A cytotoxicity,optical spectroscopy and computational binding analysis of 4‐[3‐acetyl‐5‐(acetylamino)‐2‐methyl‐2,3‐dihydro‐1,3,4‐thiadiazole‐2‐yl]phenyl benzoate in calf thymus DNA

In this study the interaction mechanism between newly synthesized 4‐(3‐acetyl‐5‐(acetylamino)‐2‐methyl‐2, 3‐dihydro‐1,3,4‐thiadiazole‐2‐yl) phenyl benzoate (thiadiazole derivative) anticancer active drug with calf thymus DNA was investigated by using various optical spectroscopy techniques along with computational technique. The absorption spectrum shows a clear shift in the lower wavelength region, which may be due to strong hypochromic effect in the ctDNA and the drug. The results of steady state fluorescence spectroscopy show that there is static quenching occurring while increasing the thiadiazole drug concentration in the ethidium bromide‐ctDNA system. Also the binding constant (K), thermo dynamical parameters of enthalpy change (ΔH°), entropy change (ΔS°) Gibbs free energy change (ΔG°) were calculated at different temperature (293 K, 298 K) and the results are in good agreement with theoretically calculated MMGBSA binding analysis. Time resolved emission spectroscopy analysis clearly explains the thiadiazole derivative competitive intercalation in the ethidium bromide‐ctDNA system. Further, molecular docking studies was carried out to understand the hydrogen bonding and hydrophobic interaction between ctDNA and thiadiazole derivative molecule. In addition the docking and molecular dynamics charge distribution analysis was done to understand the internal stability of thiadiazole derivative drug binding sites of ctDNA. The global reactivity of thiadiazole derivative such as electronegativity, electrophilicity and chemical hardness has been calculated.     

Structural insights into the inclusion complexes between clomiphene citrate and β‐cyclodextrin: The mechanism of preferential isomeric selection

A major challenge in pharmaceuticals for clinical applications is to alter the solubility, stability, and toxicity of drug molecules in living systems. Cyclodextrins (CDs) have the ability to form host–guest inclusion complexes with pharmaceuticals for further development of new drug formulations. The inclusion complex of clomiphene citrate (CL), a poorly water‐soluble drug, with native β‐cyclodextrin (β‐CD) was characterized by a one and two‐dimensional nuclear magnetic resonance (NMR) spectroscopic approach and also by molecular docking techniques. Here we report NMR and a computational approach in preferential isomeric selection of CL, which exists in two stereochemical isomers, enclomiphene citrate (ENC; E isomer) and zuclomiphene citrate (ZNC; Z isomer) with β‐CD. β‐CD cavity protons, namely, H‐3′ and H‐5′, experienced shielding in the presence of CL. The aromatic ring protons of the CL molecule were observed to be deshielded in the presence of β‐CD. The stoichiometric ratio of the β‐CD:CL inclusion complex was observed by NMR and found to be 1:1. The overall binding constant of β‐CD:CL inclusion complexes was based on NMR chemical shifts and was calculated to be 50.21 M⁻¹. The change in Gibb's free energy (∆G) was calculated to be −9.80 KJ mol⁻¹. The orientation and structure of the β‐CD:CL inclusion complexes are proposed on the basis of NMR and molecular docking studies. 2D ¹H‐¹H ROESY confirmed the involvement of all three aromatic rings of CL in the inclusion complexation with β‐CD in the solution, confirming the multiple equilibria between β‐CD and CL. Molecular docking and 2D ¹H‐¹H ROESY provide insight into the inclusion complexation of two isomers of CL into the β‐CD cavity. A molecular docking technique further provided the different binding affinities of the E and Z isomers of CL with β‐CD and confirmed the preference of the Z isomer binding for β‐CD:CL inclusion complexes. The study indicates that the formation of a hydrogen bond between –O– of CL and the hydrogen atom of the hydroxyl group of β‐CD was the main factor for noncovalent β‐CD:CL inclusion complex formation and stabilization in the aqueous phase.     

Supramolecular interactions between β‐lapachone with cyclodextrins studied using isothermal titration calorimetry and molecular modeling

Supramolecular interactions between β‐lapachone (β‐lap) and cyclodextrins (CDs) were investigated by isothermal titration calorimetry. The most favorable host: guest interaction was characterized using X‐ray powder diffraction (XRD), differential scanning calorimetry and thermogravimetry (DSC/TG), spectroscopy (FT‐IR), spectroscopy (2D ROESY) nuclear magnetic resonance (NMR), and molecular modeling. Phase solubility diagrams showed β‐, HP‐β‐, SBE‐β‐, γ‐, and HP‐γ‐CDs at 1.5% (w/w) allowed an increase in apparent solubility of β‐lap with enhancement factors of 12.0, 10.1, 11.8, 2.4, and 2.2, respectively. β‐lap has a weak interaction with γ‐ and HP‐γ‐CDs and tends to interact more favorably with β‐CD and its derivatives, especially SBE‐β‐CD (K = 4160 M⁻¹; ΔG = −20.66 kJ·mol⁻¹). Thermodynamic analysis suggests a hydrophobic interaction associated with the displacement of water from the cavity of the CD by the β‐lap. In addition, van der Waals forces and hydrogen bonds were responsible for the formation of complexes. Taken together, the results showed intermolecular interactions between β‐lap and SBE‐β‐CD, thereby confirming the formation of the inclusion complex. Molecular docking results showed 2 main orientations in which the interaction of benzene moiety at the wider rim of the SBE‐β‐CD is the most stable (average docking energy of −7.0 kcal/mol). In conclusion, β‐lap:SBE‐β‐CD is proposed as an approach for use in drug delivery systems in cancer research.     

CD‐sensitive Zn‐porphyrin tweezer host‐guest complexes,part 2: Cis‐ and trans‐3‐hydroxy‐4‐aryl/alkyl‐β‐lactams. A case study

This article describes an application of the host‐guest chiral recognition approach called tweezer methodology for the determination of the absolute configuration of 3‐hydroxy‐β‐lactams. These substrates represent challenging cases due to their chemical reactivity, the presence of multiple stereogenic centers and several functional groups which offer various possibilities of binding to the Zn‐porphyrin host. OPLS‐2005, the force field used in this work to predict the interporphyrin twist, modeled correctly the host‐guest complexation mechanism and revealed conformational details of the bound substrates. The computational study also suggested that in cases where an increase in the magnitude of the stereodifferentiation and an intense experimental CD are observed, the bound conformation of the conjugates are hydrogen bonded. The present investigation provides evidence that when the tweezer method is assisted by the OPLS‐2005 based computational approach, it can be successfully applied to the configurational and conformational elucidation of multi‐functional compounds with multiple stereogenic centers. Chirality, 2010. © 2009 Wiley‐Liss, Inc.     

A new fluorescent chemosensor for cadmium(II) based on a pyrene‐appended piperidone derivative and its β‐cyclodextrin complex

We report, in this article, a piperidin‐4‐one derivative carrying pyrenyl fluorescent reporter groups which acts as a Cd²⁺ ion sensor. The compound is synthesized and characterized using IR and NMR spectral techniques. The compound forms an inclusion complex with β‐cyclodextrin. It selectively binds to Cd²⁺ ions in water and aqueous β‐cyclodextrin media. The stoichiometry of the host–guest complex of the compound with β‐cyclodextrin is 1:2. The ligand–metal ion binding stoichiometry is 1:1 both in water and in β‐cyclodextrin. The linear concentration range of detection of the metal ion is reported. Cyclodextrin complex formation does not affect the metal ion selectivity of the compound.     

Comprehensive analysis of the atenolol – DNA complex by viscometric,molecular docking and spectroscopic techniques

This paper discusses multi‐spectroscopic and molecular docking analysis of the interaction between atenolol (ATN) and deoxyribose nucleic acid (DNA) using alizarin (ALZ) as a spectroscopic probe. ATN is a β₁‐receptor antagonist belonging to the β‐blocker class of molecules. Experimental findings that were based on different spectroscopic analysis, melting studies, viscometric analysis, ¹H nuclear magnetic resonance and circular dichroism studies revealed the presence of a grove‐binding mode. The effect of ionic strength was also studied, and observations suggested that electrostatic interaction also played a minor role during interaction. Molecular docking analysis suggested that the dominant force for the grove‐binding phenomenon was hydrogen bonding between the 24‐H residue of ATN and O of the 10‐G residue, and the 40‐H residue of ATN and N of the 17‐A base residue. Competitive binding study of the ALZ?DNA complex with ATN showed that, despite an increase in the amount of ATN in the ALZ?DNA complex, the overall absorbance remained unchanged. The decrease in fluorescence in the ALZ?DNA system may be due to new non‐fluorescent ATN?DNA?ALZ complex formation.     

Revealing interaction between sulfobutylether‐β‐cyclodextrin and reserpine by chemiluminescence and site‐directed molecular docking

The host–guest interaction between sulfobutylether‐β‐cyclodextrin (SBE‐β‐CD) and reserpine (RSP) is described using flow injection‐chemiluminescence (FI‐CL) and site‐directed molecular docking methods. It was found that RSP could inhibit the CL intensity produced by a luminol/SBE‐β‐CD system. The decrease in CL intensity was logarithmic over an RSP concentration range of 0.03 to 700.0 nM, giving a regression equation of ?I = 107.1lgC_RES + 186.1 with a detection limit of 10 pM (3σ). The CL assay was successfully applied in the determination of RSP in injection, saliva and urine samples with recoveries in the range 93.5–106.1%. Using the proposed CL model, the binding constant (K_CD‐R) and the stoichiometric ratio of SBE‐β‐CD/RSP were calculated to be 7.4 × 10⁶ M^‐1 and 1 : 1, respectively. Using molecular docking, it was confirmed that luminol binds to the small cavity of SBE‐β‐CD with a nonpolar interaction, while RSP targeted the larger cavity of SBE‐β‐CD and formed a 1 : 1 complex with hydrogen bonds. The proposed new CL method has the potential to become a powerful tool for revealing the host–guest interaction between CDs and drugs, as well as monitoring drugs with high sensitivity. Copyright © 2013 John Wiley & Sons, Ltd.     

Building a foundation for structure‐based cellulosome design for cellulosic ethanol: Insight into cohesin‐dockerin complexation from computer simulation

The organization and assembly of the cellulosome, an extracellular multienzyme complex produced by anaerobic bacteria, is mediated by the high‐affinity interaction of cohesin domains from scaffolding proteins with dockerins of cellulosomal enzymes. We have performed molecular dynamics simulations and free energy calculations on both the wild type (WT) and D39N mutant of the C. thermocellum Type I cohesin‐dockerin complex in aqueous solution. The D39N mutation has been experimentally demonstrated to disrupt cohesin‐dockerin binding. The present MD simulations indicate that the substitution triggers significant protein flexibility and causes a major change of the hydrogen‐bonding network in the recognition strips—the conserved loop regions previously proposed to be involved in binding—through electrostatic and salt‐bridge interactions between β‐strands 3 and 5 of the cohesin and α‐helix 3 of the dockerin. The mutation‐induced subtle disturbance in the local hydrogen‐bond network is accompanied by conformational rearrangements of the protein side chains and bound water molecules. Additional free energy perturbation calculations of the D39N mutation provide differences in the cohesin‐dockerin binding energy, thus offering a direct, quantitative comparison with experiments. The underlying molecular mechanism of cohesin‐dockerin complexation is further investigated through the free energy profile, that is, potential of mean force (PMF) calculations of WT cohesin‐dockerin complex. The PMF shows a high‐free energy barrier against the dissociation and reveals a stepwise pattern involving both the central β‐sheet interface and its adjacent solvent‐exposed loop/turn regions clustered at both ends of the β‐barrel structure.     

μ2‐Dependent endocytosis of N‐cadherin is regulated by β‐catenin to facilitate neurite outgrowth

Circuit formation in the brain requires neurite outgrowth throughout development to establish synaptic contacts with target cells. Active endocytosis of several adhesion molecules facilitates the dynamic exchange of these molecules at the surface and promotes neurite outgrowth in developing neurons. The endocytosis of N‐cadherin, a calcium‐dependent adhesion molecule, has been implicated in the regulation of neurite outgrowth, but the mechanism remains unclear. Here, we identified that a fraction of N‐cadherin internalizes through clathrin‐mediated endocytosis (CME). Two tyrosine‐based motifs in the cytoplasmic domain of N‐cadherin recognized by the μ2 subunit of the AP‐2 adaptor complex are responsible for CME of N‐cadherin. Moreover, β‐catenin, a core component of the N‐cadherin adhesion complex, inhibits N‐cadherin endocytosis by masking the 2 tyrosine‐based motifs. Removal of β‐catenin facilitates μ2 binding to N‐cadherin, thereby increasing clathrin‐mediated N‐cadherin endocytosis and neurite outgrowth without affecting the steady‐state level of surface N‐cadherin. These results identify and characterize the mechanism controlling N‐cadherin endocytosis through β‐catenin‐regulated μ2 binding to modulate neurite outgrowth.      

Spectrofluorimetric determination of the antineoplastic agent lomustine based on the sensitizing effect of β‐cyclodextrin

The effects of solvent dipolarity/polarizability and solvent–solute hydrogen bonding on the photophysical properties of the antineoplastic drug lomustine were analysed by means of the linear solvation energy relationship (LSER) concept proposed by Kamlet and Taft. The LSER method enabled the overall solvent effects to be quantitatively estimated and separated into specific and non‐specific contributions. The molecular encapsulation of lomustine by β‐cyclodextrin (β‐CD) has been studied using fluorescence spectroscopy. The results are discussed in terms of the binding parameter and the effect of the solvent used. It was concluded that β‐CD forms a 1:1 inclusional complex with lomustine in acetonitrile solution and its association constant was calculated to be 500 M^?1. In addition, and for the first time, a simple, rapid and high sensitive fluorimetric method for the determination of lomustine was developed based upon the enhancement effect produced through complex formation with β‐CD. The new approach for the quantification of lomustine in the presence of β‐CD was described in aqueous and organic solutions. Better limits of detection (0.31 µg ml^?1) and quantification (1.05 µg ml^?1) were obtained in aqueous solution with respect to those obtained in organic solvent. Copyright © 2015 John Wiley & Sons, Ltd.     

Polyethylene glycol‐based low generation dendrimers functionalized with β‐cyclodextrin as cryo‐ and dehydro‐protectant of catalase formulations

Polyethylene glycol (PEG)‐based low generation dendrimers are analyzed as single excipient or combined with trehalose in relation to their structure and efficiency as enzyme stabilizers during freeze‐thawing, freeze‐drying, and thermal treatment. A novel functional dendrimer (DG_o‐CD) based on the known PEG's ability as cryo‐protector and β‐CD as supramolecular stabilizing agent is presented. During freeze‐thawing, PEG and β‐CD failed to prevent catalase denaturation, while dendrimers, and especially DG_o‐CD, offered the better protection to the enzyme. During freeze‐drying, trehalose was the best protective additive but DG_o‐CD provided also an adequate catalase stability showing a synergistic behavior in comparison to the activities recovered employing PEG or β‐CD as unique additives. Although all the studied dendrimers improved the enzyme remaining activity during thermal treatment of freeze‐dried formulations, the presence of amorphous trehalose was critical to enhance enzyme stability. The crystallinity of the protective matrix, either of PEG derivatives or of trehalose, negatively affected catalase stability in the freeze‐dried systems. When humidified at 52% of relative humidity, the dendrimers delayed trehalose crystallization in the combined matrices, allowing extending the protection at those conditions in which normally trehalose fails. The results show how a relatively simple covalent combination of a polymer such as PEG with β‐CD could significantly affect the properties of the individual components. Also, the results provide further insights about the role played by polymer–enzyme supramolecular interactions (host–guest crosslink, hydrogen bonding, and hydrophobic interactions) on enzyme stability in dehydrated models, being the effect on the stabilization also influenced by the physical state of the matrix. © 2013 American Institute of Chemical Engineers Biotechnol. Prog., 29:786–795, 2013     

Host–guest inclusion complex of mesalazine and β‐cyclodextrin and spectrofluorometric determination of mesalazine

The supramolecular interaction of mesalazine (MSZ) and β‐cyclodextrin (β‐CD) has been examined by ultraviolet–visible (UV–vis) light, infra‐red (IR) light and fluorescence spectroscopy. The formation of an inclusion complex has been confirmed based on the changes of the spectral properties. MSZ–β‐CD host–guest complex was formed in (1:1) stoichiometry and the inclusion constant (K = 1.359 × 10² L mol^–1) was ascertained by typical double reciprocal plots. Furthermore, the thermodynamic parameters (ΔG°, ΔH° and ΔS°) of (MSZ–β‐CD) were obtained. Based on the remarkable enhancement of the fluorescence intensity of MSZ produced through complex formation, a simple, accurate, rapid and highly sensitive spectrofluorometric method for the determination of MSZ in aqueous solution in the presence of β‐CD was developed. The measurement of relative fluorescence intensity was carried with excitation at 330 nm and emission 493 nm. All variables affecting the reactions were studied and optimized. Beer's law was obeyed in the concentration range 0.1–0.45 µg/mL. Absorbance was found to increase linearly with increasing concentration of MSZ, which is corroborated by the calculated correlation coefficient values of 0.99989. The molar absorptivity, Sandell's sensitivity, detection and quantification limits were calculated. The validity of the described methods was assessed, and the method was successfully applied to the determination of MSZ in its pharmaceutical formulation. In addition, a solid inclusion complex was synthesized by co‐precipitation method. Copyright © 2014 John Wiley & Sons, Ltd.     

Synthesis and DNA‐binding study of imidazole linked thiazolidinone derivatives

A novel series of imidazole‐linked thiazolidinone hybrid molecules were designed and synthesized through a feasible synthetic protocol. The molecules were characterized with Fourier transform infrared (FT‐IR), ¹H nuclear magnetic resonance (NMR), ¹³C NMR and high‐resolution mass spectrometry (HRMS) techniques. In vitro susceptibility tests against Gram‐positive (S. aureus and B. subtilis ) and Gram‐negative bacteria (E. coli and P. aeruginosa ) gave highly promising results. The most active molecule (3e) gave a minimal inhibitory concentration (MIC) value of 3.125 μg/mL which is on par with the reference drug streptomycin. Structure–activity relationships revealed activity enhancement by nitro and chloro groups when they occupied meta position of the arylidene ring in 2‐((3‐(imidazol‐1‐yl)propyl)amino)‐5‐benzylidenethiazolidin‐4‐ones. DNA‐binding study of the most potent molecule 3e with salmon milt DNA (sm‐DNA) under simulated physiological pH was probed with UV–visible absorption, fluorescence quenching, gel electrophoresis and molecular docking techniques. These studies established that compound 3e has a strong affinity towards DNA and binds at DNA minor groove with a binding constant (K_b) 0.18 × 10² L mol^?1. Molecular docking simulations predicted strong affinity of 3e towards DNA with a binding affinity (ΔG) ‐8.5 kcal/mol. Van der Waals forces, hydrogen bonding and hydrophobic interactions were predicted as the main forces of interaction. The molecule 3e exhibited specific affinity towards adenine–thiamine base pairs. Copyright © 2016 John Wiley & Sons, Ltd.     

Structures of single‐layer β‐sheet proteins evolved from β‐hairpin repeats

Free‐standing single‐layer β‐sheets are extremely rare in naturally occurring proteins, even though β‐sheet motifs are ubiquitous. Here we report the crystal structures of three homologous, single‐layer, anti‐parallel β‐sheet proteins, comprised of three or four twisted β‐hairpin repeats. The structures reveal that, in addition to the hydrogen bond network characteristic of β‐sheets, additional hydrophobic interactions mediated by small clusters of residues adjacent to the turns likely play a significant role in the structural stability and compensate for the lack of a compact hydrophobic core. These structures enabled identification of a family of secreted proteins that are broadly distributed in bacteria from the human gut microbiome and are putatively involved in the metabolism of complex carbohydrates. A conserved surface patch, rich in solvent‐exposed tyrosine residues, was identified on the concave surface of the β‐sheet. These new modular single‐layer β‐sheet proteins may serve as a new model system for studying folding and design of β‐rich proteins.     

Mycobacterium tuberculosis class II apurinic/apyrimidinic‐endonuclease/3′‐5′ exonuclease III exhibits DNA regulated modes of interaction with the sliding DNA β‐clamp

The class‐II AP‐endonuclease (XthA) acts on abasic sites of damaged DNA in bacterial base excision repair. We identified that the sliding DNA β‐clamp forms in vivo and in vitro complexes with XthA in Mycobacterium tuberculosis. A novel ₂₃₉QLRFPKK₂₄₅ motif in the DNA‐binding domain of XthA was found to be important for the interactions. Likewise, the peptide binding‐groove (PBG) and the C‐terminal of β‐clamp located on different domains interact with XthA. The β‐clamp‐XthA complex can be disrupted by clamp binding peptides and also by a specific bacterial clamp inhibitor that binds at the PBG. We also identified that β‐clamp stimulates the activities of XthA primarily by increasing its affinity for the substrate and its processivity. Additionally, loading of the β‐clamp onto DNA is required for activity stimulation. A reduction in XthA activity stimulation was observed in the presence of β‐clamp binding peptides supporting that direct interactions between the proteins are necessary to cause stimulation. Finally, we found that in the absence of DNA, the PBG located on the second domain of the β‐clamp is important for interactions with XthA, while the C‐terminal domain predominantly mediates functional interactions in the substrate's presence.     

Capecitabine as a minor groove binder of DNA: molecular docking,molecular dynamics,and multi-spectroscopic studies

The interaction mechanism and binding mode of capecitabine with ctDNA was extensively investigated using docking and molecular dynamics simulations, fluorescence and circular dichroism (CD) spectroscopy, DNA thermal denaturation studies, and viscosity measurements. The possible binding mode and acting forces on the combination between capecitabine and DNA had been predicted through molecular simulation. Results indicated that capecitabine could relatively locate stably in the G-C base-pairs-rich DNA minor groove by hydrogen bond and several weaker nonbonding forces. Fluorescence spectroscopy and fluorescence lifetime measurements confirmed that the quenching was static caused by ground state complex formation. This phenomenon indicated the formation of a complex between capecitabine and ctDNA. Fluorescence data showed that the binding constants of the complex were approximately 2 × 10⁴ M^?1. Calculated thermodynamic parameters suggested that hydrogen bond was the main force during binding, which were consistent with theoretical results. Moreover, CD spectroscopy, DNA melting studies, and viscosity measurements corroborated a groove binding mode of capecitabine with ctDNA. This binding had no effect on B-DNA conformation.     

Thermal effects in guest–host systems: [Zn2(bdc)(S‐lac)(dmf)]•PhEtOH: A DSC and NMR study

Differential scanning calorimetry and nuclear magnetic resonance were used to investigate thermal effects in the guest–host systems where homochiral metal–organic sorbent [Zn₂(bdc)(S ‐lac)(dmf)] is considered as a host while 1‐phenylethanol enantiomers and their racemic mixture serve as guest molecules. A maximum energy gain from the guest–host interaction was observed in the system with the racemic mixture. The effect of host–guest recognition was revealed for the case of the host and guest having a similar type of chirality in the presence of antipode guest molecules.     

Systematical investigation of binding interaction between novel ruthenium(II) arene complex with curcumin analogs and ctDNA

In this study, the interaction between a novel ruthenium(II) arene complex with curcumin analogs and calf thymus DNA (ctDNA) was investigated systematically by viscosity measurement, the DNA melting approach, multispectroscopic techniques and electrochemical methods. The absorption spectra of the ctDNA–drug complex showed a slight red shift and a weak hypochromic effect. The relative viscosity and melting temperature of ctDNA increased on addition of the drug. The evidence obtained from fluorescence competitive experiments indicated that the binding mode of the drug with ctDNA was intercalative. Using acridine orange (AO) as a fluorescence probe, the drug statically quenched the fluorescence of the ctDNA–AO complex, and hydrogen bonding and van der Waals interactions played vital roles in the binding interaction between the drug and ctDNA. The influences of ionic strength, chemical denaturants and pH on the binding interaction were also investigated. Circular dichroism and Fourier transform infrared spectra suggested that this drug might bond with the G–C base pairs of ctDNA and the right‐handed B‐form helicity of ctDNA remained after drug binding. The intercalative binding between the drug and ctDNA was further investigated using electrochemical techniques. All these results suggested that the biological activity of ctDNA was affected by ruthenium(II) arene complex with curcumin analogs. Copyright © 2016 John Wiley & Sons, Ltd.     

The crystal structure of Z‐(Aib)10‐OH at 0.65 Å resolution: three complete turns of 310‐helix

The synthetic peptide Z‐(Aib)₁₀‐OH was crystallized from hot methanol by slow evaporation. The crystal used for data collection reflected synchrotron radiation to sub‐atomic resolution, where the bonding electron density becomes visible between the non‐hydrogen atoms. Crystals belong to the centrosymmetric space group P . Both molecules in the asymmetric unit form regular 3₁₀‐helices. All residues in each molecule possess the same handedness, which is in contrast to all other crystal structure determined to date of longer Aib‐homopeptides. These other peptides are C‐terminal protected by OtBu or OMe. In these cases, because of the missing ability of the C‐terminal protection group to form a hydrogen bond to the residue i‐3, the sense of the helix is reversed in the last residue. Here, the C‐terminal OH‐groups form hydrogen bonds to the residues i‐3, in part mediated by water molecules. This makes Z‐(Aib)₁₀‐OH an Aib‐homopeptide with three complete 3₁₀‐helical turns in spite of the shorter length it has compared with Z‐(Aib)₁₁‐OtBu, the only homopeptide to date with three complete turns.     

Human herpesvirus‐6A gQ1 and gQ2 are critical for human CD46 usage

Based on genetic and antigenic differences and on their cell tropism, human herpes virus‐6 (HHV‐6) has been classified into two variants, HHV‐6A and HHV‐6B. Recently, these variants were re‐classified as two different species. The HHV‐6A glycoprotein complex, gH/gL/gQ1/gQ2 binds to its cellular receptor, CD46; however, the corresponding complex in HHV‐6B rarely binds to CD46. To determine which viral molecules in the glycoprotein complex determine HHV‐6A‐CD46 binding, each molecule of the HHV‐6A complex (i.e., gH, gL, gQ1, or gQ2) was replaced with the corresponding HHV‐6B molecule, and the ability of the replaced protein to be incorporated into the complex and the ability of the complex to bind CD46 were examined. It was found that when all four glycoproteins were expressed, they were able to form a tetrameric complex. However, a complex formed by HHV‐6A gH/gL/gQ1/gQ2 complexes replaced with HHV‐6B gQ1 or gQ2 scarcely bind CD46, whereas HHV‐6A complexes in which gH or gL was replaced with the HHV‐6B molecules did bind it. These results indicate that HHV‐6A gQ1 and gQ2 play an important role in CD46 binding.