Preparation of dicationic palladium catalysts for asymmetric catalytic reactions

The synthesis of Pd(OTf)(2)·2H(2)O is described. This was used to generate two different types of chiral dicationic palladium complexes for highly enantioselective addition of aromatic amines to α, β-unsaturated conjugate alkenes ([(R-BINAP)Pd(OH(2))(2)][OTf](2) and [(R-BINAP)Pd(μ-OH)](2)[OTf](2)). The resulting optically active N-arylated β-amino acid derivatives are valuable synthetic intermediates for the synthesis of biologically active molecules and peptidomimetics. The reaction of (2E)-but-2-enoylcarbamate and aniline is shown as an example of the use of these catalysts for enantioselective aza-Michael addition. For the preparation of palladium(II) triflate, the time scale is 20 h 50 min, plus 5 h 15 min for the monomeric complex and plus 6 h 45 min for the dimeric complex.     

Failure to insert the iron-sulfur cluster into the Rieske iron-sulfur protein impairs both center N and center P of the cytochrome bc1 complex

Mutation of a serine that forms a hydrogen bond to the iron-sulfur cluster of the Rieske iron-sulfur protein to a cysteine results in a respiratory-deficient yeast strain due to formation of iron-sulfur protein lacking the iron-sulfur cluster. The Rieske apoprotein lacking the iron-sulfur cluster is inserted into both monomers of the dimeric cytochrome bc(1) complex and processed to mature size, but the protein lacking iron-sulfur cluster is more susceptible to proteolysis. In addition, the protein environment of center P in one half of the dimer is affected by failure to insert the iron-sulfur cluster as indicated by the fact that only one molecule of myxothiazol can be bound to the cytochrome bc(1) dimer. Although the bc(1) complex lacking the Rieske iron-sulfur cluster cannot oxidize ubiquinol through center P, rates of reduction of cytochrome b by menaquinol through center N are normal. However, less cytochrome b is reduced through center N, and only one molecule of antimycin can be bound at center N in the bc(1) dimer lacking iron-sulfur cluster. These results indicate that failure to insert the [2Fe-2S] cluster impairs assembly of the Rieske protein into the bc(1) complex and that this interferes with proper assembly of both center P and center N in one half of the dimeric enzyme.     

The mitochondrial copper metallochaperone Cox17 exists as an oligomeric, polycopper complex

Cox17 is the candidate copper metallochaperone for delivery of copper ions to the mitochondrion for assembly of cytochrome c oxidase. Cox17 purified as a recombinant molecule lacking any purification tag binds three Cu(I) ions per monomer in a polycopper cluster as shown by X-ray absorption spectroscopy. The CuCox17 complex exists in a dimer/tetramer equilibrium with a 20 microM k(d). The spectroscopic data do not discern whether the dimeric complex forms a single hexanuclear Cu(I) cluster or two separate trinuclear Cu(I) clusters. The Cu(I) cluster(s) exhibit(s) predominantly trigonal Cu(I) coordination. The cluster(s) in Cox17 resemble(s) the polycopper clusters in Ace1 and the Cup1 metallothionein in being pH-stable and luminescent. The physical properties of the CuCox17 complex purified as an untagged molecule differ from those reported previously for a GST-Cox17 fusion protein. The CuCox17 cluster is distinct from the polycopper cluster in Cup1 in being labile to ligand exchange. CuCox17 localized within the intermitochondrial membrane space appears to be predominantly tetrameric, whereas the cytosolic CuCox17 is primarily a dimeric species. Cys-->Ser substitutions at Cys23, Cys24, or Cys26 abolish the Cox17 function and prevent tetramerization, although Cu(I) binding is largely unaffected. Thus, the oligomeric state of Cox17 may be important to its physiological function.     

Self-assembly of porphyrins on nucleic acid templates

The cis and trans isomers of dicationic bis(4-N-methylpyridyl)diphenylporphine show a much greater tendency to aggregate than similar tetracationic porphyrins. Upon binding to nucleic acids these aggregating dicationic porphyrins form long-range structures on the polymer template giving intense circular dichroism signals whose profile reports the helical sense of the DNA.     

CopH from Cupriavidus metallidurans CH34. A novel periplasmic copper-binding protein

The copH gene is one of the 19 open reading frames (ORFs) found in the cop cluster borne by the large plasmid pMol30 in Cupriavidus metallidurans CH34. The entire cluster is involved in detoxification of copper from the cytoplasm as well as from the periplasm. The function of the corresponding protein, CopH, is not yet clear, but it seems to be involved in the late response phase. We have cloned copH and overproduced and purified the corresponding protein. CopH is rather unique as only one paralog can be found in the databases. It is a dimeric protein with a molecular mass of 13 200 Da per subunit and located in the periplasm. The metal binding properties of CopH were examined by using a series of techniques such as UV-visible spectroscopy, circular dichroism (CD), electron paramagnetic resonance (EPR), surface plasmon resonance (SPR), mass spectrometry, and nuclear magnetic resonance (NMR). All together, the corresponding data are consistent with a dimeric protein containing one metal-binding site per subunit. These sites have a high affinity for Cu(II) but can also bind zinc or nickel. CopH does not contain any cysteines or methionines but contains two histidines. EPR and UV-visible features are consistent with the presence of Cu(II) type 2 centers in a nitrogen ligand field. SPR data confirm the involvement of the histidine residues in copper binding. CD and NMR data reveal that CopH is partially unfolded.     

Adaptive evolution of variable region genes encoding an unusual type of immunoglobulin in camelids

A typical immunoglobulin (Ig) molecule is composed of four polypeptide chains: two identical heavy (H) chains and two identical light (L) chains. This tetrameric structure is conserved in almost all jawed vertebrate species. However, it has been discovered that camels and llamas (family: Camelidae) possess a type of dimeric Ig that consists of two H chains only. These H chains do not associate with L chains, and they do not have the first constant region (CH1), which is present in the conventional Ig. In spite of these changes, the dimeric Ig maintains the normal immune function. To understand the evolution of the dimeric Ig, we studied the phylogenetic relationships of the variable region (V(H)H) genes of the dimeric Ig from Camelidae and those (V(H)) of the conventional Ig from mammals. The results showed that the V(H)H genes form a monophyletic cluster within one of the mammalian V(H) groups, group C. We examined the type of selective force in complementarity-determining regions (CDRs) and framework regions (FRs) by comparing the rate of synonymous (dS) and nonsynonymous (dN) substitutions. We found that the results obtained from V(H)H genes were similar to those from V(H) genes in that CDRs showed an excess of dN over dS (indicating positive selection), whereas the reverse was true for FRs (purifying selection). However, when the extent of positive selection or purifying selection was investigated at each codon site, three major differences between V(H)H and V(H) genes were found. That is, very different types of selective force were observed between V(H)H and V(H) genes (1) at the sites that contact the L chain in the conventional Ig, (2) at the sites that interact with the CH1 region in the conventional Ig, and (3) in the H1 loop. Our findings suggest that adaptive evolution has occurred in the functionally important sites of the V(H)H genes to maintain the normal immune function in the dimeric Ig.     

Changing cellular location of CheZ predicted by molecular simulations

In the chemotaxis pathway of the bacterium Escherichia coli, signals are carried from a cluster of receptors to the flagellar motors by the diffusion of the protein CheY-phosphate (CheYp) through the cytoplasm. A second protein, CheZ, which promotes dephosphorylation of CheYp, partially colocalizes with receptors in the plasma membrane. CheZ is normally dimeric in solution but has been suggested to associate into highly active oligomers in the presence of CheYp. A model is presented here and supported by Brownian dynamics simulations, which accounts for these and other experimental data: A minority component of the receptor cluster (dimers of CheA_short) nucleates CheZ oligomerization and CheZ molecules move from the cytoplasm to a bound state at the receptor cluster depending on the current level of cellular stimulation. The corresponding simulations suggest that dynamic CheZ localization will sharpen cellular responses to chemoeffectors, increase the range of detectable ligand concentrations, and make adaptation more precise and robust. The localization and activation of CheZ constitute a negative feedback loop that provides a second tier of adaptation to the system. Subtle adjustments of this kind are likely to be found in many other signaling pathways.     

9-Aminoacridine blocks NMDA and AMPA receptors by different mechanisms

Tricyclic mono- and dicationic compounds (derivatives of 9-aminoacridine) antagonize AMPA and NMDA glutamate receptors. The aim of the present study was to compare mechanisms of the 9-aminoacridine action on AMPA and NMDA receptors. Experiments were carried out by whole-cell patch-clamp technique on native receptors from rat brain neurons. An important peculiarity of the 9-aminoacridine action on NMDA receptors is the large slope of the concentration dependence, which suggests the binding of two molecules in the channel. AMPA receptors blockade also demonstrated interesting features. In contrast to the NMDA receptor channel block, inhibition of AMPA receptors is voltage-independent. 9-Aminoacridine and its dicationic analog demonstrated similar anti-AMPA activity. For classical AMPA-receptor channel blockers (derivatives of adamantane and phenylcyclohexyl) it was demonstrated that dicationic analogs are much more potent than monocationic analogs. We conclude that 9-aminoacridine binds to a specific site in AMPA receptors. This finding opens a possibility to develop a new family of non-competitive antagonists of AMPA receptors.     

The nucleotide sequence and in situ localization of a gene for a dimeric haemoglobin from the midge Chironomus thummi piger

A cluster containing at least four globin genes was isolated by screening an lambda EMBL3 genomic DNA library of the midge Chironomus thummi piger (Ctp) with a heterologous haemoglobin (Hb) gene IV (HbIV) probe from Chironomus thummi thummi (Ctt). This globin gene cluster was localized by in situ hybridization to chromosome II. One globin gene together with its 5'- and 3'-flanking regions has been sequenced. It can be deduced from the sequence that it is a new member of the dimeric HbVIIB family. The Ctp HbVIIB-5 gene displays 91.8% nucleotide sequence homology to a HbVIIB cDNA sequence, reported previously. There is no evidence for intron/exon structure in the Ctp HbVIIB-5 gene.     

A dimer of the FeS cluster biosynthesis protein IscA from cyanobacteria binds a [2Fe2S] cluster between two protomers and transfers it to [2Fe2S] and [4Fe4S] apo proteins.

Two proteins with similarity to IscA are encoded in the genome of the cyanobacterium Synechocystis PCC 6803. One of them, the product of slr1417 which accounts for 0.025% of the total soluble protein of Synechocystis was over-expressed in E. coli and purified. The purified protein was found to be mainly dimeric and did not contain any cofactor. Incubation with iron ions, cysteine and Synechocystis IscS led to the formation of one [2Fe2S] cluster at an IscA dimer as demonstrated (by the binding of about one iron and one sulfide ion per IscA monomer) by UV/Vis, EPR and M?ssbauer spectroscopy. M?ssbauer spectroscopy further indicated that the FeS cluster was bound by four cysteine residues. Site-directed mutagenesis revealed that of the five cysteine residues only C110 and C112 were involved in cluster binding. It was therefore concluded that the [2Fe2S] cluster is located between the two protomers of the IscA dimer and ligated by C110 and C112 of both protomers. The cluster could be transferred to apo ferredoxin, a [2Fe2S] protein, with a half-time of 10 min. Surprisingly, incubation of cluster-containing IscA with apo adenosine 5'-phosphosulfate reductase led to a reactivation of the enzyme which requires the presence of a [4Fe4S] cluster. This demonstrates that it is possible to build [4Fe4S] clusters from [2Fe2S] units.     

Lipid arrangement in fluid model membranes: analysis by cross-linking of phosphatidylethanolamines

Binary mixtures of fluid phase phosphatidylethanolamines at pH 10 were treated with the bifunctional cross-linking reagent dimethylsuberimidate. Analysis of the dimeric species formed demonstrated that the phospholipid species in dimyristoylphosphatidylethanolamine/dielaidoylphosphatidylethanolamine mixtures at 52 degrees C and dielaidoylphosphatidylethanolamine/dilauroylphosphatidylethanolamine mixtures at 41 degrees C were randomly arranged. Analysis of the dimeric species formed in dipalmitoylphosphatidylethanolamine/dioleoylphosphatidylethanolamine mixtures at 68 degrees C showed that this mixture was very close to being randomly arranged, with just a slight propensity of like phospholipid species to cluster.     

Interaction of enkephalin peptides with anionic model membranes.

According to the model for passive transport across the membranes, the total flow of permeant molecules is related to the product of the water-membrane partition coefficient and the diffusion coefficient, and to the water-membrane interfacial barrier. The effect of membrane surface charge on the permeability and interaction of analgesic peptide ligands with model membranes was investigated. A mixture of zwitterionic phospholipids with cholesterol was used as a model membrane. The lipid membrane charge density was controlled by the addition of anionic 1-palmitoyl-2-oleoylphosphatidylserine. Two classes of highly potent analgesic peptides were studied, c[D-Pen(2),D-Pen(5)]enkephalin (DPDPE) and biphalin, a dimeric analog of enkephalin. The effect of increased surface charge on the permeability of the zwitterionic DPDPE is a relatively modest decrease, that appears to be due to a diminished partition coefficient. On the other hand the binding of the dicationic biphalin ligands to membranes increases proportionally with increased negative surface charge. This effect translates into a significant reduction of biphalin permeability by reducing the diffusion of the peptide across the bilayer. These experiments show the importance of electrostatic effects on the peptide-membrane interactions and suggest that the negative charge naturally present in cell membranes may hamper the membrane transport of some peptide drugs, especially cationic ones, unless there are cationic transporters present.     

Genetic and structural organization of the aminophenol catabolic operon and its implication for evolutionary process

The aminophenol (AP) catabolic operon in Pseudomonas putida HS12 mineralizing nitrobenzene was found to contain all the enzymes responsible for the conversion of AP to pyruvate and acetyl coenzyme A via extradiol meta cleavage of 2-aminophenol. The sequence and functional analyses of the corresponding genes of the operon revealed that the AP catabolic operon consists of one regulatory gene, nbzR, and the following nine structural genes, nbzJCaCbDGFEIH, which encode catabolic enzymes. The NbzR protein, which is divergently transcribed with respect to the structural genes, possesses a leucine zipper motif and a MarR homologous domain. It was also found that NbzR functions as a repressor for the AP catabolic operon through binding to the promoter region of the gene cluster in its dimeric form. A comparative study of the AP catabolic operon with other meta cleavage operons led us to suggest that the regulatory unit (nbzR) was derived from the MarR family and that the structural unit (nbzJCaCbDGFEIH) has evolved from the ancestral meta cleavage gene cluster. It is also proposed that these two functional units assembled through a modular type gene transfer and then have evolved divergently to acquire specialized substrate specificities (NbzCaCb and NbzD) and catalytic function (NbzE), resulting in the creation of the AP catabolic operon. The evolutionary process of the AP operon suggests how bacteria have efficiently acquired genetic diversity and expanded their metabolic capabilities by modular type gene transfer.     

Inhibition of in vitro intracellular growth of Trypanosoma cruzi by dicationic compounds

Dicationic compounds, which are derivatives of pentamidine, are being developed for use as antiprotozoal drugs. These compounds bind to the minor groove of DNA and are thought to inhibit DNA-dependent enzymes and thereby prevent cellular replication by protozoans. The objective of this study was to test the ability of a group of these compounds to inhibit the intracellular and extracellular reproduction of Trypanosoma cruzi in vitro. At present, there are few drugs in use capable of inhibiting the intracellular stages of this parasite, and therefore compounds with this ability would be of value. Cultures of mouse fibroblasts were infected and treated with doses of dicationic compounds, and the numbers of parasites released at the end of the 5- to 7-day growth cycle were determined. Five of the compounds tested were found to be effective at inhibiting T. cruzi growth at doses that were not toxic to the host cells. The compound found most effective (DB709) inhibited parasite release at the low concentration of 0.8 ng/ ml, justifying further study. These results suggest that dicationic compounds may have potential as chemotherapy against T. cruzi infection.     

Synthesis and antibacterial studies of binaphthyl-based tripeptoids. Part 2

A compact synthesis of 15 new binaphthyl-based dicationic tripeptoids and one biphenyl based dicationic tripeptoid is described. Fourteen of these tripeptoids resulted from variation of the C-2′ ether substituent of the binaphthyl unit. An O-iso-butyl ether binaphthyl derivative was found to be the most active against Staphylococcus aureus (MIC 1.95 μg/mL). The biphenyl analogue also showed good activity against S. aureus (MIC 1.95 μg/mL). These compounds, however, were less active against four vancomycin-resistant strains of enterococci (VRE) than some of our previously developed compounds that had an O-iso-pentyl ether substituent on the binaphthyl unit and a C-2 l-Leu moiety.     

Crystal structure of the cysteine-rich domain of scavenger receptor MARCO reveals the presence of a basic and an acidic cluster that both contribute to ligand recognition

MARCO is a trimeric class A scavenger receptor of macrophages and dendritic cells that recognizes polyanionic particles and pathogens. The distal, scavenger receptor cysteine-rich (SRCR) domain of the extracellular part of this receptor has been implicated in ligand binding. To provide a structural basis for understanding the ligand-binding mechanisms of MARCO, we have determined the crystal structure of the mouse MARCO SRCR domain. The recombinant SRCR domain purified as monomeric and dimeric forms, and their structures were determined at 1.78 and 1.77 A resolution, respectively. The monomer has a compact globular fold with a twisted five-stranded antiparallel beta-sheet and a long loop covering a single alpha-helix, whereas the dimer is formed via beta-strand swapping of two monomers, thus containing a large eight-stranded beta-sheet. Calculation of the surface electrostatic potential revealed that the beta-sheet region with several arginines forms a basic cluster. Unexpectedly, an acidic cluster was found in the long loop region. In the monomer, the acidic cluster is involved in metal ion binding. Studies with cells expressing various SRCR domain mutants showed that all of the arginines of the basic cluster are involved in ligand binding, suggesting a cooperative binding mechanism. Ligand binding is also dependent on the acidic cluster and Ca2+ ions whose depletion appears to affect ligand binding at least by modulating the electrostatic potential or relative domain orientation. We propose that the SRCR domain dimerization can contribute to the recognition of large ligands by providing a means for the MARCO receptor oligomerization.     

Chromium(III) hydrolytic oligomers: their relevance to protein binding

The nature of chromium(III) complexes has been found to show a profound influence in its interaction with collagen. The hydrothermal stability of rat tail tendon (RTT) fibres treated with dimeric, trimeric and tetrameric species of chromium(III) has been found to be 102, 87 and 68 degrees C, while that of native RTT is 62 degrees C. This shows that the efficiency of crosslinking of collagen by chromium(III) species is dimeric > trimeric > tetrameric. This order of stabilisation is again confirmed by cyanogen bromide (CNBr) cleavage of RTT collagen treated with dimeric, trimeric and tetrameric chromium(III) species. CNBr has been found to cleave the collagen treated with tetrameric chromium(III) species extensively. On the other hand, dimer-treated collagen does not undergo any cleavage on CNBr treatment. The equilibrium constants for the reaction of a nucleophile like NCS(-) to the dimeric, trimeric and tetrameric species of chromium(III) have been found to be 15.7+/-0.1, 14.6+/-0.1 and 1.2+/-0.1 M(-1), respectively. These equilibrium constant values reflect the relative thermodynamic stability of the chromium(III) species-nucleophile complex. The low stabilising effect of the tetrameric species can be traced to its low thermodynamic affinity for nucleophiles.     

The binding site in {beta}2-glycoprotein I for ApoER2' on platelets is located in domain V

The antiphospholipid syndrome is caused by autoantibodies directed against beta(2)-glycoprotein I (beta(2)GPI). Dimerization of beta(2)GPI results in an increased platelet deposition to collagen. We found that apolipoprotein E receptor 2' (apoER2'), a member of the low density lipoprotein receptor family, is involved in activation of platelets by dimeric beta(2)GPI. To identify which domain of dimeric beta(2)GPI interacts with apoER2', we have constructed domain deletion mutants of dimeric beta(2)GPI, lacking domain I (DeltaI), II (DeltaII), or V (DeltaV), and a mutant with a W316S substitution in the phospholipid (PL)-insertion loop of domain V. DeltaI and DeltaII prolonged the clotting time, as did full-length dimeric beta(2)GPI; DeltaV had no effect on the clotting time. Second, DeltaI and DeltaII bound to anionic PL, comparable with full-length dimeric beta(2)GPI. DeltaV and the W316S mutant bound with decreased affinity to anionic PL. Platelet adhesion to collagen increased significantly when full-length dimeric beta(2)GPI, DeltaI, or DeltaII (mean increase 150%) were added to whole blood. No increase was found with plasma beta(2)GPI, DeltaV, or the W316S mutant. Immunoprecipitation indicated that full-length dimeric beta(2)GPI, DeltaI, DeltaII, and the W316S mutant can interact with apoER2' on platelets. DeltaV did not associate with apoER2'. We conclude that domain V is involved in both binding beta(2)GPI to anionic PL and in interaction with apoER2' and subsequent activation of platelets. The binding site in beta(2)GPI for interaction with apoER2' does not overlap with the hydrophobic insertion loop in domain V.     

Mapping of a substrate binding site in the protein disulfide isomerase-related chaperone wind based on protein function and crystal structure

The protein disulfide isomerase (PDI)-related protein Wind is essential in Drosophila melanogaster, and is required for correct targeting of Pipe, an essential Golgi transmembrane 2-O-sulfotransferase. Apart from a thioredoxin fold domain present in all PDI proteins, Wind also has a unique C-terminal D-domain found only in PDI-D proteins. Here, we show that Pipe processing requires dimeric Wind, which interacts directly with the soluble domain of Pipe in vitro, and we map an essential substrate binding site in Wind to the vicinity of an exposed cluster of tyrosines within the thioredoxin fold domain. In vitro, binding occurs to multiple sites within the Pipe polypeptide and shows specificity for two consecutive aromatic residues. A second site in Wind, formed by a cluster of residues within the D-domain, is likewise required for substrate processing. This domain, expressed separately, impairs Pipe processing by the full-length Wind protein, indicating competitive binding to substrate. Our data represent the most accurate map of a peptide binding site in a PDI-related protein available to date and directly show peptide specificity for a naturally occurring substrate.