Fluorescence in situ hybridization on human metaphase chromosomes detected by near-field scanning optical microscopy

Visualization by atomic force microscopy and FISH of the 45S rDNA gaps in mitotic chromosomes of Lolium perenne

The mitotic chromosome structure of 45S rDNA site gaps in Lolium perenne was studied by atomic force microscope (AFM) combining with fluorescence in situ hybridization (FISH) analysis in the present study. FISH on the mitotic chromosomes showed that 45S rDNA gaps were completely broken or local despiralizations of the chromatid which had the appearance of one or a few thin DNA fiber threads. Topography imaging using AFM confirmed these observations. In addition, AFM imaging showed that the broken end of the chromosome fragment lacking the 45S rDNA was sharper, suggesting high condensation. In contrast, the broken ends containing the 45S rDNA or thin 45S rDNA fibers exhibited lower density and were uncompacted. Higher magnification visualization by AFM of the terminals of decondensed 45S rDNA chromatin indicated that both ends containing the 45S rDNA also exhibited lower density zones. The measured height of a decondensed 45S rDNA chromatin as obtained from the AFM image was about 55-65 nm, composed of just two 30-nm single fibers of chromatin. FISH in flow-sorted G2 interphase nuclei showed that 45S rDNA was highly decondensed in more than 90% of the G2/M nuclei. Our results suggested that a failure of the complex folding of the chromatin fibers occurred at 45S rDNA sites, resulting in gap formation or break.

Scanning conductance microscopy investigations on fixed human chromosomes

Scanning conductance microscopy investigations were carried out in air on human chromosomes fixed on pre-fabricated SiO2 surfaces with a backgate. The point of the investigation was to estimate the dielectric constant of fixed human chromosomes in order to use it for microfluidic device optimization. The phase shift caused by the electrostatic forces, together with geometrical measurements of the atomic force microscopy (AFM) cantilever and the chromosomes were used to estimate a value for the dielectric constant of different human chromosomes.

Chromosome morphology after long-term storage investigated by scanning near-field optical microscopy

Fluorescence in situ hybridization coupled with far-field fluorescence microscopy is a commonly used technique to visualize chromosomal aberrations in diseased cells. To obtain the best possible results, chromatin integrity must be preserved to ensure optimal hybridization of fluorescence in situ hybridization probes. However, biological samples are known to degrade and storage conditions can be critical. This study concentrates its investigation on chromatin stability as a function of time following fluorescence in situ hybridization type denaturing protocols. This issue is extremely important because chromatin integrity affects the fluorescence response of the chromosome. To investigate this, metaphase chromosome spreads of human lymphocytes were stored at both -20 and -80 degrees C, and were then imaged using scanning near-field optical microscopy over a nine month period. Using the scanning near-field optical microscope's topography mode, chromosome morphology was analysed before and after the application of fluorescence in situ hybridization type protocols, and then as a function of storage time. The findings revealed that human chromosome samples can be stored at -20 degrees C for short periods of time (approximately several weeks), but storage over 3 months compromises chromatin stability. Topography measurements clearly show the collapse of the stored chromatin, with variations as large as 60 nm across a chromosome. However, storage at -80 degrees C considerably preserved the integrity with variations in topography significantly reduced. We report studies of the fluorescent response of stored chromosomes using scanning near-field optical microscopy and their importance for gaining further understanding of chromosomal aberrations.

Near-field scanning optical microscopy in cell biology and cytogenetics

Light microscopy has proven to be one of the most versatile analytical tools in cell biology and cytogenetics. The growing spectrum of scientific knowledge demands a continuous improvement of the optical resolution of the instruments. In far-field light microscopy, the attainable resolution is dictated by the limit of diffraction, which, in practice, is about 250 nm for high-numerical-aperture objective lenses. Near-field scanning optical microscopy (NSOM) was the first technique that has overcome this limit up to about one order of magnitude. Typically, the resolution range below 100 nm is accessed for biological applications. Using appropriately designed scanning probes allows for obtaining an extremely small near-field light excitation volume (some tens of nanometers in diameter). Because of the reduction of background illumination, high contrast imaging becomes feasible for light transmission and fluorescence microscopy. The height of the scanning probe is controlled by atomic force interactions between the specimen surface and the probe tip. The control signal can be used for the production of a topographic (nonoptical) image that can be acquired simultaneously. In this chapter, the principle of NSOM is described with respect to biological applications. A brief overview of some requirements in biology and applications described in the literature are given. Practical advice is focused on instruments with aperture-type illumination probes. Preparation protocols focussing on NSOM of cell surfaces and chromosomes are presented.

Scanning Near-field Optical/Atomic Force Microscopy detection of fluorescence in situ hybridization signals beyond the optical limit

Fluorescence in situ hybridization (FISH) is widely used in molecular biological study. However, high-resolution analysis of fluorescent signals is theoretically limited by the 300-nm resolution optical limit of light microscopy. As an alternative to detection by light microscopy, we used Scanning Near-field Optical/Atomic Force Microscopy (SNOM/AFM), which can simultaneously obtain topographic and fluorescent images with nanometer-scale resolution. In this study, we demonstrated high-resolution SNOM/AFM imaging of barley chromosome (Hordeum vulgare, cv. Minorimugi) FISH signals using telomeric DNA probes. Besides detecting the granular structures on chromosomes in a topographic image, we clearly detected fluorescent signals in telomeric regions with low-magnification imaging. The high-resolution analysis suggested that one of the telomeric signals could be observed by expanded imaging as two fluorescent regions separated by approximately 250 nm. This result indicated that the fluorescent signals beyond the optical limit were detected with higher resolution scanning by SNOM/AFM.

Scanning probe microscopy for chromosomal research

The study of chromosome structure with scanning probe microscopy provides a range of information from three-dimensional topographic structures through mechanical properties to optical information, usually fluorescence. For atomic force microscopy studies, the importance of removing cell debris from the chromosome surface has been recognized. Studies in aqueous environments reveal a highy swollen and tough chromosomal structure, but the charge interaction between the probe and specimen needs to be considered if high-resolution images are to be achieved. This charge interaction can be used to extract DNA strands of about 2 kbp from the chromosome. SPM studies of chromosomes may also be of value in the identification of defective chromosomes with either duplications or deletions.

Imaging of chromosomes at nano-meter scale resolution using scanning near-field optical/atomic force microscopy

Topographic and fluorescent images of whole barley chromosomes stained with YOYO-1 were observed simultaneously by scanning near-field optical/ atomic force microscopy (SNOM/AFM). The chromosome was relatively smooth and flat in the topographic images and no significant difference in height was present between regions of high fluorescent and low fluorescent intensity in the chromosomes. The telomeric region, labeled by fluorescence in situ hybridization (FISH) method, was also observed by SNOM/AFM at high resolution, and fluorescent signals of the telomeric region were clearly defined on the topographic image of chromatin fibers on the chromosome at the nano-meter scale level. Although the telomeric signals were usually visualized as a single fluorescent region at the end of sister chromatids by conventional light microscopy, they were observed separately as two fluorescent regions, less than 100-200 nm distance, using the SNOM/AFM. The SNOM/AFM offers great potential in identifying particular single gene location on chromosomes in the near future.

Cell biology beyond the diffraction limit: near-field scanning optical microscopy

Throughout the years, fluorescence microscopy has proven to be an extremely versatile tool for cell biologists to study live cells. Its high sensitivity and non-invasiveness, together with the ever-growing spectrum of sophisticated fluorescent indicators, ensure that it will continue to have a prominent role in the future. A drawback of light microscopy is the fundamental limit of the attainable spatial resolution – ∼250 nm – dictated by the laws of diffraction. The challenge to break this diffraction limit has led to the development of several novel imaging techniques. One of them, near-field scanning optical microscopy (NSOM), allows fluorescence imaging at a resolution of only a few tens of nanometers and, because of the extremely small near-field excitation volume, reduces background fluorescence from the cytoplasm to the extent that single-molecule detection sensitivity becomes within reach. NSOM allows detection of individual fluorescent proteins as part of multimolecular complexes on the surface of fixed cells, and similar results should be achievable under physiological conditions in the near future.

Behavior of DNA fibers stretched by precise meniscus motion control

A modified DNA combing method, which can precisely locate straightened DNA fibers on a substrate, has been developed. Precise motion control of a DNA solution droplet on hydrophobic surfaces has allowed detailed analyses of DNA straightening behavior. Our method provides a technique for consistently straightening lambda phage DNA on a trace of droplet motion, though the straightened DNAs had several variations in their alignments. The dependence of the straightened DNA frequency upon motion rate, fluidity in the droplet and environmental humidity was investigated. Visualization of the solution flow in the moving droplet indicated that flows circulating parallel to the contour of the droplet markedly bias the direction of straightening in relation to the site in the droplet. As a result, the alignment variations caused by the site specificity of the bias direction revealed that environmental humidity significantly alters the straightening behavior.

Advances in fluorescence in situ hybridization

The techniques of in situ hybridization (ISH) are widely applied for analyzing the genetic make-up and RNA expression patterns of individual cells. This review focusses on a number of advances made over the last 5 years in the fluorescence ISH (FISH) field, i.e., Fiber-FISH, Multi-colour chromosome painting, Comparative Genomic Hybridization, Tyramide Signal Amplification and FISH with Polypeptide Nucleic Acid and Padlock probes.

Gold-bead scanning near-field optical microscope with laser-force position control

We have developed a scanning near-field optical microscope with an optically trapped metallic particle that has a small diameter compared to the wavelength of visible light. In this microscope we employed spot illumination to enhance the intensity of light scattered from a probe particle so we could reduce the diameter of the probe particle to 40 nm. We detected slight irregularities of the surface of the cover glass near 10-nm depth. Also, we observed gold colloidal particles on the surface of the cover glass.

Near-field fluorescence imaging of genetic material: toward the molecular limit

Chromosomes, DNA, and single fluorescent molecules are studied using an aperture-type near-field scanning optical microscope with tuning fork shear force feedback. Fluorescence in situ hybridization labels on repetitive and single copy probes on human metaphase chromosomes are imaged with a width of 80 nm, allowing their localisation with nanometer accuracy, in direct correlation with the simultaneously obtained topography. Single fluorophores, both in polymer and covalently attached to amino-silanized glass, are imaged using two-channel fluorescence polarization detection. The molecules are selectively excited according to their dipole orientation. The orientation of the dipole moment of all molecules in one image could be directly determined. Rotational dynamics on a 10-ms to 100-s timescale is observed. Finally, shear force imaging of double-stranded DNA with a vertical sensitivity of 0.2 nm is presented. A DNA height of 1.4 nm is measured, which indicates the nondisturbing character of the shear force mechanism.

Simultaneous detection of near-field topographic and fluorescence images of human chromosomes via scanning near-field optical/atomic-force microscopy (SNOAM)

Scanning near-field optical/atomic-force microscopy (SNOAM) provided us with simultaneous topographical and optical images of human chromosomes using a sharp and bent optical fiber as a near-field optical probe. Native chromosomes were spread out onto a coverslip using the surface-spreading whole-mount method. The SNOAM system does not need pretreatment of samples such as metal coating or chemical immobilization. Near-field topographic and fluorescence images provided useful information on native chromosome structure.