Highly discriminating protein-protein interaction specificities in the context of a conserved binding energy hotspot

We explore the thermodynamic basis for high affinity binding and specificity in conserved protein complexes using colicin endonuclease-immunity protein complexes as our model system. We investigated the ability of each colicin-specific immunity protein (Im2, Im7, Im8 and Im9) to bind the endonuclease (DNase) domains of colicins E2, E7 and E8 in vitro and compared these to the previously studied colicin E9. We find that high affinity binding (Kd < or = 10(-14) M) is a common feature of cognate colicin DNase-Im protein complexes as are non-cognate protein-protein associations, which are generally 10(6)-10(8)-fold weaker. Comparative alanine scanning of Im2 and Im9 residues involved in binding the E2 DNase revealed similar behaviour to that of the two proteins binding the E9 DNase; helix III forms a conserved binding energy hotspot with specificity residues from helix II only contributing favourably in a cognate interaction, a combination we have termed as "dual recognition". Significant differences are seen, however, in the number and side-chain chemistries of specificity sites that contribute to cognate binding. In Im2, Asp33 from helix II dominates colicin E2 specificity, whereas in Im9 several hydrophobic residues, including position 33 (leucine), help define its colicin specificity. A similar distribution of specificity sites was seen using phage display where, with Im2 as the template, a library of randomised sequences was generated in helix II and the library panned against either the E2 or E9 DNase. Position 33 was the dominant specificity site recovered in all E2 DNase-selected clones, whereas a number of Im9 specificity sites were recovered in E9 DNase-selected clones, including position 33. In order to probe the relationship between biological specificity and in vitro binding affinity we compared the degree of protection afforded to bacteria against colicin E9 toxicity by a set of immunity proteins whose affinities for the E9 DNase differed by up to ten orders of magnitude. This analysis indicated that the Kd required for complete biological protection is <10(-10)M and that the "affinity window" over which the selection of novel immunity protein specificities likely evolves is 10(-6)-10(-10)M. This comprehensive survey of colicin DNase-immunity protein complexes illustrates how high affinity protein-protein interactions can be very discriminating even though binding is dominated by a conserved hotspot, with single or multiple specificity sites modulating the overall binding free energy. We discuss these results in the context of other conserved protein complexes and suggest that they point to a generic specificity mechanism in divergently evolved protein-protein interactions.     

Experimental and computational analyses of the energetic basis for dual recognition of immunity proteins by colicin endonucleases

Colicin endonucleases (DNases) are bound and inactivated by immunity (Im) proteins. Im proteins are broadly cross-reactive yet specific inhibitors binding cognate and non-cognate DNases with K_d values that vary between 10^− 4 and 10^− 14 M, characteristics that are explained by a ‘dual-recognition’ mechanism. In this work, we addressed for the first time the energetics of Im protein recognition by colicin DNases through a combination of E9 DNase alanine scanning and double-mutant cycles (DMCs) coupled with kinetic and calorimetric analyses of cognate Im9 and non-cognate Im2 binding, as well as computational analysis of alanine scanning and DMC data. We show that differential ΔΔGs observed for four E9 DNase residues cumulatively distinguish cognate Im9 association from non-cognate Im2 association. E9 DNase Phe86 is the primary specificity hotspot residue in the centre of the interface, which is coordinated by conserved and variable hotspot residues of the cognate Im protein. Experimental DMC analysis reveals that only modest coupling energies to Im9 residues are observed, in agreement with calculated DMCs using the program ROSETTA and consistent with the largely hydrophobic nature of E9 DNase-Im9 specificity contacts. Computed values for the 12 E9 DNase alanine mutants showed reasonable agreement with experimental ΔΔG data, particularly for interactions not mediated by interfacial water molecules. ΔΔG predictions for residues that contact buried water molecules calculated using solvated rotamer models met with mixed success; however, we were able to predict with a high degree of accuracy the location and energetic contribution of one such contact. Our study highlights how colicin DNases are able to utilise both conserved and variable amino acids to distinguish cognate from non-cognate Im proteins, with the energetic contributions of the conserved residues modulated by neighbouring specificity sites.     

Structure of the ultra-high-affinity colicin E2 DNase--Im2 complex

How proteins achieve high-affinity binding to a specific protein partner while simultaneously excluding all others is a major biological problem that has important implications for protein design. We report the crystal structure of the ultra-high-affinity protein-protein complex between the endonuclease domain of colicin E2 and its cognate immunity (Im) protein, Im2 (K(d)～10(-)(15)?M), which, by comparison to previous structural and biophysical data, provides unprecedented insight into how high affinity and selectivity are achieved in this model family of protein complexes. Our study pinpoints the role of structured water molecules in conjoining hotspot residues that govern stability with residues that control selectivity. A key finding is that a single residue, which in a noncognate context massively destabilizes the complex through frustration, does not participate in specificity directly but rather acts as an organizing center for a multitude of specificity interactions across the interface, many of which are water mediated.     

Specificity in protein-protein interactions: the structural basis for dual recognition in endonuclease colicin-immunity protein complexes

Bacteria producing endonuclease colicins are protected against their cytotoxic activity by virtue of a small immunity protein that binds with high affinity and specificity to inactivate the endonuclease. DNase binding by the immunity protein occurs through a "dual recognition" mechanism in which conserved residues from helix III act as the binding-site anchor, while variable residues from helix II define specificity. We now report the 1.7 A crystal structure of the 24.5 kDa complex formed between the endonuclease domain of colicin E9 and its cognate immunity protein Im9, which provides a molecular rationale for this mechanism. Conserved residues of Im9 form a binding-energy hotspot through a combination of backbone hydrogen bonds to the endonuclease, many via buried solvent molecules, and hydrophobic interactions at the core of the interface, while the specificity-determining residues interact with corresponding specificity side-chains on the enzyme. Comparison between the present structure and that reported recently for the colicin E7 endonuclease domain in complex with Im7 highlights how specificity is achieved by very different interactions in the two complexes, predominantly hydrophobic in nature in the E9-Im9 complex but charged in the E7-Im7 complex. A key feature of both complexes is the contact between a conserved tyrosine residue from the immunity proteins (Im9 Tyr54) with a specificity residue on the endonuclease directing it toward the specificity sites of the immunity protein. Remarkably, this tyrosine residue and its neighbour (Im9 Tyr55) are the pivots of a 19 degrees rigid-body rotation that relates the positions of Im7 and Im9 in the two complexes. This rotation does not affect conserved immunity protein interactions with the endonuclease but results in different regions of the specificity helix being presented to the enzyme.     

Probing metal ion binding and conformational properties of the colicin E9 endonuclease by electrospray ionization time-of-flight mass spectrometry

Nano-electrospray ionization time-of-flight mass spectrometry (ESI-MS) was used to study the conformational consequences of metal ion binding to the colicin E9 endonuclease (E9 DNase) by taking advantage of the unique capability of ESI-MS to allow simultaneous assessment of conformational heterogeneity and metal ion binding. Alterations of charge state distributions on metal ion binding/release were correlated with spectral changes observed in far- and near-UV circular dichroism (CD) and intrinsic tryptophan fluorescence. In addition, hydrogen/deuterium (H/D) exchange experiments were used to probe structural integrity. The present study shows that ESI-MS is sensitive to changes of the thermodynamic stability of E9 DNase as a result of metal ion binding/release in a manner consistent with that deduced from proteolysis and calorimetric experiments. Interestingly, acid-induced release of the metal ion from the E9 DNase causes dramatic conformational instability associated with a loss of fixed tertiary structure, but secondary structure is retained. Furthermore, ESI-MS enabled the direct observation of the noncovalent protein complex of E9 DNase bound to its cognate immunity protein Im9 in the presence and absence of Zn(2+). Gas-phase dissociation experiments of the deuterium-labeled binary and ternary complexes revealed that metal ion binding, not Im9, results in a dramatic exchange protection of E9 DNase in the complex. In addition, our metal ion binding studies and gas-phase dissociation experiments of the ternary E9 DNase-Zn(2+)-Im9 complex have provided further evidence that electrostatic interactions govern the gas phase ion stability.     

The crystal structure of the DNase domain of colicin E7 in complex with its inhibitor Im7 protein

Background: Colicin E7 (ColE7) is one of the bacterial toxins classified as a DNase-type E-group colicin. The cytotoxic activity of a colicin in a colicin-producing cell can be counteracted by binding of the colicin to a highly specific immunity protein. This biological event is a good model system for the investigation of protein recognition.Results: The crystal structure of a one-to-one complex between the DNase domain of colicin E7 and its cognate immunity protein Im7 has been determined at 2.3 Å resolution. Im7 in the complex is a varied four-helix bundle that is identical to the structure previously determined for uncomplexed Im7. The structure of the DNase domain of ColE7 displays a novel α/β fold and contains a Zn²⁺ ion bound to three histidine residues and one water molecule in a distorted tetrahedron geometry. Im7 has a V-shaped structure, extending two arms to clamp the DNase domain of ColE7. One arm (α1¹–loop12–α2¹; where ¹ represents helices in Im7) is located in the region that displays the greatest sequence variation among members of the immunity proteins in the same subfamily. This arm mainly uses acidic sidechains to interact with the basic sidechains in the DNase domain of ColE7. The other arm (loop 23–α3¹–loop 34) is more conserved and it interacts not only with the sidechain but also with the mainchain atoms of the DNase domain of ColE7.Conclusions: The protein interfaces between the DNase domain of ColE7 and Im7 are charge-complementary and charge interactions contribute significantly to the tight and specific binding between the two proteins. The more variable arm in Im7 dominates the binding specificity of the immunity protein to its cognate colicin. Biological and structural data suggest that the DNase active site for ColE7 is probably near the metal-binding site.     

Physical and structural basis for the strong interactions of the -ImPy- central pairing motif in the polyamide f-ImPyIm

The polyamide f-ImPyIm has a higher affinity for its cognate DNA than either the parent analogue, distamycin A (10-fold), or the structural isomer, f-PyImIm (250-fold), has for its respective cognate DNA sequence. These findings have led to the formulation of a two-letter polyamide "language" in which the -ImPy- central pairings associate more strongly with Watson-Crick DNA than -PyPy-, -PyIm-, and -ImIm-. Herein, we further characterize f-ImPyIm and f-PyImIm, and we report thermodynamic and structural differences between -ImPy- (f-ImPyIm) and -PyIm- (f-PyImIm) central pairings. DNase I footprinting studies confirmed that f-ImPyIm is a stronger binder than distamycin A and f-PyImIm and that f-ImPyIm preferentially binds CGCG over multiple competing sequences. The difference in the binding of f-ImPyIm and f-PyImIm to their cognate sequences was supported by the Na(+)-dependent nature of DNA melting studies, in which significantly higher Na(+) concentrations were needed to match the ability of f-ImPyIm to stabilize CGCG with that of f-PyImIm stabilizing CCGG. The selectivity of f-ImPyIm beyond the four-base CGCG recognition site was tested by circular dichroism and isothermal titration microcalorimetry, which shows that f-ImPyIm has marginal selectivity for (A.T)CGCG(A.T) over (G.C)CGCG(G.C). In addition, changes adjacent to this 6 bp binding site do not affect f-ImPyIm affinity. Calorimetric studies revealed that binding of f-ImPyIm, f-PyImIm, and distamycin A to their respective hairpin cognate sequences is exothermic; however, changes in enthalpy, entropy, and heat capacity (DeltaC(p)) contribute differently to formation of the 2:1 complexes for each triamide. Experimental and theoretical determinations of DeltaC(p) for binding of f-ImPyIm to CGCG were in good agreement (-142 and -177 cal mol(-)(1) K(-)(1), respectively). (1)H NMR of f-ImPyIm and f-PyImIm complexed with their respective cognate DNAs confirmed positively cooperative formation of distinct 2:1 complexes. The NMR results also showed that these triamides bind in the DNA minor groove and that the oligonucleotide retains the B-form conformation. Using minimal distance restraints from the NMR experiments, molecular modeling and dynamics were used to illustrate the structural complementarity between f-ImPyIm and CGCG. Collectively, the NMR and ITC experiments show that formation of the 2:1 f-ImPyIm-CGCG complex achieves a structure more ordered and more thermodynamically favored than the structure of the 2:1 f-PyImIm-CCGG complex.     

Multistep binding of transition metals to the H-N-H endonuclease toxin colicin E9

We report the first stopped-flow fluorescence analysis of transition metal binding (Co(2+), Ni(2+), Cu(2+), and Zn(2+)) to the H-N-H endonuclease motif within colicin E9 (the E9 DNase). The H-N-H consensus forms the active site core of a number of endonuclease groups but is also structurally homologous to the so-called treble-clef motif, a ubiquitous zinc-binding motif found in a wide variety of metalloproteins. We find that all the transition metal ions tested bind via multistep mechanisms. Binding was further dissected for Ni(2+) and Zn(2+) ions through the use of E9 DNase single tryptophan mutants, which demonstrated that most steps reflect conformational rearrangements that occur after the bimolecular collision, many common to the two metals, while one appears specific to zinc. The kinetically derived equilibrium dissociation constants (K(d)) for transition metal binding to the E9 DNase agree with previously determined equilibrium measurements and so confirm the validity of the derived kinetic mechanisms. Zn(2+) binds tightest to the enzyme (K(d) approximately 10(-)(9) M) but does not support endonuclease activity, whereas the other metals (K(d) approximately 10(-)(6) M) are active in endonuclease assays implying that the additional step seen for Zn(2+) traps the enzyme in an inactive but high affinity state. Metal-induced conformational changes are likely to be a conserved feature of H-N-H/treble clef motif proteins since similar Zn(2+)-induced, multistep binding was observed for other colicin DNases. Moreover, they appear to be independent both of the conformational heterogeneity that is naturally present within the E9 DNase at equilibrium, as well as the conformational changes that accompany the binding of its cognate inhibitor protein Im9.     

Hierarchical order of critical residues on the immunity-determining region of the Im7 protein which confer specific immunity to its cognate colicin.

The directed mutagenesis study of the Im7 protein of colicin E7 revealed that three residues, D31, D35, and E39, located in the loop 1 and helix 2 regions of the protein were critical for initiating the complex formation with its cognate colicin E7. Interestingly, the importance of these three critical residues in conferring specific immunity to its own colicin was exhibited in a hierarchical order, respectively. Moreover, we found that existence of the three critical residues was common among the DNase-type Im proteins. Most likely the three residues of the DNase-type immunity proteins are critical for initiating the unique protein-protein interactions with their cognate colicin. In addition, replacement of the helix 2 of Im7 by the corresponding region of Im8 produced a phenotype of the mutant protein very similar to that of Im8. This result suggests that the DNase-type Im proteins indeed share a "homologous-structural framework" and evolution of the Im proteins may be engendered by minor amino acid changes in this specific immunity-determining region without causing structural alteration of the proteins.     

NMR characterisation of the relationship between frustration and the excited state of Im7

Previous work shows that Im9 folds in a two-state transition while its homologue Im7 folds in a three-state transition via an on-pathway kinetic intermediate state (KIS), with this difference being related to frustration in the structure of Im7. We have used NMR spectroscopy to study conformational dynamics connected to the frustration. A combination of equilibrium peptide N¹H/N²H exchange, model-free analyses of backbone NH relaxation data and relaxation dispersion (RD)-NMR shows that the native state of Im7 is in equilibrium with an intermediate state that is lowly populated [equilibrium intermediate state (EIS)]. Comparison of kinetic and thermodynamic parameters describing the EIS native-state equilibrium obtained by RD-NMR with previously reported parameters describing the KIS native-state equilibrium obtained from stopped-flow fluorescence studies of refolding His-tagged Im7 shows that the KIS and the EIS are the same species. ¹⁵N chemical shifts of the EIS obtained from the RD-NMR analysis show that residues forming helix III in the native state are unstructured in the EIS while other residues experiencing frustration in the native state are in structured regions of the EIS. We show that binding of Im7 and its L53A/I54A variant (which resembles the EIS as shown in previous work) to the cognate partner for Im7, the DNase domain of colicin E7, causes the dynamic processes associated with the frustration to be dampened.     

Hx, a novel fluorescent, minor groove and sequence specific recognition element: design, synthesis, and DNA binding properties of p-anisylbenzimidazole-imidazole/pyrrole-containing polyamides

With the aim of incorporating a recognition element that acts as a fluorescent probe upon binding to DNA, three novel pyrrole (P) and imidazole (I)-containing polyamides were synthesized. The compounds contain a p-anisylbenzimidazolecarboxamido (Hx) moiety attached to a PP, IP, or PI unit, giving compounds HxPP (2), HxIP (3), and HxPI (4), respectively. These fluorescent hybrids were tested against their complementary nonfluorescent, non-formamido tetraamide counterparts, namely, PPPP (5), PPIP (6), and PPPI (7) (cognate sequences 5'-AAATTT-3', 5'-ATCGAT-3', and 5'-ACATGT-3', respectively). The binding affinities for both series of polyamides for their cognate and noncognate sequences were ascertained by surface plasmon resonance (SPR) studies, which revealed that the Hx-containing polyamides gave binding constants in the 10(6) M(-1) range while little binding was observed for the noncognates. The binding data were further compared to the corresponding and previously reported formamido-triamides f-PPP (8), f-PIP (9), and f-PPI (10). DNase I footprinting studies provided additional evidence that the Hx moiety behaved similarly to two consecutive pyrroles (PP found in 5-7), which also behaved like a formamido-pyrrole (f-P) unit found in distamycin and many formamido-triamides, including 8-10. The biophysical characterization of polyamides 2-7 on their binding to the abovementioned DNA sequences was determined using thermal melts (ΔT(M)), circular dichroism (CD), and isothermal titration calorimetry (ITC) studies. Density functional calculations (B3LYP) provided a theoretical framework that explains the similarity between PP and Hx on the basis of molecular electrostatic surfaces and dipole moments. Furthermore, emission studies on polyamides 2 and 3 showed that upon excitation at 322 nm binding to their respective cognate sequences resulted in an increase in fluorescence at 370 nm. These low molecular weight polyamides show promise for use as probes for monitoring DNA recognition processes in cells.     

Sequence recognition in the minor groove of DNA by covalently linked formamido imidazole-pyrrole-imidazole polyamides: effect of H-pin linkage and linker length on selectivity and affinity

The polyamide N-formamido imidazole-pyrrole-imidazole (f-ImPyIm) binds with an exceptionally high affinity for its cognate site 5'-ACGCGT-3' as a stacked, staggered, and noncovalent cooperative dimer. Investigations are presented into its sequence specificity and binding affinity when linked covalently as an H-pin "dimer". Five f-ImPyIm cross-linked analogues with six to nine methylene linkers and an eight-linked ethylene glycol linker were examined to investigate the effect of linkage and linker length on DNA binding. Thermal denaturation studies on short DNA hairpins showed preferential binding by both f-ImPyIm (DeltaTm = 7.8 degrees C) and its cross-linked derivatives (DeltaTm > 30 degrees C) at 5'-ACGCGT-3', indicating sequence specificity was retained on linkage. DNase I footprinting confirmed strict cognate site selectivity and demonstrated that affinity increased with linker length (f-ImPyIm-9 = f-ImPyIm-8 = f-ImPyIm-EG-8 > f-ImPyIm-7 > f-ImPyIm-6). The eight- and nine-linked derivatives bound at 100-fold lower concentrations at the cognate site relative to f-ImPyIm-6, and with 10-fold higher affinity than unlinked f-ImPyIm. Use of an ethylene glycol linkage in f-ImPyIm-EG-8 to improve solubility slightly increased the cognate site affinity relative to those of f-ImPyIm-8 and f-ImPyIm-9, although some selectivity was lost at high ligand concentration. CD demonstrated that cognate site binding by eight and nine-linked compounds occurred in the minor groove. SPR analysis gave a binding affinity (K) for f-ImPyIm-EG-8 at the cognate site of 2 x 10(10) M-1, representing a 100-fold increase relative to that of f-ImPyIm. This study demonstrates that the high-affinity cooperative binding of f-ImPyIm can be enhanced significantly by suitable covalent linkage, while maintaining its strict cognate site selectivity.     

In vivo and in vitro characterization of overproduced colicin E9 immunity protein.

We report the overproduction of the immunity protein for the DNase colicin E9 and its characterization both in vivo and in vitro. The genes for colicin immunity proteins are normally co-expressed from Col plasmids with their corresponding colicins. In the context of the enzymatic colicins, the two proteins form a complex, thereby protecting the host bacterium from the antibiotic activity of the colicin. This complex is then released into the medium, whereupon the colicin alone translocates (through the appropriate receptor) into sensitive bacterial strains, resulting in bacterial cell death. The immunity protein for colicin E9 (Im9) has been overproduced in a bacterial host in the absence of its colicin, to enable sufficient material to be isolated for structural studies. As a prelude to such studies, the in-vivo and in-vitro properties of overproduced Im9 were analysed. Electrospray mass spectrometry verified the molecular mass of the purified protein and analytical ultracentrifugation indicated that the native protein approximates a symmetric monomer. Fluorescence-enhancement and gel-filtration experiments show that purified Im9 binds to colicin E9 in a 1:1 molar ratio and that this binding neutralizes the DNase activity of the colicin. These results lay the foundations for a full biophysical and structural characterization of the colicin E9 DNase inhibitor protein, Im9.     

Synthesis and biophysical evaluation of minor-groove binding C-terminus modified pyrrole and imidazole triamide analogs of distamycin

Five polyamide derivatives with rationally modified C-terminus moieties were synthesized and their DNA binding specificity and affinity determined. A convergent approach was employed to synthesize polyamides containing an alkylaminopiperazine (4 and 5), a truncated piperazine (6), or an alkyldiamino-C-terminus moiety (7 and 8) with two specific objectives: to investigate the effects of number of potential cationic centers and steric bulk at the C-terminus. CD studies confirmed that compounds 4, 5, 7, and 8 bind in the minor groove of DNA. The alkylpiperazine containing compounds (4 and 5) showed only moderate binding to DNA with DeltaT(m) values of 2.8 and 8.3 degrees C with their cognate sequence, respectively. The alkyldiamino compounds (7 and 8) were more impressive producing a DeltaT(m) of >17 and >22 degrees C, respectively. Compound 6 (truncated piperazine) did not stabilize its cognate DNA sequence. Footprints were observed for all compounds (except compound 6) with their cognate DNA sequence using DNase I footprinting, with compound 7 producing a footprint of 0.1 microM at the expected 5'-ACGCGT-3' site. SPR analysis of compound 7 binding to 5'-ACGCGT-3', 5'-ACCGGT-3', and 5'-AAATTT-3' produced binding affinities of 2.2x10(6), 3.3x10(5), and 1x10(5)M(-1), respectively, indicating a preference for its cognate sequence of 5'-ACGCGT-3'. These results are in good agreement with the footprinting data. The results indicate that steric crowding at the C-terminus is important with respect to binding. However, the number of cationic centers within the molecule may also play a role. The alkyldiamino-containing compounds (7 and 8) warrant further investigation in the field of polyamide research.     

Ligand-induced changes in the conformational dynamics of a bacterial cytotoxic endonuclease

Knowledge about the conformational dynamics of a protein is key to understanding its biochemical and biophysical properties. In the present work we investigated the dynamic properties of the enzymatic domain of DNase colicins via time-resolved fluorescence and anisotropy decay analysis in combination with steady-state acrylamide quenching experiments. The dynamic properties of the apoenzyme were compared to those of the E9 DNase ligated to the transition metal ion Zn(2+) and the natural inhibitor Im9. We further investigated the contributions of each of the two tryptophans within the E9 DNase (Trp22 and Trp58) using two single-tryptophan mutants (E9 W22F and E9 W58F). Wild-type E9 DNase, E9 W22F, and E9 W58F, as well as Im9, showed multiple lifetime decays. The time-resolved and steady-state fluorescence results indicated that complexation of E9 DNase with Zn(2+) induces compaction of the E9 DNase structure, accompanied by immobilization of Trp22 along with a reduced solvent accessibility for both tryptophans. Im9 binding resulted in immobilization of Trp22 along with a decrease in the longest lifetime component. In contrast, Trp58 experienced less restriction on complexation of E9 DNase with Im9 and showed an increase in the longest lifetime component. Furthermore, the results point out that the Im9-induced changes in the conformational dynamics of E9 DNase are predominant and occur independently of the Zn(2+)-induced conformational effects.     

Computational design of a new hydrogen bond network and at least a 300-fold specificity switch at a protein-protein interface

The redesign of protein-protein interactions is a stringent test of our understanding of molecular recognition and specificity. Previously we engineered a modest specificity switch into the colicin E7 DNase-Im7 immunity protein complex by identifying mutations that are disruptive in the native complex, but can be compensated by mutations on the interacting partner. Here we extend the approach by systematically sampling alternate rigid body orientations to optimize the interactions in a binding mode specific manner. Using this protocol we designed a de novo hydrogen bond network at the DNase-immunity protein interface and confirmed the design with X-ray crystallographic analysis. Subsequent design of the second shell of interactions guided by insights from the crystal structure on tightly bound water molecules, conformational strain, and packing defects yielded new binding partners that exhibited specificities of at least 300-fold between the cognate and the non-cognate complexes. This multi-step approach should be applicable to the design of polar protein-protein interactions and contribute to the re-engineering of regulatory networks mediated by protein-protein interactions.     

Equilibrium measurements of cognate and noncognate interactions between aminoacyl transfer RNA synthetases and transfer RNA.

The interaction of Escherichia coli isoleucyl-tRNA synthetase with its cognate and five noncognate tRNAs, and of yeast valyl-tRNA synthetase with its cognate and four noncognate tRNAs, has been measured directly by fluorescence quenching. The cognate associations are strongest (association constant of 10(8) M-1 or more at pH 5.5, 17 degrees). A wide variation is found in the strengths of the noncognate interactions; these have association constants smaller than that of these cognate association by a factor of less than 10 to over 10(4), depending on the enzyme-t-RNA pair. A more detailed study of the cognate isoleucyl-tRNA synthetase-tRNAIle association suggests that the strength of the interaction is markedly sensitive to a pH-dependent transition in the enzyme centered at pH 6 on the other hand, Mg2+-induced structural changes in tRNAIle at 17 degrees in low salt do not greatly affect the availability of the nucleic acid's receptor sites for enzyme...     

Introducing intrinsic disorder reduces electrostatic steering in protein-protein interactions

Protein-protein interactions underlie many critical biology functions, such as cellular signaling and gene expression, in which electrostatic interactions can play a critical role in mediating the specificity and stability of protein complexes. A substantial portion of proteins are intrinsically disordered, and the influences of structural disorder on binding kinetics and thermodynamics have been widely investigated. However, whether the effect of electrostatic steering depends on structural disorder remains unexplored. In this work, we addressed the consequence of introducing intrinsic disorder in the electrostatic steering of the E3/Im3 complex using molecular dynamics simulation. Our results recapitulated the experimental observations that the responses of stability and kinetics to salt concentration for the ordered E3/Im3 complex were larger than those for the disordered E3/Im3 complex. Mechanistic analysis revealed that the native contact interactions involved in the encounter state and the transition state were essentially identical for both ordered and disordered E3. Therefore, the observed difference in electrostatic steering between ordered E3 and disordered E3 may result from their difference in conformation rather than their difference in binding mechanism. Because charged residues are frequently involved in protein-protein interactions, our results suggest that increasing structural disorder is expected to generally modulate the effect of electrostatic steering.     

T antigen origin-binding domain of simian virus 40: determinants of specific DNA binding

To better understand origin recognition and initiation of DNA replication, we have examined by NMR complexes formed between the origin-binding domain of SV40 T antigen (T-ag-obd), the initiator protein of the SV40 virus, and cognate and noncognate DNA oligomers. The results reveal two structural effects associated with "origin-specific" binding that are absent in nonspecific DNA binding. The first is the formation of a hydrogen bond (H-bond) involving His 203, a residue that genetic studies have previously identified as crucial to both specific and nonspecific DNA binding in full-length T antigen. In free T-ag-obd, the side chain of His 203 has a pK(a) value of approximately 5, titrating to the N(epsilon)(1)H tautomer at neutral pH (Sudmeier, J. L., et al. (1996) J. Magn. Reson., Ser. B 113, 236-247). In complexes with origin DNA, His 203 N(delta)(1) becomes protonated and remains nontitrating as the imidazolium cation at all pH values from 4 to 8. The H-bonded N(delta1)H resonates at 15.9 ppm, an unusually large N-H proton chemical shift, of a magnitude previously observed only in the catalytic triad of serine proteases at low pH. The formation of this H-bond requires the middle G/C base pair of the recognition pentanucleotide, GAGGC. The second structural effect is a selective distortion of the A/T base pair characterized by a large (0.6 ppm) upfield chemical-shift change of its Watson-Crick proton, while nearby H-bonded protons remain relatively unaffected. The results indicate that T antigen, like many other DNA-binding proteins, may employ "catalytic" or "transition-state-like" interactions in binding its cognate DNA (Jen-Jacobson, L. (1997) Biopolymers 44, 153-180), which may be the solution to the well-known paradox between the relatively modest DNA-binding specificity exhibited by initiator proteins and the high specificity of initiation.     

Synthesis and DNA binding properties of 1-(3-aminopropyl)-imidazole-containing triamide f-Im(∗)PyIm: A novel diamino polyamide designed to target 5'-ACGCGT-3'

A novel diamino/dicationic polyamide f-Im(?)PyIm (5) that contains an orthogonally positioned aminopropyl chain on an imidazole (Im(?)) moiety was designed to target 5'-ACGCGT-3'. The DNA binding properties of the diamino polyamide 5, determined by CD, ΔT(M), DNase I footprinting, SPR, and ITC studies, were compared with those of its monoamino/monocationic counterpart f-ImPyIm (1) and its diamino/dicationic isomer f-ImPy(?)Im (2), which has the aminopropyl group attached to the central pyrrole unit (Py(?)). The results gave evidence for the minor groove binding and selectivity of polyamide 5 for the cognate sequence 5'-ACGCGT-3', and with strong affinity (K(eq)=2.3×10(7)M(-1)). However, the binding affinities varied according to the order: f-ImPy(?)Im (2)>f-ImPyIm (1)?f-Im(?)PyIm (5) confirming that the second amino group can improve affinity, but its position within the polyamide can affect affinity.