To study fidelity of RNA polymerase II (Pol II), we analyzed properties of the 6-azauracil-sensitive and TFIIS-dependent E1103G mutant of rbp1 (rpo21), the gene encoding the catalytic subunit of Pol II in Saccharomyces cerevisiae. Using an in vivo retrotransposition-based transcription fidelity assay, we observed that rpb1-E1103G causes a 3-fold increase in transcription errors. This mutant showed a 10-fold decrease in fidelity of transcription elongation in vitro. The mutation does not appear to significantly affect translocation state equilibrium of Pol II in a stalled elongation complex. Primarily, it promotes NTP sequestration in the polymerase active center. Furthermore, pre-steady-state analyses revealed that the E1103G mutation shifted the equilibrium between the closed and the open active center conformations toward the closed form. Thus, open conformation of the active center emerges as an intermediate essential for preincorporation fidelity control. Similar mechanisms may control fidelity of DNA-dependent DNA polymerases and RNA-dependent RNA polymerases.
In the cell, RNA polymerase II (pol II) efficiently transcribes DNA packaged into nucleosomes, but in vitro encounters with the nucleosomes induce catalytic inactivation (arrest) of the pol II core enzyme. To determine potential mechanisms making nucleosomes transparent to transcription in vivo, we analyzed the nature of the nucleosome-induced arrest. We found that the arrests have been detected mostly at positions of strong intrinsic pause sites of DNA. The transient pausing makes pol II vulnerable to arrest, which involves backtracking of the elongation complex for a considerable distance on DNA. The histone-DNA contacts reestablished in front of pol II stabilize backtracked conformation of the polymerase. In agreement with this mechanism, blocking of backtracking prevents nucleosome-induced arrest. Transcript cleavage factor TFIIS reactivates the backtracked complexes and promotes pol II transcription through the nucleosome. Our findings establish the crucial role of elongation factors that suppress pol II pausing and backtracking for transcription in the context of chromatin.
We have engineered bacterial outer membrane vesicles (OMVs) with dramatically enhanced functionality by fusing several heterologous proteins to the vesicle-associated toxin ClyA of Escherichia coli. Similar to native unfused ClyA, chimeric ClyA fusion proteins were found localized in bacterial OMVs and retained activity of the fusion partners, demonstrating for the first time that ClyA can be used to co-localize fully functional heterologous proteins directly in bacterial OMVs. For instance, fusions of ClyA to the enzymes β-lactamase and organophosphorus hydrolase resulted in synthetic OMVs that were capable of hydrolyzing β-lactam antibiotics and paraoxon, respectively. Similarly, expression of an anti-digoxin single-chain Fv antibody fragment fused to the C-terminus of ClyA resulted in designer "immuno-MVs" that could bind tightly and specifically to the antibody's cognate antigen. Finally, OMVs displaying green fluorescent protein fused to the C-terminus of ClyA were highly fluorescent and, as a result of this new functionality, could be easily tracked during vesicle interaction with human epithelial cells. We expect that the relative plasticity exhibited by ClyA as a fusion partner should prove useful for: (i) further mechanistic studies to identify the vesiculation machinery that regulates OMV secretion and to map the intracellular routing of ClyA-containing OMVs during invasion of host cells; and (ii) biotechnology applications such as surface display of proteins and delivery of biologics.
The actin binding protein α-actinin is a major component of focal adhesions found in vertebrate cells and of the focal adhesion-like structures found the body wall muscle of the nematode Caenorhabditis elegans. To study its in vivo function in this genetic model system we isolated a strain carrying a deletion of the single C. elegans α-actinin gene. We assessed the cytological organization of other C. elegans focal adhesion proteins, and the ultrastructure of the mutant. The mutant does not have normal dense bodies by EM but these dense body-like structures still contain the focal adhesion proteins integrin, talin and vinculin by immunofluorescence microscopy. Actin is found in normal-appearing I-bands, but with abnormal accumulations near muscle cell membranes. Although swimming in water appeared grossly normal, use of automated methods for tracking locomotion of individual worms revealed a defect in bending. We propose that the reduced motility of the α-actinin null is due to abnormal dense bodies that are less able to transmit the forces generated by actin/myosin interactions.
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