Kiyoto Kamagata

Fast Compaction of α-Lactalbumin During Folding Studied by Stopped-flow X-ray Scattering

To monitor the fast compaction process during protein folding, we have used a stopped-flow small-angle X-ray scattering technique combined with a two-dimensional charge-coupled device-based X-ray detector that makes it possible to improve the signal-to-noise ratio of data dramatically, and measured the kinetic refolding reaction of α-lactalbumin. The results clearly show that the radius of gyration and the overall shape of the kinetic folding intermediate of α-lactalbumin are the same as those of the molten globule state observed at equilibrium. Thus, the identity between the kinetic folding intermediate and the equilibrium molten globule state is firmly established. The present results also suggest that the folding intermediate is more hydrated than the native state and that the hydrated water molecules are dehydrated when specific side-chain packing is formed during the change from the molten globule to the native state.

Development of a technique for the investigation of folding dynamics of single proteins for extended time periods

A technique was developed for the detection of fluorescence signals from free single molecules for extended time periods and was applied to the characterization of the unfolded states of iso-1-cytochrome c (cyt c). Protein molecules labeled with fluorescent dye were slowly injected into a capillary at concentrations that allow for the observation of one molecule at a time. A laser was introduced into the capillary coaxially, and the fluorescence was imaged as traces by using a lens with a large focal depth and wide field of view. Thus, the traces reflect the time-dependent changes in the fluorescence signals from single proteins. Cyt c was labeled with Alexa Fluor 532 at the C-terminal cysteine (cyt c-Alexa). In bulk experiments, cyt c-Alexa was shown to possess different fluorescence intensity for the native state, the unfolded state (U), and the intermediate state. Single-molecule traces of cyt c-Alexa were recorded by using the device. Intensity histograms of the traces revealed two distributions with broad and narrow widths, which were interpreted to correspond to the U and intermediate state, respectively, observed in the bulk measurements. The broad width of the U suggested the existence of a relatively slow conformational dynamics, which might be consistent with the correlation time (≈15 ms) estimated from the traces assignable to the U. The technique was expected to reveal dynamics of proteins along the folding processes without artifacts caused by immobilization.

Equilibrium and kinetics of the allosteric transition of GroEL studied by solution X-ray scattering and fluorescence spectroscopy

We have studied the ATP-induced allosteric structural transition of GroEL using small angle X-ray scattering and fluorescence spectroscopy in combination with a stopped-flow technique. With X-ray scattering one can clearly distinguish the three allosteric states of GroEL, and the kinetics of the transition of GroEL induced by 85 microM ATP have been observed directly by stopped-flow X-ray scattering for the first time. The rate constant has been found to be 3-5s(-1) at 5 degrees C, indicating that this process corresponds to the second phase of the ATP-induced kinetics of tryptophan-inserted GroEL measured by stopped-flow fluorescence. Based on the ATP concentration dependence of the fluorescence kinetics, we conclude that the first phase represents bimolecular non-cooperative binding of ATP to GroEL with a bimolecular rate constant of 5.8 x 10(5)M(-1)s(-1) at 25 degrees C. Considering the electrostatic repulsion between negatively charged GroEL (-18 of the net charge per monomer at pH 7.5) and ATP, the rate constant is consistent with a diffusion-controlled bimolecular process. The ATP-induced fluorescence kinetics (the first and second phases) at various ATP concentrations (< 400 microM) occur before ATP hydrolysis by GroEL takes place and are well explained by a kinetic allosteric model, which is a combination of the conventional transition state theory and the Monod-Wyman-Changeux model, and we have successfully evaluated the equilibrium and kinetic parameters of the allosteric transition, including the binding constant of ATP in the transition state of GroEL.

Microsecond dynamics of an unfolded protein by a line confocal tracking of single molecule fluorescence

We present a new method for high speed tracking of fluorescence time series from single proteins. The method uses a fast sample flow and a modified confocal microscopy, line confocal microscopy, and achieves the time resolution of less than 20 μs. The obtained time series from the B domain of protein A labeled with donor and acceptor fluorophores suggest conformational heterogeneity and dynamic fluctuations in the unfolded state.

One-Dimensional Sliding of p53 Along DNA Is Accelerated in the Presence of Ca(2+) or Mg(2+) at Millimolar Concentrations.

One-dimensional (1D) sliding of the tumor suppressor p53 along DNA is an essential dynamics required for its efficient search for the binding sites in the genome. To address how the search process of p53 is affected by the changes in the concentration of Mg(2+) and Ca(2+) after the cell damages, we investigated its sliding dynamics at different concentrations of the divalent cations. The 1D sliding trajectories of p53 along the stretched DNA were measured by using single-molecule fluorescence microscopy. The averaged diffusion coefficient calculated from the mean square displacement of p53 on DNA increased significantly at the higher concentration of Mg(2+) or Ca(2+), indicating that the divalent cations accelerate the sliding likely by weakening the DNA-p53 interaction. In addition, two distributions were identified in the displacement of the observed trajectories of p53, demonstrating the presence of the fast and slow sliding modes having large and small diffusion coefficients, respectively. A coreless mutant of p53, in which the core domain was deleted, showed only a single mode whose diffusion coefficient is about twice that of the fast mode for the full-length p53. Thus, the two modes are likely the result of the tight and loose interactions between the core domain of p53 and DNA. These results demonstrated clearly that the 1D sliding dynamics of p53 is strongly dependent on the concentration of Mg(2+) and Ca(2+), which maintains the search distance of p53 along DNA in cells that lost homeostatic control of the divalent cations.

Where the complex things are: single molecule and ensemble spectroscopic investigations of protein folding dynamics.

Progress in our understanding of the simple folding dynamics of small proteins and the complex dynamics of large proteins is reviewed. Recent characterizations of the folding transition path of small proteins revealed a simple dynamics explainable by the native centric model. In contrast, the accumulated data showed the substates containing residual structures in the unfolded state and partially populated intermediates, causing complexity in the early folding dynamics of small proteins. The size of the unfolded proteins in the absence of denaturants is likely expanded but still controversial. The steady progress in the observation of folding of large proteins has clarified the rapid formation of long-range contacts that seem inconsistent with the native centric model, suggesting that the folding strategy of large proteins is distinct from that of small proteins.

Complexity of the folding transition of the B domain of protein A revealed by the high-speed tracking of single-molecule fluorescence time series.

The equilibrium unfolding transition of the B domain of protein A (BdpA) was investigated by using single-molecule fluorescence spectroscopy based on line-confocal detection of fast-flowing samples. The method achieved the time resolution of 120 μs and the observation time of a few milliseconds in the single-molecule time-series measurements of fluorescence resonance energy transfer (FRET). Two samples of BdpA doubly labeled with donor and acceptor fluorophores, the first possessing fluorophores at residues 22 and 55 (sample 1) and the second at residues 5 and 55 (sample 2), were prepared. The equilibrium unfolding transition induced by guanidium chloride (GdmCl) was monitored by bulk measurements and demonstrated that the both samples obey the apparent two-state unfolding. In the absence of GdmCl, the single-molecule FRET measurements for the both samples showed a single peak assignable to the native state (N). The FRET efficiency for N shifts to lower values as the increase of GdmCl concentration, suggesting the swelling of the native state structure. At the higher concentration of GdmCl, the both samples convert to the unfolded state (U). Near the unfolding midpoint for sample 1, the kinetic exchange between N and U causes the averaging of the two states and the higher values of the relative fluctuation. The time series for different molecules in U showed slightly different FRET efficiencies, suggesting the apparent heterogeneity. Thus, the high-speed tracking of fluorescence signals from single molecules revealed a complexity and heterogeneity hidden in the apparent two-state behavior of protein folding.

Activation of p53 Facilitates the Target Search in DNA by Enhancing the Target Recognition Probability.

Tumor suppressor p53 binds to the target in a genome and regulates the expression of downstream genes. p53 searches for the target by combining three-dimensional diffusion and one-dimensional sliding along the DNA. To examine the regulation mechanism of the target binding, we constructed the pseudo-wild type (pseudo-WT), activated (S392E), and inactive (R248Q) mutants of p53 and observed their target binding in long DNA using single-molecule fluorescence imaging. The pseudo-WT sliding along the DNA showed many pass events over the target and possessed target recognition probability (TRP) of 7±2%. The TRP increased to 18±2% for the activated mutant but decreased to 0% for the inactive mutant. Furthermore, the fraction of the target binding by the one-dimensional sliding among the total binding events increased from 63±9% for the pseudo-WT to 87±2% for the activated mutant. Control of TRP upon activation, as demonstrated here for p53, might be a general activation mechanism of transcription factors.

The Disordered Linker in p53 Participates in Nonspecific Binding to and One-Dimensional Sliding along DNA Revealed by Single-Molecule Fluorescence Measurements

The tumor suppressor p53 is a multidomain transcription factor that can quickly bind to its target DNA by sliding along the DNA strand. We hypothesized that the intrinsically disordered and positively charged linker of p53 regulates its search dynamics first by directly interacting with DNA and second by modulating hopping of the core domain. To test the two hypotheses, we prepared five variants of p53 in which the length and charge of the linker were modulated. The affinity for and sliding along nonspecific DNA of p53 were altered by the charge of the linker, but not by the linker length. In particular, charge neutralization significantly reduced the affinity, suggesting that the linker directly contacts the DNA. Charge neutralization eliminated the slow mode of sliding, in which the core domain was assumed to contact nonspecific DNA. In contrast, the affinity of p53 for the target DNA was not affected by linker mutations. These results demonstrate that the linker participates in a target search of p53 by contacting nonspecific DNA and recruiting the core domain to contact DNA.

The Use of the Time-Resolved X-Ray Solution Scattering for Studies of Globular Proteins

In order to improve the low signal-to-noise ratio of the time-resolved small-angle X-ray scattering, we have used a two-dimensional X-ray detector with a beryllium-windowed X-ray image intensifier and a charge-coupled device as an im- age sensor, and applied this to studies on (1) the kinetic folding reaction of α-lactalbumin, which accumulates the molten globule-like intermediate at an early stage of refolding and (2) the cooperative conformational transition of Escherichia coli chaperonin GroEL induced by ATP, which occurs in an allosteric manner between the close and open conformational states. In the α-lactalbumin reaction, we have firmly established the equivalence between the kinetic intermediate and the equilibrium molten globule state, and obtained further information about dehydration from the highly hydrated folding intermediate during a late stage of refolding. In the chaperonin study, we have successfully observed the kinetics of the allosteric transition of GroEL that occurs with a rate constant of about 3-4 s −1 at 5 ◦ C. The combination of the time-resolved X-ray scattering with other spectroscopic techniques such as circular dichroism and intrinsic fluorescence is thus very effective in understanding the conformational transitions of proteins and protein complexes.