Huaichang Sun

Retrovirus vector-mediated correction and cross-correction of lysosomal alpha-mannosidase deficiency in human and feline fibroblasts.

Lysosomal alpha-mannosidase (EC 3.2.1.24) is an exoglycosidase in the glycoprotein degradation pathway. A deficiency of this enzyme causes the lysosomal storage disease alpha-mannosidosis. Retrovirus vector transfer of a new human alpha-mannosidase cDNA resulted in high-level expression of alpha-mannosidase enzymatic activity in deficient human and feline fibroblasts. The expressed alpha-mannosidase had the same biochemical properties (thermal stability, pH profile, inhibitor/activator sensitivity) as the native enzyme expressed in normal cells. The transferred enzyme colocalized with a control lysosomal hydrolase in cell fractionation experiments. The vector-encoded enzyme also was released at high levels from the corrected cells, and was taken up by untreated mutant cells via the mannose 6-phosphate receptor-mediated endocytic pathway (cross-correction). It is envisioned that genetic correction of a subset of cells (e.g., hematopoietic stem cells) in patients will provide a source of corrective enzyme for other affected tissues in this multisystem disease. Development of a vector expressing high levels of alpha-mannosidase that cross-corrects mutant cells will enable somatic gene transfer experiments in the cat model of human alpha-mannosidosis.

Recent Progress in Lysosomal

Lysosomal α-mannosidase (EC 3.2.1.24) is a major exoglycosidase in the glycoprotein degradation pathway. A deficiency of this enzyme causes the lysosomal storage disease, α-mannosidosis, which has been described in humans, cattle, domestic cats and guinea pigs. Recently, great progress has been made in studying the enzyme and its deficiency. This includes cloning of the gene encoding the enzyme, characterization of mutations related to the disease, establishment of valuable animal models, and encouraging results from bone marrow transplantation experiments.

{\alpha}-Mannosidase

The African swine fever virus (ASFV) j13L gene encodes a 177 amino acid protein (19.0 kDa) with a putative transmembrane domain between residues 32 and 52. There is a potential signal peptide cleavage site at residue 54 and several possible motifs for phosphorylation and myristylation. Rabbit antisera raised against a synthetic peptide from the C terminus of the j13L ORF identified proteins of 25-27 kDa in cells infected with a recombinant vaccinia virus expressing the j13L ORF, in ASFV-infected cells and in purified extracellular ASF virions. In ASFV-infected cells the j13L protein was expressed late during infection and exhibited size variation (25-27 kDa) between the different ASFV strains. Nucleotide sequence analysis of the gene in these strains showed that these size differences were due to variation in the number and sequence of tandemly repeated amino acid repeats. Although ASFV-infected animals made antibodies to the j13L protein, no protection was observed when pigs were vaccinated with a recombinant vaccinia virus expressing the j13L ORF.

and Its Deficiency

RNA interference (RNAi) is a novel antiviral strategy against a variety of virus infections. Infectious bursal disease virus (IBDV) causes an economically important disease in young chickens. This study demonstrated efficient inhibition of IBDV replication by recombinant avian adeno-associated virus (rAAAV)-delivered anti-VP1 and anti-VP2 microRNAs (miRNAs). In the viral vector-transduced cells, sequence-specific miRNA expression was detected by poly(A)-tailed RT-PCR. Reporter assays using a pVP2-EGFP vector showed significant and long-lasting inhibition of VP2-EGFP expression in cells transduced with anti-VP2 miRNA-expressing rAAAV-RFPmiVP2E, but not with the control miRNA-expressing rAAAV-RFPmiVP2con or anti-VP1 miRNA-expressing rAAAV-RFPmiVP1. Semi-quantitative RT-PCR and/or virus titration assays showed a significant inhibitory effect on homologous IBDV replication in cells transduced with rAAAV-RFPmiVP1 or rAAAV-RFPmiVP2E. For two heterologous IBDV isolates, transduction with rAAAV-RFPmiVP1 led to slightly weaker but similar inhibitory effects, whereas transduction with rAAAV-RFPmiVP2E resulted in significantly weaker and different inhibitory effects. These results suggest that rAAAV could act as an efficient vector for miRNA delivery into avian cells and that VP1 is the more suitable target for interfering with IBDV replication using RNAi technology.

AFRICAN SWINE FEVER VIRUS GENE J13L ENCODES A 25-27 KDA VIRION PROTEIN WITH VARIABLE NUMBERS OF AMINO ACID REPEATS

Staphylococci are the leading pathogens of bovine mastitis which is difficult to control. However, the published data on the prevalence of staphylococcal species, virulence and antibiotic resistance genes in bovine mastitis from China are limited. In this study, 104 out of 209 subclinical mastitis milk samples from a single Chinese dairy herd were cultured-positive for staphylococci (49.8%), which were further identified as coagulase-positive staphylococci (CPS) or coagulase-negative staphylococci (CNS). According to the partial tuf and/or 16S rRNA gene sequence, the 28 CPS isolates were confirmed to be Staphylococcus aureus (26.9%), and 76 CNS isolates were assigned to 13 different species (73.1%) with Staphylococcus arlettae, Staphylococcus sciuri, Staphylococcus xylosus and Staphylococcus chromogenes as the dominant species. In the 28 S. aureus isolates, the most prevalent general virulence genes were coa, Ig and eno (100%), followed by hla (96.4%), hlb (92.9%), fib (92.9%), clfA (89.3%), clfB (85.7%) and nuc (85.7%). Both exotoxin and biofilm-associated genes were significantly less prevalent than the previously reported. Although 19 different virulence gene patterns were found, only one was dominant (32.1%). The prevalence of blaZ (82.1%) or mecA gene (35.7%) was much higher than the previously reported. In the 76 CNS isolates, the virulence genes were significantly less prevalent than that in the S. aureus isolates. Among the 4 main CNS species, S. chromogenes (n = 12) was the only species with high percentage (75%) of blaZ gene, while S. sciuri (n = 12) was the only species with the high percentage (66.7%) of mecA gene. The most of antibiotic resistance genes were present as multi-resistance genes, and the antibiotic resistances were attributed by different resistance genes between resistant S. aureus and CNS isolates. These data suggest that the prevalence of staphylococcal species, virulence and antibiotic resistance in the mastitis milk from the Chinese dairy herd are different from the previously reported, and that the herd- or farm-based diagnosis of staphylococcal bovine mastitis is required.

Effective inhibition of infectious bursal disease virus replication by recombinant avian adeno-associated virus-delivered microRNAs.

The j5R open reading frame (ORF) of the Malawi LIL 20/1 African swine fever virus (ASFV) isolate encodes a 111 amino acid protein with a putative transmembrane domain at the N terminus. Antisera raised against the predicted C-terminal peptide were used to identify the j5R protein by Western blotting in cells infected with ASFV or with recombinant vaccinia virus expressing the j5R ORF. This showed that the j5R protein migrates with an apparent molecular mass of 23-25 kDa, depending on the virus isolate, on SDS-PAGE and is expressed late during ASFV infection. The localization in infected cells and in virions of the j5R protein, and that of a previously characterized virion protein, j13L, which also contains a putative transmembrane domain, were studied by immunofluorescence and immuno-electron microscopy. Both proteins were expressed at 8-10 h post-infection (p.i.) as small multiple perinuclear foci which coalesced to a single area indicative of the virus factory at 18 h p.i. At the ultrastructural level j5R and j13L were detected mainly on membrane-like structures within the virus factory and on virus particles, suggesting that they may be involved in particle assembly. Negative contrast immuno-electron microscopy of mature extracellular virions confirmed that they are also integral structural proteins.

The diversities of staphylococcal species, virulence and antibiotic resistance genes in the subclinical mastitis milk from a single Chinese cow herd

Previous studies on the underlying mechanism for porcine reproductive and respiratory syndrome virus (PRRSV)-induced reproductive failure have been focused on the viral replication in the endothelial macrophages, and the susceptibility of porcine endometrial endothelial (PEE) cells to PRRSV has not yet been investigated. Therefore, in the present study we generated a PEE cell line by transfection of the primary cells with a SV40 large T antigen expression vector. The PEE cell line maintained the endothelial morphology with a significantly faster growth rate, shorter population doubling time and higher plating efficiency than the primary cells. The endothelial origination of the cell line was confirmed by detection of the endothelial cell-specific markers. The PEE cell line had been passed successively for 60 generations with an unlimited growth potential. To further characterize the PEE cell line, cells of different passages were infected with different PRRSV strains and analyzed for the viral antigen and replication. Overt cytopathic effect was observed from 36h postinfection (HPI) and the viral antigen detected as early as 12 HPI. The infectious virus was recovered from the infected PEE cells with a titer higher than that in MARC-145 cells. Since the data presented indicate a high susceptibility of PEE cells to PRRSV, we conclude that the PEE cell line generated will be useful for growth of PRRSV and further studies on the underlying mechanism for PRRSV infection of PEE cells. The finding of the susceptibility of PEE cells to PRRSV may provide an alternative explanation for PRRSV-induced reproductive failure.

Characterization of African swine fever virion proteins j5R and j13L: immuno-localization in virus particles and assembly sites.

Porcine reproductive and respiratory syndrome (PRRS) is an economically important swine disease to the swine industry worldwide. Current PRRS vaccines are only partially effective and new vaccine development faces great challenges. Sialoadhesin (Sn) and CD163 are the two essential receptors for PRRSV infection of porcine alveolar macrophage (PAM). To investigate the feasibility of the soluble viral receptors for PRRS control, in the present study we generated recombinant adenovirus (rAd) expressing the four N-terminal Ig-like domains of porcine Sn (Sn4D), the fifth SRCR domain (SRCR5) or domains 5-9 (SRCR59) of porcine CD163 as porcine Fc (pFc) fusion proteins. Efficient expression of the soluble viral receptors in the rAd-transduced cells was confirmed by RT-PCR and Western blotting. To detect their antiviral activities, the soluble viral receptors were purified from the media of rAd-transduced cells and identified by Western blotting. The viral binding assay showed that the soluble receptors Sn4D-Fc and SRCR59-Fc, but not SRCR5-Fc and the control pFc, were able to bind to PRRSV particles. The viral infection blocking assays showed that co-treatment of PRRSV with different concentrations of Sn4D-Fc and SRCR59-Fc proteins resulted in a much higher (72.1%-77.6%) reduction in PRRSV-positive cell number than the single protein treatment (45.1%-60.0% or 44.0%-56.2%). To investigate the feasibility of delivering the soluble viral receptors to PAM, two pig cell lines were transduced with rAd-Sn4D-Fc and/or rAd-SRCR59-Fc using a transwell culture system. PAM cells were infected with PRRSV and then co-cultured with the rAd-transduced cells. Viral titration assay showed that co-cultivation of the infected PAM with rAd-Sn4D-Fc- and rAd-SRCR59-Fc-transduced cells resulted in much higher (by ∼3.5 log) reduction in the viral titers (TCID50) than that of co-cultivation with the single vector-transduced cells (by ∼1.0 log). Further studies showed that the rAd co-delivered soluble receptors Sn4D-Fc and SRCR59-Fc had dose-dependent and temporal antiviral effect against three different PRRSV strains. Since the data presented indicate an additive anti-PRRSV activity between the soluble receptors Sn4D-Fc and SRCR59-Fc, we conclude that the two rAd vectors generated will be useful for development a novel reagent for PRRS control.

Generation and characterization of a porcine endometrial endothelial cell line susceptible to porcine reproductive and respiratory syndrome virus

The African swine fever virus (ASFV) open reading frame (ORF) that is named jl8L in the Malawi (LIL20/1) isolate and E199L in the Ba71V isolate encodes a cysteine rich protein of 195 amino acids with a predicted molecular mass of 21.7 kDa and a hydrophobic domain near the C terminus. There are several possible motifs for glycosylation, phosphorylation and myristoylation. Rabbit antisera and monoclonal antibodies raised against a recombinant ASFV j18L protein expressed as a fusion protein with glutathione S-transferase (GST) identified proteins of 19.0-20 kDa in cells infected with different ASFV strains and with a recombinant vaccinia virus expressing j18L. The monoclonal antibodies detected a protein of 20.0 kDa whereas rabbit antisera detected two proteins with relative molecular masses of 15.0 and 20.0 kDa in purified extracellular ASF virions. In ASFV-infected cells, the j18L protein was expressed late post-infection and was localized mainly in the viral factories.

Additive inhibition of porcine reproductive and respiratory syndrome virus infection with the soluble sialoadhesin and CD163 receptors

Purification of recombinant proteins is a major task and challenge in biotechnology and medicine. In this paper we report a novel single-step recombinant protein purification system which was based on elastin-like peptide (ELP)-mediated reversible phase transition and FrpC self-processing module (SPM)-mediated cleavage. After construction of a SPM-ELP fusion expression vector, we cloned the coding sequence for green fluorescent protein (GFP), the Fc portion of porcine IgG (pFc) or human β defensin 3 (HBD3) into the vector, transformed the construct into Escherichia coli, and induced the fusion protein expression with IPTG. The target-SPM-ELP fusion proteins GFP-SPM-ELP, Fc-SPM-ELP and HBD3-SPM-ELP were expressed in a soluble form and efficiently purified from the clarified cell extracts by two rounds of inverse transition cycling (ITC). Under the optimized conditions, the SPM-mediated cleavage efficiencies for the three fusion proteins ranged from 92% to 93%. After an additional round of ITC, the target proteins GFP, pFc and HBD3 were recovered with purities ranging from 90% to 100% and yields ranging from 1.1 to 36mg/L in shake flasks. The endotoxin levels in all of the three target proteins were <0.03EU/mg. The three target proteins were functionally active with the expected molecular weights. These experimental results confirmed the high specificity and efficiency of SPM-mediated cleavage, and suggested the applicability of SPM-ELP fusion system for purification of recombinant proteins.