Efficient production of fluorophore-labeled CC chemokines for biophysical studies using recombinant enterokinase and recombinant sortase.

Chemokines are important immune system proteins, many of which mediate inflammation due to their function to activate and cause chemotaxis of leukocytes. An important anti-inflammatory strategy is therefore to bind and inhibit chemokines, which leads to the need for biophysical studies of chemokines as they bind various possible partners. Because a successful anti-chemokine drug should bind at low concentrations, techniques such as fluorescence anisotropy that can provide nanomolar signal detection are required. To allow fluorescence experiments to be carried out on chemokines, a method is described for the production of fluorescently labeled chemokines. First, a fusion-tagged chemokine is produced in Escherichia coli, then efficient cleavage of the N-terminal fusion partner is carried out with lab-produced enterokinase, followed by covalent modification with a fluorophore, mediated by the lab-produced sortase enzyme. This overall process reduces the need for expensive commercial enzymatic reagents. Finally, we utilize the product, vMIP-fluor, in binding studies with the chemokine binding protein vCCI, which has great potential as an anti-inflammatory therapeutic, showing a binding constant for vCCI:vMIP-fluor of 0.37 ± 0.006 nM. We also show how a single modified chemokine homolog (vMIP-fluor) can be used in competition assays with other chemokines and we report a Kd for vCCI:CCL17 of 14 µM. This work demonstrates an efficient method of production and fluorescent labeling of chemokines for study across a broad range of concentrations.

Group 14 Metallafluorenes as Sensitive Luminescent Probes of Surfactants in Aqueous Solution.

Sila- and germafluorenes containing alkynyl(aryl) substituents at the 2,7- position are strongly emissive with high quantum yields in organic solvents. Provided they are sufficiently soluble in water, their hydrophobic structures have the potential for many biological and industrial applications in the detection and characterization of lipophilic structures. To that end, the emission behaviors of previously synthesized 2,7- bis[alkynyl(biphenyl)]-9,9-diphenylsilafluorene (1), 2,7- bis[alkynyl(methoxynaphthyl)]-9,9-diphenylgermafluorene (2), 2,7- bis[alkynyl(p-tolyl)]-9,9-diphenylsilafluorene (3), and 2,7- bis[alkynyl(m-fluorophenyl)]-9,9-diphenylsilafluorene (4) were characterized in aqueous solution and in the presence of various surfactants. Despite a high degree of hydrophobicity, all of these metallafluorenes (MFs) are soluble in aqueous solution at low micromolar concentrations and luminesce in a common aqueous buffer. Further, the 2,7 substituent makes the emission behavior tunable (up to 30 nm). Fold emission enhancements in the presence of various surfactants are highest toward Triton X-100 and CTAB (ranging from 5 to 25 fold) and are lowest for the anionic surfactants SDS and SDBS. These enhancements are competitive with existing probes of surfactants. Quantum yields in buffer range from 0.11 to 0.34, competitive with many common fluorophores in biological use. Strikingly, MF quantum yields in the presence of TX-100 and CTAB approach 100 % quantum efficiency. MF anisotropies are dramatically increased only in the presence of TX-100, CTAB, and CHAPS. Coupled with the above data, this suggests that MFs associate with neutral and charged surfactant aggregates. Interactions with the anionic surfactants are weaker and/or leave MFs solvent exposed. These properties make metallafluorenes competitive probes for surfactants and their properties and behaviors, and thus could also have important biological applications.

Stereospecific cholinesterase inhibition by O,S-diethylphenylphosphonothioate.

The inhibition kinetics and stereospecificity of the chiral nerve agent derivative O,S-diethylphenylphosphonothioate (DEPP) were examined for two forms of acetylcholinesterase (human and eel) and equine butyrylcholinesterase. Both S- and R-DEPP are poor inhibitors of eel AChE (IC50 150µM), consistent with a large, nondiscriminatory binding interaction in the active site of this enzyme. However, S-DEPP is active against human and equine AChE with low µM IC50s. DEPP stereospecificities (S/R) toward these enzymes are moderate (20) relative to other cholinesterase-organophosphate (OP) systems. Pralidoxime, a common rescue agent, affects a modest recovery of both hAChE and eqBChE from treatment with S-DEPP. This result is consistent with expected chemical modification by DEPP and indicates that a measurable amount of the enzyme-phosphonate adduct does not undergo aging. Kinetic analysis of inhibition of both hAChE and eqBChE by S-DEPP yields KI values near 8µM and k2 values of about 0.10min-1. In both cases, the reaction is practically irreversible. Second order rate constants calculated from these values are similar to those obtained previously using other thio-substituted OPs with bulky groups. Since BChE has a more accommodating acyl pocket than AChE, the similar behaviors of both enzymes toward S-DEPP is notable and is likely a reflection of the weakened potency of DEPP relative to chemical warfare agents.

Biophysical and Computational Studies of the vCCI:vMIP-II Complex.

Certain viruses have the ability to subvert the mammalian immune response, including interference in the chemokine system. Poxviruses produce the chemokine binding protein vCCI (viral CC chemokine inhibitor; also called 35K), which tightly binds to CC chemokines. To facilitate the study of vCCI, we first provide a protocol to produce folded vCCI from Escherichia coli (E. coli.) It is shown here that vCCI binds with unusually high affinity to viral Macrophage Inflammatory Protein-II (vMIP-II), a chemokine analog produced by the virus, human herpesvirus 8 (HHV-8). Fluorescence anisotropy was used to investigate the vCCI:vMIP-II complex and shows that vCCI binds to vMIP-II with a higher affinity than most other chemokines, having a Kd of 0.06 ± 0.006 nM. Nuclear magnetic resonance (NMR) chemical shift perturbation experiments indicate that key amino acids used for binding in the complex are similar to those found in previous work. Molecular dynamics were then used to compare the vCCI:vMIP-II complex with the known vCCI:Macrophage Inflammatory Protein-1ß/CC-Chemokine Ligand 4 (MIP-1ß/CCL4) complex. The simulations show key interactions, such as those between E143 and D75 in vCCI/35K and R18 in vMIP-II. Further, in a comparison of 1 µs molecular dynamics (MD) trajectories, vMIP-II shows more overall surface binding to vCCI than does the chemokine MIP-1ß. vMIP-II maintains unique contacts at its N-terminus to vCCI that are not made by MIP-1ß, and vMIP-II also makes more contacts with the vCCI flexible acidic loop (located between the second and third beta strands) than does MIP-1ß. These studies provide evidence for the basis of the tight vCCI:vMIP-II interaction while elucidating the vCCI:MIP-1ß interaction, and allow insight into the structure of proteins that are capable of broadly subverting the mammalian immune system.

Structural insights into the interaction between a potent anti-inflammatory protein, viral CC chemokine inhibitor (vCCI), and the human CC chemokine, Eotaxin-1.

Chemokines play important roles in the immune system, not only recruiting leukocytes to the site of infection and inflammation but also guiding cell homing and cell development. The soluble poxvirus-encoded protein viral CC chemokine inhibitor (vCCI), a CC chemokine inhibitor, can bind to human CC chemokines tightly to impair the host immune defense. This protein has no known homologs in eukaryotes and may represent a potent method to stop inflammation. Previously, our structure of the vCCI·MIP-1ß (macrophage inflammatory protein-1ß) complex indicated that vCCI uses negatively charged residues in ß-sheet II to interact with positively charged residues in the MIP-1ß N terminus, 20s region and 40s loop. However, the interactions between vCCI and other CC chemokines have not yet been fully explored. Here, we used NMR and fluorescence anisotropy to study the interaction between vCCI and eotaxin-1 (CCL11), a CC chemokine that is an important factor in the asthma response. NMR results reveal that the binding pattern is very similar to the vCCI·MIP-1ß complex and suggest that electrostatic interactions provide a major contribution to binding. Fluorescence anisotropy results on variants of eotaxin-1 further confirm the critical roles of the charged residues in eotaxin-1. In addition, the binding affinity between vCCI and other wild type CC chemokines, MCP-1 (monocyte chemoattractant protein-1), MIP-1ß, and RANTES (regulated on activation normal T cell expressed and secreted), were determined as 1.1, 1.2, and 0.22 nm, respectively. To our knowledge, this is the first work quantitatively measuring the binding affinity between vCCI and multiple CC chemokines.

Synthesis and comparison of the biological activity of monocyclic phosphonate, difluorophosphonate and phosphate analogs of the natural AChE inhibitor cyclophostin.

New monocyclic phosphate, phosphonate and difluorophosphonate analogs of the natural AChE inhibitor cyclophostin were synthesized and their activity toward human AChE examined. Surprisingly, the phosphate, phosphonate, and difluorophosphonate analogs all showed diminished activity when compared with the natural product.

Rat hormone sensitive lipase inhibition by cyclipostins and their analogs.

Cyclipostins are bicyclic lipophilic phosphate natural products. We report here that synthesized individual diastereomers of cyclipostins P and R have nanomolar IC50s toward hormone sensitive lipase (HSL). The less potent diastereomers of these compounds have 10-fold weaker IC50s. The monocyclic phosphate analog of cyclipostin P is nearly as potent as the bicyclic natural product. Bicyclic phosphonate analogs of both cyclipostins exhibit IC50s similar to those of the weaker diastereomer phosphates (about 400nM). The monocyclic phosphonate analog of cyclipostin P has similar potency. A series of monocyclic phosphonate analogs in which a hydrophobic tail extends from the lactone side of the ring are considerably poorer inhibitors, with IC50s around 50µM. Finally cyclophostin, a related natural product inhibitor of acetylcholinesterase (AChE) that lacks the hydrocarbon tail of cyclipostins, is not active against HSL. These results indicate a critical SAR for these compounds, the hydrophobic tail. The smaller lactone ring is not critical to activity, a similarity shared with cyclophostin and AChE. The HSL kinetics of inhibition for the cyclipostin P trans diastereomer were examined in detail. The reaction is irreversible with a KI of 40nM and a rate constant for inactivation of 0.2min(-1). These results are similar to those observed for cyclophostin and AChE.

Mapping small DNA ligand hydroxyl radical footprinting and affinity cleavage products for capillary electrophoresis.

The mapping of DNA footprints and affinity cleavage sites for small DNA ligands is affected by the choice of sequencing chemistry and end label, and the potential for indexing errors can be significant when mapping small ligand-DNA interactions. Described here is a mechanism for avoiding such errors based on a summary of standard labeling, cleavage, and indexing chemistries and a comparison among them for analysis of these interactions by capillary electrophoresis. The length dependence of the difference between Sanger and Maxam-Gilbert indexing is examined for a number of duplexes of mixed sequence.

DNA targeting and cleavage by an engineered metalloprotein dimer.

Nature has illustrated through numerous examples that protein dimerization has structural and functional advantages. We previously reported the design and characterization of an engineered "metallohomeodomain" protein (C2) based on a chimera of the EF-hand Ca-binding motif and the helix-turn-helix motif of homeodomains (Lim and Franklin in Protein Sci. 15:2159-2165, 2004). This small metalloprotein binds the hard metal ions Ca(II) and Ln(III) and interacts with DNA with modest sequence preference and affinity, yet exhibits only residual DNA cleavage activity. Here we have achieved substantial improvement in function by constructing a covalent dimer of this C2 module (F2) to create a larger multidomain protein. As assayed via fluorescence spectroscopy, this F2 protein binds Ca(II) more avidly (25-fold) than C2 on a per-domain basis; in gel shift selection experiments, metallated F2 exhibits a specificity toward 5'-TAATTA-3' sequences. Finally, Ca(2)F2 cleaves plasmid DNA and generates a linear product in a Ca(II)-dependent way, unlike the CaC2 monomer. To the best of our knowledge this activation of Ca(II) in the context of an EF-hand binding motif is unique and represents a significant step forward in the design of artificial metallonucleases by utilizing biologically significant metal ions.

Fluorescence assay of polyamide-DNA interactions.

Polyamides (PAs) are distamycin-type ligands of DNA that bind the minor groove and are capable of sequence selective recognition. This capability provides a viable route to their development as therapeutics. Presented here is a simple and convenient fluorescence assay for PA-DNA binding. PAs are titrated into a sample of a hairpin DNA featuring a TAMRA dye attached to an internal dU near the PA binding site. In a study of 6 PAs, PA binding leads to a steady reproducible decrease in fluorescence intensity that can be used to generate binding isotherms. The assay works equally well with both short (6- to 8-ring) and long (14-ring) PAs, and K(d) values ranging from approximately 1 nM to at least 140 nM were readily obtained using a simple monochromator or filter configuration. Competition assays provide a means to assessing possible dye interference, which can be negligible. The assay can also be used to determine PA extinction coefficients and to measure binding kinetics; thus, it is an accessible and versatile tool for the study of PA properties and PA-DNA interactions.

Size matters: DNA binding site kinetics as a function of polyamide size.

Hairpin polyamides (PAs) are remarkable minor groove-binding DNA ligands that demonstrate high affinity and sequence selectivity. Following extensive studies of 6-8 ring hairpin PAs have been more recent descriptions of larger PAs (14 rings or more) and their distinguishing properties and biological activities. However, there are no comparative kinetic studies of PA DNA binding behaviors over a range of PA sizes, making it difficult to understand important structure-activity relationships related to PA size. Described herein is the first comparative kinetic study as a function of hairpin PA size that examines the complexities of PA-DNA binding behaviors with unprecedented detail. DNA binding kinetics of PAs with 6 (PA6) and 20 (PA20) rings are extensively characterized by fluorescence spectroscopy, and the properties compared with those of 8 and 14 ring hairpin PAs. PA6 has a 1:1 binding site stoichiometry but exhibits biphasic association kinetics, consistent with populating more than one binding mode. One decay constant is at the diffusion controlled limit, and the other is 400-fold slower. In contrast, PA20 has high binding site stoichiometry (2.5:1) but displays a much simpler association kinetic trace with a decay constant of 1e6 M-1s-1. Due to the variability and complexity of association kinetics, it is difficult to identify trends in this behavior as a function of PA size. However, even though hairpin PAs of 8 or more rings bind DNA with similar affinities, residence times increase as PA size increases, ranging from 20 s to over 2500 s. Particularly compelling is that the antiviral PA20 shows little to no dissociation from DNA when challenged with competitor DNA, suggesting that high residence times are important for this biological activity.

Metal ion and DNA binding by single-chain PvuII endonuclease: lessons from the linker.

Understanding the roles of metal ions in restriction enzymes has been complicated by both the presence of two metal ions in many active sites and their homodimeric structure. Using a single-chain form of the wild-type restriction enzyme PvuII (scWT) in which subunits are fused with a short polypeptide linker (Simoncsits et al. in J. Mol. Biol. 309:89-97, 2001), we have characterized metal ion and DNA binding behavior in one subunit and examined the effects of the linker on dimer behavior. scWT exhibits heteronuclear single quantum coherence NMR spectra similar to those of native wild-type PvuII (WT). For scWT, isothermal titration calorimetry data fit to two Ca(II) sites per subunit with low-millimolar K (d)s. The variant scWT|E68A, in which metal ion binding in one subunit is abolished by mutation, also binds two Ca(II) ions in the WT subunit with low-millimolar K (d)s. When there are no added metal ions, DNA binding affinity for scWT is tenfold stronger than that of the native WT, but tenfold weaker at saturating Ca(II) concentration. In the presence of Ca(II), scWT|E68A binds target DNA similarly to scWT, indicating that high-affinity substrate binding can be carried energetically by one metal-ion-binding subunit. Global analysis of DNA binding data for scWT|E68A suggests that the metal-ion-dependent behaviors observed for WT are reflective of independent subunit behavior. This characterization provides an understanding of subunit contributions in a homodimeric context.

DNA binding site kinetics of a large antiviral polyamide.

Polyamides (PAs) are powerful DNA ligands that can bind the minor groove of DNA with high affinity and specificity. While the characterization of PA-DNA behavior has focused principally on hairpin PAs 6-8 rings in size, there is increasing evidence that their behavior does not necessarily reflect the complexities that are emerging from studies of larger hairpin PAs, particularly concerning sequence mismatch tolerance and observed but unaddressed high PA-target site binding stoichiometries. To explore these complexities in more detail, kinetics studies of binding a large anti-HPV hairpin polyamide to an isolated DNA recognition site are described. Using a fluorescence assay, two distinct binding phases are observed for the first time in hairpin PA literature. PA14 concentration dependence analysis indicates that the faster binding event is diffusion-controlled; the apparent, second event is significantly slower (350-1500 fold). Both association phases are sampled in 1:1 complexes, consistent with cooperative binding of two PA molecules even under this condition. Fitting of the slow phase to a biexponential model yields two λon,app that differ by 4-5-fold, which is consistent with the high mismatch tolerance and binding site stoichiometry previously observed. A/T patterns in the recognition sequence do not affect these decay constants significantly. Dissociation decay constants are among the slowest reported for hairpin PAs (10-3 s-1), independent of A/T pattern, and may point to the efficacy of PA14 as an antiviral.

Characterizing metalloendonuclease mixed metal complexes by global kinetic analysis.

To test the role of a secondary metal ion in a two metal ion metallonuclease mechanism, some groups have introduced a nonsupportive metal ion [usually Ca(II)] in cleavage reactions. Stimulation of Mg(II)- or Mn(II)-supported activity has been taken as evidence that the second metal ion is regulatory. However, this activity has yet to be dissected to determine what processes and species contribute to this observation. Here, we test global kinetic analysis as an approach to this problem. Taking advantage of the various binding and cleavage constants established for PvuII endonuclease, we apply cleavage data obtained under a range of Mg(II) and Ca(II) concentrations to a number of kinetic models which specify A and B sites for both metal ions and various active species. The data are best fit and simulated with models which feature Ca(II) being held more strongly in the B (or secondary) site. This mixed metal enzyme species is the only one which forms appreciably and exhibits a cleavage rate constant similar to that observed when there is only one Mg(II) per active site (approximately 0.01 s(-1)). Thus, in the case of PvuII endonuclease, Ca(II) does not stimulate cleavage. However, a simulated increase in activity at moderate Ca(II) concentrations can be rationalized with a cleavage rate constant for the mixed species similar to that when two Mg(II) ions are present in the active site. This provides an important insight into the underlying basis for the Ca(II)-stimulated activity observed for some metallonucleases that is not accessible by any other means.

Synthesis and kinetic analysis of some phosphonate analogs of cyclophostin as inhibitors of human acetylcholinesterase.

Two new monocyclic analogs of the natural AChE inhibitor cyclophostin and two exocyclic enol phosphates were synthesized. The potencies and mechanisms of inhibition of the bicyclic and monocyclic enol phosphonates and the exocyclic enol phosphates toward human AChE are examined. One diastereoisomer of the bicyclic phosphonate exhibits an IC(50) of 3 microM. Potency is only preserved when the cyclic enol phosphonate is intact and conjugated to an ester. Kinetic analysis indicates both a binding and a slow inactivation step for all active compounds. Mass spectrometric analysis indicates that the active site Ser is indeed phosphorylated by the bicyclic phosphonate.

Roles of metal ions in nucleases.

The hydrolysis of phosphodiester bonds by metallonucleases is crucial to most aspects of nucleic acid processing. In recent years, studies of the classical restriction endonucleases have given way to the characterization of metallonucleases with widely divergent active site motifs. These developments fuel debates regarding the roles of metal ions in these enzymes. It is fortuitous that the current literature also includes the increased application of a variety of computational techniques to test the roles of metal ions in nucleic acid hydrolysis by these systems. This includes recent proposals and indirect evidence that these enzymes utilize metal ion movement in these reactions.

Kinetic analysis of product release and metal ions in a metallonuclease.

Most nucleases rely on divalent cations as cofactors to catalyze the hydrolysis of nucleic acid phosphodiester bonds. Here both equilibrium and kinetic experiments are used to test recently proposed models regarding the metal ion dependence of product release and the degree of cooperativity between metal ions bound in the active sites of the homodimeric PvuII endonuclease. Equilibrium fluorescence anisotropy studies indicate that product binding is dramatically weakened in the presence of metal ions. Pre-steady state kinetics indicate that product release is at least partially rate limiting. Steady state and pre-steady state data fit best to models in which metals remain bound to the enzyme after the release of product. Finally, analysis of cooperative and independent binding models for metal ions indicates that single turnover kinetic data are consistent with little to no positive cooperativity between the two metal ions binding each active site.

Thermodynamics and site stoichiometry of DNA binding by a large antiviral hairpin polyamide.

PA1 (dIm-PyPyßPyPyPy-γ-PyPyßPyPyPyPyß-Ta) is a large (14-ring) hairpin polyamide that was designed to recognize the DNA sequence 5'-W2GW7-3', where W is either A or T. As is common among the smaller 6-8-ring hairpin polyamides (PAs), it binds its target recognition sequence with low nM affinity. However, in addition to its large size, it is distinct from these more extensively characterized PAs in its high tolerance for mismatches and antiviral properties. In ongoing attempts to understand the basis for these distinctions, we conducted thermodynamics studies of PA1-DNA interactions. The temperature dependence of binding affinity was measured using TAMRA-labeled hairpin DNAs containing a single target sequence. PA1 binding to either an ATAT/TATA or an AAAA/TTTT pattern is consistently entropically driven. This is in contrast to the A/T pattern-dependent driving forces for DNA binding by netropsin, distamycin, and smaller hairpin polyamides. Analysis of the salt dependence of PA1-DNA binding reveals that within experimental error, there is no dependence on ionic strength, indicating that the polyelectrolyte effect does not contribute to PA1-DNA binding energetics. This is similar to that observed for smaller PAs. PA1-DNA recognition sequence binding stoichiometries were determined at both nM (fluorescence) and µM (circular dichroism) concentrations. With all sequences and under both conditions, multiple PA1 molecules bind the small DNA hairpin that contains only a single recognition sequence. Implications for these observations are discussed.

DNA binding thermodynamics and site stoichiometry as a function of polyamide size.

The interactions of 6-8 ring hairpin polyamides (PAs) with the minor groove of DNA have been investigated extensively. More recent studies of large antiviral PAs (14-20 rings) active against small DNA tumor viruses lead to questions regarding the extent to which the DNA binding behaviors of the well studied, smaller PAs can be reliably extrapolated to the larger ones. Described here is the first reported study of hairpin PA-DNA binding thermodynamics as a function of PA size (6-20 rings). All PAs exhibit binding affinity in the low nM to upper pM range, which indicates that affinity is not a discriminator of antiviral activity. Unlike the smaller PAs, a 20-ring PA does not appreciably dissociate from DNA in competition experiments, which indicates very long residence time that is consistent with antiviral activity. While the DNA binding thermodynamics for the smaller antivirally inactive 6- and 8-ring PAs is clearly enthalpically driven, the larger antiviral PAs (14- and 20-rings) exhibit strongly entropically-driven DNA binding. These distinct energetic signatures indicate that different types of interactions drive these associations. In DNA binding site stoichiometry experiments conducted at both nM and µM concentrations, all PAs except the 6-ring PA bind an isolated site with site stoichiometry of at least two PAs per recognition sequence. Electrostatic contributions to DNA binding affinity are small for all PAs and not correlated with PA size but weakly correlated with the number of imidazole residues. Altogether, these results indicate that DNA binding behaviors of smaller hairpin PAs do not necessarily reflect those of larger PAs. These are vital considerations in the development of hairpin PAs for biological use.

One- and two-metal ion catalysis: global single-turnover kinetic analysis of the PvuII endonuclease mechanism.

Ester hydrolysis is one of the most ubiquitous reactions in biochemistry. Many of these reactions rely on metal ions for various mechanistic steps. A large number of metal-dependent nucleases have been crystallized with two metal ions in their active sites. In spite of an ongoing discussion about the roles of these metal ions in nucleic acid hydrolysis, there are very few studies which examine this issue using the native cofactor Mg(II) and global fitting of reaction progress curves. As part of a comprehensive study of the representative homodimeric PvuII endonuclease, we have collected single-turnover DNA cleavage data as a function of Mg(II) concentration and globally fit these data to a number of models which test various aspects of the metallonuclease mechanism. DNA association rate constants are approximately 100-fold higher in the presence of the catalytically nonsupportive Ca(II) versus the native cofactor Mg(II), highlighting an interesting cofactor difference. A pathway in which metal ions bind prior to DNA is kinetically favored. The data fit well to a model in which both one and two metal ions per active site (EM(2)S and EM(4)S, respectively) support cleavage. Interestingly, the cleavage rate for EM(2)S is approximately 100-fold slower than that displayed by EM(4)S. Collectively, these data indicate that for the PvuII system, catalysis involving one metal ion per active site can indeed occur, but that a more efficient two-metal ion mechanism can be operative under saturating metal ion (in vitro) conditions.