Severe acute respiratory syndrome (SARS) coronavirus is a novel human coronavirus and is responsible for SARS infection. SARS coronavirus 3C-like proteinase (SARS 3CLpro ) plays key roles in viral replication and transcription and is an attractive target for anti-SARS drug discovery. In this report, we quantitatively characterized the dimerization features of the full-length and N-terminal residues 1-7 deleted SARS 3CL pro s by using glutaraldehyde cross-linking SDS-PAGE, size-exclusion chromatography, and isothermal titration calorimeter techniques. Glutaraldehyde cross-linking SDS-PAGE and size-exclusion chromatography results show that, similar to the full-length SARS 3CLpro , the N-terminal deleted SARS 3CL pro still remains a dimer/monomer mixture within a wide range of protein concentrations. Isothermal titration calorimeter determinations indicate that the equilibrium dissociation constant (K d ) of the N-terminal deleted proteinase dimer (262 M) is very similar to that of the full-length proteinase dimer (227 M). Enzymatic activity assay using the fluorescence resonance energy transfer method reveals that N-terminal deletion results in almost complete loss of enzymatic activity for SARS 3CL pro . Molecular dynamics and docking simulations demonstrate the N-terminal deleted proteinase dimer adopts a state different from that of the full-length proteinase dimer, which increases the angle between the two protomers and reduces the binding pocket that is not beneficial to the substrate binding. This conclusion is verified by the surface plasmon resonance biosensor determination, indicating that the model substrate cannot bind to the N-terminal deleted proteinase. These results suggest the N terminus is not indispensable for the proteinase dimerization but may fix the dimer at the active state and is therefore vital to enzymatic activity.
-Hydroxyacyl-acyl carrier protein dehydratase (FabZ) is an important enzyme for the elongation cycles of both saturated and unsaturated fatty acids biosyntheses in the type II fatty acid biosynthesis system (FAS II) pathway. FabZ has been an essential target for the discovery of compounds effective against pathogenic microbes. In this work, to characterize the catalytic and inhibitory mechanisms of FabZ, the crystal structures of the FabZ of Helicobacter pylori (HpFabZ) and its complexes with two newly discovered inhibitors have been solved. Different from the structures of other bacterial FabZs, HpFabZ contains an extra short two-turn ␣-helix (␣4) between ␣3 and 3, which plays an important role in shaping the substrate-binding tunnel. Residue Tyr-100 at the entrance of the tunnel adopts either an open or closed conformation in the crystal structure. The crystal structural characterization, the binding affinity determination, and the enzymatic activity assay of the HpFabZ mutant (Y100A) confirm the importance of Tyr-100 in catalytic activity and substrate binding. Residue Phe-83 at the exit tunnel was also refined in two alternative conformations, leading the tunnel to form an L-shape and U-shape. All these data thus contributed much to understanding the catalytic mechanism of HpFabZ. In addition, the co-crystal structures of HpFabZ with its inhibitors have suggested that the enzymatic activity of HpFabZ could be inhibited either by occupying the entrance of the tunnel or plugging the tunnel to prevent the substrate from accessing the active site. Our study has provided some insights into the catalytic and inhibitory mechanisms of FabZ, thus facilitating antibacterial agent development.Recently, because of the major difference between the enzymes involved in the type II fatty acid biosynthesis system (FAS II) 4 found in bacteria and the counterpart in mammals and yeast, the enzymes involved in FAS II have been looked at as a promising antibacterial agent development target (1-3). The synthesis of fatty acid in vivo includes initiation and elongation phases. During the elongation cycle of FAS II, four consecutive reactions complete the extension of two carbons (4, 5). In the third step of the elongation cycle, the dehydration of -hydroxy-ACP to trans-2-acyl-ACP is catalyzed by FabA or FabZ. FabA is a bifunctional enzyme and only found in Gram-negative bacteria with its partner, FabB, to participate in the formation of unsaturated fatty acids (6). FabZ has ubiquitous distribution in the FAS II pathway, and it is a primary dehydratase that participates in the elongation cycles of both saturated and unsaturated fatty acid biosyntheses. Accordingly, FabZ presents itself as a suitable, yet unexplored, target for the discovery of compounds effective against pathogenic microbes (5, 7).So far, although the detailed enzymatic characterization has been performed for the FabZs from Enterococcus faecalis (EfFabZ) (8, 9), Pseudomonas aeruginosa (PaFabZ) (7), and Plasmodium falciparum (PfFabZ) (2, 5, 10), and the crystal st...
Nitric oxide (NO)-release in blood serum initiated by gold nanoparticles has been prove to be a reaction between RSNO and the gold nanoparitcles. In this reaction the NO production was catalyzed on the surface of the nanoparticles, and a new bond of Au-thiolate was simultaneously formed.
Cancer stem cells (CSCs) have key roles in treatment resistance, tumour metastasis and relapse. Using colorectal cancer (CC) cell lines, patient-derived xenograft (PDX) tissues and patient tissues, here we report that CC CSCs, which resist chemoradiation, have higher SUMO activating enzyme (E1) and global SUMOylation levels than non-CSCs. Knockdown of SUMO E1 or SUMO conjugating enzyme (E2) inhibits CC CSC maintenance and self-renewal, while overexpression of SUMO E1 or E2 increases CC cell stemness. We found that SUMOylation regulates CSCs through Oct-1, a transcription factor for aldehyde dehydrogenases (ALDHs). ALDH activity is not only a marker for CSCs but also important in CSC biology. SUMO does not modify Oct-1 directly, but regulates the expression of TRIM21 that enhances Oct-1 ubiquitination and, consequently, reducing Oct-1 stability. In summary, our findings suggest that SUMOylation could be a target to inhibit CSCs and ultimately to reduce treatment resistance, tumour metastasis and relapse.
Adipose tissue is an important metabolic organ that is crucial for whole-body insulin sensitivity and energy homeostasis. Highly refined fructose intake increases visceral adiposity although the mechanism(s) remain unclear. Differentiation of preadipocytes to mature adipocytes is a highly regulated process that is associated with characteristic sequential changes in adipocyte gene expression. We demonstrate that fructose treatment of murine 3T3-L1 cells incubated in standard differentiation medium increases adipogenesis and adipocyte-related gene expression. We further show that the key fructose transporter, GluT5, is expressed in early-stage adipocyte differentiation but is not expressed in mature adipocytes. GluT5 overexpression or knockdown increased and decreased adipocyte differentiation, respectively, and treatment of 3T3-L1 cells with a specific GluT5 inhibitor decreased adipocyte differentiation. Epidymal white adipose tissue was reduced in GluT5-/- mice compared with wild-type mice, and mouse embryonic fibroblasts derived from GluT5-/- mice exhibited impaired adipocyte differentiation. Taken together, these results demonstrate that fructose and GluT5 play an important role in regulating adipose differentiation.
Cushing disease (CD) is a life-threatening disorder attributed to excess pituitary tumor-derived adrenocorticotrophic hormone (ACTH) and adrenal steroid secretion caused by pituitary tumors. Whereas CD was first described in 1932, the underlying genetic basis driving tumor growth and ACTH secretion remains unsolved. Here, we show that testicular orphan nuclear receptor 4 (TR4, nuclear receptor subfamily 2, group C, member 2) is overexpressed in human corticotroph tumors as well as in human and mouse corticotroph tumor cell lines. Forced overexpression of TR4 in both human and murine tumor cells increased proopiomelanocortin transcription, ACTH secretion, cellular proliferation, and tumor invasion rates in vitro. Conversely, knockdown of TR4 expression reversed all phenotypes. Mechanistically, we show that TR4 transcriptionally activates proopiomelanocortin through binding of a direct repeat 1 response element in the promoter, and that this is enhanced by MAPK-mediated TR4 phosphorylation. In vivo, TR4 overexpression promotes murine corticotroph tumor growth as well as enhances ACTH and corticosterone production, whereas TR4 knockdown decreases circulating ACTH and corticosterone levels in mice harboring ACTH-secreting tumors. Our findings directly link TR4 to the etiology of corticotroph tumors, hormone secretion, and cell growth as well as identify it as a potential target in the treatment of CD.
Highlights d We identified an allosteric inhibitory site for an activating enzyme d The lead compound inhibits the ATP-dependent step of SUMO E1 catalysis d The compound has specificity to 1 out of 18 non-disulfide bonded Cys residues d The compound increased miR-34b and reduced c-Myc in cellular and xenograft models
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