A new recombinant rabies virus expressing a green fluorescent protein: A novel and fast approach to quantify virus neutralizing antibodies.

The Rapid Fluorescent Focus Inhibition Test (RFFIT) is a standard assay used to detect and assess the titers of rabies virus neutralizing antibodies (RVNA) in blood sera. To simplify the multistep RFFIT procedure by eliminating the immunostaining step, we generated a new recombinant RV expressing a green fluorescent protein (rRV-GFP) and assess its suitability for quantifying RVNA. We rescued the rRV-GFP virus from plasmid DNA carrying a full-length genome of the CVS-N2c strain of RV in which the eGFP gene was inserted between the glycoprotein and RNA-polymerase genes. The recombinant virus was genetically stable and grew efficiently in appropriate cells expressing sufficient GFP fluorescence to detect directly 20 h post infection (hpi). We evaluated the feasibility of using rRV-GFP in RFFIT by comparing RVNA titers in 27 serum samples measured by conventional RFFIT and RFFIT-GFP. A linear regression analysis of the data demonstrated a good agreement between these two methods (r = 0.9776) including results with samples having RVNA titers close to the minimally acceptable vaccine potency threshold (0.5 IU/ml). Study results showed that the rRV-GFP virus could replace the CVS-11 challenge virus currently used in the conventional RFFIT and enabling more rapid, simpler, and less expensive detection and quantitation of RVNA.

Use of tangential flow filtration for improving detection of viral adventitious agents in cell substrates.

In this study, we assessed the feasibility of tangential flow filtration (TFF) for primary concentration of viral adventitious agents (AAs) from large volumes of cell substrate-derived samples, such as cell-free Chinese hamster ovary (CHO) culture supernatants (500 mL) and CHO cell lysates (50 mL), prior to virus detection in them by nucleic acid-based methods (i.e., qPCR and massively parallel sequencing (MPS). The study was conducted using the samples spiked with four model DNA viruses (bovine herpesvirus type 4, human adenovirus type 5, simian polyomavirus SV-40, and bovine parvovirus). The results showed that the combined TFF/MPS approach enables reliable detection of as low as 1000 genome equivalents (GE) of each of the four viruses spiked into the cell substrate samples. The final achieved sensitivities of 2 GE/mL for cell culture supernatant and 20 GE/mL for cell lysate make this approach more sensitive than virus-specific PCR and qPCR assays. The study results allowed us to propose that TFF might be useful and valuable method for simple and rapid concentration of potential AAs in cell substrate samples prior to AAs detection by conventional in vivo, in vitro, or molecular methods.

Collaborative study report: evaluation of the ATCC experimental mycoplasma reference strains panel prepared for comparison of NAT-based and conventional mycoplasma detection methods.

The main goal of this collaborative study was to evaluate the experimental panel of cryopreserved mycoplasma reference strains recently prepared by the American Type Culture Collection (ATCC(®)) in order to assess the viability and dispersion of cells in the mycoplasma stocks by measuring the ratio between the number of genomic copies (GC) and the number of colony forming units (CFU) in the reference preparations. The employment of microbial reference cultures with low GC/CFU ratios is critical for unbiased and reliable comparison of mycoplasma testing methods based on different methodological approaches, i.e., Nucleic Acid Testing (NAT) and compendial culture-based techniques. The experimental panel included ten different mycoplasma species known to represent potential human and animal pathogens as well as common contaminants of mammalian and avian cell substrates used in research, development, and manufacture of biological products. Fifteen laboratories with expertise in field of mycoplasma titration and quantification of mycoplasmal genomic DNA participated in the study conducted from February to October of 2012. The results of this study demonstrated the feasibility of preparing highly viable and dispersed (possessing low GC/CFU ratios) frozen stocks of mycoplasma reference materials, required for reliable comparison of NAT-based and conventional mycoplasma detection methods.

Syntaxin 11 marks a distinct intracellular compartment recruited to the immunological synapse of NK cells to colocalize with cytotoxic granules.

The syntaxin 11 (STX11) gene is mutated in a proportion of patients with familial haemophagocytic lymphohistiocytosis (FHL) and exocytosis of cytotoxic granules is impaired in STX11-deficient NK cells. However, the subcellular localization, regulation of expression and molecular function of STX11 in NK cells and other cytotoxic lymphocytes remain unknown. Here we demonstrate that STX11 expression is strictly controlled by several mechanisms in a cell-type-specific manner and that the enzymatic activity of the proteasome is required for STX11 expression in NK cells. In resting NKL cells, STX11 was localized in the cation-dependent mannose-6-phosphate receptor (CD-M6PR)-containing compartment, which was clearly distinct from cytotoxic granules or Rab27a-expressing vesicles. These subcellular structures appeared to fuse at the contact area with NK-sensitive target cells as demonstrated by partial colocalization of STX11 with perforin and Rab27a. Although STX11-deficent allo-specific cytotoxic T-lymphocytes efficiently lysed target cells and released cytotoxic granules, they exhibited a significantly lower extent of spontaneous association of perforin with Rab27a as compared with STX11-expressing T cells. Thus, our results suggest that STX11 promotes the fusion of Rab27a-expressing vesicles with cytotoxic granules and reveal an additional level of complexity in the spatial/temporal segregation of subcellular structures participating in the process of granule-mediated cytotoxicity.

Hemin activation abrogates Mycoplasma hyorhinis replication in chronically infected prostate cancer cells via heme oxygenase-1 induction.

Mycoplasma hyorhinis (M. hyorhinis) lacks a cell wall and resists multiple antibiotics. We describe here the striking > 90% inhibitory effect of hemin, a natural inducer of the cytoprotective enzyme heme oxygenase-1 (HO-1), on M. hyorhinis replication in chronically infected LNCaP prostate cancer cells. The role of HO-1 in interrupting M. hyorhinis replication was confirmed by HO-1-specific siRNA suppression of hemin-induced HO-1 protein expression, which increased intracellular M. hyorhinis DNA levels in LNCaP cells. Proteomic analysis and transmission electron microscopy of hemin-treated cells confirmed the complete absence of M. hyorhinis proteins and intact microorganisms, respectively, strongly supporting these findings. Our study is the first to our knowledge suggesting therapeutic potential for activated HO-1 in cellular innate responses against mycoplasma infection.

Switching protein-DNA recognition specificity by single-amino-acid substitutions in the P1 par family of plasmid partition elements.

The P1, P7, and pMT1 par systems are members of the P1 par family of plasmid partition elements. Each has a ParA ATPase and a ParB protein that recognizes the parS partition site of its own plasmid type to promote the active segregation of the plasmid DNA to daughter cells. ParB contacts two parS motifs known as BoxA and BoxB, the latter of which determines species specificity. We found that the substitution of a single orthologous amino acid in ParB for that of a different species has major effects on the specificity of recognition. A single change in ParB can cause a complete switch in recognition specificity to that of another species or can abolish specificity. Specificity changes do not necessarily correlate with changes in the gross DNA binding properties of the protein. Molecular modeling suggests that species specificity is determined by the capacity to form a hydrogen bond between ParB residue 288 and the second base in the BoxB sequence. As changes in just one ParB residue and one BoxB base can alter species specificity, plasmids may use such simple changes to evolve new species rapidly.

Mycoplasma Clearance and Risk Analysis in a Model Bioprocess.

Mycoplasmas are a type of bacteria that lack cell walls and are occasional cell culture contaminants. In a biotechnology setting, because they can pass through 0.2 µm filters, mycoplasmas could pose a potential patient safety hazard if undetected contaminants from the production culture were not completely removed by downstream biotechnology manufacturing. In this study we investigated the ability of typical commercial monoclonal antibody purification operations to clear and kill mycoplasmas, using Acholeplasma laidlawii as a model organism. Our spike/removal studies have shown that protein A column chromatography clears about 4-5 log10 Column regeneration effectively prevents A. laidlawii column carryover between chromatography runs. Moreover, low-pH hold steps, typically implemented after protein A purification, effectively kill A. laidlawii using either pH 3.8 glycine or acetate solutions (LRV ≥5.30 and ≥4.57, respectively). Solvent/detergent treatment, used in some processes instead of low-pH hold, also completely kills highly concentrated A. laidlawii (LRV ≥5.95).LAY ABSTRACT: Biotechnology medicines need to be free from contaminating microorganisms such as mycoplasmas, a type of bacteria that can cause disease in humans (e.g., walking pneumonia). Here we show that some monoclonal antibody manufacturing steps can effectively clear and/or kill Acholeplasma laidlawii, a model mycoplasma species used in our study. This provides an additional level of safety assurance of biotechnology medicines for patients.

Genome Sequence of Mycoplasma hyorhinis Strain DBS 1050.

Mycoplasma hyorhinis is known as one of the most prevalent contaminants of mammalian cell and tissue cultures worldwide. Here, we present the complete genome sequence of the fastidious M. hyorhinis strain DBS 1050.

Species and incompatibility determination within the P1par family of plasmid partition elements.

The P1par family of active plasmid partition systems consists of at least six members, broadly distributed in a variety of plasmid types and bacterial genera. Each encodes two Par proteins and contains a cis-acting parS site. Individual par systems can show distinct species specificities; the proteins from one type cannot function with the parS site of another. P1par-versus-P7par specificity resides within two hexamer BoxB repeats encoded by parS that contact the ParB protein near the carboxy terminus. Here, we examine the species specificity differences between Yersinia pestis pMT1parS and Escherichia coli P1 and P7parS. pMT1parS site specificity could be altered to that of either P1 or P7 by point mutation changes in the BoxB repeats. Just one base change in a single BoxB repeat sometimes sufficed. The BoxB sequence appears to be able to adopt a number of forms that define exclusive interactions with different ParB species. The looped parS structure may facilitate this repertoire of interaction specificities. Different P1par family members have different partition-mediated incompatibility specificities. This property defines whether two related plasmids can coexist in the same cell and is important in promoting the evolution of new plasmid species. BoxB sequence changes that switch species specificity between P1, P7, and pMT1 species switched partition-mediated plasmid incompatibility in concert. Thus, there is a direct mechanistic link between species specificity and partition-mediated incompatibility, and the BoxB-ParB interaction can be regarded as a special mechanism for facilitating plasmid evolution.

Plasmid partition system of the P1par family from the pWR100 virulence plasmid of Shigella flexneri.

P1par family members promote the active segregation of a variety of plasmids and plasmid prophages in gram-negative bacteria. Each has genes for ParA and ParB proteins, followed by a parS partition site. The large virulence plasmid pWR100 of Shigella flexneri contains a new P1par family member: pWR100par. Although typical parA and parB genes are present, the putative pWR100parS site is atypical in sequence and organization. However, pWR100parS promoted accurate plasmid partition in Escherichia coli when the pWR100 Par proteins were supplied. Unique BoxB hexamer motifs within parS define species specificities among previously described family members. Although substantially different from P1parS from the P1 plasmid prophage of E. coli, pWR100parS has the same BoxB sequence. As predicted, the species specificity of the two types proved identical. They also shared partition-mediated incompatibility, consistent with the proposed mechanistic link between incompatibility and species specificity. Among several informative sequence differences between pWR100parS and P1parS is the presence of a 21-bp insert at the center of the pWR100parS site. Deletion of this insert left much of the parS activity intact. Tolerance of central inserts with integral numbers of helical DNA turns reflects the critical topology of these sites, which are bent by binding the host IHF protein.

The role of Par proteins in the active segregation of the P1 plasmid.

The parS centromere-like site promotes active P1 plasmid segregation in the presence of P1 ParA and ParB proteins. At the modest growth rate used here, time-lapse and still photomicroscopy shows that the plasmid copies are clustered as a focus at the Escherichia coli cell centre. Just before cell division, the focus is actively divided and ejects bidirectionally into opposite halves of the dividing cell. In the absence of the wild-type parS binding protein ParB, a focus was formed, but generally did not go to the cell centre. The randomly placed focus did not divide and was inherited by one daughter cell only. In the absence of ParA, foci formed and frequently fixed to the cell centre. However, they failed to divide or eject and were left at the new cell pole of one cell at division. Thus, ParB appears to be required for recognition of the plasmid and its attachment to the cell centre, and ParA is required for focus division and energetic ejection from the cell centre. The ATPase active site mutation, parAK122E, blocked ejection. Mutant parAM314I ejected weakly, and the daughter foci took two generations to reach a new cell centre. This explains the novel alternation of segregation and missegregation in successive generations seen in time-lapse images of this mutant.