Yuri L. Lyubchenko

Silatrane-based surface chemistry for immobilization of DNA, protein-DNA complexes and other biological materials.

The procedure of surface functionalization based on the use of 1-(3-Aminopropyl)silatrane (APS) instead of our early procedure utilizing aminopropyl triethoxy silane (APTES) is described. Unlike APTES, APS is less reactive and extremely resistant to hydrolysis and polymerization at neutral pH. The kinetics of DNA adsorption to APS-mica was studied. The results are consistent with a diffusion controlled mechanism suggesting that DNA molecules bind irreversibly with the surface upon immobilization. This conclusion is supported by the data on imaging of supercoiled DNA, the labile conformations of which are very sensitive to the conditions at the surface-liquid interface. In addition, we demonstrated directly that the segments of DNA molecules could move along the surface if the sample is imaged in aqueous solution without drying of the sample. Using the time-lapse mode of AFM imaging we visualized the transition of purine-pyrimidine sequence in supercoiled DNA from intramolecular triple-helical conformation (H-form) into the B-helix upon the change of pH from acidic (pH 5) to neutral. The mechanisms of the H-to-B transitions and the correlation of the local structural transitions with a global DNA conformation are discussed.

Simple test system for single molecule recognition force microscopy

We have established an easy-to-use test system for detecting receptor–ligand interactions on the single molecule level using atomic force microscopy (AFM). For this, avidin–biotin, probably the best characterized receptor–ligand pair, was chosen. AFM sensors were prepared containing tethered biotin molecules at sufficiently low surface concentrations appropriate for single molecule studies. A biotin tether, consisting of a 6 nm poly(ethylene glycol) (PEG) chain and a functional succinimide group at the other end, was newly synthesized and covalently coupled to amine-functionalized AFM tips. In particular, PEG800 diamine was glutarylated, the mono-adduct NH2–PEG–COOH was isolated by ion exchange chromatography and reacted with biotin succinimidylester to give biotin–PEG–COOH which was then activated as N-hydroxysuccinimide (NHS) ester to give the biotin–PEG–NHS conjugate which was coupled to the aminofunctionalized AFM tip. The motional freedom provided by PEG allows for free rotation of the biotin molecule on the AFM sensor and for specific binding to avidin which had been adsorbed to mica surfaces via electrostatic interactions. Specific avidin–biotin recognition events were discriminated from nonspecific tip–mica adhesion by their typical unbinding force (∼40 pN at 1.4 nN/s loading rate), unbinding length (<13 nm), the characteristic nonlinear force–distance relation of the PEG linker, and by specific block with excess of free d-biotin. The convenience of the test system allowed to evaluate, and compare, different methods and conditions of tip aminofunctionalization with respect to specific binding and nonspecific adhesion. It is concluded that this system is well suited as calibration or start-up kit for single molecule recognition force microscopy.

Atomic Force Microscopy Imaging of Double Stranded DNA and RNA

A procedure for imaging long DNA and double stranded RNA (dsRNA) molecules using Atomic Force Microscopy (AFM) is described. Stable binding of double stranded DNA molecules to the flat mica surface is achieved by chemical modification of freshly cleaved mica under mild conditions with 3-aminopropyltriethoxy silane. We have obtained striking images of intact lambda DNA, Hind III restriction fragments of lambda DNA and dsRNA from reovirus. These images are stable under repeated scanning and measured contour lengths are accurate to within a few percent. This procedure leads to strong DNA attachment, allowing imaging under water. The widths of the DNA images lie in the range of 20 to 80nm for data obtained in air with commercially available probes. The work demonstrates that AFM is now a routine tool for simple measurements such as a length distribution. Improvement of substrate and sample preparation methods are needed to achieve yet higher resolution.

Atomic force microscopy : a powerful tool to observe biomolecules at work

Atomic force microscopes (AFMs) move a sharp tip attached to a soft cantilever in a TV-raster-like pattern over a surface and record deflections of the tip that correspond to the surface topography. When operated in physiological solutions, an AFM allows biomolecules to be observed in their native environment. Progress in instrumentation, sample-preparation methods and recording conditions has provided images of biomolecules and their assemblies that reveal submolecular details. In addition, the AFM allows conformational changes to be observed directly. This article discusses these points and illustrates them with some pertinent examples.

Regulation of Poly(ADP-ribose) Polymerase-1 by DNA Structure-specific Binding

Poly(ADP-ribose) polymerase-1 (PARP-1) is an intracellular sensor of DNA strand breaks and plays a critical role in cellular responses to DNA damage. In normally functioning cells, PARP-1 enzymatic activity has been linked to the alterations in chromatin structure associated with gene expression. However, the molecular determinants for PARP-1 recruitment to specific sites in chromatin in the absence of DNA strand breaks remain obscure. Using gel shift and enzymatic footprinting assays and atomic force microscopy, we show that PARP-1 recognizes distortions in the DNA helical backbone and that it binds to three- and four-way junctions as well as to stably unpaired regions in double-stranded DNA. PARP-1 interactions with non-B DNA structures are functional and lead to its catalytic activation. DNA hairpins, cruciforms, and stably unpaired regions are all effective co-activators of PARP-1 auto-modification and poly(ADP-ribosyl)ation of histone H1 in the absence of free DNA ends. Enzyme kinetic analyses revealed that the structural features of non-B form DNA co-factors are important for PARP-1 catalysis activated by undamaged DNA. K0.5 constants for DNA co-factors, which are structurally different in the degree of base pairing and spatial DNA organization, follow the order: cruciform ≤ hairpin « loop. DNA structure also influenced the reaction rate; when a hairpin was substituted with a stably unpaired region, the maximum reaction velocity decreased almost 2-fold. These data suggest a link between PARP-1 binding to non-B DNA structures in genome and its function in the dynamics of local modulation of chromatin structure in the normal physiology of the cell.

Triplet repeat DNA structures and human genetic disease: dynamic mutations from dynamic DNA.

Fourteen genetic neurodegenerative diseases and three fragile sites have been associated with the expansion of (CTG)n•(CAG)n, (CGG)n•(CCG)n, or (GAA)n•(TTC)n repeat tracts. Different models have been proposed for the expansion of triplet repeats, most of which presume the formation of alternative DNA structures in repeat tracts. One of the most likely structures, slipped strand DNA, may stably and reproducibly form within triplet repeat sequences. The propensity to form slipped strand DNA is proportional to the length and homogeneity of the repeat tract. The remarkable stability of slipped strand DNA may, in part, be due to loop-loop interactions facilitated by the sequence complementarity of the loops and the dynamic structure of three-way junctions formed at the loop-outs.

AFM for analysis of structure and dynamics of DNA and protein-DNA complexes

This paper describes protocols for studies of structure and dynamics of DNA and protein-DNA complexes with atomic force microscopy (AFM) utilizing the surface chemistry approach. The necessary specifics for the preparation of functionalized surfaces and AFM probes with the use of silanes and silatranes, including the protocols for synthesis of silatranes are provided. The methodology of studies of local and global conformations DNA with the major focus on the time-lapse imaging of DNA in aqueous solutions is illustrated by the study of dynamics of Holliday junctions including branch migration. The analysis of nucleosome dynamics is selected as an example to illustrate the application of the time-lapse AFM to studies of dynamics of protein-DNA complexes. The force spectroscopy is the modality of AFM with a great importance to various fields of biomedical studies. The AFM force spectroscopy approach for studies of specific protein-DNA complexes is illustrated by the data on analysis of dynamics of synaptic SfiI-DNA complexes. When necessary, additional specifics are added to the corresponding example.

Residues 17–20 and 30–35 of beta‐amyloid play critical roles in aggregation

We examined the effects of co‐incubating nine different Aβ peptide fragments with full‐length Aβ1–40 (Aβ40) on protein aggregation. Six fragments enhanced aggregation of Aβ40 (Aβ1–28, 12–28, 17–28, 10–20, 25–35 and 17–40), while three others did not (Aβ1–11, 1–16, and 20–29). All of the peptides that enhanced aggregation contained either residues 17–20 or 30–35, indicating the importance of these regions for promoting aggregation of full‐length Aβ. Aβ25–35 in particular increased both the rate and extent of aggregation of Aβ40 considerably as indicated by fluorescence staining. Atomic force microscope imaging (AFM) indicates the increase in fluorescence staining with Aβ25–35 is primarily due to increased formation of oligomers and protofibrils rather than formation of large amyloid fibrils. AFM images of Aβ25–35 when incubated alone also indicate formation of aggregates and long thin filaments. The increase in formation of the small toxic oligomeric morphology of Aβ40, along with formation of Aβ25–35 oligomers and thin filaments, represent two different potential pathways for Aβ25–35 toxicity. The critical roles of residues 17–20 and 30–35 of Aβ provide further insight into mechanism that underlie the formation of toxic aggregates in Alzheimer Disease (AD) and suggest targets for the design of β‐sheet breakers to modulate the aggregation and inhibit toxicity of full‐length Aβ.

Comparative studies of bacteria with an atomic force microscopy operating in different modes.

Escherichia coli bacterial cells of two strains JM109 and K12 J62 were imaged with atomic force microscopy (AFM) in different environmental conditions. The AFM results show that the two strains have considerable difference in the surface morphology. At the same time after rehydration both strains show the loss of the topographic features and increase in lateral and vertical dimensions. Results obtained in different AFM modes (contact, tapping, MAC) were compared. Imaging in culture medium was applied for direct observation of the surface degradation effect of lysozyme. The treatment of the cells with the enzyme in the culture medium lead to the loss of surface rigidity and eventually to dramatic changes of the bacteria shape.

Atomic Force Microscopy Imaging of DNA Covalently Immobilized on a Functionalized Mica Substrate

A procedure for covalent binding of DNA to a functionalized mica substrate is described. The approach is based on photochemical cross-linking of DNA to immobilized psoralen derivatives. A tetrafluorphenyl (TFP) ester of trimethyl psoralen (trioxalen) was synthesized, and the procedure to immobilize it onto a functionalized aminopropyl mica surface (AP-mica) was developed. DNA molecules were cross-linked to trioxalen moieties by UV irradiation of complexes. The steps of the sample preparation procedure were analyzed with x-ray photoelectron spectroscopy (XPS). Results from XPS show that an AP-mica surface can be formed by vapor phase deposition of silane and that this surface can be derivatized with trioxalen. The derivatized surface is capable of binding of DNA molecules such that, after UV cross-linking, they withstand a thorough rinsing with SDS. Observations with atomic force microscopy showed that derivatized surfaces remain smooth, so DNA molecules are easily visualized. Linear and circular DNA molecules were photochemically immobilized on the surface. The molecules are distributed over the surface uniformly, indicating rather even modification of AP-mica with trioxalen. Generally, the shapes of supercoiled molecules electrostatically immobilized on AP-mica and those photocross-linked on trioxalen-functionalized surfaces remain quite similar. This suggests that UV cross-linking does not induce formation of a noticeable number of single-stranded breaks in DNA molecules.