Solution structure of ribosomal protein L40E, a unique C4 zinc finger protein encoded by archaeon Sulfolobus solfataricus.

The ribosomal protein L40E from archaeon Sulfolobus solfataricus is a component of the 50S ribosomal subunit. L40E is a 56-residue, highly basic protein that contains a C4 zinc finger motif, CRKC_X(10)_CRRC. Homologs are found in both archaea and eukaryotes but are not present in bacteria. Eukaryotic genomes encode L40E as a ubiquitin-fusion protein. L40E was absent from the crystal structure of euryarchaeota 50S ribosomal subunit. Here we report the three-dimensional solution structure of L40E by NMR spectroscopy. The structure of L40E is a three-stranded beta-sheet with a simple beta2beta1beta3 topology. There are two unique characteristics revealed by the structure. First, a large and ordered beta2-beta3 loop twists to pack across the one side of the protein. L40E contains a buried polar cluster comprising Lys19, Lys20, Cys22, Asn29, and Cys36. Second, the surface of L40E is almost entirely positively charged. Ten conserved basic residues are positioned on the two sides of the surface. It is likely that binding of zinc is essential in stabilizing the tertiary structure of L40E to act as a scaffold to create a broad positively charged surface for RNA and/or protein recognition.

NMR investigation of the dynamics of tryptophan side-chains in hemoglobins.

NMR relaxation measurements of 15N spin-lattice relaxation rate (R(1)), spin-spin relaxation rate (R(2)), and heteronuclear nuclear Overhauser effect (NOE) have been carried out at 11.7T and 14.1T as a function of temperature for the side-chains of the tryptophan residues of 15N-labeled and/or (2H,15N)-labeled recombinant human normal adult hemoglobin (Hb A) and three recombinant mutant hemoglobins, rHb Kempsey (betaD99N), rHb (alphaY42D/betaD99N), and rHb (alphaV96W), in the carbonmonoxy and the deoxy forms as well as in the presence and in the absence of an allosteric effector, inositol hexaphosphate (IHP). There are three Trp residues (alpha14, beta15, and beta37) in Hb A for each alphabeta dimer. These Trp residues are located in important regions of the Hb molecule, i.e. alpha14Trp and beta15Trp are located in the alpha(1)beta(1) subunit interface and beta37Trp is located in the alpha(1)beta(2) subunit interface. The relaxation experiments show that amino acid substitutions in the alpha(1)beta(2) subunit interface can alter the dynamics of beta37Trp. The transverse relaxation rate (R(2)) for beta37Trp can serve as a marker for the dynamics of the alpha(1)beta(2) subunit interface. The relaxation parameters of deoxy-rHb Kemspey (betaD99N), which is a naturally occurring abnormal human hemoglobin with high oxygen affinity and very low cooperativity, are quite different from those of deoxy-Hb A, even in the presence of IHP. The relaxation parameters for rHb (alphaY42D/betaD99N), which is a compensatory mutant of rHb Kempsey, are more similar to those of Hb A. In addition, TROSY-CPMG experiments have been used to investigate conformational exchange in the Trp residues of Hb A and the three mutant rHbs. Experimental results indicate that the side-chain of beta37Trp is involved in a relatively slow conformational exchange on the micro- to millisecond time-scale under certain experimental conditions. The present results provide new dynamic insights into the structure-function relationship in hemoglobin.

Molecular basis of Pirh2-mediated p53 ubiquitylation.

Pirh2 (p53-induced RING-H2 domain protein; also known as Rchy1) is an E3 ubiquitin ligase involved in a negative-feedback loop with p53. Using NMR spectroscopy, we show that Pirh2 is a unique cysteine-rich protein comprising three modular domains. The protein binds nine zinc ions using a variety of zinc coordination schemes, including a RING domain and a left-handed beta-spiral in which three zinc ions align three consecutive small beta-sheets in an interleaved fashion. We show that Pirh2-p53 interaction is dependent on the C-terminal zinc binding module of Pirh2, which binds to the tetramerization domain of p53. As a result, Pirh2 preferentially ubiquitylates the tetrameric form of p53 in vitro and in vivo, suggesting that Pirh2 regulates protein turnover of the transcriptionally active form of p53.

Biochemical and structural characterization of a novel family of cystathionine beta-synthase domain proteins fused to a Zn ribbon-like domain.

We have identified a novel family of proteins, in which the N-terminal cystathionine beta-synthase (CBS) domain is fused to the C-terminal Zn ribbon domain. Four proteins were overexpressed in Escherichia coli and purified: TA0289 from Thermoplasma acidophilum, TV1335 from Thermoplasma volcanium, PF1953 from Pyrococcus furiosus, and PH0267 from Pyrococcus horikoshii. The purified proteins had a red/purple color in solution and an absorption spectrum typical of rubredoxins (Rds). Metal analysis of purified proteins revealed the presence of several metals, with iron and zinc being the most abundant metals (2-67% of iron and 12-74% of zinc). Crystal structures of both mercury- and iron-bound TA0289 (1.5-2.0 A resolution) revealed a dimeric protein whose intersubunit contacts are formed exclusively by the alpha-helices of two cystathionine beta-synthase subdomains, whereas the C-terminal domain has a classical Zn ribbon planar architecture. All proteins were reversibly reduced by chemical reductants (ascorbate or dithionite) or by the general Rd reductase NorW from E. coli in the presence of NADH. Reduced TA0289 was found to be capable of transferring electrons to cytochrome C from horse heart. Likewise, the purified Zn ribbon protein KTI11 from Saccharomyces cerevisiae had a purple color in solution and an Rd-like absorption spectrum, contained both iron and zinc, and was reduced by the Rd reductase NorW from E. coli. Thus, recombinant Zn ribbon domains from archaea and yeast demonstrate an Rd-like electron carrier activity in vitro. We suggest that, in vivo, some Zn ribbon domains might also bind iron and therefore possess an electron carrier activity, adding another physiological role to this large family of important proteins.

The conserved CPH domains of Cul7 and PARC are protein-protein interaction modules that bind the tetramerization domain of p53.

Cul7 is a member of the Cullin Ring Ligase (CRL) family and is required for normal mouse development and cellular proliferation. Recently, a region of Cul7 that is highly conserved in the p53-associated, Parkin-like cytoplasmic protein PARC, was shown to bind p53 directly. Here we identify the CPH domains (conserved domain within Cul7, PARC, and HERC2 proteins) of both Cul7 and PARC as p53 interaction domains using size exclusion chromatography and NMR spectroscopy. We present the first structure of the evolutionarily conserved CPH domain and provide novel insight into the Cul7-p53 interaction. The NMR structure of the Cul7-CPH domain reveals a fold similar to peptide interaction modules such as the SH3, Tudor, and KOW domains. The p53 interaction surface of both Cul7 and PARC CPH domains was mapped to a conserved surface distinct from the analogous peptide-binding regions of SH3, KOW, and Tudor domains, suggesting a novel mode of interaction. The CPH domain interaction surface of p53 resides in the tetramerization domain and is formed by residues contributed by at least two subunits.

Quaternary structure of carbonmonoxyhemoglobins in solution: structural changes induced by the allosteric effector inositol hexaphosphate.

We have applied the residual dipolar coupling (RDC) method to investigate the solution quaternary structures of (2)H- and (15)N-labeled human normal adult recombinant hemoglobin (rHb A) and a low-oxygen-affinity mutant recombinant hemoglobin, rHb(alpha96Val-->Trp), both in the carbonmonoxy form, in the absence and presence of an allosteric effector, inositol hexaphosphate (IHP), using a stretched polyacrylamide gel as the alignment medium. Our recent RDC results [Lukin, J. A., Kontaxis, G., Simplaceanu, V., Yuan, Y., Bax, A., and Ho, C. (2003) Proc. Natl. Acad. Sci. U.S.A. 100, 517-520] indicate that the quaternary structure of HbCO A in solution is a dynamic ensemble between two previously determined crystal structures, R (crystals grown under high-salt conditions) and R2 (crystals grown under low-salt conditions). On the basis of a comparison of the geometric coordinates of the T, R, and R2 structures, it has been suggested that the oxygenation of Hb A follows the transition pathway from T to R and then to R2, with R being the intermediate structure [Srinivasan, R., and Rose, G. D. (1994) Proc. Natl. Acad. Sci. U.S.A. 91, 11113-11117]. The results presented here suggest that IHP can shift the solution quaternary structure of HbCO A slightly toward the R structure. The solution quaternary structure of rHbCO(alpha96Val-->Trp) in the absence of IHP is similar to that of HbCO A in the presence of IHP, consistent with rHbCO(alpha96Val-->Trp) having an affinity for oxygen lower than that of Hb A. Moreover, IHP has a much stronger effect in shifting the solution quaternary structure of rHbCO(alpha96Val-->Trp) toward the R structure and toward the T structure, consistent with IHP causing a more pronounced decrease in its oxygen affinity. The results presented in this work, as well as other results recently reported in the literature, clearly indicate that there are multiple quaternary structures for the ligated form of hemoglobin. These results also provide new insights regarding the roles of allosteric effectors in regulating the structure and function of hemoglobin. The classical two-state/two-structure allosteric mechanism for the cooperative oxygenation of hemoglobin cannot account for the structural and functional properties of this protein and needs to be revised.

A biophysical investigation of recombinant hemoglobins with aromatic B10 mutations in the distal heme pockets.

This study examines the structural and functional effects of amino acid substitutions in the distal side of both the alpha- and beta-chain heme pockets of human normal adult hemoglobin (Hb A). Using our Escherichia coli expression system, we have constructed four recombinant hemoglobins: rHb(alphaL29F), rHb(alphaL29W), rHb(betaL28F), and rHb(betaL28W). The alpha29 and beta28 residues are located in the B10 helix of the alpha- and beta-chains of Hb A, respectively. The B10 helix is significant because of its proximity to the ligand-binding site. Previous work showed the ability of the L29F mutation to inhibit oxidation. rHb(alphaL29W), rHb(betaL28F), and rHb(betaL28W) exhibit very low oxygen affinity and reduced cooperativity compared to those of Hb A, while the previously studied rHb(alphaL29F) exhibits high oxygen affinity. Proton nuclear magnetic resonance spectroscopy indicates that these mutations in the B10 helix do not significantly perturb the alpha(1)beta(1) and alpha(1)beta(2) subunit interfaces, while as expected, the tertiary structures near the heme pockets are affected. Experiments in which visible spectrophotometry was utilized reveal that rHb(alphaL29F) has equivalent or slower rates of autoxidation and azide-induced oxidation than does Hb A, while rHb(alphaL29W), rHb(betaL28F), and rHb(betaL28W) have increased rates. Bimolecular rate constants for NO-induced oxidation have been determined using a stopped-flow apparatus. These findings indicate that amino acid residues in the B10 helix of the alpha- and beta-chains can play different roles in regulating the functional properties and stability of the hemoglobin molecule. These results may provide new insights for designing a new generation of hemoglobin-based oxygen carriers.

NMR and X-ray crystallography, complementary tools in structural proteomics of small proteins.

NMR spectroscopy and X-ray crystallography, the two primary experimental methods for protein structure determination at high resolution, have different advantages and disadvantages in terms of sample preparation and data collection and analysis. It is therefore of interest to assess their complementarity when applied to small proteins. Structural genomics/proteomics projects provide an ideal opportunity to make such comparisons as they generate data in a systematic manner for large enough numbers of proteins to allow firm conclusions to be drawn. Here we report a comparison for 263 unique proteins screened by both NMR spectroscopy and X-ray crystallography in our structural proteomics pipeline. Only 21 targets (8%) were deemed amenable to both methods based on an initial 2D 15N-HSQC NMR spectrum and optimized crystallization trials. However, the use of both methods in the pipeline increased the total number of targets amenable to structure determination to 107, with 43 amenable to NMR only and 43 amenable to X-ray crystallographic methods only. We did not observe a correlation between 15N-HSQC spectral quality and the success of the same protein in crystallization screens. Similar results were found for an independent set of 159 proteins as reported in the accompanying paper by Snyder et al. Thus, we conclude that both methods are highly complementary, and in order to increase the number of proteins suited for structure determination, we suggest that both methods be used in parallel in screening of all small proteins for structure determination.

MONTE: An automated Monte Carlo based approach to nuclear magnetic resonance assignment of proteins.

A general-purpose Monte Carlo assignment program has been developed to aid in the assignment of NMR resonances from proteins. By virtue of its flexible data requirements the program is capable of obtaining assignments of both heavily deuterated and fully protonated proteins. A wide variety of source data, such as inter-residue scalar connectivity, inter-residue dipolar (NOE) connectivity, and residue specific information, can be utilized in the assignment process. The program can also use known assignments from one form of a protein to facilitate the assignment of another form of the protein. This attribute is useful for assigning protein-ligand complexes when the assignments of the unliganded protein are known. The program can be also be used as an interactive research tool to assist in the choice of additional experimental data to facilitate completion of assignments. The assignment of a deuterated 45 kDa homodimeric Glutathione-S-transferase illustrates the principal features of the program.

Quaternary structure of hemoglobin in solution.

Many important proteins perform their physiological functions under allosteric control, whereby the binding of a ligand at a specific site influences the binding affinity at a different site. Allosteric regulation usually involves a switch in protein conformation upon ligand binding. The energies of the corresponding structures are comparable, and, therefore, the possibility that a structure determined by x-ray diffraction in the crystalline state is influenced by its intermolecular contacts, and thus differs from the solution structure, cannot be excluded. Here, we demonstrate that the quaternary structure of tetrameric human normal adult carbonmonoxy-hemoglobin can readily be determined in solution at near-physiological conditions of pH, ionic strength, and temperature by NMR measurement of (15)N-(1)H residual dipolar couplings in weakly oriented samples. The structure is found to be a dynamic intermediate between two previously solved crystal structures, known as the R and R2 states. Exchange broadening at the subunit interface points to a rapid equilibrium between different structures that presumably include the crystallographically observed states.