Protein core packing by dynamic combinatorial chemistry.

We describe the first example of the recursive selection of biologically relevant macromolecules from a dynamic combinatorial library (DCL). A small library of 36 peptides was allowed to undergo self-association in aqueous solution to form 8436 trimers. The stability of each of these trimers was governed by the formation of a well-packed hydrophobic core. The DCL allowed variation of the hydrophobic residues comprising this core over all combinations of glycine, alanine, valine, leucine, isoleucine, and phenylalanine at six positions. The study leads to three important conclusions: (i) fewer than 0.2% of all possible core packing arrangements have high folding stabilities; (ii) these arrangements are stabilized by intimate "jigsaw" packing, not by sequestration of maximum hydrophobic surface area; (iii) a well-defined "rule" for packing of stable cores exists, but this rule is nuanced by the presence of two unexpected amino acid sequences and the absence of one expected amino acid sequence.

Conjugation of a peptide to an antibody engineered with free cysteines dramatically improves half-life and activity.

The long circulating half-life and inherently bivalent architecture of IgGs provide an ideal vehicle for presenting otherwise short-lived G-protein-coupled receptor agonists in a format that enables avidity-driven enhancement of potency. Here, we describe the site-specific conjugation of a dual agonist peptide (an oxyntomodulin variant engineered for potency and in vivo stability) to the complementarity-determining regions (CDRs) of an immunologically silent IgG4. A cysteine-containing heavy chain CDR3 variant was identified that provided clean conjugation to a bromoacetylated peptide without interference from any of the endogenous mAb cysteine residues. The resulting mAb-peptide homodimer has high potency at both target receptors (glucagon receptor, GCGR, and glucagon-like peptide 1 receptor, GLP-1R) driven by an increase in receptor avidity provided by the spatially defined presentation of the peptides. Interestingly, the avidity effects are different at the two target receptors. A single dose of the long-acting peptide conjugate robustly inhibited food intake and decreased body weight in insulin resistant diet-induced obese mice, in addition to ameliorating glucose intolerance. Inhibition of food intake and decrease in body weight was also seen in overweight cynomolgus monkeys. The weight loss resulting from dosing with the bivalently conjugated dual agonist was significantly greater than for the monomeric analog, clearly demonstrating translation of the measured in vitro avidity to in vivo pharmacology.

Electrostatic determinants of stability in parallel 3-stranded coiled coils.

The optimal positioning of salt-bridging interactions in a parallel alpha-helical homotrimeric coiled coil has been explored in a metal ion-assembled polypeptide trimer of 60 residues; arginine-glutamate pairs are more stabilizing than the corresponding lysine-glutamate pairs, and optimal stabilization is obtained with positively charged arginine residues at the c positions of the alpha-helical heptad and negatively charged glutamate residues at the e positions.

Microsecond melting of a folding intermediate in a coiled-coil peptide, monitored by T-jump/UV Raman spectroscopy.

A truncated version of the GCN4 coiled-coil peptide has been studied by ultraviolet resonance Raman (UVRR) spectroscopy with 197 nm excitation, where amide modes are optimally enhanced. Although the CD melting curve could be satisfactorily described with a two-state transition having Tm = 30 degrees C, singular value decomposition of the UVRR data yielded three principal components, whose temperature dependence implicates an intermediate form between the folded and unfolded forms, with formation and melting temperatures of 10 and 40 degrees C. Two alpha-helical amide III bands, at 1340 and 1300 cm(-1), melted out selectively at 10 and 40 degrees C, respectively, and are assigned to hydrated and unhydrated helical regions. The hydrated regions are proposed to be melted in the intermediate form, while the unhydrated regions are intact. Time-resolved UVRR spectra following laser-induced temperature jumps revealed two relaxations, with time constants of 0.2 and 15 mus. These are suggested to reflect the melting times of hydrated and unhydrated helices. The unhydrated helical region may be associated with a 14-residue "trigger" sequence that has been identified in the C-terminal half of GCN4. Dehydration of helices may be a key step in the folding of coiled-coils.

Time-resolved absorption and UV resonance Raman spectra reveal stepwise formation of T quaternary contacts in the allosteric pathway of hemoglobin.

Hemoglobin undergoes a series of molecular changes on the nanosecond and microsecond time-scale following photodissociation of CO ligands. We have monitored these processes with a combination of transient absorption and resonance Raman (RR) spectroscopy. The latter have been acquired at higher data rates than previously available, thanks to kilohertz Ti:sapphire laser technology, with frequency-quadrupling into the ultraviolet. As a result of improved resolution of the UVRR time-course, a new intermediate has been identified in the pathway from the R (HbCO) to the T (deoxyHb) state. This intermediate is not detected via absorption transients, since the change in heme absorption is insignificant, but its lifetime agrees with a reported magnetic circular dichroism transient, which has been attributed to a quaternary tryptophan interaction. The new UVRR data allow elaboration of the allosteric pathway by establishing that the T-state quaternary contacts are formed in two well-separated steps, with time constants of 2.9 micros and 21 micros, instead of a single 20 micros process. The first step involves the "hinge" region contacts, as monitored by the Trp beta 37...Asp alpha 94 H-bond, while the second involves the "switch" region, as monitored by the Tyr alpha 42...Asp beta 99 H-bond. A working model for the allosteric pathway is presented.

Hemoglobin site-mutants reveal dynamical role of interhelical H-bonds in the allosteric pathway: time-resolved UV resonance Raman evidence for intra-dimer coupling.

The dynamical effect of eliminating specific tertiary H-bonds in the hemoglobin (Hb) tetramer has been investigated by site-directed mutagenesis and time-resolved absorption and ultraviolet resonance Raman (UVRR) spectroscopy. The Trp alpha 14...Thr alpha 67 and Trp beta 15...Ser beta 72 H-bonds connect the A and E helices in the alpha and beta chains, and are proposed to break in the earliest protein intermediate (Rdeoxy) following photo-deligation of HbCO, along with a second pair of H-bonds involving tyrosine residues. Mutation of the acceptor residues Thr alpha 67 and Ser beta 72 to Val and Ala eliminates the A-E H-bonds, but has been shown to have no significant effect on ligand-binding affinity or cooperativity, or on spectroscopic markers of the T-state quaternary interactions. However, the mutations have profound and unexpected effects on the character of the Rdeoxy intermediate, and on the dynamics of the subsequent steps leading to the T state. Formation of the initial quaternary contact (RT intermediate) is accelerated, by an order of magnitude, but the locking-in of the T state is delayed by a factor of 2. These rate effects are essentially the same for either mutation, or for the double mutation, suggesting that the alpha beta dimer behaves as a mechanically coupled dynamical unit. Further evidence for intra-dimer coupling is provided by the Rdeoxy UVRR spectrum, in which either or both mutations eliminate the tyrosine difference intensity, although only tryptophan H-bonds are directly affected. A possible mechanism for mechanical coupling is outlined, involving transmission of forces through the alpha(1)beta(1) (and alpha(2)beta(2)) interface. The present observations establish that quaternary motions can occur on the approximately 100 ns time-scale. They show also that a full complement of interhelical H-bonds actually slows the initial quaternary motion in Hb, but accelerates the locking in of the T-contacts.

Recursively enriched dynamic combinatorial libraries for the self-selection of optimally stable proteins.

Even at very low template (guest) concentrations, the optimal template-assembled host from a dynamic combinatorial library (DCL) of host fragments may be unobtainable because hetero-oligomers will always be present at higher concentrations than isoenergetic homo-oligomers. Recursively enriched dynamic combinatorial libraries (REDCLs) offer a general solution to this problem that should be applicable to any self-selecting system under thermodynamic control. The utility of the REDCL strategy is demonstrated by determination of the optimal hydrophobic core packing in a template-assembled triple helical protein for which the template is a metal ion and the contributing host fragments are components of a 36-member conformationally restricted peptide library in which each peptide is augmented with a metal-binding moiety. Convergence of the 8436-member DCL to 5 optimal trimers (0.06% of the DCL) is complete after four cycles of enrichment. The core packing of the optimal sequences is shown to be native-like, and to reflect the hydrophobic amino acid preferences found in natural parallel three-stranded coiled coils. The influence of potentially critical amino acids on the outcome of the recursive enrichment is explored in a second REDCL. The same peptide sequences were returned and were shown to populate seven of the 8436 possible trimers, or 0.08% of the DCL.

Metal-assembled modular proteins: toward functional protein design.

Metal-assembled parallel helix-bundle proteins have been used to investigate electron transfer through alpha-helical structures. Fermi Golden Rule distance dependence of electron transfer rates was established in a family of designed metalloproteins, and the contribution of intrahelical hydrogen bonding to the matrix tunneling element was explored. The first steps toward the design of functional proteins using dynamic combinatorial assembly of alpha-helical structural elements are described.

Structural characterization of a paramagnetic metal-ion-assembled three-stranded alpha-helical coiled coil.

A helical peptide designed to present an all-leucine core upon folding has been shown to exhibit concentration-dependent helicity and to exist as an ill-defined equilibrium population of oligomers. In marked contrast, an identical peptide covalently modified with a 2,2'-bipyridyl group at the N terminus forms a stable three-stranded parallel coiled coil in the presence of transition metal ions. We have employed paramagnetic Ni(2+) and Co(2+) ions to stabilize the trimeric assembly and to exploit their shift and relaxation properties in NMR structural studies. We find that metal-ion binding and helix-bundle folding are tightly coupled. Surprisingly, the three-helix bundle exhibits a dynamic N-terminal region, and a well-structured C-terminal half. The spectra indicate the presence of a dual conformation for the bundle extending from the N terminus to residue 12. The structure of the two isomeric forms has been ascertained from interpretation of NOEs in the Ni(II) complex and (1)H pseudocontact shifts in the Co(II) complex. Two different facial isomers with distinct susceptibility tensors were identified. The bulky leucine side chain at position 3 in the peptide chain appears to play a role in the conformational variation at the N terminus.

Design of a functional protein for molecular recognition: specificity of ligand binding in a metal-assembled protein cavity probed by 19f NMR.

A metal-assembled homotrimeric coiled coil based on the GCN4-p1 sequence has been designed that noncovalently binds hexafluorobenzene and other similar ligands in a hydrophobic cavity, created by making the core substitution Asn16Ala ([Fe(bpyGCN4-N16A)3]2+). The KD of binding of hexafluorobenzene with [Fe(bpyGCN4-N16A)3]2+ was observed to be 1.1(9) x 10(-4) M by diffusion NMR experiments. A control coiled coil with the core substitution Asn16Val ([Fe(bpyGCN4-N16V)3]2+) exhibited a significantly weaker association with hexafluorobenzene, providing evidence that even in the absence of structural data, benzene-like ligands bind in the cavity created by the Asn16Ala substitution. 19F NMR was employed to observe hexafluorobenzene binding and to monitor titrations with competing hydrophobic and polar ligands similar in size and shape to hexafluorobenzene. All hydrophobic ligands bound with greater affinity than the polar ligands in the hydrophobic core, although the cavity seems to be somewhat flexible in terms of the sizes of molecules it can accommodate. Thus 19F NMR has proved to be a useful spectral tool to probe molecular recognition in a hydrophobic cavity of a metal-assembled coiled coil.

Electrospray ionization Fourier transform ion cyclotron resonance mass spectrometric analysis of metal-ion selected dynamic protein libraries.

The application of electrospray ionization (ESI) Fourier transform ion cyclotron resonance (FT-ICR) mass spectrometry to the investigation of the relative stabilities (and thus packing efficiencies) of Fe-bound trihelix peptide bundles is demonstrated. Small dynamic protein libraries are created by metal-ion assisted assembly of peptide subunits. Control of the trimeric aggregation state is coupled to stability selection by exploiting the coordination requirements of Fe(2+) in the presence of bidentate 2,2'-bipyridyl ligands covalently appended to the peptide monomers. At limiting metal-ion concentration, the most thermodynamically stable, optimally packed peptide trimers dominate the mass spectrum. The identities of optimally stable candidate trimers observed in the ESI FT-ICR mass spectra are confirmed by resynthesis of exchange-inert analogues and measurement of their folding free energies. The peptide composition of the trimers may be determined by infrared multiphoton dissociation (IRMPD) MS(3) experiments. Additional sequence information for the peptide subunits is obtained from electron capture dissociation (ECD) of peptides and metal-bound trimers. The experiments also suggest the presence of secondary structure in the gas phase, possibly due to partial retention of the solution-phase coiled coil structure.

Molecular targeting of inhibitor of apoptosis proteins based on small molecule mimics of natural binding partners.

An assay based on a solvent-sensitive fluorogenic dye molecule, badan, is used to test the binding affinity of a library of tetrapeptide molecules for the BIR3 (baculovirus IAP repeat) domain of XIAP (X-linked inhibitor of apoptosis protein). The fluorophore is attached to a tetrapeptide, Ala-Val-Pro-Cys-NH(2), through a thiol linkage and, upon binding to XIAP, undergoes a solvatochromic shift in fluorescence emission. When a molecule (e.g., a natural protein known to bind to XIAP or a tetrapeptide mimic) displaces the dye, the emission shifts back to the spectrum observed in water. As emission intensity is related to the binding of the tetrapeptide, the intensity can be used to determine the equilibrium constant, K, for the displacement of the dye by the tetrapeptide. The results permit residue-specific analysis of the interaction. Furthermore, we show that hydrophobic effects in the fourth position are general and can effectively increase overall affinity.

Dynamics of carbon monoxide binding to CooA.

CooA is a dimeric CO-sensing heme protein from Rhodospirillum rubrum. The heme iron in reduced CooA is six-coordinate; the axial ligands are His-77 and Pro-2. CO displaces Pro-2 and induces a conformation change that allows CooA to bind DNA and activate transcription of coo genes. Equilibrium CO binding is cooperative, with a Hill coefficient of n = 1.4, P(50) = 2.2 microm, and estimated Adair constants K(1) = 0.16 and K(2) = 1.3 microm(-1). The rates of CO binding and release are both strongly biphasic, with roughly equal amplitudes for the fast and slow phases. The association rates show a hyperbolic dependence on [CO], consistent with Pro-2 dissociation being rate-limiting. The kinetic characteristics of the transiently formed five-coordinate heme are probed via flash photolysis. These observations are integrated into a kinetic model, in which CO binding to one subunit decreases the rate of Pro-2 rebinding in the second, leading to a net increase in affinity for the second CO. The CO adduct exists in slowly interconverting "open" and "closed" forms. This interconversion probably involves the large-scale motions required to bring the DNA-binding domains into proper orientation. The combination of low CO affinity, slow CO binding, and slow conformational transitions ensures that activation of CooA only occurs at high (micromolar) and sustained (> or =1 min) levels of CO. When micromolar levels do occur, positive cooperativity allows efficient activation over a narrow range of CO concentrations.