Structural features of piperazinyl-linked ciprofloxacin dimers required for activity against drug-resistant strains of Staphylococcus aureus

We previously demonstrated that piperazinyl-linked fluoroquinolone dimers possess potent antibacterial activity against drug-resistant strains of Staphylococcus aureus. In this study, we report the preparation and evaluation of a series of incomplete dimers toward ascertaining structural features of piperazinyl-linked ciprofloxacin dimers that render these agents refractory to fluoroquinolone-resistance mechanisms in Staphylococcus aureus.     

Piperazinyl-linked fluoroquinolone dimers possessing potent antibacterial activity against drug-resistant strains of Staphylococcus aureus

The synthesis of symmetric and asymmetric piperazinyl-linked dimers of the fluoroquinolone class of antibiotics is described. Specific dimers are shown to possess potent antibacterial activity against drug-resistant strains of Staphylococcus aureus, including strains possessing resistance due to the NorA multidrug efflux pump and a mutation in the quinolone resistance-determining region of topoisomerase IV.     

Synthesis and antimicrobial activity of brominated resorcinol dimers

Dibrominated resorcinol dimers were synthesized by reaction of 4-bromoresorcinol with aldehydes under reflux in ethanol in the presence of HCl. Subsequent dehalogenation yielded the corresponding monobrominated compounds and a fully dehalogenated dimer. Of the dimers, 6,6'-((4-hydroxyphenyl)methylene)bis(4-bromobenzene-1,3-diol) (4) displayed potent antibacterial activity and inhibitory activity against isocitrate lyase Candida albicans.     

Parallel and antiparallel dimers of magainin 2: their interaction with phospholipid membrane and antibacterial activity.

Magainin 2 (M2) forms pores by associating with several other M2 molecules in lipid membranes and shows antibacterial activity. To examine the effect of M2 dimerization on biological activity and membrane interaction, parallel and antiparallel M2 dimers were prepared from two monomeric precursors. Antibacterial and haemolytic activities were enhanced by dimerization. CD measurements showed that both dimers and monomers have an alpha-helical structure in the presence of lipid vesicles. Tryptophan fluorescence shift and KI quenching studies showed that all the peptides were more deeply embedded in acidic liposomes than in neutral liposomes. Experiments on dye-leakage activity and membrane translocation of peptides suggest that dimers and monomers form pores through lipid membranes, although the pore formation may be accompanied by membrane disturbance. Although dimerization of M2 increased the interaction activity with lipid membranes, no appreciable difference between the activities of parallel and antiparallel M2 dimers was observed.     

Development of novel antibacterial peptides that kill resistant isolates

The rapid emergence of bacterial strains that are resistant to current antibiotics requires the development of novel types of antimicrobial compounds. Proline-rich cationic antibacterial peptides such as pyrrhocoricin kill responsive bacteria by binding to the 70 kDa heat shock protein DnaK and inhibiting protein folding. We designed and synthesized multiply protected dimeric analogs of pyrrhocoricin and optimized the in vitro antibacterial efficacy assays for peptide antibiotics. Pyrrhocoricin and the designed dimers killed β-lactam, tetracycline- or aminoglycoside-resistant strains of Escherichia coli, Salmonella typhimurium, Klebsiella pneumoniae, Haemophilus influenzae, and Moraxella catarrhalis in the submicromolar or low micromolar concentration range. One of the peptides also killed Pseudomonas aeruginosa. The designed dimers showed improved stability in mammalian sera compared to the native analog. In a murine H. influenzae lung infection model, a single dose of a dimeric pyrrhocoricin analog reduced the bacteria in the bronchoalveolar lavage when delivered intranasally. The solid-phase synthesis was optimized for large-scale laboratory preparations.     

Chemistry and function of vegetable polyphenols with high molecular weights

Structure and function of polypehnols with high molecular weights (tannins) were briefly reviewed to better understand the significance of polyphenol-rich foods and beverages. In a survey of bioactive ellagiannins with a macrocyclic structure and/or a gluconic acid core, some new oligomeric ellagitannins (eucarpanins and elaeagnatins) have been found in species of Myrtaceae and Elaeagnaceae, and their structures were elucidated by spectroscopic and chemical methods. Cytotoxic activity against human oral tumor cell lines and antibacterial activity against Helicobacter pylori have been evaluated for the ellagitannins obtained from both plants, and related compounds. The macrocyclic dimers, oentothein B, camelliin B and woodfordin C showed a remarkable cytotoxicity against human oral squamous cell carcinoma, but not against normal cells. These active tannins induced apoptosis of tumor cells. A potent antibacterial activity against Helicobacter pylori was exhibited by monomeric ellagitannins such as tellimagrandin I and stricitinin.     

A bioconjugate approach toward squalamine mimics: Insight into the mechanism of biological action

A short and efficient synthesis has been devised for a family of squalamine mimics, based on the use of cholic acid, deoxycholic acid, lithocholic acid, putrescine, and spermine as starting materials. Those mimics that contain two facially amphiphilic sterol-spermidine conjugates show strong antibacterial activity against a broad spectrum of Gram-positive bacteria; their corresponding activities against a broad spectrum of Gram-negative bacteria are relatively moderate. Larger mimics, containing four such sterol-spermidine conjugates, exhibit very weak activities. Reversal of the pendent spermidine moiety and a putrescine linkage on the A- and D-rings had little consequence on the antibacterial activity for the most active of the squalamine mimics, which contained two sterol-polyamine units; similar results were obtained with squalamine mimics made from only one sterol unit. Detailed structure-activity measurements, in combination with kinetic studies carried out using liposomes as model membranes, support a mechanism of action involving noncovalent dimers as ion transporting species, most probably via the formation of pores or channels.     

The Role of Phe181 in the Hexamerization of <Emphasis Type="Italic">Helicobacter pylori</Emphasis> Quinolinate Phosphoribosyltransferase

Quinolinic acid phosphoribosyltransferase (QAPRTase; NadC) catalyzes an indispensable step in NAD biosynthesis, one that is essential for cell survival in prokaryotes, which makes it an attractive target for antibacterial drug therapy. We recently reported the crystal structures of Helicobacter pylori QAPRTase with bound quinolinic acid, nicotinamide mononucleotide, and phthalic acid. The enzyme exists as a hexamer organized as a trimer of dimers, which is essential for full enzymatic activity. The loop between helix α7 and strand β8 contributes significantly to the hydrophobic dimer-dimer interactions. Phe181Pro mutation within the α7-β8 loop disrupts the hexamerization of QAPRTase, and the resultant dimer shows dramatically reduced protein stability and no activity. Our findings thus suggest that compounds able to disrupt its proper oligomerization could potentially function as selective inhibitors of Helicobacter pylori QAPRTase and represent a novel set of antibacterial agents.     

Antimicrobially active alkaloids from Tabernaemontana pachysiphon

Twenty-three alkaloids and five steroids and triterpenes have been isolated and identified from the root bark and stem bark of a Nigerian Tabernaemontana pachysiphon. The following bases have not previously been obtained from this species: isositsirikine, 16-epiisositsirikine, normacusine B, 16-epiaffinine, anhydrovobasindiol, tubotaiwine, ibogaline, isovoacangine, voacamine, lochnericine, 3R-hydroxyconopharyngine, 3S-hydroxyconopharyngine and 11-demethylconoduramine, the last three being new alkaloids. The dimeric indole alkaloids and 3R/S-hydroxyconopharyngine were shown to possess strong antibacterial activity against Gram-positive bacteria and the dimers against Gram-negative bacteria also.     

Chitooligosaccharides--preparation with the aid of pectinase isozyme from Aspergillus niger and their antibacterial activity

An isozyme of pectinase from Aspergillus niger with polygalacturonase activity caused chitosanolysis at pH 3.5, resulting in low-molecular weight chitosan (86%), chitooligosaccharides (COs, 4.8%) and monomers (2.2%). HPLC showed the presence of COs with DP ranging from 2 to 6. Charcoal-Celite chromatography and re-N-acetylation of the COs followed by CD, IR, MALDI-TOF-MS and FAB-MS analyses revealed an abundance of chitobiose, chitotriose and chitotetraose. The COs-monomeric mixture showed a bactericidal effect towards Bacillus cereus and Escherichia coli more efficiently than native chitosan. Among the chitooligomers, the hexamer showed maximum antibacterial effect followed by the penta-, tetra-, tri- and dimers. Of the two monomers, only GlcN showed slight bacterial growth inhibition. SEM revealed bactericidal action patterns of COs-monomeric mixture towards B. cereus and E. coli.     

Non‐equivalent roles of two periplasmic subunits in the function and assembly of triclosan pump TriABC from Pseudomonas aeruginosa

In Gram‐negative bacteria, multidrug efflux transporters function in complexes with periplasmic membrane fusion proteins (MFPs) that enable antibiotic efflux across the outer membrane. In this study, we analyzed the function, composition and assembly of the triclosan efflux transporter TriABC–OpmH from Pseudomonas aeruginosa. We report that this transporter possesses a surprising substrate specificity that encompasses not only triclosan but the detergent SDS, which are often used together in antibacterial soaps. These two compounds interact antagonistically in a TriABC‐dependent manner and negate antibacterial properties of each other. Unlike other efflux pumps that rely on a single MFP for their activities, two different MFPs, TriA and TriB, are required for triclosan/SDS resistance mediated by TriABC–OpmH. We found that analogous mutations in the α‐helical hairpin and membrane proximal domains of TriA and TriB differentially affect triclosan efflux and assembly of the complex. Furthermore, our results show that TriA and TriB function as a dimer, in which TriA is primarily responsible for stabilizing interactions with the outer membrane channel, whereas TriB is important for the stimulation of the transporter. We conclude that MFPs are engaged into complexes as asymmetric dimers, in which each protomer plays a specific role.     

Coptisine-induced inhibition of Helicobacter pylori: elucidation of specific mechanisms by probing urease active site and its maturation process

In this study, we examined the anti-Helicobactor pylori effects of the main protoberberine-type alkaloids in Rhizoma Coptidis. Coptisine exerted varying antibacterial and bactericidal effects against three standard H. pylori strains and eleven clinical isolates, including four drug-resistant strains, with minimum inhibitory concentrations ranging from 25 to 50?μg/mL and minimal bactericidal concentrations ranging from 37.5 to 125?μg/mL. Coptisine’s anti-H. pylori effects derived from specific inhibition of urease in vivo. In vitro, coptisine inactivated urease in a concentration-dependent manner through slow-binding inhibition and involved binding to the urease active site sulfhydryl group. Coptisine inhibition of H. pylori urease (HPU) was mixed type, while inhibition of jack bean urease was non-competitive. Importantly, coptisine also inhibited HPU by binding to its nickel metallocentre. Besides, coptisine interfered with urease maturation by inhibiting activity of prototypical urease accessory protein UreG and formation of UreG dimers and by promoting dissociation of nickel from UreG dimers. These findings demonstrate that coptisine inhibits urease activity by targeting its active site and inhibiting its maturation, thereby effectively inhibiting H. pylori. Coptisine may thus be an effective anti-H. pylori agent.     

Chimeric Antimicrobial Peptides Exhibit Multiple Modes of Action

Pyrrhocoricin and drosocin, representatives of the short, proline-rich antimicrobial peptide family kill bacteria by inactivating the bacterial heat shock protein DnaK and inhibiting chaperone-assisted protein folding. The molecular architecture of these peptides features an N-terminal DnaK-binding half and a C-terminal delivery unit, capable of crossing bacterial membranes. Cell penetration is enhanced if multiple copies of pyrrhocoricin are conjugated. To obtain drug leads with improved antimicrobial properties, and possible utility as therapeutic agents, we synthesized chimeric dimers, in which pyrrhocoricins potent DnaK-binding domain was connected to drosocins superior cell penetrating module. Indeed, the new constructs not only exhibited enhanced in vitro antibacterial properties against the originally sensitive strains Escherichia coli, Klebsiella pneumoniae and Salmonella typhimurium, but also showed activity against Staphylococcus aureus, a bacterial strain resistant to native pyrrhocoricin and drosocin. The improved antimicrobial profile could be demonstrated with assays designed to distinguish intracellular or membrane activities. While a novel mixed pyrrhocoricin–drosocin dimer and the purely pyrrhocoricin-based old dimer bound E. coli DnaK with an identical 4 M K_d, the mixed dimers penetrated a significantly larger number of E. coli and S. aureus cells than the previous analogs and destroyed a larger percentage of bacterial membrane structures. Toxicity to human red blood cells could not be observed up to the highest peptide concentration tested, 640 M. In addition, repetitive reculturing of E. coli or S. aureus cells with sublethal concentrations of the mixed dimer did not result in resistance induction to the novel peptide antibiotic. The new concept of pyrrhocoricin–drosocin mixed dimers yields antibacterial peptide derivatives acting with a multiple mode of action, and can serve as a useful addition to the current antimicrobial therapy repertoire.     

Dynamic interplay between adhesive and lateral E-cadherin dimers

E-cadherin, an adhesive transmembrane protein of epithelial adherens junctions, forms two types of detergent-resistant dimers: adhesive dimers consisting of cadherin molecules derived from two neighboring cells and lateral dimers incorporating cadherins of the same cell. Both dimers depend on the integrity of the same residue, Trp156. While the relative amounts of these complexes are not certain, we show here that in epithelial A-431 cells, adhesive dimers may be a prevalent form. Inactivation of the calcium-binding sites, located between successive cadherin ectodomains, drastically reduced the amount of adhesive dimers and concomitantly increased the amount of lateral dimers. A similar interdependence of adhesive and lateral dimers was observed in digitonin-permeabilized cells. In these cells, adhesive dimers immediately disassembled after lowering the Ca2+ concentration below 0.1 mM. The disappearance of adhesive dimers was counterbalanced by an increase in Trp156-dependent lateral dimers. Increasing the calcium concentration to a normal level rapidly restored the original balance between adhesive and lateral dimers. We also present evidence that E-cadherin dimers in vivo have a short lifetime. These observations suggest that cadherin-mediated adhesion is based on the dynamic cycling of E-cadherin between monomeric and adhesive dimer states.     

Pyrimidine Dimers in the DNA of Paramecium aurelia

The production and fate of thymine-containing pyrimidine dimers in Paramecium aurelia DNA was investigated in three experimental series: production of dimers by UV irradiation, fate of dimers in the dark, and “loss of photoreactivability of dimers.” It is shown that cyclobutyl dimers are made by UV irradiation of Paramecium DNA in vivo, that because of cytoplasmic absorption the number of dimers made in DNA irradiated in vivo is much lower than in DNA irradiated in vitro, that dimers are lost from animals incubated in the dark after irradiation, and that all the dimers that remain in the animals can be destroyed by photoreactivating illumination. Since mutation induction is photoreactivable, these and previous photoreactivation data suggest that pyrimidine dimers are important in mutation induction in P. aurelia.     

New chemical and biological aspects of artemisinin-derived trioxane dimers.

Joining two 10-deoxoartemisinin trioxane units via a p-diacetylbenzene linker produces new C-10 non-acetal dimers and. 1H NMR spectroscopy allows unambiguous assignment of the stereochemistry at C-10 in these dimers. Successful replacement of both carbonyl oxygen atoms in these diketone dimers by fluorine atoms produces new tetrafluorinated dimers and. Each dimer was evaluated in vitro for antimalarial, antiproliferative, and antitumor activities; ketone dimers and, more than fluorinated dimers and, are promising for chemotherapy of both malaria and cancer.     

Functional determinants of human enteric α-defensin HD5: crucial role for hydrophobicity at dimer interface

Human α-defensins are cationic peptides that self-associate into dimers and higher-order oligomers. They bind protein toxins, such as anthrax lethal factor (LF), and kill bacteria, including Escherichia coli and Staphylococcus aureus, among other functions. There are six members of the human α-defensin family: four human neutrophil peptides, including HNP1, and two enteric human defensins, including HD5. We subjected HD5 to comprehensive alanine scanning mutagenesis. We then assayed LF binding by surface plasmon resonance, LF activity by enzyme kinetic inhibition, and antibacterial activity by the virtual colony count assay. Most mutations could be tolerated, resulting in activity comparable with that of wild type HD5. However, the L29A mutation decimated LF binding and bactericidal activity against Escherichia coli and Staphylococcus aureus. A series of unnatural aliphatic and aromatic substitutions at position 29, including aminobutyric acid (Abu) and norleucine (Nle) correlated hydrophobicity with HD5 function. The crystal structure of L29Abu-HD5 depicted decreased hydrophobic contacts at the dimer interface, whereas the Nle-29-HD5 crystal structure depicted a novel mode of dimerization with parallel β strands. The effect of mutating Leu(29) is similar to that of a C-terminal hydrophobic residue of HNP1, Trp(26). In addition, in order to further clarify the role of dimerization in HD5 function, an obligate monomer was generated by N-methylation of the Glu(21) residue, decreasing LF binding and antibacterial activity against S. aureus. These results further characterize the dimer interface of the α-defensins, revealing a crucial role of hydrophobicity-mediated dimerization.     

Roles of PsbI and PsbM in photosystem II dimer formation and stability studied by deletion mutagenesis and X-ray crystallography

PsbM and PsbI are two low molecular weight subunits of photosystem II (PSII), with PsbM being located in the center, and PsbI in the periphery, of the PSII dimer. In order to study the functions of these two subunits from a structural point of view, we crystallized and analyzed the crystal structure of PSII dimers from two mutants lacking either PsbM or PsbI. Our results confirmed the location of these two subunits in the current crystal structure, as well as their absence in the respective mutants. The relative contents of PSII dimers were found to be decreased in both mutants, with a concomitant increase in the amount of PSII monomers, suggesting a destabilization of PSII dimers in both of the mutants. On the other hand, the accumulation level of the overall PSII complexes in the two mutants was similar to that in the wild-type strain. Treatment of purified PSII dimers with lauryldimethylamine N-oxide at an elevated temperature preferentially disintegrated the dimers from the PsbM deletion mutant into monomers and CP43-less monomers, whereas no significant degradation of the dimers was observed from the PsbI deletion mutant. These results indicate that although both PsbM and PsbI are required for the efficient formation and stability of PSII dimers in vivo, they have different roles, namely, PsbM is required directly for the formation of dimers and its absence led to the instability of the dimers accumulated. On the other hand, PsbI is required in the assembly process of PSII dimers in vivo; once the dimers are formed, PsbI was no longer required for its stability.