An Obligatory Intermediate in the Folding Pathway of Cytochromec552 from Hydrogenobacterthermophilus

Travaglini-Allocatelli, Carlo; Gianni, Stefano; Dubey, Vikash Kumar; Borgia, Alessandro; Matteo, Adele Di; Bonivento, Daniele; Cutruzzolà, Francesca; Bren, Kara L.; Brunori, Maurizio

doi:10.1074/jbc.m502628200

Cited by 68 publications

(168 citation statements)

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“…The folding of c 552 from Thermus thermophylus [29] and Hydrogenobacter thermophilus [36], the FF domain [30] and Im7 protein [28] In all cases, global analysis of observed kinetics led to the conclusion that the observed folding intermediate was an on-pathway species on the route between the denatured and native states.…”

Section: Accepted M Manuscriptmentioning

confidence: 99%

Identification and characterization of protein folding intermediates

Gianni

Ivarsson

Jemth

et al. 2007

Biophysical Chemistry

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In order to understand the mechanism by which a polypeptide chain folds into its functionally active native state it is necessary to characterize in detail all the species accumulated along the pathway.The elusive nature of protein folding intermediates poses their identification and characterization as an extremely difficult task in the protein folding field. In the case of small single domain proteins, the direct measurement of the thermodynamics and structural parameters of protein folding intermediates has provided new insights on the nature of the forces involved in the stabilization of nascent protein structures. Here we summarize some of the experimental approaches aimed at the detection and characterization of folding intermediates along with a discussion of some general structural features emerging from these studies.

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Section: Accepted M Manuscriptmentioning

confidence: 99%

Identification and characterization of protein folding intermediates

Gianni

Ivarsson

Jemth

et al. 2007

Biophysical Chemistry

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“…The proximal His16 in Ht cyt c 552 and Pa cyt c 551 donates a hydrogen bond to the backbone carbonyl of Pro25, with an oxygen-nitrogen distance of ~2.8 Å ( Figure 1A) (21,22). Hydrogen bonding involving the axial His in heme proteins has been shown to affect the ligand's electrondonating properties, which in turn tunes redox potential (13,14,44,46,47,57).…”

Section: Effect Of Mutations On Proximal Hismentioning

confidence: 99%

Heme Attachment Motif Mobility Tunes CytochromecRedox Potential

et al. 2007

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Hydrogen exchange (HX) rates and midpoint potentials (E m ) of variants of cytochromes c from Pseudomonas aeruginosa (Pa cyt c 551 ) and Hydrogenobacter thermophilus (Ht cyt c 552 ) have been characterized toward developing an understanding of the impact of properties of the Cys-X-X-CysHis pentapeptide c-heme attachment motif (CXXCH) on heme redox potential. Despite structural conservation of the CXXCH motif, Ht cyt c 552 exhibits low protection from HX for amide protons within this motif relative to Pa cyt c 551 . Site-directed mutants have been prepared to determine the structural basis for and functional implications of these variations in HX behavior. The double mutant Ht-M13V/K22M displays suppressed HX within the CXXCH motif as well as decreased E m (by 81 mV), whereas the corresponding double mutant of Pa cyt c 551 (V13M/M22K) exhibits enhanced HX within the CXXCH pentapeptide and a modest increase in E m (by 30 mV). The changes in E m correlate with changes in axial His chemical shifts in the ferric proteins reflecting extent of histidinate character. Thus the mobility of the CXXCH pentapeptide is found to impact the His-Fe(III) interaction and therefore heme redox potential.Electron transfer reactions involving iron-protoporphyrin IX (heme) are central to fundamental biological processes such as respiration, redox catalysis, sensing, and signaling (1-5). A key parameter determining energetics and kinetics of electron transfer is the redox potential (1), thus, much emphasis has been placed on understanding the role of protein structure in tuning heme redox potential. Two fundamental features known to have a substantial influence on heme redox potentials are the nature of the ligands coordinated to the metal and the burial of the heme in the hydrophobic protein core. Nature alters the electron donating properties of the coordinating ligands through choice of ligands (6), modulating metal-ligand bond strength (6-12), varying coordination geometry (5), and hydrogen bonding to ligands (13)(14)(15). The encapsulation of the heme within a protein's interior also is significant for determining potential, as the hydrophobic environment favors the ferrous state over the ferric (7,8,10,16,17). Although there have been many studies of the effects of static polypeptide structure on heme-ligand interactions and on heme burial, the role of protein mobility has received less attention. Protein motions may indeed be important as they could influence metal-ligand interactions (15,18,19) and solvent exposure. † This work supported by National Institutes of Health Grant GM63170 (K.L.B.), a Fellowship from the Alfred P. Sloan Foundation (K.L.B.), and National Science Foundation Grant MCB-0546323 (S.J.E.).*To whom correspondence should be addressed: Department of Chemistry, University of Rochester, Rochester, NY 14627-0216. Telephone: (585) Here, we investigate the effects of structural fluctuations of the c-heme motif of cytochrome c (cyt c 1 ) on redox potential. The c-type heme is characterized by its covalen...

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“…24 Unlike its homologues, Ht-cyt c 552 has a glutamine at position 64 (Gln64), which is not oriented toward the axial Met61, but is instead localized over a methyl group (heme 3-CH 3 using the Fischer numbering system) at the heme edge, near the protein surface ( Figure 1b). [15][16][17] Zhong and co-workers have shown that the absence of a hydrogen bond to the axial Met affects the dynamics, and presumably the functionality, of the active site by imparting a fluxional character to Met61 and influencing heme redox potential. 17,[22][23][24] Multidimensional spectroscopic techniques have provided a wealth of information in the field of biology.…”

Section: Introductionmentioning

confidence: 99%

“…[1][2][3] Due to their wide availability, robust structure, and ease of handling, these proteins have served as model systems to study the interplay of protein structure, dynamics, and function. [4][5][6][7][8][9][10][11][12][13] Cytochrome c 552 from Hydrogenobacter thermophilus (Ht-cyt c 552 ) [14][15][16][17] was recently shown to be a structurally unique example within the cyt c 8 family of class I 18 cyt c's. Proteins in the cyt c 8 structural family, for example, Pseudomonas cyt c 551 's, [19][20][21] typically have an asparagine residue at position 64 (Asn64) that is situated to donate a hydrogen bond to a methionine at position 61 (Met61), which occupies the sixth coordination site to the heme ( Figure 1a; sequence numbering is based on the Pseudomonas aeruginosa cyt c 551 sequence).…”

Section: Introductionmentioning

confidence: 99%

“…The first mutant studied (Ht-M61A) was characterized by only the single M61A mutation and retained an axial Gln64, which was expected to be oriented out of the heme pocket (Figure 1b) as it is in the native protein. 16,17,22 The second mutant (Ht-M61A/Q64N) was further modified to have Gln64 replaced by an Asn in an effort to generate an active site structure similar to that seen in most cyt c 8 's, [19][20][21][22][23] with Asn64 positioned to interact with the heme-bound CO (Figure 1a).…”

Section: Introductionmentioning

confidence: 99%

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Cytochrome c₅₅₂Mutants: Structure and Dynamics at the Active Site Probed by Multidimensional NMR and Vibration Echo Spectroscopy

et al. 2006

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Spectrally resolved infrared stimulated vibrational echo experiments are used to measure the vibrational dephasing of a CO ligand bound to the heme cofactor in two mutated forms of the cytochrome c 552 from Hydrogenobacter thermophilus. The first mutant (Ht-M61A) is characterized by a single mutation of Met61 to an Ala (Ht-M61A), while the second variant is doubly modified to have Gln64 replaced by an Asn in addition to the M61A mutation (Ht-M61A/Q64N). Multidimensional NMR experiments determined that the geometry of residue 64 in the two mutants is consistent with a non-hydrogen-bonding and hydrogen-bonding interaction with the CO ligand for Ht-M61A and Ht-M61A/Q64N, respectively. The vibrational echo experiments reveal that the shortest time scale vibrational dephasing of the CO is faster in the Ht-M61A/ Q64N mutant than that in Ht-M61A. Longer time scale dynamics, measured as spectral diffusion, are unchanged by the Q64N modification. Frequency-frequency correlation functions (FFCFs) of the CO are extracted from the vibrational echo data to confirm that the dynamical difference induced by the Q64N mutation is primarily an increase in the fast (hundreds of femtoseconds) frequency fluctuations, while the slower (tens of picoseconds) dynamics are nearly unaffected. We conclude that the faster dynamics in Ht-M61A/Q64N are due to the location of Asn64, which is a hydrogen bond donor, above the heme-bound CO. A similar difference in CO ligand dynamics has been observed in the comparison of the CO derivative of myoglobin (MbCO) and its H64V variant, which is caused by the difference in axial residue interactions with the CO ligand. The results suggest a general trend for rapid ligand vibrational dynamics in the presence of a hydrogen bond donor.

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An Obligatory Intermediate in the Folding Pathway of Cytochromec552 from Hydrogenobacterthermophilus

Cited by 68 publications

References 40 publications

Identification and characterization of protein folding intermediates

Identification and characterization of protein folding intermediates

Heme Attachment Motif Mobility Tunes CytochromecRedox Potential

Cytochrome c₅₅₂Mutants: Structure and Dynamics at the Active Site Probed by Multidimensional NMR and Vibration Echo Spectroscopy

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An Obligatory Intermediate in the Folding Pathway of Cytochromec552 from Hydrogenobacterthermophilus

Cited by 68 publications

References 40 publications

Identification and characterization of protein folding intermediates

Identification and characterization of protein folding intermediates

Heme Attachment Motif Mobility Tunes CytochromecRedox Potential

Cytochrome c552Mutants: Structure and Dynamics at the Active Site Probed by Multidimensional NMR and Vibration Echo Spectroscopy

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Product

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Cytochrome c₅₅₂Mutants: Structure and Dynamics at the Active Site Probed by Multidimensional NMR and Vibration Echo Spectroscopy