MS2 phage-like particles (MS2 PLP) are artificially constructed pseudo-viral particles derived from bacteriophage MS2. They are able to carry a specific single stranded RNA (ssRNA) sequence of choice inside their capsid, thus protecting it against the effects of ubiquitous nucleases. Such particles are able to mimic ssRNA viruses and, thus, may serve as the process control for molecular detection and quantification of such agents in several kinds of matrices, vaccines and vaccine candidates, drug delivery systems, and systems for the display of immunologically active peptides or nanomachines. Currently, there are several different in vivo plasmid-driven packaging systems for production of MS2 PLP. In order to combine all the advantages of the available systems and to upgrade and simplify the production and purification of MS2 PLP, a one-plasmid double-expression His-tag system was designed. The described system utilizes a unique fusion insertional mutation enabling purification of particles using His-tag affinity. Using this new production system, highly pure MS2 PLP can be quickly produced and purified by a fast performance liquid chromatography (FPLC) approach. The system can be easily adapted to produce other MS2 PLP with different properties.
- MeSH
- Levivirus * chemie genetika metabolismus MeSH
- plazmidy * genetika metabolismus MeSH
- rekombinantní fúzní proteiny * biosyntéza chemie genetika izolace a purifikace MeSH
- virion * chemie genetika izolace a purifikace metabolismus MeSH
- virové plášťové proteiny * biosyntéza chemie genetika izolace a purifikace MeSH
- Publikační typ
- časopisecké články MeSH
- práce podpořená grantem MeSH
Although in vitro maturation (IVM) of oocytes has been used for a relatively long time, during which the culture conditions have improved remarkably, the resulting germ cells are still not fully comparable to the cells obtained from the ovary in many important aspects, namely in fertilization rate and subsequent embryonic development. Some of the differences between IVM and in vivo maturation (IVV) oocytes were already discovered, including variability in spindle assembly and morphology. In this study we focused on a role of molecular motor Kif11 (hereafter referred to as Eg5) in maintaining bipolar spindle structure in IVM and IVV oocytes. Our experiments revealed that in IVM oocytes, Eg5 is abundant on meiosis II spindle, which makes these cells more sensitive to Eg5 inhibition than IVV oocytes. We further demonstrate that this sensitivity is acquired gradually with exposure to the in vitro conditions. This is a remarkable difference in function of spindle apparatus between IVM and IVV oocytes, and we believe our results are important not only for understanding of the chromosome segregation in mammalian oocytes but also because they indicate cells are using alternative pathways to achieve the same function when exposed to different conditions.
RNA viruses are pathogenic agents of many serious infectious diseases affecting humans and animals. The detection of pathogenic RNA viruses is based on modern molecular methods, of which the most widely used methods are the reverse transcription polymerase chain reaction (RT-PCR) and the real-time quantitative reverse transcription polymerase chain reaction (qRT-PCR). All steps of RT-PCR and qRT-PCR should be strictly controlled to ensure the validity of obtained results. False-negative results may be caused not only by inhibition of RT or/and PCR steps but also by failure of the nucleic acid extraction step, particularly in the case of viral RNA extraction. The control of nucleic acid extraction generally involves the utilization of a non-pathogenic virus (process control virus) of similar structural properties to those of the target virus. Although in clinical samples the use of such process control virus is only recommended, in other kinds of settings such as food matrices its use is necessary. Currently, several different process control viruses are used for these purposes. Process control viruses can also be constructed artificially using technology for production of MS2 phage-like particles, which have many advantages in comparison with other used controls and are especially suited for controlling the detection and quantification of certain types of RNA viruses. The technology for production of MS2 phage-like particles is theoretically well established, uses the knowledge gained from the study of the familiar bacteriophage MS2 and utilizes many different approaches for the construction of the various process control viruses. Nevertheless, the practical use of MS2 phage-like particles in routine diagnostics is relatively uncommon. The current situation with regard to the use of MS2 phage-like particles as process control viruses in detection of RNA viruses and different methods of their construction, purification and use are summarized and discussed in this review.
Uplatněná certifikovaná metodika ; č. 52
15 nečíslovaných stran ; 30 cm
