Tracking the structural dynamics of proteins in solution using time-resolved wide-angle X-ray scattering

We demonstrate tracking of protein structural changes with time-resolved wide-angle X-ray scattering (TR-WAXS) with nanosecond time resolution. We investigated the tertiary and quaternary conformational changes of human hemoglobin under nearly physiological conditions triggered by laser-induced ligand photolysis. We also report data on optically induced tertiary relaxations of myoglobin and refolding of cytochrome c to illustrate the wide applicability of the technique. By providing insights into the structural dynamics of proteins functioning in their natural environment, TR-WAXS complements and extends results obtained with time-resolved optical spectroscopy and X-ray crystallography.     

Probing RNA dynamics via longitudinal exchange and CPMG relaxation dispersion NMR spectroscopy using a sensitive 13C-methyl label

The refolding kinetics of bistable RNA sequences were studied in unperturbed equilibrium via (13)C exchange NMR spectroscopy. For this purpose a straightforward labeling technique was elaborated using a 2'-(13)C-methoxy uridine modification, which was prepared by a two-step synthesis and introduced into RNA using standard protocols. Using (13)C longitudinal exchange NMR spectroscopy the refolding kinetics of a 20 nt bistable RNA were characterized at temperatures between 298 and 310K, yielding the enthalpy and entropy differences between the conformers at equilibrium and the activation energy of the refolding process. The kinetics of a more stable 32 nt bistable RNA could be analyzed by the same approach at elevated temperatures, i.e. at 314 and 316 K. Finally, the dynamics of a multi-stable RNA able to fold into two hairpin- and a pseudo-knotted conformation was studied by (13)C relaxation dispersion NMR spectroscopy.     

Thiol exchange catalysed refolding of small proteins utilizing solid-phase supports

The study of isolated snake toxin refolding has been a valuable tool in the understanding of protein folding dynamics. We report here differences in the refolding characteristics of three toxin classes and introduce a novel method for overcoming disulphide mismatching and oligomer formation by utilizing solid-phase thiol exchange gels.     

Hydrogen bonding dynamics during protein folding of reduced cytochrome c: temperature and denaturant concentration dependence

Folding dynamics of reduced cytochrome c triggered by the laser-induced reduction method is investigated from a viewpoint of the intermolecular interaction change. Change of the diffusion coefficient of cytochrome c during the refolding process is traced in the time domain from the unfolded value to the native value continuously at various denaturant (guanidine hydrochloride (GdnHCl)) concentrations and temperatures. In the temperature range of 288 K-308 K and GdnHCl concentration range of 2.5 M-4.25 M, the diffusion change can be analyzed well by the two-state model consistently. It was found that the m(double dagger)-value and the activation energy of the transition state from the unfolded state for the hydrogen bonding network change are surprisingly similar to that for the local structural change around the heme group monitored by the fluorescence quenching experiment. This agreement suggests the existence of common or similar fundamental dynamics including water molecular movement to control the refolding dynamics. The nature of the transition state is discussed.     

Probing the Impact of Temperature and Substrates on the Conformational Dynamics of the Neurotransmitter:Sodium symporter LeuT

The crucial function of neurotransmitter:sodium symporters (NSS) in facilitating the reuptake of neurotransmitters into neuronal cells makes them attractive drug targets for treating multiple mental diseases. Due to the challenges in working with eukaryotic NSS proteins, LeuT, a prokaryotic amino acid transporter, has served as a model protein for studying structure–function relationships of NSS family proteins. With hydrogen–deuterium exchange mass spectrometry (HDX-MS), slow unfolding/refolding kinetics were identified in multiple regions of LeuT, suggesting that substrate translocation involves cooperative fluctuations of helical stretches. Earlier work has solely been performed at non-native temperatures (25 °C) for LeuT, which is evolutionarily adapted to function at high temperatures (85 – 95 °C). To address the effect of temperature on LeuT dynamics, we have performed HDX-MS experiments at elevated temperatures (45 °C and 60 °C). At these elevated temperatures, multiple regions in LeuT exhibited increased dynamics compared to 25 °C. Interestingly, coordinated slow unfolding/refolding of key regions could still be observed, though considerably faster. We have further investigated the conformational impact of binding the efficiently transported substrate alanine (Ala) relative to the much slower transported substrate leucine (Leu). Comparing the HDX of the Ala-bound versus Leu-bound state of LeuT, we observe distinct differences that could explain the faster transport rate (k_cat) of Ala relative to Leu. Importantly, slow unfolding/refolding dynamics could still be observed in regions of Ala-bound LeuT . Overall, our work brings new insights into the conformational dynamics of LeuT and provides a better understanding of the transport mechanism of LeuT and possibly other transporters bearing the LeuT fold.     

The conformational transition of horse heart porphyrin c

The heme iron of horse heart cytochrome c was selectively removed using anhydrous HF. The product, porphyrin c, exhibits the viscosity, far ultraviolet circular dichroic, and fluorescence properties characteristic for native cytochrome c. However, porphyrin c is more susceptible to denaturation by guanidine hydrochloride and by heat than is the parent cytochrome. All of the conformational parameters of porphyrin c exhibit a common reversible transition centered at 0.95 m guanidine hydrochloride at 23 degrees C and pH 7.0. Guanidine denatured porphyrin c refolds in two kinetic phases having time constants of 20 and 200 ms as detected by stopped flow absorbance or fluorescence measurement, with about 80% of the observed change in the faster phase. The kinetics of porphyrin c refolding are not significantly altered by increasing the viscosity of the refolding solvent 15-fold by addition of sucrose. We suggest that the folding of guanidine denatured cytochrome c is not a diffusion-limited process and that the requirement for protein axial ligation elicits the slow (s) kinetic phase observed in the refolding of cytochrome c.     

A novel system for continuous protein refolding and on-line capture by expanded bed adsorption

A novel two-step protein refolding strategy has been developed, where continuous renaturation-bydilution is followed by direct capture on an expanded bed adsorption (EBA) column. The performance of the overall process was tested on a N-terminally tagged version of human beta2-microglobulin (HAT-hbeta2m) both at analytical, small, and preparative scale. In a single scalable operation, extracted and denatured inclusion body proteins from Escherichia coli were continuously diluted into refolding buffer, using a short pipe reactor, allowing for a defined retention and refolding time, and then fed directly to an EBA column, where the protein was captured, washed, and finally eluted as soluble folded protein. Not only was the eluted protein in a correctly folded state, the purity of the HAThbeta2m was increased from 34% to 94%, and the product was concentrated sevenfold. The yield of the overall process was 45%, and the product loss was primarily a consequence of the refolding reaction rather than the EBA step. Full biological activity of HAT-hbeta2m was demonstrated after removal of the HAT-tag. In contrast to batch refolding, a continuous refolding strategy allows the conditions to be controlled and maintained throughout the process, irrespective of the batch size; i.e., it is readily scalable. Furthermore, the procedure is fast and tolerant toward aggregate formation, a common complication of in vitro protein refolding. In conclusion, this system represents a novel approach to small and preparative scale protein refolding, which should be applicable to many other proteins.     

Nature of the fast and slow refolding reactions of iron(III) cytochrome c

The fast and slow refolding reactions of iron(III) cytochrome c (Fe(III) cyt c), previously studied by Ikai et al. (Ikai, A., Fish, W. W., & Tanford, C. (1973) J. Mol. Biol. 73, 165--184), have been reinvestigated. The fast reaction has the major amplitude (78%) and is 100-fold faster than the slow reaction in these conditions (pH 7.2, 25 degrees C, 1.75 M guanidine hydrochloride). We show here that native cyt c is the product formed in the fast reaction as well as in the slow reaction. Two probes have been used to test for formation of native cyt c. absorbance in the 695-nm band and rate of reduction of by L-ascorbate. Different unfolded species (UF, US) give rise to the fast and slow refolding reactions, as shown both by refolding assays at different times after unfolding ("double-jump" experiments) and by the formation of native cyt c in each of the fast and slow refolding reactions. Thus the fast refolding reaction is UF leads to N and the slow refolding reaction is Us leads to N, where N is native cyt c, and there is a US in equilibrium UF equilibrium in unfolded cyt c. The results are consistent with the UF in equilibrium US reaction being proline isomerization, but this has not yet been tested in detail. Folding intermediates have been detected in both reactions. In the UF leads to N reaction, the Soret absorbance change precedes the recovery of the native 695-nm band spectrum, showing that Soret absorbance monitors the formation of a folding intermediate. In the US leads to N reaction an ascorbate-reducible intermediate has been found at an early stage in folding and the Soret absorbance change occurs together with the change at 695 nm as N is formed in the final stage of folding.     

蛋白质的排阻色谱复性的新进展

外源蛋白在大肠杆菌中高效表达时 ,常常形成不溶的、无活性的包涵体 ,包涵体蛋白的复性是重组蛋白生产过程中的一个技术难题。排阻色谱 (sizeexclusionchromatography ,SEC)用于蛋白复性是一种较新的、适用于任何一种蛋白的方法 ,与常用的稀释复性法相比 ,它能在高的起始蛋白浓度下对蛋白进行复性 ,活性回收率较高 ,同时又能使目标蛋白得到一定程度的纯化。对使用SEC复性的进展进行了评述 ,其内容包括SEC复性的原理及其复性过程中的影响因素 ,并对其未来发展进行了展望。     

Binding,unfolding and refolding dynamics of serum albumins

Background

The serum albumins (human and bovine serum albumin) occupy a seminal position among all proteins investigated until today as they are the most abundant circulatory proteins. They play the major role of a transporter of many bio-active substances which include various fatty acids, drug molecules, and amino acids to the target cells. Hence, studying the interaction of these serum albumins with different binding agents has attracted enormous research interests from decades. The nature and magnitude of these bindings have direct consequence on drug delivery, pharmacokinetics, therapeutic efficacy and drug design and control.

Scope of the review

In the present review, we summarize the binding characteristics of both the serum albumins with surfactants, lipids and vesicles, polymers and dendrimers, nanomaterials and drugs. Finally we have reviewed the effect of various chemical and physical denaturants on these albumins with a special emphasis on protein unfolding and refolding dynamics.

Major conclusions

The topic of binding and dynamics of protein unfolding and refolding spans across all areas of inter-disciplinary sciences and will benefit clinical toxicology and medicines. The extensive data from several contemporary research based on albumins will help us to understand protein dynamics in a more illustrious manner.

General significance

These data have immense significance in understanding and unravelling the mechanisms of protein unfolding/refolding and thus can pave the way to prevent protein mis-folding/aggregation which sometimes leads to severe consequences like Parkinson's and Alzheimer's diseases. This article is a part of a Special Issue entitled Serum Albumin. This article is part of a Special Issue entitled Serum Albumin.     

Overproduction of single-chain antibodies against human IFN-alpha2B in Escherichia coli and their isolation in biologically active form

The gene encoding mouse single chain antibody (ScFv) against human interferon alpha2b (IFN-alpha2b) was cloned into the plasmid vector under the control of promoter from phage T7 and the recombinant protein was expressed in Escherichia coli as inclusion bodies. After the isolation of inclusion bodies the desired protein containing affinity tail "6His tag" was solubilized and purified under denaturing conditions by immobilized-metal affinity chromatography. The soluble and purified ScFv was obtained by "on column" refolding and the recovery of biological activity were demonstrated. The higher levels of ScFv production for intracellular expression system in comparison with ScFv obtained by secretion were shown. The advantages of described refolding method are simplicity and high efficacy, moreover, refolding using a chromatographic process represents the manufacturable approach because it is easily automated using commercially available materials and preparative chromatography systems and also can be combined with simultaneous purification.     

The enzyme rhodanese can be reactivated after denaturation in guanidinium chloride

For the first time, the enzyme rhodanese has been refolded after denaturation in guanidinium chloride (GdmHCl). Renaturation was by either (a) direct dilution into the assay, (b) intermediate dilution into buffer, or (c) dialysis followed by concentration and centrifugation. Method (c) preferentially retained active enzyme whose specific activity was 1140 IU/mg, which fell to 898 IU/mg after 6 days. The specific activity of native enzyme is 710 IU/mg. Progress curves were linear for the dialyzed enzyme, and kinetic analysis showed it had the same Km for thiosulfate as the native enzyme, but apparently displayed a higher turnover number. Progress curves for denatured enzyme directly diluted into assay mix showed as many as three phases: a lag during which no product formed; a first order reactivation; and an apparently linear steady state. An induction period was determined by extrapolating the steady-state line to the time axis. The percent reactivation fell to 7% (t1/2 = 10 min) as the time increased between GdmHCl dilution and the start of the assay, independent of the presence of thiosulfate. The induction period, which decreased to zero as the incubation time increased, was retained in the presence of thiosulfate. There were no observable differences between native and renatured protein by electrophoresis or fluorescence spectroscopy. Previous reports of some refolding of urea-denatured rhodanese (Stellwagen, E. (1979) J. Mol. Biol. 135, 217-229) were confirmed, extended, and compared with results using GdmHCl. A working hypothesis is that rhodanese refolding involves intermediates that partition into active and inactive products. These intermediates may result from nucleation of the two rhodanese domains, which exposes hydrophobic surfaces that become the interdomain interface in the correctly folded protein.     

Review: Protein refolding and inactivation during bioseparation: Bioprocessing implications

The recombinant production of proteins leads to inclusion bodies which contain aggregated proteins in active, partially active, and inactive conformational states. These aggregated proteins must be extracted from the inclusion bodies, unfolded, and carefully refolded to the active and the stable conformational state. Mechanistic models for protein refolding are briefly presented. Different strategies and protocols are presented that lead to the active and stable protein conformational state. The techniques presented include chaperonin-assisted refolding, amino acid substitution, polyethylene glycolassisted refolding, protein refolding in reverse micelles, and antibody-assisted refolding of proteins. The techniques presented together provide a reasonable framework of the state-of-the-art and may be carefully applied to the bioseparation of other proteins and biological macromolecules of interest. (c) 1995 John Wiley & Sons, Inc.     

Refolding of proteins from inclusion bodies: rational design and recipes

The need to develop protein biomanufacturing platforms that can deliver proteins quickly and cost-effectively is ever more pressing. The rapid rate at which genomes can now be sequenced demands efficient protein production platforms for gene function identification. There is a continued need for the biotech industry to deliver new and more effective protein-based drugs to address new diseases. Bacterial production platforms have the advantage of high expression yields, but insoluble expression of many proteins necessitates the development of diverse and optimised refolding-based processes. Strategies employed to eliminate insoluble expression are reviewed, where it is concluded that inclusion bodies are difficult to eliminate for various reasons. Rational design of refolding systems and recipes are therefore needed to expedite production of recombinant proteins. This review article discusses efforts towards rational design of refolding systems and recipes, which can be guided by the development of refolding screening platforms that yield both qualitative and quantitative information on the progression of a given refolding process. The new opportunities presented by light scattering technologies for developing rational protein refolding buffer systems which in turn can be used to develop new process designs armed with better monitoring and controlling functionalities are discussed. The coupling of dynamic and static light scattering methodologies for incorporation into future bioprocess designs to ensure delivery of high-quality refolded proteins at faster rates is also discussed.     

Transient dimer in the refolding kinetics of cytochrome c characterized by small-angle X-ray scattering

The equilibrium unfolding and the kinetic refolding of cytochrome c (Cyt c) in the presence of imidazole were studied with small-angle X-ray scattering (SAXS). The equilibrium unfolding experiments showed the radius of gyration, R(g), of native Cyt c to swell approximately 1 A with the addition of imidazole. The thermodynamic parameter m also reflects an expansion of the protein as its lower value demonstrates an increase in solvent-accessible surface area over that of native Cyt c in the absence of imidazole. Refolding was studied in the presence of imidazole as it prevents misligated intermediate states from forming during the refolding process, simplifying the kinetics, and making them easier to resolve. Time-resolved decreases in the forward scattering amplitude, I(0), demonstrated the transient formation of an aggregated intermediate. Final protein and denaturant concentrations were varied in the refolding kinetics, and the singular value decomposition (SVD) method was employed to characterize the associated state. This state was determined to be a dimer, with properties consistent with a molten globule.     

Partially oxidized active intermediates in refolding of reduced ribonuclease

The refolding of reduced ribonuclease A has been studied by measurements of enzymatic activity under conditions where the oxidation of thiol groups into disulfide bonds is rather slow. The sensitivity to a treatment by N-ethylmaleimide has been used to distinguish between partially and totally oxidized active species. It is found that the first active protein molecules to be formed do not have all of their disulfide bonds. Because they are active, these partially oxidized intermediates probably have very close to native conformation, which they can reach without being trapped in a wrong structure by forming too many incorrect disulfide bonds. The significance of these intermediates to the refolding pathway of reduced ribonuclease is discussed.     

Review: mechanisms of disaggregation and refolding of stable protein aggregates by molecular chaperones

Molecular chaperones are essential for the correct folding of proteins in the cell under physiological and stress conditions. Two activities have been traditionally attributed to molecular chaperones: (1) preventing aggregation of unfolded polypeptides and (2) assisting in the correct refolding of chaperone-bound denatured polypeptides. We discuss here a novel function of molecular chaperones: catalytic solubilization and refolding of stable protein aggregates. In Escherichia coli, disaggregation is carried out by a network of ATPase chaperones consisting of a DnaK core, assisted by the cochaperones DnaJ, GrpE, ClpB, and GroEL-GroES. We suggest a sequential mechanism in which (a) ClpB exposes new DnaK-binding sites on the surface of the stable protein aggregates; (b) DnaK binds the aggregate surfaces and, by doing so, melts the incorrect hydrophobic associations between aggregated polypeptides; (c) ATP hydrolysis and DnaK release allow local intramolecular refolding of native domains, leading to a gradual weakening of improper intermolecular links; (d) DnaK and GroEL complete refolding of solubilized polypeptide chains into native proteins. Thus, active disaggregation by the chaperone network can serve as a central cellular tool for the recovery of native proteins from stress-induced aggregates and actively remove disease-causing toxic aggregates, such as polyglutamine-rich proteins, amyloid plaques, and prions.