Is transformation associated with an increased error frequency in mammalian cells?

Cellular Senescence limits Translational Readthrough

The origin and evolution of cancer cells is considered to be mainly fueled by DNA mutations. Although translation errors could also expand the cellular proteome, their role in cancer biology remains poorly understood. Tumor suppressors called caretakers block cancer initiation and progression by preventing DNA mutations and/or stimulating DNA repair. If translational errors contribute to tumorigenesis, then caretaker genes should prevent such errors in normal cells in response to oncogenic stimuli. Here, we show that the process of cellular senescence induced by oncogenes, tumor suppressors or chemotherapeutic drugs is associated with a reduction in translational readthrough (TR) measured using reporters containing termination codons withing the context of both normal translation termination or programmed TR. Senescence reduced both basal TR and TR stimulated by aminoglycosides. Mechanistically, the reduction of TR during senescence is controlled by the RB tumor suppressor pathway. Cells that escape from cellular senescence either induced by oncogenes or chemotherapy have an increased TR. Also, breast cancer cells that escape from therapy-induced senescence express high levels of AGO1x, a TR isoform of AGO1 linked to breast cancer progression. We propose that senescence and the RB pathway reduce TR limiting proteome diversity and the expression of TR proteins required for cancer cell proliferation.

Summary: We report that senescence and the RB pathway reduce translational readthrough (TR) limiting proteome diversity and the expression of TR proteins such as Ago1X required for cancer cell proliferation.

The Ubiquitin-Proteasome Pathway and Resistance Mechanisms Developed Against the Proteasomal Inhibitors in Cancer Cells

BACKGROUND

The ubiquitin-proteasome pathway is crucial for all cellular processes and is, therefore, a critical target for the investigation and development of novel strategies for cancer treatment. In addition, approximately 30% of newly synthesized proteins never attain their final conformations due to translational errors or defects in post-translational modifications; therefore, they are also rapidly eliminated by the ubiquitin-proteasome pathway.

OBJECTIVE

Here, an effort was made to outline the recent findings deciphering the new molecular mechanisms involved in the regulation of ubiquitin-proteasome pathway as well as the resistance mechanisms developed against proteasome inhibitors in cell culture experiments and in the clinical trials.

RESULTS

Since cancer cells have higher proliferation rates and are more prone to translational errors, they require the ubiquitin-proteasome pathway for selective advantage and sustained proliferation. Therefore, drugs targeting the ubiquitin-proteasome pathway are promising agents for the treatment of both hematological and solid cancers.

CONCLUSION

A number of proteasome inhibitors are approved and used for the treatment of advanced and relapsed multiple myeloma. Unfortunately, drug resistance mechanisms may develop very fast within days of the start of the proteasome inhibitor-treatment either due to the inherent or acquired resistance mechanisms under selective drug pressure. However, a comprehensive understanding of the mechanisms leading to the proteasome inhibitor-resistance will eventually help the design and development of novel strategies involving new drugs and/or drug combinations for the treatment of a number of cancers.

Transfer RNAs: diversity in form and function

As the adaptor that decodes mRNA sequence into protein, the basic aspects of tRNA structure and function are central to all studies of biology. Yet the complexities of their properties and cellular roles go beyond the view of tRNAs as static participants in protein synthesis. Detailed analyses through more than 60 years of study have revealed tRNAs to be a fascinatingly diverse group of molecules in form and function, impacting cell biology, physiology, disease and synthetic biology. This review analyzes tRNA structure, biosynthesis and function, and includes topics that demonstrate their diversity and growing importance.

Decreased accuracy of protein synthesis in extracts from aging human diploid fibroblasts

The accuracy of protein synthesis has been measured in extracts from human diploid fibroblasts of different ages. Extracts were supplied with purified mRNA for the coat protein of the cowpea variant of tobacco mosaic virus (CcTMV), which lacks codons for cysteine and methionine. The presence of 35S-cysteine in CcTMV coat protein synthesized during translation reactions therefore represents translational error. Translation reactions were performed with extracts from young fibroblasts (less than 50% of life span completed) and old fibroblasts (more than 90% of life span completed), and the translation products were purified by immunoprecipitation and analyzed by polyacrylamide gel electrophoresis. The error frequency increased from 4.2 x 10(-5) cysteines/amino acid in young cell extracts to 2.9 x 10(-4) cysteines/amino acid in old cell extracts. Cysteine incorporation was not due to nonspecific binding, and could be increased approximately sixfold by the addition of the misreading antibiotic, paromomycin. It is concluded that translational accuracy is not stable during aging in vitro, and it is proposed that this decrease in the fidelity of information transfer could be responsible for the variety of changes observed in aging cultured human cells.

The accuracy of protein synthesis in reticulocyte and HeLa cell lysates

The accuracy of translation in protein synthesis is measured as the rate of misincorporation of a particular amino acid, different from that specified by an mRNA codon, into protein. The cowpea variant of tobacco mosaic virus, CcTMV, contains no cysteine or methionine in its coat protein. Translation in vitro of purified CcTMV coat protein mRNA by rabbit reticulocyte and HeLa cell lysates has been performed. The coat protein product was purified by immunoprecipitation with specific antisera, and separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The error rate was measured by comparing the incorporation of [35S]cysteine with incorporation of [3H]leucine, and the total CcTMV coat protein synthesized was calculated from its known leucine content. An error rate of (1-2) X 10(-3) cysteines/CcTMV coat protein was obtained with reticulocyte lysates. If errors were cysteine incorporation in place of arginine, this number is converted to 3 X 10(-4) cysteine/codon. If cysteine was incorporated anywhere in the polypeptide, the rate is 9 X 10(-6) cysteines/amino acid. The error frequencies with HeLa cell lysates were 6-fold higher. Paromomycin, a eukaryotic misreading antibiotic, increased error rates 10-fold in both lysates. These data compare well with in vivo measurements and suggest that some transformed cells may survive with higher mistranslation rates.

Protein synthetic fidelity in aging human fibroblasts

The fidelity of protein synthesis was measured in human diploid skin fibroblasts as a function of passage level ("aging in vitro") and physiological age of tissue donor ("aging in vivo") using two different test systems. First, in cell-free extracts the ratio of delta leu/delta phe incorporation into peptide linkage following in the latter case using cells derived from elderly normal donors and from subjects with the premature aging disorders of Hutchinson-Gilford progeria and the Werner syndrome. Similar results were obtained using a second system of intact cells whereby histidine starvation induces quantifiable satellite spots resolved by two dimensional electrophoresis on polyacrylamide gels on the acidic side of the native actin species due to substitution of the neutral amino acid glutamine for the basic histidine. In fact, error frequencies appeared to decrease during aging in vitro, likely due to selection for clonal subpopulations with the highest fidelity of protein synthesis. The only increases were seen in the intact cell system where SV40-transformed cells showed a three-to-five fold greater error frequency compared to nontransformed fibroblasts. In total, these data fail to support the error catastrophe theory of cellular aging.