Grifolin derivatives from Albatrellus caeruleoporus, new inhibitors of nitric oxide production in RAW 264.7 cells

Two new farnesyl phenols named grifolinones A and B, together with known grifolin and neogrifolin, were isolated from methanolic extract of the inedible mushroom Albatrellus caeruleoporus. Their structures were characterized by a combination of 2D NMR, MS, IR, and UV spectra. Grifolinone B was composed of two grifolin molecules, which were connected by a C-C bond. Grifolinones A and B, grifolin, and neogrifolin exhibited inhibitory activity against nitric oxide (NO) production stimulated by lipopolysaccharide (LPS) in RAW 264.7 cells with IC50values of 23.4, 22.9, 29.0, and 23.3 microM, respectively.     

Molecular cloning and characterization of a Pichia pastoris ortholog of the yeast Golgi GDP-mannose transporter gene

There are two structural profiles in the yeast Golgi. The Golgi of Saccharomyces cerevisiae is composed of a number of vesicular compartments dispersed in the cytoplasm as recognized by a large number of Golgi marker proteins. In contrast, the Golgi of Pichia pastoris was reported to be organized in a small number of stacked cisternae located near the transitional endoplasmic reticulum (tER) sites by electron microscopy and immunofluorescent staining of a few marker proteins. The guanosine diphosphate (GDP)-mannose transporter (GMT) is an essential component in the yeast Golgi apparatus. We isolated an ortholog of the GMT gene of P. pastoris and visualized the gene product by epitope tagging to verify the structural characteristics of the Golgi. The tagged product in P. pastoris cell was observed in rod-like compartments in which Och1 mannosyltransferase was also found and the tER marker Sec12 and Sec13 proteins localized very close to them. The present results add further evidence of the restricted localization of the Golgi in P. pastoris cell.     

Effects of immunization with CCR5-based cycloimmunogen on simian/HIVSF162P3 challenge

A synthetic cycloimmunogen targeting the HIV-1 coreceptor CCR5 was evaluated for its capacity to induce CCR5-specific Abs with anti-HIV-1 activity in cynomolgus macaques. The cyclic closed-chain dodecapeptide (cDDR5) mimicking the conformation-specific domain of human CCR5 was chemically prepared, in which the Gly-Glu dipeptide links the amino and carboxy termini of the decapeptidyl linear chain (Arg168 to Thr177) derived from the undecapeptidyl arch (Arg168 to Cys178) of extracellular loop-2 in CCR5. The immunization of cynomolgus macaques with the cDDR5-conjugated multiple-Ag peptide (cDDR5-MAP) induced anti-cDDR5 serum production for approximately 15 wk after the third immunization. The antisera raised against cDDR5-MAP reacted with both human and macaque CCR5s, and potently suppressed infection by the R5 HIV-1 laboratory isolate (HIV JRFL), R5 HIV-1 primary isolates (clade A:HIV 93RW004 and clade C:HIV MJ4), and a pathogenic simian/HIV (SHIV SF162P3) bulk isolate in vitro. To examine the prophylactic efficacy of anti-CCR5 serum Ab for acute HIV-1 infection, cynomolgus macaques were challenged with SHIV SF162P3. The cDDR5-MAP immunization attenuated the acute phase of SHIV SF162P3 replication. The geometric mean plasma viral load in the vaccinated macaques was 217.10 times lower than that of the control macaques at 1 wk postchallenge. Taken together, these results suggest that cDDR5-MAP immunization is an effective prophylactic vaccine strategy that suppresses and delays viral propagation during the initial HIV-1 transmission for the containment of HIV-1 replication subsequent to infection.     

Molecular Mechanisms for the Variation of Mitochondrial Gene Content and Gene Arrangement Among Chigger Mites of the Genus Leptotrombidium (Acari: Acariformes)

The gene content of a mitochondrial (mt) genome, i.e., 37 genes and a large noncoding region (LNR), is usually conserved in Metazoa. The arrangement of these genes and the LNR is generally conserved at low taxonomic levels but varies substantially at high levels. We report here a variation in mt gene content and gene arrangement among chigger mites of the genus Leptotrombidium. We found previously that the mt genome of Leptotrombidium pallidum has an extra gene for large-subunit rRNA (rrnL), a pseudo-gene for small-subunit rRNA (PrrnS), and three extra LNRs, additional to the 37 genes and an LNR typical of Metazoa. Further, the arrangement of mt genes of L. pallidum differs drastically from that of the hypothetical ancestor of the arthropods. To find to what extent the novel gene content and gene arrangement occurred in Leptotrombidium, we sequenced the entire or partial mt genomes of three other species, L. akamushi, L. deliense, and L. fletcheri. These three species share the arrangement of all genes with L. pallidum, except trnQ (for tRNA-glutamine). Unlike L. pallidum, however, these three species do not have extra rrnL or PrrnS and have only one extra LNR. By comparison between Leptotrombidium species and the ancestor of the arthropods, we propose that (1) the type of mt genome present in L. pallidum evolved from the type present in the other three Leptotrombidium species, and (2) three molecular mechanisms were involved in the evolution of mt gene content and gene arrangement in Leptotrombidium species. [Reviewing Editor: Dr. Martin Kreitman]     

Effect of combination of nitric oxide synthase and cyclooxygenase inhibitors on carrageenan-induced pleurisy in rats

In the present study, we examined the effects of L-nitroarginine methylester (L-NAME), a non-selective nitric oxide synthase (NOS) inhibitor, indomethacin (IND), a non-selective COX inhibitor and a combination of these agents (L-NAME+IND) on carrageenan-induced pleurisy in rats. Exudate volume, albumin leakage, leukocyte influx, exudate and plasma nitrite/nitrate (NO(x)) levels and exudate PGE(2) levels increased markedly 6 h after an intrapleural injection of 2% carrageenan. First, the effects of L-NAME and IND alone were investigated. L-NAME non-significantly reduced exudate volume by 26% at 10 mg/kg (i.p.), and significantly by 45% at 30 mg/kg. IND dose-dependently decreased the exudate volume at 0.3-10 mg/kg (p.o.) and the effect reached the maximal level at 1 mg/kg (33%). Second, the effects of L-NAME (10 mg/kg, i.p.), IND (1 mg/kg, p.o.) and L-NAME+IND were examined. L-NAME and IND alone at the dose employed significantly reduced the exudate volume and albumin levels by 21-26%. L-NAME but not IND tended to reduce the increased exudate and plasma NO(x) by 18% and 19%, respectively. IND but not L-NAME significantly reduced leukocyte numbers and PGE(2) levels in the exudates by 25% and 77%, respectively. L-NAME+IND significantly reduced exudate volume, albumin leakage, leukocyte number, PGE(2) and NO(x) by 43%, 41%, 31%, 80% and 37%, respectively. The inhibitory effects of L-NAME+IND on exudate volume, albumin leakage and NO(x) levels were greater than those of L-NAME and IND alone. In conclusion, a non-selective NOS inhibitor and COX inhibitor showed anti-inflammatory effects at the early phase of carrageenan-induced pleurisy, and a combination of both inhibitors had a greater effect than each alone probably via the potentiation of NOS inhibition. The simultaneous inhibition of NOS and COX could be a useful approach in therapy for acute inflammation.     

Hydrophobic interaction chromatography in dual salt system increases protein binding capacity

Hydrophobic interaction chromatography (HIC) uses weakly hydrophobic resins and requires a salting‐out salt to promote protein–resin interaction. The salting‐out effects increase with protein and salt concentration. Dynamic binding capacity (DBC) is dependent on the binding constant, as well as on the flow characteristics during sample loading. DBC increases with the salt concentration but decreases with increasing flow rate. Dynamic and operational binding capacity have a major raw material cost/processing time impact on commercial scale production of monoclonal antibodies. In order to maximize DBC the highest salt concentration without causing precipitation is used. We report here a novel method to maintain protein solubility while increasing the DBC by using a combination of two salting‐out salts (referred to as dual salt). In a series of experiments, we explored the dynamic capacity of a HIC resin (TosoBioscience Butyl 650M) with combinations of salts. Using a model antibody, we developed a system allowing us to increase the dynamic capacity up to twofold using the dual salt system over traditional, single salt system. We also investigated the application of this novel approach to several other proteins and salt combinations, and noted a similar protein solubility and DBC increase. The observed increase in DBC in the dual salt system was maintained at different linear flow rates and did not impact selectivity. Biotechnol. Bioeng. 2009;103: 930–935. © 2009 Wiley Periodicals, Inc.     

The SUMO protease SENP1 is required for cohesion maintenance and mitotic arrest following spindle poison treatment

SUMO conjugation is a reversible posttranslational modification that regulates protein function. SENP1 is one of the six SUMO-specific proteases present in vertebrate cells and its altered expression is observed in several carcinomas. To characterize SENP1 role in genome integrity, we generated Senp1 knockout chicken DT40 cells. SENP1^−/− cells show normal proliferation, but are sensitive to spindle poisons. This hypersensitivity correlates with increased sister chromatid separation, mitotic slippage, and apoptosis. To test whether the cohesion defect had a causal relationship with the observed mitotic events, we restored the cohesive status of sister chromatids by introducing the TOP2α^+/− mutation, which leads to increased catenation, or by inhibiting Plk1 and Aurora B kinases that promote cohesin release from chromosomes during prolonged mitotic arrest. Although TOP2α is SUMOylated during mitosis, the TOP2α^+/− mutation had no obvious effect. By contrast, inhibition of Plk1 or Aurora B rescued the hypersensitivity of SENP1^−/− cells to colcemid. In conclusion, we identify SENP1 as a novel factor required for mitotic arrest and cohesion maintenance during prolonged mitotic arrest induced by spindle poisons.     

Real-time analysis of P-glycoprotein-mediated drug transport across primary intestinal epithelium three-dimensionally cultured in vitro

P-glycoprotein (P-gp) is an efflux transporter that regulates bioavailability of orally administered drugs at the intestinal epithelium. To develop an in vitro experimental model that mimics P-gp-mediated intestinal drug transport in vivo, we employed normal intestinal epithelium three-dimensionally cultured. Physiological expression of P-gp mRNA and the expression of its protein at the apical membrane were observed in the small intestinal epithelium grown as cystic organoids. Rhodamine123 (Rh123), a substrate for P-gp, was actively transported in the basoapical direction and accumulated in the luminal space, while the epithelial integrity was kept intact. Furthermore, we were able to monitor the whole process of Rh123 transport and its inhibition by verapamil in real-time, from which kinetic parameters for Rh123 transport could be estimated by a mathematical modeling. The method here described to evaluate the dynamics of P-gp-mediated transport in primary intestinal epithelial cells would be instrumental in investigating the physiological function of P-gp and its inhibitors/inducers in vitro.     

Structural basis for inhibition of xyloglucan-specific endo-β-1,4-glucanase (XEG) by XEG-protein inhibitor

Microorganisms such as plant pathogens secrete glycoside hydrolases (GHs) to digest the polysaccharide chains of plant cell walls. The degradation of cell walls by these enzymes is a crucial step for nutrition and invasion. To protect the cell wall from these enzymes, plants secrete glycoside hydrolase inhibitor proteins (GHIPs). Xyloglucan-specific endo-β-1,4-glucanase (XEG), a member of GH family 12 (GH12), could be a great threat to many plants because xyloglucan is a major component of the cell wall in most plants. Understanding the inhibition mechanism of XEG by GHIP is therefore of great importance in the field of plant defense, but to date the mechanism and specificity of GHIPs remain unclear. We have determined the crystal structure of XEG in complex with extracellular dermal glycoprotein (EDGP), a carrot GHIP that inhibits XEG. The structure reveals that the conserved arginines of EDGP intrude into the active site of XEG and interact with the catalytic glutamates of the enzyme. We have also determined the crystal structure of the XEG-xyloglucan complex. These structures show that EDGP closely mimics the XEG-xyloglucan interaction. Although EDGP shares structural similarity to a wheat GHIP (Triticum aestivum xylanase inhibitor-IA (TAXI-IA)) that inhibits GH11 family xylanases, the arrangement of GH and GHIP in the XEG-EDGP complex is distinct from that in the xylanase-TAXI-IA complex. Our findings imply that plants have evolved structures of GHIPs to inhibit different GH family members that attack their cell walls.