Structure–activity relationship studies on quorum sensing ComXRO-E-2 pheromone
Autor: | Isao Sato, Masahiro Okada, Hisao Yamaguchi, Youji Sakagami, Soo Jeong Cho, David Dubnau |
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Rok vydání: | 2007 |
Předmět: |
Stereochemistry
Clinical Biochemistry Pharmaceutical Science Bacillus Tripeptide Biochemistry Mass Spectrometry Article Structure-Activity Relationship Bacterial Proteins Drug Discovery Structure–activity relationship Molecular Biology Chromatography High Pressure Liquid Alanine chemistry.chemical_classification Chemistry Organic Chemistry Histidine kinase Tryptophan Quorum Sensing Biological activity Glutamic acid Amino acid Amino Acid Substitution Lac Operon Molecular Medicine Indicators and Reagents |
Zdroj: | Bioorganic & Medicinal Chemistry Letters. 17:1705-1707 |
ISSN: | 0960-894X |
Popis: | Bacteria secrete specific extracellular signaling molecules that increase in concentration with cell density. In a process known as quorum sensing, bacteria regulate their behavior in response to such molecules.1 Quorum sensing attracts attention as a promising anti-pathogenic drug target rather than anti-bacterial, notably preventing the emergence of drag-resistant bacteria.2 The ComX pheromone3 is a signaling oligopeptide that stimulates natural genetic competence controlled by quorum sensing in Bacillus subtilis.4 In the presence of the ComX pheromone, the membrane-located receptor histidine kinase ComP autophosphorylates and donates phosphate via a two-component-system to activate competence gene expression.5 Previous studies indicated that the ComX pheromone is posttranslationally modified by the addition of an isoprenoid to a tryptophan residue.6,7 Posttranslational isoprenoidal modification on the cystein residue8 is widely observed in many important proteins such as the Ras oncoproteins, which plays a crucial role in human tumor and the isoprenoidal modification is essential for the Ras functions.9 Therefore, the posttranslational isoprenoidal modification is an attractive target for cancer therapy, but on the tryptophan residue, including other amino acid residues except cystein, is unprecedented. Recently the ComXRO-E-2 pheromone 1 from B. subtilis strain RO-E-2,6 was shown to be a hexapeptide possessing a modified tryptophan residue with a geranyl group. This novel modification resulted in the formation of a tricyclic structure (Figure 1).10 Fig 1 Chemical structure of ComXRO-E-2 pheromone Since further studies are required to elucidate the details of the function through the interaction between the ComX pheromone and ComP, various ComXRO-E-2 analogs were prepared using solid phase peptide synthesis.10–13 The biological activities of these peptides as well as of ComXRO-E-2 pheromone were investigated using β-galactosidase assays.6,10–12,14 These data were used to draw the dose response curves. The biological activities of these peptides were represented by two values both normalized to the activity of the ComXRO-E-2 pheromone (Table 1). The first value presents the concentration of each peptide, needed to obtain the same β-galactosidase activity as that obtained with the ComXRO-E-2 pheromone at EC50. The second is the maximum activity as a percentage of that obtained with the ComXRO-E-2 pheromone. Table 1 Biological activities of ComXRO-E-2 analogs Although N-terminal truncated [2–6]ComXRO-E-2 and [3–6]ComXRO-E-2 showed significant biological activities as previously reported,12 [4–6]ComXRO-E-2 lost all activity (entry 4). The C-terminal glutamate residue was partially dispensable like the N-terminal glycine. In contrast, deletion of the glutamic acid and glutamate residues C-terminal to tryptophan dramatically decreased the activity (entry 5–8). These results indicated that for activity, either the modified tryptophan must reside at an internal position, or that contacts of the ComP receptor with the glutamic acid residue are important. A minimal active core within ComXRO-E-2 appears to consist of the tripeptide, [3–5]ComXRO-E-2 (entry 9). Elongation of ComXRO-E-2 pheromone by the addition of alanine at either the N- or C-terminus did not affect the activity (entry 10,11). The roles of individual amino acid side chains were investigated substitution of each residue except the modified tryptophan with alanine. Surprisingly, none were absolutely essential for biological activity, although alanine substitution of 3 phenylalanins and 6 glutamate decreased the activity substantially (entry 12–16). Earlier work on the structure-activity-relationships of tremerogen A-10,15 which is the sex pheromone of basidiomycetous yeasts containing a C-terminal farnesyl modified cysteine methyl ester, revealed that removal of the C-terminus methyl ester or N-terminal residues decreased biological activity16 in contrast to the present results with the ComXRO-E-2 pheromone, which showed that only tripeptide, [3–5]ComXRO-E-2, still had considerable activity. These results indicated that the pattern of specific interaction of the ComX pheromone with its receptor are unique and different from that of the S-isoprenoidal peptides. Furthermore, the precise structure of modified tryptophan residue was essential for the biological activity, because synthetic ComXRO-E-2 peptides, containing a geranyltryptophan residue with a geranyl group replacing a tryptophanyl proton10 or with additional stereoisomers at the modified tryptophan residue,11,12 showed no biological activities. Although the farnesyl group on tremerogen A-10 was replaceable by lipophilic long chains,16 the role of the geranyl moiety in biological activity and in determining pherotype specificity is not yet known. Into investigate this question, we are synthesizing analogs of ComXRO-E-2 with other side chains replacing the geranyl moiety. In summary, various ComXRO-E-2 analogs were synthesized and their biological activities were studied to investigate structure-activity-relationships. These results showed that the minimal active unit was the tripeptide, [3–5]ComXRO-E-2, and all residues except the modified tryptophan residue were replaceable by alanine without total loss of activity. |
Databáze: | OpenAIRE |
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