Volume Holographic Reflection Endoscope for In-Vivo Ovarian Cancer Clinical Studies.

We present the design for an endoscopic system capable of imaging tissues of the ovary at two selected imaging depths simultaneously. The method utilizes a multiplexed volume hologram to select wavefronts from different depths within the tissue. It is the first demonstration of an endoscopic volume holographic imaging system. The endoscope uses both gradient index (GRIN) optical components and off the shelf singlet lenses to relay an image from the distal tip to the proximal end. The endoscope has a minimum diameter of 3.75 mm. The system length is 30 cm which is connected to a handle that includes the holographic components and optics that relay the image to a camera. Preliminary evaluation of the endoscope was performed with tissue phantoms and calibrated targets, which shows lateral resolution ≈ 4 µm at an operating wavelength of 660 nm. The hologram is recorded in phenanthraquinone doped poly methacrylate and is designed to produce images from two tissue depths. One image is obtained at the tissue surface and the second 70 µm below the surface. This method requires no mechanical scanning and acquires an image at the camera frame rate. The preliminary ex-vivo results show good correlation with histology sections of the same tissue sections.

Ovarian neoplasm development by 7,12-dimethylbenz[a]anthracene (DMBA) in a chemically-induced rat model of ovarian failure.

OBJECTIVES: The objectives were to determine the time course for ovarian failure in rats caused by 4-vinylcyclohexene diepoxide (VCD) and develop a model for ovarian cancer in which ovarian neoplasms were chemically induced in an animal that was follicle depleted, but retained residual ovarian tissue. METHODS: Initially, female Fisher 344 rats were treated with VCD (to induce ovarian failure) or vehicle control (sesame oil). Three or 6 months after treatment, ovaries were collected and processed for histological evaluation for confirmation of ovarian failure. A further set of female rats was assigned to four groups exposed to combinations of vehicle control, VCD and/or DMBA (directly applied to the ovary) in a novel model for examining early stages of ovarian neoplasia. RESULTS: Three and 6 months following VCD dosing there was a significant reduction of ovarian weight and follicle number. Treatment with DMBA subsequent to VCD resulted in tumors in 42% of animals at 3 months and 57% at 5 months. All neoplasms were classified Sertoli-Leydig cell tumors (SLCT). No tumor occurred in animals treated with vehicle or DMBA alone. CONCLUSIONS: These studies demonstrate that the VCD-treated rat can be used as a model for peri- and post-menopause. DMBA induction of ovarian neoplasms was greater in those rats treated with VCD. Whether this increase was due to tumor initiation by VCD or was the result of ovarian failure cannot be distinguished from these results. This represents the only animal model to date for sex cord stromal tumors.

Investigating sun-damaged skin and actinic keratosis with optical coherence tomography: a pilot study.

Actinic Keratosis (AK) arises from sun-damaged skin and is the first clinical manifestation in the multistep process of skin carcinogenesis to invasive squamous cell carcinoma. Thus, it is an ideal target for chemopreventive efforts. Noninvasive measures of AK severity are needed to assess the efficacy of chemoprevention agents. We performed a pilot study on 20 participants to investigate the OCT appearance of sun-protected skin of the upper inner arm as well as sun-damaged skin and early AKs of the dorsal forearms, and to determine if features or quantitative measures in Optical Coherence Tomography (OCT) images could be used to reliably differentiate between these categories. OCT images of upper inner arm (normal appearing skin) showed skin layers and features (stratum corneum, epidermis, dermis, blood vessels) seen in previous studies; additionally in this participant group the subcutaneous fat layer was usually identified. Sun-damaged skin was characterized by increased signal in the epidermis and rapid attenuation of light. AKs were diverse in appearance but frequently characterized by high surface reflection, the presence of a low-signal band in the stratum corneum, and heterogeneous appearance in the epidermis/dermis. Significant differences were found between skin categories using measures of stratum corneum and epidermal/dermal depths and intensities. The presence of a dark band in the stratum corneum was 79% sensitive and 100% specific for AK. This study indicates that OCT holds promise as a useful technique for identifying and characterizing AKs and monitoring their response to chemoprevention agents.

Evidence for DNA charge transport in the nucleus.

Oxidative damage to DNA bases in isolated HeLa nuclei occurs upon treatment with rhodium intercalators and photoactivation. Oxidation occurs preferentially at the 5'-guanine of 5'-GG-3' sites, indicative of base damage by DNA-mediated charge transfer chemistry. Moreover, oxidative damage occurs at protein-bound sites which are inaccessible to rhodium. Thus, on transcriptionally active DNA within the cell nucleus, DNA-mediated charge transport leads to base damage from a distance, and direct interaction of an oxidant is not necessary to generate a base lesion at a specific site. These observations require consideration in designing new chemotherapeutics and in understanding cellular mechanisms for DNA damage and repair.

Influence of intervening mismatches on long-range guanine oxidation in DNA duplexes.

A systematic investigation of the efficiency of oxidative damage at guanine residues through long-range charge transport was carried out as a function of intervening base mismatches. A series of DNA oligonucleotides were synthesized that incorporate a ruthenium intercalator linked covalently to the 5' terminus of one strand and containing two 5'-GG-3' sites in the complementary strand. Single base mismatches were introduced between the two guanine doublet steps, and the efficiency of transport through the mismatches was determined through measurements of the ratio of oxidative damage at the guanine doublets distal versus proximal to the intercalated ruthenium oxidant. Differing relative extents of guanine oxidation were observed for the different mismatches. The damage ratio of oxidation at the distal versus proximal site for the duplexes containing different mismatches varies in the order GC approximately GG approximately GT approximately GA > AA > CC approximately TT approximately CA approximately CT. For all assemblies, damage found with the Delta-Ru diastereomer was found to be greater than with the Lambda-diastereomer. The extent of distal/proximal guanine oxidation in different mismatch-containing duplexes was compared with the helical stability of the duplexes, electrochemical data for intercalator reduction on different mismatch-containing DNA films, and base-pair lifetimes for oligomers containing the different mismatches derived from 1H NMR measurements of the imino proton exchange rates. While a clear correlation is evident both with helix stability and electrochemical data monitoring reduction of an intercalator through DNA films, damage ratios correlate most closely with base-pair lifetimes. Competitive hole trapping at the mismatch site does not appear to be a key factor governing the efficiency of transport through the mismatch. These results underscore the importance of base dynamics in modulating long-range charge transport through the DNA base-pair stack.

Synthesis and spectroelectrochemistry of Ir(bpy)(phen)(phi)(3+), a tris(heteroleptic) metallointercalator.

A tris(heteroleptic) phenanthrenequinone diimine (phi) complex of Ir(III), Ir(bpy)(phen)(phi)(3+), was synthesized through the stepwise introduction of three different bidentate ligands, and the Lambda- and Delta-enantiomers were resolved and characterized by CD spectroscopy. Like other phi complexes, this tris(heteroleptic) iridium complex binds avidly to DNA by intercalation. Electrochemical studies show that Ir(bpy)(phen)(phi)(3+) undergoes a reversible one-electron reduction at E(0) = -0.025 V in 0.1 M TBAH/DMF (versus Ag/AgCl), and spectroelectrochemical studies indicate that this reduction is centered on the phi ligand. The EPR spectrum of electrochemically generated Ir(bpy)(phen)(phi)(2+) is consistent with a phi-based radical. The electrochemistry of Ir(bpy)(phen)(phi)(3+) was also probed at a DNA-modified electrode, where a DNA binding affinity of K = 1.1 x 10(6) M(-1) was measured. In contrast to Ir(bpy)(phen)(phi)(3+) free in solution, the complex bound to DNA undergoes a concerted two-electron reduction, to form a diradical species. On the basis of UV-visible and EPR spectroscopies, it is found that disproportionation of electrochemically generated Ir(bpy)(phen)(phi)(2+) occurs upon DNA binding. These results underscore the rich redox chemistry associated with metallointercalators bound to DNA.

Direct observation of radical intermediates in protein-dependent DNA charge transport.

Charge migration through the DNA base stack has been probed both spectroscopically, to observe the formation of radical intermediates, and biochemically, to assess irreversible oxidative DNA damage. Charge transport and radical trapping were examined in DNA assemblies in the presence of a site-specifically bound methyltransferase HhaI mutant and an intercalating ruthenium photooxidant using the flash-quench technique. The methyltransferase mutant, which can flip out a base and insert a tryptophan side chain within the DNA cavity, is found to activate long-range hole transfer through the base pair stack. Protein-dependent DNA charge transport is observed over 50 A with guanine radicals formed >10(6) s(-1); hole transport through DNA over this distance is not rate-limiting. Given the time scale and distance regime, such protein-dependent DNA charge transport chemistry requires consideration physiologically.

Long-range oxidative damage in DNA/RNA duplexes.

Oxidative damage as a result of DNA-mediated long-range charge transport occurs readily and at high yield in duplex DNA, and it is of interest whether similar damage can occur in duplex oligonucleotides that include both ribo- and deoxyribonucleotides. Assemblies containing RNA and mixed RNA.DNA strands were constructed containing tethered ethidium as a photooxidant. In photooxidation experiments, long-range oxidative damage to the ribose-containing strand of the oligonucleotide duplexes was examined. Hole injection by photoexcited ethidium followed by radical migration to oxidatively susceptible guanines afforded significant damage on ribose-containing strands at long range ( approximately 35 A). This damage does not differ substantially in yield and location from that found in B-DNA duplexes. No oxidative damage was found upon photooxidation of DNA/RNA duplexes containing tethered metallointercalator, despite the ability of the rhodium complex to promote oxidative damage at a distance in DNA duplexes. This result is attributed to the poor coupling of the rhodium complex into the A-like RNA/DNA duplex. The ability for long-range charge transport to occur in double-stranded nucleic acids of different comformations is considered in light of modeling studies that show interstrand base-base overlap between the opposing, complementary strands that make up RNA/DNA hybrid duplexes. Thus, the possibility of long-range radical migration to effect oxidative damage or signaling may be considered also in the context of transcriptional events.

Cooperative phenomena in two-pulse, two-color laser photocoagulation of cutaneous blood vessels.

A novel laser system has been developed to study the effects of multiple laser pulses of differing wavelengths on cutaneous blood vessels in vivo, using the hamster dorsal skin flap preparation and in vitro, using cuvettes of whole or diluted blood. The system permits sequenced irradiation with well-defined intrapulse spacing at 532 nm, using a long-pulse frequency-doubled Nd:YAG laser, and at 1064 nm, using a long-pulse Nd:YAG laser. Using this system, we have identified a parameter space where two pulses of different wavelengths act in a synergistic manner to effect permanent vessel damage at radiant exposures where the two pulses individually have little or no effect. Using a two-color pump-probe technique in vitro, we have identified a phenomenon we call greenlight-induced infrared absorption, where a pulse of green light causes photochemical and photothermal modifications to the chemical constituents of blood and results in enhanced infrared absorption. We identify a new chemical species, met-hemoglobin, not normally present in healthy human blood but formed during laser photocoagulation which we believe is implicated in the enhanced near-infrared absorption.

Photothermal coagulation of blood vessels: a comparison of high-speed optical coherence tomography and numerical modelling.

Optical-thermal models that can accurately predict temperature rise and damage in blood vessels and surrounding tissue may be used to improve the treatment of vascular disorders. Verification of these models has been hampered by the lack of time- and depth-resolved experimental data. In this preliminary study, an optical coherence tomography system operating at 4-30 frames per second was used to visualize laser irradiation of cutaneous (hamster dorsal skin flap) blood vessels. An argon laser was utilized with the following parameters: pulse duration 0.1-2.0 s, spot size 0.1-1.0 mm, power 100-400 mW. Video microscopy images were obtained before and after irradiations, and optical-thermal modelling was performed on two irradiation cases. Time-resolved optical coherence tomography and still images were compared with predictions of temperature rise and damage using Monte Carlo and finite difference techniques. In general, predicted damage agreed with the actual blood vessel and surrounding tissue coagulation seen in images. However, limitations of current optical-thermal models were identified, such as the inability to model the dynamic changes in blood vessel diameter that were seen in the optical coherence tomography images.

Charge transport through DNA four-way junctions.

Long range oxidative damage as a result of charge transport is shown to occur through single crossover junctions assembled from four semi-complementary strands of DNA. When a rhodium complex is tethered to one of the arms of the four-way junction assembly, thereby restricting its intercalation into the pi-stack, photo-induced oxidative damage occurs to varying degrees at all guanine doublets in the assembly, though direct strand scission only occurs at the predicted site of intercalation. In studies where the Mg(2+) concentration was varied, so as to perturb base stacking at the junction, charge transport was found to be enhanced but not to be strongly localized to the arms that preferentially stack on each other. These data suggest that the conformations of four-way junctions can be relatively mobile. Certainly, in four-way junctions charge transport is less discriminate than in the more rigidly stacked DNA double crossover assemblies.

How different DNA-binding proteins affect long-range oxidative damage to DNA.

Here the effect on DNA-mediated charge transport of binding by a variety of proteins is examined. DNA assemblies were constructed that contain a tethered rhodium intercalator, as photooxidant, as well as two 5'-GG-3' sites flanking the DNA-binding site for the different proteins. By monitoring the ratio of oxidative damage promoted at the guanine doublet situated distal to the protein-binding site versus that at the proximal site as a function of protein binding, the effects of binding the proteins on DNA-mediated charge transport were determined. Proteins examined included both the wild-type and mutant methyltransferase, M.HhaI, which are base-flipping enzymes, the restriction endonuclease R.PvuII, a TATA-binding protein, which kinks the DNA, and the transcription factor Antennapedia homeodomain protein, which binds DNA through a helix-turn-helix motif. In general, it was observed that yields of long-range oxidative damage correlate with protein-dependent alterations in DNA base stacking. Interactions that disturb the DNA pi-stack inhibit DNA charge transport. Alternatively, interactions that promote no helix distortion but, as a result of tight packing, may rigidify the pi-stack, serve instead to enhance the ability of the DNA base pairs to serve as a conduit for charge transport. Thus, protein binding to DNA modulates long-range charge transport both negatively and positively, depending upon the specific protein/DNA interactions in play. Long-range DNA charge transport and this modulation by protein binding may be important to consider physiologically.

Probing nucleic acid structure with shape-selective rhodium and ruthenium complexes.

In this unit, transition metal complexes are used as photochemical probes for the structure of RNA and DNA. The transition metal ion provides a rigid substitutionally inert framework and an octahedral geometry for ligand coordination. The complexes can be constructed to define shapes, symmetries, and functionalities that complement those of the nucleic acid target. Complex formation is easily detected by light-induced nucleic acid cleavage. The modular construction of the complexes makes it possible to generate probes to examine a wide variety of structural characteristics of nucleic acids.

Femtosecond direct observation of charge transfer between bases in DNA.

Charge transfer in supramolecular assemblies of DNA is unique because of the notion that the pi-stacked bases within the duplex may mediate the transport, possibly leading to damage and/or repair. The phenomenon of transport through pi-stacked arrays over a long distance has an analogy to conduction in molecular electronics, but the mechanism still needs to be determined. To decipher the elementary steps and the mechanism, one has to directly measure the dynamics in real time and in suitably designed, structurally well characterized DNA assemblies. Here, we report our first observation of the femtosecond dynamics of charge transport processes occurring between bases within duplex DNA. By monitoring the population of an initially excited 2-aminopurine, an isomer of adenine, we can follow the charge transfer process and measure its rate. We then study the effect of different bases next to the donor (acceptor), the base sequence, and the distance dependence between the donor and acceptor. We find that the charge injection to a nearest neighbor base is crucial and the time scale is vastly different: 10 ps for guanine and up to 512 ps for inosine. Depending on the base sequence the transfer can be slowed down or inhibited, and the distance dependence is dramatic over the range of 14 A. These observations provide the time scale, and the range and efficiency of the transfer. The results suggest the invalidity of an efficient wire-type behavior and indicate that long-range transport is a slow process of a different mechanism.

Mutation detection by electrocatalysis at DNA-modified electrodes.

Detection of mutations and damaged DNA bases is important for the early diagnosis of genetic disease. Here we describe an electrocatalytic method for the detection of single-base mismatches as well as DNA base lesions in fully hybridized duplexes, based on charge transport through DNA films. Gold electrodes modified with preassembled DNA duplexes are used to monitor the electrocatalytic signal of methylene blue, a redox-active DNA intercalator, coupled to [Fe(CN)6]3-. The presence of mismatched or damaged DNA bases substantially diminishes the electrocatalytic signal. Because this assay is not a measure of differential hybridization, all single-base mismatches, including thermodynamically stable GT and GA mismatches, can be detected without stringent hybridization conditions. Furthermore, many common DNA lesions and "hot spot" mutations in the human p53 genome can be distinguished from perfect duplexes. Finally, we have demonstrated the application of this technology in a chip-based format. This system provides a sensitive method for probing the integrity of DNA sequences and a completely new approach to single-base mismatch detection.

Robust charge transport in DNA double crossover assemblies.

BACKGROUND: Multiple-stranded DNA assemblies, encoded by sequence, have been constructed in an effort to self-assemble nanodevices of defined molecular architecture. Double-helical DNA has been probed also as a molecular medium for charge transport. Conductivity studies suggest that DNA displays semiconductor properties, whereas biochemical studies have shown that oxidative damage to B-DNA at the 5'-G of a 5'-GG-3' doublet can occur by charge transport through DNA up to 20 nm from a photo-excited metallointercalator. The possible application of DNA assemblies, in particular double crossover (DX) molecules, in electrical nanodevices prompted the design of a DNA DX assembly with oxidatively sensitive guanine moieties and a tethered rhodium photo-oxidant strategically placed to probe charge transport. RESULTS: DX assemblies support long-range charge transport selectively down the base stack bearing the intercalated photo-oxidant. Despite tight packing, no electron transfer (ET) crossover to the adjacent base stack is observed. Moreover, the base stack of a DX assembly is well-coupled and less susceptible than duplex DNA to stacking perturbations. Introducing a double mismatch along the path for charge transport entirely disrupts long-range ET in duplex DNA, but only marginally decreases it in the analogous stack within DX molecules. CONCLUSIONS: The path for charge transport in a DX DNA assembly is determined directly by base stacking. As a result, the two closely packed stacks within this assembly are electronically insulated from one another. Therefore, DX DNA assemblies may serve as robust, insulated conduits for charge transport in nanoscale devices.

DNA-Bound peptide radicals generated through DNA-mediated electron transport.

Flash-quench experiments were carried out to explore peptide/DNA electron-transfer reactions. DNA-bound [Ru(phen)(2)(dppz)](3+) (phen = 1,10-phenanthroline; dppz = dipyridophenazine) and [Ru(phen)(bpy')(dppz)](3+) [bpy' = 4-(4'-methyl-2, 2'-bipyridyl)valerate], generated in situ by flash-quench methodology, are powerful ground-state oxidants, capable of oxidizing guanine or tyrosine intercalated in DNA. In flash-quench experiments with mixed-sequence oligonucleotides in the presence of Lys-Tyr-Lys, transient absorption spectroscopy yielded a spectrum with a sharp maximum at 405 nm assigned to the tyrosine radical. Experiments with poly(dG.dC) suggested the intermediacy of the guanine radical, since the rise of the 405 nm signal occurred with the same kinetics as the disappearance of the guanine radical, as monitored at 510 nm. In oligonucleotide duplexes containing [Ru(phen)(bpy')(dppz)](2+) tethered at one end, damage to distant guanines was observed by gel electrophoresis, consistent with the mobility of the electron hole through the DNA duplex; the presence of the peptide did not inhibit but instead altered the distribution of guanine damage. Covalent adducts of the DNA and Lys-Tyr-Lys were detected as final irreversible products of this peptide-to-DNA electron-transfer chemistry by mass spectrometric and enzymatic digestive analysis. From these different assays and comparison of reactions of Lys-Trp-Lys and Lys-Tyr-Lys, the reactivity of the DNA-bound tyrosine radical was found to differ considerably from that of the tryptophan radical. These results establish that Lys-Tyr-Lys and Lys-Trp-Lys can participate in long-range electron-transfer reactions through the DNA from a distinct binding site. On that basis, proposals for functional roles for these peptide radicals may be considered.

Recognition of base mismatches in DNA by 5,6-chrysenequinone diimine complexes of rhodium(III): a proposed mechanism for preferential binding in destabilized regions of the double helix.

5,6-chrysenequinone diimine (chrysi) complexes of rhodium(III) have been shown to be versatile and specific recognition agents for mismatched base pairs in DNA. The design of these compounds was based on the hypothesis that the sterically expansive chrysi ligand, which should be too wide to readily intercalate into B-DNA, would bind preferentially in the destabilized regions of the DNA helix near base mismatches. In this work, this recognition hypothesis is comprehensively explored. Comparison of the recognition patterns of the complex [Rh(bpy)(2)(chrysi)](3+) with a nonsterically demanding analogue, [Rh(bpy)(2)(phi)](3+) (phi = 9,10-phenanthrenequinone diimine), demonstrates that the chrysi ligand does indeed disfavor binding to B-DNA and generate mismatch selectivity. Examination of mismatch recognition by [Rh(bpy)(2)(chrysi)](3+) in both constant and variable sequence contexts using photocleavage assays indicates that the recognition of base mismatches is influenced by the amount that a mismatch thermodynamically destabilizes the DNA helix. Thermodynamic binding constants for the rhodium complex at a range of mismatch sites have been determined by quantitative photocleavage titration and yield values which vary from 1 x 10(6) to 20 x 10(6) M(-)(1). These mismatch-specific binding affinities correlate with independent measurements of thermodynamic destabilization, supporting the hypothesis that helix destabilization is a factor determining the binding affinity of the metal complex for the mismatched site. Although not the only factor involved in the binding of [Rh(bpy)(2)(chrysi)](3+) to mismatch sites, a model is proposed where helix destabilization acts as the "door" which permits access of the sterically demanding intercalator to the base stack.

Long-range guanine oxidation in DNA restriction fragments by a triplex-directed naphthalene diimide intercalator.

Naphthalene diimide (NDI), a powerful oxidant that binds avidly to DNA by intercalation, is seen to damage the 5' guanine of 5'-GG-3' sites by photoactivated charge transport through DNA. When covalently tethered to the center of a triplex-forming oligonucleotide and delivered by triplex formation within a pyrimidine.purine-pyrimidine motif to a specific site on a restriction fragment, NDI can photooxidize guanine over at least 25-38 bp in each direction from the site of binding. Charge migration occurs in both directions from the NDI intercalator and on both DNA strands of the target, but the oxidation is significantly more efficient to the 3' side of the triplex. NDI and octahedral rhodium intercalators, when tethered directly to the 5' terminus of the triplex-forming strand as opposed to the center, generate significant amounts of oxidative damage only in the immediate vicinity of the intercalation site. Given that long-range charge transport depends on DNA stacking, these results suggest that the base stack is distorted at the 5' end of the triplex region in the duplex-triplex junction. Targeting of photooxidative damage by triplex formation extends our previous studies of long-range charge transport to significantly longer DNA sequences through a strategy that does not require covalent attachment of the photooxidant to the DNA being probed. Moreover, triplex targeting of oxidative damage provides for the first time a typical distance distribution for genomic charge transport of approximately 200 A around the oxidant.