REVERBa couples the circadian clock to hepatic glucocorticoid action.

The glucocorticoid receptor (GR) is a major drug target in inflammatory disease. However, chronic glucocorticoid (GC) treatment leads to disordered energy metabolism, including increased weight gain, adiposity, and hepatosteatosis - all programs modulated by the circadian clock. We demonstrated that while antiinflammatory GC actions were maintained irrespective of dosing time, the liver was significantly more GC sensitive during the day. Temporal segregation of GC action was underpinned by a physical interaction of GR with the circadian transcription factor REVERBa and co-binding with liver-specific hepatocyte nuclear transcription factors (HNFs) on chromatin. REVERBa promoted efficient GR recruitment to chromatin during the day, acting in part by maintaining histone acetylation, with REVERBa-dependent GC responses providing segregation of carbohydrate and lipid metabolism. Importantly, deletion of Reverba inverted circadian liver GC sensitivity and protected mice from hepatosteatosis induced by chronic GC administration. Our results reveal a mechanism by which the circadian clock acts through REVERBa in liver on elements bound by HNF4A/HNF6 to direct GR action on energy metabolism.

A non-transcriptional role for the glucocorticoid receptor in mediating the cell stress response.

The glucocorticoid receptor (GR) is essential for the stress response in mammals. We investigated potential non-transcriptional roles of GR in cellular stress response using fission yeast as a model.We surprisingly discovered marked heat stress resistance in yeast ectopically expressing human GR, which required expression of both the N-terminal transactivation domain, and the C-terminal ligand binding domain, but not the DNA-binding domain of the GR. This effect was not affected by GR ligand exposure, and occurred without significant GR nuclear accumulation. Mechanistically, the GR survival effect required Hsp104, and, indeed, GR expression increased Hsp104 expression. Proteomic analysis revealed GR binding to translasome components, including eIF3, a known partner for Sty1, a pattern of protein interaction which we confirmed using yeast two-hybrid studies.Taken together, we find evidence for a novel pathway conferring stress resistance in yeast that can be activated by the human GR, acting by protein-protein mechanisms in the cytoplasm. This suggests that in organisms where GR is natively expressed, GR likely contributes to stress responses through non-transcriptional mechanisms in addition to its well-established transcriptional responses.

Spatially coordinated dynamic gene transcription in living pituitary tissue.

Transcription at individual genes in single cells is often pulsatile and stochastic. A key question emerges regarding how this behaviour contributes to tissue phenotype, but it has been a challenge to quantitatively analyse this in living cells over time, as opposed to studying snap-shots of gene expression state. We have used imaging of reporter gene expression to track transcription in living pituitary tissue. We integrated live-cell imaging data with statistical modelling for quantitative real-time estimation of the timing of switching between transcriptional states across a whole tissue. Multiple levels of transcription rate were identified, indicating that gene expression is not a simple binary 'on-off' process. Immature tissue displayed shorter durations of high-expressing states than the adult. In adult pituitary tissue, direct cell contacts involving gap junctions allowed local spatial coordination of prolactin gene expression. Our findings identify how heterogeneous transcriptional dynamics of single cells may contribute to overall tissue behaviour.

Zinc binding stabilizes mitochondrial Tim10 in a reduced and import-competent state kinetically.

Tim10 and all the small Tim proteins of the mitochondrial intermembrane space contain a consensus twin CX3C Zn2+-finger motif. While disulphide bond formation between the Cys residues of this motif is essential for complex formation by the small Tim proteins, the specific role of Zn2+-binding during the import and assembly of these proteins is not clear. In this study, we investigated the effects of the biologically relevant thiol-disulphide redox molecule, glutathione, and Zn2+-binding on the oxidative folding of yeast mitochondrial Tim10 using both biochemical and biophysical methods in vitro. We show that, whilst oxidized Tim10 cannot be reduced by reduced glutathione, reduced Tim10 is effectively oxidized at levels of glutathione comparable to those found in the cytosol. The oxidized Tim10 generated in the presence of glutathione is competent for complex formation with its partner protein Tim9, confirming it has a native fold. The standard redox potential of Tim10 at pH 7.4 was determined to be -0.32 V, confirming that Tim10 is a much stronger reductant than glutathione (-0.26 V, at pH 7.4) and could therefore be oxidized rapidly by oxidized glutathione in the cytosol. However, we found that Zn2+-binding can stabilize the reduced Tim10, decreasing the rate of the oxidative folding more than tenfold. In addition, we show that protein disulphide isomerase can catalyse the oxidative folding of Tim10 provided that Zn2+ was removed. We propose that Zn2+-binding is essential to maintain the protein in a reduced and import-competent state in the cytosol, and that zinc has to be removed after the protein is imported into mitochondria to initiate protein oxidative folding and assembly.