Calcium ion significance on the maintenance of barley (Hordeum vulgare) chromosome compaction.

Cations, especially calcium ions (Ca2+), is one of the major factors responsible for the chromosome higher-order structure formation. The effects of cations on the human chromosomes have already been evaluated, however, whether the presence of similar effects on plant chromosomes has not been reported to date. Thus, in this study, we investigated the role of Ca2+ on the barley (Hordeum vulgare L.) chromosome structure. Barley chromosomes were isolated from the meristematic tissue within the germinated roots. The roots were subjected to enzymatic treatment, fixed, and drop on the cover glass to spread the chromosomes out. Some chromosomes were treated with BAPTA (1,2-Bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid) to chelate Ca2+. Chromosome samples were then observed by fluorescence microscopy and scanning electron microscopy (SEM). The disperse structure of the chromosome was observed after BAPTA treatment. Chromosomes showed less condensed structure due to Ca2+ chelation. The high-resolution of SEM provided a more detailed visualization of chromosome ultrastructure under different calcium ion conditions. This study revealed the calcium ion effect on chromosome structure is important regardless of the organisms, suggesting a similar mechanism of chromosome condensation through humans and plants.

Imaging the inner structure of chromosomes: contribution of focused ion beam/scanning electron microscopy to chromosome research.

Visualization of the chromosome ultrastructure has revealed new insights into its structural and functional properties. The use of new methods for revealing not only the surface but also the inner structure of the chromosome has been emerged. Some methods have long been used, such as conventional transmission electron microscopy (TEM). Although it has indispensably contributed to the revelation of the ultrastructure of the various biological samples, including chromosomes, some challenges have also been encountered, such as laborious sample preparation, limited view areas, and loss of information on some parts due to ultramicrotome sectioning. Therefore, a more advanced method is needed. Scanning electron microscopy (SEM) is also advantageous in the surface visualization of chromosome samples. However, it is limited by accessibility to gain the inner structure information. Focused ion beam/scanning electron microscopy (FIB/SEM) provides a way to investigate the inner structure of the samples in a direct slice-and-view manner to observe the ultrastructure of the inner part of the sample continuously and further construct a three-dimensional image. This method has long been used in the material science field, and recently, it has also been applied to biological research, such as in showing the inner structure of chromosomes. This review article presents the contributions of this new method to chromosome research and its recent developments in the inner structure of chromosome and discusses its current and potential applications to the high-resolution imaging of chromosomes.

Application of the Chromosome Image Analyzing System (CHIAS) for Straightening Cation-treated Bent Chromosomes.

Divalent cations, mainly calcium and magnesium ions, are known to play a major role in the maintenance of chromosomes. The depletion of both ions using ethylenediaminetetraacetic acid (EDTA) results in a bent chromosome structure with extended arms and dispersed chromatin fibers. The importance of divalent cations for the maintenance of chromosome structure has been reported previously; nevertheless, previous studies were limited to qualitative data only. Straightening the bent image of the chromosome would provide quantitative data. Thus, this study aimed to evaluate the effects of cation depletion by the application of the Chromosome Image Analyzing System (CHIAS) to straighten bent chromosomes. Human HeLa chromosomes were treated with EDTA as a known chelating agent in order to investigate the importance of divalent cations on the maintenance of chromosome structure. Chromosomes were stained and directly observed with a fluorescence microscope. Images were then analyzed using CHIAS. The results revealed that EDTA-treated chromosomes showed longer arms than those without EDTA treatment, and most of them tended to bend-out. By straightening the image using CHIAS, the bent chromosomes were successfully straightened. The average lengths of the chromosomes treated with and without EDTA were 4.97 and 0.96 µm, respectively. These results signify the advantages of CHIAS for chromosome analysis and highlight the fundamental effects of cations on chromosome condensation.