Establishment of cell-based reporter system for diagnosis of poxvirus infection.

Poxvirus detection assays are based on morphology, viral antigens and specific nucleic acids, none of which indicates virus viability or infectious capacity. Determination of virus viability is achieved by propagation in cell cultures and subsequent analysis by the mentioned methods, a process that takes days. Thus, presented here the development of a new assay, named PILA (Poxvirus Infection Luciferase Assay), for rapid detection of infectious poxviruses which is a cell-based reporter assay. The assay is composed of two steps: (i) Transfection of cells with a poxvirus specific reporter vector which consists of the early 7.5-kDa-STR promoter, regulating the expression of luciferase gene; (ii) Infection with a poxvirus containing sample. Luciferase activity measured post infection, indicates the presence of infectious poxvirus in the sample. The assay can detect quantities as low as 100 PFU of VACV, six hours post infection. Orthopox virus universality was confirmed by detection of various Orthopoxviruses, and specificity was verified by using pox-specific neutralizing antibodies. The PILA is specific, rapid, simple, and suitable for detecting viable virus. The assay can be utilized for applications such as poxvirus titration, neutralizing assay and drug discovery. The assay was adjusted for live detection assay by using GFP as reporting gene.

Concentration of Bacillus spores by using silica magnetic particles.

Silica particles are mainly used for the concentration of nucleic acid for diagnostic purposes. This is usually done under acidic or chaotropic conditions that will demolish most of the living organisms and prevent the application of other diagnostic tests. Here we describe the development of a method for the capturing and concentration of Bacillus spores using silica magnetic particles to enable fast and sensitive detection. We have shown that capturing various Bacilli spores via silica magnetic particles is limited, with large differences between spore batches (42 +/- 25%). The hydrophobic exosporium layer of spore limits the capture by the hydrophilic silica beads. Partial removal of Bacillus exosporium increases capture efficiency. To increase capturing efficiency without harming the spores' viability, a cationic lipid, didecyldimethylammonium bromide (DDAB), was used as a coat for the negatively charged silica particles. DDAB treatment increased capture efficiency from 42% to more than 90%. Using this method, we were able to capture as few as 100 Bacillus anthracis spores/mL with 90% efficacy. Release of captured spores was achieved by the addition of albumin. The capture and release processes were verified by plating and by flow cytometry using light scatter analysis. The method is simple, efficient, easy to operate, and fast.