Small antisense RNA to cyclin D1 generated by pre-tRNA splicing inhibits growth of human hepatoma cells.

Introns are present in some human pre-tRNAs. They are spliced out during the maturation processes of pre-tRNAs in a way that is irrelevant to their specific nucleotide sequences. This unique characteristic of tRNA splicing can be used for generation of small antisense RNAs by replacing the intron sequences with corresponding antisense sequences. In this work, the intron sequence of human pre-tRNAtyr gene was replaced with a 20 bp antisense sequence targeted to the 5' coding region of cyclin D1, a molecule that was over-expressed in many malignant proliferating cells. Under the control of U6 SnRNA promoter to further enhance transcription efficiency of the modified pre-tRNAtyr gene and subsequent antisense generation, the antisense RNA exhibited obvious suppression of cyclin D1 expression in H22 hepatoma cells. The growth of H22-transplanted tumors in mice was significantly inhibited when treated with naked plasmid DNA harboring the cyclin D1 antisense RNA generating cassette. Such tumor growth inhibition might be due to apoptosis caused by reduced cyclin D1 expression as revealed by immunohistochemical analysis of tumor samples.

[Modification of Chinese hamster ovary cells].

Chinese hamster ovary cells (CHO) are preferable to prokaryotic, yeast or insect cells as hosts for biopharmaceutical production due to the products are more similar to their natural conformation. However, CHO cells confront tremendous difficulties when cultured in large scale such as mal-adaptation to serum-free medium, apoptosis and over-growth without limitation. So in addition to optimizing CHO system in respect of medium, environment and expression vector, modification of CHO cells themselves has drawn more and more attention. Here the main progress in CHO-modification is reviewed.

Blocking caspase-3 activity with a U6 SnRNA promoter-driven ribozyme enhances survivability of CHO cells cultured in low serum medium and production of interferon-beta.

Apoptosis responding to various insults in bioreactors was observed to reduce cell viability and prevent cells from growing to high density. Inhibition of apoptosis in different ways has proved to be effective in keeping cells viable in high density and result in higher recombinant protein production. In apoptosis, death signals activate a family of proteinases, namely caspases, in a cascade and ultimately activate the final effector proteinase, caspase-3, which cleaves various substrates and drives the cells irreversibly to death. Caspase-3 is the executioner of an apoptotic cell and thus plays a central role in apoptosis. Therefore inhibition of caspase-3 may provide an effective way for apoptosis prevention. In this study, we designed a ribozyme targeted at the 451 nt of hamster caspase-3's open reading frame (ORF) and the ribozyme was proved to be effective in cleaving caspase-3 mRNA in vitro. Then, the ribozyme was cloned into a vector under the control of U6 snRNA promoter, an RNA polymerase III promoter, for high rate of transcription in vivo. The vector was transfected into an interferon-beta producing recombinant CHO cell line, and some clones were screened out that exhibited low caspase-3 production by Western blot analysis. One such clone was then further analyzed and it showed good anti-apoptosis property with respect to cell viability, cell density, and interferon-beta production.

[Construction of CHO-IVB, A serum-independent, apoptosis-resistant cell line that can grow in adherence].

Without serum to provide adherent factors, CHO-dhfr- cells grow in suspension when cultured in serum-free medium. Although this offers advantages in some applications, in most production systems adherent cell growth is preferable. Gene transfection, clonal selection and amplification can be easier for adherent cells; the density of immobilized cells is often higher than those in suspension culture, which results in a higher protein productivity; washout of cells by perfused medium during continuous fermentation can be avoided; for high-throughput microplate assays, adherent cells are preferred to facilitate medium changes and cell washing. It has been proved that purified vitronectin alone was able to mediate attachment and spreading of CHO cells in serum-free medium. So we constructed a tricistronic expression vector expressing Igf-1, Vitronectin and Bel-2 at the same time. The vector was transfected into CHO-dhfr- cells and one clone, namely CHO-IVB2, expressing high level of the three proteins was screened out by Western blot. The cell line showed similar apoptosis-resistant and serum-independent properties to CHO-IB, an engineered cell line constructed before. When cultured in IMEM protein-free medium without any components supplemented, CHO-IVB can grow adherently. The viable cell numbers and growth rate of CHO-IVB were much higher than CHO-IB, making CHO-IVB an apoptosis-resistant host for production of recombinant proteins which can grow adherently in protein-free medium.

[Construction of two robust CHO cell lines resistant to apoptosis and adapted to protein-free medium by over-expression of Igf-1/bcl-2 or bcl-2/cyclin E genes].

Serum used widely in mammalian cell culture is also a potential source of bacterial, mycoplasmal and viral contaminations. In addition, the complex biological components in serum make harder the subsequent product recovery process. High cost, high batch variation and potential source limitation are among the other shortcomings. So serum-free or even protein-free medium are preferable for recombinant protein production. However, without serum to provide essential components such as hormones, growth factors and binding proteins, cells are easy to die. In this study, CHO-dhfr- cells were genetically engineered to make them adapted to IMEM, a protein-free medium, and resistant to apoptosis. The genes in choice are insulin-like factor (Igf-1), Bcl-2 and cyclin E. Bcl-2 is a mitochondrial membrane-integrated protein. It can block the release of cytochrome c by maintaining the integrity of mitochondrial membrane, and thus inhibit apoptosis. Igf-1 is similar both in structure and function to insulin, a growth factor added to serum-free medium to promote cell growth and is the only protein component in many currently used serum-free media. cyclin E is a cell cycle protein expressed continuously in G1 phase. When cyclin E accumulates to certain amount, cell cycle was driven to S phase. So cyclin E is a proliferation-promoting protein. By co-express Igf-1/Bcl-2 or Bcl-2/ cyclin E in CHO-dhfr- cells with a dicistronic expression vector, we constructed two cell lines: CHO-IB and CHO-BC. The high expression of each protein was confirmed by Western blot and flow cytometry. Apoptosis was analyzed by flow cytometry and DNA ladder detection, and the two cell lines were both found much more resistant to apoptosis induced by withdrawal of serum or addition of actinomycin D than the CHO-dhfr- parent cell. Cell proliferation assay by MTT method showed that the two cell lines proliferated much faster than CHO-dhfr- in IMDM medium without serum. Continuously culture assay proved that the two cell lines grow very well in IMEM protein-free medium supplemented with fibronectin and vitronectin to ease adherence. When compared to CHO-dhfr-, the two cell lines exhibited much more viable cell numbers and faster growth rate.

[Construction of an anti-apoptosis CHO cell line for biopharmaceutical production].

Mammalian cells are prone to apoptosis when cultured in large scale for production of biopharmaceuticals. And this will reduce production duration and result in high cost of production. Apoptosis is triggered by various factors, and delicately regulated by a set of genes. Bcl-2, a component integrated in mitochondria membrane, is an important member of these genes. By maintaining the integrity of mitochondria membrane, Bcl-2 keeps cytochrome C from releasing into cytoplasm, and thus blocks the activation of caspases, and subsequent onset of apoptosis. Over-expression of Bcl-2 has proven to be useful in blocking apoptosis in various cell lines, including CHO, hybridoma, myeloma, lymphoma and insect cells. Ammonia, a metabolite of cultured cells, however, showed apparent pro-apoptosis activity. In living cells, ammonia can be utilized by glutamine synthetase (GS) to synthesize glutamine, and thus lower the concentration of ammonia in medium, and its negative effects. Glutamine is essential to living cells. If not added into medium, glutamine can only be synthesized by GS, which makes GS a qualified selection marker. This marker can be used for gene amplification by adding into medium increased concentration of MSX, an inhibitor of GS. In this study, we over-expressed Bcl-2 using GS amplification in a recombinant CHO cell line stably expressing human interferon-beta. The modified cell line, with higher expression of Bcl-2 and lower production of ammonia, exhibited good anti-apoptosis quality and higher interferon-beta production in continuous culture.