Transcriptomic profiling of TK2 deficient human skeletal muscle suggests a role for the p53 signalling pathway and identifies growth and differentiation factor-15 as a potential novel biomarker for mitochondrial myopathies

One of the main objectives in the analysis of microarray experiments is the identification of genes that are differentially expressed under two experimental conditions. This task is complicated by the noisiness of the data and the large number of genes that are examined simultaneously. Here, we present a novel technique for identifying differentially expressed genes that does not originate from a sophisticated statistical model but rather from an analysis of biological reasoning. The new technique, which is based on calculating rank products (RP) from replicate experiments, is fast and simple. At the same time, it provides a straightforward and statistically stringent way to determine the significance level for each gene and allows for the flexible control of the false-detection rate and familywise error rate in the multiple testing situation of a microarray experiment. We use the RP technique on three biological data sets and show that in each case it performs more reliably and consistently than the non-parametric t-test variant implemented in Tusher et al.'s significance analysis of microarrays (SAM). We also show that the RP results are reliable in highly noisy data. An analysis of the physiological function of the identified genes indicates that the RP approach is powerful for identifying biologically relevant expression changes. In addition, using RP can lead to a sharp reduction in the number of replicate experiments needed to obtain reproducible results.

Thirty years of research on the p53 family of genes has generated almost fifty thousand publications. The first of these papers detected the p53 protein associated with a viral oncogene product in transformed cells and tumors and focused the field on cancer biology. Subsequent manuscripts have shown a wide variety of functions for the p53 family of genes and their proteins. These proteins are involved in reproduction, genomic repair, fidelity and recombination, the regulation of metabolic processes, longevity, surveillance of the stability of development, the production of stem cells and changes in epigenetic marks, the development of the nervous system (p73), the immune system (p73) and skin (p63), as well as the better known roles for the family in tumor suppression. The p53 family of genes has been found in the modern day ancestors of organisms with over one billion years of evolutionary history where they play a role in germ-line fidelity over that time span. As the body plan of the vertebrates emerged with the regeneration of tissues by stem cells over a lifetime, the p53 gene and its protein were adapted to be a tumor suppressor of somatic stem and progenitor cells complementing its' past functions in the germ line. Because the p53 family of genes has played a role in germ-line fidelity and preservation of the species, even in times of stress, these genes have been under constant selection pressure to change and adapt to new situations. This has given rise to this diversity of functions all working to preserve homeostatic processes that permit growth and reproduction in a world that is constantly challenging the fidelity of information transfer at each generation. The p53 family of gene products has influenced the rates of evolutionary change, just as evolutionary changes have altered the p53 family and its functions.

Cultured human myoblasts fail to immortalize following the introduction of telomerase. The availability of an immortalization protocol for normal human myoblasts would allow one to isolate cellular models from various neuromuscular diseases, thus opening the possibility to develop and test novel therapeutic strategies. The parameters limiting the efficacy of myoblast transfer therapy (MTT) could be assessed in such models. Finally, the presence of an unlimited number of cell divisions, and thus the ability to clone cells after experimental manipulations, reduces the risks of insertional mutagenesis by many orders of magnitude. This opportunity for genetic modification provides an approach for creating a universal donor that has been altered to be more therapeutically useful than its normal counterpart. It can be engineered to function under conditions of chronic damage (which are very different than the massive regeneration conditions that recapitulate normal development), and to overcome the biological problems such as cell death and failure to proliferate and migrate that limit current MTT strategies. We describe here the production and characterization of a human myogenic cell line, LHCN-M2, that has overcome replicative aging due to the expression of telomerase and cyclin-dependent kinase 4. We demonstrate that it functions as well as young myoblasts in xenotransplant experiments in immunocompromized mice under conditions of regeneration following muscle damage.