Synthesis, cellular evaluation, and mechanism of action of piperlongumine analogs

Piperlongumine is a naturally occurring small molecule recently identified to be toxic selectively to cancer cells in vitro and in vivo. This compound was found to elevate cellular levels of reactive oxygen species (ROS) selectively in cancer cell lines. The synthesis of 80 piperlongumine analogs has revealed structural modifications that retain, enhance, and ablate key piperlongumine-associated effects on cells, including elevation of ROS, cancer cell death, and selectivity for cancer cells over nontransformed cell types. Structure/activity relationships suggest that the electrophilicity of the C2-C3 olefin is critical for the observed effects on cells. Furthermore, we show that analogs lacking a reactive C7-C8 olefin can elevate ROS to levels observed with piperlongumine but show markedly reduced cell death, suggesting that ROS-independent mechanisms, including cellular cross-linking events, may also contribute to piperlongumine’s induction of apoptosis. In particular, we have identified irreversible protein glutathionylation as a process associated with cellular toxicity. We propose a mechanism of action for piperlongumine that may be relevant to other small molecules having two sites of reactivity, one with greater and the other with lesser electrophilicity.

Gene expression profile in rat adrenal zona glomerulosa cells stimulated with aldosterone secretagogues

The mineralocorticoid aldosterone, mainly produced by the adrenal gland, is essential for life, but an abnormally excessive secretion causes severe pathological effects including hypertension and target organ injury in the heart and kidney. The aim of this study was to determine the gene regulatory network triggered by aldosterone secretagogues in a nontransformed cell system. Freshly isolated rat adrenal zona glomerulosa cells were stimulated with the two main aldosterone secretagogues, angiotensin II and potassium, for 2 h and subjected to whole genome expression studies using multiple biological and bioinformatics tools. Several genes were differentially expressed by ANG II ( n = 133) or potassium ( n = 216). Genes belonging to the nucleic acid binding and transcription factor activity categories were significantly enriched. A subset of the most regulated genes was confirmed by real-time RT-PCR, and then their expression was analyzed in time curve studies. Differentially expressed genes were grouped according to their time response expression pattern, and their promoter regions were analyzed for common regulatory transcription factor binding sites. Finally, data mining with gene promoters, transcription factors, and literature databases was performed to generate gene interaction networks for either ANG II or potassium. This paper provides for the first time a complete study of the genes that are regulated, and the interaction between them, by aldosterone secretagogues in rat adrenal cells. Increasing our knowledge of adrenal physiology and gene regulation in nontransformed cell systems could lead us to a better approach for the discovery of candidate genes involved in pathological conditions of the adrenal cortex.

Conserved charge of glomerular and mesangial cell proteoglycans: possible role of amino acid-derived sulphate

Sulphation of proteoglycans was studied in isolated glomeruli and cultured rat mesangial cells. Both preparations produced heparan, dermatan, and chondroitin sulphates, recoverable both from the tissue layers and the conditioned media. The proportion of heparan sulphate made by mesangial cells was independent of the age of the culture, but declined in later passage. These preparations differed from several other nontransformed cell types studied to date in that the degree of proteoglycan sulphation was independent of the concentration of inorganic sulphate provided. Even when no exogenous sulphate was added, sulphation-dependent charge density of newly synthesized proteoglycans was conserved. Both isolated glomeruli and cultured mesangial cells produced proteoglycans with 35S-labelled sulphate esters when [35S]methionine was provided as the sole source of labelled sulphate. Conversion of methionine to cysteine and subsequent oxidation of organic sulphate via the sulphinyl pyruvate pathway is the only mechanism known in eukaryotic cells that can account for this observation. We conclude that facile oxidation of sulphur-containing amino acids can contribute to sulphation of glomerular proteoglycans and may serve to sustain the charge density of these multifunctional molecules when the supply of inorganic sulphate is otherwise compromised.Key words: renal glomerulus, proteoglycans, sulphation, heparan sulphate, basement membrane.