Current clinical strategy for staging and prognostication of colorectal cancer (CRC) relies mainly upon the TNM or Duke system. This clinicopathological stage is a crude prognostic guide because it reflects in part the delay in diagnosis in the case of an advanced cancer and gives little insight into the biological characteristics of the tumor. We hypothesized that global metabolic profiling (metabonomics/metabolomics) of colon mucosae would define metabolic signatures that not only discriminate malignant from normal mucosae, but also could distinguish the anatomical and clinicopathological characteristics of CRC. We applied both high-resolution magic angle spinning nuclear magnetic resonance (HR-MAS NMR) and gas chromatography mass spectrometry (GC/MS) to analyze metabolites in biopsied colorectal tumors and their matched normal mucosae obtained from 31 CRC patients. Orthogonal partial least-squares discriminant analysis (OPLS-DA) models generated from metabolic profiles obtained by both analytical approaches could robustly discriminate normal from malignant samples (Q(2) > 0.50, Receiver Operator Characteristic (ROC) AUC >0.95, using 7-fold cross validation). A total of 31 marker metabolites were identified using the two analytical platforms. The majority of these metabolites were associated with expected metabolic perturbations in CRC including elevated tissue hypoxia, glycolysis, nucleotide biosynthesis, lipid metabolism, inflammation and steroid metabolism. OPLS-DA models showed that the metabolite profiles obtained via HR-MAS NMR could further differentiate colon from rectal cancers (Q(2)> 0.60, ROC AUC = 1.00, using 7-fold cross validation). These data suggest that metabolic profiling of CRC mucosae could provide new phenotypic biomarkers for CRC management.
The lipotoxicity hypothesis posits that obesity predisposes individuals to metabolic diseases because the oversupply of lipids to tissues not suited for fat storage leads to the accumulation of fat-derived molecules that impair tissue function. Means of combating this have been to stimulate anabolic processes to promote lipid storage or to promote catabolic ones to drive fat degradation. Herein, we demonstrate that ablating dihydroceramide desaturase 1 (Des1), an enzyme that produces ceramides, leads to the simultaneous activation of both anabolic and catabolic signaling pathways. In cells lacking Des1, the most common sphingolipids were replaced with dihydro forms lacking the double bond inserted by Des1. These cells exhibited a remarkably strong activation of the antiapoptotic and anabolic signaling pathway regulated by Akt/protein kinase B (PKB), were resistant to apoptosis, and were considerably larger than their wild-type counterparts. Paradoxically, Des1؊/؊ cells exhibited high levels of autophagy. Mechanistic studies revealed that this resulted from impaired ATP synthesis due in part to decreased expression and activity of several complexes of the electron transport chain, particularly complex IV, leading to activation of AMP-activated protein kinase and its induction of the autophagosome. Thus, Des1 ablation enhanced starvation responses but dissociated them from the anabolic, prosurvival, and antiautophagic Akt/PKB pathways.
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