Immunohistochemistry,glycosylation and immunosuppression of glycodelin in human ovarian cancer

Glycodelins (Gds) are glycoproteins with a gender specific glycosylation. Glycodelin A (GdA) is primarily produced in endometrial and decidual tissue and secreted to amniotic fluid. Glycodelins were also identified in several cancer types, including serous ovarian cancer. Gds act as a T-cell inhibitor and are involved in inactivation of human monocytes. With a Gd peptide antibody, derived from a 15 amino acid sequence of human Gd and in situ hybridization experiments, the expression of Gd in serous, mucinous, endometrioid and clear cell ovarian tumors was identified. In contrast to former investigations with antibodies against GdA, a positive immunohistochemical reaction for Gd was observed in all forms of epithelium ovarian cancer. These results were confirmed with in situ hybridization. In addition, Gd is expressed in granulose cell tumors, a non-epithelial form of ovarian cancer. Furthermore, Gd was purified from ascites fluid of ovarian cancer patients. Ascites Gd showed significant differences in its structure of sialyl Lewis-type oligosaccharides compared to GdA. Additionally, ascites Gd inhibits IL-2 stimulated proliferation of peripheral blood leucocytes and inhibits adhesion of SLe^X-positive cells to E-selectin. Therefore, Gd could act as an inhibitor of lymphocyte activation and/or adhesion in ovarian cancer. U. Jeschke, I. Mylonas and C. Kunert-Keil contributed equally to this work.     

Characterization of Determinants Important for Hepatitis C Virus p7 Function in Morphogenesis by Using trans-Complementation

Hepatitis C virus (HCV) p7 is an integral membrane protein that forms ion channels in vitro and that is crucial for the efficient assembly and release of infectious virions. Due to these properties, p7 was included in the family of viroporins that comprises proteins like influenza A virus M2 and human immunodeficiency virus type 1 (HIV-1) vpu, which alter membrane permeability and facilitate the release of infectious viruses. p7 from different HCV isolates sustains virus production with variable efficiency. Moreover, p7 determinants modulate processing at the E2/p7 and the p7/NS2 signal peptidase cleavage sites, and E2/p7 cleavage is incomplete. Consequently, it was unclear if a differential ability to sustain virus production was due to variable ion channel activity or due to alternate processing at these sites. Therefore, we developed a trans-complementation assay permitting the analysis of p7 outside of the HCV polyprotein and thus independently of processing. The rescue of p7-defective HCV genomes was accomplished by providing E2, p7, and NS2, or, in some cases, by p7 alone both in a transient complementation assay as well as in stable cell lines. In contrast, neither influenza A virus M2 nor HIV-1 vpu compensated for defective p7 in HCV morphogenesis. Thus, p7 is absolutely essential for the production of infectious HCV particles. Moreover, our data indicate that p7 can operate independently of an upstream signal sequence, and that a tyrosine residue close to the conserved dibasic motif of p7 is important for optimal virus production in the context of genotype 2a viruses. The experimental system described here should be helpful to investigate further key determinants of p7 that are essential for its structure and function in the absence of secondary effects caused by altered polyprotein processing.Hepatitis C virus (HCV) is a highly variable enveloped virus. It is the sole member of the genus Hepacivirus within the family Flaviviridae (36). Based on sequence homology, patient isolates are classified into seven genotypes and more than 100 subtypes (17, 52).The genome of HCV is a single-stranded RNA molecule of positive polarity with a size of ∼9.6 kb. It encodes a polyprotein of ca. 3,000 amino acids and contains nontranslated regions (NTRs) at both the 5′ and 3′ termini that are required for translation and RNA replication (33). Cellular and two viral proteases, NS2-3 and NS3-4A, liberate the individual viral proteins. The N-terminal portion of the polyprotein contains the structural proteins core and envelope glycoproteins 1 and 2 (E1, E2), which constitute the virus particle. These proteins are cleaved from the polyprotein by the host cell signal peptidase (18, 24). In the case of the core protein, an additional cleavage step mediated by the signal peptide peptidase liberates its mature C terminus (41). Further downstream of the structural proteins the polyprotein harbors p7, a short membrane-associated polypeptide required for virus assembly and release (27, 55), and the nonstructural (NS) proteins NS2, NS3, NS4A, NS4B, NS5A, and NS5B. Proteins NS3 to NS5B are the minimal components of the membrane-bound replication complexes that catalyze RNA replication (16, 38).Using the novel JFH1-based HCV infection model (35, 61, 65), it has been demonstrated recently that besides the canonical structural proteins core, E1, and E2, NS5A, p7, NS3, and NS2 also are crucial for the production of infectious HCV particles (1, 26, 27, 39, 40, 55, 57). These data highlight that HCV assembly and release is a coordinated process involving both structural and nonstructural proteins. However, how the aforementioned proteins contribute to the production of infectious virus particles remains poorly understood.HCV p7 comprises two helical domains connected by a polar loop. Studies with epitope-tagged p7 variants indicate that both termini of the protein are resident in the lumen of the endoplasmic reticulum (ER) (4) or that, in addition, a second alternative topology with the C terminus exposed to the cytoplasm can be adopted (25). Using such constructs for fluorescent microscopy, a complex localization of p7 was revealed. While most prominent staining generally was observed at the ER (4, 19, 23), pools of p7 also were detected at mitochondria (19) and at the plasma membrane (4). These data suggest that p7 influences virus replication at various sites within infected cells, and that the function and/or localization of p7 is regulated by different trafficking signals that could be exposed in a topology-dependent manner. However, caution is warranted since, due to the lack of antibodies, epitope-tagged p7 variants had to be employed for most analyses, and since localization studies of virus-producing cells with functional p7 still are lacking.One hallmark of p7 is its ability to form cation-selective channels in artificial membranes (20, 46, 49), a property that likely depends on the oligomerization of the protein (7, 21). There are intriguing correlations that link p7''s function as an ion channel protein in vitro to its role in the assembly and release of infectious HCV particles in tissue culture. First, the mutation of the conserved dibasic motif in the polar loop of p7 abrogates ion channel activity and interferes with virus production in tissue culture (20, 27, 55). Second, iminosugars coupled to long alkyl chains like N-nonyl deoxygalactonojirimycin (NN-DGJ) not only interfere with ion channel activity but also repress the release of infectious particles from transfected Huh-7 cells (46, 56). Taken together, these data suggest that the ion channel activity of p7 is crucial for its role in the late steps of the HCV replication cycle, and that this function is amenable to the development of selective inhibitors for antiviral therapy. However, presently it is unknown how mechanistically p7, as an ion channel protein, facilitates HCV assembly and release or if p7 also is a component of virus particles and participates in entry.Besides its function as an ion channel, p7 harbors a signal-like sequence in its C-terminal domain that directs the insertion of the N terminus of NS2 into the lumen of the ER (4). Strikingly, due to structural determinants within the C terminus of E2, p7, and the N terminus of NS2, signalase cleavages at the E2/p7 and the p7/NS2 sites are incomplete, thus yielding E2-p7-NS2 and E2-p7 precursor proteins (3, 18, 34, 42). Although these precursors are not absolutely essential for the production of infectious HCV particles (26, 27), a defined ratio between mature and precursor proteins might play a role to orchestrate optimal virus assembly. Given these circumstances, genetic studies of p7 function are complicated, since mutations may, on the one hand, affect ion channel activity, and on the other hand influence processing at the E2-p7 and p7-NS2 junctions.To circumvent this problem, in this study we developed a complementation system that permits the rescue of genomes with defects in p7 by the ectopic expression of p7 in trans. This enabled us to directly assess the function of p7 in the absence of secondary effects caused by aberrant polyprotein cleavage. Using this approach, we analyzed the role of the native signal sequence of p7 and p7-containing precursor proteins. In addition, we investigated key determinants that are essential for the optimal function of p7 in the course of HCV infectious particle production.     

CK2β interacts with and regulates p21-activated kinases in Drosophila

The role of CK2β has been defined as the regulatory subunit of protein kinase CK2, which is a heterotetrameric complex composed of two CK2β and two catalytic active CK2α subunits. The identification of other serine/threonine kinases such as A-Raf, Chk1, and c-Mos that interact with and are regulated by CK2β has challenged this view and provided evidence for functions of CK2β outside the CK2 holoenzyme. In this report we describe the first interaction of Drosophila CK2β outside the CK2 holoenzyme with p21-activated kinase (PAK) proteins. This interaction is seen for distinct PAK and CK2β isoforms. In contrast to the CK2α–CK2β interaction, dimer formation of the CK2β subunits is not a prerequisite for binding of PAK proteins. Our results support the idea that CK2β can bind to PAK proteins in a CK2α independent manner and negatively regulates PAK kinase activity.     

Description of Bryceella perpusilla n. sp. (Monogononta: Proalidae), a New Rotifer Species from Terrestrial Mosses,with Notes on the Ground Plan of Bryceella Remane, 1929

We here describe the new proalid rotifer species Bryceella perpusilla n. sp. on the basis of light and electron microscopy. The species, certainly representing one of the smallest rotifer and even metazoan species at all, was obtained in January 2008 from terrestrial mosses of North‐west Germany. Bryceella perpusilla n. sp. is distinguished from other species of the genus by the very small size, the slender body outline, the short apical styli, the triangular rostrum, the outward curving, blunt and rod‐shaped toes, the four‐nucleated vitellogermarium, the slender manubria and the caudally directed alulae. With our observations, that can be used for future cladistic analyses of the Proalidae, we are able to define the generic diagnosis of Bryceella more precisely and to give an adapted species key. (© 2010 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)     

CRK adaptor protein expression is required for efficient replication of avian influenza A viruses and controls JNK‐mediated apoptotic responses

The non‐structural protein 1 (A/NS1) of influenza A viruses (IAV) harbours several src‐homology domain (SH) binding motifs that are required for interaction with cellular proteins. The SH3 binding motif at aa212‐217 [PPLPPK] of A/NS1 was shown to be essential for binding to the cellular adaptor proteins CRK and CRKL. Both regulate diverse cellular effector pathways, including activation of the MAP‐kinase JNK that in turn mediates antiviral responses to IAV infection. By studying functional consequences of A/NS1–CRK interaction we show here that A/NS1 binding to CRK contributes to suppression of the antiviral‐acting JNK–ATF2 pathway. However, only IAV that encode an A/NS1‐protein harbouring the CRK/CRKL SH3 binding motif PPLPPK were attenuated upon downregulation of CRKI/II and CRKL, but not of CRKII alone. The PPLPPK site‐harbouring candidate strains could be discriminated from other strains by a pronounced viral activation of the JNK–ATF2 signalling module that was even further boosted upon knock‐down of CRKI/II. Interestingly, this enhanced JNK activation did not alter type‐I IFN‐expression, but rather resulted in increased levels of virus‐induced cell death. Our results imply that binding capacity of A/NS1 to CRK/CRKL has evolved in virus strains that over‐induce the antiviral acting JNK–ATF2 signalling module and helps to suppress the detrimental apoptosis promoting action of this pathway.     

Characterization of the early steps of hepatitis C virus infection by using luciferase reporter viruses

The lack of an efficient system to produce hepatitis C virus (HCV) particles has impeded the analysis of the HCV life cycle. Recently, we along with others demonstrated that transfection of Huh7 hepatoma cells with a novel HCV isolate (JFH1) yields infectious viruses. To facilitate studies of HCV replication, we generated JFH1-based bicistronic luciferase reporter virus genomes. We found that RNA replication of the reporter construct was only slightly attenuated and that virus titers produced were only three- to fivefold lower compared to the parental virus, making these reporter viruses an ideal tool for quantitative analyses of HCV infections. To expand the scope of the system, we created two chimeric JFH1 luciferase reporter viruses with structural proteins from the Con1 (genotype 1b) and J6CF (genotype 2a) strains. Using these and the authentic JFH1 reporter viruses, we analyzed the early steps of the HCV life cycle. Our data show that the mode of virus entry is conserved between these isolates and involves CD81 as a key receptor for pH-dependent virus entry. Competition studies and time course experiments suggest that interactions of HCV with cell surface-resident glycosaminoglycans aid in efficient infection of Huh7 cells and that CD81 acts during a postattachment step. The reporter viruses described here should be instrumental for investigating the viral life cycle and for the development of HCV inhibitors.     

Multi-host Model-Based Identification of Armillifer agkistrodontis (Pentastomida), a New Zoonotic Parasite from China

Background

Pentastomiasis is a rare parasitic infection of humans. Pentastomids are dioecious obligate parasites requiring multiple hosts to complete their lifecycle. Despite their worm-like appearance, they are commonly placed into a separate sub-class of the subphylum Crustacea, phylum Arthropoda. However, their systematic position is not uncontested and historically, they have been considered as a separate phylum.

Methodology/Principal Findings

An appraisal of Armillifer agkistrodontis was performed in terms of morphology and genetic identification after its lifecycle had been established in a multi-host model, i.e., mice and rats as intermediate hosts, and snakes (Agkistrodon acutus and Python molurus) as definitive hosts. Different stages of the parasite, including eggs, larvae and adults, were isolated and examined morphologically using light and electron microscopes. Phylogenetic and cluster analysis were also undertaken, focusing on the 18S rRNA and the Cox1 gene. The time for lifecycle completion was about 14 months, including 4 months for the development of eggs to infectious larvae in the intermediate host and 10 months for infectious larvae to mature in the final host. The main morphological difference between A. armillatus and Linguatula serrata is the number of abdominal annuli. Based on the 18S rRNA sequence, the shortest hereditary distance was found between A. agkistrodontis and Raillietiella spp. The highest degree of homology in the Cox 1 nucleic acid sequences and predicted amino acid sequences was found between A. agkistrodontis and A. armillatus.

Conclusion

This is the first time that a multi-host model of the entire lifecycle of A. agkistrodontis has been established. Morphologic and genetic analyses supported the notion that pentastomids should be placed into the phylum Arthropoda.     

A methodology for separating uncertainty and variability in the life cycle greenhouse gas emissions of coal-fueled power generation in the USA

Purpose

Results of life cycle assessments (LCAs) of power generation technologies are increasingly reported in terms of typical values and possible ranges. Extents of these ranges result from both variability and uncertainty. Uncertainty may be reduced via additional research. However, variability is a characteristic of supply chains as they exist; as such, it cannot be reduced without modifying existing systems. The goal of this study is to separately quantify uncertainty and variability in LCA.

Methods

In this paper, we present a novel method for differentiating uncertainty from variability in life cycle assessments of coal-fueled power generation, with a specific focus on greenhouse gas emissions. Individual coal supply chains were analyzed for 364 US coal power plants. Uncertainty in CO₂ and CH₄ emissions throughout these supply chains was quantified via Monte Carlo simulation. The method may be used to identify key factors that drive the range of life cycle emissions as well as the limits of precision of an LCA.

Results and discussion

Using this method, we statistically characterized the carbon footprint of coal power in the USA in 2009. Our method reveals that the average carbon footprint of coal power (100 year time horizon) ranges from 0.97 to 1.69 kg CO₂eq/kWh of generated electricity (95 % confidence interval), primarily due to variability in plant efficiency. Uncertainty in the carbon footprints of individual plants spans a factor of 1.04 for the least uncertain plant footprint to a factor of 1.2 for the most uncertain plant footprint (95 % uncertainty intervals). The uncertainty in the total carbon footprint of all US coal power plants spans a factor of 1.05.

Conclusions

We have developed and successfully implemented a framework for separating uncertainty and variability in the carbon footprint of coal-fired power plants. Reduction of uncertainty will not substantially reduce the range of predicted emissions. The range can only be reduced via substantial changes to the US coal power infrastructure. The finding that variability is larger than uncertainty can obviously not be generalized to other product systems and impact categories. Our framework can, however, be used to assess the relative influence of uncertainty and variability for a whole range of product systems and environmental impacts.     

Analysis of taxonomic and geographic patterns of Turkish Veronica orientalis using nuclear and plastid DNA and morphological data

Veronica orientalis and related species form one of the taxonomically most challenging subgroups within the genus Veronica. Hybridization and polyploidization on the one hand and convergent character evolution on the other have made delimitation of species difficult. Amplified fragment length polymorphisms and plastid DNA markers were used in conjunction with 54 morphological characters to study relationships among 35 accessions of V. orientalis Mill. as well as other closely related species of Veronica occurring in Turkey and adjacent areas of Georgia and Armenia. In addition, ploidy levels were estimated for 15 accessions using flow cytometry. Diploid to hexaploid individuals were detected in V. orientalis. Analysis of DNA markers demonstrated the non-monophyly of V. orientalis, especially with regard to V. fuhsii and V. multifida from Eastern Turkey, but nuclear and plastid DNA markers are largely incongruent. Neither demonstrates a clear biogeographic pattern. The morphological analysis reveals the distinction of V. orientalis subsp. carduchorum, which is weakly retrieved in some molecular analyses and some clustering according to geography. V. multifida is not monophyletic likely due to parallel evolution of pinnatifid leaves east and west of the Anatolian diagonal.     

Predator-induced flow disturbances alert prey,from the onset of an attack

Many prey species, from soil arthropods to fish, perceive the approach of predators, allowing them to escape just in time. Thus, prey capture is as important to predators as prey finding. We extend an existing framework for understanding the conjoint trajectories of predator and prey after encounters, by estimating the ratio of predator attack and prey danger perception distances, and apply it to wolf spiders attacking wood crickets. Disturbances to air flow upstream from running spiders, which are sensed by crickets, were assessed by computational fluid dynamics with the finite-elements method for a much simplified spider model: body size, speed and ground effect were all required to obtain a faithful representation of the aerodynamic signature of the spider, with the legs making only a minor contribution. The relationship between attack speed and the maximal distance at which the cricket can perceive the danger is parabolic; it splits the space defined by these two variables into regions differing in their values for this ratio. For this biological interaction, the ratio is no greater than one, implying immediate perception of the danger, from the onset of attack. Particular attention should be paid to the ecomechanical aspects of interactions with such small ratio, because of the high degree of bidirectional coupling of the behaviour of the two protagonists. This conclusion applies to several other predator–prey systems with sensory ecologies based on flow sensing, in air and water.