CH/π interactions of π-system of acetylacetonato chelate ring: Comparison of CH/π interactions of Ni(II)-acetylacetonato chelate and benzene rings

The calculations have been done for CH/π interaction with π-system of Ni(II)-acetylacetonato chelate ring. The results show that there is an attractive electrostatic interaction, while dispersion component is a major source of attractive interacting energies. The interaction was compared with CH/π interaction between two benzene rings. The comparison shows that two interactions are quite similar, enabling to estimate the energy of CH/π interaction with π-system of Ni(II)-acetylacetonato chelate ring to be about 10.5 kJ/mol. The results indicate that CH/π interactions of chelate ring in various molecular systems can be as important as CH/π interactions of phenyl ring.     

The role of carboxymethyl substituents in the interaction of tetracationic porphyrins with DNA

Cationic porphyrin-based compounds capable of interacting with DNA are currently under extensive investigation as prospective anticancer and anti-infective drugs. One of the approaches to enhancing the DNA-binding affinity of these ligands is chemical modification of functional groups of the porphyrin macrocycle. We analyzed the interaction with DNA of novel derivatives containing carboxymethyl and ethoxycarbonylmethyl substituents at quaternary nitrogen atoms of pyridinium groups at the periphery of the porphyrin macrocycle. The parameters of binding of 5,10,15,20-tetrakis(N-carboxymethyl-4-pyridinium)porphyrin (P1) and 5,10,15,20-tetrakis(N-ethoxycarbonylmethyl-4-pyridinium)porphyrin (P2) to double-stranded DNA sequences of different nucleotide content were determined using optical spectroscopy. The association constant of P1 interaction with calf thymus DNA (K?=?3.4?×?10(6)?M(-1)) was greater than that of P2 (K?=?2.8?×?10(5)?M(-1)). Preferential binding of P1 to GC- rather than AT-rich oligonucleotides was detected. In contrast, P2 showed no preference for particular nucleotide content. Modes of binding of P1 and P2 to GC and AT duplexes were verified using the induced circular dichroism spectra. Molecular modeling confirmed an intercalative mode of interaction of P1 and P2 with CpG islands. The carboxyl groups of the peripheral substituent in P1 determine the specific interactions with GC-rich DNA regions, whereas ethoxycarbonylmethyl substituents disfavor binding to DNA. This study contributes to the understanding of the impact of peripheral substituents on the DNA-binding affinity of cationic porphyrins, which is important for the design of DNA-targeting drugs.     

Structure of malaria pigment and related propanoate-linked metalloporphyrin dimers

Malaria pigment, the heme detoxification product of malaria's invasion, digestion, and growth inside mammalian red blood cells, is an insoluble phase of iron(III)protoporphyrin-IX. Even though its structure was determined in 2000 by powder X-ray diffraction, significant questions remain about its formation and possible interaction with quinoline antimalarial drugs. A recent structural study, also with X-ray powder diffraction, has reconfirmed that the material isolated from the parasite is isostructural with its synthetic equivalent. It was recently suggested that other isomers may also be formed and may be present in synthetic samples. In particular, a series of stereoisomers are possible for the arrangement of vinyl groups on the periphery of the dimerized porphyrin rings. In principle, any given dimer can have vinyl groups at the α or β sites, and at γ or δ sites. In this paper, several models are evaluated, both biphasic and homogeneous methyl/vinyl disorder, against several sets of diffraction data, both published and new. We conclude that methyl/vinyl disorder is intrinsic to the system, and that the evidence at hand does not support the existence of any other crystalline isomers in carefully prepared samples of either natural or synthetic samples. Finally, the porphyrin?porphyrin interactions are evaluated using Scheidt's indicies for porphyrin π-stacking, and we find modest to weak π-interactions in these condensed phases.     

Heparin-induced circular dichroism of chloroquine

Circular dichroism (CD) and UV/Visible absorption (UV/Vis) spectroscopy techniques were used to investigate the interaction between heparin and chloroquine, an antimalarial drug that has shown potential as an anti-prion agent. CD spectra of rac-chloroquine upon addition of heparin provide evidence of glycosaminoglycan (GAG) binding, support recent findings suggesting that interactions between heparin and antimalarial drugs are largely due to electrostatic interactions, and represent the first reported GAG-induced CD signal of a bicyclic, aromatic compound. The association constant (∼10³ M⁻¹) between chloroquine and heparin was calculated from a UV titration curve and provided additional insight into the nature of the association between these two compounds.     

The reaction of artemisinin with hemin: a further insight into the mechanism

The mechanism of action of trioxane antimalarial drugs is still largely controversial and warrants further investigation. We report here on the direct reaction of artemisinin with hemin, carried out in DMSO, in the absence of reducing agents. The reaction was analysed, independently, by visible spectroscopy, HPLC-ESI/MS and ¹H NMR. Two isomeric artemisinin-hemin long-lived adducts are unambiguously detected. Eventual degradation of the porphyrin ring and loss of the Soret band are observed as well. Implications of the present results for the mechanism of action of artemisinin-based antimalarials are discussed.     

The procapsid binding domain of phi29 packaging RNA has a modular architecture and requires 2'-hydroxyl groups in packaging RNA interaction

The phi29 packaging RNA (pRNA) is an essential component in the phi29 bacteriophage DNA packaging motor, the strongest biomolecular motor known today. Utilizing Mg2+-dependent intermolecular base pairing interactions between two 4-nucleotide loops within the pRNA procapsid binding domain, multiple copies of pRNA form a ring-shaped complex that is indispensable for packaging motor function. To understand pRNA structural organization and pRNA/pRNA interaction, studies were carried out on pRNA closed dimers, the simplest functional pRNA complex believed to be the building blocks for assembling the oligomeric ring. Tertiary folding and interactions in various pRNA mutants were evaluated based on measured closed dimer affinity that is directly linked to the proper positioning of the interacting loops. The data revealed that the procapsid binding domain contains two autonomous modules that are capable of interacting noncovalently to form a fully active species in pRNA/pRNA interaction. Deleting the 2'-hydroxyl groups in one of the interacting loops weakens the dimer affinity by 125-fold, suggesting potential tertiary interactions involving these 2'-hydroxyl groups. The results provide evidence that nonbase functional groups are involved in pRNA folding and interaction and lead to a simple model that describes the pRNA monomer configuration in terms of three arms spanning a hinge. The functional constructs developed here will aid biophysical and biochemical investigations of pRNA structure and function, as well as developments of pRNA-based technology for nanoscience and gene therapy.     

Impacts of enemy-mediated effects and the additivity of interactions in an insect trophic system

In this study, we used data from both experiments and mathematical simulations to analyze the consequences of the interacting effects of intraguild predation (IGP), cannibalism and parasitism occurring in isolation and simultaneously in trophic interactions involving two blowfly species under shared parasitism. We conducted experiments to determine the short-term response of two blowfly species to these interactions with respect to their persistence. A mathematical model was employed to extend the results obtained from these experiments to the long-term consequences of these interactions for the persistence of the blowfly species. Our experimental results revealed that IGP attenuated the strength of the effects of cannibalism and parasitism between blowfly host species, increasing the probability of persistence of both populations. The simulations obtained from the mathematical model indicated that IGP is a key interaction for the long-term dynamics of this system. The presence of different species interacting in a tri-trophic system relaxed the severity of the effects of a particular interaction between two species, changing species abundances and promoting persistence through time. This pattern was related to indirect interactions with a third species, the parasitoid species included in this study.     

Interaction of chloroquine and its analogues with heme: An isothermal titration calorimetric study

Quinoline-containing drugs such as chloroquine and quinine have had a long and successful history in antimalarial chemotherapy. Identification of ferriprotoporphyrin IX ([Fe(III)PPIX], haematin) as the drug receptors for these antimalarials called for investigations of the binding affinity, mode of interaction, and the conditions affecting the interaction. The parameters obtained are significant in recent times with the emergence of chloroquine resistant strains of the malaria parasites. This has underlined the need to unravel the molecular mechanism of their action so as to meet the requirement of an alternative to the existing antimalarial drugs. The isothermal titration calorimetric studies on the interaction of chloroquine with haematin lead us to propose an altered mode of binding. The initial recognition is ionic in nature mediated by the propionyl group of haematin with the quaternary nitrogen on CQ. This ionic interaction induces a conformational change, such as to favour binding of subsequent CQ molecules. On the contrary, conditions emulating the cytosolic environment (pH 7.4 and 150 mM salt) reveal the hydrophobic force to be the sole contributor driving the interaction. Interaction of a carefully selected panel of quinoline antimalarial drugs with monomeric ferriprotoporphyrin IX has also been investigated at pH 5.6 mimicking the acidic environment prevalent in the food vacuoles of parasite, the center of drug activity, which are consistent with their antimalarial activity.     

Intra- and interspecific tree diversity promotes multitrophic plant–Hemiptera–ant interactions in a forest diversity experiment

Interactions between species of different trophic levels have long been recognized as fundamental processes in ecology. Although mounting evidence indicates that plant species diversity (PSD) or plant genetic diversity (PGD) can influence the plant-associated arthropod community, these two fundamental levels of biodiversity are not often manipulated simultaneously to assess their effects on species interactions. We used a large tree diversity experiment (BEF-China), which manipulates PSD and PGD in a crossed design to test individual and combined effects of PSD and PGD on multitrophic interaction networks and interaction partner species richness and occurrence. We focused on two tree species, on which sap-sucking Hemiptera and interacting ant species commonly occur. This tri-trophic interaction can be divided into the antagonistic plant–Hemiptera interaction and the mutualistic Hemiptera–ant interaction, known as trophobioses. Qualitative evaluation of tri-trophic interaction networks at different PSD and PGD combinations showed increased interaction partner redundancy at high PSD and PGD. This was supported by increased Hemiptera species richness at high PSD and PGD. Furthermore, the data indicate higher occurrence of Hemiptera and trophobioses and higher trophobiotic ant species richness with increasing PSD and PGD. As no plant diversity component alone caused an effect we conclude that the combined effect of high PGD and high PSD might be additive. In summary, as plant genetic diversity, especially at low species richness, seems to increase the interaction partner redundancy in interaction networks and the diversity of interacting communities, we suggest that genetic diversity should be considered in forest conservation and restoration programs.     

Direct interaction of tricyclic antidepressants with opiate binding sites in the bovine adrenal medulla

This note reports the interaction of three currently used tricyclic antidepressant drugs (clomipramine, imipramine and amitriptyline) with delta, mu and kappa opioid binding sites in the bovine adrenal medulla. Clomipramine was the only drug interacting with delta and mu sites. On the contrary, all three drugs showed a significant interactions with subtypes of the kappa binding site. Clomipramine was the most active on the kappa 2 and kappa 3 subtypes while amitriptyline showed the highest interaction with the kappa 1 subtype. On the contrary the tricyclic cyproheptadine did not present any interaction with opioid binding sites in our system. This interaction between tricyclic antidepressants and opioid binding sites might be the origin of their analgesic action.     

Linear free energy relationships predict coordination and π-stacking interactions of small molecules with ferriprotoporphyrin IX

In order to better understand the interaction of antimalarial compounds with ferriprotoporphyrin IX (Fe(III)PPIX), association constants of pyridines, imidazoles, amines and phenolates with Fe(III)PPIX and protoporphyrin IX (PPIX) have been measured spectrophotometrically in 40% (v/v) aq. DMSO at pH 7.4. The pH independent log association constants for coordination of nitrogen donor ligands exhibit a linear free energy relationship (LFER) with the pK_a of the donor atom. Association through π-stacking interactions (log K_π) with PPIX and Fe(III)PPIX increases with the number of π-electrons in the aromatic ring system. These findings indicate that in the aqueous milieu of the malaria parasite digestive vacuole, coordination to the Fe(III) center of the porphyrin is necessarily very weak, while π-stacking interactions will be much stronger. On the other hand, in environments in which proton competition is absent, coordination will dominate, with the most basic donor atoms forming the strongest complexes with Fe(III)PPIX. The lipid nanospheres within the digestive vacuole which are now known to be the location of conversion of Fe(III)PPIX to hemozoin could possibly be such an environment, making both types of interaction relevant to the design of new hemozoin inhibitors.     

Improving species distribution models using biotic interactions: a case study of parasites,pollinators and plants

Biotic interactions have been considered as an important factor to be included in species distribution modelling, but little is known about how different types of interaction or different strategies for modelling affect model performance. This study compares different methods for including interspecific interactions in distribution models for bees, their brood parasites, and the plants they pollinate. Host–parasite interactions among bumble bees (genus Bombus: generalist pollinators and brood parasites) and specialist plant–pollinator interactions between Centris bees and Krameria flowers were used as case studies. We used 7 different modelling algorithms available in the BIOMOD R package. For Bombus, the inclusion of interacting species distributions generally increased model predictive accuracy. The improvement was better when the interacting species was included with its raw distribution rather than with its modeled suitability. However, incorporating the distributions of non‐interacting species sometimes resulted in similarly increased model accuracy despite their being no significance of any interaction for the distribution. For the Centris‐Krameria system the best strategy for modelling biotic interactions was to include the interacting species model‐predicted values. However, the results were less consistent than those for Bombus species, and most models including biotic interactions showed no significant improvement over abiotic models. Our results are consistent with previous studies showing that biotic interactions can be important in structuring species distributions at regional scales. However, correlations between species distributions are not necessarily indicative of interactions. Therefore, choosing the correct biotic information, based on biological and ecological knowledge, is critical to improve the accuracy of species distribution models and forecast distribution change.     

Effect of colony size on the competitive outcome of encrusting colonial organisms

The relative importance of colony size ratio of interacting species was studied in Tomioka Bay, Japan. Six encrusting colonial species belonging to the following three different taxonomic groups were tested: Ascidia (three species), Bryozoa (two) and Porifera (one). Colonies of these organisms were grown in the community of sessile organisms developed on plastic panels. Logistic regression analysis was carried out to determine the effect of size ratio on the competitive outcome of interacting colonies. The results between all possible combinations among these six species did not show a significant size effect in competitive outcome (i.e. a larger colony size did not always prove important in the success of a competitive interaction with smaller colonies of other species). On the contrary, competitive success depends on the types of species interacting. Certain species such asDidemnum moseleyi (ascidian) andHaliclona sp. (sponge), in spite of being smaller in colony size, won in competitive interactions with larger colonies of other species such asDiplosoma mitsukurii (ascidian) andWatersipora subovoidea (bryozoan). These results contradict the one reported earlier: that the larger the colony size, the more chance the colony will have to win in competitive interactions.     

The structure of sitting-atop complexes of metalloporphyrins studied by theoretical methods

The metallation of tetrapyrroles is believed to proceed via a sitting-atop (SAT) complex, in which some of the pyrrole nitrogen atoms are still protonated and the metal ion resides above the ring plane. No crystal structure of such a complex has been presented, but NMR and extended X-ray absorption fine structure (EXAFS) data has been reported for Cu(2+) in acetonitrile. We have used density functional calculations to obtain reasonable models for SAT complexes of porphyrins with Mg(2+), Fe(2+), and Cu(2+). The results show that there are many possible SAT complexes with 1-5 solvent molecules, one or two metal ions, and cis or trans protonation of the porphyrin ring. Many of these have similar energies and their relative stabilities vary with the metal ion. A complex with two cis pyrrolenine nitrogens atoms and 2-4 solvent molecules coordinated to Cu(2+) fits the NMR and EXAFS data best. However, we cannot fully exclude the possibility that what is observed is rather a mixture of a doubly protonated porphyrin and the copper porphyrin. Mg(2+) has a lower affinity for porphyrin and stronger affinity for water, so a complex with five water molecules and only one bond to porphyrin seems to be most stable. For Fe(2+), a cis structure with two first-sphere water molecules and four interactions to the porphyrin seems to be most likely.     

Non-canonical interactions of porphyrins in porphyrin-containing proteins

In this study we have described the non-canonical interactions between the porphyrin ring and the protein part of porphyrin-containing proteins to better understand their stabilizing role. The analysis reported in this study shows that the predominant type of non-canonical interactions at porphyrins are CH···O and CH···N interactions, with a small percentage of CH···π and non-canonical interactions involving sulfur atoms. The majority of non-canonical interactions are formed from side-chains of charged and polar amino acids, whereas backbone groups are not frequently involved. The main-chain non-canonical interactions might be slightly more linear than the side-chain interactions, and they have somewhat shorter median distances. The analysis, performed in this study, shows that about 44% of the total interactions in the dataset are involved in the formation of multiple (furcated) non-canonical interactions. The high number of porphyrin–water interactions show importance of the inclusion of solvent in protein–ligand interaction studies. Furthermore, in the present study we have observed that stabilization centers are composed predominantly from nonpolar amino acid residues. Amino acids deployed in the environment of porphyrin rings are deposited in helices and coils. The results from this study might be used for structure-based porphyrin protein prediction and as scaffolds for future porphyrin-containing protein design.     

Keystone species and vulnerable species in ecological communities: strong or weak interactors?

The loss of a species from an ecological community can trigger a cascade of secondary extinctions. The probability of secondary extinction to take place and the number of secondary extinctions are likely to depend on the characteristics of the species that is lost--the strength of its interactions with other species--as well as on the distribution of interaction strengths in the whole community. Analysing the effects of species loss in model communities we found that removal of the following species categories triggered, on average, the largest number of secondary extinctions: (a) rare species interacting strongly with many consumers, (b) abundant basal species interacting weakly with their consumers and (c) abundant intermediate species interacting strongly with many resources. We also found that the keystone status of a species with given characteristics was context dependent, that is, dependent on the structure of the community where it was embedded. Species vulnerable to secondary extinctions were mainly species interacting weakly with their resources and species interacting strongly with their consumers.     

Structural studies of metalloporphyrins. Part XIa: Complexes of water-soluble zinc(II) porphyrins with amino acids: influence of ligand-ligand interactions on the stability of the complexes

The stability constants of a series of complexes of the cationic water-soluble porphyrin ZnTMPyP with various amino acids have been determined by 1H NMR spectroscopy at pH 10.5. The following stability order has been observed: Tyr greater than Phe, Glu greater than Asp greater than Ile greater than Val greater than Gly. These results can be best rationalized by invoking complex stabilization due to ligand-ligand (e.g., stacking or electrostatic) interactions. Evidence for stacking interactions between the porphyrin ring and the aromatic ring of phenylalanine, tyrosine, and tryptophan was further provided by study of the complexation of these amino acids with the free-base porphyrin TMPyPH2. In this case, complexation constants increased in the order: Phe less than Tyr less than Trp. Attempts to form complexes of the amino acids with the anionic porphyrin ZnTCPP proved unsuccessful, indicating that electrostatic interactions play a major role in the stability of the zinc porphyrin-amino acids complexes.     

Heparin-induced circular dichroism of an achiral, bicyclic species

Antimalarial drugs have shown potential in suppressing the role of glycosaminoglycans (GAGs) in the pathology of prion protein conformational disorders (e.g. "Mad Cow" disease) by competing for sites of electrostatic interaction. In this study, circular dichroism (CD) and UV/Visible (UV/Vis) absorption spectroscopy techniques were used to investigate the interactions between N-methyl-N'-(7-chloro-4-quinolyl)-1,3-diaminopropane (QD), an achiral, bicyclic compound similar to previously investigated antimalarial drugs, and heparin, a complex GAG that is frequently used as a clinical anticoagulant. Relatively intense heparin-induced CD features were observed for QD and were noted to be radically different from previous studies using related chiral drugs, underscoring the importance of the Pfieffer effect on this and similar heparin research. Additionally, the induced CD for QD was observed to be highly dependent upon drug concentration, heparin concentration, system pH, equilibration time, and ionic strength. These results, in connection with recent work, provide new insight into the nature of the association between GAGs and antimalarial species.     

Finding NEMO: nestedness engendered by mutualistic organization in anemonefish and their hosts

The interaction structure of mutualistic relationships, in terms of relative specialization of the partners, is important to understanding their ecology and evolution. Analyses of the mutualistic interaction between anemonefish and their host sea anemones show that the relationship is highly nested in structure, generalist species interacting with one another and specialist species interacting mainly with generalists. This supports the hypothesis that the configuration of mutualistic interactions will tend towards nestedness. In this case, the structure of the interaction is at a much larger scale than previously hypothesized, across more than 180 degrees of longitude and some 60 degrees of latitude, probably owing to the pelagic dispersal capabilities of these species in a marine environment. Additionally, we found weak support for the hypothesis that geographically widespread species should be more generalized in their interactions than species with small ranges. This study extends understanding of the structure of mutualistic relationships into previously unexplored taxonomic and physical realms, and suggests how nestedness analysis can be applied to the conservation of obligate species interactions.     

Interaction of quinoline antimalarial drugs with ferriprotoporphyrin IX, a solid state spectroscopy study

To investigate the nature of binding of quinoline antimalarial drugs to heme and to extract experimental evidence for this binding, the interaction of ferriprotoporphyrin IX (FP) with chloroquine and quinacrine (both of which have a similar side chain) and quinoline methanol antimalarials quinine and mefloquine has been studied using IR and NIR-Raman spectroscopy in the solid state. Attenuated total reflectance infrared spectroscopic data clearly show that heme in chloroquine-FP complex is not μ-oxo dimeric indicating that the hypothesis that chloroquine binds to FP μ-oxo dimer with a stoichiometry of 1 chloroquine:2 μ-oxo dimers is not valid in the solid state. Moreover, the first vibrational spectroscopy evidence is presented for the formation of hydrogen bonding between a propionate group of heme and the tertiary amino nitrogen of chloroquine and quinacrine. Raman spectroscopy data does not provide any evidence to support the formation of a similar salt bridge in the complexes of FP with quinine and mefloquine; however, it suggests that the interaction of these drugs with FP happens through coordination of the Fe(III) center of the porphyrin to the 9-hydroxy group of the drug.