Proliferating cell nuclear antigen (PCNA) as a proliferative marker during embryonic and adult zebrafish hematopoiesis

We investigated the expression of proliferative cell nuclear antigen (PCNA) in zebrafish to delineate the proliferative hematopoietic component during adult and embryonic hematopoiesis. Immunostaining for PCNA and enhanced green fluorescence protein (eGFP) was performed in wild-type and fli1-eGFP (endothelial marker) and gata1-eGFP (erythroid cell marker) transgenic fish. Expression of PCNA mRNA was examined in wild-type and chordin morphant embryos. In adult zebrafish kidney, the renal tubules are surrounded by endothelial cells and it is separated into hematopoietic and excretory compartments. PCNA was expressed in hematopoietic progenitor cells but not in mature neutrophils, eosinophils or erythroid cells. Some PCNA+ cells are scattered in the hematopoietic compartment of the kidney while others are closely associated with renal tubular cells. PCNA was also expressed in spermatogonial stem cells and intestine crypts, consistent with its role in cell proliferation and DNA synthesis. In embryos, PCNA is expressed in the brain, spinal cord and intermediate cell mass (ICM) at 24 h-post fertilization. In chordin morphants, PCNA is significantly upregulated in the expanded ICM. Therefore, PCNA can be used to mark cell proliferation in zebrafish hematopoietic tissues and to identify a population of progenitor cells whose significance would have to be further investigated.     

Human protease nexin-I. Further characterization using a highly specific polyclonal antibody

We have used purified protease nexin-I (PN-I) from human fibroblasts to develop a polyclonal antibody that specifically blocks the PN-I-mediated cellular binding of thrombin and urokinase. Anti-PN-I IgG did not inhibit the binding of 125I-epidermal growth factor-binding protein to fibroblasts, which is mediated by protease nexin-II, another cell-secreted, serine protease inhibitor that is distinct from PN-I. This furthers the belief that the protease nexins are distinct from one another. In addition, while anti-PN-I IgG immunoprecipitated PN-I X thrombin complexes, it did not do so with antithrombin-III X thrombin. Metabolically labeled PN-I was also immunoprecipitated by IgG, indicating that the protein can be labeled in vivo. The antibody also recognized primarily one band on Western transfers of conditioned medium from fibroblast cultures. These results suggest that anti-PN-I will be useful in probing the physiological role of PN-I as well as its biosynthesis.     

Biosynthesis of protease nexin-I

Protease nexin-I (PN-I) is representative of a newly described class of serine protease inhibitors secreted by human fibroblasts, the protease nexins. Protease nexins form covalent complexes with their target proteases, subsequently binding to cells via specific receptors. PN-I preferentially binds thrombin, urokinase, trypsin, and plasmin, and its binding to thrombin is accelerated by heparin. We have previously described the production of a polyclonal antibody against PN-I which is able to block the binding of PN-I X proteinase complexes to cells and will immunoprecipitate metabolically labeled PN-I. Anti-PN-I was used to investigate the biosynthesis and regulation of PN-I in human fibroblasts. Unlabeled PN-I could compete for the binding of metabolically labeled PN-I to anti-PN-I, as shown by the elimination of the 43-kDa band representing PN-I on sodium dodecyl sulfate-polyacrylamide gel electrophoresis autoradiographs. Excision of this 43-kDa band from gels, followed by amino-terminal sequencing, showed a homogeneous protein that is homologous with that described by Scott et al. (Scott, R. W., Bergman, B. L., Bajpai, A., Hersh, R. T., Rodriguez, H., Jones, B. N., Barreda, C., Watts, S., and Baker, J. B. (1985) J. Biol. Chem. 260, 7029-7034). An analysis of the biosynthesis of the PN-I revealed that a lower Mr precursor exists intracellularly. This apparent rough endoplasmic reticulum form appears as a doublet on sodium dodecyl sulfate gels, as does mature PN-I. The PN-I precursor was also sensitive to endoglycosidase H, suggesting that it contains N-linked carbohydrates of the high mannose form. Mature PN-I is not sensitive to endoglycosidase H, but does contain 3 kDa of N-linked carbohydrate. PN-I appears to be constitutively secreted by fibroblasts. PN-I levels in conditioned media reach a steady state within 48 h, although PN-I synthesis maintains a constant rate. This steady state is due to the continuous uptake of PN-I from medium, presumably through a specific receptor.     

Security Analysis and Improvement of ‘a More Secure Anonymous User Authentication Scheme for the Integrated EPR Information System’

Over the past few years, secure and privacy-preserving user authentication scheme has become an integral part of the applications of the healthcare systems. Recently, Wen has designed an improved user authentication system over the Lee et al.’s scheme for integrated electronic patient record (EPR) information system, which has been analyzed in this study. We have found that Wen’s scheme still has the following inefficiencies: (1) the correctness of identity and password are not verified during the login and password change phases; (2) it is vulnerable to impersonation attack and privileged-insider attack; (3) it is designed without the revocation of lost/stolen smart card; (4) the explicit key confirmation and the no key control properties are absent, and (5) user cannot update his/her password without the help of server and secure channel. Then we aimed to propose an enhanced two-factor user authentication system based on the intractable assumption of the quadratic residue problem (QRP) in the multiplicative group. Our scheme bears more securities and functionalities than other schemes found in the literature.     

Cell-based analysis of structure-function activity of threonine aspartase 1

Taspase1 is a threonine protease responsible for cleaving intracellular substrates. As such, (de)regulated Taspase1 function is expected not only to be vital for ordered development but may also be relevant for disease. However, the full repertoires of Taspase1 targets as well as the exact biochemical requirements for its efficient and substrate-specific cleavage are not yet resolved. Also, no cellular assays for this protease are currently available, hampering the exploitation of the (patho)biological relevance of Taspase1. Here, we developed highly efficient cell-based translocation biosensor assays to probe Taspase1 trans-cleavage in vivo. These modular sensors harbor variations of Taspase1 cleavage sites and localize to the cytoplasm. Expression of Taspase1 but not of inactive Taspase1 mutants or of unrelated proteases triggers proteolytic cleavage and nuclear accumulation of the biosensors. Employing our assay combined with scanning mutagenesis, we identified the sequence and spatial requirements for efficient Taspase1 processing in liquid and solid tumor cell lines. Collectively, our results defined an improved Taspase1 consensus recognition sequence, Q(3)(F/I/L/V)(2)D(1)↓G(1)'X(2)'D(3)'D(4)', allowing the first genome-wide bioinformatic identification of the human Taspase1 degradome. Among the 27 most likely Taspase1 targets are cytoplasmic but also nuclear proteins, such as the upstream stimulatory factor 2 (USF2) or the nuclear RNA export factors 2/5 (NXF2/5). Cleavage site recognition and proteolytic processing of selected targets were verified in the context of the biosensor and for the full-length proteins. We provide novel mechanistic insights into the function and bona fide targets of Taspase1 allowing for a focused investigation of the (patho)biological relevance of this type 2 asparaginase.     

Characterization of the Murine Myeloid Precursor Cell Line MuMac-E8

Starting point for the present work was the assumption that the cell line MuMac-E8 represents a murine cell population with stem cell properties. Preliminary studies already pointed to the expression of stem-cell associated markers and a self-regenerative potential of the cells. The cell line MuMac-E8 should be examined for their differential stage within stem cell hierarchy. MuMac-E8 cells were derived from a chimeric mouse model of arthritis. It could be shown that MuMac-E8 cells express mRNA of some genes associated with pluripotent stem cells (Nanog, Nucleostemin), of genes for hematopoietic markers (EPCR, Sca-1, CD11b, CD45), for the mesenchymal marker CD105 and of genes for the neural markers Pax-6 and Ezrin. In methylcellulose and May-Grünwald-Giemsa staining, hematopoietic colonies were obtained but the hematopoietic system of lethally irradiated mice could not be rescued. Osteogenic differentiation was not detectable. Thus, it became evident that MuMac-E8 represents not a stem cell line. However, MuMac-E8 cells expressed several myeloid surface markers (i.e. CD11b, F4/80, CD14, CD64), showed phagocytosis and is capable of producing nitric oxide. Thus, this cell line seems to be arrested an advanced stage of myeloid differentiation. Adherence data measured by impedance-based real-time cell analysis together with cell morphology data suggested that MuMac-E8 represents a new macrophage precursor cell line exhibiting weak adherence. This cell line is suitable as an in-vitro model for testing of macrophage functions. Moreover, it might be also useful for differentiation or reprogramming studies.     

Human PAPS synthase isoforms are dynamically regulated enzymes with access to nucleus and cytoplasm

In higher eukaryotes, PAPS synthases are the only enzymes producing the essential sulphate-donor 3'-phospho-adenosine-5'-phosphosulphate (PAPS). Recently, PAPS synthases have been associated with several genetic diseases and retroviral infection. To improve our understanding of their pathobiological functions, we analysed the intracellular localisation of the two human PAPS synthases, PAPSS1 and PAPSS2. For both enzymes, we observed pronounced heterogeneity in their subcellular localisation. PAPSS1 was predominantly nuclear, whereas PAPSS2 localised mainly within the cytoplasm. Treatment with the nuclear export inhibitor leptomycin B had little effect on their localisation. However, a mutagenesis screen revealed an Arg-Arg motif at the kinase interface exhibiting export activity. Notably, both isoforms contain a conserved N-terminal basic Lys-Lys-Xaa-Lys motif indispensable for their nuclear localisation. This nuclear localisation signal was more efficient in PAPSS1 than in PAPSS2. The activities of the identified localisation signals were confirmed by microinjection studies. Collectively, we describe unusual localisation signals of both PAPS synthase isoforms, mobile enzymes capable of executing their function in the cytoplasm as well as in the nucleus.