Solid-Phase Total Synthesis of Dehydrotryptophan-Bearing Cyclic Peptides Tunicyclin B, Sclerotide A, CDA3a, and CDA4a using a Protected ß-Hydroxytryptophan Building Block.

A new approach to the synthesis of Z-dehydrotryptophan (ΔTrp) peptides is described. This approach uses Fmoc-ß-HOTrp(Boc)(TBS)-OH as a building block, which is readily prepared in high yield and incorporated into peptides using solid-phase Fmoc chemistry. The tert-butyldimethylsilyl-protected indolic alcohol is eliminated during global deprotection/resin cleavage to give ΔTrp peptides exclusively as the thermodynamically favored Z isomer. This approach was applied to the solid-phase synthesis of tunicyclin B, sclerotide A, CDA3a, and CDA4a.

Synthesis of redox-active fluorinated 5-hydroxytryptophans as molecular reporters for biological electron transfer.

Fluorinated 5-hydroxytryptophans (Fn-5HOWs) were synthesized in gram scale quantities and incorporated into a ß-hairpin peptide and the protein azurin. The redox-active Fn-5HOWs exhibit unique radical spectroscopic signatures that expand the function of as probes for biological electron transfer.

Synthesis, characterization, theoretical studies and biological (antioxidant, anticancer, toxicity and neuroprotective) determinations of a copper(II) complex with 5-hydroxytryptophan.

5-Hydroxy-L-tryptophan (5-HTP) is a serotonin pathway metabolite of L-tryptophan in the brain. In the knowledge that the biological properties of some compounds can be modified upon metal complexation, a new solid metal complex, [Cu(5-hydroxytryptophan)2].H2O (Cu5HTP), has been synthesized and characterized to analyze the modification of some biological properties. The conformational investigations (optimized in gas phase at B3LYP/6-311G** theory level) suggest the coexistence of two conformers of Cu5HTP with cis- and trans- arrangements of the amino acids in the equatorial plane. The trans- Cu5HTP1 complex is the most stable conformer. The complexation led to an enhancement of the antioxidant properties of the ligand. The metal complex also improved the anticancer behavior of the ligand (tested in cancer cell lines derived from human lung (A549), cervix (HeLa) and colon (HCT-116)). It did not show toxicity against either the non-malignant human lung fibroblast (MRC-5) cell line or Artemia salina and did not behave as mutagenic agent (Ames test). Cellular reactive oxygen species production may be one of the possible mechanisms of action. Besides, the metal complex exerted neuroprotective action on cortical neurons from embryonic 18 days rats exposed to glutamate.

PHOXI: A High Quantum Yield, Solvent-Sensitive Blue Fluorescent 5-Hydroxytryptophan Derivative Synthesized within Ten Minutes under Aqueous, Ambient Conditions.

Multiple tryptophan (Trp) proteins are not amenable to fluorescence study because individual residue emission is not resolvable. Biosynthetic incorporation of an indole analogue such as 5-hydroxyindole has not provided sufficient spectroscopic resolution because of low quantum yield and small emission shift. Here, 5-hydroxyindole is used as the starting framework for building a blue emitting fluorophore of high quantum yield, 2-phenyl-6H-oxazolo[4,5-e]indole (PHOXI). This is a three reagent reaction completed in 10 min under ambient conditions in borate buffer at pH 8. Reaction conditions have been optimized using 5-hydroxyindole. Derivatization is demonstrated on tryptophanyl 5-hydroxytryptophan (5-HTP) and a stable ß-hairpin "zipper" peptide with four tryptophan residues, TrpZip2, where Trp 4 has been replaced with 5-HTP, W4 → 5-HTP. Reaction optimization yields a PHOXI fluorophore that is essentially free of byproducts. Reaction specificity is demonstrated by the lack of reaction with N-acetyl-cysteine and amyloid ß-40, a peptide containing all amino acids except tryptophan, proline, and cysteine and lacking 5-HTP. Fluorescence study of PHOXI-derivatized 5-hydroxyindole in different solvents reveals the sensitivity of PHOXI to solvent polarity with a remarkable 87 nm red-shift in water relative to cyclohexane while maintaining high quantum yield. Thus, PHOXI joins the ranks of solvatochromic fluorophores such as PRODAN. Surprisingly, DFT calculations reveal coplanarity of the oxazolo/indole extended ring system and the phenyl substituent for both the HOMO and LUMO orbitals. Despite the crowded environment of three additional Trps in TrpZip2, CD spectroscopy shows that the TrpZip2 ß-hairpin structure is partially retained upon PHOXI incorporation. In an environment of smaller residues, PHOXI incorporation can be less disruptive of protein secondary structure, especially at molecular interfaces and other environments where there is typically less steric hindrance.

Synthesis of fully protected, reverse N-prenylated (2S,3R)-3-hydroxytryptophan, a unique building block of the cyclomarins.

Reverse N-prenylated 3-hydroxytryptophan, the rather exotic amino acid of the cyclomarins, is obtained in enantio- and diastereomerically pure and fully protected form by a combination of a highly stereoselective addition of a zincated indole toward protected serinal and subsequent palladium-catalyzed N-prenylation.

Tissue immunoassay for 19F-tagged 5-hydroxytryptophan.

A new tool for magnetic resonance, L-6-heptafluorobutyryl-5-hydroxytryptophan, was synthesized and investigated using an antibody to perfluoroalkyl moieties developed previously. To be useful as an imaging agent, the compound must cross the blood brain barrier and then be concentrated in vesicles in serotonergic neurons in order to accumulate in sufficient quantity for in vivo detection to be possible. The novel imaging compound was administered in ova to domestic chicks (Gallus domestics) to investigate the bioavailability and uptake dynamics of the compound in this model organism. Typical immunoassay methods were ineffective, so a new technique was developed which binds amines and amino acids to the walls of acid-functionalized cuvettes. The first study established the presence of higher quantities of the tags in neural and liver tissue than in heart tissue. A second study investigated regional differences, with the midbrain containing more tagged compounds than the frontal lobe sample, and the frontal lobe sample containing more than the occipital or cerebellum samples. These studies demonstrate that the compound follows the pathway of endogenous serotonin. A third study investigated uptake dynamics of the novel compound. Maximum concentration of the tagged molecule in the brain was achieved three days after injecting Incubation Day 14 eggs, suggesting that it bioaccumulates in vivo. This new immunoassay technique used to detect the novel compound in tissue samples demonstrated good repeatability.

Development of an automated synthesis apparatus for L-[3-11C] labeled aromatic amino acids.

We have developed an automated synthesis apparatus for L-[3-11C]-labeled aromatic amino acids by improved multi-enzymatic reactions. Use of a specially designed reaction vessel and of CH2Cl2 as a solvent has greatly simplified the overall operation, proving to be suitable for automated synthesis, and also has given better yields and higher specific activities than formerly reported values.

Enantiospecific syntheses of alpha-(fluoromethyl)tryptophan analogues: interactions with tryptophan hydroxylase and aromatic L-amino acid decarboxylase.

alpha-Fluoromethyl amino acids are enzyme-activated irreversible inhibitors of amino acid decarboxylases. Aromatic L-amino acid decarboxylase (AADC) is the enzyme responsible for the final step in the biosynthesis of both dopamine and serotonin via decarboxylation of L-dopa and 5-hydroxy-L-tryptophan, respectively. Our goal is to utilize antagonists of the serotonin-producing enzymes (tryptophan hydroxylase and AADC) as the basis for a chemotherapeutic approach to the treatment of carcinoid tumors, a rare tumor type characterized by the overproduction of serotonin. We report here an enantiospecific synthesis of alpha(S)-(fluoromethyl)tryptophan [(S)-11a] and alpha(S)-(fluoromethyl)-5-hydroxytryptophan [(S)-11b], as well as the (R)-enantiomers, based upon recent methodology involving the face-selective alkylation of cyclic tryptophan tautomers. Our synthetic route provided both enantiomers of 11a and 11b with greater than 97% enantiomeric purity based upon evaluation of the NMR spectra of their Mosher's acid derivatives. (S)-11a was evaluated as a substrate for P815 tryptophan hydroxylase and determined to have an apparent Km of 4.31 +/- 1.07 mM, essentially half the value previously reported for the racemic mixture of 11a with rat brain stem tryptophan hydroxylase. (R)-11a was not a substrate for P815 tryptophan hydroxylase. (S)-11b was evaluated as an enzyme-activated irreversible inhibitor of murine liver AADC and determined to have a KI of 24.3 +/- 3.01 microM and a k2 of 2.26 +/- 0.44 min-1. (R)-11b was not an inhibitor of murine liver AADC.

Synthesis and biological properties of alpha-mono- and alpha-difluoromethyl derivatives of tryptophan and 5-hydroxytryptophan.

The syntheses of alpha-mono- and alpha-difluoromethyl derivatives of tryptophan and 5-hydroxytryptophan are described. In an attempt to selectively regulate serotonin synthesis, alpha-(mono- and difluoromethyl)tryptophan were tested in vivo as precursors (or prodrugs) of their 5-hydroxy analogues. Although alpha-(mono- and difluoromethyl)-5-hydroxytryptophans are potent irreversible inhibitors of aromatic amino acid decarboxylase (equipotent to alpha-difluoromethyl-Dopa), only alpha-(monofluoromethyl)tryptophan affects the level of serotonin in vivo (small decrease), alpha-(difluoromethyl)tryptophan being a very poor substrate of the activating (or helper) enzyme, tryptophan hydroxylase.

Analgesic properties of a systemically-administered synthetic dipeptide of 5-hydroxytryptophan.

Synthetic peptides of 5-hydroxytryptophan (5-HTP), including N-acetyl-5-HTP-5-HTP amide (5-HTP-ACETYL-DP), specifically inhibit the binding of serotonin to serotonin binding protein. 5-HTP-ACETYL-DP also produces a long-lasting, opiate-sensitive analgesia following central, but not systemic administration. The present study evaluated an apolar derivative of 5-HTP dipeptide, N-hexanoyl-5-HTP-5-HTP amide (5-HTP-HEX-DP), for its analgesic properties in rats following systemic administration. 5-HTP-HEX-DP (5-50 mg/kg) significantly increased jump thresholds in a dose-dependent manner with peak analgesia occurring at 2.5 hr after injection, and lasting up to 5 hr. In the tail-flick assay, 5-HTP-HEX-DP (20 mg/kg) produced a significant antinociceptive effect at 1 hr post-injection using both high and low intensity levels of radiant heat. While 5-HTP-HEX-DP and morphine each elicited analgesia following acute administration, chronic (14 days) incremental dosing with 5-HTP-HEX-DP or morphine resulted in persistent analgesia in 5-HTP-HEX-DP-treated animals, and a loss of analgesia in morphine-treated rats. Thus, significant tolerance to morphine, but not 5-HTP-HEX-DP analgesia developed using this protocol. Hence, 5-HTP-HEX-DP is a systemically-active analgesic which fails to develop tolerance when administered daily over 14 days.

Oxidation of tryptophan to oxindolylalanine by dimethyl sulfoxide-hydrochloric acid. Selective modification of tryptophan containing peptides.

Tryptophan is readily oxidized to oxindolylalanine (2-hydroxytryptophan) in good yield on treatment in acetic acid solution with a mixture of dimethyl sulfoxide (DMSO) and concentrated aqueous HCl at room temperature. Other sulfoxides can be used in combination with HCl; for example, methionine sulfoxide reacts with an equimolar amount of tryptophan to give high yields of methionine and oxindolylalanine. Methionine and cysteine are quantitatively oxidized by DMSO/HCl to methionine sulfoxide and cystine, respectively. The tryptophan containing peptides LRF (luteinizing hormone-releasing factor), somatostatin, valine-gramicidin A and ACTH 1-24 were each treated with the DMSO/HCl reagent in acetic acid solution and the corresponding oxindolylalanine-derivatives isolated in over 90% yield after chromatography. The identity and purity of the derivatives were established on the basis of ultraviolet spectral characteristics and quantitative amino acid analysis of the oxindolylalanine content of acid hydrolyzates of the oxidized peptides with 3N-p-toluenesulfonic acid at 110 degrees for 24 h. The results indicate that modification of tryptophan peptides with DMSO/HCl provides a useful procedure, which seems superior to previously used reagents. In addition, the method could be well applied to other indoles of biological and pharmacological interest.