Photophysics and biological applications of the environment-sensitive fluorophore 6-N,N-dimethylamino-2,3-naphthalimide.

We have synthesized a new environment-sensitive fluorophore, 6-N,N-dimethylamino-2,3-naphthalimide (6DMN). This chromophore exhibits valuable fluorescent properties as a biological probe with emission in the 500-600 nm range and a marked response to changes in the environment polarity. The 6DMN fluorescence is red-shifted in polar protic environments, with the maximum emission intensity shifting more than 100 nm from 491 nm in toluene to 592 nm in water. Additionally, the fluorescence quantum yield decreases more than 100-fold from chloroform (Phi = 0.225) to water (Phi = 0.002). The scope and applications of the 6DMN probe are expanded with the synthesis of an Fmoc-protected amino acid derivative (5), which contains the fluorophore. This unnatural amino acid has been introduced into several peptides, demonstrating that it can be manipulated under standard solid-phase peptide synthesis conditions. Peptides incorporating the new residue can be implemented for monitoring protein-protein interactions as exemplified in studies with Src homology 2 (SH2) phosphotyrosine binding domains. The designed peptides exhibit a significant increase in the quantum yield of the long wavelength fluorescence emission band (596 nm) upon binding to selected SH2 domains (e.g., Crk SH2, Abl SH2, and PI3K SH2). The peptides can be used as ratiometric sensors, since the short wavelength band (460 nm) was found almost invariable throughout the titrations.

Substrate specificity of the glycosyl donor for oligosaccharyl transferase.

Oligosaccharyl transferase (OT) catalyzes the co-translational transfer of a dolichol-linked tetradecasaccharide (Dol-PP-GlcNAc(2)Man(9)Glc(3), 1a) to an asparagine side chain of a nascent polypeptide inside the lumen of the endoplasmic reticulum (ER). The glycosyl acceptor requires an Asn-Xaa-Thr/Ser sequon, where Xaa can be any natural amino acid except proline, for N-linked glycosylation to occur. To address the substrate specificity of the glycosyl donor, three unnatural dolichol-linked disaccharide analogues (Dol-PP-GlcNTFA-GlcNAc 1c, Dol-PP-2DFGlc-GlcNAc 1d, and Dol-PP-GlcNAc-Glc 1e) were synthesized and evaluated as substrates or inhibitors for OT from yeast. The synthetic analogue Dol-PP-GlcNAc-Glc 1e, with substitution in the distal sugar, was found to be a substrate (K(m)(app)() = 26 microM) for OT. On the other hand, the analogues Dol-PP-GlcNTFA-GlcNAc 1c (K(i) = 154 microM) and Dol-PP-2DFGlc-GlcNAc 1d (K(i) = 252 microM), with variations in the proximal sugar, were inhibitors for OT. The dolichol-linked monosaccharide Dol-PP-GlcNAc 3 was found to be the minimum unit for glycosylation to occur.

Oligomerization of uniquely folded mini-protein motifs: development of a homotrimeric betabetaalpha peptide.

The discovery of a discretely folded homotrimeric betabetaalpha motif (BBAT1) was recently reported (J. Am. Chem. Soc. 2001, 123, 1002-1003). Herein the design, synthesis, and analysis of a small library of peptides which led to the isolation of BBAT1 is described. betabetaalpha peptides based on the monomeric sequence of BBA5 (Folding Des. 1998, 120, 95-103) were synthesized to include the anthranilic acid/nitrotyrosine fluorescence quenching pair to rapidly detect interpeptide association. In the first generation of peptides synthesized, truncations in the loop region connecting the beta-hairpin to the alpha-helix revealed that a two-residue deletion in the loop promoted an interpeptide association as detected by fluorescence quenching. An additional library of 22 loop-truncated betabetaalpha peptides was subsequently synthesized to include a variety of sequence mutations in an effort to enhance the observed peptide-peptide binding. From the fluorescence quenching screen, peptide B2 was found to possess the strongest fluorescence-quenching response, indicative of a strong peptide-peptide association. Due the poor solubility of peptide B2, the S-methylated cysteine at position 9 in the loop was substituted with a glycine to generate peptide BBAT1 which possessed greatly improved water solubility and formed discrete trimers. The successful design of this oligomeric betabetaalpha structure will likely aid the design of more complex alpha-beta superstructures and further our understanding of the factors controlling protein-protein interactions at alpha-beta protein interfaces.

Design of a discretely folded mini-protein motif with predominantly beta-structure.

Here we report the creation of a predominantly beta-structured mini-protein motif. The design target is based on the naturally occurring toxin hand (TH) motifs that are composed of four disulfide bonds and three loops that form a 'hand'. Analysis and subsequent modification of several generations of mini-proteins produced the final 29-residue mini-protein. The structured motif of this new mini-protein provides insight into the compensatory changes that result in the formation of a tightly packed hydrophobic core in a small, globular beta-structure motif. Additionally, this mini-motif represents a new, distinct surface topology for protein design and a valuable, yet compact, model system for the study of beta-sheet structure in water.

Substrate specificity of N-acetylglucosaminyl(diphosphodolichol) N-acetylglucosaminyl transferase, a key enzyme in the dolichol pathway.

N-Acetylglucosaminyl(diphosphodolichol) N-acetylglucosaminyl transferase, also known as Enzyme II, is the second enzyme in the dolichol pathway. This pathway is responsible for the assembly of the tetradecasaccharide pyrophosphate dolichol, which is the substrate for oligosaccharyl transferase. In order to study the specificity of Enzyme II, four unnatural dolichol diphosphate monosaccharides were synthesized, with the C-2 acetamido group in the natural substrate Dol-PP-GlcNAc 1a replaced by fluoro, ethoxy, trifluoroacetamido, and amino functionalities. These analogues 1b-e were evaluated as glycosyl acceptors for Enzyme II, which catalyzes the formation of dolichol diphosphate chitobiose (Dol-PP-GlcNAc(2)) from UDP-GlcNAc and Dol-PP-GlcNAc. Enzyme II from pig liver was found to be highly specific for its glycosyl acceptor and the acetamido group shown to be a key functional determinant for this glycosylation reaction.

Probing the extended binding determinants of oligosaccharyl transferase with synthetic inhibitors of asparagine-linked glycosylation.

Protein glycosylation is associated with many critical biological processes. In connection with studies on the mechanism of asparagine-linked glycosylation by the enzyme oligosaccharyl transferase, we have prepared peptide inhibitors that interact with the enzyme at nanomolar concentrations. Herein we describe efforts directed toward improving the binding properties of these inhibitors.

Effect of N-linked glycosylation on glycopeptide and glycoprotein structure.

Asparagine-linked glycosylation is an enzyme-catalyzed, co-translational protein modification reaction that has the capacity to influence either the protein folding process or the stability of the native glycoprotein conjugate. Advances in both glycoconjugate chemical synthesis and glycoprotein expression methods have increased the availability of these once elusive biopolymers. The application of spectroscopic methods to these proteins has begun to illuminate the various ways in which the saccharide affects the structure, function and stability of the proteins.

Uniquely folded mini-protein motifs.

Mini-proteins containing fewer than 40 amino acids provide simple model systems for studying protein folding and stability as well as serving as scaffolds for the rational design of new functional motifs. This article reviews current progress on the design and characterization of discretely folded mini-protein motifs.

Modulating pyridoxamine-mediated transamination through a betabeta alpha motif peptide scaffold.

A pyridoxamine coenzyme amino acid chimera (Pam) was incorporated into a designed betabeta alpha motif peptide to explore the ability of a small synthetic peptide scaffold to influence coenzyme mediated transamination. Structural characterization of this peptide by CD and NMR spectroscopy suggested that the pyridoxamine containing residue was accommodated into the sheet region of the motif without gross structural perturbations. To investigate the ability of the peptide architecture to influence the amount and distribution of transamination product in the conversion of pyruvic acid to alanine, a family of 18 related peptides, CBP01-CBP18, was rapidly synthesized and purified in parallel. These peptides were designed to generate different peptide environments for the pyridoxamine functionality within the context of the structured betabeta alpha peptide motif. Studies of peptide-mediated transamination revealed clear trends in stereospecific production of L-alanine as a function of substitutions at positions five and seven of the motif. Furthermore, new trends favoring the other enantiomeric product resulted from the addition of copper(II) ion, a known chelator of the transamination reaction intermediates. In the presence of copper(II) ion the amount of alanine product generated was increased by up to 32-fold relative to a pyridoxamine model compound in the presence of copper(II) ion. These functional results, accompanied by further CD and NMR spectroscopic analysis of CBP14, one of the CBP family of peptides, suggest that small synthetic betabeta alpha motif peptides can be used to influence the functional properties of coenzymes.

Study of the stability and unfolding mechanism of BBA1 by molecular dynamics simulations at different temperatures.

BBA1 is a designed protein that has only 23 residues. It is the smallest protein without disulfide bridges that has a well-defined tertiary structure in solution. We have performed unfolding molecular dynamics simulations on BBA1 and some of its mutants at 300, 330, 360, and 400 K to study their kinetic stability as well as the unfolding mechanism of BBA1. It was shown that the unfolding simulations can provide insights into the forces that stabilize the protein. Packing, hydrophobic interactions, and a salt bridge between Asp12 and Lys16 were found to be important to the protein's stability. The unfolding of BBA1 goes through two major steps: (1) disruption of the hydrophobic core and (2) unfolding of the helix. The beta-hairpin remains stable in the unfolding because of the high stability of the type II' turn connecting the two beta-strands.

A potent oligosaccharyl transferase inhibitor that crosses the intracellular endoplasmic reticulum membrane.

Recent work has resulted in the development of potent inhibitors of oligosaccharyl transferase (OT), the enzyme that catalyzes the cotranslational glycosylation of asparagine [Hendrickson, T. L., Spencer, J. R., Kato, M., and Imperiali, B. (1996) J. Am. Chem. Soc. 118, 7636-7637; Kellenberger, C., Hendrickson, T. L., and Imperiali, B. (1997) Biochemistry 36, 12554-12559]. However, no specific OT inhibitors that function in the cellular environment have yet been reported. The peptide cyclo(hex-Amb-Cys)-Thr-Val-Thr-Nph-NH2 was previously shown to exhibit nanomolar inhibition (Ki = 37 nM) through slow tight binding kinetics [Hendrickson, T. L., Spencer, J. R., Kato, M., and Imperiali, B. (1996) J. Am. Chem. Soc. 118, 7636-7637]. Included herein is the redesign of this prototype inhibitor for achieving both passive and active translocation into model membrane systems representing the endoplasmic reticulum (ER). The strategy for passive transport involved the incorporation of a membrane permeable import function previously shown to carry various peptides across the outer as well as the interior cellular membranes [Rojas, M., Donahue, J. P., Tan, Z., and Lin, Y.-Z. (1998) Nat. Biotechnol. 16, 370-375]. Assessment of function in intact ER membranes revealed that the inhibitor targeted toward passive diffusion demonstrated concentration-dependent inhibition of two different glycosylation substrates. Thus, this modified inhibitor achieved potent inhibition of glycosylation after being successfully transported through the ER membrane. In the active translocation approach, the lead OT inhibitor and a corresponding substrate were redesigned to include features recognized by the transporter associated with antigen processing (TAP). This protein translocates peptides into the lumen of the ER [Heemels, M.-T., Schumacher, T. N. M., Wonigeit, K., and Ploegh, H. L. (1993) Science 262, 2059-2063]. However, although acceptance of the cyclized substrate by the TAP receptor was demonstrated via efficient transport and glycosylation, the modified inhibitor was not translocated by TAP machinery, and therefore, active translocation was achieved for the modified substrate only. Both of these ER transport methods afforded redesigned OT inhibitors that retained their inhibitor properties in vitro, regardless of the extensions to the carboxy-terminus of the root inhibitor. The above family of redesigned inhibitors provides a template for generating a transcellular pathway and represents the first step toward OT inhibition in intact cells.

Design strategies for the construction of independently folded polypeptide motifs.

In this paper we present a redesign strategy for the development of uniquely folded polypeptide motifs of less than 40 residues. These mini proteins are based on natural target domains, including the zinc finger domains (BBA motif)* and the disulfide-rich snake and scorpion toxins (BBB motif). These motifs are designed to act as the molecular framework for the construction of novel functional polypeptides. We will explore the structural determinants of the folded BBA motif, inspired by the zinc finger peptides, in relation to the redesign process.

A molecular basis for glycosylation-induced conformational switching.

BACKGROUND: Asparagine-linked glycosylation has the capacity to greatly influence the structure and function of glycoproteins. In most cases, however, it is unclear specifically how the carbohydrate moiety interacts with the protein to influence its conformation. RESULTS: A series of glycosylation based on the critical A285 glycosylation site of the hemagglutinin glycoprotein from influenza from influenza virus was used as a model system to study the effects of asparagine-linked glycosylation. Derivatization of this peptide with a family of short carbohydrates reveals that subtle changes in the structure of the carbohydrate have a dramatic impact on peptide conformation. Modification of the hemagglutinin glycopeptide with a truncated version of the native carbohydrate induces a beta-turn structure similar to the structure found in the native protein. Replacement of the C2 and C2' N-acetyl groups of the carbohydrates with hydroxyl moieties results in a less well-ordered peptide conformation. CONCLUSIONS: It is likely that the N-acetyl groups of the carbohydrates have a critical role in promoting the more compact beta-turn conformation through steric interactions with the peptide. This study has demonstrated that relatively small changes in carbohydrate composition can have dramatic ramifications on glycopeptide conformation.

Substrate assistance in the mechanism of family 18 chitinases: theoretical studies of potential intermediates and inhibitors.

Based on first principles and molecular mechanics calculations, we conclude that the mechanism of hevamine (a family 18 chitinase) involves an oxazoline ion intermediate stabilized by the neighboring C2' acetamido group. In this intermediate, the acetamido carbonyl oxygen atom forms a covalent bond to C1' of N-acetyl-glucosamine and has a transferred positive charge from the pyranose ring onto the acetamido nitrogen atom, leading to an anchimeric stabilization of 38.1 kcal/mol when docked with hevamine. This double displacement mechanism involving an oxazoline intermediate distinguishes the family 18 chitinase (which have one acidic residue near the active site) from family 19 chitinase and from hen egg-white lysozyme, which have two acidic residues near the active site. The structural and electronic properties of the oxazoline intermediate are similar to the known chitinase inhibitor allosamidin, suggesting that allosamidins act as transition state analogs of an oxazoline intermediate. Structural and electronic features of the oxazoline ion likely to be important in the design of new chitinase inhibitors are discussed.

Design and NMR analyses of compact, independently folded BBA motifs.

BACKGROUND: Small folded polypeptide motifs represented highly simplified systems for theoretical and experimental studies on protein structure and folding. We have recently reported the design and characterization of a metal-ion-independent 23-residue peptide with a beta beta alpha structure (BBA1), based on the zinc finger domains. To understand better the determinants of structure for this small peptide, we investigated the conformational role of the synthetic residue 3-(1, 10-phenanthrol-2-yl)-L-alanine (Fen) in BBA1. RESULTS: NMR analysis revealed that replacing the Fen residue of peptide BBA1 by either of the natural amino acids tyrosine (BBA2) or tryptophan (BBA3) resulted in conformational flexibility in the sheet and loop regions of the structure. This conformational ambiguity was eliminated in peptides BBA4 and BBA5 by including charged residues on the exterior of the beta hairpin designed to both select against the undesired fold and stabilize the desired structure. The evaluation of two additional peptides (BBA6 and BBA7) provided further insight into the specific involvement of the surface polar residues in the creation of well-defined structure in BBA4 and BBA5. The sequences of BBA5, BBA6 and BBA7 include only one non-standard amino acid (D-proline), which constrains a critical engineered type II' turn. CONCLUSIONS: Manipulation of residues on the exterior of small beta beta alpha motifs has led to the design of 23-residue polypeptides that adopt a defined tertiary structure in the absence of synthetic amino acids, increasing the availability and expanding the potential uses of the BBA motif. The importance of negative design concepts to the creation of structured polypeptides is also highlighted.