Total Chemical Synthesis of an Orf Virus Protein, ORFV002, an Inhibitor of the Master Gene Regulator NF-κB.

ORFV002 is a novel orf viral protein (117 Aa) that inhibits nuclear events through the regulation of the transcriptional activity of NF-κB, a master regulator of human gene expression (Diel et al., J Virol 2011, 85, 264-275). It is identified as the first nuclear inhibitor of NF-κB produced by orf virus (ORFV) and no homologues in other genera of the Chordopoxvirinae subfamily have been reported to date (Diel et al., J Virol 2011, 85, 264-275). Our molecular structure predictions suggest that ORFV002 may mimic part of IκB, an inhibitor and natural human partner of NF-κB. Recent advances in total chemical synthesis of proteins have provided solutions in overcoming challenges of current recombinant methods of protein isolation for structure elucidation. Aided by Boc solid phase peptide synthesis and native chemical ligation, ORFV002 was successfully synthesized in multimilligram amounts in good yield and high purity.

Total synthesis of cytochrome b562 by native chemical ligation using a removable auxiliary.

We have completed the total chemical synthesis of cytochrome b562 and an axial ligand analogue, [SeMet(7)]cyt b562, by thioester-mediated chemical ligation of unprotected peptide segments. A novel auxiliary-mediated native chemical ligation that enables peptide ligation to be applied to protein sequences lacking cysteine was used. A cleavable thiol-containing auxiliary group, 1-phenyl-2-mercaptoethyl, was added to the alpha-amino group of one peptide segment to facilitate amide bond-forming ligation. The amine-linked 1-phenyl-2-mercaptoethyl auxiliary was stable to anhydrous hydrogen fluoride used to cleave and deprotect peptides after solid-phase peptide synthesis. Following native chemical ligation with a thioester-containing segment, the auxiliary group was cleanly removed from the newly formed amide bond by treatment with anhydrous hydrogen fluoride, yielding a full-length unmodified polypeptide product. The resulting polypeptide was reconstituted with heme and folded to form the functional protein molecule. Synthetic wild-type cyt b562 exhibited spectroscopic and electrochemical properties identical to the recombinant protein, whereas the engineered [SeMet(7)]cyt b562 analogue protein was spectroscopically and functionally distinct, with a reduction potential shifted by approximately 45 mV. The use of the 1-phenyl-2-mercaptoethyl removable auxiliary reported here will greatly expand the applicability of total protein synthesis by native chemical ligation of unprotected peptide segments.

A sensitive fluorescence monitor for the detection of activated Ras: total chemical synthesis of site-specifically labeled Ras binding domain of c-Raf1 immobilized on a surface.

BACKGROUND: The Ras.GDP-Ras.GTP cycle plays a central role in eukaryotic signaling cascades. Mutations in Ras which stabilize activated Ras.GTP lead to a continuous stimulation of downstream effectors and ultimately to cell proliferation. Ras mutants which increase the steady-state concentration of Ras.GTP are involved in about 30% of all human cancers. It is therefore of great interest to develop a biosensor which is sensitive to Ras.GTP but not to Ras.GDP. RESULTS: The Ras binding domain (RBD) of c-Raf1 was synthesized from two unprotected peptide segments by native chemical ligation. Two fluorescent amino acids with structures based on the nitrobenz-2-oxa-1,3-diazole and coumaryl chromophores were incorporated at a site which is close to the RBD/Ras.GTP binding surface. Additionally, a C-terminal tag consisting of His6 was introduced. The Kd values for binding of the site-specifically modified proteins to Ras.GTP are comparable to that of wild-type RBD. Immobilization of C-terminal His6 tag-modified fluorescent RBD onto Ni-NTA-coated surfaces allowed the detection of Ras.GTP in the 100 nM range. Likewise, Ras.GTP/Q61L (an oncogenic mutant of Ras with very low intrinsic GTP hydrolysis activity) can also be detected in this assay system. Ras.GDP does not bind to the immobilized RBD, thus allowing discrimination between inactive and activated Ras. CONCLUSIONS: The site-specific incorporation of a fluorescent group at a strategic position in a Ras effector protein allows the detection of activated Ras with high sensitivity. This example illustrates the fact that the chemical synthesis of proteins or protein domains makes it possible to incorporate any kind of natural or unnatural amino acid at the position of choice, thereby enabling the facile preparation of specific biosensors, enhanced detection systems for drug screening, or the synthesis of activated proteins, e.g. phosphorylated proteins involved in signaling pathways, as defined molecular species.

Chemical synthesis of lymphotactin: a glycosylated chemokine with a C-terminal mucin-like domain.

The synthesis of a 93-residue chemokine, lymphotactin, containing eight sites of O-linked glycosylation, was achieved using the technique of native chemical ligation. A single GalNAc residue was incorporated at each glycosylation site using standard Fmoc-chemistry to achieve the first total synthesis of a mucin-type glycoprotein. Using this approach quantities of homogeneous material were obtained for structural and functional analysis.

Chemical synthesis and spontaneous folding of a multidomain protein: anticoagulant microprotein S.

Because of recent high-yield native ligation techniques, chemical synthesis of larger multidomain bioactive proteins is rapidly coming within reach. Here we describe the total chemical synthesis of a designed "microprotein S," comprising the gamma-carboxyglutamic acid-rich module, the thrombin-sensitive module, and the first epidermal growth factor-like module of human plasma protein S (residues 1-116). Synthetic microprotein S expressed anticoagulant cofactor activity for activated protein C in the down-regulation of blood coagulation, and the anticoagulant activity of microprotein S was not neutralized by C4b-binding protein, a natural inhibitor of native protein S in plasma. The correct folding of this complex multidomain protein was enhanced compared with individual modules because the gamma-carboxyglutamic acid-rich module and the thrombin-sensitive module markedly facilitated correct folding of the first epidermal growth factor-like module compared with folding of the first epidermal growth factor-like module alone. These results demonstrate that total chemical synthesis of proteins offers an effective way to generate multidomain biologically active proteins.

Synthesis of native proteins by chemical ligation.

In just a few short years, the chemical ligation of unprotected peptide segments in aqueous solution has established itself as the most practical method for the total synthesis of native proteins. A wide range of proteins has been prepared. These synthetic molecules have led to the elucidation of gene function, to the discovery of novel biology, and to the determination of new three-dimensional protein structures by both NMR and X-ray crystallography. The facile access to novel analogs provided by chemical protein synthesis has led to original insights into the molecular basis of protein function in a number of systems. Chemical protein synthesis has also enabled the systematic development of proteins with enhanced potency and specificity as candidate therapeutic agents.

Sexual dimorphism in diverse metazoans is regulated by a novel class of intertwined zinc fingers.

Sex determination is regulated by diverse pathways. Although upstream signals vary, a cysteine-rich DNA-binding domain (the DM motif) is conserved within downstream transcription factors of Drosophila melanogaster (Doublesex) and Caenorhabditis elegans (MAB-3). Vertebrate DM genes have likewise been identified and, remarkably, are associated with human sex reversal (46, XY gonadal dysgenesis). Here we demonstrate that the structure of the Doublesex domain contains a novel zinc module and disordered tail. The module consists of intertwined CCHC and HCCC Zn(2+)-binding sites; the tail functions as a nascent recognition alpha-helix. Mutations in either Zn(2+)-binding site or tail can lead to an intersex phenotype. The motif binds in the DNA minor groove without sharp DNA bending. These molecular features, unusual among zinc fingers and zinc modules, underlie the organization of a Drosophila enhancer that integrates sex- and tissue-specific signals. The structure provides a foundation for analysis of DM mutations affecting sexual dimorphism and courtship behavior.

Deciphering the role of the electrostatic interactions involving Gly70 in eglin C by total chemical protein synthesis.

Eglin c from the leech Hirudo medicinalis is a potent protein inhibitor of many serine proteinases including chymotrypsin and subtilisins. Unlike most small protein inhibitors whose solvent-exposed enzyme-binding loop is stabilized primarily by disulfide bridges flanking the reactive-site peptide bond, eglin c possesses an enzyme-binding loop supported predominantly by extensive electrostatic/H-bonding interactions involving three Arg residues (Arg48, Arg51, and Arg53) projecting from the scaffold of the inhibitor. As an adjacent residue, the C-terminal Gly70 participates in these interactions via its alpha-carboxyl group interacting with the side chain of Arg51 and the main chain of Arg48. In addition, the amide NH group of Gly70 donates an H-bond to the carbonyl C=O groups of Arg48 and Arg51. To understand the structural and functional relevance of the electrostatic/H-bonding network, we chemically synthesized wild-type eglin c and three analogues in which Gly70 was either deleted or replaced by glycine amide (NH(2)CH(2)CONH(2)) or by alpha-hydroxylacetamide (HOCH(2)CONH(2)). NMR analysis indicated that the core structure of eglin c was maintained in the analogues, but that the binding loop was significantly perturbed. It was found that deletion or replacement of Gly70 destabilized eglin c by an average of 2.7 kcal/mol or 20 degrees C in melting temperature. As a result, these inhibitors become substrates for their target enzymes. Binding assays on these analogues with a catalytically incompetent subtilisin BPN' mutant indicated that loss or weakening of the interactions involving the carboxylate of Gly70 caused a decrease in binding by approximately 2 orders of magnitude. Notably, for all four synthetic inhibitors, the relative free energy changes (DeltaDeltaG) associated with protein destabilization are strongly correlated (slope = 0.94, r(2) = 0. 9996) with the DeltaDeltaG values derived from a decreased binding to the enzyme.

The chemokine receptor antagonist AOP-RANTES reduces monocyte infiltration in experimental glomerulonephritis.

UNLABELLED: The chemokine receptor antagonist AOP-RANTES reduces monocyte infiltration in experimental glomerulonephritis. BACKGROUND: This study was designed to evaluate the role of the novel chemokine receptor antagonist amino-oxypentane RANTES (AOP-RANTES), which blocks the binding of macrophage inflammatory protein-1alpha (MIP-1alpha), MIP-1beta, and RANTES to the chemokine receptor-5 (CCR-5) on the infiltration of monocytes in experimental glomerulonephritis. METHODS: Rats were treated twice daily with 12.5 microg AOP-RANTES following an induction of anti-rat-thymocyte antibody-mediated glomerulonephritis. The white blood cell count, glomerular monocyte infiltration, chemokine expression, and collagen type IV deposition were assessed. RESULTS: The induction of glomerulonephritis increased glomerular monocyte/macrophage (M/M) infiltration at 24 hours and at 5 days was still higher than in controls. AOP-RANTES prevented glomerular M/M infiltration at 24 hours and at 5 days. This was paralleled by reduced glomerular collagen type IV deposition as a fibrotic marker in nephritic animals. CONCLUSION: These data show that the CCR-5 chemokine receptor antagonist AOP-RANTES ameliorates M/M infiltration and improves glomerular pathology in experimental glomerulonephritis. The use of chemokine receptor antagonists may offer a new therapeutic option in inflammatory renal injuries.

Chemical protein synthesis.

Since the mid-1990s, chemical synthesis has emerged as a powerful technique for the study of structure/function relationships in proteins. During the review period, the applicability of chemical protein synthesis techniques has been significantly broadened by increases in the size of synthetically accessible proteins through two new techniques: solid-phase protein synthesis and expressed protein ligation. Also in the period under review, synthetic access to novel classes of proteins has been established, including metalloproteins with tuned properties and integral membrane proteins.

Engineering an unnatural Nalpha-anchored disulfide into BPTI by total chemical synthesis: structural and functional consequences.

A disulfide-engineered analogue of bovine pancreatic trypsin inhibitor (BPTI), ((N(alpha)-(CH2)2S-)Gly38)BPTI, has been prepared using a thioester-mediated auxiliary functional group chemical ligation of a N(alpha)-ethanethiol-containing peptide segment with a peptide-alphaCOSR segment. In this study, Nalpha-(ethanethiol)Gly38 replaces the native Cys38, providing the sulfhydryl group required for ligation and folding. Comparisons between ((Nalpha-(CH2)2SH)Gly38)BPTI, synthetic native BPTI and reference BPTI purchased from Sigma were made using mass spectroscopy, enzyme inhibitor association constant determination (K(a)) and 1H-nuclear magnetic resonance total correlated spectroscopy (1H-NMR TOCSY) measurements. The K(a) value for ((Nalpha-(CH2)2SH)Gly38)BPTI was approximately 20-fold lower than synthetic and reference BPTI, which was attributed to perturbations in the binding loop of the protein (near Cys14). This hypothesis was confirmed by two-dimensional (2D) 1H-NMR TOCSY experiments. The data reported here demonstrate that total chemical synthesis by auxiliary functional group chemical ligation is a practical method for the synthesis of a novel class of biologically active protein analogues containing additional functional groups linked to the protein backbone.

Total chemical synthesis of the integral membrane protein influenza A virus M2: role of its C-terminal domain in tetramer assembly.

The M2 protein from influenza A virus is a 97-residue homotetrameric membrane protein that functions as a proton channel. To determine the features required for the assembly of this protein into its native tetrameric state, the protein was prepared by total synthesis using native chemical ligation of unprotected peptide segments. Circular dichroism spectroscopy of synthetic M2 protein in dodecylphosphocholine (DPC) micelles indicated that approximately 40 residues were in an alpha-helical secondary structure. The tetramerization of the full-length protein was compared to that of a 25-residue transmembrane (TM) fragment. Analytical ultracentrifugation demonstrated that both the peptide and the full-length protein in DPC micelles existed in a monomer-tetramer equilibrium. Comparison of the association constants for the two sequences showed the free energy of tetramerization of the full-length protein was more favorable by approximately 7 kcal/mol. Partial proteolysis of DPC-solubilized M2 was used as a further probe of the structure of the full-length protein. A 15-20-residue segment C-terminal to the membrane-spanning region was found to be highly resistant to digestion by chymotrypsin and trypsin. This region, which we have modeled as an extension of the TM helices, may help to stabilize the tetrameric assembly.

Design, total chemical synthesis, and binding properties of a [Leu-91-N1-methyl-7-azaTrp]Ras-binding domain of c-Raf-1.

The Ras-binding domain (RBD) of c-Raf-1 has been synthesized chemically, taking advantage of the chemical ligation of two peptide fragments of the protein. This procedure allowed incorporation of an unnatural amino acid (N1-methyl-7-azatryptophan) at position 91 of RBD, producing a protein with fluorescent properties distinct from and distinguishable from those of proteins containing the natural fluorophore tryptophan. The resulting protein was shown to interact with Ras in a manner that was almost indistinguishable from that of unmodified RBD based on transient kinetic monitoring of the binding event. Modified RBD containing the L-isomer of the unnatural amino acid or its racemic D,L mixture appeared to interact identically with Ras. The approach demonstrates a general procedure for the introduction of unnatural amino acids that can be used for monitoring protein-protein interactions and for the introduction of an unnatural backbone structure at strategic positions.

Probing intermolecular backbone H-bonding in serine proteinase-protein inhibitor complexes.

BACKGROUND: Intermolecular backbone H-bonding (N-H.O=C) is a common occurrence at the interface of protein-protein complexes. For instance, the amide NH groups of most residues in the binding loop of eglin c, a potent serine proteinase inhibitor from the leech Hirudo medicinalis, are H-bonded to the carbonyl groups of residues in the target enzyme molecules such as chymotrypsin, elastase and subtilisins. We sought to understand the energetic significance of these highly conserved backbone-backbone H-bonds in the enzyme-inhibitor complexes. RESULTS: We synthesized an array of backbone-engineered ester analogs of eglin c using native chemical ligation to yield five inhibitor proteins each containing a single backbone ester bond from P3 to P2' (i.e. -CONH-to -COO-). The structure at the ligation site (P6-P5) is essentially unaltered as shown by a high-resolution analysis of the subtilisin-BPN'-eglin c complex. The free-energy changes (DeltaDeltaGNH-->O) associated with the binding of ester analogs at P3, P1 and P2' with bovine alpha-chymotrypsin, subtilisin Carlsberg and porcine pancreatic elastase range from 0-4.5 kcal/mol. Most markedly, the NH-->O substitution at P2 not only stabilizes the inhibitor but also enhances binding to the enzymes by as much as 500-fold. CONCLUSIONS: Backbone H-bond contributions are context dependent in the enzyme-eglin c complexes. The interplay of rigidity and adaptability of the binding loop of eglin c seems to play a prominent role in defining the binding action.

NMR structure of a minimized human agouti related protein prepared by total chemical synthesis.

The structure of the chemically synthesized C-terminal region of the human agouti related protein (AGRP) was determined by 2D 1H NMR. Referred to as minimized agouti related protein, MARP is a 46 residue polypeptide containing 10 Cys residues involved in five disulfide bonds that retains the biological activity of full length AGRP. AGRP is a mammalian signaling molecule, involved in weight homeostasis, that causes adult onset obesity when overexpressed in mice. AGRP was originally identified by homology to the agouti protein, another potent signaling molecule involved in obesity disorders in mice. While AGRP's exact mechanism of action is unknown, it has been identified as a competitive antagonist of melanocortin receptors 3 and 4 (MC3r, MC4r), and MC4r in particular is implicated in the hypothalamic control of feeding behavior. Full length agouti and AGRP are only 25% homologous, however, their active C-terminal regions are approximately 40% homologous, with nine out of the 10 Cys residues spatially conserved. Until now, 3D structures have not been available for either agouti, AGRP or their C-terminal regions. The NMR structure of MARP reported here can be characterized as three major loops, with four of the five disulfide bridges at the base of the structure. Though its fold is well defined, no canonical secondary structure is identified. While previously reported structural models of the C-terminal region of AGRP were attempted based on Cys homology between AGRP and certain toxin proteins, we find that Cys spacing is not sufficient to correctly determine the 3D fold of the molecule.

Characterization of the DNA binding properties of the bHLH domain of Deadpan to single and tandem sites.

The basic helix-loop-helix domain of the Drosophila transcription factor Deadpan (Dpn) was prepared by total chemical protein synthesis in order to characterize its DNA binding properties. Circular dichroism spectroscopy was used to correlate structural changes in Dpn with physiologically relevant monovalent (KCl) and divalent (MgCl2) cation concentrations. In addition, we have used electrophoretic mobility shift assay (EMSA) and fluorescence anisotropy methods to determine equilibrium dissociation constants for the interaction of Dpn with two biologically relevant promoters involved in neural development and sex determination pathways. In this study, we have optimized DNA binding conditions for Dpn, and we have found a markedly higher DNA binding affinity for Dpn than reported for other bHLH domain transcription factors. Dpn binds as a homodimer (Kd = 2.6 nM) to double-stranded oligonucleotides containing the binding site CACGCG. In addition, we found that Dpn bound with the same affinity to a single or tandem binding site, indicating no cooperativity between adjacent DNA-bound Dpn dimers. DNA binding was also monitored as a function of physiologically relevant KCl and MgCl2 concentrations, and we found that this activity was significantly different in the presence and absence of the nonspecific competitor poly(dI-dC). Moreover, Dpn displayed moderate sequence selectivity, exhibiting a 100-fold higher binding affinity for specific DNA than for poly(dI-dC). This study constitutes the first detailed biophysical characterization of the DNA binding properties of a bHLH protein.

The conserved SOCS box motif in suppressors of cytokine signaling binds to elongins B and C and may couple bound proteins to proteasomal degradation.

The suppressors of cytokine signaling (SOCS) family of proteins act as intracellular inhibitors of several cytokine signal transduction pathways. Their expression is induced by cytokine activation of the Janus kinase/signal transducer and activator of transcription (JAK/STAT) pathway and they act as a negative feedback loop by subsequently inhibiting the JAK/STAT pathway either by direct interaction with activated JAKs or with the receptors. These interactions are mediated at least in part by the SH2 domain of SOCS proteins but these proteins also contain a highly conserved C-terminal homology domain termed the SOCS box. Here we show that the SOCS box mediates interactions with elongins B and C, which in turn may couple SOCS proteins and their substrates to the proteasomal protein degradation pathway. Analogous to the family of F-box-containing proteins, it appears that the SOCS proteins may act as adaptor molecules that target activated cell signaling proteins to the protein degradation pathway.

Total chemical synthesis and high-resolution crystal structure of the potent anti-HIV protein AOP-RANTES.

BACKGROUND: RANTES is a CC-type chemokine protein that acts as a chemoattractant for several kinds of leukocytes, playing an important pro-inflammatory role. Entry of human immunodeficiency virus-1 (HIV-1) into cells depends on the chemokine receptor CCR5. RANTES binds CCR5 and inhibits HIV-1 entry into peripheral blood cells. Interaction with chemokine receptors involves a distinct set of residues at the amino terminus of RANTES. This finding was utilized in the development of a chemically modified aminooxypentane derivative of RANTES, AOP-RANTES, that was originally produced from the recombinant protein using semisynthetic methods. RESULTS: AOP-RANTES has been produced by a novel total chemical synthesis that provides efficient, direct access to large amounts of this anti-HIV protein analog. The crystal structure of chemically synthesized AOP-RANTES has been solved and refined at 1.6 A resolution. The protein is a dimer, with the amino-terminal pentane oxime moiety clearly defined. CONCLUSIONS: Total chemical synthesis of AOP-RANTES provides a convenient method of producing the multi-milligram quantities of this protein needed to investigate the molecular basis of receptor binding and antiviral activity. This work provides the first truly high-resolution structure of a RANTES protein, although the structure of RANTES was known from previous nuclear magnetic resonance (NMR) determinations.

Characterization of Agouti-related protein binding to melanocortin receptors.

Agouti-related protein (AGRP) is a naturally occurring antagonist of melanocortin action that is thought to play an important role in the hypothalamic control of feeding behavior. The exact mechanism of AGRP and Agouti protein action has been difficult to examine, in part because of difficulties in producing homogeneous forms of these molecules that can be used for direct binding assays. In this report we describe the application of chemical protein synthesis to the construction of two novel AGRP variants. Examination of the biological activity of the AGRP variants demonstrates that a truncated variant, human AGRP(87-132), a 46-amino acid variant based on the carboxyl-terminal cysteine-rich domain of AGRP, is equipotent to an 111-amino acid variant, mouse [Leu127Pro]AGRP (mature AGRP minus its signal sequence), in its ability to dose dependently inhibit alpha-MSH-generated cAMP generation at the cloned melanocortin receptors. Furthermore, deletion of the amino-terminal portion of the full-length variant did not alter the MCR subtype specificity of AGRP(87-132). Finally, iodination of human AGRP(87-132) provided a useful reagent with which the binding properties of AGRP could be analyzed. In both conventional and photoemulsion binding studies [125I]AGRP(87-132) was observed only to bind to cells expressing melanocortin receptors MC3R, MC4R, and MC5R. These results demonstrate that the residues critical for receptor binding, alpha-MSH inhibition, and melanocortin receptor subtype specificity are all located in the carboxyl terminus of the molecule. Because [Nle4, D-Phe7] (NDP)-MSH displaces the binding of [125I]AGRP(87-132) to MCRs and AGRP(87-132) displaces the binding of [125I]NDP-MSH, we conclude that these molecules bind in a competitive fashion to melanocortin receptors.

Chemical protein synthesis.

Chemical protein synthesis is a field in transition. Previously, the synthetic accomplishment itself was the major focus of work in this field. Increasingly, chemical synthesis is now being applied to understanding how biological function originates in the structure of the protein molecule. A novel approach--'chemical ligation', which is the chemoselective reaction of unprotected peptide segments in water at pH7--has made the total synthesis of proteins a robust and practical route to the study of structure-function relationships. For certain protein families, chemical protein synthesis is the most effective way to obtain functional proteins direct from genome sequence data.