Structural Mapping of an Aggregation Nucleation Site in a Molten Globule Intermediate
Protein aggregation plays an important role in biotechnology and also causes numerous diseases. Human carbonic anhydrase II is a suitable model protein for studying the mechanism of aggregation. We found that a molten globule state of the enzyme formed aggregates. The intermolecular interactions involved in aggregate formation were localized in a direct way by measuring excimer formation between each of 20 site-specific pyrene-labeled cysteine mutants. The contact area of the aggregated protein was very specific, and all sites included in the intermolecular interactions were located in the large -sheet of the protein, within a limited region between the central -strands 4 and 7. This substructure is very hydrophobic, which underlines the importance of hydrophobic interactions between specific -sheet containing regions in aggregate formation.
The stability versus unfolding to the molten globule intermediate of bovine carbonic anhydrase II (BCA II) in guanidine hydrochloride (GuHCl) was found to depend on the metal ion cofactor [Zn(II) or Co(II)], and the apoenzyme was observed to be least stable. Therefore, it was possible to find a denaturant concentration (1.2 M GuHCl) at which refolding from the molten globule to the native state could be initiated merely by adding the metal ion to the apo molten globule. Thus, refolding could be performed without changing the concentration of the denaturant. The molten globule intermediate of BCA II could still bind the metal cofactor. Cofactor-effected refolding from the molten globule to the native state can be summarized as follows: (1) initially, the metal ion binds to the molten globule; (2) compaction of the metal-binding site region is then induced by the metal ion binding; (3) a functioning active center is formed; and (4) finally, the native tertiary structure is generated in the outer parts of the protein.
The contribution to the circular dichroism (CD) spectrum made by each of the four Trp residues in the extracellular domain of human tissue factor, sTF (s designates soluble), was determined from difference CD spectra. The individual Trp CD spectra showed that all four residues contributed to the CD spectrum in almost the entire wavelength region investigated (180±305 nm). The sum of the individual spectra of each Trp residue in the near-UV region was qualitatively identical to the wild-type spectrum, clearly demonstrating that the Trp residues are the major contributors to the spectrum in this wavelength region. Trp CD bands interfere with the peptide bands in the far-UV region, leading to uncertainty in the predictions of the amounts of various types of secondary structure. Accordingly, the best prediction of secondary sTF structure content was achieved using a hypothetical Trp-free CD spectrum obtained after subtraction of all individual Trp spectra from the wild-type spectrum. The mutated Trp residues were also exploited as intrinsic probes to monitor the formation of local native-like tertiary structure by kinetic near-UV CD measurements. The global folding reaction was followed in parallel with a novel functional assay that registered the recovery of cofactor activity, i.e. stimulation of the amidolytic activity of Factor VIIa. From these measurements, it was found that sTF appears to regain FVIIa cofactor activity before the final side-chain packing of the Trp residues. The combined kinetic refolding results suggest that the compact asymmetric environments of the individual Trp residues in sTF are formed simultaneously, leading to the conclusion that the native tertiary structure of the whole protein is formed in a cooperative manner.
Subunit interaction in extracellular superoxide dismutase: Effects of mutations in the N‐terminal domain
Human extracellular superoxide dismutase (hEC-SOD) is a secreted tetrameric protein involved in protection against oxygen free radicals. Because EC-SOD is too large a protein for structural determination by multidimensional NMR, and attempts to crystallize the protein for X-ray structural determination have failed, the three-dimensional structure of hEC-SOD is unknown. This means that alternative strategies for structural studies are needed. The N-terminal domain of EC-SOD has already been studied using the fusion protein FusNN, comprised of the 49 N-terminal amino acids from hEC-SOD fused to human carbonic anhydrase (HCAII). The N-terminal domain in this fusion protein forms a welldefined three-dimensional structure, which probably contains a-helical elements and is responsible for the tetramerization of the protein.In this work, we have extended the studies, using site-directed mutagenesis in combination with size-exclusion chromatography, CD, and fluorescence spectroscopy, to investigate the nature of the tetrameric interaction. Our results show that the hydrophobic side of a predicted amphiphatic a-helix (formed by residues 14-32) in the N-terminal domain is essential for the subunit interaction.Keywords: carbonic anhydrase 11; extracellular superoxide dismutase; heterologous expression; site-directed mutagenesis; subunit interaction; tetramer contact area Mammalian cells produce two different types of CuZnSODs, an intracellular and an extracellular form, which are almost equally efficient as catalysts and have nearly identical kinetic parameters (Tibell et al., 1987). The two enzyme forms exhibit significant sequence similarity, but they differ in several respects. The intracellular human CuZnSOD contains 153 amino acid residues per subunit, has a subunit molecular mass of 16 kDa, and is a dimer. The mature human EC-SOD subunit, on the other hand, contains 222 amino acid residues (plus an 18-residue-long signal peptide) and a N-linked oligosaccharide, resulting in a calculated molecular mass of 26.7 kDa (24.2 kDa from the polypeptide and 2.5 kDa from the oligosaccharide) (Edlund et al., 1992). The hEC-SOD protein forms a tetramer, is secreted, and binds to proteoglycans, which are found on the surface of almost every cell in the human body. The central part of the hEC-SOD sequence is homologous with the sequence of the intracellular CuZnSODs, including those amino acid residues that are metal ligands. The 48 N-terminal Reprint requests to: LenaA.E. Tibell, Department of Biochemistry, Umei University, S-901 87 Umei, Sweden; e-mail: lenat@chem.umu.se.Abbreviarions: CuZnSOD, Cu-and Zn-containing intracellular superoxide dismutase; EC-SOD, extracellular superoxide dismutase; GuHC1, guanidine hydrochloride; HCAII, human carbonic anhydrase 11: MRW, mean residue weight: SOD, superoxide dismutase. amino acid residues of hEC-SOD, and 30 of the C-terminal, have no counterparts in intracellular CuZnSODs, and no significant homology with any other sequenced protein.The three-dimensional structure of the intrace...
In the present study, near-UV CD kinetic measurements on mutants, in which one Trp residue had been replaced, were performed to probe the development of asymmetric environments around specific Trp residues during the refolding of human carbonic anhydrase II (HCAII). In addition, the formation of the active site was probed by the binding of a fluorescent sulfonamide inhibitor. The development of the individual Trp CD spectra during refolding was obtained by subtracting the CD spectrum of the mutant lacking one Trp from that of HCAII at different time points. The same method was used for the particular Trp residues to obtain the kinetic CD traces monitored at a specific wavelength (270 nm). Trp residues 16, 97, and 245 were analyzed. Trp16 probes the N-terminal domain (amino acid residues 1-25), and this part is forming its tertiary structure slower than the major domain (amino acid residues 26-260) of the protein molecule, which contains the active site and a dominating beta-sheet. An essentially native structure of the major domain seems to act as a template for the correct folding of the N terminus. Trp97 is located in a hydrophobic cluster comprising beta-strands 3-5 in the protein core. Previously, we have shown that this region is remarkably stable and compact, and stopped-flow fluorescence data indicate that Trp97 is buried in an apolar compact cluster within a few milliseconds [Svensson, M., Jonasson, P., Freskgård, P.-O., Jonsson, B.-H., Lindgren, M., Martensson, L.-G., Gentile, M., Bóren, K., & Carlsson, U. (1995) Biochemistry 34, 8606-8620; Jonasson, P., Aronsson, G., Carlsson, U., & Jonsson, B.-H. (1997) Biochemistry 36 (in press)]. Here it is shown that the development of the native tertiary structure at Trp97 occurs in the minute time domain. Trp245 is located in a long loop between the N-terminal domain and the core structure. Although this Trp has attained native-like fluorescence properties within the dead time of the CD experiment, it assumes a native-like asymmetric environment even slower than Trp97. Thus, the investigated Trp residues develop their native CD bands at different rates, showing that formation of native-like tertiary structure is occurring with varying rates in different regions of the protein.
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