Ultrastructural 3D Microscopy for Biomedicine: Principles, Applications, and Perspectives.

Modern biomedical research often requires a three-dimensional microscopic analysis of the ultrastructure of biological objects and materials. Conceptual technical and methodological solutions for three-dimensional structure reconstruction are needed to improve the conventional optical, electron, and probe microscopy methods, which to begin with allow one to obtain two-dimensional images and data. This review discusses the principles and potential applications of such techniques as serial section transmission electron microscopy; techniques based on scanning electron microscopy (SEM) (array tomography, focused ion beam SEM, and serial block-face SEM). 3D analysis techniques based on modern super-resolution optical microscopy methods are described (stochastic optical reconstruction microscopy and stimulated emission depletion microscopy), as well as ultrastructural 3D microscopy methods based on scanning probe microscopy and the feasibility of combining them with optical techniques. A comparative analysis of the advantages and shortcomings of the discussed approaches is performed.

Correlative Fluorescent Scanning Probe Nanotomography Used to Study the Intracellular Distribution of Doxorubicin in MCF-7 Human Breast Adenocarcinoma Cells.

Developing technologies for efficient targeted drug delivery for oncotherapy requires new methods to analyze the features of micro- and nanoscale distributions of antitumor drugs in cells and tissues. A new approach to three-dimensional analysis of the intracellular distribution of cytostatics was developed using fluorescence scanning optical-probe nanotomography. A correlative analysis of the nanostructure and distribution of injected doxorubicin in MCF-7 human breast adenocarcinoma cells revealed the features of drug penetration and accumulation in the cell. The technology is based on the principles of scanning optical probe nanotomography and is applicable to studying the distribution patterns of various fluorescent or fluorescence-labelled substances in cells and tissues.

Assessment of core-shell nanoparticles surface structure heterogeneity by SAXS contrast variation and ab initio modeling.

For the biomedical applications of nanoparticles, the study of their structure is a major step towards understanding the mechanisms of their interaction with biological environment. Detailed structural analysis of particles' surface is vital for rational design of drug delivery systems. In particular, for core-shell or surface-modified nanoparticles surface structure can be described in terms of shell coating uniformity and shell thickness uniformity around the nanoparticle core. Taken together, these terms can be used to indicate degree of heterogeneity of nanoparticle surface structure. However, characterization of nanoparticle surface structure under physiological conditions is challenging due to limitations of experimental techniques. In this paper, we apply SAXS contrast variation combined with ab initio bead modeling for this purpose. Approach is based on the fact that nanoparticles under study are produced by self-assembly of phospholipid-conjugated molecules that possess moieties with significantly different electron densities enabling SAXS technique to be used to distinguish nanoparticle shell and study its structure. Ab initio single phase and ab initio multiphase modeling based on SAXS curve of nanoparticles in phosphate buffer solution allowed to reconstruct nanoparticle shell coating and assess its uniformity, while serial nanoparticle reconstructions from solutions with gradually increased solvent electron densities revealed relative shell coating thickness around nanoparticle core. Nanoparticle shell structure representation was verified by molecular dynamics simulation and derived full-atom nanoparticle shell structure showed good agreement with SAXS-derived representation. Obtained data indicate that studied nanoparticles exhibit highly heterogeneous surface structure.

Identification of Ultrastructural Details of the Astrocyte Process System in Nervous Tissue of the Brain Using Correlative Scanning Probe and Transmission Electron Microscopy.

Nanoscale morphological features of branched processes of glial cells may be of decisive importance for neuron-astrocyte interactions in health and disease. The paper presents the results of a correlation analysis of images of thin processes of astrocytes in nervous tissue of the mouse brain, which were obtained by scanning probe microscopy (SPM) and transmission electron microscopy (TEM) with high spatial resolution. Samples were prepared and imaged using a unique hardware combination of ultramicrotomy and SPM. Astrocyte details with a thickness of several tens of nanometers were identifiable in the images, making it possible to reconstruct the three-dimensional structure of astrocytic processes by integrating a series of sequential images of ultrathin sections of nervous tissue in the future.

Investigation of the Distribution of Magnetic Nanoparticles in Tumor Tissues by the Method of Scanning Magnetic Force Nanotomography.

The development of effective biomedical technologies using magnetic nanoparticles (MNPs) for the tasks of oncotherapy and nanodiagnostics requires the development and implementation of new methods for the analysis of micro- and nanoscale distributions of MNPs in the volume of cells and tissues. The paper presents a new approach to three-dimensional analysis of MNP distributions - scanning magnetic force nanotomography as applied to the study of tumor tissues. Correlative reconstruction of MNP distributions and nanostructure features of the studied tissues made it possible to quantitatively estimate the parameters of three-dimensional distributions of composite nanoparticles based on silicon and iron oxide obtained by femtosecond laser ablation and injected intravenously and intratumorally into tumor tissue samples of B16/F1 mouse melanoma. The developed technology based on the principles of scanning probe nanotomography is applicable for studying the features of three-dimensional micro- and nanoscale distributions of magnetic nanoparticles in biomaterials, cells and tissues of various types.

Nanohybrid Structures Based on Plasmonic or Fluorescent Nanoparticles and Retinal-Containing Proteins.

Rhodopsins are light-sensitive membrane proteins enabling transmembrane charge separation (proton pump) on absorption of a light quantum. Bacteriorhodopsin (BR) is a transmembrane protein from halophilic bacteria that belongs to the rhodopsin family. Potential applications of BR are considered so promising that the number of studies devoted to the use of BR itself, its mutant variants, as well as hybrid materials containing BR in various areas grows steadily. Formation of hybrid structures combining BR with nanoparticles is an essential step in promotion of BR-based devices. However, rapid progress, continuous emergence of new data, as well as challenges of analyzing the entire data require regular reviews of the achievements in this area. This review is devoted to the issues of formation of materials based on hybrids of BR with fluorescent semiconductor nanocrystals (quantum dots) and with noble metal (silver, gold) plasmonic nanoparticles. Recent data on formation of thin (mono-) and thick (multi-) layers from materials containing BR and BR/nanoparticle hybrids are presented.

[Semiconductor fluorescent nanocrystals (quantum dots) in biological biochips].

Comprehension of biological processes in cells, tissues and organisms requires identification and analysis of numerous biological objects, mechanisms of their action and regulation. Microarray (biochips) technology is a rare tool to solve this problem. It is based on high-throughput recognition of a target to the probe and has the potential to measure simultaneously the presence of numerous molecules in multiplexed testes, all contained in a small drop of test fluid. Biochips allow the parallel analysis of genomic or proteomic content in healthy versus disease-affected or altered tissues or cells. The signals read-out from the biochips is done with organic dyes which often suffer from photobleaching, low brightness and background fluorescence. Recent data show that the use of fluorescent nanocrystals "quantum dots" (QDs) allows push away these restrictions. The QDs are sufficiently bright to be detected as individual particles, extremely resistant to photobleaching and provide unique possibilities for multiplexing thus supplying the microarray technology with the novel read-out option enabling the sensitivity of detection reaching the single molecule level. This paper is aimed at the development of the approaches to the QDs application in microarray-based detection. Possibilities of QDs application both in solid state (planar) biochips as well as intensively developing technique of suspension biochips (bead-based assays or liquid biochips) are demonstrated. The latter are more and more applied for simultaneous identification of very large numbers of molecules in proteomics, genomics, drug screening and clinical diagnostics. This assays base on spectral encoded elements (as a rule polymer microbeads). The benefits of using optically encoded microbeads (instead of the solid-state two-dimensional arrays) are derived from the freedom of bead to move in three dimensions. Polymeric beads optically encoded with organic dyes allow for a limited number of unique codes, whereas the use of semiconductor nanocrystals as fluorescent tags improves the beads multiplexed imaging capabilities, photostability and sensitivity of the biological objects detection. Additionally, an employment in suspension biochips of Frster resonance energy transfer (FRET) allows improving detection specificity. The absence of fluorescent background from non-interacting with the beads dye-labelled antibodies additionally increases the sensitivity of detection and further facilitates the multiplexing capabilities of nanocrystals-based detection and diagnostics. So the combination of the biochips and QDs techniques allow increasing detection sensitivity and significantly raising the number of detected objects (multiplexing capacities). Such combination should provide the breakthrough in proteomics, particularly in new drugs development, clinical diagnostics, new disease markers identification, better understanding of intracellular mechanisms.

[DNA sequence-specific ligands: XIII. New Dimeric Hoechst 33258 molecules, inhibitors of HIV-1 integrase in vitro].

Dimeric Hoechst 33258 molecules [dimeric bisbenzimidazoles (DBBIs)] that, upon binding, occupy one turn of the B form of DNA in the narrow groove were constructed by computer simulation. Three fluorescent DBBIs were synthesized; they consist of two bisbenzimidazole units tail-to-tail linked to phenolic hydroxy groups via penta- or heptamethylene or tri(ethylene glycol) spacers and have terminal positively charged N.N-dimethylaminopropyl carboxamide groups in the molecule. The absorption spectra of the DBBIs in the presence of different DNA concentrations showed a hypochromic effect and a small shift of the absorption band to longer wavelengths, which indicated the formation of a complex with DNA. The presence of an isobestic point in the spectrum indicates the formation of one type of DBBI-DNA complexes. The interaction of DBBIs with DNA was studied by CD using a cholesteric liquid-crystalline dispersion (CLD) of DNA. The appearance of a positive band in the absorption region of ligand chromophores in the CD spectrum of the DNA CLD indicates the formation of a DBBI-DNA complex in which ligand chromophores are arranged at an angle close to 54 degrees relative to the helix axis of DNA, which suggests the localization of the DBBI in the narrow groove of DNA. All the DBBIs were found to be in vitro inhibitors of HIV-1 DNA integrase in the 3'-processing reaction, and, of the three DBBIs, two dimers inhibit HIV-1 integrase even in submicromolar concentrations.

The Hoechst 33258 covalent dimer covers a total turn of the double-stranded DNA.

With the goal to design ligands recognizing extended regions on dsDNA, a covalent dimer of the fluorescent dye Hoechst 33258 [bis-HT(NMe)] composed of two dye molecules linked via the phenol oxygen atoms with a (CH2)3-N+ H(CH3)-(CH2)3 fragment was constructed using computer modeling and then synthesized. Its interactions with the double-stranded DNA (dsDNA) were studied by fluorescent and UV-Vis spectroscopy and circular (CD) and linear dichroism (LD). Based on variations in the affinity to the dsDNA, it was shown that complexes of three types are formed. The first type complexes result from binding of a bis-HT(NMe) monomer in the open conformation; in this case the ligand covers the total dsDNA turn and is located in the minor groove according to the positive value of CD at 370 nm. In addition, the ability to form bis-HT(NMe)-bridges between two dsDNA molecules, i.e., each of the two bis-HT(NMe) ends binds to two different dsDNA molecules, was demonstrated for the first type complexes. Spectral characteristics (maximal absorption at 362 nm, positive sign, and maximal value of CD at 370 nm) of the first type complexes conform to those of the specific Hoechst 33258 complex with poly[d(A-T)] x poly[d(A-T]. The second type complexes correspond to the bis-HT(NMe) sandwich (as an inter- or intramolecular) binding to dsDNA with stoichiometry > or = 5 bp. Thereby, a negative LD at 360 nm and the location of bis-HT(NMe) sandwiches in the minor groove of B form dsDNA seems contradictory. Spectral characteristics (maximal positive CD at 345 nm, a dramatic decrease in fluorescence intensity and the shift of its maximum to 490 nm) of these complexes favor a suggestion that this binding correlates to the formation of nonspecific dimeric Hoechst 33258 complex with dsDNA. The third type complexes are characterized by stoichiometry of one bis-HT(NMe) molecule per approximately 2 bp and the tendency to zero of LD values at 270 and 360 nm. We assume that in these complexes bis-HT(NMe) sandwich dimers are formed on dsDNA. The complexes of this type conform to the aggregation type complex of Hoechst 33258 with dsDNA. The ability of bis-HT(NMe) to cover the whole dsDNA turn or form bridges with two dsDNA upon the formation of the first type complexes essentially distinguishes it from Hoechst 33258, which can only occupy 5 bp and does not form such bridges. This specific property of bis-HT(NMe) may support new biological activities.

[Ligands with affinity to specific sequence of DNA base pairs. XII. The synthesis and cytological studies of dimeric Hoechst 33258 molecules].

We synthesized dimeric Hoechst dye molecules composed of two moieties of the Hoechst 33258 fluorescent dye phenolic hydroxy groups of which were tethered via pentamethylene, heptamethylene, or triethylene oxide linkers. A characteristic pattern of differential staining of chromosome preparations from human premonocytic leukemia HL60 cells was observed for all the three fluorescent dyes. The most contrast pattern was obtained for the bis-Hoechst analogue with the heptamethylene linker; its quality was comparable with the picture obtained in the case of chromosome staining with 4',6-diamidino-2-phenylindole. The ability to penetrate into the live human fibroblasts was studied for the three bis-Hoechst compounds. The fluorescence intensity of nuclei of live and fixed cells stained with the penta- and heptamethylene-linked bis-Hoechst analogues was found to differ only slightly, whereas the fluorescence of the nuclei of live cells stained with triethylene oxide-linked bis-Hoechst was considerably weaker than that of the fixed cells. The bis-Hoechst molecules are new promising fluorescent dyes that can both differentially stain chromosome preparations and penetrate through cell and nuclear membranes and effectively stain cell nuclei.

[Kinetics of the lactone-carboxylate transition of hybrid camptothecin-netropsin molecules]. / Kinetika lakton/karboksilatnogo perekhoda gibridnoi molekuly kamptotetsin-netropsin.

The kinetics of the hydrolysis of the lactone ring of a hybrid molecule containing the molecules of the antitumor drug camptothecin and a derivative of the antibiotic netropsines, which is highly affine and specific to the DNA A-T sequences was investigated. It was shown that intramolecular interaction significantly slows down the rate of hydrolysis but does not change the equilibrium ratio of concentrations of the lactone and carboxylate forms of the camptothecin fragment of the hybrid molecule, which corresponds to the pH value. The use of intramolecular interaction for controlling the kinetics of the lactone/carboxylate transition makes it possible to create the drugs of the camptothecin family, which preserve the biologically active lactone form under the physiological conditions for a longer time and, therefore, are more effective as anticancer agents.

[Study of P-glycoprotein effect on the lipid monolayer properties by the Langmuir-Blodgett technique]. / Issledovanie metodom Lengmiura-Blodzhett vliianiia P-glikoproteina na svoistva lipidnykh monosloev.

Expression of the P-glycoprotein (Pgp) is proved to be one of the main reasons for the development of the multidrug resistance (MDR) phenotype by cancer cells. The effect of Pgp on the properties of lipid monolayers was studied using membrane fractions of sensitive and Pgp over-expressing multidrug resistance cancer cells containing 11, 24 or 32% of Pgp relative to the total content of membrane proteins. The effect of the Pgp membrane concentration on the properties of monolayers prepared from the membrane fractions was analyzed by the Langmuir-Blodgett method. The subphase composition was found to play a critical role in the stability of monolayers at any Pgp concentration. The optimal subphase comprised 10 mM tris-HCl buffer, pH 6.5, which made it possible to create very stable monolayer films with the pressure of collapse of about 30-40 mN/m. Monolayers prepared from membrane fractions of sensitive cells and cells containing the maximum (32%) amount of Pgp were found to be much more stable compared with fractions comprising 11 or 24% of Pgp. The analysis of monolayer compression dynamics revealed three distinct stages: (1) the self-organization of lipid molecules, which is characterized by an abrupt change of surface potential; (2) the compression of Pgp molecules at the constant potential of monolayers; and (3) the compression of lipid molecules, which is characterized by a quasilinear increase of both pressure and surface potential. It was shown that the specific surface areas of monolayers formed from sensitive and Pgp-enriched membranes containing 11 or 24% of Pgp are very similar, whereas the surface area of the monolayer formed from membranes containing 32% of Pgp is nearly 1.5-fold greater. This fact may reflect the effect of the threshold rearrangement of the structure of lipid molecules or cooperative modifications of lipid-Pgp interactions induced by the increase in the Pgp content from 24 to 32%. The effect of verapamil, a well-known Pgp modulator, on the properties of monolayers was studied. It was show that verapamil is able to induce changes of the surface of Pgp-containing monolayers, and these modifications are maximal at the Pgp:verapamil 1:1 molar ratio. The data present the first experimental evidence for the possible intervention of Pgp modulator into the processes of lipid-lipid or lipid-Pgp cooperative interactions within Pgp-enriched membranes.

[Interaction of topotecan, DNA topoisomerase I inhibitor, with double-stranded polydeoxyribonucleotides. 4. Topotecan binds preferably to the GC base pairs of DNA]. / Vzaimodeistvie topotekana--ingibitora DNK-topoizomerazy I--s dvunitevymi polidezoksiribonukleotidami. IV. Topotekan sviazyvaetsia preimushchestvenno s GC-parami osnovanii DNK.

Interaction of topotecan (TPT) with synthetic double-stranded polydeoxyribonucleotides has been studied in solutions of low ionic strength at pH = 6.8 by linear flow dichroism (LD), circular dichroism (CD), UV-Vis absorption and Raman spectroscopy. The complexes of TPT with poly(dG-dC).poly(dG-dC), poly(dG).poly(dC), poly(dA-dC).poly(dG-dT), poly(dA).poly(dT) and previously studied by us complexes of TPT with calf thymus DNA and coliphage T4 DNA have been shown to have negative LD in the long-wavelength absorption band of TPT, whereas the complex of TPT with poly(dA-dT).poly(dA-dT) has positive LD in this absorption band of TPT. Thus, there are two different types of TPT complexes with the polymers. TPT has been established to bind preferably to GC base pairs because its affinity to the polymers of different GC composition decreases in the following order: poly(dG-dC).poly(dG-dC) > poly(dG).poly(dC) > poly(dA-dC).poly(dG-dT) > poly(dA).poly(dT). The presence of DNA has been shown to shift monomer-dimer equilibrium in TPT solutions toward dimer formation. Several duplexes of the synthetic polynucleotides bound together by the bridges of TPT dimers may participate in the formation of the studied type of TPT-polynucleotide complexes. Molecular models of TPT complex with linear and ring supercoiled DNAs and with deoxyguanosine have been considered. TPT (and presumably all camptothecin family) proved to be a representative of a new class of DNA-specific ligands whose biological action is associated with formation of dimeric bridges between two DNA duplexes.

[Interaction of topotecan, DNA topoisomerase I inhibitor, with double-stranded polydeoxyribonucleotides. III. Binding at the minor groove]. / Vzaimodeistvie topotekana--ingibitora DNK-topoizomerazy I--s dvunitevymi polidezoksiribonukleotidami. III. Mesto sviazyvaniia--uzkaia borozdka.

Interaction of topotecan (TPT) with calf thymus DNA, coliphage T4 DNA, and poly(dG-dC). poly(dG-dC) was studied by optical (linear flow dichroism, UV-vis spectroscopy) and quantum chemical methods. The linear dichroism (LD) signal of TPT bound to DNA was shown to have positive sign in the range 260-295 nm. This means that the plane of quinoline fragment (rings A and B) of TPT molecule form an angle lower 54 degrees with the long axis of DNA, and hence TPT molecule can not intercalate between DNA base pairs. TPT was established to bind to calf thymus DNA as readily as to coliphage T4 DNA whose all cytosines in the major groove were glycosylated at the 5th position. Consequently, the DNA major groove does not participate in TPT binding. TPT molecule was shown to compete with distamycin for binding sites in the minor groove of DNA and poly(dG-dC). poly(dG-dC). Thus, it was demonstrated for the first time that TPT binds to DNA at its minor groove.

[Interaction of topotecan--a DNA topoisomerase inhibitor--with dual-stranded polydeoxyribonucleotides. I. Dimerization of topotecan in solution]. / Vzaimodeistvie topotekana--ingibitora DNK-topoizomerazy I--s dvunitevymi polidezoksiribonukleotidami. I. Dimerizatsii topotekana v rastvore.

Behavior of topotecan, DNA topoisomerase I inhibitor, was studied in aqueous solutions by optical methods. Topotecan absorption spectra were recorded in the pH range 0.5-11.5 and its pKa were determined. Quantum chemical calculations were made for all charge states of the topotecan molecule in lactone and carboxylate form. The calculated absorption maxima agree well with the experimental data. Protonation of the topotecan D ring (pKa = 3.6) was revealed. Comparison of experimental and calculated data showed topotecan structure with a proton at the oxygen atom at C16a rather than N4 to be the most preferable. Topotecan molecules were shown to form dimers at concentrations above 10(-5) M. Topotecan dimerization is accompanied by an increase in the pKa of hydroxy group of the A ring from 6.5 ([TPT] = 10(-6) M) to 7.1 ([TPT] = 10(-4) M), which indicates participation of this group in dimer stabilization, perhaps due to intermolecular hydrogen bonding with N1 of the B ring of a neighboring molecule. Probable dimer structures were proposed. The topotecan dimerization constant was determined, K = (4.0 +/- 0.7) x 10(3) M-1.

[Surface enhanced Raman spectroscopy for characterization of structural characteristics of carbon chains in alpha1-acid glycoprotein and pseudoglycoproteins]. / Osobennosti strukturnoi organizatsii uglevodnykh tsepei v alfa1- kislom glikoproteine i psevdoglikoproteinakh po dannym spektroskopii gigantskogo kombinatsionnogo rasseianiia.

Surface-enhanced Raman scattering (SERS) spectroscopy was used to study the structure of carbohydrate chains in glycosylated forms of alpha 1-acid glycoprotein (AGP) and in pseudoglycoproteins obtained by transferring the carbohydrate chains of AGP to a polyacrylamide carrier. It was found that AGP-D glycoform and pseudoglycoproteins containing three or more glycans per molecule, which possess high immunomodulating activity, have a specific spatial organization of carbohydrate chains. This organization is maintained by the interaction of neighboring glycans with each other and does not depend on the nature of the carrier (whether it is polypeptide or polyacrylamide).

[Study of sialated neoglycoconjugates by surface enhanced Raman scattering spectroscopy]. / Issledovanie sialirovannykh neoglikokon''iugatov metodom spektroskopii gigantskogo kombinatsionnogo rasseianiia.

Neoglycoconjugates based on polyacrylamide and sialic acid with N-acetylneuraminic acid or sialooligosaccharides as side chains were studied by surface-enhanced Raman scattering (SERS) spectroscopy. It had previously been found that these polymers can effectively inhibit influenza virus adhesion. This study revealed the possibility to evaluate, based on the intensity of SERS signals, the overall availability for interaction and the conformational freedom of sialic acid residues in glycoconjugates. The dependence of these two factors on the structure and density of sialylated side chains was studied. The uniformity of distribution of sialylated side chains in conjugates was shown. Comparison of the results of the SERS spectroscopic study of the conjugates and the data on their inhibitory effect on the adhesion of specific strains of influenza virus allowed the identification of the conjugates for which the availability and conformational freedom of sialic acid are the main factors determining their inhibitory properties. A conclusion was also reached about the predominance of one of the mechanisms (competitive inhibition or steric stabilization) in the inhibitory properties of the specific conjugates.