Characterization and use of Tetrahymena thermophila artificial chromosome 2 (TtAC2) constructed by biomimetic of macronuclear rDNA minichromosome.

Efficient expression vectors for unicellular ciliate eukaryotic Tetrahymena thermophila are still needed in recombinant biology and biotechnology applications. Previously, the construction of the T. thermophila Macronuclear Artificial Chromosome 1 (TtAC1) vector revealed additional needs for structural improvements such as better in vivo stability and maintenance as a recombinant protein expression platform. In this study, we designed an efficiently maintained artificial chromosome by biomimetic of the native macronuclear rDNA minichromosome. TtAC2 was constructed by sequential cloning of subtelomeric 3'NTS region (1.8 kb), an antibiotic resistance gene cassette (2 kb neo4), a gene expression cassette (2 kb TtsfGFP), rDNA coding regions plus a dominant C3 origin sequence (10.3 kb), and telomeres (2.4 kb) in a pUC19 backbone plasmid (2.6 kb). The 21 kb TtAC2 was characterized using fluorescence microscopy, qPCR, western blot and Southern blot after its transformation to vegetative T. thermophila CU428.2 strain, which has a recessive B origin allele. All experimental data show that circular or linear forms of novel TtAC2 were maintained as free replicons in T. thermophila macronucleus with or without antibiotic treatment. Notably, TtAC2 carrying strains expressed a TtsfGFP marker protein, demonstrating the efficacy and functionality of the protein expression platform. We show that TtAC2 is functionally maintained for more than two months, and can be efficiently used in recombinant DNA, and protein production applications.