The most commonly used 3′-splice site on the human papillomavirus type 16 (HPV-16) genome named SA3358 is used to produce HPV-16 early mRNAs encoding E4, E5, E6 and E7, and late mRNAs encoding L1 and L2. We have previously shown that SA3358 is suboptimal and is totally dependent on a downstream splicing enhancer containingmultiple potential ASF/SF2 binding sites. Here weshow that only one of the predicted ASF/SF2 sites accounts for the majority of the enhancer activity. We demonstrate that single nucleotide substitutions in this predicted ASF/SF2 site impair enhancer function and that this correlates with less efficient binding to ASF/SF2 in vitro. We provide evidence that HPV-16 mRNAs that arespliced to SA3358 interact with ASF/SF2 in living cells. In addition,mutational inactivation of the ASF/SF2 site weakened the enhancer at SA3358 in episomal forms of the HPV-16 genome, indicating that the enhancer is active in the context of the full HPV-16 genome.This resulted in induction of HPV-16 late gene expression as a result of competition from late splice site SA5639. Furthermore, inactivation of the ASF/SF2 site of the SA3358 splicing enhancer reduced the ability of E6- and E7-encoding HPV-16 plasmids to increase the life span of primary keratinocytes in vitro, demonstrating arequirement for an intact splicing enhancer of SA3358 forefficient production of the E6 and E7 mRNAs. These results link the strength of the HPV-16 SA3358 splicing enhancer to expression of E6 and E7 and to the pathogenic properties of HPV-16.
The phylogenetic relationships and structural similarities of the proteins encoded within the regulatory region (containing the integrase gene and the lytic–lysogenic transcriptional switch genes) of P2-like phages were analyzed, and compared with the phylogenetic relationship of P2-like phages inferred from four structural genes. P2-like phages are thought to be one of the most genetically homogenous phage groups but the regulatory region nevertheless varies extensively between different phage genomes. The analyses showed that there are many types of regulatory regions, but two types can be clearly distinguished; regions similar either to the phage P2 or to the phage 186 regulatory regions. These regions were also found to be most frequent among the sequenced P2-like phage or prophage genomes, and common in phages using Escherichia coli as a host. Both the phylogenetic and the structural analyses showed that these two regions are related. The integrases as well as the cox/apl genes show a common monophyletic origin but the immunity repressor genes, the type P2 C gene and the type 186 cI gene, are likely of different origin. There was no indication of recombination between the P2–186 types of regulatory genes but the comparison of the phylogenies of the regulatory region with the phylogeny based on four structural genes revealed recombinational events between the regulatory region and the structural genes. Less common regulatory regions were phylogenetically heterogeneous and typically contained a fusion of genes from distantly related or unknown phages and P2-like genes.
The amount and distribution of variation in the genomic region containing the genes in the lytic-lysogenic genetic switch and the sequence that determines the integration site into the host chromosome were analyzed for 38 P2-like phages from Escherichia coli. The genetic switch consists of two convergent mutually exclusive promoters, Pe and Pc, and two repressors, C and Cox. The immunity repressor C blocks the early Pe promoter, leading to the establishment of lysogeny. The Cox repressor blocks expression of Pc, allowing lytic growth. Phylogenetic analyses showed that the C and Cox proteins were distributed into seven distinct classes. The phylogenetic relationship differed between the two proteins, and we showed that homologous recombination plays a major role in creating alterations in the genetic switch, leading to new immunity classes. Analyses of the host integration site for these phages resulted in the discovery of a previously unknown site, and there were at least four regular integration sites. Interestingly, we found no case where phages of the same immunity class had different host attachment sites. The evolution of immunity and integration sites is complex, since it involves interactions both between the phages themselves and between phages and hosts, and often, both regulatory proteins and target DNA must change.P2-like phages are a group of related temperate phages that grow on ␥-proteobacteria and share common traits such as morphology, control of lytic versus lysogenic growth, and noninducibility by UV light (for a recent review, see reference 26). Temperate phages have the ability to reproduce by two alternative life cycles: the lytic or the lysogenic cycle. In the latter life cycle, the phage genome integrates into a specific location on the host chromosome, and most phage genes are turned off by the phage-encoded immunity repressor C. P2-like phages are prevalent in Escherichia coli strains; about 30% of the strains in the ECOR collection (28) contain P2-like prophages (27). P2-like phages that are found in other ␥-proteobacteria are more distantly related to P2 than those found in E. coli, and it seems as if the evolution of the P2-like phages tracks the evolution of their respective hosts (26; A. S. Nilsson, unpublished data). An analysis of the DNA sequence of the late structural genes of 18 P2-like isolates that grow on E. coli showed that these genes are at least 96% identical to the genes of P2 (25). Thus, these P2-like coliphages might be considered different isolates of P2, but they have been shown to have different immunities, based on their capacity to grow on bacteria lysogenized with different P2-like phages (6,9,14) and to integrate at at least two different sites in the host chromosome (22,38). Phage 186 is a more distantly related E. coli phage, and its immunity repressor, cI, differs in size and sequence from the C repressors of the P2-like coliphages in this study. In fact, both cI and Apl (the equivalent of Cox) of phage 186 are more related to the cI and Cox repressors of Ha...
The Cox protein of the coliphage P2 is multifunctional; it acts as a transcriptional repressor of the Pc promoter, as a transcriptional activator of the P(LL) promoter of satellite phage P4, and as a directionality factor for site-specific recombination. The Cox proteins constitute a unique group of directionality factors since they couple the developmental switch with the integration or excision of the phage genome. In this work, the DNA binding characteristics of the Cox protein of WPhi, a P2-related phage, are compared with those of P2 Cox. P2 Cox has been shown to recognize a 9 bp sequence, repeated at least 6 times in different targets. In contrast to P2 Cox, WPhi Cox binds with a strong affinity to the early control region that contains an imperfect direct repeat of 12 nucleotides. The removal of one of the repeats has drastic effects on the capacity of WPhi to bind to the Pe-Pc region. Again in contrast to P2 Cox, WPhi Cox has a lower affinity to attP compared to the Pe-Pc region, and a repeat of 9 bp can be found that has 5 bp in common with the repeat in the Pe-Pc region. WPhi Cox, however, is essential for excisive recombination in vitro. WPhi Cox, like P2 Cox, binds cooperatively with integrase to attP. Both Cox proteins induce a strong bend in their DNA targets upon binding.
Counterfeit pharmaceutical drugs imply an increasing threat to the global public health. It is necessary to have systems to control the products that reach the market and to detect falsified medicines. In this work, molecules in several pharmaceutical tablets were directly analyzed using nanospray desorption electrospray ionization mass spectrometry (nano-DESI MS). Nano-DESI is an ambient surface sampling technique which enables sampling of molecules directly from the surface of the tablets without any sample pretreatment. Both the active pharmaceutical ingredients (APIs) and some excipients were detected in all analyzed tablets. Principal component analysis was used to analyze mass spectral features from different tablets showing strong clustering between tablets with different APIs. The obtained results suggest nano-DESI MS as future tool for forensic analysis to discern APIs present in unknown tablet samples.
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