Role of the linker domain and the 203-214 N-terminal residues in the human topoisomerase I DNA complex dynamics

The influence of the N-terminal residues 203-214 and the linker domain on motions in the human topoisomerase I-DNA complex has been investigated by comparing the molecular dynamics simulations of the system with (topo70) or without (topo58/6.3) these regions. Topo58/6.3 is found to fluctuate more than topo70, indicating that the presence of the N-terminal residues and the linker domain dampen the core and C-terminal fluctuations. The simulations also show that residues 203-207 and the linker domain participate in a network of correlated movements with key regions of the enzyme, involved in the human topoisomerase I catalytic cycle, providing a structural-dynamical explanation for the better DNA relaxation activity of topo70 when compared to topo58/6.3. The data have been examined in relation to a wealth of biochemical, site-directed mutagenesis and crystallographic data on human topoisomerase I. The simulations finally show the occurrence of a network of direct and water mediated hydrogen bonds in the proximity of the active site, and the presence of a water molecule in the appropriate position to accept a proton from the catalytic Tyr-723 residue, suggesting that water molecules have an important role in the stabilization and function of this enzyme.     

Defining the core structure of the alpha-lactalbumin molten globule state.

Molten globules are partially folded states of proteins which are generally believed to mimic structures formed during the folding process. In order to determine the minimal requirements for the formation of a molten globule state, we have prepared a set of peptide models of the molten globule state of human alpha-lactalbumin (alphaLA). A peptide consisting of residues 1-38 crosslinked, via the native 28-111 disulfide bond, to a peptide corresponding to residues 95-120 forms a partially folded state at pH 2.8 which has all of the characteristics of the molten globule state of alphaLA as judged by near and far UV CD, fluorescence, ANS binding and urea denaturation experiments. The structure of the peptide construct is the same at pH 7.0. Deletion of residues 95-100 from the construct has little effect. Thus, less than half the sequence is required to form a molten globule. Further truncation corresponding to the selective deletion of the A (residues 1-19) or D (residues 101-110) helices or the C-terminal 310 helix (residues 112-120) leads to a significant loss of structure. The loss of structure which results from the deletion of any of these three regions is much greater than that which would be expected based upon the non-cooperative loss of local helical structure. Deletion of residues corresponding to the region of the D helix or C-terminal 310 helix region results in a peptide construct which is largely unfolded and contains no more helical structure than is expected from the sum of the helicity of the two reduced peptides. These experiments have defined the minimum core structure of the alphaLA molten globule state.     

A comparative study of the alpha-subdomains of bovine and human alpha-lactalbumin reveals key differences that correlate with molten globule stability

The alpha-lactalbumins form stable molten globule states under a range of conditions, with the low pH form being the best characterized. The stability of the molten globule varies among different members of this family, but the origin of the stability difference is not clear. We compare the folding and stability of alpha-subdomain constructs of human and bovine alpha-lactalbumin. Previous studies have demonstrated that the isolated alpha-subdomain of human alpha-lactalbumin folds and forms a molten globule state. The minimum core construct has been defined to include the A, B, and D alpha-helices and the C-terminal 3(10) helix. A construct corresponding to the same region of bovine alpha-lactalbumin is much less structured and less stable than the human alpha-lactalbumin construct. Addition of the C-helix to generate a 75-residue bovine construct does not lead to a significant increase in structure or stability. This construct (AB-CD/3(10)) contains the entire alpha-subdomain of bovine alpha-lactalbumin. Thus molten globule formation in the human protein, but not in the bovine protein, can be rationalized on the basis of a stable alpha-subdomain. Interactions involving more of the protein chain are required to generate a well structured molten globule in the bovine protein. Comparison of AB-CD/3(10) to the molten globule formed by the intact protein and to the protein with the 6-120 disulfide reduced indicates that both the beta-subdomain and the 6-120 disulfide play a role in stabilizing the bovine alpha-lactalbumin molten globule.     

The p14ARF Alternate Reading Frame Protein Enhances DNA Binding of Topoisomerase I by Interacting with the Serine 506-Phosphorylated Core Domain

In addition to its well-characterized function as a tumor suppressor, p14ARF (ARF) is a positive regulator of topoisomerase I (topo I), a central enzyme in DNA metabolism and a target for cancer therapy. We previously showed that topo I hyperphosphorylation, a cancer-associated event mediated by elevated levels of the protein kinase CK2, increases topo I activity and the cellular sensitivity to topo I-targeted drugs. Topo I hyperphosphorylation also increases its interaction with ARF. Because the ARF−topo I interaction could be highly relevant to DNA metabolism and cancer treatment, we identified the regions of topo I involved in ARF binding and characterized the effects of ARF binding on topo I function. Using a series of topo I deletion constructs, we found that ARF interacted with the topo I core domain, which encompasses most of the catalytic and DNA-interacting residues. ARF binding increased the DNA relaxation activity of hyperphosphorylated topo I by enhancing its association with DNA, but did not affect the topo I catalytic rate. In cells, ARF promoted the chromatin association of hyperphosphorylated, but not basal phosphorylated, topo I, and increased topo I-mediated DNA nicking under conditions of oxidative stress. The aberrant nicking was found to correlate with increased formation of DNA double-strand breaks, which are precursors of many genome destabilizing events. The results suggest that the convergent actions of oxidative stress and elevated CK2 and ARF levels, which are common features of cancer cells, lead to a dysregulation of topo I that may contribute both to the cellular response to topo I-targeted drugs and to genome instability.     

The binding of topoisomerase I to T antigen enhances the synthesis of RNA-DNA primers during simian virus 40 DNA replication

Topoisomerase I (topo I) is required for the proper initiation of simian virus 40 (SV40) DNA replication. This enzyme binds to SV40 large T antigen at two places, close to the N-terminal end and near the C-terminal end of the helicase domain. We have recently demonstrated that the binding of topo I to the C-terminal site is necessary for the stimulation of DNA synthesis by topo I and for the formation of normal amounts of completed daughter molecules. In this study, we investigated the mechanism by which this stimulation occurs. Contrary to our expectation that the binding of topo I to this region of T antigen provides the proper unwound DNA substrate for initiation to occur, we demonstrate that binding of topo I stimulates polymerase alpha/primase (pol/prim) to synthesize larger amounts of primers consisting of short RNA and about 30 nucleotides of DNA. Topo I binding also stimulates the production of large molecular weight DNA by pol/prim. Mutant T antigens that fail to bind topo I normally do not participate in the synthesis of expected amounts of primers or large molecular weight DNAs indicating that the association of topo I with the C-terminal binding site on T antigen is required for these activities. It is also shown that topo I has the ability to bind to human RPA directly, suggesting that the stimulation of pol/prim activity may be mediated in part through RPA in the DNA synthesis initiation complex.     

An in vitro peptide folding model suggests the presence of the molten globule state during nascent peptide folding

Although molten globules have been widely accepted as a general intermediate in protein folding, there is no clear evidence to show their presence during nascent peptide folding. This paper concentrates on whether the molten globule state occurs, and if it does, when does it form during nascent peptide folding, by comparing the changes in conformation during peptide chain extension of staphylococcal nuclease R. The results show that a large N-terminal fragment of staphylococcal nuclease, SNR121, which already contains more than 80% amino acid sequence of the nuclease, is found to fulfill all the criteria for the molten globule state, suggesting that the molten globule should occur at a later stage of peptide elongation. At this stage the hydrophobic collapse of the polypeptide chain occurs driven by the hydrophobic force, which leads to the formation of a solvent-accessible non-polar core, characterized by the high ANS-binding fluorescence. The nascent peptide folding of the nuclease is a hierarchical process that at the very least includes the following steps: secondary structure accumulation, pre-molten globule state, molten globule state, post-molten globule state and finally the native state. Constant conformation adjustment is necessary for correct folding and active expression of the protein.     

Biophysical characterization of Z(SPA-1)--a phage-display selected binder to protein A

Affibodies are a novel class of binding proteins selected from phagemid libraries of the Z domain from staphylococcal protein A. The Z(SPA-1) affibody was selected as a binder to protein A, and it binds the parental Z domain with micromolar affinity. In earlier work we determined the structure of the Z:Z(SPA-1) complex and noted that Z(SPA-1) in the free state exhibits several properties characteristic of a molten globule. Here we present a more detailed biophysical investigation of Z(SPA-1) and four Z(SPA-1) mutants with the objective to understand these properties. The characterization includes thermal and chemical denaturation profiles, ANS binding assays, size exclusion chromatography, isothermal titration calorimetry, and an investigation of structure and dynamics by NMR. The NMR characterization of Z(SPA-1) was facilitated by the finding that trimethylamine N-oxide (TMAO) stabilizes the molten globule conformation in favor of the fully unfolded state. All data taken together lead us to conclude the following: (1) The topology of the molten globule conformation of free Z(SPA-1) is similar to that of the fully folded structure in the Z-bound state; (2) the extensive mutations in helices 1 and 2 destabilize these without affecting the intrinsic stability of helix 3; (3) stabilization and reduced aggregation can be achieved by replacing mutated residues in Z(SPA-1) with the corresponding wild-type Z residues. This stabilization is better correlated to changes in helix propensity than to an expected increase in polar versus nonpolar surface area of the fully folded state.     

N and C-terminal sub-regions in the c-Myc transactivation region and their joint role in creating versatility in folding and binding

The proto-oncogene c-myc governs the expression of a number of genes targeting cell growth and apoptosis, and its expression levels are distorted in many cancer forms. The current investigation presents an analysis by proteolysis, circular dichroism, fluorescence and Biacore of the folding and ligand-binding properties of the N-terminal transactivation domain (TAD) in the c-Myc protein. A c-Myc sub-region comprising residues 1-167 (Myc1-167) has been investigated that includes the unstructured c-Myc transactivation domain (TAD, residues 1-143) together with a C-terminal segment, which appears to promote increased folding. Myc1-167 is partly helical, binds both to the target proteins Myc modulator-1 (MM-1) and TATA box-binding protein (TBP), and displays the characteristics of a molten globule. Limited proteolysis divides Myc1-167 in two halves, by cleaving in a predicted linker region between two hotspot mutation regions: Myc box I (MBI) and Myc box II (MBII). The N-terminal half (Myc1-88) is unfolded and does not alone bind to target proteins, whereas the C-terminal half (Myc92-167) has a partly helical fold and specifically binds both MM-1 and TBP. Although this might suggest a bipartite organization in the c-Myc TAD, none of the N and C-terminal fragments bind target protein with as high affinity as the entire Myc1-167, or display molten globule properties. Furthermore, merely linking the MBI with the C-terminal region, in Myc38-167, is not sufficient to achieve binding and folding properties as in Myc1-167. Thus, the entire N and C-terminal regions of c-Myc TAD act in concert to achieve high specificity and affinity to two structurally and functionally orthogonal target proteins, TBP and MM-1, possibly through a mechanism involving molten globule formation. This hints towards understanding how binding of a range of targets can be accomplished to a single transactivation domain.     

Simian virus 40 DNA replication is dependent on an interaction between topoisomerase I and the C-terminal end of T antigen

Topoisomerase I (topo I) is needed for efficient initiation of simian virus 40 (SV40) DNA replication and for the formation of completed DNA molecules. Two distinct binding sites for topo I have been previously mapped to the N-terminal (residues 83 to 160) and C-terminal (residues 602 to 708) regions of T antigen. By mutational analysis, we identified a cluster of six residues on the surface of the helicase domain at the C-terminal binding site that are necessary for efficient binding to topo I in enzyme-linked immunosorbent assay and far-Western blot assays. Mutant T antigens with single substitutions of these residues were unable to participate normally in SV40 DNA replication. Some mutants were completely defective in supporting DNA replication, and replication was not enhanced in the presence of added topo I. The same mutants were the ones that were severely compromised in binding topo I. Other mutants demonstrated intermediate levels of activity in the DNA replication assay and were correspondingly only partially defective in binding topo I. Mutations of nearby residues outside this cluster had no effect on DNA replication or on the ability to bind topo I. These results strongly indicate that the association of topo I with these six residues in T antigen is essential for DNA replication. These residues are located on the back edges of the T-antigen double hexamer. We propose that topo I binds to one site on each hexamer to permit the initiation of SV40 DNA replication.     

A protein dissection study demonstrates that two specific hydrophobic clusters play a key role in stabilizing the core structure of the molten globule state of human alpha-lactalbumin

The molten globule state of alpha-lactalbumin (alpha LA) has served as a paradigm for understanding the role of these partially folded states in protein folding. We previously showed that a peptide construct consisting of the A and B helices (residues 1-38) cross-linked to the D- and C-terminal 3(10) helices (residues 101-120) of alpha LA is capable of folding to a stable molten globule-like state. Here, we report the study of three peptide constructs that are designed to investigate the contribution two short hydrophobic sequences located near the C-terminus of alpha LA make to the structure and stability of the alpha LA molten globule state. These regions of the protein have been shown to form stable non-native structures in isolation. The three peptide constructs contain residues 1-38 cross-linked to three separate C-terminal peptides via the native 28-111 disulfide bond. The C-terminal peptides consist of residues 101-114, 106-120, and 106-114. The results of CD, fluorescence, ANS binding, and urea denaturation experiments indicate that constructs that lack either of the hydrophobic sequences (residues 101-105 and 115-120) are significantly less structured. These results highlight the importance of long-range, mutually stabilizing interactions within the molten globule state of the protein. Proteins 2001;42:237-242.     

Effects of the stabilization of the molten globule state on the folding mechanism of alpha-lactalbumin: a study of a chimera of bovine and human alpha-lactalbumin

The N-terminal half of the alpha-domain (residues 1 to 34) is more important for the stability of the acid-induced molten globule state of alpha-lactalbumin than the C-terminal half (residues 86 to 123). The refolding and unfolding kinetics of a chimera, in which the amino acid sequence of residues 1 to 34 was from human alpha-lactalbumin and the remainder of the sequence from bovine alpha-lactalbumin, were studied by stopped-flow tryptophan fluorescence spectroscopy. The chimeric protein refolded and unfolded substantially faster than bovine alpha-lactalbumin. The stability of the molten globule state formed by the chimera was greater than that of bovine alpha-lactalbumin, and the hydrophobic surface area buried inside of the molecule in the molten globule state was increased by the substitution of residues 1 to 34. Peptide fragments corresponding to the A- and B-helix of the chimera showed higher helix propensity than those of the bovine protein, indicating the contribution of local interactions to the high stability of the molten globule state of the chimera. Moreover, the substitution of residues 1-34 decreased the free energy level of the transition state and increased hydrophobic surface area buried inside of the molecule in the transition state. Our results indicate that local interactions as well as hydrophobic interactions formed in the molten globule state are important in guiding the subsequent structural formation of alpha-lactalbumin.     

A functional 125-kDa core polypeptide of fission yeast DNA topoisomerase II.

We purified fission yeast DNA topoisomerase II (topo II) to apparent homogeneity. It consists of a single 165-kDa polypeptide in sodium dodecyl sulfate-polyacrylamide gel electrophoresis and, upon treatment with a bifunctional reagent, doubles its molecular weight. Limited proteolysis of intact topo II by papain produces a 125-kDa core, which lacks the N-terminal 75 and the C-terminal approximately 260 amino acids but still contains regions similar to those of bacterial or phage T4 topo II subunits. The core retains relaxing and unknotting activities. Further digestion inactivates the core, cleaving it at the middle of the GyrB-like domain and at the beginning of the GyrA-like domain. Therefore, papain appears to cleave spatially distinct subdomains of topo II. We made top2 mutant genes deleted of the C-terminal 286 or N-terminal 74 amino acids, which can substitute for the wild-type top2+ gene in mitosis and meiosis. However, a mutant containing deletions of both termini cannot rescue the top2 null mutant, despite the fact that the product is enzymatically active. Therefore, the top2 product of the doubly truncated gene may not fulfill all of the in vivo requirements for top2+ function.     

Localized nature of the transition-state structure in goat alpha-lactalbumin folding

To investigate whether the structure partially formed in the molten globule folding intermediate of goat alpha-lactalbumin is further organized in the transition state of folding, we constructed a number of mutant proteins and performed Phi-value analysis on them. For this purpose, we measured the equilibrium unfolding transitions and kinetic refolding and unfolding reactions of the mutants using equilibrium and stopped-flow kinetic circular dichroism techniques. The results show that the mutants with mutations located in the A-helix (V8A, L12A), the B-helix (V27A), the beta-domain (L52A, W60A), the C-helix (K93A, L96A), the C-D loop (Y103F), the D-helix (L105A, L110A), and the C-terminal 3(10)-helix (W118F), have low Phi-values, less than 0.2. On the other hand, D87N, which is located on the Ca(2+)-binding site, has a high Phi-value, 0.91, indicating that tight packing of the side-chain around Asp87 occurs in the transition state. One beta-domain mutant (I55V) and three C-helix mutants (I89V, V90A, and I95V) demonstrated intermediate Phi-values, between 0.4 and 0.7. These results indicate that the folding nucleus in the transition state of goat alpha-LA is not extensively distributed over the alpha-domain of the protein, but very localized in a region that contains the Ca(2+)-binding site and the interface between the C-helix and the beta-domain. This is apparently in contrast with the fact that the molten globule state of alpha-lactalbumin has a partially formed structure inside the alpha-domain. It is concluded that the specific docking of the alpha and beta-domains at a domain interface is necessary for this protein to organize its native structure from the molten globule intermediate.     

Crystal structure of NaeI-an evolutionary bridge between DNA endonuclease and topoisomerase

NAE:I is transformed from DNA endonuclease to DNA topoisomerase and recombinase by a single amino acid substitution. The crystal structure of NAE:I was solved at 2.3 A resolution and shows that NAE:I is a dimeric molecule with two domains per monomer. Each domain contains one potential DNA recognition motif corresponding to either endonuclease or topoisomerase activity. The N-terminal domain core folds like the other type II restriction endonucleases as well as lambda-exonuclease and the DNA repair enzymes MutH and Vsr, implying a common evolutionary origin and catalytic mechanism. The C-terminal domain contains a catabolite activator protein (CAP) motif present in many DNA-binding proteins, including the type IA and type II topoisomerases. Thus, the NAE:I structure implies that DNA processing enzymes evolved from a few common ancestors. NAE:I may be an evolutionary bridge between endonuclease and DNA processing enzymes.     

Structure of the nucleocapsid-binding domain from the mumps virus polymerase; an example of protein folding induced by crystallization

The human pathogen mumps virus, like all paramyxoviruses, encodes a polymerase responsible for virally directed RNA synthesis. The template for the polymerase is the nucleocapsid, a filamentous protein-RNA complex harboring the viral genome. Interaction of the polymerase and the nucleocapsid is mediated by a small domain tethered to the end of the phosphoprotein (P), one of the polymerase subunits. We report the X-ray crystal structure of this region of mumps virus P (the nucleocapsid-binding domain, or NBD, amino acids 343-391). The mumps P NBD forms a compact bundle of three α-helices within the crystal, a fold apparently conserved across the Paramyxovirinae. In solution, however, the domain exists in the molten globule state. This is demonstrated through application of differential scanning calorimetry, circular dichroism spectroscopy, NMR spectroscopy, and dynamic light scattering. While the mumps P NBD is compact and has persistent secondary structure, it lacks a well-defined tertiary structure under normal solution conditions. It can, however, be induced to fold by addition of a stabilizing methylamine cosolute. The domain provides a rare example of a molten globule that can be crystallized. The structure that is stabilized in the crystal represents the fully folded state of the domain, which must be transiently realized during binding to the viral nucleocapsid. While the intermolecular forces that govern the polymerase-nucleocapsid interaction appear to be different in measles, mumps, and Sendai viruses, for each of these viruses, polymerase translocation involves the coupled binding and folding of protein domains. In all cases, we suggest that this will result in a weak-affinity protein complex with a short lifetime, which allows the polymerase to take rapid steps forward.     

Role of C-terminal sequences in the folding of muscle creatine kinase

Proteinase K selectively nicks the native homodimeric muscle creatine kinase (MM-CK) into two 37.1 kDa N-terminal (K1) and two 5.8 kDa C-terminal (K2) fragments that remain firmly associated in a native-like, although inactive, heterotetrameric structure. This truncated protein has been named (K1K2)(2). To analyze the role of the C-terminal peptide in the protein structure acquisition, we studied in vitro refolding of the guanidinium chloride-denatured (K1K2)(2). Although they never reassociate with K2, in selected conditions the K1 fragments refold slowly to a dimeric state as shown by size exclusion chromatography data. This K1 dimer exhibits a fluorescence emission lambda max of 335 nm, a high degree of tyrosine exposure, strongly binds ANS but not MgADP, a CK substrate, and according to these structural characteristics, could be a dimeric molten globule species. We propose a folding model that takes into account the existence of a new transient intermediate state in the MM-CK refolding process. Besides two monomeric premolten and molten globule kinetic intermediates and the active final dimeric form, an inactive dimer, with partly compacted monomers, must ephemerally exist. Our results strongly suggest that the C-terminal end of the protein accelerates folding and plays a critical role for monomer final packing into a native-like conformation. The data also indicate that MM-CK catalytic efficiency is only acquired after dimerization.     

Iron-sulfur cluster biosynthesis: biochemical characterization of the conformational dynamics of Thermotoga maritima IscU and the relevance for cellular cluster assembly

Important for the understanding of the functional properties of the iron-sulfur scaffold IscU is knowledge of the structure and dynamics of this protein class. Structural characterization of Thermotoga maritima IscU by CD (Mansy, S. S., Wu, G., Surerus, K. K., and Cowan, J. A. (2002) J. Biol. Chem. 277, 21397-21404) and high resolution NMR (Bertini, I., Cowan, J. A., Del Bianco, C., Luchinat, C., and Mansy, S. S. (2003) J. Mol. Biol. 331, 907-924) yielded data indicating a high degree of secondary structure. However, the latter also revealed IscU to exist in a dynamic equilibrium between two or more distinct conformations, possibly existing in a molten globule state. Herein, we further characterize the molten globule characteristics of T. maritima IscU by near-ultraviolet circular dichroism, 1-anilino-8-naphthalenesulfonic acid binding, free energy of unfolding, hydrodynamic radius measurements, and limited tryptic digestion. The data suggest unusual dynamic behavior that is not fully consistent with typical protein states such as fully folded, fully unfolded, or molten globule. For instance, the existence of a stable tertiary fold is supported by near-UV CD spectra and hydrodynamic radius measurements, whereas other data are less clearly interpretable and may be viewed as consistent with either a molten globule or fully folded state. However, all of the data are consistent with our previous hypothesis of a protein sampling multiple discrete tertiary conformations in which these structural transitions occur on a "slow" time scale. To describe such proteins, we introduce the term multiple discrete conformers.