Alanine scan reveals modifiable residues in teixobactin.

An alanine scan of Lys10-teixobactin reveals that a cationic residue at position 10 is not necessary for antibiotic activity and that position 3 tolerates substitution without loss of activity. An unexpected correlation between poor aqueous solubility and better antibiotic activity of the teixobactin analogues is observed.

X-ray crystallographic structure of a teixobactin analogue reveals key interactions of the teixobactin pharmacophore.

The X-ray crystallographic structure of a truncated teixobactin analogue reveals hydrogen-bonding and hydrophobic interactions and a cavity that binds a chloride anion. Minimum inhibitory concentration (MIC) assays against Gram-positive bacteria correlate the observed structure with antibiotic activity.

A triply templated artificial beta-sheet.

This paper describes the design, synthesis, and structural evaluation of a compound (4) comprising three molecular templates and a peptide strand that mimics a three-stranded protein beta-sheet. Two of the templates mimic the hydrogen-bonding functionality of peptide beta-strands and serve as the top and bottom strands by embracing the peptide strand, which is located in the middle of the sheet. The remaining template holds the three strands next to each other. The synthesis of artificial beta-sheet 4 begins with the bottom template and involves the sequential addition of the middle and top strands. (1)H NMR chemical shift and NOE studies establish that this compound folds to adopt a hydrogen-bonded beta-sheetlike structure in CDCl(3) solution. Chemical shift studies indicate that triply stranded artificial beta-sheet 4 is more tightly folded than its smaller doubly stranded homologue, artificial beta-sheet 1.

Novel RNA catalysts for the Michael reaction.

BACKGROUND: In vitro selected ribozymes with nucleotide synthase, peptide and carbon-carbon bond forming activity provide insight into possible scenarios on how chemical transformations may have been catalyzed before protein enzymes had evolved. Metabolic pathways based on ribozymes may have existed at an early stage of evolution. RESULTS: We have isolated a novel ribozyme that mediates Michael-adduct formation at a Michael-acceptor substrate, similar to the rate-limiting step of the mechanistic sequence of thymidylate synthase. The kinetic characterization of this catalyst revealed a rate enhancement by a factor of approximately 10(5). The ribozyme shows substrate specificity and can act as an intermolecular catalyst which transfers the Michael-donor substrate onto an external 20-mer RNA oligonucleotide containing the Michael-acceptor system. CONCLUSION: The ribozyme described here is the first example of a catalytic RNA with Michael-adduct forming activity which represents a key mechanistic step in metabolic pathways and other biochemical reactions. Therefore, previously unforeseen RNA-evolution pathways can be considered, for example the formation of dTMP from dUMP. The substrate specificity of this ribozyme may also render it useful in organic syntheses.

Synthesis, incorporation efficiency, and stability of disulfide bridged functional groups at RNA 5'-ends.

Modified guanosine monophosphates have been employed to introduce various functional groups onto RNA 5'-ends. Applications of modified RNA 5'-ends include the generation of functionalized RNA libraries for in vitro selection of catalytic RNAs, the attachment of photoaffinity-tags for mapping RNA-protein interactions or active sites in catalytic RNAs, or the nonradioactive labeling of RNA molecules with fluorescent groups. While in these and in similar applications a stable linkage is desired, in selection experiments for generating novel catalytic RNAs it is often advantageous that a functional group is introduced reversibly. Here we give a quantitative comparison of the different strategies that can be applied to reversibly attach functional groups via disulfide bonds to RNA 5'-ends. We report the preparation of functional groups with disulfide linkages, their incorporation efficiency into an RNA library, and their stability under various conditions.

Designed molecules that fold to mimic protein secondary structures.

Molecules that fold to mimic protein secondary structures have emerged as important targets of bioorganic chemistry. Recently, a variety of compounds that mimic helices, turns, and sheets have been developed, with notable advances in the design of beta-peptides that mimic each of these structures. These compounds hold promise as a step toward synthetic molecules with protein-like properties and as drugs that block protein-protein interactions.

Two new beta-strand mimics.

In a previous report, Nowick and co-workers described beta-strand mimic A, which duplicates the structure and hydrogen-bonding pattern of one edge of a tetrapeptide in a beta-strand conformation (Nowick, J. S.; Pairish, M.; Lee, I. Q.; Holmes, D. L.; Ziller, J. W. J. Am. Chem. Soc. 1997, 119, 5413). Beta-strand mimic A is composed of a 5-amino-2-methoxybenzoic acid unit linked to a 5-hydrazino-2-methoxybenzamide unit by means of an acylhydrazine group. This paper introduces two related beta-strand mimics (B and C) and reports their comparison to beta-strand mimic A. Beta-strand mimic B is composed of a 5-amino-2-methoxybenzoic acid unit linked by a diacylhydrazine group to a fumaramide unit; beta-strand mimic C is composed of a 5-amino-2-methoxybenzoic acid unit linked by a diacylhydrazine group to a peptide. Beta-strand mimics A-C were connected to tripeptide (Phe-Ile-Leu) groups by means of 1,2-diaminoethane diurea turn units to form artificial beta-sheets 1-3. 1H NMR studies, involving ROESY, chemical shift, coupling constant, and variable temperature experiments, reveal that 1-3 adopt hydrogen-bonded antiparallel beta-sheet conformations and establish that all three templates are viable beta-strand mimics.

Design and synthesis of a transition state analogue for the Diels-Alder reaction.

This paper describes the design and synthesis of a tricationic transition state analogue (TSA 1) for the Diels-Alder reaction. TSA 1 contains a bicyclo[2.2.1]heptene ring system that mimics the boat conformation of the Diels-Alder transition state and is designed to bind tightly to antibodies, nucleic acids, and imprinted polymers by means of hydrogen bonds and salt-bridges. This paper also describes the syntheses of the Diels-Alder reaction substrates (diene 2 and dienophile 3) and a sensitive HPLC assay to monitor the formation of Diels-Alder product 4. In contrast to previously reported TSAs and dienophiles for the Diels-Alder reaction that are based upon maleimides, TSA 1 and dienophile 3 are based upon fumaramide. The fumaramide system should destabilize the initially formed boat conformer of Diels-Alder product 4 and stabilize a half-chair conformer. The conversion of the initially formed boat conformer to the half-chair conformer is designed to help prevent Diels-Alder product 4 from binding strongly to catalysts selected to strongly bind TSA 1. This feature should minimize product inhibition, which can be a problem in the catalysis of the Diels-Alder reaction.

Unnatural oligomers and unnatural oligomer libraries.

Within the past few years, a variety of compounds that mimic biopolymers have been developed. All of these unnatural oligomers are prepared by iterative syntheses, which are amenable to combinatorial strategies. Peptides continue to be popular targets for mimicry, and there is growing interest in targeting oligosaccharides. The incorporation of unnatural oligomers into compounds that adopt defined structures, such as helices or sheets, has emerged as an exciting new area of unnatural oligomer research.