Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.1.26.4 (RNase H)
 2,751 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We have used photoaffinity labelling to examine the chloroplast RNA polymerase components which come into contact with nascent transcripts during the in vitro transcription of plastid DNA. The transcripts were synthesized in the presence of a photoactive analogue (4-thio UTP) and alpha-32P-ATP, using enriched pea chloroplast RNA polymerase preparation and a recombinant plasmid containing the plastid 16S rRNA promoter. Brief irradiation of the transcriptional complex crosslinked the photoactive nascent RNA to proximal proteins. Labelling of the transcriptional complex was dependent on 4-thio UTP and template DNA. Two polypeptides of 51 and 54 kDa were consistently crosslinked to the nascent transcripts; about 60% of the total radioactivity of the crosslinked RNA was associated with these polypeptides. In some experiments, two additional polypeptides of 38 and 75 kDa were also found to be associated with about 13% and 17% of the total crosslinked RNA radioactivity, respectively. The UV-crosslinked transcriptional complexes were stable to either DNase or S1 nuclease hydrolysis but partially sensitive to RNase T1. Insensitivity of the complex to hydrolysis with RNase H suggested that the nascent transcripts were not crosslinked to the template. The complexes could also be hydrolysed by proteinase K and thermolysin. No crosslinkage was observed when labelled RNA molecules containing 4-thio UMP residues were added after synthesis to the polymerase preparation. This suggested that the method identified only those polypeptides which came into close contact with the transcript during its synthesis. Antibodies raised against the RNA-protein complex confirmed the presence of the polypeptides in the chloroplast RNA polymerase preparation on Western blots. Preincubation of these antibodies with the chloroplast RNA polymerase inhibited plastid DNA transcription. These data showed that the transcript-binding polypeptides were functional components of the chloroplast transcriptional complex.
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PMID:Photoaffinity labelling of the pea chloroplast transcriptional complex by nascent RNA in vitro. 171 36

Protein inactivation frequently occurs through partially unfolded states under native conditions, and temperature is an important parameter that affects the susceptibility of proteins to inactivation. While the effect of temperature on global unfolding is well documented, however, experimental characterizations of the temperature effect on partial unfolding are rare. Proteolysis offers a valuable chance to investigate the temperature effect on partial unfolding. By investigating proteolysis kinetics, the energetics of the partially unfolded state responsible for proteolysis (the cleavable state) can be studied. E. coli ribonuclease H (RNase H) has been shown to be cleaved by thermolysin at the amide bond between Thr92 and Ala93 through partial unfolding. Using this cleavage as a model system, we evaluated quantitatively the temperature effect on conformational equilibrium between the native state and a cleavable state. The analysis shows that decrease in temperature from 37 degrees C to 4 degrees C decreases the population in the cleavable state and reduces proteolytic susceptibility of the substrate protein. The conformational change leading to the cleavable state has a temperature-independent positive DeltaH degrees with negligible DeltaC(p) degrees . This thermodynamic characteristic of partial unfolding for proteolysis is quite distinct from that of global unfolding of RNase H that has a considerable DeltaC(p) degrees and a negative DeltaH degrees at low temperature. The distinct thermodynamic characteristics of partial unfolding from global unfolding mainly result from the difference in the changes of solvent-accessible surface area, which confirmed that the temperature effect on partial unfolding is strongly scale-dependent.
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PMID:Investigating the effect of temperature on transient partial unfolding by proteolysis. 1950 5

Salt bridges are frequently observed in protein structures. Because the energetic contribution of salt bridges is strongly dependent on the environmental context, salt bridges are believed to contribute to the structural specificity rather than the stability. To test the role of salt bridges in enhancing structural specificity, we investigated the contribution of a salt bridge to the energetics of native-state partial unfolding in a cysteine-free version of Escherichia coli ribonuclease H (RNase H*). Thermolysin cleaves a protruding loop of RNase H(*) through transient partial unfolding under native conditions. Lys86 and Asp108 in RNase H(*) form a partially buried salt bridge that tethers the protruding loop. Investigation of the global stability of K86Q/D108N RNase H(*) showed that the salt bridge does not significantly contribute to the global stability. However, K86Q/D108N RNase H(*) is greatly more susceptible to proteolysis by thermolysin than wild-type RNase H(*) is. The free energy for partial unfolding determined by native-state proteolysis indicates that the salt bridge significantly increases the energy for partial unfolding by destabilizing the partially unfolded form. Double mutant cycles with single and double mutations of the salt bridge suggest that the partially unfolded form is destabilized due to a significant decrease in the interaction energy between Lys86 and Asp108 upon partial unfolding. This study demonstrates that, even in the case that a salt bridge does not contribute to the global stability, the salt bridge may function as a gatekeeper against partial unfolding that disturbs the optimal geometry of the salt bridge.
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PMID:Salt bridge as a gatekeeper against partial unfolding. 2691 81