Simultaneous Disruption of Both Polyubiquitin Genes Affects Proteasome Function and Decreases Cellular Proliferation.

The ubiquitin (Ub) proteasome system is important for maintaining protein homeostasis and has various roles in cell signaling, proliferation, and cell cycle regulation. In mammals, Ub is encoded by two monoubiquitin and two polyubiquitin genes. Although reduced levels of Ub due to the disruption of one polyubiquitin gene are known to decrease cell proliferation, the effect of disrupting both polyubiquitin genes remains elusive. Polyubiquitin gene Ubc knockout mice are embryonically lethal and polyubiquitin gene Ubb knockout mice are infertile. Thus, it is difficult to study the effects of double knockouts (DKOs). In the present study, the CRISPR/Cas9 system was used to simultaneously knockout both polyubiquitin genes, UBB and UBC, in HEK293T and HeLa cells. In DKO cells, growth decreased significantly compared to the control cells. We observed reduced proteasome function and reduced levels of free Ub in DKO cells. However, the levels of purified proteasome were not different between control and DKO cells, although the mRNA levels of proteasomal subunits were significantly increased in latter. We propose that the reduction of Ub levels, by disruption of both polyubiquitin genes, resulted in an altered proteasomal status, leading to the reduced proteasome activity, and decreased cellular proliferation.

Molecular Dissection of the Human Ubiquitin C Promoter Reveals Heat Shock Element Architectures with Activating and Repressive Functions.

The promoter of the polyubiquitin C gene (UBC) contains putative heat shock elements (HSEs) which are thought to mediate UBC induction upon stress. However, the mapping and the functional characterization of the cis-acting determinants for its up-regulation have not yet been addressed. In this study, the sequence encompassing 916 nucleotides upstream of the transcription start site of the human UBC gene has been dissected by in silico, in vitro and in vivo approaches. The information derived from this analysis was used to study the functional role and the interplay of the identified HSEs in mediating the transcriptional activation of the UBC gene under conditions of proteotoxic stress, induced by the proteasome inhibitor MG132. Here we demonstrate that at least three HSEs, with different configurations, exist in the UBC promoter: two distal, residing within nucleotides -841/-817 and -715/-691, and one proximal to the transcription start site (nt -100/-65). All of them are bound by transcription factors belonging to the heat shock factor (HSF) family, as determined by bandshift, supershift and ChIP analyses. Site-directed mutagenesis of reporter constructs demonstrated that while the distal elements are involved in the up-regulation of UBC in response to proteasome inhibition, the proximal one appears rather to function as negative regulator of the stress-induced transcriptional activity. This is the first evidence that an HSE may exert a negative role on the transcription driven by other HSE motifs on the same gene promoter, highlighting a new level of complexity in the regulation of HSFs and in the control of ubiquitin levels.

New semi-synthesis of ubiquitin C-terminal conjugate with 7-amino-4-methylcoumarin.

The ligation of peptide hydrazides at a Gly site carrying a removal auxiliary was found to be an efficient process. This technology was successfully used for the synthesis of ubiquitin C-terminal conjugates. Recombinant Ub(1-75)-NHNH2 was prepared through the hydrozinolysis of the Ub(1-75)-intein fusion protein. It was ligated with a glycine derivative modified with an acid-sensitive thiol auxiliary. The final acid treatment produced the desired bioactive ubiquitin conjugates in practical quantities. Thus, the method described here extends the protocols of expressed protein ligation.

ASH2L regulates ubiquitylation signaling to MLL: trans-regulation of H3 K4 methylation in higher eukaryotes.

Crosstalk between H2B ubiquitylation (H2Bub) and H3 K4 methylation plays important roles in coordinating functions of diverse cofactors during transcription activation. The underlying mechanism for this trans-tail signaling pathway is poorly defined in higher eukaryotes. Here, we show the following: (1) ASH2L in the MLL complex is essential for H2Bub-dependent H3 K4 methylation. Deleting or mutating K99 of the N-terminal winged helix (WH) motif in ASH2L abrogates H2Bub-dependent regulation. (2) Crosstalk can occur in trans and does not require ubiquitin to be on nucleosomes or histones to exert regulatory effects. (3) trans-regulation by ubiquitin promotes MLL activity for all three methylation states. (4) MLL3, an MLL homolog, does not respond to H2Bub, highlighting regulatory specificity for MLL family histone methyltransferases. Altogether, our results potentially expand the classic histone crosstalk to nonhistone proteins, which broadens the scope of chromatin regulation by ubiquitylation signaling.

The structure of the UbcH8-ubiquitin complex shows a unique ubiquitin interaction site.

Ubiquitin-mediated proteolysis utilizes a series of three key enzymes (E1, E2, and E3) to transfer and then covalently modify a substrate with ubiquitin. E2 conjugating enzymes are central proteins in this pathway responsible for the acceptance of a ubiquitin from the E1 enzyme and association with an E3 protein. All E2 enzymes covalently bind ubiquitin through a thiolester linkage between a conserved active-site cysteine on E2 and the C-terminal glycine on ubiquitin. It is not known whether E2 enzymes utilize similar surfaces and residues to coordinate a ubiquitin molecule and how this might contribute to any substrate specificity. In this work, we determined the structure of the human E2 enzyme UbcH8 (UBE2L6) covalently bound to ubiquitin by NMR spectroscopy. A disulfide bond mimicking the short-lived thiolester was formed between the two proteins providing a stable complex. Overall, the structure of UbcH8 does not undergo a significant conformational change upon forming a complex with ubiquitin. Chemical shift perturbation and cross-saturation experiments were used to identify contacts between UbcH8 and ubiquitin and those contacts used as inputs for HADDOCK molecular docking to produce the structure of the UbcH8-ubiquitin complex. An ensemble of 16 structures (root-mean-square deviation of 0.83 A) showed that ubiquitin interacts with the linker region prior to the alpha5 helix as well as residues near the catalytic site. This region corresponds to an area of negative potential on the UbcH8 surface and is considerably different from other E2-ubiquitin interaction sites. Our findings indicate the positioning of ubiquitin on UbcH8 would still allow interaction with E1 and E3 enzymes. Together, the results suggest the UbcH8-ubiquitin complex may provide an additional level of specificity in the ubiquitination pathway.