The Augmenting Effects of the tDNA Insulator on Stable Expression of Monoclonal Antibody in Chinese Hamster Ovary Cells.

Cell line development is one of the most critical steps in the production of complex recombinant therapeutic proteins such as monoclonal antibodies in mammalian cells. Generation of industrial cell lines is mainly based on the time-consuming and laborious process of selection and screening of a large number of clones. With the increasing demand for therapeutic proteins during the past years, more effort is invested to improve the efficiency of cell line development. In line with this premise, several studies employed expression vector engineering strategies based on incorporation of epigenetic regulatory elements, which can enhance the expression level and stability of the transgenes. Main examples of such elements include ubiquitous chromatin opening elements, scaffold or matrix attachment regions, stabilizing antirepressor elements, and insulators. This work evaluates the utility of the tDNA insulator element for stable expression of an IgG1 monoclonal antibody as well as the enhanced green fluorescent protein (EGFP) reporter gene in Chinese hamster ovary (CHO) cells. Initial analysis of EGFP transfected cells showed improved mean fluorescent intensity in cell pools and single cell clones when tDNA element was included in the expression vector. Our results also indicated up to nine- and sixfold enhancements in antibody titer and specific productivity of clones derived from tDNA containing vectors, respectively. Moreover, improved single cell cloning efficiency was observed for transfectants generated using tDNA harboring expression constructs. Our study clearly shows the beneficial effects of the tDNA insulator on monoclonal antibody expression in CHO cells.

A barrier-type insulator forms a boundary between active and inactive chromatin at the murine TCRß locus.

In CD4(-)CD8(-) double-negative thymocytes, the murine Tcrb locus is composed of alternating blocks of active and inactive chromatin containing Tcrb gene segments and trypsinogen genes, respectively. Although chromatin structure is appreciated to be critical for regulated recombination and expression of Tcrb gene segments, the molecular mechanisms that maintain the integrity of these differentially regulated Tcrb locus chromatin domains are not understood. We localized a boundary between active and inactive chromatin by mapping chromatin modifications across the interval extending from Prss2 (the most 3' trypsinogen gene) to D(ß)1. This boundary, located 6 kb upstream of D(ß)1, is characterized by a transition from repressive (histone H3 lysine 9 dimethylation [H3K9me2]) to active (histone H3 acetylation [H3ac]) chromatin and is marked by a peak of histone H3 lysine 4 dimethylation (H3K4me2) that colocalizes with a retroviral long terminal repeat (LTR). Histone H3 lysine 4 dimethylation is retained and histone H3 lysine 9 dimethylation fails to spread past the LTR even on alleles lacking the Tcrb enhancer (E(ß)) suggesting that these features may be determined by the local DNA sequence. Notably, we found that LTR-containing DNA functions as a barrier-type insulator that can protect a transgene from negative chromosomal position effects. We propose that, in vivo, the LTR blocks the spread of heterochromatin, and thereby helps to maintain the integrity of the E(ß)-regulated chromatin domain. We also identified low-abundance, E(ß)-dependent transcripts that initiate at the border of the LTR and an adjacent long interspersed element. We speculate that this transcription, which extends across D(ß), J(ß) and C(ß) gene segments, may play an additional role promoting initial opening of the E(ß)-regulated chromatin domain.