Complementary visualization of mitotic barley chromatin by field-emission scanning electron microscopy and scanning force microscopy

Karyotype analysis of buckwheat using atomic force microscopy

Karyotype analysis and classification of buckwheat chromosomes were performed without chemical banding or staining using atomic force microscopy (AFM). Fagopyrum esculentum (common buckwheat) and Fagopyrum tartaricum (Tartarian buckwheat) chromosomes were isolated from root tissues using an enzymatic maceration technique and spread over a glass substrate. Air-dried chromosomes had a surface with ridges, and the height of common and tartary buckwheat were approximately 350 and 150 nm. Volumes of metaphase sets of buckwheat chromosomes were calculated using three-dimensional AFM measurements. Chromosomes were morphologically characterized by the size, volume, arm lengths, and ratios. The calculated volumes of the F. esculentum and F. tartaricum chromosomes were in the ranges of 1.08-2.09 μm3 and 0.49-0.78 μm3, respectively. The parameters such as the relative arm length, centromere position, and the chromosome volumes measured using AFM provide accurate karyomorphological classification by avoiding the subjective inconsistencies in banding patterns of conventional methods. The karyotype evolutionary trend indicates that F. esculentum is an ancient species compared to F. tartaricum. This is the first report of a cytological karyotype of buckwheat using AFM.

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.

Focused ion beam (FIB) combined with high resolution scanning electron microscopy: a promising tool for 3D analysis of chromosome architecture

Focused ion beam (FIB) milling in combination with field emission scanning electron microscopy (FESEM) was applied to investigations of metaphase barley chromosomes, providing new insight into the chromatin packaging in the chromosome interior and 3D distribution of histone variants in the centromeric region. Whole mount chromosomes were sectioned with FIB with thicknesses in the range of 7-20nm, resulting in up to 2000 sections, which allow high resolution three-dimensional reconstruction. For the first time, it could be shown that the chromosome interior is characterized by a network of interconnected cavities, with openings to the chromosome surface. In combination with immunogold labeling, the centromere-correlated distribution of histone variants (phosphorylated histone H3, CENH3) could be investigated with FIB in three dimensions. Limitations of classical SEM analysis of whole mount chromosomes with back-scattered electrons requiring higher accelerating voltages, e.g. faint and blurred interior signals, could be overcome with FIB milling: from within the chromosome even very small labels in the range of 10nm could be precisely visualized. This allowed direct quantification of marker molecules in a three-dimensional context. Distribution of DNA in the chromosome interior could be directly analyzed after staining with a DNA-specific platinorganic compound Platinum Blue. Higher resolution visualization of DNA distribution could be performed by preparation of FIB lamellae with the in situ lift-out technique followed by investigation in dark field with a scanning transmission electron detector (STEM) at 30kV.

Scanning electron microscopy of chromosomes

Scanning electron microscopic analysis is an indispensable tool for high-resolution visualization of chromosomes and their ultrastructural details. It allows a three-dimensional structural approach for elucidating higher-order chromatin structure and chromosome architecture. Artificial decondensation under a variety of conditions shows that structural elements of chromosomes are composed of matrix fibers and chromomeres. Currently, chromosome labeling methods include DNA contrasting with platinum blue, silver contrasting of proteins, and immunolabeling with Nanogold. With these techniques, DNA and protein distribution can be determined, and functionally relevant elements (e.g., epigenetic modifications, specific proteins, DNA sequences) can be located to structural elements of chromosomes with, at present, local resolution of approximately 30 nm.

3D analysis of chromosome architecture: advantages and limitations with SEM

Three-dimensional mitotic plant chromosome architecture can be investigated with the highest resolution with scanning electron microscopy compared to other microscopic techniques at present. Specific chromatin staining techniques making use of simultaneous detection of back-scattered electrons and secondary electrons have provided conclusive information on the distribution of DNA and protein in barley chromosomes through mitosis. Applied to investigate the structural effects of different preparative procedures, these techniques were the groundwork for the "dynamic matrix model" for chromosome condensation, which postulates an energy-dependent process of looping and bunching of chromatin coupled with attachment to a dynamic matrix of associated protein fibers. Data from SEM analysis shows basic higher order chromatin structures: chromomeres and matrix fibers. Visualization of nanogold-labeled phosphorylated histone H3 (ser10) with high resolution on chromomeres shows that functional modifications of chromatin can be located on structural elements in a 3D context.

Effects of acetic acid treatment on plant chromosome structures analyzed by atomic force microscopy

Acetic acid treatment has been frequently used to remove cellular contaminants from plant chromosome samples for structural analyses by scanning electron microscopy and atomic force microscopy (AFM). We evaluated the effects of various concentrations of acetic acid treatments on barley chromosome structures by using AFM. The long-term 45% acetic acid treatment significantly damaged the chromosome structures, although the treatment effectively removed the cellular contaminants. On the other hand, the treatment with 15% acetic acid could not obtain sufficiently clean chromosome samples and the chromosome surface structures could not be observed. In contrast, we obtained clean chromosome preparation without severe damage by using an intermediate concentration (30%) of acetic acid treatment. In the centromeric region, we could observe fiber structures with a width of 100 nm, which were composed of ca. 50-nm granules and aligned to the axes of chromosomes. Thus, AFM analysis of chromosomes appropriately treated with acetic acid will provide important insights into the organization of higher-order structures of plant chromosomes.

Immunogold labeling of chromosomes for scanning electron microscopy: a closer look at phosphorylated histone H3 in mitotic metaphase chromosomes of Hordeum vulgare

High-resolution detection of phosphorylated histone H3 at serine 10 in mitotic barley chromosomes for scanning electron microscopy was shown using a novel application of indirect immunogold labeling with Nanogold. This method permits localization and quantification of signals in a three-dimensional context. Because the chromosome structure is well preserved, characterization of binding sites (chromomeres, parallel matrix fibers, solenoids), currently in the realm of nanometer decades, is possible. Quantification and three-dimensional localization of labels is possible with stereoscopic analysis. Limitations of the method pertain to the challenges in preservation of chromosome ultrastructure, accessibility of immunoreactants into the fixed chromatin and unspecific labeling. The differences between silver and gold enhancement and the current status of labeling efficiency are addressed.

Analysis by atomic force microscopy of morphological changes in barley chromosomes during FISH treatment

We employed atomic force microscopy (AFM) to examine structural changes in barley chromosomes during the four steps of standard FISH processes. Rehydration and dehydration with alcohol accompanying RNase treatment increased chromosome arm width and decreased chromosome height about 50%. Subsequent heat denaturation reduced chromosome height further. These three-dimensional structural changes of the chromosomes were substantial, but the FISH signal produced by the hybridization of fluorescent probes was clear when observed by a fluorescence microscope. In higher-magnification images, we observed granular structures considered to represent the chromatin fiber on the surface of the chromosomes in each FISH protocol step. These our results indicate that FISH treatments result in severe damage of the three-dimensional higher-order structures of the chromosomes, although nano-structures, such as nucleosome and chromatin fibers, remain intact and relatively unaffected.

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.

Nano-scale imaging of chromosomes and DNA by scanning near-field optical/atomic force microscopy

Nano-scale structures of the YOYO-1-stained barley chromosomes and lambda-phage DNA were investigated by scanning near-field optical/atomic force microscopy (SNOM/AFM). This technique enabled precise analysis of fluorescence structural images in relation to the morphology of the biomaterials. The results suggested that the fluorescence intensity does not always correspond to topographic height of the chromosomes, but roughly reflects the local amount and/or density of DNA. Various sizes of the bright fluorescence spots were clearly observed in fluorescence banding-treated chromosomes. Furthermore, fluorescence-stained lambda-phage DNA analysis by SNOM/AFM demonstrated the possibility of nanometer-scale imaging for a novel technique termed nano-fluorescence in situ hybridization (nano-FISH). Thus, SNOM/AFM is a powerful tool for analyzing the structure and the function of biomaterials with higher resolution than conventional optical microscopes.

Atomic force microscopic imaging of 30 nm chromatin fiber from partially relaxed plant chromosomes

We have developed a procedure for partially relaxing the barley metaphase chromosomes and exposing fibrous structures from the chromosomes. The observation by atomic force microscopy (AFM) showed that the fibrous structures are typically 0.5 to 1 microm long and 40 to 50 nm in diameter. In higher magnification imaging, we found the fibrous structures were composed of aligned granules and looked like "knobby fiber." These observations are consistent with previously reported features of chromatin fiber observed by AFM and scanning electron microscopy, suggesting that the structures correspond to 30 nm chromatin fibers. We observed the chromatin fiber extending straight from the periphery of the chromosomes in most cases, but fibers with different shapes, such as loop and spiral, were also observed. The procedure reported here will provide a new approach for observing the organization of chromatin fiber to higher-order structures by AFM and other high-resolution microscopy.

Atomic force microscopy study of chromosome surface structure changed by protein extraction

We applied atomic force microscopy (AFM) to investigate the surface structure of barley chromosome in combination with a chemical treatment method. As a result, we have obtained high-resolution topographic images of granular structures with a diameter of ca. 50 nm on the surface of critical-point dried metaphase chromosomes. Treatment with 2M NaCl significantly modified the chromosome surface structure: surface roughness was increased and chromosome thickness was decreased. The NaCl treatment extracted two major proteins with molecular weights of 4000 and 20,000 Da. These proteins might be belonging to non-histone protein families that do not contain any aromatic amino acid. The results demonstrate the advantage of the combined method of high-resolution AFM imaging and chemical treatments for understanding nano-scale surface structures of the chromosome.

Mechanical elongation of the centromere in the barley metaphase chromosome

The present study investigated the mechanical elongation of the centromere in the barley chromosomes by a microneedle manipulation method for the structural analysis of the chromosomes. Chromosomes were extracted from barley root cells, affixed on a cover slip by a standard preparation method, and elongated in either distilled water, phosphate buffered saline (PBS), or 2 x sodium saline citrate (SSC). The mechanical property of the chromosome elongation was assessed by the measurement of the force required for the elongation of chromosomes. This assessment has shown that the chromosomes in distilled water were much firmer than those in the PBS or 2 x SSC. To confirm the elongation of the centromere, the elongated chromosomes were investigated by fluorescence in situ hybridization with a centromere probe. The fluorescence information indicated that the extent of the loosening of the centromere during elongation differed depending on the buffers used; the centromere elongated in 2 x SSC was more loosened than that in the PBS. Atomic force microscopy also revealed the structure of the unpacked centromere after the mechanical elongation, when rows of fibrous structures about 30 to 50 nm thick were clearly observed in the centromere elongated in 2 x SSC. The investigation of elongated chromosomes should prove useful for an understanding of the structural analysis of chromosomes.

A new chromosome model

We present a new model of the three-dimensional structure of chromosomes. With DNA and protein staining it could be shown by high-resolution scanning electron microscopy that metaphase chromosomes are mainly composed of DNA packed in "chromomeres" (coiled solenoides) and a dynamic matrix formed of parallel protein fibers. In the centromeric region, the chromomeres are less densely packed, giving insight into the matrix fibers. We postulate that chromosome condensation is achieved by the binding of solenoids to matrix fibers which have contact sites to one another and move antiparallel to each other. As condensation progresses, loops of solenoids accumulate to form additional chromomeres, causing chromosomes to become successively shorter and thicker as more chromomeres are formed. For sterical reasons, a tension vertical to the axial direction forces the chromatids apart. The model can simply explain the enormous variety of chromosome morphology in plant and animal systems by varying only a few cytological parameters. Primary and secondary constrictions and deletions are defined as regions devoid of chromomeres. Even in the highly condensed metaphase, all genes would be easily accessible.