Nuclear localization and DNA interaction of protein disulfide isomerase ERp57 in mammalian cells

Protein disulfide isomerase ERp57 is localized predominantly in the endoplasmic reticulum, but is also present in the cytosol and, according to preliminary evidence, in the nucleus of avian cells. Conclusive evidence of its nuclear localization and of its interaction with DNA in vivo in mammalian cells is provided here on the basis of DNA-protein cross-linking experiments performed with two different cross-linking agents on viable HeLa and 3T3 cells. Nuclear ERp57 could also be detected by immunofluorescence in HeLa cells, where it showed an intracellular distribution clearly different from that of an homologous protein, located exclusively in the endoplasmic reticulum. Mammalian ERp57 resembles the avian protein in its recognition of S/MAR-like DNA sequences and in its association with the nuclear matrix. It can be hypothesized that ERp57, which is known to associate with other proteins, in particular STAT3 and calreticulin, may contribute to their nuclear import, DNA binding, or other functions that they fulfil inside the nucleus.     

A novel synthesis of 2-arylpyrrolo[1,2-a]pyrimid-7-ones and their structure-activity relationships as potent GnRH receptor antagonists

In the process of developing GnRH receptor antagonists, a novel base-catalyzed cyclization of compounds 5a-b was discovered, which led to the formation of the 2-aryl pyrrolo[1,2-a]pyrimid-7-one core structures 6a-b. These intermediates were further modified at positions 1, 2, 4 and 6 to afford a series of potent GnRH antagonists with low nanomolar K(i) values.     

Dynamics of green fluorescent protein mutant2 in solution, on spin-coated glasses, and encapsulated in wet silica gels

Single-molecule experiments are performed by investigating spectroscopic properties of molecules either diffusing in and out of the observation volume or fixed in space by different immobilization procedures. To evaluate the effect of immobilization methods on the structural and dynamic properties of proteins, a highly fluorescent mutant of the green fluorescent protein, GFPmut2, was spectroscopically characterized in bulk solutions, dispersed on etched glasses, and encapsulated in wet, nanoporous silica gels. The emission spectrum, the fluorescence lifetimes, the anisotropy, and the rotational correlation time of GFPmut2, encapsulated in silica gels, are very similar to those obtained in solution. This finding indicates that the gel matrix does not alter the protein conformation and dynamics. In contrast, the fluorescence lifetimes of GFPmut2 on glasses are two-to fourfold higher and the fluorescence anisotropy decays yield almost no phase shifts. This indicates that the interaction of the protein with the bare glass surface induces a significant structural perturbation and severely restricts the rotational motion. Single molecules of GFPmut2 on glasses or in silica gels, identified by confocal image analysis, show a significant stability to illumination with bleaching times of the order of 90 and 60 sec, respectively. Overall, these data indicate that silica gels represent an ideal matrix for following biologically relevant events at a single molecule level.     

Folding and oxidation of the antibody domain C(H)3

The non-covalent homodimer formed by the C-terminal domains of the IgG1 heavy chains (C(H)3) is the simplest naturally occurring model system for studying immunoglobulin folding and assembly. In the native state, the intrachain disulfide bridge, which connects a three-stranded and a four-stranded beta-sheet is buried in the hydrophobic core of the protein. Here, we show that the disulfide bridge is not required for folding and association, since the reduced C(H)3 domain folds to a dimer with defined secondary and tertiary structure. However, the thermodynamic stability of the reduced C(H)3 dimer is much lower than that of the oxidized state. This allows the formation of disulfide bonds either concomitant with folding (starting from the reduced, denatured state) or after folding (starting from the reduced dimer). The analysis of the two processes revealed that, under all conditions investigated, one of the cysteine residues, Cys 86, reacts preferentially with oxidized glutathione to a mixed disulfide that subsequently interacts with the less-reactive second thiol group of the intra-molecular disulfide bond. For folded C(H)3, the second step in the oxidation process is slow. In contrast, starting from the unfolded and reduced protein, the oxidation reaction is faster. However, the overall folding reaction of C(H)3 during oxidative folding is a slow process. Especially, dimerization is slow, compared to the association starting from the denatured oxidized state. This deceleration may be due to misfolded conformations trapped by the disulfide bridge.     

Assembly,stability and integrity of basement membranes in vivo

Basement membranes are layered structures of the extracellular matrix which separate cells of various kinds from the surrounding stroma. One of the frequently recurring questions about basement membranes is how these structures are formed in vivo. Up to a few years ago, it was thought that basement membranes were formed spontaneously by a process of self-assembly of their components. However, it has now become clear that cell membrane receptors for basement membrane components are essential factors for the formation and stability of basement membranes in vivo. The present review highlights the modern concepts of basement membrane formation.     

Monomeric recombinant MD-2 binds toll-like receptor 4 tightly and confers lipopolysaccharide responsiveness

In order to mediate cellular response to lipopolysaccharide (LPS), Toll-like receptor (TLR) 4 must interact with MD-2, a secreted protein. In this study, a biochemical assay was developed to demonstrate that recombinant MD-2 can interact with the extracellular portion of TLR4 in solution. The ability of MD-2 to multimerize was confirmed, and MD-1 was also shown to possess this ability. Through site-directed mutagenesis, more than two intermolecular disulfide bonds were found to stabilize the MD-2 multimer. MD-2's abilities to confer LPS responsiveness and to bind TLR4 were strongly associated functions. Remarkably, although the majority of recombinant MD-2 exists in multimeric form, monomeric MD-2 was found to preferentially bind TLR4 and to confer LPS responsiveness more efficiently than MD-2 multimers.     

Editing autoreactive TCR enables efficient positive selection

Allelic exclusion is inefficient at the TCRalpha locus, allowing a sizeable portion of T cells to carry two functional TCRs. The potential danger of dual TCR expression is a rescue of autoreactive TCRs during selection in the thymus and subsequent development of autoimmunity. In this study, we examine the reason(s) for replacing an autoreactive TCR and for allowing the survival of cells carrying two TCRs. We compared development of TCR transgenic CD4(+)CD8(-) thymocytes in the presence or absence of MHC class II autoantigen that does not induce deletion of thymocytes. Contrary to the expected negative effect of the presence of autoantigen, approximately 100% more CD4(+)CD8(-) thymocytes were found in the presence of MHC class II autoantigen than in the neutral background. A further increase in the strength of autoantigenic signal via expression of a human CD4 transgene led to an additional increase in the numbers of CD4(+)CD8(-) thymocytes. Thus, editing autoreactive TCR results in more efficient positive selection, and this may be both a reason and a reward for risking autoimmunity.     

Immunoprecipitation of DNA-protein complexes cross-linked by cis-diamminedichloroplatinum

For the study of in vitro and in vivo DNA-protein interactions, cross-linking reactions driven by UV or formaldehyde have been frequently used, followed by standard protocols of immunoprecipitation and analysis of the DNA isolated from the complexes. Here we present a basically modified method to analyze the DNA-protein cross-linked complexes obtained by an alternative cross-linking reagent. The innovations presented here include cross-linking by cis-diamminedichloroplatinum II, a fast method to isolate DNA-protein complexes using gel-filtration chromatography, and a modified procedure to obtain specific immunocomplexes that can be analyzed either for DNA or for protein content. The application of this method to two nuclear proteins from chicken liver nuclei is described.     

Ethylene emission and responsiveness to applied ethylene vary among Poa species that inherently differ in leaf elongation rates

A plant's ability to produce and respond to ethylene is essential for its vegetative growth. We studied whole-shoot ethylene emission and leaf growth responses to applied ethylene in four Poa spp. that differ inherently in leaf elongation rate and whole-plant relative growth rate. Compared with the fast-growing Poa annua and Poa trivialis, the shoots of the slow-growing species Poa alpina and Poa compressa emitted daily 30% to 50% less ethylene, and their leaf elongation rate was more strongly inhibited when ethylene concentration was increased up to 1 microL L(-1). To our surprise, however, low ethylene concentrations (0.02-0.03 microL L(-1)) promoted leaf growth in the two slow-growing species; at the same concentrations, leaf elongation rate of the two fast-growing species was only slightly inhibited. All responses were observed within 20 min after ethylene applications. Although ethylene generally inhibits growth, our results show that in some species, it may actually stimulate growth. Moreover, in the two slow-growing Poa spp., both growth stimulation and inhibition occurred in a narrow ethylene concentration range, and this effect was associated with a much lower ethylene emission. These findings suggest that the regulation of ethylene production rates and perception of the gas may be more crucial during leaf expansion of these species under non-stressful conditions and that endogenous ethylene concentrations are not large enough to saturate leaf growth responses. In the two fast-growing species, a comparatively higher ethylene endogenous concentration may conversely be present and sufficiently high to saturate leaf elongation responses, invariably leading to growth inhibition.