Targeted proteomics reveals strain-specific changes in the mouse insulin and central metabolic pathways after a sustained high-fat diet.

The metabolic syndrome is a collection of risk factors including obesity, insulin resistance and hepatic steatosis, which occur together and increase the risk of diseases such as diabetes, cardiovascular disease and cancer. In spite of intense research, the complex etiology of insulin resistance and its association with the accumulation of triacylglycerides in the liver and with hepatic steatosis remains not completely understood. Here, we performed quantitative measurements of 144 proteins involved in the insulin-signaling pathway and central metabolism in liver homogenates of two genetically well-defined mouse strains C57BL/6J and 129Sv that were subjected to a sustained high-fat diet. We used targeted mass spectrometry by selected reaction monitoring (SRM) to generate accurate and reproducible quantitation of the targeted proteins across 36 different samples (12 conditions and 3 biological replicates), generating one of the largest quantitative targeted proteomics data sets in mammalian tissues. Our results revealed rapid response to high-fat diet that diverged early in the feeding regimen, and evidenced a response to high-fat diet dominated by the activation of peroxisomal ß-oxidation in C57BL/6J and by lipogenesis in 129Sv mice.

Glucagon-induced acetylation of Foxa2 regulates hepatic lipid metabolism.

Circulating levels of insulin and glucagon reflect the nutritional state of animals and elicit regulatory responses in the liver that maintain glucose and lipid homeostasis. The transcription factor Foxa2 activates lipid metabolism and ketogenesis during fasting and is inhibited via insulin-PI3K-Akt signaling-mediated phosphorylation at Thr156 and nuclear exclusion. Here we show that, in addition, Foxa2 is acetylated at the conserved residue Lys259 following inhibition of histone deacetylases (HDACs) class I-III and the cofactors p300 and SirT1 are involved in Foxa2 acetylation and deacetylation, respectively. Physiologically, fasting states and glucagon stimulation are sufficient to induce Foxa2 acetylation. Introduction of the acetylation-mimicking (K259Q) or -deficient (K259R) mutations promotes or inhibits Foxa2 activity, respectively, and adenoviral expression of Foxa2-K259Q augments expression of genes involved in fatty acid oxidation and ketogenesis. Our study reveals a molecular mechanism by which glucagon signaling activates a fasting response through acetylation of Foxa2.

A new player in the orchestra of cell growth: SREBP activity is regulated by mTORC1 and contributes to the regulation of cell and organ size.

Cell growth requires co-ordinated regulation of processes that provide metabolites for the synthesis of macromolecules such as proteins and membrane lipids. In recent years, a lot of emphasis has been placed on the activation of protein synthesis by mTORC1 (mammalian target of rapamycin complex 1). The contribution of anabolic pathways other than protein synthesis has only been considered recently. In the present paper, we discuss recent findings regarding the contribution of transcriptional regulation of lipogenesis genes by the SREBP (sterol-regulatory-element-binding protein) transcription factor, a central regulator of expression of lipogenic genes, to the control of cell size in vitro and cell and organ size in vivo.

SREBP activity is regulated by mTORC1 and contributes to Akt-dependent cell growth.

Cell growth (accumulation of mass) needs to be coordinated with metabolic processes that are required for the synthesis of macromolecules. The PI3-kinase/Akt signaling pathway induces cell growth via activation of complex 1 of the target of rapamycin (TORC1). Here we show that Akt-dependent lipogenesis requires mTORC1 activity. Furthermore, nuclear accumulation of the mature form of the sterol responsive element binding protein (SREBP1) and expression of SREBP target genes was blocked by the mTORC1 inhibitor rapamycin. We also show that silencing of SREBP blocks Akt-dependent lipogenesis and attenuates the increase in cell size in response to Akt activation in vitro. Silencing of dSREBP in flies caused a reduction in cell and organ size and blocked the induction of cell growth by dPI3K. Our results suggest that the PI3K/Akt/TOR pathway regulates protein and lipid biosynthesis in an orchestrated manner and that both processes are required for cell growth.

PKB/Akt induces transcription of enzymes involved in cholesterol and fatty acid biosynthesis via activation of SREBP.

Protein kinase B (PKB/Akt) has been shown to play a role in protection from apoptosis, cell proliferation and cell growth. It is also involved in mediating the effects of insulin, such as lipogenesis, glucose uptake and conversion of glucose into fatty acids and cholesterol. Sterol-regulatory element binding proteins (SREBPs) are the major transcription factors that regulate genes involved in fatty acid and cholesterol synthesis. It has been postulated that constitutive activation of the phosphatidylinositol 3 kinase/Akt pathway may be involved in fatty acid and cholesterol accumulation that has been described in several tumour types. In this study, we have analysed changes in gene expression in response to Akt activation using DNA microarrays. We identified several enzymes involved in fatty acid and cholesterol synthesis as targets for Akt-regulated transcription. Expression of these enzymes has previously been shown to be regulated by the SREBP family of transcription factors. Activation of Akt induces synthesis of full-length SREBP-1 and SREBP-2 proteins as well as expression of fatty acid synthase (FAS), the key regulatory enzyme in lipid biosynthesis. We also show that Akt leads to the accumulation of nuclear SREBP-1 but not SREBP-2, and that activation of SREBP is required for Akt-induced activation of the FAS promoter. Finally, activation of Akt induces an increase in the concentration of cellular fatty acids as well as phosphoglycerides, the components of cellular membranes. Our data indicate that activation of SREBP by Akt leads to the induction of key enzymes of the cholesterol and fatty acid biosynthesis pathways, and thus membrane lipid biosynthesis.

Studies on substrate recognition by the budding yeast separase.

Sister chromatid cohesion is resolved at anaphase onset when separase, a site-specific protease, cleaves the Scc1 subunit of the chromosomal cohesin complex that is responsible for holding sister chromatids together. This mechanism to initiate anaphase is conserved in eukaryotes from budding yeast to man. Budding yeast separase recognizes and cleaves two conserved peptide motifs within Scc1. In addition, separase cleaves a similar motif in the kinetochore and spindle protein Slk19. Separase may cleave further substrate proteins to orchestrate multiple cellular events that take place during anaphase. To investigate substrate recognition by budding yeast separase we analyzed the sequence requirements at one of the Scc1 cleavage site motifs by systematic mutagenesis. We derived a cleavage site consensus motif (not(FKRWY))(ACFHILMPVWY)(DE)X(AGSV)R/X. This motif is found in 1,139 of 5,889 predicted yeast proteins. We analyzed 28 candidate proteins containing this motif as well as 35 proteins that contain a core (DE)XXR motif. We could so far not confirm new separase substrates, but we have uncovered other forms of mitotic regulation of some of the proteins. We studied whether determinants other than the cleavage site motif mediate separase-substrate interaction. When the separase active site was occupied with a peptide inhibitor covering the cleavage site motif, separase still efficiently interacted with its substrate Scc1. This suggests that separase recognizes both a cleavage site consensus sequence as well as features outside the cleavage site.