Label-free, high-throughput measurements of dynamic changes in cell nuclei using angle-resolved low coherence interferometry

Accurate measurements of nuclear deformation, i.e., structural changes of the nucleus in response to environmental stimuli, are important for signal transduction studies. Traditionally, these measurements require labeling and imaging, and then nuclear measurement using image analysis. This approach is time-consuming, invasive, and unavoidably perturbs cellular systems. Light scattering, an emerging biophotonics technique for probing physical characteristics of living systems, offers a promising alternative. Angle-resolved low-coherence interferometry (a/LCI), a novel light scattering technique, was developed to quantify nuclear morphology for early cancer detection. In this study, a/LCI is used for the first time to noninvasively measure small changes in nuclear morphology in response to environmental stimuli. With this new application, we broaden the potential uses of a/LCI by demonstrating high-throughput measurements and by probing aspherical nuclei. To demonstrate the versatility of this approach, two distinct models relevant to current investigations in cell and tissue engineering research are used. Structural changes in cell nuclei due to subtle environmental stimuli, including substrate topography and osmotic pressure, are profiled rapidly without disrupting the cells or introducing artifacts associated with traditional measurements. Accuracy ≥ 3% is obtained for the range of nuclear geometries examined here, with the greatest deviations occurring for the more complex geometries. Given the high-throughput nature of the measurements, this deviation may be acceptable for many biological applications that seek to establish connections between morphology and function.     

Solid state fluorescence of lyophilized proteins

Fluorescence spectroscopy has been used to measure changes in the tertiary structure of proteins in the solution state. The sensitivity of fluorescence to the protein tryptophan environment has made it a useful tool for studying protein conformation and stability. Using fluorescence spectroscopy to probe structural alterations in lyophilized proteins has been limited due to technical challenges and overwhelming background light scattering. We have investigated the possibility of analyzing lyophilized proteins using the Cary-Eclipse spectrofluorometer by monitoring the fluorescence of the protein therapeutic after subjecting the lyophilized cake to heat-induced accelerated degradation. We have been able to obtain reproducible fluorescence spectra, detecting possible structural changes under these conditions. Fluorescence and circular dichroism spectroscopic analyses of the reconstituted proteins indicated that changes in fluorescence intensities observed in the solid state could be correlated to that in solution and to possible tertiary structural changes. Size exclusion chromatography analysis of protein Y subject to accelerated degradation showed a correlation between decreasing fluorescence intensity and increasing protein Y tetramer in solution, consistent with long-term stability. This suggests that solid state, intrinsic protein fluorescence measurements using the Cary-Eclipse holder may be feasible for long-term stability studies and formulation development.     

Unusual salt-induced behaviour of guanine-rich natural DNA evidenced by dynamic light scattering

The appearance of the slow mode, revealed by dynamic light scattering (DLS) measurements in Micrococcus luteus DNA with high GC content, and the effect of guanine sequences on changes of DNA physical state and conformational transitions were investigated. We used two different spectroscopic approaches: DLS, to evidence the relatively slowly diffusing particles arising at high salt concentration, ascribable to the formation of large unspecific molecular aggregates, and circular dichroism spectroscopy, to identify these entities. Our results bring us to conclude that a peculiar, unconventional, structural transition, due to the presence of long guanine stretches, in a well-defined experimental condition, can occur. We comment on the biological implications to detect, by spectroscopic measurements, such an unusual structure involved in the stability, protection and replication maintenance along the human telomeric G-rich strand.     

Protein conformations explored by difference high-angle solution X-ray scattering: oxidation state and temperature dependent changes in cytochrome C

We demonstrate the use of high-angle X-ray scattering to explore protein conformational states in solution by resolving oxidation state- and temperature-dependent changes in the conformation of horse heart cytochrome c. Several detailed models exist for oxidation-dependent changes in mitochondrial class I c cytochromes determined by X-ray crystallography and solution NMR techniques. These models differ in the magnitude and locations of structural change. Our scattering measurements show that high-angle X-ray scattering can discriminate between these models, and that the experimental scattering data for horse cytochrome c can be best reconciled with selected NMR models for the same protein. These results demonstrate the ability to use high-angle X-ray scattering to resolve conformational states of proteins in solution, and to relate these measurements to detailed structural models. Furthermore, temperature-dependent changes are found in the high angle scattering patterns for horse cytochrome c, illustrating the sensitivity of these measurements to dynamic aspects of protein structure. These results demonstrate the ability to use difference high angle scattering as a quantitative monitor of reaction-linked changes in protein conformation and structural dynamics. Synchrotron-based high-angle scattering holds promise as a widely applicable, high throughput technique for exploring conformational states linked to physiological protein function, for resolving configurational differences between protein structures in solution and crystalline states, and for bridging the gap between solution NMR and crystallographic structure techniques.     

Tomographic phase microscopy

We report a technique for quantitative three-dimensional (3D) mapping of refractive index in live cells and tissues using a phase-shifting laser interferometric microscope with variable illumination angle. We demonstrate tomographic imaging of cells and multicellular organisms, and time-dependent changes in cell structure. Our results will permit quantitative characterization of specimen-induced aberrations in high-resolution microscopy and have multiple applications in tissue light scattering.     

Quantifying Biomass Changes of Single CD8+ T Cells during Antigen Specific Cytotoxicity

Existing approaches that quantify cytotoxic T cell responses rely on bulk or surrogate measurements which impede the direct identification of single activated T cells of interest. Single cell microscopy or flow cytometry methodologies typically rely on fluorescent labeling, which limits applicability to primary cells such as human derived T lymphocytes. Here, we introduce a quantitative method to track single T lymphocyte mediated cytotoxic events within a mixed population of cells using live cell interferometry (LCI), a label-free microscopy technique that maintains cell viability. LCI quantifies the mass distribution within individual cells by measuring the phase shift caused by the interaction of light with intracellular biomass. Using LCI, we imaged cytotoxic T cells killing cognate target cells. In addition to a characteristic target cell mass decrease of 20–60% over 1–4 h following attack by a T cell, there was a significant 4-fold increase in T cell mass accumulation rate at the start of the cytotoxic event and a 2–3 fold increase in T cell mass relative to the mass of unresponsive T cells. Direct, label-free measurement of CD8+ T and target cell mass changes provides a kinetic, quantitative assessment of T cell activation and a relatively rapid approach to identify specific, activated patient-derived T cells for applications in cancer immunotherapy.     

Cell cycle studies of murine leukemia cell L5l78Y by polarization effects of light scattering

The structural changes during the life cycle of a synchronized population of mouse leukemia cell line L5l78Y have been described by polarized light scattering measurements. Exponentially growing cells were synchronized by an automatic excess thymidine-colcemid treatment technique. Samples were removed from the suspension culture and fixed with glutaraldehyde at hourly intervals throughout the life cycle. The effect these cell samples had in changing right-hand circularly polarized light to 45° linearly polarized light during the scattering process was measured at angles 6–l60° to the incident beam. The reproducibility of the light scattering signals for each time interval was statistically evaluated and found to have good intertrial correlation for each time period in the angular range 6–60° to the incident beam. Statistically significant changes were seen between cell samples during the synchronous life cycle. Therefore, the system developed has applications as an extremely sensitive measure of cell structure, and of structural changes caused by low-level chemical, physical or biological agents.     

Angular range,sampling and noise considerations for inverse light scattering analysis of nuclear morphology

In recent years, significant work has been devoted to the use of angle‐resolved elastic scattering for the extraction of nuclear morphology in tissue. By treating the nucleus as a Mie scattering object, techniques such as angle‐resolved low‐coherence interferometry (a/LCI) have demonstrated substantial success in identifying nuclear alterations associated with dysplasia. Because optical biopsies are inherently noninvasive, only a small, discretized portion of the 4π scattering field can be collected from tissue, limiting the amount of information available for diagnostic purposes. In this work, we comprehensively characterize the diagnostic impact of variations in angular sampling, range and noise for inverse light scattering analysis of nuclear morphology, using a previously reported dataset from 40 patients undergoing a/LCI optical biopsy for cervical dysplasia. The results from this analysis are applied to a benchtop scanning a/LCI system which compromises angular range for wide‐area scanning capability. This work will inform the design of next‐generation optical biopsy probes by directing optical design towards parameters which offer the most diagnostic utility.      

Structural basis of eye lens transparency: light scattering by concentrated solutions of bovine alpha-crystallin proteins.

Short range order of the crystallins does account for the transparency of the eye lens. To explain the solution structure of this highly concentrated protein solution on a quantitative basis, the hydrodynamic structure and the interparticle interactions of the proteins have to be known. For that purpose, the light scattering of concentrated solutions of alpha-crystallin has been studied. Starting from the detailed knowledge of the solution parameters of alpha-crystallin in diluted solutions, the structure of concentrated solutions up to 360 mg/ml has been studied using light scattering. Our results indicate that subtle changes in the macromolecular structure such as optical anisotropy or structural asymmetry for part of the alpha-crystallins, which results in solute light-scattering heterogeneity, can dramatically increase the light scattering by the alpha-crystallins and cause solution opacity.     

Characterization of lysozyme PEGylation products using polarized excitation-emission matrix spectroscopy

The growing use of therapeutic proteins requires accurate analytical techniques for measuring biophysical and structural changes during manufacturing. This is particularly true for the PEGylation of proteins, because characterization of PEGylation reactions and products can often be difficult due to the relatively small impact on protein structure, the lack of an accessible polyethylene glycol (PEG) chromophore, and the heterogeneous final product mixtures. Intrinsic fluorescence spectroscopy is one potential solution due to its relatively high sensitivity to small changes in protein structure and its suitability for online or atline measurements. In this study, we use the PEGylation of lysozyme as a model system to determine the efficacy of polarized excitation-emission matrix (pEEM) spectroscopy as a rapid tool for characterizing the structural variability of the lysozyme (LZ) starting materials and PEGylated products with varying PEG-to-protein ratios (PPR). Dynamic light scattering showed that as PPR increased from 0 to 2.8, the hydrodynamic radius increased from ∼2.2 to 4.8 nm. pEEM measurements provided several sources of information: Rayleigh scattering to identify size changes and aggregate/particle formation, and fluorescence emission to assess chemical and structural changes. PEGylation induced sufficient physicochemical changes in LZ, which produced changes in the pEEM spectra, largely due to variations in the hydrophobic environments of tryptophan residues close to a PEG attachment site. These significant spectral changes when modeled using conventional multivariate analysis methods were able to easily discriminate the raw product solutions according to the degree of PEGylation and were also able to predict PPR with reasonable accuracy (root mean square error for calibration ∼10%, relative error of prediction < 20%), considering the reference size exclusion chromatography method error of ∼7.2%. The variable selection of the pEEM data suggests that equivalent predictions could be obtained with faster and simpler two-dimensional spectra, making the method a more viable online measurement method.     

Spectroscopic studies of D-α-tocopherol concentration-induced transformation in egg phosphatidylcholne vesicles

The effects of embedding up to 60 mol% of α-tocopherol (α-Toc) on the morphology and structure of the egg phosphatidylcholine (PC) membrane were studied using spectroscopic techniques. The resulting vesicles were subjected to turbidometric and dynamic light scattering measurements to evaluate their size distribution. The α-Toc intrinsic fluorescence and its quenching was used to estimate the tocopherol position in the membrane. Optical microscopy was used to visualize morphological changes in the vesicles during the inclusion of tocopherol into the 2 mg/ml PC membrane. The incorporation of up to 15 mol% of tocopherol molecules into PC vesicles is accompanied by a linear increase in the fluorescence intensity and the simultaneous formation of larger, multilamellar vesicles. Increasing the tocopherol concentration above 20 mol% induced structural and morphological changes leading to the disappearance of micrometer-sized vesicles and the formation of small unilamellar vesicles of size ranging from 30 to 120 nm, mixed micelles and non-lamellar structures.     

Coupled analysis of in vitro and histology tissue samples to quantify structure-function relationship

The structure/function relationship is fundamental to our understanding of biological systems at all levels, and drives most, if not all, techniques for detecting, diagnosing, and treating disease. However, at the tissue level of biological complexity we encounter a gap in the structure/function relationship: having accumulated an extraordinary amount of detailed information about biological tissues at the cellular and subcellular level, we cannot assemble it in a way that explains the correspondingly complex biological functions these structures perform. To help close this information gap we define here several quantitative temperospatial features that link tissue structure to its corresponding biological function. Both histological images of human tissue samples and fluorescence images of three-dimensional cultures of human cells are used to compare the accuracy of in vitro culture models with their corresponding human tissues. To the best of our knowledge, there is no prior work on a quantitative comparison of histology and in vitro samples. Features are calculated from graph theoretical representations of tissue structures and the data are analyzed in the form of matrices and higher-order tensors using matrix and tensor factorization methods, with a goal of differentiating between cancerous and healthy states of brain, breast, and bone tissues. We also show that our techniques can differentiate between the structural organization of native tissues and their corresponding in vitro engineered cell culture models.     

Mechanical properties of plant cell walls probed by relaxation spectra

Transformants and mutants with altered cell wall composition are expected to display a biomechanical phenotype due to the structural role of the cell wall. It is often quite difficult, however, to distinguish the mechanical behavior of a mutant's or transformant's cell walls from that of the wild type. This may be due to the plant's ability to compensate for the wall modification or because the biophysical method that is often employed, determination of simple elastic modulus and breakstrength, lacks the resolving power necessary for detecting subtle mechanical phenotypes. Here, we apply a method, determination of relaxation spectra, which probes, and can separate, the viscoelastic properties of different cell wall components (i.e. those properties that depend on the elastic behavior of load-bearing wall polymers combined with viscous interactions between them). A computer program, BayesRelax, that deduces relaxation spectra from appropriate rheological measurements is presented and made accessible through a Web interface. BayesRelax models the cell wall as a continuum of relaxing elements, and the ability of the method to resolve small differences in cell wall mechanical properties is demonstrated using tuber tissue from wild-type and transgenic potatoes (Solanum tuberosum) that differ in rhamnogalacturonan I side chain structure.     

Molecular dynamics in living cells observed by fluorescence correlation spectroscopy with one- and two-photon excitation.

Multiphoton excitation (MPE) of fluorescent probes has become an attractive alternative in biological applications of laser scanning microscopy because many problems encountered in spectroscopic measurements of living tissue such as light scattering, autofluorescence, and photodamage can be reduced. The present study investigates the characteristics of two-photon excitation (2PE) in comparison with confocal one-photon excitation (1PE) for intracellular applications of fluorescence correlation spectroscopy (FCS). FCS is an attractive method of measuring molecular concentrations, mobility parameters, chemical kinetics, and fluorescence photophysics. Several FCS applications in mammalian and plant cells are outlined, to illustrate the capabilities of both 1PE and 2PE. Photophysical properties of fluorophores required for quantitative FCS in tissues are analyzed. Measurements in live cells and on cell membranes are feasible with reasonable signal-to-noise ratios, even with fluorophore concentrations as low as the single-molecule level in the sampling volume. Molecular mobilities can be measured over a wide range of characteristic time constants from approximately 10(-3) to 10(3) ms. While both excitation alternatives work well for intracellular FCS in thin preparations, 2PE can substantially improve signal quality in turbid preparations like plant cells and deep cell layers in tissue. At comparable signal levels, 2PE minimizes photobleaching in spatially restrictive cellular compartments, thereby preserving long-term signal acquisition.     

Multimodal CARS microscopy determination of the impact of diet on macrophage infiltration and lipid accumulation on plaque formation in ApoE-deficient mice

We characterized several cellular and structural features of early stage Type II/III atherosclerotic plaques in an established model of atherosclerosis—the ApoE-deficient mouse—by using a multimodal, coregistered imaging system that integrates three nonlinear optical microscopy (NLOM) contrast mechanisms: coherent anti-Stokes Raman scattering (CARS), second harmonic generation (SHG), and two-photon excitation fluorescence (TPEF). Specifically, the infiltration of lipid-rich macrophages and the structural organization of collagen and elastin fibers were visualized by CARS, SHG, and TPEF, respectively, in thick tissue specimens without the use of exogenous labels or dyes. Label-free CARS imaging of macrophage accumulation was confirmed by histopathology using CD68 staining. A high-fat, high-cholesterol Western diet resulted in an approximate 2-fold increase in intimal plaque area, defined by CARS signals of lipid-rich macrophages. Additionally, analysis of collagen distribution within lipid-rich plaque regions revealed nearly a 4-fold decrease in the Western diet–fed mice, suggesting NLOM sensitivity to increased matrix metalloproteinase (MMP) activity and decreased smooth muscle cell (SMC) accumulation. These imaging results provide significant insight into the structure and composition of early stage Type II/III plaque during formation and allow for quantitative measurements of the impact of diet and other factors on critical plaque and arterial wall features.     

Lorenz-Mie light scattering in cellular biology.

The Lorenz-Mie light scattering is discussed as a tool allowing living cell characterization. The scattered light carries information about the size, shape, internal structure and refractive index of the cell. The advantages of light scattering methods consist in high speed, nondestructive, sensitive and relatively easy measurements. Light scattering methods are compatible with other methods. In light scattering in both static and flow systems. For sphere-like cells reliable size and refractive index information can be extracted. On the empirical basis, light scattering pattern can be used for the cell identification and separation purposes. The full utilization of the light scattering information is limited due to the lack of theoretical knowledge about the complex scatterer properties and efficient inversion schemes. The rapid progress in computer technique and in single-particle scattering experiments may significantly improve the interpretation of light scattering patterns of the biological particles.     

Micromechanics and anatomical changes during early ontogeny of two lianescent Aristolochia species

 The mechanical properties of young stems of Aristolochia macrophylla Lam. and Aristolochia brasiliensis Mart. et Zucc. were studied during elongation growth and primary differentiation. Data for the modulus of elasticity, for the viscoelastic behaviour caused by longitudinal tension and for the shear modulus resulting from torsion around a longitudinal axis were related to the underlying structural changes by quantitative analysis of stem anatomy, tissue distribution, ultrastructure, and cell wall biochemistry. The orientation of cellulose microfibrils was determined by light microscopy and small-angle X-ray diffraction, and the lignin content was determined by thioglycolic acid derivatization and spectroscopic quantification. It was demonstrated that the increase in stability during early development is due to the complementary effects of increase in cell wall material, lignification, and cellulose microfibril alignment. A detailed micromechanical model, considering internal prestresses, is proposed to explain the characteristic biphasic stress-strain behaviour as well as the strain-hardening observed. Received: 22 March 1999 / Accepted 9 September 1999     

X-ray scattering combined with coordinate-based analyses for applications in natural and artificial photosynthesis

Advances in X-ray light sources and detectors have created opportunities for advancing our understanding of structure and structural dynamics for supramolecular assemblies in solution by combining X-ray scattering measurement with coordinate-based modeling methods. In this review the foundations for X-ray scattering are discussed and illustrated with selected examples demonstrating the ability to correlate solution X-ray scattering measurements to molecular structure, conformation, and dynamics. These approaches are anticipated to have a broad range of applications in natural and artificial photosynthesis by offering possibilities for structure resolution for dynamic supramolecular assemblies in solution that can not be fully addressed with crystallographic techniques, and for resolving fundamental mechanisms for solar energy conversion by mapping out structure in light-excited reaction states.     

Nonspecific prion protein-nucleic Acid interactions lead to different aggregates and cytotoxic species

A misfolded form of the prion protein (PrP) is the primary culprit in mammalian prion diseases. It has been shown that nucleic acids catalyze the misfolding of cellular PrP into a scrapie-like conformer. It has also been observed that the interaction of PrP with nucleic acids is nonspecific and that the complex can be toxic to cultured cells. No direct correlation has yet been drawn between changes in PrP structure and toxicity due to nucleic acid binding. Here we asked whether different aggregation, stability, and toxicity effects are detected when nonrelated DNA sequences interact with recombinant PrP. Using spectroscopic techniques to analyze PrP tertiary and secondary structure and cellular assays to assess toxicity, we found that rPrP-DNA interactions lead to different aggregated species, depending on the sequence and size of the oligonucleotide tested. A 21-mer DNA sequence (D67) induced higher levels of aggregation and also dissimilar structural changes in rPrP, compared to binding to oligonucleotides with the same length and different nucleotide sequences or different GC contents. The rPrP-D67 complex induced significant cell dysfunction, which appears to be correlated with the biophysical properties of the complex. Although sequence specificity is not apparent for PrP-nucleic acid interactions, we believe that particular nucleic acid patterns, possibly related to GC content, oligonucleotide length, and structure, govern PrP recognition. Understanding the structural and cellular effects observed for PrP-nucleic acid complexes may shed light on the still mysterious pathology of the prion protein.     

In situ structure and activity studies of an enzyme adsorbed on spectroscopically undetectable particles

The structural characteristics and the activity of a hyperthermophilic endoglucanase were investigated upon adsorption. Silica (hydrophilic) and Teflon (hydrophobic) surfaces were selected for the study. The materials were specially designed so that the interaction of the particles with light was negligible, and the enzyme conformation in the adsorbed state was monitored in situ. The adsorption isotherms were determined, and the adsorbed endoglucanase was studied using a number of spectroscopic techniques, enzymatic activity tests, and dynamic light scattering. Experiments were performed at pH values below, at, and above the isoelectric point of the enzyme. It was shown that the enzyme adsorbed on the hydrophobic surface of Teflon with higher affinity as compared to the hydrophilic silica nanoparticles. In all cases, adsorption was followed by (slight) changes in the secondary structure resulting in decreased beta-structural content. The changes were more profound upon adsorption on Teflon. The adsorbed enzyme remained active in the adsorbed state in spite of the structural changes induced when interacting with the surfaces.