Thiolutin is a zinc chelator that inhibits the Rpn11 and other JAMM metalloproteases

Thiolutin is a disulfide-containing antibiotic and anti-angiogenic compound produced by Streptomyces. Its biological targets are not known. We show that reduced thiolutin is a zinc chelator that inhibits the JAB1/MPN/Mov34 (JAMM) domain–containing metalloprotease Rpn11, a deubiquitinating enzyme of the 19S proteasome. Thiolutin also inhibits the JAMM metalloproteases Csn5, the deneddylase of the COP9 signalosome; AMSH, which regulates ubiquitin-dependent sorting of cell-surface receptors; and BRCC36, a K63-specific deubiquitinase of the BRCC36-containing isopeptidase complex and the BRCA1–BRCA2-containing complex. We provide evidence that other dithiolopyrrolones also function as inhibitors of JAMM metalloproteases

Of switches and hourglasses: regulation of subcellular traffic in circadian clocks by phosphorylation

A major aspect of molecular timekeeping is the daytime-specific nuclear accumulation of circadian clock proteins. The authors discuss recent insights into the regulation of subcellular shuttling and consider the importance of these cycles in regulating circadian period in different organisms

Transcriptional regulation and function of the Neurospora clock gene white collar 2 and its isoforms

FREQUENCY (FRQ) and the White Collar Complex (WCC), consisting of WC1 and WC2 subunits, are crucial components of positive and negative feedback loops of the circadian clock of Neurospora. In the positive limb, FRQ supports the accumulation of WC1 on a post-translational level and activates transcription of wc2. We analysed the transcriptional regulation of wc2. The WCC indirectly inhibits wc2 by controlling expression of a putative repressor. FRQ activates wc2 transcription by inhibiting WCC. A putative transcriptional activator binds to the wc2 promoter and antagonizes the repressor function. Furthermore, an internal promoter in the wc2 coding region drives expression of an amino-terminally shortened isoform, sWC2. Full-length WC2 and sWC2 are expressed in an antagonistic manner; thus, sWC2 expression seems to be a fail-safe mechanism that maintains total WC2 levels above a threshold

Phosphorylation-dependent maturation of Neurospora circadian clock protein from a nuclear repressor toward a cytoplasmic activator

Frequency (FRQ) is a central component of interconnected negative and positive limbs of feedback loops of the circadian clock of Neurospora. In the negative limb, FRQ inhibits its transcriptional activator White Collar Complex (WCC) and in the positive limb, FRQ supports accumulation of WCC. We show that these conflicting functions are confined to distinct subcellular compartments and coordinated in temporal fashion. Inactivation of the transcriptional activator WCC requires nuclear FRQ and occurs early after the onset of FRQ expression. Support of WCC accumulation requires cytosolic FRQ and occurs on a post-translational level, when high amounts of FRQ have accumulated. The transcriptional function of FRQ in the negative loop and its post-translational function in the positive loop are independent and associated with distinct regions of FRQ. Phosphorylation of FRQ at the PEST-2 region triggers its maturation from a nuclear repressor toward a cytoplasmic activator

Circadian activity and abundance rhythms of the Neurospora clock transcription factor WCC associated with rapid nucleo–cytoplasmic shuttling

The Neurospora clock protein FREQUENCY (FRQ) inhibits its transcriptional activator WHITE COLLAR COMPLEX (WCC) in a negative feedback loop and supports its accumulation in a positive loop. We show that positive feedback is a delayed effect of negative feedback underlying the same post-translational mechanisms: DNA-binding-competent active WCC commits rapidly to degradation. FRQ-dependent phosphorylation of WCC, which interferes with DNA binding (negative feedback), leads to reduced turnover and slow accumulation of newly expressed WCC (positive feedback). When DNA binding of WCC is compromised by mutation, its accumulation is independent of FRQ. Cycles of FRQ-dependent inactivation and PP2A-dependent reactivation of WCC occur in the minute range and are coupled to obligate rapid cycles of nucleo–cytoplasmic shuttling. WCC shuttling and activity cycles are modulated by FRQ in circadian fashion

Molecular mechanism of temperature sensing by the circadian clock of Neurospora crassa

Expression levels and ratios of the long (l) and short (s) isoforms of the Neurospora circadian clock protein FREQUENCY (FRQ) are crucial for temperature compensation of circadian rhythms. We show that the ratio of l-FRQ versus s-FRQ is regulated by thermosensitive splicing of intron 6 of frq, a process removing the translation initiation site of l-FRQ. Thermosensitivity is due to inefficient recognition of nonconsensus splice sites at elevated temperature. The temperature-dependent accumulation of FRQ relative to bulk protein is controlled at the level of translation. The 5'-UTR of frq RNA contains six upstream open reading frames (uORFs) that are in nonconsensus context for translation initiation. Thermosensitive trapping of scanning ribosomes at the uORFs leads to reduced translation of the main ORF and allows adjustment of FRQ levels according to ambient temperature.

Browning of White Adipose Tissue Uncouples Glucose Uptake from Insulin Signaling

<div><p>Presence of thermogenically active adipose tissue in adult humans has been inversely associated with obesity and type 2 diabetes. While it had been shown that insulin is crucial for the development of classical brown fat, its role in development and function of inducible brown-in-white (brite) adipose tissue is less clear. Here we show that insulin deficiency impaired differentiation of brite adipocytes. However, adrenergic stimulation almost fully induced the thermogenic program under these settings. Although brite differentiation of adipocytes as well as browning of white adipose tissue entailed substantially elevated glucose uptake by adipose tissue, the capacity of insulin to stimulate glucose uptake surprisingly was not higher in the brite state. Notably, in line with the insulin-independent stimulation of glucose uptake, our data revealed that brite recruitment results in induction of solute carrier family 2 (GLUT-1) expression in adipocytes and inguinal WAT. These results for the first time demonstrate that insulin signaling is neither essential for brite recruitment, nor is it improved in cells or tissues upon browning.</p></div

Lack of insulin impairs differentiation but not browning capacity of primary pre-adipocytes.

<p>(<b>A</b>) Heatmap showing differential mRNA expression between confluent primary inguinal white adipose tissue (iWAT) precursor cells differentiated for 24 h with white (EtOH treated) or brite (cPGI₂ treated) differentiation cocktail and between absence or presence of insulin (Ins) in the medium. Higher and lower expression is displayed in red and blue, respectively. (n = 3). (<b>B</b>) mRNA expression of UCP-1 and CIDEA or (<b>C</b>) FABP4 and RETN in primary iWAT precursor cells differentiated into white (EtOH treated) or brite (cPGI₂ treated) adipocytes for 8 days with insulin present in the differentiation medium for the indicated timepoints (n = 3). All values in bar graphs are expressed as means ± SEM, #p<0.05, ##p<0.01, ###p<0.001 white (EtOH treated) vs. brite (cPGI₂ treated) cells, *p<0.05, **p<0.01, ***p<0.001 normal conditions vs. insulin deprived conditions.</p