Mutational analysis of the tetrahydrobiopterin-binding site in inducible nitric-oxide synthase.

Inducible nitric-oxide synthase (iNOS) is a hemeprotein that requires tetrahydrobiopterin (H4B) for activity. The influence of H4B on iNOS structure-function is complex, and its exact role in nitric oxide (NO) synthesis is unknown. Crystal structures of the mouse iNOS oxygenase domain (iNOSox) revealed a unique H4B-binding site with a high degree of aromatic character located in the dimer interface and near the heme. Four conserved residues (Arg-375, Trp-455, Trp-457, and Phe-470) engage in hydrogen bonding or aromatic stacking interactions with the H4B ring. We utilized point mutagenesis to investigate how each residue modulates H4B function. All mutants contained heme ligated to Cys-194 indicating no deleterious effect on general protein structure. Ala mutants were monomers except for W457A and did not form a homodimer with excess H4B and Arg. However, they did form heterodimers when paired with a full-length iNOS subunit, and these were either fully or partially active regarding NO synthesis, indicating that preserving residue identities or aromatic character is not essential for H4B binding or activity. Aromatic substitution at Trp-455 or Trp-457 generated monomers that could dimerize with H4B and Arg. These mutants bound Arg and H4B with near normal affinity, but Arg could not displace heme-bound imidazole, and they had NO synthesis activities lower than wild-type in both homodimeric and heterodimeric settings. Aromatic substitution at Phe-470 had no significant effects. Together, our work shows how hydrogen bonding and aromatic stacking interactions of Arg-375, Trp-457, Trp-455, and Phe-470 influence iNOSox dimeric structure, heme environment, and NO synthesis and thus help modulate the multiple effects of H4B.     

N-terminal domain swapping and metal ion binding in nitric oxide synthase dimerization

Nitric oxide synthase oxygenase domains (NOS(ox)) must bind tetrahydrobiopterin and dimerize to be active. New crystallographic structures of inducible NOS(ox) reveal that conformational changes in a switch region (residues 103-111) preceding a pterin-binding segment exchange N-terminal beta-hairpin hooks between subunits of the dimer. N-terminal hooks interact primarily with their own subunits in the 'unswapped' structure, and two switch region cysteines (104 and 109) from each subunit ligate a single zinc ion at the dimer interface. N-terminal hooks rearrange from intra- to intersubunit interactions in the 'swapped structure', and Cys109 forms a self-symmetric disulfide bond across the dimer interface. Subunit association and activity are adversely affected by mutations in the N-terminal hook that disrupt interactions across the dimer interface only in the swapped structure. Residue conservation and electrostatic potential at the NOS(ox) molecular surface suggest likely interfaces outside the switch region for electron transfer from the NOS reductase domain. The correlation between three-dimensional domain swapping of the N-terminal hook and metal ion release with disulfide formation may impact inducible nitric oxide synthase (i)NOS stability and regulation in vivo.     

Binding of the UvrB dimer to non-damaged and damaged DNA: residues Y92 and Y93 influence the stability of both subunits

UvrB is the ultimate damage-binding protein in bacterial nucleotide excision repair. Previous AFM experiments have indicated that UvrB binds to a damage as a dimer. In this paper we visualize for the first time a UvrB dimer in a gel retardation assay, with the second subunit (B2) more loosely bound than the subunit (B1) that interacts with the damage. A beta-hairpin motif in UvrB plays an important role in damage specific binding. Alanine substitutions of Y92 or Y93 in the beta-hairpin result in proteins that kill E. coli cells as a consequence of incision in non-damaged DNA. Apparently, both residues are needed to prevent binding of UvrB to non-damaged DNA. The lethality of Y93A results from UvrC-mediated incisions, whereas that of Y92A is due to incisions by Cho. This difference could be ascribed to a difference in stability of the B2 subunit in the mutant UvrB-DNA complexes. We show that for 3' incision UvrC needs to displace this second UvrB subunit from the complex, whereas Cho seems capable to incise the dimer-complex. Footprint analysis of the contacts of UvrB with damaged DNA revealed that the B2 subunit interacts with the flanking DNA at the 3' side of the lesion. The B2 subunit of mutant Y92A appeared to be more firmly associated with the DNA, indicating that even when B1 is bound to a lesion, the B2 subunit probes the adjacent DNA for presence of damage. We propose this to be a reflection of the process that the UvrB dimer uses to find lesions in the DNA. In addition to preventing binding to non-damaged DNA, the Y92 and Y93 residues appear also important for making specific contacts (of B1) with the damaged site. We show that the concerted action of the two tyrosines lead to a conformational change in the DNA surrounding the lesion, which is required for the 3' incision reaction.     

Subunit gamma of the oxaloacetate decarboxylase Na(+) pump: interaction with other subunits/domains of the complex and binding site for the Zn(2+) metal ion.

The oxaloacetate decarboxylase Na(+) pump of Klebsiella pneumoniae is an enzyme complex composed of the peripheral alpha subunit and the two integral membrane-bound subunits beta and gamma. The alpha subunit consists of the N-terminal carboxyltransferase domain and the C-terminal biotin domain, which are connected by a flexible proline/alanine-rich linker peptide. To probe interactions between the two domains of the alpha subunit and between alpha-subunit domains and the gamma subunit, the relevant polypeptides were synthesized in Escherichia coli and subjected to copurification studies. The two alpha-subunit domains had no distinct affinity toward each other and could, therefore, not be purified as a unit on avidin-sepharose. The two domains reacted together catalytically, however, performing the carboxyl transfer from oxaloacetate to protein-bound biotin. This reaction was enhanced up to 6-fold in the presence of the Zn(2+)-containing gamma subunit. On the basis of copurification with different tagged proteins, the C-terminal biotin domain but not the N-terminal carboxyltransferase domain of the alpha subunit formed a strong complex with the gamma subunit. Upon the mutation of gamma H78 to alanine, the binding affinity to subunit alpha was lost, indicating that this amino acid may be essential for formation of the oxaloacetate decarboxylase enzyme complex. The binding residues for the Zn(2+) metal ion were identified by site-directed and deletion mutagenesis. In the gamma D62A or gamma H77A mutant, the Zn(2+) content of the decarboxylase decreased to 35% or 10% of the wild-type enzyme, respectively. Less than 5% of the Zn(2+) present in the wild-type enzyme was found if the two C-terminal gamma-subunit residues H82 and P83 were deleted. Corresponding with the reduced Zn(2+) contents in these mutants, the oxaloacetate decarboxylase activities were diminished. These results indicate that aspartate 62, histidine 77, and histidine 82 of the gamma subunit are ligands for the catalytically important Zn(2+) metal ion.     

Dissociation and unfolding of inducible nitric oxide synthase oxygenase domain identifies structural role of tetrahydrobiopterin in modulating the heme environment

The oxygenase domain of the inducible nitric oxide synthase, Δ65 iNOSox is a dimer that binds heme, L-Arginine (L-Arg), and tetrahydrobiopterin (H₄B) and is the site for NO synthesis. The role of H₄B in iNOS structure-function is complex and its exact structural role is presently unknown. The present paper provides a simple mechanistic account of interaction of the cofactor tetrahydrobiopterin (H₄B) with the bacterially expressed Δ65 iNOSox protein. Transverse urea gradient gel electrophoresis studies indicated the presence of different conformers in the cofactor-incubated and cofactor-free Δ65 iNOSox protein. Dynamic Light Scattering (DLS) studies of cofactor-incubated and cofactor-free Δ65 iNOSox protein also showed two distinct populations of two different diameter ranges. Cofactor tetrahydrobiopterin (H₄B) shifted one population, with higher diameter, to the lower diameter ranges indicating conformational changes. The additional role played by the cofactor is to elevate the heme retaining capacity even in presence of denaturing stress. Together, these findings confirm that the H₄B is essential in modulating the iNOS heme environment and the protein environment in the dimeric iNOS oxygenase domain. (Mol Cell Boichem xxx: 1–10, 2005) Supported by Calcutta University Research Grants.     

Differences in collagen prolyl 4-hydroxylase assembly between two Caenorhabditis nematode species despite high amino acid sequence identity of the enzyme subunits.

The collagen prolyl 4-hydroxylases (P4Hs) are essential for proper extracellular matrix formation in multicellular organisms. The vertebrate enzymes are alpha(2)beta(2) tetramers, in which the beta subunits are identical to protein disulfide isomerase (PDI). Unique P4H forms have been shown to assemble from the Caenorhabditis elegans catalytic alpha subunit isoforms PHY-1 and PHY-2 and the beta subunit PDI-2. A mixed PHY-1/PHY-2/(PDI-2)(2) tetramer is the major form, while PHY-1/PDI-2 and PHY-2/PDI-2 dimers are also assembled but less efficiently. Cloning and characterization of the orthologous subunits from the closely related nematode Caenorhabditis briggsae revealed distinct differences in the assembly of active P4H forms in spite of the extremely high amino acid sequence identity (92-97%) between the C. briggsae and C. elegans subunits. In addition to a PHY-1/PHY-2(PDI-2)(2) tetramer and a PHY-1/PDI-2 dimer, an active (PHY-2)(2)(PDI-2)(2) tetramer was formed in C. briggsae instead of a PHY-2/PDI-2 dimer. Site-directed mutagenesis studies and generation of inter-species hybrid polypeptides showed that the N-terminal halves of the Caenorhabditis PHY-2 polypeptides determine their assembly properties. Genetic disruption of C. briggsae phy-1 (Cb-dpy-18) via a Mos1 insertion resulted in a small (short) phenotype that is less severe than the dumpy (short and fat) phenotype of the corresponding C. elegans mutants (Ce-dpy-18). C. briggsae phy-2 RNA interference produced no visible phenotype in the wild type nematodes but produced a severe dumpy phenotype and larval arrest in phy-1 mutants. Genetic complementation of the C. briggsae and C. elegans phy-1 mutants was achieved by injection of a wild type phy-1 gene from either species.     

NMR study and molecular dynamics simulations of optimized beta-hairpin fragments of protein G

The stability and structure of several beta-hairpin peptide variants derived from the C-terminus of the B1 domain of protein G were investigated by a number of experimental and computational techniques. Our analysis shows that the structure and stability of this hairpin can be greatly affected by one or a few simple mutations. For example, removing an unfavorable charge near the N-terminus of the peptide (Glu42 to Gln or Thr) or optimization of the N-terminal charge-charge interactions (Gly41 to Lys) both stabilize the peptide, even in water. Furthermore, a simple replacement of a charged residue in the turn (Asp47 to Ala) changes the beta-turn conformation. Finally, we show that the effects of combining these single mutations are additive, suggesting that independent stabilizing interactions can be isolated and evaluated in a simple model system. Our results indicate that the structure and stability of this beta-hairpin peptide can be modulated in numerous ways and thus contributes toward a more complete understanding of this important model beta-hairpin as well as to the folding and stability of larger peptides and proteins.     

Functional consequences of N- or C-terminal deletions of the delta subunit of chloroplast ATP synthase

Mutagenesis was used to generate seven truncation mutants of the spinach (Spinacia oleracea) chloroplast ATP synthase delta subunit lacking 5, 11, 17, or 35 amino acid residues from the N-terminus or 3, 9, or 15 residues from the C-terminus. Interactions between these mutants and all other subunits of the chloroplast ATPase were investigated by a yeast two-hybrid system. The results indicate that the N-terminal deletions mainly affected interactions between the delta subunit and the other part of CF(1), but did not significantly affect interactions with the CF(0) sector. In contrast, C-terminal truncations of the delta subunit mainly affected its interaction with the CF(0) sector and caused little impairment in interactions with the other part of CF(1). The conformation of the delta subunit C-terminal domain seems to be more sensitive to the truncations, as shown by minimal expression driven by C-terminal deleted (nine residues) mutants. Further studies showed C-terminal truncations of the delta subunit greatly impaired its ability to restore cyclic photophosphorylation in NaBr vesicles, whereas N-terminal truncations had little effect on the ability of delta to plug the CF(0) channel. None of the mutants impaired ATP hydrolysis by CF(1).     

Influence of the dimer interface on glutathione transferase structure and dynamics revealed by amide H/D exchange mass spectrometry

Mammalian glutathione (GSH) transferases are dimeric proteins, many of which share a common hydrophobic interaction motif that is important for dimer stability. In the rGSTM1-1 enzyme this motif involves the side chain of F56, located on the 56 loop of the N-terminal domain, which is intercalated between the alpha4- and alpha5-helices of the C-terminal domain of the opposing subnuit. Disruption of the complementary interactions in this motif by mutation of F56 to serine, arginine, or glutamate is known to have deleterious effects on catalytic efficiency but remarkably different effects on the stability of the dimer [Hornby et al. (2002) Biochemistry 41, 14238-14247]. The structural basis for the behavior of the mutants by amide H/D exchange mass spectrometry is described. A substantial decrease in H/D exchange is observed in the GSH binding domain and in parts of the dimer interface upon substrate binding. The F56S and F56R mutants exhibit enhanced H/D exchange kinetics in the GSH binding domain and at the dimer interface. In contrast, the F56E mutant shows a decrease in the rate and extent of amide H/D exchange at the dimer interface and enhanced exchange kinetics in the GSH binding domain. The results suggest that the F56E mutant has a restructured dimer interface with decreased solvent accessibility and dynamics. Although all of the F56 mutations disrupt the GSH binding site, the effects of the mutations on the structure of the subunit interface and dimer stability are quite distinct.     

Identification of N- and C-terminal amino acids of Lhca1 and Lhca4 required for formation of the heterodimeric peripheral photosystem I antenna LHCI-730

Apoproteins of higher plant light-harvesting complexes (LHC) share considerable amino acid sequence identity/similarity. Despite this fact, they occur in different oligomeric states (i.e., monomeric, dimeric, and trimeric). As a step toward understanding the underlying structure requirements for different oligomerization behavior, we analyzed whether amino acids at the N- and C-termini of Lhca1 and Lhca4 are involved in the formation of the heterodimeric LHCI-730. Using altered proteins produced by deletion or site-directed mutagenesis for reconstitution, we were able to identify amino acids required for the assembly of LHCI-730. At the N-terminus of Lhca1, W4 is involved in heterodimerization. This interaction probably depends on aromatic properties because only replacement of W4 by F resulted in dimer formation. Also, at the C-terminus of Lhca1, W seems to play a crucial role for interaction with Lhca4. A detailed analysis by point mutants revealed the importance of an aromatic residue at position 185. One or more other amino acid(s) located downstream of position 188 may exert additional stabilizing effects, presumably in a cooperative way. The scenario for Lhca4 is different. Dimerization broke down only after the deletion of the entire extrinsic N- or C-terminal region, demonstrating that the termini of Lhca4 are not involved in strong interactions with Lhca1 decisive for dimerization. At the N-terminus, dimerization was abolished after the removal of the same number of amino acids at which monomer formation failed. Site-specific mutagenesis of the amino acid decisive for LHC-formation in a deletion study demonstrated that its character is of no importance for dimerization and, therefore, that abolition of dimer formation may be the consequence of a loss in monomer formation. At the C-terminus of Lhca4, an even higher number of amino acids than required for monomer formation could be removed without the loss of dimerization. The decisive position is I168, located in the third transmembrane region. Because all point mutants of I168 in the full-length protein yielded dimers, failure of dimerization may be caused by either falling below a critical length of the polypeptide chain, resulting in the loss of too many weak interactions, or by too strong an impairment of Lhca4-folding. Interestingly, N- and C-terminal mutants of Lhca4 not able to form stable monomers formed stable dimers, indicating stabilization of labile monomeric complexes by the Lhca1 subunit in dimerization. Finally, the significance for dimer formation of amino acids in other parts of Lhca1 and Lhca4 which may be involved, besides the amino acids identified here in the specific assembly of the heterodimeric LHCI-730, is discussed. Their identification will result in a better understanding of structure characteristics determining the different oligomerization behavior of LHCs.     

The second stalk of the yeast ATP synthase complex: identification of subunits showing cross-links with known positions of subunit 4 (subunit b).

A component of the stator of the yeast ATP synthase (subunit 4 or b) showed many cross-linked products with the homobifunctional reagent dithiobis[succinimidyl propionate], which reacts with the amino group of lysine residues. The positions in subunit 4 that were involved in the cross-linkings were determined by using cysteine-generated mutants constructed by site-directed mutagenesis of ATP4. Cross-linking experiments with the heterobifunctional reagent p-azidophenacyl bromide, which has a spacer arm of 9 A, were performed with mitochondria and crude Triton X-100 extracts containing the solubilized enzyme. Substitution of lysine residues by cysteine residues in the hydrophilic C-terminal part of subunit 4 allowed cross-links with subunit h from C98 and with subunit d from C141, C143, and C151. OSCP was cross-linked from C174 and C209. A cross-linked product, 4+beta, was also obtained from C174. It is concluded that the C-terminus of subunit 4 is distant from the membrane surface and close to F(1) and OSCP. The N-terminal part of subunit 4 is close to subunit g, as demonstrated by the identification of a cross-linked product involving subunit g and the cysteine residues 7 or 14 of subunit 4.     

Structure of a nitric oxide synthase heme protein from Bacillus subtilis

Eukaryotic nitric oxide synthases (NOSs) produce nitric oxide to mediate intercellular signaling and protect against pathogens. Recently, proteins homologous to mammalian NOS oxygenase domains have been found in prokaryotes and one from Bacillus subtilis (bsNOS) has been demonstrated to produce nitric oxide [Adak, S., Aulak, K. S., and Stuehr, D. J. (2002) J. Biol. Chem. 277, 16167-16171]. We present structures of bsNOS complexed with the active cofactor tetrahydrofolate and the substrate L-arginine (L-Arg) or the intermediate N(omega)-hydroxy-L-arginine (NHA) to 1.9 or 2.2 A resolution, respectively. The bsNOS structure is similar to those of the mammalian NOS oxygenase domains (mNOS(ox)) except for the absence of an N-terminal beta-hairpin hook and zinc-binding region that interact with pterin and stabilize the mNOS(ox) dimer. Changes in patterns of residue conservation between bacterial and mammalian NOSs correlate to different binding modes for pterin side chains. Residue conservation on a surface patch surrounding an exposed heme edge indicates a likely interaction site for reductase proteins in all NOSs. The heme pockets of bsNOS and mNOS(ox) recognize L-Arg and NHA similarly, although a change from Val to Ile beside the substrate guanidinium may explain the 10-20-fold slower dissociation of product NO from the bacterial enzyme. Overall, these structures suggest that bsNOS functions naturally to produce nitrogen oxides from L-Arg and NHA in a pterin-dependent manner, but that the regulation and purpose of NO production by NOS may be quite different in B. subtilis than in mammals.     

Stoichiometric arginine binding in the oxygenase domain of inducible nitric oxide synthase requires a single molecule of tetrahydrobiopterin per dimer

In addition to its catalytic roles, the nitric oxide synthase (NOS) cofactor tetrahydrobiopterin (H4B) is required for substrate binding and for stabilization of the dimeric structure. We expressed and purified the core of the iNOS oxygenase domain consisting of residues 75-500 (CODiNOS) in the presence (H4B+) and absence (H4B-) of this cofactor. Both forms bound stoichiometric amounts of heme (>0.9 heme per protein subunit). H4B- CODiNOS was unable to bind arginine, gave an unstable ferrous carbonyl adduct, and was a mixture of monomer and dimer. H4B+ CODiNOS bound arginine, gave a stable ferrous carbonyl adduct, and was exclusively dimeric. The H4B cofactor content of this species was only one per dimer yet this was sufficient to form two competent arginine binding sites as determined by optical stoichiometric titrations.     

Synthesis, folding, and structure of the beta-turn mimic modified B1 domain of streptococcal protein G

The mechanism of beta-sheet formation remains a fundamental issue in our understanding of the protein folding process, but is hampered by the often encountered kinetic competition between folding and aggregation. The role of local versus nonlocal interactions has been probed traditionally by mutagenesis of both turn and strand residues. Recently, rigid organic molecules that impose a correct chain reversal have been introduced in several small peptides to isolate the importance of the long-range interactions. Here, we present the incorporation of a well-studied beta-turn mimic, designated as the dibenzofuran-based (DBF) amino acid, in the B1 domain of streptococcal protein G (B1G), and compare our results with those obtained upon insertion of the same mimic into the N-terminal beta-hairpin of B1G (O Melnyk et al., 1998, Lett Pept Sci 5:147-150). The DBF-B1G domain conserves the structure and the functional and thermodynamical properties of the native protein, whereas the modified peptide does not adopt a native-like conformation. The nature of the DBF flanking residues in the modified B1G domain prevents the beta-turn mimic from acting as a strong beta-sheet nucleator, which reinforces the idea that the native beta-hairpin formation is not driven by the beta-turn formation, but by tertiary interactions.     

Mutational analysis of the folding transition state of the C-terminal domain of ribosomal protein L9: a protein with an unusual beta-sheet topology

The C-terminal domain of ribosomal protein L9 (CTL9) is a 92-residue alpha-beta protein which contains an unusual three-stranded mixed parallel and antiparallel beta-sheet. The protein folds in a two-state fashion, and the folding rate is slow. It is thought that the slow folding may be caused by the necessity of forming this unusual beta-sheet architecture in the transition state for folding. This hypothesis makes CTL9 an interesting target for folding studies. The transition state for the folding of CTL9 was characterized by phi-value analysis. The folding of a set of hydrophobic core mutants was analyzed together with a set of truncation mutants. The results revealed a few positions with high phi-values (> or = 0.5), notably, V131, L133, H134, V137, and L141. All of these residues were found in the beta-hairpin region, indicating that the formation of this structure is likely to be the rate-limiting step in the folding of CTL9. One face of the beta-hairpin docks against the N-terminal helix. Analysis of truncation mutants of this helix confirmed its importance in folding. Mutations at other sites in the protein gave small phi-values, despite the fact that some of them had major effects on stability. The analysis indicates that formation of the antiparallel hairpin is critical and its interactions with the first helix are also important. Thus, the slow folding is not a consequence of the need to fully form the unusual three-stranded beta-sheet in the transition state. Analysis of the urea dependence of the folding rates indicates that mutations modulate the unfolded state. The folding of CTL9 is broadly consistent with the nucleation-condensation model of protein folding.     

Cytochrome b5 reductase: role of the si-face residues, proline 92 and tyrosine 93, in structure and catalysis

The conserved sequence motif "RxY(T)(S)xx(S)(N)" coordinates flavin binding in NADH:cytochrome b(5) reductase (cb(5)r) and other members of the flavin transhydrogenase superfamily of oxidoreductases. To investigate the roles of Y93, the third and only aromatic residue of the "RxY(T)(S)xx(S)(N)" motif, that stacks against the si-face of the flavin isoalloxazine ring, and P92, the second residue in the motif that is also in close proximity to the FAD moiety, a series of rat cb(5)r variants were produced with substitutions at either P92 or Y93, respectively. The proline mutants P92A, G, and S together with the tyrosine mutants Y93A, D, F, H, S, and W were recombinantly expressed in E. coli and purified to homogeneity. Each mutant protein was found to bind FAD in a 1:1 cofactor:protein stoichiometry while UV CD spectra suggested similar secondary structure organization among all nine variants. The tyrosine variants Y93A, D, F, H, and S exhibited varying degrees of blue-shift in the flavin visible absorption maxima while visible CD spectra of the Y93A, D, H, S, and W mutants exhibited similar blue-shifted maxima together with changes in absorption intensity. Intrinsic flavin fluorescence was quenched in the wild type, P92S and A, and Y93H and W mutants while Y93A, D, F, and S mutants exhibited increased fluorescence when compared to free FAD. The tyrosine variants Y93A, D, F, and S also exhibited greater thermolability of FAD binding. The specificity constant (k(cat)/K(m)(NADH)) for NADH:FR activity decreased in the order wild type > P92S > P92A > P92G > Y93F > Y93S > Y93A > Y93D > Y93H > Y93W with the Y93W variant retaining only 0.5% of wild-type efficiency. Both K(s)(H4NAD) and K(s)(NAD+) values suggested that Y93A, F, and W mutants had compromised NADH and NAD(+) binding. Thermodynamic measurements of the midpoint potential (E degrees ', n = 2) of the FAD/FADH(2) redox couple revealed that the potentials of the Y93A and S variants were approximately 30 mV more positive than that of wild-type cb(5)r (E degrees ' = -268 mV) while that of Y93H was approximately 30 mV more negative. These results indicate that neither P92 nor Y93 are critical for flavin incorporation in cb(5)r and that an aromatic side chain is not essential at position 93, but they demonstrate that Y93 forms contacts with the FAD that effectively modulate the spectroscopic, catalytic, and thermodynamic properties of the bound cofactor.     

Potential for interactions between the carboxy- and amino-termini of Rubisco activase subunits

The subunit interactions of Rubisco activase were investigated using mutants containing an introduced Cys near the N- and/or C-terminus. Chemical cross-linking of the C-terminal and double insertion mutant produced subunit dimers and dimers plus high ordered oligomers, respectively. Fluorescence measurements with N,N′-dimethyl-N-(iodoacetyl)-N′-(7-nitrobenz-2-oxa-1,3-diazol-4-yl)ethylenediamine showed that the environment around the introduced Cys near the C-terminus becomes more hydrophilic upon nucleotide binding. The Cys insertion mutants catalyzed Rubisco activation and ATP hydrolysis even when the subunits of the C-terminal or double insertion mutants were completely cross-linked. The results indicate that the termini of adjacent activase subunits are in close proximity and can be modified and even joined without affecting enzyme function.     

Sequence, structure, and dynamic determinants of Hsp27 (HspB1) equilibrium dissociation are encoded by the N-terminal domain

Human small heat shock protein 27 (Hsp27) undergoes concentration-dependent equilibrium dissociation from an ensemble of large oligomers to a dimer. This phenomenon plays a critical role in Hsp27 chaperone activity in vitro enabling high affinity binding to destabilized proteins. In vivo dissociation, which is regulated by phosphorylation, controls Hsp27 role in signaling pathways. In this study, we explore the sequence determinants of Hsp27 dissociation and define the structural basis underlying the increased affinity of Hsp27 dimers to client proteins. A systematic cysteine mutagenesis is carried out to identify residues in the N-terminal domain important for the equilibrium between Hsp27 oligomers and dimers. In addition, spin-labels were attached to the cysteine mutants to enable electron paramagnetic resonance (EPR) analysis of residue environment and solvent accessibility in the context of the large oligomers, upon dissociation to the dimer, and following complex formation with the model substrate T4 Lysozyme (T4L). The mutagenic analysis identifies residues that modulate the equilibrium dissociation in favor of the dimer. EPR analysis reveals that oligomer dissociation disrupts subunit contacts leading to the exposure of Hsp27 N-terminal domain to the aqueous solvent. Moreover, regions of this domain are highly dynamic with no evidence of a packed core. Interaction between T4L and sequences in this domain is inferred from transition of spin-labels to a buried environment in the substrate/Hsp27 complex. Together, the data provide the first structural analysis of sHSP dissociation and support a model of chaperone activity wherein unstructured and highly flexible regions in the N-terminal domain are critical for substrate binding.