Solution structures of two FHA1-phosphothreonine peptide complexes provide insight into the structural basis of the ligand specificity of FHA1 from yeast Rad53.

Rad53, a yeast checkpoint protein involved in regulating the repair of DNA damage, contains two forkhead-associated domains, FHA1 and FHA2. Previous combinatorial library screening has shown that FHA1 strongly selects peptides containing a pTXXD motif. Subsequent location of this motif within the sequence of Rad9, the target protein, coupled with spectroscopic analysis has led to identification of a tight binding sequence that is likely the binding site of FHA1: (188)SLEV(pT)EADATFVQ(200). We present solution structures of FHA1 in complex with this pT-peptide and with another Rad9-derived pT-peptide that has ca 30-fold lower affinity, (148)KKMTFQ(pT)PTDPLE(160). Both complexes showed intermolecular NOEs predominantly between three peptide residues (pT, +1, and +2 residues) and five FHA1 residues (S82, R83, S85, T106, and N107). Furthermore, the following interactions were implicated on the basis of chemical shift perturbations and structural analysis: the phosphate group of the pT residue with the side-chain amide group of N86 and the guanidino group of R70, and the carboxylate group of Asp (at the +3 position) with the guanidino group of R83. The generated structures revealed a similar binding mode adopted by these two peptides, suggesting that pT and the +3 residue Asp are the major contributors to binding affinity and specificity, while +1 and +2 residues could provide additional fine-tuning. It was also shown that FHA1 does not bind to the corresponding pS-peptides or a related pY-peptide. We suggest that differentiation between pT and pS-peptides by FHA1 can be attributed to hydrophobic interactions between the methyl group of the pT residue and the aliphatic protons of R83, S85, and T106 from FHA1.

Solution structure of the yeast Rad53 FHA2 complexed with a phosphothreonine peptide pTXXL: comparison with the structures of FHA2-pYXL and FHA1-pTXXD complexes.

It was proposed previously that the FHA2 domain of the yeast protein kinase Rad53 has dual specificity toward pY and pT peptides. The consensus sequences of pY peptides for binding to FHA2, as well as the solution structures of free FHA2 and FHA2 complex with a pY peptide derived from Rad9, have been obtained previously. We now report the use of a pT library to screen for binding of pT peptides with the FHA2 domain. The results show that FHA2 binds favorably to pT peptides with Ile at the +3 position. We then searched the Rad9 sequences with a pTXXI/L motif, and tested the binding affinity of FHA2 toward ten pT peptides derived from Rad9. One of the peptides, (599)EVEL(pT)QELP(607), displayed the best binding affinity (K(d)=12.9 microM) and the greatest chemical shift changes. The structure of the FHA2 complex with this peptide was then determined by solution NMR and the structure of the complex between FHA2 and the pY peptide (826)EDI(pY)YLD(832) was further refined. Structural comparison of these two complexes indicates that the Leu residue at the +3 position in the pT peptide and that at the +2 position in the pY peptide occupy a very similar position relative to the binding site residues from FHA2. This can explain why FHA2 is able to bind both pT and pY peptides. This position change from +3 to +2 could be the consequence of the size difference between Thr and Tyr. Further insight into the structural basis of ligand specificity of FHA domains was obtained by comparing the structures of the FHA2-pTXXL complex obtained in this work and the FHA1-pTXXD complex reported in the accompanying paper.

Tumor suppressor INK4: refinement of p16INK4A structure and determination of p15INK4B structure by comparative modeling and NMR data.

Within the tumor suppressor protein INK4 (inhibitor of cyclin-dependent kinase 4) family, p15INK4B is the smallest and the only one whose structure has not been determined previously, probably due to the protein's conformational flexibility and instability. In this work, multidimensional NMR studies were performed on this protein. The first tertiary structure was built by comparative modeling with p16INK4A as the template, followed by restrained energy minimization with NMR constraints (NOE and H-bonds). For this purpose, the solution structure of pl6INK4A, whose quality was also limited by similar problems, was refined with additional NMR experiments conducted on an 800 MHz spectrometer and by structure-based iterative NOE assignments. The nonhelical regions showed major improvement with root-mean-square deviation (RMSD) improved from 1.23 to 0.68 A for backbone heavy atoms. The completion of p15INK4B coupled with refinement of p16INK4A made it possible to compare the structures of the four INK4 members in depth, and to compare the structures of p16INK4A in the free form and in the p16INK4A-CDK6 complex. This is an important step toward a comprehensive understanding of the precise functional roles of each INK4 member.

Tumor suppressor INK4: quantitative structure-function analyses of p18INK4C as an inhibitor of cyclin-dependent kinase 4.

We report the first detailed structure-function analyses of p18INK4C (p18), which is a homologue of the important tumor suppressor p16INK4A (p16). Twenty-four mutants were designed rationally. The global conformations of the mutants were characterized by NMR, while the function was assayed by inhibition of cyclin-dependent kinase 4 (CDK4). Most of these mutants have unperturbed global structures, thus the changes in their inhibitory abilities can be attributed to the mutated residues. The important results are summarized as follows: (a) some residues at loops 1 and 2, but not 3, are important for the inhibitory function of p18, similar to the results for p16; (b) two residues at the first helix-turn-helix motif and two at the third are important for inhibition; (c) while the results generally agree with the prediction based on the crystal structures of p16-CDK6 and p19-CDK6 binary complexes, there are significant differences in a few residues, suggesting that the interactions in the binary complexes may not accurately represent the interactions in the ternary complexes (in the presence of cyclin D2); (d) most importantly, the extra loop of p18 appears to contribute to the function of p18, even though the crystal structure of the p19INK4D-CDK6 complex indicates no interactions involving this loop; (e) detailed analyses of the crystal structures and the functional results suggest that there are notable differences in the interactions between different members of the INK4 family and CDKs.

Tumor suppressor INK4: comparisons of conformational properties between p16(INK4A) and p18(INK4C).

The INK4 (inhibitor of cyclin-dependent kinase 4) family consists of four tumor-suppressor proteins: p15(INK4B), p16(INK4A), p18(INK4C), and p19(INK4D). While their sequences and structures are highly homologous, they show appreciable differences in conformational flexibility, stability, and aggregation tendency. Here, p16 and p18 were first compared directly by NMR for line broadening and disappearance, then investigated by three different approaches in search of the causes of these differences. From denaturation experiments it was found that both proteins are marginally stable with low denaturation stability (1.94 and 2.98 kcal/mol, respectively). Heteronuclear (1)H-(15)N nuclear Overhauser enhancement measurements revealed very limited conformational flexibility on the pico- to nanosecond time-scale for both p16 and p18. H/(2)H exchange of amide protons monitored by NMR on three proteins (p16, p18 as well as p15), however, revealed markedly different rates in the order p18

Tumor suppressor INK4: determination of the solution structure of p18INK4C and demonstration of the functional significance of loops in p18INK4C and p16INK4A.

Since the structures of several ankyrin-repeat proteins including the INK4 (inhibitor of cyclin-dependent kinase 4) family have been reported recently, the detailed structures and the functional roles of the loops have drawn considerable interest. This paper addresses the potential importance of the loops of ankyrin-repeat proteins in three aspects. First, the solution structure of p18INK4C was determined by NMR, and the loop structures were analyzed in detail. The loops adapt nascent antiparallel beta-sheet structures, but the positions are slightly different from those in the crystal structure. A detailed comparison between the solution structures of p16 and p18 has also been presented. The determination of the p18 solution structure made such detailed comparisons possible for the first time. Second, the [1H,15N]HSQC NMR experiment was used to probe the interactions between p18INK4C and other proteins. The results suggest that p18INK4C interacts very weakly with dna K and glutathione S-transferase via the loops. The third aspect employed site-specific mutagenesis and functional assays. Three mutants of p18 and 11 mutants of p16 were constructed to test functional importance of loops and helices. The results suggest that loop 2 is likely to be part of the recognition surface of p18INK4C or p16INK4A for CDK4, and they provide quantitative functional contributions of specific residues. Overall, our results enhance understanding of the structural and functional roles of the loops in INK4 tumor suppressors in particular and in ankyrin-repeat proteins in general.

Tumor suppressor p16INK4A: determination of solution structure and analyses of its interaction with cyclin-dependent kinase 4.

The solution structure of the tumor suppressor p16INK4A has been determined by NMR, and important recognition regions of both cdk4 and p16INK4A have been identified. The tertiary structure of p16INK4A contains four helix-turn-helix motifs linked by three loops. Twelve tumorigenic mutants of p16INK4A have been constructed and analyzed for their structure and activity, and new mutants have been designed rationally. A fragment of 58 residues at the N terminus of cdk4 important for p16INK4A binding has been identified. The importance of this region was further verified by mutational analysis of cdk4. These results and docking experiments have been used to assess possible modes of binding between p16INK4A and cdk4.

Tumor suppressor p16INK4A: structural characterization of wild-type and mutant proteins by NMR and circular dichroism.

The tumor suppressor p16INK4A with eight N-terminal amino acids deleted (p16/delta 1-8) was expressed in Escherichia coli without any fusion artifacts and purified. The integrity of p16/delta 1-8 was confirmed by mass spectrometry, and its activity was demonstrated by in vitro cdk4 inhibition assay. Various physical methods were used to characterize the molecular and structural properties of p16/delta 1-8. The protein was found to oligomerize in vitro, as demonstrated by gel electrophoresis, mass spectrometry, and NMR. Various approaches, including changes of concentration and pH, additions of salts, detergents, and various organic solvents, and construction of a C-terminal deletion mutant and a cysteine mutant were used to try to reduce the extent of oligomerization. Only decreasing the protein concentration was found to reduce oligomerization. The affinity between p16 molecules in vivo was demonstrated by the yeast two-hybrid system. The protein was found to be very unstable on the basis of urea- and guanidinium chloride-induced denaturation studies monitored by NMR and CD, respectively. Despite these unfavorable properties, total NMR assignments were accomplished with uniform 13C and 15N isotope labeling. All multidimensional NMR experiments were performed at a very low concentration of 0.2 mM. The secondary structure was then determined from the NMR data. The results of NMR and CD studies indicate that the protein is highly alpha-helical, and the ankyrin repeat sequences show helix-turn-helix structures. This is the first structural information obtained for the important motif of ankyrin repeats. Overall, p16/delta 1-8 appears to be conformationally flexible. In order to understand the structural basis of the functional changes for some mutants existing in tumor cells, several missense mutants of p16/delta 1-8 were constructed. Four of them were expressed at high levels and purified. The molecular and structural properties of these mutants were analyzed by CD and NMR and compared with the corresponding properties of wild-type p16/delta 1-8. The results suggest that the functional changes in P114L and G101W are likely to be related to global conformational changes. In addition, we have demonstrated that the tendency of aggregation increases significantly by a single D84H mutation.

Immunogenicity and conformational properties of an N-linked glycosylated peptide epitope of human T-lymphotropic virus type 1 (HTLV-I).

The identification and characterization of epitopes of human T-lymphotropic virus type 1 (HTLV-I), which elicit an effective humoral or cell-mediated immune response, remains a central obstacle to the development of a peptide-based vaccine against the virus infection. The objective of the studies presented here was to examine the influence of N-linked glycosylation on peptide structure and immunogenicity. We engineered the 233-253 sequence of gp46 of HTLV-I to contain an N-acetylglucosamine (GlcNAc) residue at Asn244. Secondary structure prediction using computer algorithms indicated that this peptide may contain a beta-turn at residues 242-246. Recent work with model glycopeptides suggests that beta-turn conformation in peptides may be induced, and probably is stabilized, by the presence of even a single sugar residue. In the present study, the structures of the 233-253 peptide, SC1, and the 233-253(Asn244-GlcNAc) glycopeptide, SC2, were determined. Similar conformation was exhibited by both the glycosylated and nonglycosylated peptide displaying a beta-turn at residues 243-246 and extended-chain structure at the peptide/glycopeptide termini. Both peptides were engineered into chimeric constructs with a promiscuous T-cell epitope from measles virus and were used as immunogens in rabbits. Both chimeric peptides were highly immunogenic in rabbits, producing high-titered antibodies as early as primary + three weeks. The antibodies generated against either construct were able to bind to whole virus (ELISA) and to gp46 (radioimmunoprecipitation assay). Additionally, human sera of individuals known to be positive for HTLV-I recognized both the glycosylated and nonglycosylated constructs. It appears that the 233-253 peptide is able to adopt a conformation that mimics the structure in native gp46, and addition of a GlcNAc residue at Asn244 does not affect the conformational preference or stability of this construct; nor does glycosylation alter immunogenicity but instead appears to enhance immune recognition.

Mechanism of adenylate kinase. 1H, 13C, and 15N NMR assignments, secondary structures, and substrate binding sites.

Backbone 1H, 13C, and 15N NMR assignments were obtained for the complex of chicken muscle adenylate kinase (AK) with its bisubstrate analog, MgAP5A [magnesium P1,P5-bis(5'-adenosyl)-pentaphosphate]. The assignments were used to elucidate the secondary structures and the enzyme-MgAP5A interactions. The work involves two unusual features: the molecular weight of AK (21.6 kDa) is one of the largest, on a monomeric basis, for which nearly complete assignment has been reported to date, and the assignment was performed at pH 7.1 instead of the acidic pH used for most other proteins. The results are summarized as follows. Firstly, unambiguous sequential assignments of backbone resonances have been achieved effectively by the combined use of two sequential assignment methods: NOE-directed assignments and the recently developed 1J-coupling-directed assignments. The starting points of the assignments were provided by several specifically labeled enzyme samples. Over 90% of the backbone 1H, 13C, and 15N resonances have been assigned. Secondly, spin system information was obtained from the HCCH-TOCSY and HCCH-COSY experiments as well as from 2D homonuclear NMR data. Overall, the side-chain resonances of ca. 40% of the residues, including most of the those displaying NOEs with the adenosine moieties of MgAP5A, have been assigned. Thirdly, secondary structural elements in the AK-MgAP5A complex were identified by extensive analyses of 1H-15N 2D HMQC-NOESY and 3D NOESY-HMQC spectra. Overall, the enzyme consists of ca. 60% alpha-helices and a five-stranded parallel beta-sheet. The results are compared with the secondary structure of the free AK from porcine muscle in crystals [Dreusicke, D., Karplus, P. A., & Schulz, G. E. (1988) J. Mol. Biol. 199, 359-371]. Lastly, most of the intermolecular NOEs between AK and the adenosine moieties of MgAP5A have been identified: Thr39, Leu43, Gly64, Leu66, Val67, Val72, and Gln101 are in proximity to the adenosine moiety of the adenosine 5'-monophosphate site, whereas Thr23 is in proximity to that of the adenosine 5'-triphosphate site. These data are discussed in relation to previous results from site-directed mutagenesis, NMR, and X-ray studies and in relation to the mechanism of catalysis.

Mechanism of adenylate kinase. What can be learned from a mutant enzyme with minor perturbation in kinetic parameters?

The structural and functional roles of threonine-23 in the chicken muscle adenylate kinase (AK) were investigated by site-directed mutagenesis coupled with proton nuclear magnetic resonance (NMR) and phosphorus stereochemistry. The residue is potentially important because it is conserved among all types of AK and is part of the consensus P-loop sequence, 15GXPGXGKGT23. A mutant enzyme T23A (replacing threonine-23 with alanine) was constructed. Analyses of conformational stability and proton NMR indicate that the side chain of this residue contributes little to the structure of AK, which suggests that the side chain of Thr-23 does not play a structural role. The steady-state kinetic data of the mutant enzyme T23A showed no change in kcat and only 5-7-fold increases in Km and dissociation constants. Such minor changes in kinetic data are insufficient to suggest a functional role of Thr-23. However, two-dimensional NMR analyses of WT.MgAP5A and T23A.MgAP5A complexes indicated that the side chain of Thr-23 is in proximity to the adenine ring of the ATP moiety in the WT.MgAP5A complex in solution. In addition, T23A showed a significant perturbation in the stereospecificity toward the diastereomers of (Rp)- and (Sp)-adenosine 5'-(1-thiotriphosphate) (ATP alpha S), with the Rp/Sp ratio increased from < 0.02 in wild-type to 0.37 in T23A. Detailed 31P NMR analysis indicated that the stereospecificity at the AMP site was not perturbed. These results suggest that the side chain of Thr-23 is involved in catalysis, most likely via a hydrogen bonding interaction Thr-OH...O-P alpha(ATP).(ABSTRACT TRUNCATED AT 250 WORDS)

Kringle-2 domain of the tissue-type plasminogen activator. 1H-NMR assignments and secondary structure.

A recombinant 90-residue polypeptide fragment containing the three-loop kringle-2 domain of human tissue-type plasminogen activator (t-PA) has been studied by two-dimensional 1H-NMR spectroscopy at 500 MHz. Complete sequence-specific resonance assignments were derived. Overall, the kringle exhibits a compact, folded conformation with more than 50% of the residues in irregular structures. Elements of secondary structure were identified from sequential, medium- and long-range dipolar (Overhauser) interproton interactions. These identifications were corroborated by analysis of spin-spin scalar 3J alpha N splittings and identification of backbone amide NH protons exhibiting retarded 1H/2H exchange in 2H2O. Three antiparallel beta-sheets and six tight turns were located. In addition, one short alpha-helical region was found in the Ser43-Ala44-Gln44a-Ala44b-Leu44c-Gly45+ ++ segment; this region contains three-residue insertions unique to the t-PA and urokinase kringles. Although the secondary structure of the t-PA kringle 2 in solution is in overall agreement with that observed in the crystallographic structure of the prothrombin kringle 1 [Tulinsky, A., Park, C.H. & Skrzypczak-Jankun, E. (1988) J. Mol. Biol. 202, 885-901], the alpha-helical segment and other details of the secondary structure differ somewhat from the prothrombin homolog.