A Role for Stefin B (Cystatin B) in Inflammation and Endotoxemia

Stefin B (cystatin B) is an endogenous cysteine cathepsin inhibitor, and the loss-of-function mutations in the stefin B gene were reported in patients with Unverricht-Lundborg disease (EPM1). In this study we demonstrated that stefin B-deficient (StB KO) mice were significantly more sensitive to the lethal LPS-induced sepsis and secreted higher amounts of pro-inflammatory cytokines IL-1β and IL-18 in the serum. We further showed that increased caspase-11 gene expression and better pro-inflammatory caspase-1 and -11 activation determined in StB KO bone marrow-derived macrophages resulted in enhanced IL-1β processing. Pretreatment of macrophages with the cathepsin inhibitor E-64d did not affect secretion of IL-1β, suggesting that the increased cathepsin activity determined in StB KO bone marrow-derived macrophages is not essential for inflammasome activation. Upon LPS stimulation, stefin B was targeted into the mitochondria, and the lack of stefin B resulted in the increased destabilization of mitochondrial membrane potential and mitochondrial superoxide generation. Collectively, our study demonstrates that the LPS-induced sepsis in StB KO mice is dependent on caspase-11 and mitochondrial reactive oxygen species but is not associated with the lysosomal destabilization and increased cathepsin activity in the cytosol.     

Monitoring lysosomal fusion in electrofused hybridoma cells

Dendritic and tumor cells are fused to produce hybridoma cells, which are considered to be used as cellular vaccines to treat cancer. Previous strategies for hybridoma cell production were based on the quantification of the electrofusion yield by labeling the cytoplasm of both parental cell types. However, a better physiological strategy would be to label subcellular structures related directly to the antigen presentation process. Therefore, we here electrofused the same amount of CHO cells stained with red and green fluorescent dextrans and have monitored the yield of hybridoma cell formation by measuring the fusion of red and green late endocytic organelles that are involved in antigen presentation. By using confocal microscopy, the level of fused, fluorescently labelled late endocytic compartments in a single hybridoma cell was determined. The results demonstrate that organellar fusion occurs in hybridomas, which is time- and temperature-dependent. This approach therefore provides a new method for the hybridoma cell vaccine evaluation, which is based on the intracellular physiological mechanism of antigen presentation.     

Host physiological status determines phage-like particle distribution in the lysate

Bacteriophage morphotype diversity and latent period duration upon induction were correlated with the host population growth. The prophages of the lysogenic Vibrio sp. (DSM14379) were induced with mitomycin C in a batch culture with different salinity, substrate concentration or composition, and at different temperatures. Under all experimental conditions, phages were induced and a population of different complete and incomplete phage-like particles was observed in the lysate. Under favorable growth conditions, the phage-like particle community in the lysate was overpopulated with phage tail-like rigid rods. The number of rods was reduced in samples with low organic carbon concentration, samples with 8% and 10% NaCl, and samples induced at 40 and 43 degrees C. Although all lysates contained all phage-like particle-size fractions, their relative abundances varied. Up to a fivefold difference in phage-like particle size was observed in lysates. Size distribution of phage-like particles changed along temperature, salinity and organic carbon gradients. Results also indicated that the latent period of the induced phage-like particle population converged to approximately 90 min above a growth rate of 1.0 h(-1). At lower host growth rates, the latent period generally increased. However, at 40 and 43 degrees C and at low peptone-yeast extract concentration in the growth medium, the latent period remained short. We propose that different host physiological conditions influence organic matter composition upon prophage induction and may thus affect virus-controlled flow of the energy and carbon in the ecosystem.     

BRCA2 gene mutations in Slovenian male breast cancer patients

Male breast cancer (MBC) is a rare disease, comprising less than 1% of breast cancer patients in Slovenia. Some inherited cases are due to the mutations of BRCA1 or BRCA2 genes. There is no information available about the frequency of BRCA gene mutations in Slovenian MBC population. The purpose of this study was to characterize BRCA germline mutations in Slovenian MBC patients. Forty-one patients who were diagnosed with breast cancer at the Institute of Oncology Ljubljana between 1970 and 2006 were proposed to take part in this study. Of them, 27 agreed to follow a genetic counseling session and 25 patients agreed to provide a blood sample for genetic testing. The BRCA1 and BRCA2 genes from the MBC patients were screened for four highly recurrent mutations in the Slovenian population. When an additional breast cancer case or an ovarian cancer was present in the family, a more extended analysis was performed. No BRCA1 mutations were found. A BRCA2 gene mutation was identified in four MBC patients. Three of them carried the Slovenian founder mutation IVS16-2A>G. All four mutations were confined to the patients with a family history of breast cancer. Among the MBC patients with a family history of breast cancer in the first- or second-degree relatives, the frequency of BRCA2 gene mutation was 50%. The median age of the patients with a BRCA2 gene mutation was 60 years, not significantly different from those without a mutation. The BRCA2 mutations were diagnosed in 16% of our MBC patients.     

Globular domain of the prion protein needs to be unlocked by domain swapping to support prion protein conversion

Prion diseases are fatal transmissible neurodegenerative diseases affecting many mammalian species. The normal prion protein (PrP) converts into a pathological aggregated form, PrPSc, which is enriched in the β-sheet structure. Although the high resolution structure of the normal PrP was determined, the structure of the converted form of PrP remains inaccessible to high resolution techniques. To map the PrP conversion process we introduced disulfide bridges into different positions within the globular domain of PrP, tethering selected secondary structure elements. The majority of tethered PrP mutants exhibited increased thermodynamic stability, nevertheless, they converted efficiently. Only the disulfides that tether subdomain B1-H1-B2 to subdomain H2-H3 prevented PrP conversion in vitro and in prion-infected cell cultures. Reduction of disulfides recovered the ability of these mutants to convert, demonstrating that the separation of subdomains is an essential step in conversion. Formation of disulfide-linked proteinase K-resistant dimers in fibrils composed of a pair of single cysteine mutants supports the model based on domain-swapped dimers as the building blocks of prion fibrils. In contrast to previously proposed structural models of PrPSc suggesting conversion of large secondary structural segments, we provide evidence for the conservation of secondary structural elements of the globular domain upon PrP conversion. Previous studies already showed that dimerization is the rate-limiting step in PrP conversion. We show that separation and swapping of subdomains of the globular domain is necessary for conversion. Therefore, we propose that the domain-swapped dimer of PrP precedes amyloid formation and represents a potential target for therapeutic intervention.     

The structure of Yersinia pestis V-antigen, an essential virulence factor and mediator of immunity against plague

The LcrV protein (V-antigen) is a multifunctional virulence factor in Yersinia pestis, the causative agent of plague. LcrV regulates the translocation of cytotoxic effector proteins from the bacterium into the cytosol of mammalian cells via a type III secretion system, possesses antihost activities of its own, and is also an active and passive mediator of resistance to disease. Although a crystal structure of this protein has been actively sought for better understanding of its role in pathogenesis, the wild-type LcrV was found to be recalcitrant to crystallization. We employed a surface entropy reduction mutagenesis strategy to obtain crystals of LcrV that diffract to 2.2 A and determined its structure. The refined model reveals a dumbbell-like molecule with a novel fold that includes an unexpected coiled-coil motif, and provides a detailed three-dimensional roadmap for exploring structure-function relationships in this essential virulence determinant.     

Interaction of the HIV-1 gp120 viral protein V3 loop with bacterial lipopolysaccharide: a pattern recognition inhibition

HIV-1 represents an elusive target for therapeutic compounds due to its high rate of mutation. Targeting structural patterns instead of a constantly changing specific three-dimensional structure may represent an approach that is less sensitive to viral mutations. The V3 loop of gp120 of HIV-1, which is responsible for binding of viral gp120 to CCR5 or CXCR4 coreceptors, has already been identified as an effective target for the inhibition of viral entry. The peptide derived from the V3 loop of gp120 specifically interacts with the lipid A moiety of LPS, as does the full gp120 protein. NMR analysis of V3 in complex with LPS shows formation of an amphipathic turn. The interaction between LPS and V3 relies on the structural pattern, comprising a combination of hydrophobic and charge interactions, similar to the interaction between antimicrobial peptides and LPS. LPS inhibited binding of gp120 to the surface of target T cells. Nonendotoxic LPS antagonists inhibited viral infection, demonstrating the possibility for the development of an inhibitor of HIV-1 attachment to T cells based on the recognition of a conserved structural pattern.     

Freeze-fracture replica immunolabelling reveals urothelial plaques in cultured urothelial cells

The primary function of the urothelium is to provide the tightest and most impermeable barrier in the body, i.e. the blood-urine barrier. Urothelial plaques are formed and inserted into the apical plasma membrane during advanced stages of urothelial cell differentiation. Currently, it is supposed that differentiation with the final formation of urothelial plaques is hindered in cultured urothelial cells. With the aid of the high-resolution imaging technique of freeze-fracture replica immunolabelling, we here provide evidence that urothelial cells in vitro form uroplakin-positive urothelial plaques, localized in fusiform-shaped vesicles and apical plasma membranes. With the establishment of such an in vitro model of urothelial cells with fully developed urothelial plaques and functional properties equivalent to normal bladder urothelium, new perspectives have emerged which challenge prevailing concepts of apical plasma membrane biogenesis and blood-urine barrier development. This may hopefully provide a timely impulse for many ongoing studies and open up new questions for future research.     

Erythropoietin unfolding: thermodynamics and its correlation with structural features

Human erythropoietin (EPO) is a glycoprotein hormone considered to be the principal regulator of red blood cell formation. Although its recombinant version (rEPO) has been widely used for treatment of various anemias and its biological effects are relatively well-known, we know little about its biophysical properties and their relation to its structure. To gain a fuller understanding of the structural and functional properties of rEPO on the molecular level we followed its thermal and urea-induced unfolding at different pH (3.1-9.4) and urea concentrations (0-8 M) using spectropolarimetry, UV absorption, intrinsic emission fluorescence, and differential scanning calorimetry. Our results show that under a variety of conditions rEPO undergoes thermal or urea-induced denaturation that may be considered as a reversible two-state process characterized by unusually high (thermal) or moderate (urea-induced) extent of the residual structure. The highest thermal stability of the protein observed in aqueous solutions at physiological pH appears to be due to the largest difference in the extent of structure in the denatured and native state at this pH. The comparison between experimentally determined energetics of rEPO denaturation and its structure-based calculations indicates that the parametrization of thermodynamic quantities in terms of changes in solvent accessible nonpolar and polar surface areas resulting from protein unfolding can be successfully used provided that these changes are estimated from combination of experimentally determined deltaC(o)p and deltaH(o) values and not calculated from the structure of the protein's folded and assumingly fully unfolded state.