Probing the topography of the photosystem II oxygen evolving complex: PsbO is required for efficient calcium protection of the manganese cluster against dark-inhibition by an artificial reductant.

The photosystem II (PSII) manganese-stabilizing protein (PsbO) is known to be the essential PSII extrinsic subunit for stabilization and retention of the Mn and Cl(-) cofactors in the oxygen evolving complex (OEC) of PSII, but its function relative to Ca(2+) is less clear. To obtain a better insight into the relationship, if any, between PsbO and Ca(2+) binding in the OEC, samples with altered PsbO-PSII binding properties were probed for their potential to promote the ability of Ca(2+) to protect the Mn cluster against dark-inhibition by an exogenous artificial reductant, N,N-dimethylhydroxylamine. In the absence of the PsbP and PsbQ extrinsic subunits, Ca(2+) and its surrogates (Sr(2+), Cd(2+)) shield Mn atoms from inhibitory reduction (Kuntzleman et al., Phys Chem Chem Phys 6:4897, 2004). The results presented here show that PsbO exhibits a positive effect on Ca(2+) binding in the OEC by facilitating the ability of the metal to prevent inhibition of activity by the reductant. The data presented here suggest that PsbO may have a role in the formation of the OEC-associated Ca(2+) binding site by promoting the equilibrium between bound and free Ca(2+) that favors the bound metal.

Carboxylate and aromatic active-site residues are determinants of high-affinity binding of ω-aminoaldehydes to plant aminoaldehyde dehydrogenases.

The crystal structures of both isoforms of the aminoaldehyde dehydrogenase from pea (PsAMADH) have been solved recently [Tylichováet al. (2010) J Mol Biol396, 870-882]. The characterization of the PsAMADH2 proteins, altered here by site-directed mutagenesis, suggests that the D110 and D113 residues at the entrance to the substrate channel are required for high-affinity binding of ω-aminoaldehydes to PsAMADH2 and for enzyme activity, whereas N162, near catalytic C294, contributes mainly to the enzyme's catalytic rate. Inside the substrate cavity, W170 and Y163, and, to a certain extent, L166 and M167 probably preserve the optimal overall geometry of the substrate channel that allows for the appropriate orientation of the substrate. Unconserved W288 appears to affect the affinity of the enzyme for the substrate amino group through control of the substrate channel diameter without affecting the reaction rate. Therefore, W288 may be a key determinant of the differences in substrate specificity found among plant AMADH isoforms when they interact with naturally occurring substrates such as 3-aminopropionaldehyde and 4-aminobutyraldehyde.

Binding stoichiometry and affinity of the manganese-stabilizing protein affects redox reactions on the oxidizing side of photosystem II.

It has been reported previously that the two subunits of PsbO, the photosystem II (PSII) manganese stabilizing protein, have unique functions in relation to the Mn, Ca(2+), and Cl(-) cofactors in eukaryotic PSII [Popelkova; (2008) Biochemistry 47, 12593]. The experiments reported here utilize a set of N-terminal truncation mutants of PsbO, which exhibit altered subunit binding to PSII, to further characterize its role in establishing efficient O(2) evolution activity. The effects of PsbO binding stoichiometry, affinity, and specificity on Q(A)(-) reoxidation kinetics after a single turnover flash, S-state transitions, and O(2) release time have been examined. The data presented here show that weak rebinding of a single PsbO subunit to PsbO-depleted PSII repairs many of the defects in PSII resulting from the removal of the protein, but many of these are not sustainable, as indicated by low steady-state activities of the reconstituted samples [Popelkova; (2003) Biochemistry 42 , 6193]. High affinity binding of PsbO to PSII is required to produce more stable and efficient cycling of the water oxidation reaction. Reconstitution of the second PsbO subunit is needed to further optimize redox reactions on the PSII oxidizing side. Native PsbO and recombinant wild-type PsbO from spinach facilitate PSII redox reactions in a very similar manner, and nonspecific binding of PsbO to PSII has no significance in these reactions.

PsbO, the manganese-stabilizing protein: analysis of the structure-function relations that provide insights into its role in photosystem II.

The minireview presented here summarizes current information on the structure and function of PsbO, the photosystem II (PSII) manganese-stabilizing protein, with an emphasis on the protein's assembly into PSII, and its function in facilitating rapid turnovers of the oxygen evolving reaction. Two putative mechanisms for functional assembly of PsbO, which behaves as an intrinsically disordered polypeptide in solution, into PSII are proposed. Finally, a model is presented for the role of PsbO in relation to the function of the Mn, Ca(2+), and Cl(-) cofactors that are required for water oxidation, as well as for the action of hydroxide and small Mn reductants that inhibit the function of the active site of the oxygen-evolving complex.

The double mutation ΔL6MW241F in PsbO, the photosystem II manganese stabilizing protein, yields insights into the evolution of its structure and function.

The W241F mutation in spinach manganese-stabilizing protein (PsbO) decreases binding to photosystem II (PSII); its thermostability is increased and reconstituted activity is lower [Wyman et al. (2008) Biochemistry 47, 6490-6498]. The results reported here show that W241F cannot adopt a normal solution structure and fails to reconstitute efficient Cl(-) retention by PSII. An N-terminal truncation of W241F, producing the ΔL6MW241F double mutant that resembles some features of cyanobacterial PsbO, significantly repairs the defects in W241F. Our data suggest that the C-terminal F→W mutation likely evolved in higher plants and green algae in order to preserve proper PsbO folding and PSII binding and assembly, which promotes efficient Cl(-) retention in the oxygen-evolving complex.

Function of PsbO, the photosystem II manganese-stabilizing protein: probing the role of aspartic acid 157.

The D157N, D157E, and D157K mutations in the psbO gene encoding the photosystem II (PSII) manganese-stabilizing protein from spinach, exhibit near-wild-type PSII binding but are significantly impaired in O(2) evolution activity and Cl(-) retention by PSII [Popelkova et al. (2009) Biochemistry 48, 11920-11928]. To better characterize the role of PsbO-Asp157 in eukaryotic PSII, the effect of mutations in Asp157 on heat-induced changes in PsbO solution structure, O(2) release kinetics, and PSII redox reactions both within and outside the oxygen-evolving complex (OEC) have been examined. The data presented here show that Asn, Glu, or Lys mutations in PsbO-Asp157 modify PsbO thermostability in solution, which is consistent with the previously reported perturbation of the functional assembly of PsbO-Asp157 mutants into PSII that caused inefficient Cl(-) retention by PSII. Fluorescence decay signals from PSII reconstituted with Asp157 mutants indicate that that the Q(A)(-) to Q(B) transition on the PSII reducing side is unaffected, but complex alterations are detected on the PSII oxidizing side that affect the recombination of Q(A)(-) with the O(2)-evolving complex. In addition, oxygen yield on the first flash is increased, which indicates an impaired ability of mutant-reconstituted PSII samples to decay back to the S(1) state in the dark.

Phenyl- and benzylurea cytokinins as competitive inhibitors of cytokinin oxidase/dehydrogenase: a structural study.

Cytokinin oxidase/dehydrogenase (CKO) is a flavoenzyme, which irreversibly degrades the plant hormones cytokinins and thereby participates in their homeostasis. Several synthetic cytokinins including urea derivatives are known CKO inhibitors but structural data explaining enzyme-inhibitor interactions are lacking. Thus, an inhibitory study with numerous urea derivatives was undertaken using the maize enzyme (ZmCKO1) and the crystal structure of ZmCKO1 in a complex with N-(2-chloro-pyridin-4-yl)-N'-phenylurea (CPPU) was solved. CPPU binds in a planar conformation and competes for the same binding site with natural substrates like N(6)-(2-isopentenyl)adenine (iP) and zeatin (Z). Nitrogens at the urea backbone are hydrogen bonded to the putative active site base Asp169. Subsequently, site-directed mutagenesis of L492 and E381 residues involved in the inhibitor binding was performed. The crystal structures of L492A mutant in a complex with CPPU and N-(2-chloro-pyridin-4-yl)-N'-benzylurea (CPBU) were solved and confirm the importance of a stacking interaction between the 2-chloro-4-pyridinyl ring of the inhibitor and the isoalloxazine ring of the FAD cofactor. Amino derivatives like N-(2-amino-pyridin-4-yl)-N'-phenylurea (APPU) inhibited ZmCKO1 more efficiently than CPPU, as opposed to the inhibition of E381A/S mutants, emphasizing the importance of this residue for inhibitor binding. As highly specific CKO inhibitors without undesired side effects are of major interest for physiological studies, all studied compounds were further analyzed for cytokinin activity in the Amaranthus bioassay and for binding to the Arabidopsis cytokinin receptors AHK3 and AHK4. By contrast to CPPU itself, APPU and several benzylureas bind only negligibly to the receptors and exhibit weak cytokinin activity.

Asp157 is required for the function of PsbO, the photosystem II manganese stabilizing protein.

PsbO, the photosystem II manganese stabilizing protein, contains an aspartate residue [Asp157 (spinach numbering)], which is highly conserved in eukaryotic and prokaryotic PsbOs. The homology model of the PSII-bound conformation of spinach PsbO presented here positions Asp157 in the large flexible loop of the protein. We have characterized site-directed mutants (D157N, D157E, and D157K) of spinach PsbO that were rebound to PsbO-depleted PSII to probe the role of Asp157. Structural data revealed that PsbO Asp157 mutants exhibit near-wild-type solution structure at 25 degrees C, but functional analyses of the mutants showed that these are the first genetically modified PsbO proteins from spinach that combine wild-type PSII binding behavior with significantly impaired O(2) evolution activity; all of the mutants reconstituted approximately 30% of control O(2) evolution activity. PsbO Asp157 has been proposed to be a part of a putative H(2)O/H(+) channel that links the active site of the oxygen-evolving complex with the lumen [De Las Rivas, J., and Barber, J. (2004) Photosynth. Res. 81, 329-343]. Unsuccessful attempts to use chemical rescue to enhance the activity restored by Asp157 mutants could indicate that this residue is not involved in a proton transfer network. It is shown, however, that these mutants are deficient in restoring efficient Cl(-) retention by PSII.

Inorganic cofactor stabilization and retention: the unique functions of the two PsbO subunits of eukaryotic photosystem II.

Eukaryotic PsbO, the photosystem II (PSII) manganese-stabilizing protein, has two N-terminal sequences that are required for binding of two copies of the protein to PSII [Popelkova, H., et al. (2002) Biochemistry 41, 10038-10045; Popelkova, H., et al. (2003) Biochemistry 42, 6193-6200]. In the work reported here, a set of selected N-terminal truncation mutants of PsbO that affect subunit binding to PSII were used to determine the effects of PsbO stoichiometry on the Mn, Ca(2+), and Cl(-) cofactors and to characterize the roles of each of the PsbO subunits in PSII function. Results of the experiments with the PsbO-depleted PSII membranes reconstituted with the PsbO deletion mutants showed that the presence of PsbO does not affect Ca(2+) retention by PSII in steady-state assays of activity, nor is it required for Ca(2+) to protect the Mn cluster against reductive inhibition in darkness. In contrast to the results with Ca(2+), PsbO increases the affinity of Cl(-) for the active site of the O(2)-evolving complex (OEC) as expected. These results together with other data on activity retention suggest that PsbO can stabilize the Mn cluster by facilitating retention of Cl(-) in the OEC. The data presented here indicate that each of two copies of PsbO has a distinctive function in PSII. Binding of the first PsbO subunit fully stabilizes the Mn cluster and enhances Cl(-) retention, while binding of the second subunit optimizes Cl(-) retention, which in turn maximizes O(2) evolution activity. Nonspecific binding of some PsbO truncation mutants to PSII has no functional significance.

Site-directed mutagenesis of conserved C-terminal tyrosine and tryptophan residues of PsbO, the photosystem II manganese-stabilizing protein, alters its activity and fluorescence properties.

The extrinsic photosystem II PsbO subunit (manganese-stabilizing protein) contains near-UV CD signals from its complement of aromatic amino acid residues (one Trp, eight Tyr, and 13 Phe residues). Acidification, N-bromosuccinimide modification of Trp, reduction or elimination of a disulfide bond, or deletion of C-terminal amino acids abolishes these signals. Site-directed mutations that substitute Phe for Trp241 and Tyr242, near the C-terminus of PsbO, were used to examine the contribution of these residues to the activity and spectral properties of the protein. Although this substitution is, in theory, conservative, neither mutant binds efficiently to PSII, even though these proteins appear to retain wild-type solution structures. Removal of six residues from the N-terminus of the W241F mutant restores activity to near-wild-type levels. The near-UV CD spectra of the mutants are modified; well-defined Tyr and Trp peaks are lost. Characterizations of the fluorescence spectra of the full-length WF and YF mutants indicate that Y242 contributes significantly to PsbO's Tyr fluorescence emission and that an excited-state tyrosinate could be present in PsbO. Deletion of W241 shows that this residue is a major contributor to PsbO's fluorescence emission. Loss of function is consistent with the proposal that a native C-terminal domain is required for PsbO binding and activity, and restoration of activity by deletion of N-terminal amino acids may provide some insights into the evolution of this important photosynthetic protein.

Current status of the role of Cl(-) ion in the oxygen-evolving complex.

This minireview summarizes the current state of knowledge concerning the role of Cl(-) in the oxygen-evolving complex (OEC) of photosystem II (PSII). The model that proposes that Cl(-) is a Mn ligand is discussed in light of more recent work. Studies of Cl(-) specificity, stoichiometry, kinetics, and retention by extrinsic polypeptides are discussed, as are the results that fail to detect Cl(-) ligation to Mn and results that show a lack of a requirement for Cl(-) in PSII-catalyzed H(2)O oxidation. Mutagenesis experiments in cyanobacteria and higher plants that produce evidence for a correlation between Cl(-) retention and stable interactions among intrinsic and extrinsic polypeptides are summarized, and spectroscopic data on the interaction between PSII and Cl(-) are discussed. Lastly, the question of the site of Cl(-) action in PSII is discussed in connection with the current crystal structures of the enzyme.

Kinetic and chemical analyses of the cytokinin dehydrogenase-catalysed reaction: correlations with the crystal structure.

CKX (cytokinin dehydrogenase) is a flavoprotein that cleaves cytokinins to adenine and the corresponding side-chain aldehyde using a quinone-type electron acceptor. In the present study, reactions of maize (Zea mays) CKX with five different substrates (N6-isopentenyladenine, trans-zeatin, kinetin, p-topolin and N-methyl-isopentenyladenine) were studied. By using stopped-flow analysis of the reductive half-reaction, spectral intermediates were observed indicative of the transient formation of a binary enzyme-product complex between the cytokinin imine and the reduced enzyme. The reduction rate was high for isoprenoid cytokinins that showed formation of a charge-transfer complex of reduced enzyme with bound cytokinin imine. For the other cytokinins, flavin reduction was slow and no charge-transfer intermediates were observed. The binary complex of reduced enzyme and imine product intermediate decays relatively slowly to form an unbound product, cytokinin imine, which accumulates in the reaction mixture. The imine product only very slowly hydrolyses to adenine and an aldehyde derived from the cytokinin N6 side-chain. Mixing of the substrate-reduced enzyme with Cu2+/imidazole as an electron acceptor to monitor the oxidative half-reaction revealed a high rate of electron transfer for this type of electron acceptor when using N6-isopentenyladenine. The stability of the cytokinin imine products allowed their fragmentation analysis and structure assessment by Q-TOF (quadrupole-time-of-flight) MS/MS. Correlations of the kinetic data with the known crystal structure are discussed for reactions with different cytokinins.

Mutagenesis of basic residues R151 and R161 in manganese-stabilizing protein of photosystem II causes inefficient binding of chloride to the oxygen-evolving complex.

Manganese-stabilizing protein of photosystem II, an intrinsically disordered polypeptide, contains a high ratio of charged to hydrophobic amino acid residues. Arg151 and Arg161 are conserved in all known MSP sequences. To examine the role of these basic residues in MSP structure and function, three mutants of spinach MSP, R151G, R151D, and R161G, were produced. Here, we present evidence that replacement of Arg151 or Arg161 yields proteins that have lower PSII binding affinity, and are functionally deficient even though about 2 mol of mutant MSP/mol PSII can be rebound to MSP depleted PSII membranes. R161G reconstitutes O(2) evolution activity to 40% of the control, while R151G and R151D reconstitute only 20% of the control activity. Spectroscopic and biochemical techniques fail to detect significant changes in solution structure. More extensive O(2) evolution assays revealed that the Mn cluster is stable in samples reconstituted with each mutated MSP, and that all three Arg mutants have the same ability to retain Ca(2+) as the wild-type protein. Activity assays exploring the effect of these mutations on retention of Cl(-), however, showed that the R151G, R151D, and R161G MSPs are defective in Cl(-) binding to the OEC. The mutants have Cl(-) K(M) values that are about four (R161G) or six times (R151G and R151D) higher than the value for the wild-type protein. The results reported here suggest that conserved positive charges on the manganese-stabilizing protein play a role in proper functional assembly of the protein into PSII, and, consequently, in retention of Cl(-) by the O(2)-evolving complex.

Ultra-structural and functional changes in the chloroplasts of detached barley leaves senescing under dark and light conditions.

Changes in the chloroplast ultra-structure and photochemical function were studied in detached barley (Hordeum vulgare L. cv. Akcent) leaf segments senescing in darkness or in continuous white light of moderate intensity (90 mumol m-2 s-1) for 5 days. A rate of senescence-induced chlorophyll degradation was similar in the dark- and light-senescing segments. The Chl a/b ratio was almost unchanged in the dark-senescing segments, whereas in the light-senescing segments an increase in this ratio was observed indicating a preferential degradation of light-harvesting complexes of photosystem II. A higher level of thylakoid disorganisation (especially of granal membranes) and a very high lipid peroxidation were observed in the light-senescing segments. In spite of these findings, both the maximal and actual photochemical quantum yields of the photosystem II were highly maintained in comparison with the dark-senescing segments.

Origin of chlorophyll fluorescence in plants at 55-75 degrees C.

The origin of heat-induced chlorophyll fluorescence rise that appears at about 55-60 degrees C during linear heating of leaves, chloroplasts or thylakoids (especially with a reduced content of grana thylakoids) was studied. This fluorescence rise was earlier attributed to photosystem I (PSI) emission. Our data show that the fluorescence rise originates from chlorophyll a (Chl a) molecules released from chlorophyll-containing protein complexes denaturing at 55-60 degrees C. This conclusion results mainly from Chl a fluorescence lifetime measurements with barley leaves of different Chl a content and absorption and emission spectra measurements with barley leaves preheated to selected temperatures. These data, supported by measurements of liposomes with different Chl a/lipid ratios, suggest that the released Chl a is dissolved in lipids of thylakoid membranes and that with increasing Chl a content in the lipid phase, the released Chl a tends to form low-fluorescing aggregates. This is probably the reason for the suppressed fluorescence rise at 55-60 degrees C and the decreasing fluorescence course at 60-75 degrees C, which are observable during linear heating of plant material with a high Chl a/lipid ratio (e.g. green leaves, grana thylakoids, isolated PSII particles).

Binding of manganese stabilizing protein to photosystem II: identification of essential N-terminal threonine residues and domains that prevent nonspecific binding.

The N-terminus of spinach photosystem II manganese stabilizing protein (MSP) contains two amino acid sequences, (4)KRLTYD(10)E and (15)TYL(18)E, that are necessary for binding of two copies of this subunit to the enzyme [Popelkova et al. (2002) Biochemistry 41, 10038-10045]. To better understand the basis of MSP-photosystem II interactions, the role of threonine residues in the highly conserved motifs T(Y/F)DE and TY has been characterized. Deletion mutants lacking the first 5, 6, 7, and 15 amino acid residues at the N-terminus of the protein were examined for their ability to reconstitute activity in MSP-depleted photosystem II. The results reported here show that truncations of five and six amino acid residues (mutants DeltaR5M and DeltaL6M mutants) have no negative effect on recovery of oxygen evolution activity or on binding of MSP to photosystem II. Deletion of seven residues (mutant DeltaT7M) decreases reconstitution activity to 40% of the control value and reduces functional binding of the mutant protein to photosystem II from two to one copy. Deletion of 15 amino acid residues (mutant DeltaT15M) severely impairs functional binding of MSP, and lowers O(2) evolution activity to less than 20% of the control. DeltaT7M is the only mutant that exhibited neither nonspecific binding to photosystem II nor changes in tertiary structure. These, and previous results, show that the highly conserved Thr7 and Thr15 residues of MSP are required for functional binding of two copies of the eukaryotic protein to photosystem II. Although the N-terminal domains, (1)EGGKR(6)L, (8)YDEIQS(14)K, and (16)YL(18)E of spinach MSP are unnecessary for specific, functional binding interactions, these sequences are necessary to prevent nonspecific binding of the protein to photosystem II.

Amino acid sequences and solution structures of manganese stabilizing protein that affect reconstitution of Photosystem II activity.

This minireview presents a summary of information available on the secondary and tertiary structure of manganese stabilizing protein (MSP) in solution, and on the identity of amino acid residues that affect binding and functional assembly of this protein into Photosystem II. New data on the secondary structure of C-terminal mutants and 90 degrees C-heated manganese stabilizing protein, along with earlier data on the secondary structure of N-terminal mutants and the tertiary structure of all modified MSP species, allow for an evaluation of models for spinach MSP secondary and tertiary structure. This summary of previous and new information better documents the natively unfolded behavior of the protein in solution. A two-step mechanism for binding of manganese stabilizing protein to Photosystem II is discussed and possible solution three-dimensional conformations of the wild-type protein and some of its unfolded mutants, are proposed.

N-terminal truncations of manganese stabilizing protein identify two amino acid sequences required for binding of the eukaryotic protein to photosystem II and reveal the absence of one binding-related sequence in cyanobacteria.

Manganese stabilizing protein (MSP) is an intrinsically disordered extrinsic subunit of photosystem II that regulates the stability and kinetic performance of the tetranuclear manganese cluster that oxidizes water to oxygen. An earlier study showed that deletion of the (1)E-(3)G domain of MSP caused no loss of activity reconstitution, whereas deletion of the (4)K-(10)E domain reduced binding of the protein from 2 to 1 mol of MSP/mol of photosystem II and lowered activity reconstitution to about 50% of the control value [Popelkova et al. (2002) Biochemistry 41, 2702-2711]. In this work we present evidence that deletion of 13 or 14 amino acid residues from the MSP N-terminus (mutants DeltaS13M and DeltaK14M) does not interfere either with functional binding of one copy of MSP to photosystem II or with reconstitution of oxygen evolution activity to 50% of the control level. Both of these mutants exhibit nonspecific binding to photosystem II at higher protein concentrations. Truncation of the MSP sequence by 18 amino acids (mutant DeltaE18M), however, causes a loss of protein binding and activity reconstitution. This result demonstrates that the N-terminal domain (15)T-(18)E is required for binding of at least one copy of MSP to photosystem II. Analyses of CD spectra reveal changes in the structure of DeltaE18M (loss of beta-sheet, gain of unordered structure). Use of the information gained from these experiments in analyses of N-terminal sequences of MSP from a number of species indicates that higher plants and algae possess two recognition domains that are required for MSP binding to PSII, whereas cyanobacteria lack the first N-terminal domain found in eukaryotes. This may explain the absence of a second copy of MSP in the crystal structure of PSII from Synechococcus elongatus [Zouni et al. (2001) Nature 409, 739-743].

N-terminus of the photosystem II manganese stabilizing protein: effects of sequence elongation and truncation.

The importance of the N-terminal domain of manganese stabilizing protein in binding to photosystem II has been previously demonstrated [Eaton-Rye and Murata (1989) Biochim. Biophys. Acta 977, 219-226; Odom and Bricker (1992) Biochemistry 31, 5616-5620]. In this paper, we report results from a systematic study of functional and structural consequences of N-terminal elongation and truncation of manganese stabilizing protein. Precursor manganese stabilizing protein is the unprocessed wild-type protein, which carries an N-terminal extension of 84 amino acids in the form of its chloroplastic signal peptide. Despite its increased size, this protein is able to reconstitute O(2) evolution activity to levels observed with the mature, processed protein, but it also binds nonspecifically to PSII. Truncation of wild-type manganese stabilizing protein by site-directed mutagenesis to remove three N-terminal amino acids, resulting in a mutant called DeltaG3M, causes no loss of activity reconstitution, but this protein also exhibits nonspecific binding. Further truncation of the wild-type protein by ten N-terminal amino acids, producing DeltaE10M, limits binding of manganese stabilizing protein to 1 mol/mol of photosystem II and decreases activity reconstitution to about 65% of that obtained with the wild-type protein. Because two copies of wild type normally bind to photosystem II, amino acids in the domain (4)K-(10)E must be involved in the binding of one copy of manganese stabilizing protein to photosystem II. Spectroscopic analysis (CD and UV spectra) reveals that N-terminal elongation and deletion of manganese stabilizing protein influence its overall conformation, even though secondary structure content is not perturbed. Our data suggest that the solution structure of manganese stabilizing protein attains a more compact solution structure upon removal of N-terminal amino acids.