EBNA1 as drug target is novel. Two EBNA1 crystal structures are publicly available and the first small-molecule EBNA1 inhibitors were recently discovered. However, no systematic studies have been reported on the structural details of EBNA1 "druggable" binding sites. We conducted computational identification and structural characterization of EBNA1 binding pockets, likely to accommodate ligand molecules (i.e. "druggable" binding sites). Then, we validated our predictions by docking against a set of compounds previously tested in vitro for EBNA1 inhibition (PubChem AID-2381). Finally, we supported assessments of pocket druggability by performing induced fit docking and molecular dynamics simulations paired with binding affinity predictions by Molecular Mechanics Generalized Born Surface Area calculations for a number of hits belonging to druggable binding sites. Our results establish EBNA1 as a target for drug discovery, and provide the computational evidence that active AID-2381 hits disrupt EBNA1:DNA binding upon interacting at individual sites. Lastly, structural properties of top scoring hits are proposed to support the rational design of the next generation of EBNA1 inhibitors.

Combination of Epstein-Barr virus nuclear antigen 1, 3 and lytic antigen BZLF1 peptide pools allows fast and efficient stimulation of Epstein-Barr virus-specific T cells for adoptive immunotherapy.

BACKGROUND: Epstein-Barr virus (EBV) infection is a major cause of morbidity following hematopoietic stem cell transplantation. EBV-infected B cells may not respond to rituximab treatment and may lead to a life-threatening post-transplantation lymphoproliferative disorder. Adoptive cellular immunotherapy using EBV-lymphoblastoid cell lines (LCL) as stimulating antigen has proved effective in restoring specific immunity. However, EBV presents several immunodominant antigens, and developing a swift and effective clinical-grade immunotherapy relies on the definition of a Good Manufacturing Practices (GMP) universal stimulating antigen. METHODS: Peripheral blood mononuclear cells (PBMCs) from six donors with a cellular immune response against EBV were immunoselected after stimulation with a new EBV antigen associated with an EBNA3 peptide pool. RESULTS: After immunoselection, a mean of 0.53 ± 0.25 × 106 cells was recovered consisting of a mean of 24.77 ± 18.01% CD4⁺-secreting interferon (IFN)-γ and 51.42 ± 26.92% CD8⁺-secreting IFN-γ. The T memory stem cell sub-population was identified. EBV-specific T cells were expanded in vitro, and their ability to secrete IFN-γ and to proliferate after re-stimulation with EBV antigen was confirmed. A specific lysis was observed against autologous target cells pulsed with EBV peptide pools (57.6 ± 11.5%) and against autologous EBV-LCL (18.3 ± 7.3%). A mean decrease of 94.7 ± 3.3% in alloreactivity against third-party donor mononuclear cells with EBV-specific T cells was observed compared with PBMCs before selection. CONCLUSIONS: Our results show that a combination of peptide pools including EBNA3 is needed to generate EBV-specific T cells with good specific cytotoxicity and devoid of alloreactivity, but as yet GMP grade is not fully achieved.

Application of a new human cell line, F2N78, in the transient and stable production of recombinant therapeutics.

Host cell lines developed by genetic engineering sometimes show instabilities in maintaining their genetically acquired phenotypes. Previously, a hybrid host cell line, designated as hybrid of kidney and B cells (HKB), capable of retaining selected phenotypes originally existing in the parental cells was developed via fusion of 293 cells and HH514-16 cells. Although HKB did indeed successfully preserve several favorable phenotypes, the expression of Epstein-Barr virus (EBV) specific nuclear antigen 1 (EBNA1), which should be constitutively expressed for host cells to utilize oriP expression vector in transient production of therapeutic proteins, was observed to be unstable. Here, in an attempt to obtain stable expression of EBNA1, a cell type that contains an integrated EBV genome, rather than HH514-16 cells, which harbor an episomal EBV genome, was applied for fusion with 293 cells. Fusion of 293 cells with Namalwa cells led to the creation of a new type of hybrid, F2N, which was able to stably express EBNA1 while not producing EBV particles. One of the F2N clones, F2N78, was observed to maintain EBNA1 expression for more than 1 year under serum-free suspension culture conditions along with human specific glycosyl phenotypes observed previously in HKB. In addition, F2N78 was demonstrated to be an appropriate host cell line for both the transient and stable production of recombinant therapeutics with the features of safety expected of production cell lines for human use.