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Query: UNIPROT:P06889 (Mol)
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We present a method for determining the structure of the transition state ensemble (TSE) of a protein by using phi values derived from protein engineering experiments as restraints in molecular dynamics simulations employing a realistic all-atom molecular mechanics energy function. The method uses a biasing potential to select an ensemble of structures having phi values in agreement with the experimental data set. An application to acylphosphatase (AcP), a protein for which phi values have been measured for 24 out of 98 residues, illustrates the approach. The properties of the TSE determined in this way are compared with those of a coarse-grained model obtained using a Monte Carlo (MC) sampling method based on a C(alpha) representation of the structure. The two TSEs determined at different structural resolution are consistent and complementary. While the C(alpha) model allows better sampling of the conformation space occupied by the transition state, the all-atom model offers a more detailed description of the structural and energetic properties of the conformations included in the TSE. The combination of low-resolution C(alpha) results with all-atom molecular dynamics simulations provides a powerful and general method for determining the nature of TSEs from protein engineering data.
J Mol Biol 2002 Nov 15
PMID:Determination of a transition state at atomic resolution from protein engineering data. 1242 65

The N-terminal domain of HypF from Escherichia coli (HypF-N) is a 91 residue protein module sharing the same folding topology and a significant sequence identity with two extensively studied human proteins, muscle and common-type acylphosphatases (mAcP and ctAcP). With the aim of learning fundamental aspects of protein folding from the close comparison of so similar proteins, the folding process of HypF-N has been studied using stopped-flow fluorescence. While mAcP and ctAcP fold in a two-state fashion, HypF-N was found to collapse into a partially folded intermediate before reaching the fully folded conformation. Formation of a burst-phase intermediate is indicated by the roll over in the Chevron plot at low urea concentrations and by the large jump of intrinsic and 8-anilino-1-naphtalenesulphonic acid-derived fluorescence immediately after removal of denaturant. Furthermore, HypF-N was found to fold rapidly with a rate constant that is approximately two and three orders of magnitudes faster than ctAcP and mAcP, respectively. Differences between the bacterial protein and the two human counterparts were also found as to the involvement of proline isomerism in their respective folding processes. The results clearly indicate that features that are often thought to be relevant in protein folding are not highly conserved in the evolution of the acylphosphatase superfamily. The large difference in folding rate between mAcP and HypF-N cannot be entirely accounted for by the difference in relative contact order or related topological metrics. The analysis shows that the higher folding rate of HypF-N is in part due to the relatively high hydrophobic content of this protein. This conclusion, which is also supported by the highly significant correlation found between folding rate and hydrophobic content within a group of proteins displaying the topology of HypF-N and AcPs, suggests that the average hydrophobicity of a protein sequence is an important determinant of its folding rate.
J Mol Biol 2003 Jul 11
PMID:Comparison of the folding processes of distantly related proteins. Importance of hydrophobic content in folding. 1284 73

Formation of misfolded aggregates is an essential part of what proteins can do. The process of protein aggregation is central to many human diseases and any aggregating event needs to be prevented within a cell and in protein design. In order to aggregate, a protein needs to unfold its native state, at least partially. The conformational state that is prone to aggregate is difficult to study, due to its aggregating potential and heterogeneous nature. Here, we use a systematic approach of limited proteolysis, in combination with electrospray ionisation mass spectrometry, to investigate the regions that are most flexible and solvent-exposed within the native, ligand-bound and amyloidogenic states of muscle acylphosphatase (AcP), a protein previously shown to form amyloid fibrils in the presence of trifluoroethanol. Seven proteases with different degrees of specificity have been used for this purpose. Following exposure to the aggregating conditions, a number of sites along the sequence of AcP become susceptible to proteolytic digestion. The pattern of proteolytic cleavages obtained under these conditions is considerably different from that of the native and ligand-bound conformations and includes a portion within the N-terminal tail of the protein (residues 6-7), the region of the sequence 18-23 and the position 94 near the C terminus. There is a significant overlap between the regions of the sequence found to be solvent-exposed from the present study and those previously identified to be critical in the rate-determining steps of aggregation from protein engineering approaches. This indicates that a considerable degree of solvent exposure is a feature of the portions of a protein that initiate the process of aggregation.
J Mol Biol 2004 Feb 06
PMID:The regions of the sequence most exposed to the solvent within the amyloidogenic state of a protein initiate the aggregation process. 1474 Dec 20

The native state of common-type acylphosphatase (AcP) elicits two alpha-helices spanning residues 22-32 and 55-67 in the protein sequence. A peptide corresponding to the second alpha-helix (helix-2) of the protein was used to select phage antibodies consisting of a single chain fragment variable. The selection was performed in the presence of trifluoroethanol, a cosolvent known to induce the formation of helical structure in peptides and proteins. Phage scFv antibodies capable of binding the peptide specifically in a trifluoroethanol-induced alpha-helical conformation were isolated by affinity selection (biopanning). Some of these scFvs were also able to bind the native protein but not the peptide in a non-helical unstructured state. This indicates that the structural determinant recognized by the selected antibodies is the alpha-helical conformation of this specific region, rather than simply its amino acid sequence. This study shows that phage display libraries can be used to raise antibodies one can use as reagents able to target regions of a protein with a specific native-like secondary structure.
J Mol Recognit
PMID:Selection of antibody fragments specific for an alpha-helix region of acylphosphatase. 1487 38

The dimensions and secondary structure content of two proteins which fold in a two-state manner are measured within milliseconds of denaturant dilution using synchrotron-based, stopped-flow small-angle X-ray scattering and far-UV circular dichroism spectroscopy. Even upon a jump to strongly native conditions, neither ubiquitin nor common-type acylphosphatase contract prior to the major folding event. Circular dichroism and fluorescence indicate that negligible amounts of secondary and tertiary structures form in the burst phase. Thus, for these two denatured states, collapse and secondary structure formation are not energetically downhill processes even under aqueous, low-denaturant conditions. In addition, water appears to be as good a solvent as that with high concentrations of denaturant, when considering the over-all dimensions of the denatured state. However, the removal of denaturant does subtly alter the distribution of backbone dihedral phi,psi angles, most likely resulting in a shift from the polyproline II region to the helical region of the Ramachandran map. We consider the thermodynamic origins of these behaviors along with implications for folding mechanisms and computer simulations thereof.
J Mol Biol 2004 Apr 23
PMID:Early collapse is not an obligate step in protein folding. 1506 38

Protein aggregation is a notable feature of various human disorders, including Parkinson's disease, Alzheimer's disease and many others systemic amyloidoses. An increasing number of observations in vitro suggest that transition metals are able to accelerate the aggregation process of several proteins found in pathological deposits, e.g. alpha-synuclein, amyloid beta (Abeta) peptide, beta(2)-microglobulin and fragments of the prion protein. Here we report the effects of metal ions on the aggregation rate of human muscle acylphosphatase, a suitable model system for aggregation studies in vitro. Among the different species tested, Cu(2+) produced the most remarkable acceleration of aggregation, the rate of the process being 2.5-fold higher in the presence of 0.1 mM metal concentration. Data reported in the literature suggest the possible role played by histidine residues or negatively charged clusters present in the amino acid sequence in Cu(2+)-mediated aggregation of pathological proteins. Acylphosphatase does not contain histidine residues and is a basic protein. A number of histidine-containing mutational variants of acylphosphatase were produced to evaluate the importance of histidine in the aggregation process. The Cu(2+)-induced acceleration of aggregation was not significantly altered in the protein variants. The different aggregation rates shown by each variant were entirely explained by the changes of hydrophobicity or propensity to form a beta structure introduced by the point mutation. The effect of Cu(2+) on acylphosphatase aggregation cannot therefore be attributed to the specific factors usually invoked in the aggregation of pathological proteins. The effect, rather, seems to be a general related to the chemistry of the polypeptide backbone and could represent an additional deleterious factor resulting from the alteration of the homeostasis of metal ions in cells.
Cell Mol Life Sci 2004 Apr
PMID:Investigation of the effects of copper ions on protein aggregation using a model system. 1509 18

An acylphosphatase (AcPase) overexpression study was carried out on SH-SY5Y neuroblastoma cells, using a green fluorescent fusion protein (AcP-GFP), with GFP acting as a reporter protein. The cellular proliferation rate was significantly reduced by overexpression of AcPase by a factor of ten. In contrast, clones transfected with two inactive AcPase mutants showed a growth rate comparable to control cells. This suggests that AcPase catalyzes the proliferative down-regulation. AcPase-overexpressing clones showed a physiological mortality rate as assessed by an MTT reduction test and by evaluation of necrotic markers. DNA fragmentation analysis and assays of caspase-3 and poly (ADP-ribose) polymerase (PARP)-active fragments showed no evidence of any apoptotic pattern. AcPase overexpression led to a marked increase in PARP activity as well as Bcl-2 content; these are commonly up-regulated during differentiative processes in neuronal cells. In fact, the typical differentiation marker, growth-associated-protein 43, was significantly up-regulated. Microscopic observations also showed a clear increase in the differentiative phenotype in AcPase-overexpressing cells. Our results clearly show that AcPase plays a primary causative role in neuronal differentiation.
Cell Mol Life Sci 2004 Jul
PMID:Acylphosphatase overexpression triggers SH-SY5Y differentiation towards neuronal phenotype. 1524 53

Observations that prefibrillar aggregates from different amyloidogenic proteins can be solubilised under some conditions have raised questions as to the generality of this phenomenon and the nature of the factors that influence it. By studying aggregates formed from human muscle acylphosphatase (AcP) under mild denaturing conditions, and by using a battery of techniques, we demonstrate that disaggregation is possible under conditions close to physiological where the protein is stable in its native state. In the presence of 25% (v/v) trifluoroethanol (TFE) AcP undergoes partial unfolding and globular aggregates (60-200 nm in diameter) that can assemble further into clusters (400-800 nm in diameter) develop progressively. Yet larger superstructures (>5 microm) are formed when the concentration of the globular aggregates exceeds a critical concentration. After diluting the sample to give a solution containing 5% TFE, the fraction of partially unfolded monomeric protein refolds very rapidly, with a rate constant of approximately 1s(-1). The 60-200 nm globular aggregates disaggregate with an apparent rate constant of approximately 2.5 x 10(-3)s(-1) while the 400-800 nm clusters disassembly more slowly with a rate constant of approximately 3.1 x 10(-4)s(-1). The larger (>5 microm) superstructures are not disrupted under the conditions used here. These results suggest that amyloid formation occurs in discrete steps whose reversibility is increasingly difficult, and dependent on the size of the aggregates, and that disaggregation experiments can provide a powerful method of detecting different types of species within the complex process of aggregation. In addition, our work suggests that destabilization of amyloid aggregates resulting in the conversion of misfolded proteins back to their native states could be an important factor in both the onset and treatment of diseases associated with protein aggregation.
J Mol Biol 2005 Feb 18
PMID:Reversal of protein aggregation provides evidence for multiple aggregated States. 1567 Jun 8

The aggregation of the alpha/beta protein acylphosphatase from Sulfolobus solfataricus has been studied under conditions in which the protein maintains a native-like, although destabilised, conformation and that therefore bear resemblance to a physiological medium. Static and dynamic light-scattering measurements indicate that under these conditions the protein aggregates rapidly, within two minutes. The initial aggregates are enzymatically active and have a secondary structure that is not yet characterized by the high content of cross-beta structure typical of amyloid, as inferred from Fourier transform infra-red and circular dichroism measurements. These species then convert slowly into enzymatically inactive aggregates that bind thioflavin T and Congo red, characteristic of amyloid structures, and contain extensive beta-sheet structure. Transmission electron microscopy reveals the presence in the latter aggregates of spherical species and thin, elongated protofibrils, both with diameters of 3-5 nm. Kinetic tests reveal that this process occurs without the need for dissolution and re-nucleation of the aggregates. Formation of thioflavin T-binding and beta-structured aggregates is substantially more rapid than unfolding of the native state, indicating that the initial aggregation process promotes formation of amyloid structures. Taken together, these findings suggest a mechanism of amyloid formation that may have physiological relevance and in which the amyloid structures result from reorganisation of the molecular interactions within the initially formed non-amyloid aggregates.
J Mol Biol 2005 Aug 26
PMID:Evidence for a mechanism of amyloid formation involving molecular reorganisation within native-like precursor aggregates. 1602 42

The acylphosphatase from Escherichia coli (EcoAcP) is the first AcP so far studied with a disulfide bond. A mutational variant of the enzyme lacking the disulfide bond has been produced by substituting the two cysteine residues with alanine (EcoAcP mutational variant C5A/C49A, mutEcoAcP). The native states of the two protein variants are similar, as shown by far-UV and near-UV circular dichroism and dynamic light-scattering measurements. From unfolding experiments at equilibrium using intrinsic fluorescence and far-UV circular dichroism as probes, EcoAcP shows an increased conformational stability as compared with mutEcoAcP. The wild-type protein folds according to a two-state model with a very fast rate constant (k(F)(H2O)=72,600 s(-1)), while mutEcoAcP folds ca 1500-fold slower, via the accumulation of a partially folded species. The correlation between the hydrophobicity of the polypeptide chain and the folding rate, found previously in the AcP-like structural family, is maintained only when considering the mutant but not the wild-type protein, which folds much faster than expected from this correlation. Similarly, the correlation between the relative contact order and the folding rate holds only for mutEcoAcP. The correlation also holds for EcoAcP, provided the relative contact order value is recalculated by considering the disulfide bridge as an alternate path for the backbone to determine the shortest sequence separation between contacting residues. These results indicate that the presence of a disulfide bond in a protein is an important determinant of the folding rate and allows its contribution to be determined in quantitative terms.
J Mol Biol 2008 Jun 20
PMID:The folding process of acylphosphatase from Escherichia coli is remarkably accelerated by the presence of a disulfide bond. 1849 59


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