Properties of anti-gp41 core structure antibodies, which compete with sera of HIV-1-infected patients

To determine the correlation between the immunoreaction against the core structure of human immunodeficiency virus type (HIV-1) transmembrane protein gp41 epitopes and the disease progression, it is essential to evaluate the anti-core structure antibody epitopes and the humoral immunity against the epitopes. For this purpose we evaluated monoclonal antibodies (mAbs) against the gp41 core structure such as mAbs 50.69, 98.6 and T26, by Western blotting (WB) and flow cytometry. WB showed mAbs 50.69 and 98.6 bound to both monomeric and oligomeric gp41, and mAb T26 exclusively bound to oligomeric gp41. We evaluated the sera from Pneumocystis pneumonia patients (PCP; n=7) and long-term survivors (LTS; n=7). Competition assay with sera and mAbs for binding to H9 cells infected with HIV-1 IIIB virus was done using flow cytometry. The results revealed that PCP sera as well as LTS sera inhibited the binding of all the three mAbs, and the PCP sera inhibited mAb T26 binding more efficiently than LTS. Therefore, PCP patients retain competing immunity to antibodies against not only the shared epitopes of the core structure (binding sites of mAbs 50.69 and 98.6) but also against oligomeric gp41 specific epitope (binding site of mAb T26).     

Discovery of diphenylcarbamate derivatives as highly potent and selective IP receptor agonists: orally active prostacyclin mimetics. Part 3

The new classes of diphenylcarbamate derivatives with a tetrahydronaphthalene skeleton as highly potent and selective IP agonists have been discovered. The optimized diphenylcarbamate type compound FK-788: (R)-4 exhibited potent antiaggregative potency with an IC50 of 18 nM and high binding affinity for the human recombinant IP receptor with K(i) values of 20 nM and selectivity for human IP over all other members of the human prostanoid receptor family. Compound (R)-4 was shown to exhibit good pharmacokinetic properties in rats and dogs, and also good bioavailability in healthy volunteers.     

Organic solvent tolerance of halophilic α-amylase from a Haloarchaeon, Haloarcula sp. strain S-1

A halophilic archaeon, Haloarcula sp. strain S-1, produced extracellular organic solvent-tolerant -amylase. Molecular mass of the enzyme was estimated to be 70 kDa by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. This amylase exhibited maximal activity at 50°C in buffer containing 4.3 M NaCl, pH 7.0. Moreover, the enzyme was active and stable in various organic solvents (benzene, toluene, and chloroform, etc.). Activity was not detected at low ionic strengths, but it was detected in the presence of chloroform at low salt concentrations. On the other hand, no activity was detected in the presence of ethyl alcohol and acetone.     

Endospores of halophilic bacteria of the family Bacillaceae isolated from non-saline Japanese soil may be transported by Kosa event (Asian dust storm)

Background

Natural microbial communities are extremely complex and dynamic systems in terms of their population structure and functions. However, little is known about the in situ functions of the microbial communities.

Results

This study describes the application of proteomic approaches (metaproteomics) to observe expressed protein profiles of natural microbial communities (metaproteomes). The technique was validated using a constructed community and subsequently used to analyze Chesapeake Bay microbial community (0.2 to 3.0 μm) metaproteomes. Chesapeake Bay metaproteomes contained proteins from pI 4–8 with apparent molecular masses between 10–80 kDa. Replicated middle Bay metaproteomes shared ~92% of all detected spots, but only shared 30% and 70% of common protein spots with upper and lower Bay metaproteomes. MALDI-TOF analysis of highly expressed proteins produced no significant matches to known proteins. Three Chesapeake Bay proteins were tentatively identified by LC-MS/MS sequencing coupled with MS-BLAST searching. The proteins identified were of marine microbial origin and correlated with abundant Chesapeake Bay microbial lineages, Bacteroides and α-proteobacteria.

Conclusion

Our results represent the first metaproteomic study of aquatic microbial assemblages and demonstrate the potential of metaproteomic approaches to link metagenomic data, taxonomic diversity, functional diversity and biological processes in natural environments.     

Structural and functional characterization of rabbit and human L-gulonate 3-dehydrogenase

L-Gulonate 3-dehydrogenase (GDH) catalyzes the NAD(+)-linked dehydrogenation of L-gulonate into dehydro-L-gulonate in the uronate cycle. In this study, we isolated the enzyme and its cDNA from rabbit liver, and found that the cDNA is identical to that for rabbit lens lambda-crystallin except for lacking a codon for Glu(309). The same cDNA species, but not the lambda-crystallin cDNA with the codon for Glu(309), was detected in the lens, which showed the highest GDH activity among rabbit tissues. In addition, recombinant human lambda-crystallin that lacks Glu(309) displays enzymatic properties similar to rabbit GDH. These data indicate that GDH is recruited as lambda-crystallin without gene duplication. An outstanding feature of GDH is modulation of its activity by low concentrations of P(i), which decreases the catalytic efficiency in a dose dependent manner. P(i) also protects the enzyme against both thermal and urea denaturation. Kinetic analysis suggests that P(i) binds to both the free enzyme and its NAD(H)-complex in the sequential ordered mechanism. Furthermore, we examined the roles of Asp(36), Ser(124), His(145), Glu(157 )and Asn(196) in the catalytic function of rabbit GDH by site-directed mutagenesis. The D36R mutation leads to a switch in favor of NADP(H) specificity, suggesting an important role of Asp(36) in the coenzyme specificity. The S124A mutation decreases the catalytic efficiency 500-fold, and the H145Q, N196Q and N195D mutations result in inactive enzyme forms, although the E157Q mutation produces no large kinetic alteration. Thus, Ser(124), His(145) and Asn(196) may be critical for the catalytic function of GDH.     

Oxidative modification of proteasome: identification of an oxidation-sensitive subunit in 26 S proteasome

Reactive oxygen species (ROS) have the potential to damage cellular components, such as protein, resulting in loss of function and structural alteration of proteins. The oxidative process affects a variety of side amino acid groups, some of which are converted to carbonyl compounds. We have previously shown that a prostaglandin D2 metabolite, 15-deoxy-delta(12,14)-prostaglandin J2 (15d-PGJ2), is the potent inducer of intracellular oxidative stress on human neuroblastoma SH-SY5Y cells [Kondo, M., Oya-Ito, T., Kumagai, T., Osawa, T., and Uchida, K. (2001) Cyclopentenone prostaglandins as potential inducers of intracellular oxidative stress, J. Biol. Chem. 276, 12076-12083]. In the present study, to elucidate the molecular mechanism underlying the oxidative stress-mediated cell degeneration, we analyzed the protein carbonylation on SH-SY5Y cells when these cells were submitted to an endogenous inducer of ROS production. Upon exposure of SH-SY5Y cells to this endogenous electrophile, we observed significant accumulation of protein carbonyls within the cells. Proteomic analysis of oxidation-sensitive proteins showed that the major intracellular target of protein carbonylation was one of the regulatory subunits in 26 S proteasome, S6 ATPase. Accompanied by a dramatic increase in protein carbonyls within S6 ATPase, the electrophile-induced oxidative stress exerted a significant decrease in the S6 ATPase activities and a decreased ability of the 26 S proteasome to degrade substrates. Moreover, in vitro oxidation of 26 S proteasome with a metal-catalyzed oxidation system also confirmed that S6 ATPase represents the most oxidation-sensitive subunit in the proteasome. These and the observation that down-regulation of S6 ATPase by RNA interference resulted in the enhanced accumulation of ubiquitinated proteins suggest that S6 ATPase is a molecular target of ROS under conditions of electrophile-induced oxidative stress and that oxidative modification of this regulatory subunit of proteasome may be functionally associated with the altered recognition and degradation of proteasomal substrates in the cells.     

Differential inhibition of membrane type 3 (MT3)-matrix metalloproteinase (MMP) and MT1-MMP by tissue inhibitor of metalloproteinase (TIMP)-2 and TIMP-3 rgulates pro-MMP-2 activation

The membrane type (MT)-matrix metalloproteinases (MMPs) constitute a subgroup of membrane-anchored MMPs that are major mediators of pericellular proteolysis and physiological activators of pro-MMP-2. The MT-MMPs also exhibit differential inhibition by members of the tissue inhibitor of metalloproteinase (TIMP) family. Here we investigated the processing, catalytic activity, and TIMP inhibition of MT3-MMP (MMP-16). Inhibitor profile and mutant enzyme studies indicated that MT3-MMP is regulated on the cell surface by autocatalytic processing and ectodomain shedding. Inhibition kinetic studies showed that TIMP-3 is a high affinity inhibitor of MT3-MMP when compared with MT1-MMP (K(i) = 0.008 nm for MT3-MMP versus K(i) = 0.16 nm for MT1-MMP). In contrast, TIMP-2 is a better inhibitor of MT1-MMP. MT3-MMP requires TIMP-2 to accomplish full pro-MMP-2 activation and this process is enhanced in marimastatpretreated cells, consistent with regulation of active enzyme turnover by synthetic MMP inhibitors. TIMP-3 also enhances the activation of pro-MMP-2 by MT3-MMP but not by MT1-MMP. TIMP-4, in contrast, cannot support pro-MMP-2 activation with either enzyme. Affinity chromatography experiments demonstrated that pro-MMP-2 can assemble trimolecular complexes with a catalytic domain of MT3-MMP and TIMP-2 or TIMP-3 suggesting that pro-MMP-2 activation by MT3-MMP involves ternary complex formation on the cell surface. These results demonstrate that TIMP-3 is a major regulator of MT3-MMP activity and further underscores the unique interactions of TIMPs with MT-MMPs in the control of pericellular proteolysis.