Mammalian TOR as a central modulator of the transcriptional response of keratinocyte stem cells to small temperature variations

Being in the layer at the interface of the body with the outside world, keratinocyte stem cells constantly adapt and respond to environmental cues such as temperature and oxygen. However, until now, experiments involving temperature have only examined cold and heat shocks. Here, our work illustrates that small variations of temperature (~1°C) are enough to affect colony size of keratinocyte stem cells and alter expression of some genes involved in various signalling pathways. The promoter regions of the temperature sensitive genes share a sequence located in some Alu short interspersed nuclear elements (Alu SINEs). This sequence termed TORRID contains several IFHL-like motifs (IFHL motif is related to ribogenesis in yeast) and interestingly a minimal TORRID sequence might be enough for a gene to acquire temperature sensitivity. Our findings demonstrated that the expression of temperature sensitive genes is regulated through the mammalian target of rapamycin (mTOR) pathway. The transcription factors ILF1 and RAP1, and histone deacetylase II (HDAC2) –human orthologs of yeast Fhl1p, Rap1 and Rpd3 respectively– associate with TORRID sequences. Small variations of temperature were enough to alter this association. Moreover, mTOR can translocate to the nucleus and associate with the TORRID sequences in a rapamycin and temperature dependent manner. Furthermore, Raptor and Rictor, members of the mTOR complexes 1 and 2 are also involved in this binding. Hence, our results reveal not only that TOR transcriptional activity is evolutionary conserved from yeast to human, but also that a small variation in temperature represents a new input to the mTOR pathway and fine-tune regulation of transcription through TORRID sequences. These results shed new light on the role of Alus in gene regulation

Target of rapamycin modulators of and use thereof

The present invention is related to new molecules capable of interacting with target of rapamycin (TOR) transcriptional complex. In particular, the present invention provides novel nucleic acid molecules, processes for production thereof, kits containing thereof, use of these in an assay for the identification of mammalian target of rapamycin (mTOR) modulators, use of mammalian target of rapamycin (mTOR) modulators identified by this assay for the preparation of a formulation for the control of hair growth and compositions for the control of hair growth

MR imaging relaxometry allows noninvasive characterization of in vivo differentiation of muscle precursor cells

Purpose To demonstrate the feasibility of in vivo monitoring of the myogenic differentiation process from human muscle precursor cells to mature skeletal muscle tissue by measuring characteristic magnetic resonance (MR) imaging relaxation and diffusion properties as a potential noninvasive diagnostic tool in muscle cell therapy. Materials and Methods The study was approved by the ethics committee for studies in humans and the animal care committee. The hypothesis was tested by means of subcutaneous injection of human muscle precursor cells from the rectus abdominis muscle into nude mice (n = 18). Animals injected with human fibroblasts, prostate cancer cells, or collagen served as control animals (four in each group). T1, T2, T2*, and apparent diffusion coefficients ( ADC apparent diffusion coefficient s) were measured at 4.7-T MR imaging. MR imaging parameters were statistically evaluated by using analysis of variance with Bonferroni correction. The engineered muscle was characterized by means of immunofluorescence, Western blot, and contraction assays. Results Muscle tissue in the early stages of the differentiation process exhibited distinctly higher T1 (mean ± standard deviation, 2242 msec ± 116), T2 (224 msec ± 18), and T2* (33.3 msec ± 3.6) values and ADC apparent diffusion coefficient s (1.53 × 10(-3) mm(2)/sec ± 0.03) compared with those of skeletal muscle. The muscle precursor cells exhibited a nonspecific pattern compared with that in control animals in the early stages. During differentiation, the relaxation and diffusion parameters decreased and approached the values for mature skeletal muscle tissue: T1, 1386 msec ± 88; T2, 32.0 msec ± 4.3; T2*, 10.8 msec ± 0.8; ADC apparent diffusion coefficient , 1.39 × 10(-3) mm(2)/sec ± 0.02 (reference erector spinae muscle tissue: T1, 1417 msec ± 106; T2, 31.0 msec ± 2.4; T2*, 11.3 msec ± 1.7; and ADC apparent diffusion coefficient , 1.40 × 10(-3) mm(2)/sec ± 0.03). Conclusion MR imaging relaxation and diffusion measurements can be used as potential biomarkers for noninvasive in vivo monitoring of the myogenic differentiation process from muscle precursor cells to mature skeletal muscle tissue in muscle cell therapy. © RSNA, 2014 Online supplemental material is available for this article