Linkage of cardiac gene expression profiles and ETS2 with lifespan variability in rats.

Longevity variability is a common feature of aging in mammals, but the mechanisms responsible for this remain largely unknown. Using microarray datasets coupled with prediction analysis of microarrays (PAM), we identified a set of 252 cardiac transcripts predictive of relative lifespan in Wistar and Fisher 344 rats. Prediction analysis of microarrays 'tests' of rat heart transcriptomes from a third longer lived Fisher × Norway Brown rat strain validated the predictive value of this gene subset. The expression patterns of these genes were highly conserved, and corresponding promoter regions were employed to identify common cis-elements and trans-activating factors implicated in their control. Specifically, four transcription factors (Max, Ets2, Erg, and Msx2) present in heart displayed longevity-dependent, strain-independent changes in abundance, but only ETS2 had an expression profile that directly correlated with the relative lifespan gene set. In heart, ETS2 was prevalent in cardiomyocytes (CMs) and showed a high degree of myocyte-to-myocyte variability predominantly in adult rat hearts prior to the exponential increase in the rate of mortality. Exclusively in this group, elevated ETS2 significantly overlapped with TUNEL staining in heart myocytes. In response to sympathetic stimuli, ETS2 is also up-regulated, and functionally, adenovirus-mediated over-expression of ETS2 promotes apoptosis-inducing factor-mediated, caspase-independent programmed necrosis exclusively in CMs that can be fully inhibited by the PARP-1 inhibitor DPQ. We conclude that variations in ETS2 abundance in hearts of adult rodents and the associated loss of CMs contribute at least partially, to the longevity variability observed during normal aging of rats through activation of programmed necrosis.

Highly sensitive simultaneous detection of cultured cellular thiols by laser induced fluorescence-capillary electrophoresis.

We have recently described a new method to determine physiological thiols, in which the quantification of plasma homocysteine, cysteine, cysteinylglycine, glutathione, and glutamylcysteine was achieved after derivatization with 5-iodoacetamidofluorescein. Samples were separated and measured by capillary electrophoresis with laser-induced fluorescence in an uncoated fused-silica capillary, using a phosphate/borate run buffer and the organic base N-Methyl-D-glucamine as effective electrolyte addictive to obtain a baseline peak separation. In this paper, we propose an improvement of our method useful for the analysis of the intracellular thiols in different cultured cells. In particular, we studied run buffer and injection conditions in order to increase the sensitivity of the assay and we found that, by incrementing two times the injected volume and using the water plug before the sample injection, the sensitivity of our previous method was increased by about ten times. To maintain a good resolution between peaks, particularly between homocysteine and the internal standard d-penicillamine, we lengthened the run time by incrementing the concentration of the electrolyte buffer and the organic base d-glucamine and by decreasing the cartridge temperature from 40 to 25 degrees C. After these changes in electrophoretical parameters, cellular thiols were baseline-resolved in less than 14 min instead of 9 min as in our previous method, but the limit of quantification is increased from 50 to 1 nmol/L. This new procedure allows also to measure the intracellular thiols commonly found at low concentration, such as cysteinylglycine, glutamylcysteine, and homocysteine. The new analytical method performance was assessed by measuring the intracellular thiols in three different cell lines, i.e., HUVEC, ECV304, and R1 stem cells.