Conformational States of the Water-Soluble Fragment of Cytochrome b5. I. pH-Induced Denaturation

Cytochrome b ₅ is a membrane protein that comprises two fragments: one is water-soluble and heme-containing, and the other is hydrophobic and membrane-embedded. The function of electron transfer is performed by the former whose crystal structure is known; however, its conformational states when in the membrane field and interacting with other proteins are still to be studied. Previously, we proposed water–alcohol mixtures for modeling the effect of membrane surface on proteins, and used this approach to study the conformational behavior of positively charged cytochrome c as well as relatively neutral retinol-binding protein also functioning in the field of a negatively charged membrane. The current study describes the conformational behavior of the negatively charged water-soluble fragment of cytochrome b ₅ as dependent on pH. Decreasing pH was shown to transform the fragment state from native to intermediate, similar to the molten globule reported earlier for other proteins in aqueous solutions: at pH 3.0, the fragment preserved a pronounced secondary structure and compactness but lost its rigid tertiary structure. A possible role of this intermediate state in cytochrome b ₅ functioning is discussed.     

Order propensity of an intrinsically disordered protein,the cyclin‐dependent‐kinase inhibitor Sic1

Intrinsically disordered proteins (IDPs) carry out important biological functions and offer an instructive model system for folding and binding studies. However, their structural characterization in the absence of interactors is hindered by their highly dynamic conformation. The cyclin‐dependent‐kinase inhibitor (Cki) Sic1 from Saccharomyces cerevisiae is a key regulator of the yeast cell cycle, which controls entrance into S phase and coordination between cell growth and proliferation. Its last 70 out of 284 residues display functional and structural homology to the inhibitory domain of mammalian p21 and p27. Sic1 has escaped systematic structural characterization until now. Here, complementary biophysical methods are applied to the study of conformational properties of pure Sic1 in solution. Based on sequence analysis, gel filtration, circular dichroism (CD), electrospray‐ionization mass spectrometry (ESI‐MS), and limited proteolysis, it can be concluded that the whole molecule exists in a highly disordered state and can, therefore, be classified as an IDP. However, the results of these experiments indicate, at the same time, that the protein displays some content in secondary and tertiary structure, having properties similar to those of molten globules or premolten globules. Proteolysis‐hypersensitive sites cluster at the N‐terminus and in the middle of the molecule, whereas the most structured region resides at the C‐terminus, including part of the inhibitory domain and the casein‐kinase‐2 (CK2) phosphorylation target S201. The mutations S201A and S201E, which are known to affect Sic1 function, do not have significant effects on the conformational properties of the pure protein. Proteins 2009;76:731–746. © 2009 Wiley‐Liss, Inc.     

All-atom molecular dynamics simulations reveal significant differences in interaction between antimycin and conserved amino acid residues in bovine and bacterial bc1 complexes

Antimycin A is the most frequently used specific and powerful inhibitor of the mitochondrial respiratory chain. We used all-atom molecular dynamics (MD) simulations to study the dynamic aspects of the interaction of antimycin A with the Q_i site of the bacterial and bovine bc₁ complexes embedded in a membrane. The MD simulations revealed considerable conformational flexibility of antimycin and significant mobility of antimycin, as a whole, inside the Q_i pocket. We conclude that many of the differences in antimycin binding observed in high-resolution x-ray structures may have a dynamic origin and result from fluctuations of protein and antimycin between multiple conformational states of similar energy separated by low activation barriers, as well as from the mobility of antimycin within the Q_i pocket. The MD simulations also revealed a significant difference in interaction between antimycin and conserved amino acid residues in bovine and bacterial bc₁ complexes. The strong hydrogen bond between antimycin and conserved Asp-228 (bovine numeration) was observed to be frequently broken in the bacterial bc₁ complex and only rarely in the bovine bc₁ complex. In addition, the distances between antimycin and conserved His-201 and Lys-227 were consistently larger in the bacterial bc₁ complex. The observed differences could be responsible for a weaker interaction of antimycin with the bacterial bc₁ complex.     

X-ray structure of the PHF core C-terminus: insight into the folding of the intrinsically disordered protein tau in Alzheimer's disease

The major constituent of Alzheimer's disease paired helical filaments (PHF) core is intrinsically disordered protein (IDP) tau. In spite of a considerable effort, insoluble character of PHF together with inherent physical properties of IDP tau have precluded so far reconstruction of PHF 3D structure by X-ray crystallography or NMR spectroscopy. Here we present first crystallographic study of PHF core C-terminus. Using monoclonal antibody MN423 specific to the tertiary structure of the PHF core, the in vivo PHF structure was imprinted into recombinant core PHF tau. Crystallization of the complex led to determination of the structure of the core PHF tau protein fragment 386TDHGAE391 at 1.65A resolution. Structural analysis suggests important role of the core PHF C-terminus for PHF assembly. It is reasonable to expect that this approach will help to reveal the structural principles underlying the tau protein assembly into PHF and possibly will facilitate rationale drug design for inhibition of Alzheimer neurofibrillary changes.     

Alkaline unfolding and salt-induced folding of arginine kinase from shrimp Feneropenaeus chinensis under high pH conditions

The structural and functional properties of arginine kinase (AK) in alkaline conditions in the absence or presence of salt have been investigated. The conformational changes of AK during alkaline unfolding and salt-induced folding at alkaline pH were monitored using intrinsic fluorescence emission, binding of the fluorescence probe 1-anilino-8-naphthalenesulfonate and circular dichroism. The results for the alkaline unfolded enzyme showed that much lower pH (11.0) was required to cause the complete loss of AK activity than was required to cause an obvious conformational change of the enzyme. Compared with the completely unfolded state in 5 M urea, the high pH denatured enzyme had some residual secondary and tertiary structure even at pH 13.0. Increasing the ionic strength by adding salt at pH 12.75 resulted in the formation of a relatively compact tertiary structure and a little new secondary structure with hydrophobic surface enhancement. These results indicate that the partially folded state formed under alkaline conditions may have similarities to the molten globule state which is compact, but it has a poorly defined tertiary structure and a native-like secondary structure.     

Engineering a compact non-native state of intestinal fatty acid-binding protein

The last three C-terminal residues (129-131) of intestinal fatty acid-binding protein (IFABP) participate in four main-chain hydrogen bonds and two electrostatic interactions to sequentially distant backbone and side-chain atoms. To assess if these interactions are involved in the final adjustment of the tertiary structure during folding, we engineered an IFABP variant truncated at residue 128. An additional mutation, Trp-6-->Phe, was introduced to simplify the conformational analysis by optical methods. Although the changes were limited to a small region of the protein surface, they resulted in an IFABP with altered secondary and tertiary structure. Truncated IFABP retains some cooperativity, is monomeric, highly compact, and has the molecular dimensions and shape of the native protein. Our results indicated that residues 129-131 are part of a crucial conformational determinant in which several long-range interactions, essential for the acquisition of the native state, are established. This work suggests that carefully controlled truncation can populate equilibrium non-native states under physiological conditions. These non-native states hold a great promise as experimental models for protein folding.     

Ligand-induced conformational changes via flexible linkers in the amino-terminal region of the inositol 1,4,5-trisphosphate receptor

Cytoplasmic Ca2+ signals are highly regulated by various ion transporters, including the inositol 1,4,5-trisphosphate (IP(3)) receptor (IP(3)R), which functions as a Ca2+ release channel on the endoplasmic reticulum membrane. Crystal structures of the two N-terminal regulatory regions from type 1 IP(3)R have been reported; those of the IP(3)-binding core (IP(3)R(CORE)) with bound IP(3), and the suppressor domain. This study examines the structural effects of ligand binding on an IP(3)R construct, designated IP(3)R(N), that contains both the IP(3)-binding core and the suppressor domain. Our circular dichroism results reveal that the IP(3)-bound and IP(3)-free states have similar secondary structure content, consistent with preservation of the overall fold within the individual domains. Thermal denaturation data show that, while IP(3) has a large effect on the stability of IP(3)R(CORE), it has little effect on IP(3)R(N), indicating that the suppressor domain is critical to the stability of IP(3)R(N). The NMR data for IP(3)R(N) provide evidence for chemical exchange, which may be due to protein conformational dynamics in both apo and IP(3)-bound states: a conclusion supported by the small-angle X-ray scattering data. Further, the scattering data show that IP(3)R(N) undergoes a change in average conformation in response to IP(3) binding and the presence of Ca2+ in the solution. Taken together, these data lead us to propose that there are two flexible linkers in the N-terminal region of IP(3)R that join stably folded domains and give rise to an equilibrium mixture of conformational sub-states containing compact and more extended structures. IP(3) binding drives the conformational equilibrium toward more compact structures, while the presence of Ca2+ drives it to a more extended set.     

Homogeneous and heterogeneous tertiary structure ensembles of amyloid-β peptides

The interplay of modern molecular simulation and high-quality nuclear magnetic resonance (NMR) experiments has reached a fruitful stage for quantitative characterization of structural ensembles of disordered peptides. Amyloid-β 1-42 (Aβ42), the primary peptide associated with Alzheimer's disease, and fragments such as Aβ21-30 are both classified as intrinsically disordered peptides (IDPs). We use a variety of NMR observables to validate de novo molecular dynamics simulations in explicit water to characterize the tertiary structure ensemble of Aβ42 and Aβ21-30 from the perspective of their classification as IDPs. Unlike the Aβ21-30 fragment that conforms to expectations of an IDP that is primarily extended, we find that Aβ42 samples conformations reflecting all possible secondary structure categories and spans the range of IDP classifications from collapsed structured states to highly extended conformations, making it an IDP with a far more heterogeneous tertiary ensemble.     

Defining Structural Domains of an Intrinsically Disordered Protein: Sic1, the Cyclin-Dependent Kinase Inhibitor of <Emphasis Type="Italic">Saccharomyces</Emphasis><Emphasis Type="Italic">cerevisiae</Emphasis>

The cyclin-dependent kinase inhibitor Sic1 is an intrinsically disordered protein (IDP) involved in cell–cycle regulation in the yeast Saccharomyces cerevisiae. Notwithstanding many studies on its biological function, structural characterization has been attempted only recently, fostering the development of production and purification protocols suitable to yield large amounts of this weakly expressed protein. In this study, we describe the identification of protein domains by the heterologous expression, purification, and characterization of Sic1-derived fragment. Four C-terminal fragments (Sic1^C-ter) were produced based on functional studies and limited-proteolysis results. The N-terminal fragment (Sic1^1–186) was complementary to the most stable C-terminal fragments (Sic1^Δ186). Both Sic1^1–186 and Sic1^C-ter fragments were, in general, less susceptible to spontaneous proteolysis than the full-length protein. The boundaries of the C-terminal fragments turned out to be crucial for integrity of the recombinant proteins and required two rounds of design and production. Sic1 fragments were purified by a simple procedure, based on their resistance to heat treatment, at the amount and purity required for structural characterization. Circular dichroism (CD) measurements and nuclear magnetic resonance (NMR) spectra of N- and C-terminal fragments confirm their disordered nature but reveal minor structural differences that may reflect their distinct functional roles.     

Conformational properties of the aggregation precursor state of HypF-N

The conversion of specific proteins or protein fragments into insoluble, ordered fibrillar aggregates is a fundamental process in protein chemistry, biology, medicine and biotechnology. As this structural conversion seems to be a property shared by many proteins, understanding the mechanism of this process will be of extreme importance. Here we present a structural characterisation of a conformational state populated at low pH by the N-terminal domain of Escherichia coli HypF. Combining different biophysical and biochemical techniques, including near- and far-UV circular dichroism, intrinsic and 8-anilinonaphthalene-1-sulfonate-derived fluorescence, dynamic light scattering and limited proteolysis, we will show that this state is largely unfolded but contains significant secondary structure and hydrophobic clusters. It also appears to be more compact than a random coil-like state but less organised than a molten globule state. Increase of the total ionic strength of the solution induces aggregation of such a pre-molten globule state into amyloid-like protofibrils, as revealed by thioflavin T fluorescence and atomic force microscopy. These results show that a pre-molten globule state can be, among other possible conformational states, one of the precursor states of amyloid formation. In addition, the possibility of triggering aggregation by modulating the ionic strength of the solution provides one a unique opportunity to study both the initial precursor state and the aggregation process.     

Structure and Disorder in an Unfolded State under Nondenaturing Conditions from Ensemble Models Consistent with a Large Number of Experimental Restraints

Obtaining detailed structural models of disordered states of proteins under nondenaturing conditions is important for a better understanding of both functional intrinsically disordered proteins and unfolded states of folded proteins. Extensive experimental characterization of the drk N-terminal SH3 domain unfolded state has shown that, although it appears to be highly disordered, it possesses significant nonrandom secondary and tertiary structure. In our previous attempts to generate structural models of the unfolded state using the program ENSEMBLE, we were limited by insufficient experimental restraints and conformational sampling. In this study, we have vastly expanded our experimental restraint set to include ¹H-¹⁵N residual dipolar couplings, small-angle X-ray scattering measurements, nitroxide paramagnetic relaxation enhancements, O₂-induced ¹³C paramagnetic shifts, hydrogen-exchange protection factors, and ¹⁵N R₂ data, in addition to the previously used nuclear Overhauser effects, amino terminal Cu²⁺-Ni²⁺ binding paramagnetic relaxation enhancements, J-couplings, chemical shifts, hydrodynamic radius, and solvent accessibility restraints. We have also implemented a new ensemble calculation methodology that uses iterative conformational sampling and seeks to calculate the simplest possible ensemble models. As a result, we can now generate ensembles that are consistent with much larger experimental data sets than was previously possible. Although highly heterogeneous and having broad molecular size distributions, the calculated drk N-terminal SH3 domain unfolded-state ensembles have very different properties than expected for random or statistical coils and possess significant nonnative α-helical structure and both native-like and nonnative tertiary structure.     

Transient tertiary structures in tau,an intrinsically disordered protein

An intrinsically disordered protein (IDP) does not have a definite 3D structure, and because of its highly flexible nature it evolves dynamically in very large and diverse regions of the phase space. A standard molecular dynamics run can sample only a limited region of the latter; even though this kind of simulation may be effective in sampling local temporary secondary structures, it is not sufficient to highlight properties that require a larger sampling of the phase space to be detected, like transient tertiary structures. But if the structure of an IDP is dynamically evolved using metadynamics (an algorithm that keeps track of the regions of the phase space already sampled), the system can be forced to wander in a much larger region of the phase space. We have applied this procedure to the simulation of tau, one of the largest totally disordered proteins. Combining the results of the simulation with small-angle X-ray scattering yields a significant improvement in the sampling of the phase space in comparison with standard molecular dynamics, and provides evidence of extended hairpin- and paperclip-like transient tertiary structures of the molecule. The more persistent tertiary pattern is a hairpin folding encompassing part of the N-terminal, the proline-rich domain, the former repeat and a functionally relevant part of the second repeat.     

Conformational states of the water-soluble fragment of cytochrome b5. I. pH-induced denaturation

Cytochrome b5 is a membrane protein that comprises two fragments: one is water-soluble and heme-containing, and the other is hydrophobic and membrane-embedded. The function of electron transfer is performed by the former whose crystal structure is known; however, its conformational states when in the membrane field and interacting with other proteins are still to be studied. Previously, we proposed water-alcohol mixtures for modeling the effect of membrane surface on proteins, and used this approach to study the conformational behavior of positively charged cytochrome c as well as relatively neutral retinol-binding protein also functioning in the field of negatively charged membrane. The current study describes the conformational behavior of the negatively charged water-soluble fragment of cytochrome b5 as dependent on pH. Decreasing pH was shown to transform the fragment state from native to intermediate, similar to the molten globule reported earlier for other proteins in aqueous solutions: at pH 3.0, the fragment preserved a pronounced secondary structure and compactness but lost its rigid tertiary structure. A possible role of this intermediate state in cytochrome b5 functioning is discussed.     

Structural and Functional Characterization of Acinetobacter baumannii Nucleoside Diphosphate Kinase

近年来,鲍曼不动杆菌(Acinetobacter baumannii)在医院里越来越受到人们的关注,尤其是在重症监护病房(ICUs)．它以强大的多重耐药性(multiresistance)而闻名．核苷二磷酸激酶(nucleoside diphosphate kinase,NDK)是一种进化上非常保守的酶,它能催化核苷之间磷酸基团的转移．我们解析了鲍曼不动杆菌NDK野生型和C端氨基酸残基Arg141-Thr142-Arg143(RTR)截短突变体的结构．通过和黄色黏菌(Myxococcus xanthus)NDK的三维结构进行比较,推断鲍曼不动杆菌NDK的催化机制和黄色黏菌类似．通过激酶活性实验和圆二色谱实验,发现鲍曼不动杆菌NDK E28A突变体二级结构发生了改变,从而导致蛋白催化活性降低,说明Glu28是鲍曼不动杆菌NDK结构中非常关键的氨基酸残基．鲍曼不动杆菌NDK C端RTR截短突变体显示出催化活性极大的降低,这可能与C端RTR残基介导的二体间相互作用有关．虽然RTR截短突变体中的Lys33伸向了和野生型中不同的方向,和Val15产生相互作用弥补了一部分因为RTR截短丢失的相互作用,维持了RTR截短突变体和野生型类似的结构．但是,Lys33产生的相互作用依然太弱,不足以维持蛋白在催化的动态过程中整体结构的高效转换．我们解析的鲍曼不动杆菌NDK晶体高分辨率结构将有助于科学家设计针对鲍曼不动杆菌的药物．     

Crystal structure of human FAF1 UBX domain reveals a novel FcisP touch-turn motif in p97/VCP-binding region

UBX domain is a general p97/VCP-binding module found in an increasing number of proteins including FAF1, p47, SAKS1 and UBXD7. FAF1, a multi-functional tumor suppressor protein, binds to the N domain of p97/VCP through its C-terminal UBX domain and thereby inhibits the proteasomal protein degradation in which p97/VCP acts as a co-chaperone. Here we report the crystal structure of human FAF1 UBX domain at 2.9 Å resolution. It reveals that the conserved FP sequence in the p97/VCP-binding region adopts a rarely observed cis-Pro touch-turn structure. We call it an FcisP touch-turn motif and suggest that it is the conserved structural element of the UBX domain. Four FAF1 UBX molecules in an asymmetric unit of the crystal show two different conformations of the FcisP touch-turn motif. The phenyl ring of F⁶¹⁹ in the motif stacks partly over cis-Pro⁶²⁰ in one conformation, whereas it is swung out from cis-P⁶²⁰, in the other conformation, and forms hydrophobic contacts with the residues of the neighboring molecule. In addition, the entire FcisP touch-turn motif is pulled out in the second conformation by about 2 Å in comparison to the first conformation. Those conformational differences observed in the p97/VCP-binding motif caused by the interaction with neighboring molecules presumably represent the conformational change of the UBX domain on its binding to the N domain of p97/VCP.     

Predicting molecular properties of α-synuclein using force fields for intrinsically disordered proteins

Independent force field validation is an essential practice to keep track of developments and for performing meaningful Molecular Dynamics simulations. In this work, atomistic force fields for intrinsically disordered proteins (IDP) are tested by simulating the archetypical IDP α-synuclein in solution for 2.5 μs. Four combinations of protein and water force fields were tested: ff19SB/OPC , ff19SB/TIP4P-D , ff03CMAP/TIP4P-D , and a99SB-disp/TIP4P-disp , with four independent repeat simulations for each combination. We compare our simulations to the results of a 73 μs simulation using the a99SB-disp/TIP4P-disp combination, provided by D. E. Shaw Research. From the trajectories, we predict a range of experimental observations of α-synuclein and compare them to literature data. This includes protein radius of gyration and hydration, intramolecular distances, NMR chemical shifts, and ³J-couplings. Both ff19SB/TIP4P-D and a99SB-disp/TIP4P-disp produce extended conformational ensembles of α-synuclein that agree well with experimental radius of gyration and intramolecular distances while a99SB-disp/TIP4P-disp reproduces a balanced α-synuclein secondary structure content. It was found that ff19SB/OPC and ff03CMAP/TIP4P-D produce overly compact conformational ensembles and show discrepancies in the secondary structure content compared to the experimental data.     

Mapping long-range contacts in a highly unfolded protein

Insights into the earliest events in protein folding can be obtained by analysis of the conformational propensities of unfolded or partly folded states. The structure of the acid-unfolded state of apomyoglobin has been characterized using paramagnetic spin labeling and NMR. Nitroxide side-chains, introduced by coupling to mutant cysteine residues at positions 18, 77, and 133, were used as probes of chain compaction and long-range tertiary contacts. Significant interactions are observed within and between the N and C termini, while the central region of the polypeptide chain behaves as a random polymer. Even in this highly denatured form, the protein samples transient compact states in which there are native-like contacts between the N and C-terminal regions.     

Development of a fluorescently labeled thermostable DHFR for studying conformational changes associated with inhibitor binding

A fluorescently-labeled, conformationally-sensitive Bacillus stearothermophilus (Bs) dihydrofolate reductase (DHFR) (C73A/S131C_MDCC DHFR) was developed and used to investigate kinetics and protein conformational motions associated with methotrexate (MTX) binding. This construct bears a covalently-attached fluorophore, N-[2-(1-maleimidyl)ethyl]-7-(diethylamino)coumarin-3-carboxamide (MDCC) attached at a distal cysteine, introduced by mutagenesis. The probe is sensitive to the local molecular environment, reporting on changes in the protein structure associated with ligand binding. Intrinsic tryptophan fluorescence of the unlabeled Bs DHFR construct (C73A/S131C DHFR) also showed changes upon MTX association. Stopped-flow analysis of all data can be understood by invoking the presence of two native state DHFR conformers that bind to MTX at different rates (20.2 and 0.067 μM⁻¹ s⁻¹), similar to previously published findings for Escherichia coli DHFR. Probe fluorescence of C73A/S131C_MDCC DHFR predominantly reports on MTX binding to one of the conformers while intrinsic tryptophan fluorescence of C73A/S131C DHFR reports on binding to the other conformer. This study demonstrates the use of an extrinsic fluorophore attached to a distal region to investigate ligand binding interactions that are not experimentally accessible via intrinsic tryptophan fluorescence alone. The thermostability of C73A/S131C_MDCC DHFR provides an important new tool with applications for investigating the temperature dependence of DHFR conformational changes associated with binding and catalysis.