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Query: EC:3.1.27.5 (
RNase
)
17,967
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
A sensitive test for kinetic unfolding intermediates in ribonuclease A (
EC 3.1.27.5
) is performed under conditions where the enzyme unfolds slowly (10 degrees C, pH 8.0, 4.5 M guanidinium chloride). Exchange of peptide NH protons (2H-1H) is used to monitor structural opening of individual hydrogen bonds during unfolding, and kinetic models are developed for hydrogen exchange during the process of protein unfolding. The analysis indicates that the kinetic process of unfolding can be monitored by
EX1
exchange (limited by the rate of opening) for ribonuclease A in these conditions. Of the 49 protons whose unfolding/exchange kinetics was measured, 47 have known hydrogen bond acceptor groups. To test whether exchange during unfolding follows the EX2 (base-catalyzed) or the
EX1
(uncatalyzed) mechanism, unfolding/exchange was measured both at pH 8.0 and at pH 9.0. A few faster-exchanging protons were found that undergo exchange by both
EX1
and EX2 processes, but the 43 slower-exchanging protons at pH 8 undergo exchange only by the
EX1
mechanism, and they have closely similar rates. Thus, it is likely that all 49 protons undergo
EX1
exchange at the same rate. The results indicate that a single rate-limiting step in unfolding breaks the entire network of peptide hydrogen bonds and causes the overall unfolding of ribonuclease A. The additional exchange observed for some protons that follows the EX2 mechanism probably results from equilibrium unfolding intermediates and will be discussed elsewhere.
...
PMID:Kinetics of hydrogen bond breakage in the process of unfolding of ribonuclease A measured by pulsed hydrogen exchange. 770
When NMR hydrogen exchange was used previously to monitor the kinetics of
RNase A
unfolding, some peptide NH protons were found to show EX2 exchange (detected by base catalysis) in addition to the expected
EX1
exchange, whose rate is limited by the kinetic unfolding process. In earlier work, two groups showed independently that a restricted two-process model successfully fits published hydrogen exchange rates of native
RNase A
in the range 0-0.7 M guanidinium chloride. We find that this model predicts properties that are very different from the observed properties of the EX2 exchange reactions of
RNase A
in conditions where guanidine-induced unfolding takes place. The model predicts that EX2 exchange should be too fast to measure by the technique used, whereas it is readily measurable. Possible explanations for the contradiction are considered here, and we show that removing the restriction from the earlier two-process model is sufficient to resolve the contradiction; instead of specifying that exchange caused by global unfolding occurs by the EX2 mechanism, we allow it to occur by the general mechanism, which includes both the
EX1
and EX2 cases. It is logical to remove this restriction because global unfolding of
RNase A
is known to give rise to
EX1
exchange in these unfolding conditions. Resolving the contradiction makes it possible to determine whether populated unfolding intermediates contribute to the EX2 exchange, and this question is considered elsewhere. The results and simulations indicate that moderate or high denaturant concentrations readily give rise to
EX1
exchange in native proteins. Earlier studies showed that hydrogen exchange in native proteins typically occurs by the EX2 mechanism but that high temperatures or pH values above 7 may give rise to
EX1
exchange. High denaturant concentrations should be added to the list of variables likely to cause
EX1
exchange.
...
PMID:A general two-process model describes the hydrogen exchange behavior of RNase A in unfolding conditions. 870 Aug 71
Pressure denaturation of Escherichia coli
ribonuclease
HI (
RNase
HI) was studied by Fourier transform infrared (FTIR) and two-dimensional NMR spectroscopy at pD* 3.0 and 25 degrees C. A reversible transition in the pressure range of 0.1-1090 MPa was observed with second-derivative FTIR experiments. A cooperative and gradual denaturation, involving both the secondary and tertiary structures, was observed between 240 and 450 MPa. The two peaks at 1629 and 1652 cm(-1), due to beta-strands and alpha-helices, respectively, did not fully disappear after the denaturation, and are different from the spectra of the random coil peptides. The hydrogen-deuterium exchange rates of the individual backbone amide protons were determined by heteronuclear NMR combined with the pressure-jump technique at 500, 650, and 850 MPa. Although most of the amides protected in the native structure are also highly protected in the pressure-denatured state, the rate constants (0.048 +/- 0.007 min(-1)) for the amide protons at 500 MPa are similar regardless of their locations, which is an indication of the
EX1
mechanism of hydrogen-deuterium exchange. The pressure-denatured state of
RNase
HI at 500 MPa represents a novel denatured state, which is different from a typical molten globule state at atmospheric pressure (0.1 MPa), from the viewpoint of the homogeneous rate constants. The observations at 650 MPa are essentially the same as those at 500 MPa. However, at 850 MPa, the amide exchange rates for the highly hydrophobic C-terminal half of alpha-helix I are significantly slower than those for the other part of the protein, which can be interpreted as a hydrophobic collapse centered at the C-terminal half of alpha-helix I.
...
PMID:Pressure-denatured state of Escherichia coli ribonuclease HI as monitored by Fourier transform infrared and NMR spectroscopy. 992 68
A key paradigm in the biology of adaptation holds that urea affects protein function by increasing the fluctuations of the native state, while trimethylamine N-oxide (TMAO) affects function in the opposite direction by decreasing the normal fluctuations of the native ensemble. Using urea and TMAO separately and together, hydrogen exchange (HX) studies on
RNase A
at pH* 6.35 were used to investigate the basic tenets of the urea:TMAO paradigm. TMAO (1 M) alone decreases HX rate constants of a select number of sites exchanging from the native ensemble, and low urea alone increases the rate constants of some of the same sites. Addition of TMAO to urea solutions containing
RNase A
also suppresses HX rate constants. The data show that urea and TMAO independently or in combination affect the dynamics of the native ensemble in opposing ways. The results provide evidence in support of the counteraction aspect of the urea:TMAO paradigm linking structural dynamics with protein function in urea-rich organs and organisms.
RNase A
is so resistant to urea denaturation at pH* 6.35 that even in the presence of 4.8 M urea, the native ensemble accounts for >99.5% of the protein. An essential test, devised to determine the HX mechanism of exchangeable protons, shows that over the 0-4.8 M urea concentration range nearly 80% of all observed sites convert from EX2 to
EX1
. The slow exchange sites are all
EX1
; they do not exhibit global exchange even at urea concentrations (5.8 M) well into the denaturation transition zone, and their energetically distinct activated complexes leading to exchange gives evidence of residual structure. Under these experimental conditions, the use of DeltaG(HX) as a basis for HX analysis of
RNase A
urea denaturation is invalid.
...
PMID:Hydrogen exchange kinetics of RNase A and the urea:TMAO paradigm. 1274 42
The studies by IR spectroscopy of the temperature dependence of the H-D exchange rate of the
RNase A
peptide NH atoms permit one to characterize two types of conformation fluctuations, local and global. A comparison with the temperature dependence of the proteolytic degradation rate of
RNase A
shows that similar in nature fluctuations allow for the H-D exchange of NH atoms and the splitting of peptide bonds of the native protein. In the low temperature region, both processes occur through local fluctuations, by way of the EX2 mechanism, and in the high temperature region, they occur through global fluctuations with the overall denaturation desorganization of the native structure, by way of the
EX1
mechanism. The biphasic dependence of the rate of H-D exchange and proteolytic degradation of
RNase A
on urea concentration is also explained by the combination of local and global fluctuations.
...
PMID:[Hydrogen exchange and proteolytic degradation of ribonuclease A. Similarities and distinctions of the kinetic mechanisms]. 1763 29
The effect of strongly destabilizing mutations, I106A and V108G of Ribonuclease A (
RNase A
), on its structure and stability has been determined by NMR. The solution structures of these variants are essentially equivalent to
RNase A
. The exchange rates of the most protected amide protons in
RNase A
(35 degrees C), the I106A variant (35 degrees C), and the V108G variant (10 degrees C) yield stability values of 9.9, 6.0, and 6.8 kcal/mol, respectively, when analyzed assuming an EX2 exchange mechanism. Thus, the destabilization induced by these mutations is propagated throughout the protein. Simulation of
RNase A
hydrogen exchange indicates that the most protected protons in
RNase A
and the V108G variant exchange via the EX2 regime, whereas those of I106A exchange through a mixed
EX1
+ EX2 process. It is striking that a single point mutation can alter the overall exchange mechanism. Thus, destabilizing mutations joins high temperatures, high pH and the presence of denaturating agents as a factor that induces
EX1
exchange in proteins. The calculations also indicate a shift from the EX2 to the
EX1
mechanism for less protected groups within the same protein. This should be borne in mind when interpreting exchange data as a measure of local stability in less protected regions.
...
PMID:Destabilizing mutations alter the hydrogen exchange mechanism in ribonuclease A. 1819 47
