Cytomegaloviruses express large amounts of viral miRNAs during lytic infection, yet, they only modestly alter the cellular miRNA profile. The most prominent alteration upon lytic murine cytomegalovirus (MCMV) infection is the rapid degradation of the cellular miR-27a and miR-27b. Here, we report that this regulation is mediated by the ∼1.7 kb spliced and highly abundant MCMV m169 transcript. Specificity to miR-27a/b is mediated by a single, apparently optimized, miRNA binding site located in its 3′-UTR. This site is easily and efficiently retargeted to other cellular and viral miRNAs by target site replacement. Expression of the 3′-UTR of m169 by an adenoviral vector was sufficient to mediate its function, indicating that no other viral factors are essential in this process. Degradation of miR-27a/b was found to be accompanied by 3′-tailing and -trimming. Despite its dramatic effect on miRNA stability, we found this interaction to be mutual, indicating potential regulation of m169 by miR-27a/b. Most interestingly, three mutant viruses no longer able to target miR-27a/b, either due to miRNA target site disruption or target site replacement, showed significant attenuation in multiple organs as early as 4 days post infection, indicating that degradation of miR-27a/b is important for efficient MCMV replication in vivo.
Cloning of cytomegalovirus (CMV) genomes as bacterial artificial chromosomes (BAC) in E. coli and their manipulation using the techniques of bacterial genetics has greatly facilitated the construction of CMV mutants. This unit describes easily applicable procedures that allow rapid introduction of any kind of targeted mutation into BAC-cloned CMV genomes. Protocols for the reconstitution of virus from isolated BAC DNA, preparation of a virus stock, and isolation and characterization of viral DNA are also included. Special emphasis is laid on description of critical steps and thorough characterization of the altered BACs.
Phytochromes are red/far-red light photoreceptors found in plants, cyanobacteria and heterotrophic bacteria. Biochemical analyses have established that the genes bphO and bphP (PA4116 and PA4117) of Pseudomonas aeruginosa encode both phytochrome components: BphO, a heme oxygenase that produces the linear tetrapyrrole chromophore biliverdin IXalpha, and BphP, the apo-phytochrome. Reverse transcription-PCR established that both genes form a bicistronic operon. Expression of the bphOP operon was induced in the stationary phase, indicating an involvement of the P. aeruginosa quorum-sensing system and/or the stationary-phase alternative sigma factor RpoS. Bioinformatic analyses of the promoter region revealed a potential binding site for the quorum sensing regulators LasR and/or RhlR. While a direct involvement of the quorum-sensing system could be ruled out, the dependence of bphOP expression on RpoS was clearly demonstrated. Chromosomal knock-out mutants showed identical growth behavior as a wild type under various conditions but increased levels of pyocyanin were detected in the DeltabphO strain. Additionally, this strain showed decreased heat tolerance in the stationary phase, indicating a potential protective role of the BphO reaction product biliverdin. Therefore, BphO might have an additional function besides providing the chromophore for BphP and both proteins are likely to fulfill a task in the stationary phase.
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