Andrey V. Golovin

Cation binding to 15-TBA quadruplex DNA is a multiple-pathway cation-dependent process

A combination of explicit solvent molecular dynamics simulation (30 simulations reaching 4 µs in total), hybrid quantum mechanics/molecular mechanics approach and isothermal titration calorimetry was used to investigate the atomistic picture of ion binding to 15-mer thrombin-binding quadruplex DNA (G-DNA) aptamer. Binding of ions to G-DNA is complex multiple pathway process, which is strongly affected by the type of the cation. The individual ion-binding events are substantially modulated by the connecting loops of the aptamer, which play several roles. They stabilize the molecule during time periods when the bound ions are not present, they modulate the route of the ion into the stem and they also stabilize the internal ions by closing the gates through which the ions enter the quadruplex. Using our extensive simulations, we for the first time observed full spontaneous exchange of internal cation between quadruplex molecule and bulk solvent at atomistic resolution. The simulation suggests that expulsion of the internally bound ion is correlated with initial binding of the incoming ion. The incoming ion then readily replaces the bound ion while minimizing any destabilization of the solute molecule during the exchange.

Zinc-induced dimerization of the amyloid-β metal-binding domain 1–16 is mediated by residues 11–14

Analysis of complex formation between amyloid-β fragments using surface plasmon resonance biosensing and electrospray mass spectrometry reveals that region 11-14 mediates zinc-induced dimerization of amyloid-β and may serve as a potential drug target for preventing development and progression of Alzheimers disease.

Structural Dynamics of Thrombin-Binding DNA Aptamer d(GGTTGGTGTGGTTGG) Quadruplex DNA Studied by Large-Scale Explicit Solvent Simulations.

The thrombin-binding aptamer (15-TBA) is a 15-mer DNA oligonucleotide with sequence d(GGTTGGTGTGGTTGG). 15-TBA folds into a quadruplex DNA (G-DNA) structure with two planar G-quartets connected by three single-stranded loops. The arrangement of the 15-TBA-thrombin complex is unclear, particularly with respect to the precise 15-TBA residues that interact with the thrombin structure. Our present understanding suggests either the 15-TBA single stranded loops containing sequential thymidines (TT) or alternatively a single-stranded loop, containing a guanine flanked by 2 thymidines (TGT), physically associates with thrombin protein. In the present study, the explicit solvent molecular dynamics (MD) simulation method was utilized to further analyze the 15-TBA-thrombin three-dimensional structure. Functional annotation of the loop residues was made with long simulations in the parmbsc0 force field. In total, the elapsed time of simulations carried out in this study exceeds 12 microseconds, substantially surpassing previous G-DNA simulation reports. Our simulations suggest that the TGT-loop function is to stabilize the structure of the aptamer, while the TT-loops participate in direct binding to thrombin. The findings of the present report advance our understanding of the molecular structure of the 15-TBA-thrombin structure further enabling the construction of biosensors for aptamer bases and the development of anticoagulant agents.

Water Replacement Hypothesis in Atomic Details: Effect of Trehalose on the Structure of Single Dehydrated POPC Bilayers

We present molecular dynamics (MD) simulations to study the plausibility of the water replacement hypothesis (WRH) from the viewpoint of structural chemistry. A total of 256 2-oleoyl-1-palmitoyl-sn-glycero-3-phosphocholine (POPC) lipids were modeled for 400 ns at 11.7 or 5.4 waters/lipid. To obtain a single dehydrated bilayer relevant to the WRH, simulations were performed in the NP(xy)h(z)T ensemble with h(z) > 8 nm, allowing interactions between lipids in the membrane plane and preventing interactions between neighboring membranes via periodic boundary conditions. This setup resulted in a stable single bilayer in (or near) the gel state. Trehalose caused a concentration-dependent increase of the area per lipid (APL) accompanied by fluidizing the bilayer core. This mechanism has been suggested by the WRH. However, dehydrated bilayers in the presence of trehalose were not structurally identical to fully hydrated bilayers. The headgroup vector was in a more parallel orientation in dehydrated bilayers with respect to the bilayer plane and maintained this orientation in the presence of trehalose in spite of APL increase. The total dipole potential changed sign in dehydrated bilayers and remained slightly positive in the presence of trehalose. The model of a dehydrated bilayer presented here allows the study of the mechanisms of membrane protection against desiccation by different compounds.

The yfiC gene of E. coli encodes an adenine-N6 methyltransferase that specifically modifies A37 of tRNA1Val(cmo5UAC)

Transfer RNA is highly modified. Nucleotide 37 of the anticodon loop is represented by various modified nucleotides. In Escherichia coli, the valine-specific tRNA (cmo(5)UAC) contains a unique modification, N(6)-methyladenosine, at position 37; however, the enzyme responsible for this modification is unknown. Here we demonstrate that the yfiC gene of E. coli encodes an enzyme responsible for the methylation of A37 in tRNA(1)(Val). Inactivation of yfiC gene abolishes m(6)A formation in tRNA(1)(Val), while expression of the yfiC gene from a plasmid restores the modification. Additionally, unmodified tRNA(1)(Val) can be methylated by recombinant YfiC protein in vitro. Although the methylation of m(6)A in tRNA(1)(Val) by YfiC has little influence on the cell growth under standard conditions, the yfiC gene confers a growth advantage under conditions of osmotic and oxidative stress.

Novel modular DNA aptamer for human thrombin with high anticoagulant activity.

Aptamers based on nucleic acids are a promising alternative to antibodies in therapy and diagnostics. Several DNA aptamers against human thrombin have been developed by selection from random libraries: a 15-mer and its derivatives, a 29-mer, and a 31-mer. Some of them are patented and already under clinical trial. The 15-mer structure was determined by X-ray and NMR and turned out to be a monomolecular antiparallel G-quadruplex. The other aptamers mentioned above have higher inhibitory activity than the initial 15-mer, but there are not yet structural data explaining this phenomenon. Here, the initial 15-mer, 31-mer, and novel RA-36 aptamers are compared to establish the structure-function correlation, providing a solid ground for further rational aptameric drug design. For the molecular dynamic simulation of aptamers, the force field parmbsc0 was ported onto GROMACS, and the main stabilizing parameters were revealed, leading to the novel DNA aptamer RA-36. The functional properties of the DNA aptamers were studied by conventional coagulation tests, which do not directly elucidate the mechanism of thrombin inhibition by aptamers. Improved turbidimetric measurements provided data to develop detailed kinetics showing that the 31-mer and RA-36, in contrast to the 15-mer, are competitive inhibitors. These data revealed RA-36 to be an efficient thrombin inhibitor with a dose-dependent effect. Animal tests of the studied DNA aptamers suggested an unexpected species-specificity of the novel RA-36.

Role of κ→λ light-chain constant-domain switch in the structure and functionality of A17 reactibody.

Catalytic antibody variants with κ and λ light-chain constant domains show differences in their crystal structures which lead to subtle changes in catalytic efficiency and thermodynamic parameters as well as in their affinity for peptide substrates.

Conjugates of Amino Acids and Peptides with 5-O-Mycaminosyltylonolide and Their Interaction with the Ribosomal Exit Tunnel

During protein synthesis the nascent polypeptide chain (NC) extends through the ribosomal exit tunnel (NPET). Also, the large group of macrolide antibiotics binds in the nascent peptide exit tunnel. In some cases interaction of NC with NPET leads to the ribosome stalling, a significant event in regulation of translation. In other cases NC-ribosome interactions lead to pauses in translation that play an important role in cotranslational folding of polypeptides emerging from the ribosome. The precise mechanism of NC recognition in NPET as well as factors that determine NC conformation in the ribosomal tunnel are unknown. A number of derivatives of the macrolide antibiotic 5-O-mycaminosyltylonolide (OMT) containing N-acylated amino acid or peptide residues were synthesized in order to study potential sites of NC-NPET interactions. The target compounds were prepared by conjugation of protected amino acids and peptides with the C23 hydroxyl group of the macrolide. These OMT derivatives showed high although varying abilities to inhibit the firefly luciferase synthesis in vitro. Three glycil-containing derivatives appeared to be strong inhibitors of translation, more potent than parental OMT. Molecular dynamics (MD) simulation of complexes of tylosin, OMT, and some of OMT derivatives with the large ribosomal subunit of E. coli illuminated a plausible reason for the high inhibitory activity of Boc-Gly-OMT. In addition, the MD study detected a new putative site of interaction of the nascent polypeptide chain with the NPET walls.

Molecular dynamics investigation of a mechanism of allosteric signal transmission in ribosomes

The ribosome is a molecular machine that synthesizes all cellular proteins via translation of genetic information encoded in polynucleotide chain of messenger RNA. Transition between different stages of the ribosome working cycle is strictly coordinated by changes in structure and mutual position both of subunits of the ribosome and its ligands. Therein, information regarding structural transformations is transmitted between functional centers of the ribosome through specific signals. Usually, functional centers of ribosomes are located at a distance reaching up to several tens of angstroms, and it is believed that such signals are transduced allosterically. In our study, we attempted to answer the question of how allosteric signal can be transmitted from one of the so-called sensory elements of ribosomal tunnel (RT) to the peptidyl transferase center (PTC). A segment of RT wall from the E. coli ribosome composed of nucleotide residues A2058, A2059, m2A2503, G2061, A2062, and C2063 of its 23S rRNA was examined by molecular dynamics simulations. It was found that a potential signal transduction pathway A2058-C2063 acted as a dynamic ensemble of interdependent conformational states, wherein cascade-like changes can occur. It was assumed that structural rearrangement in the A2058-C2063 RT segment results in reversible inactivation of PTC due to a strong stacking contact between functionally important U2585 residue of the PTC and nucleotide residue C2063. A potential role for the observed conformational transition in the A2058-C2063 segment for regulating ribosome activity is discussed.

Flexible biological sensors based on carbon nanotube films

This paper presents the technique of forming flexible liquid sensors for biological applications based on carbon nanotube networks. We bend structures with a radius of curvature of 5 mm and the resistance change is no more than 8–10%, keeping the overall properties of the conductive coatings developed during multiple bends. We demonstrate the possibility of determining thrombin when biosensor structures are immobilized by specific aptamers.