Keiju Okano

Microtexture of larval shell of oyster, Crassostrea nippona: a FIB-TEM study.

The initial formation and subsequent development of larval shells in marine bivalve, Crassostrea nippona were investigated using the FIB-TEM technique. Fourteen hours after fertilization (the trochophore stage), larvae form an incipient shell of 100-150nm thick with a columnar contrast. Selected-area electron diffraction analysis showed a single-crystal aragonite pattern with the c-axis perpendicular to the shell surface. Plan-view TEM analysis suggested that the shell contains high density of {110} twins, which are the origin of the columnar contrast in the cross-sectional images. 72h after fertilization (the veliger stage), the shell grows up to 1.2-1.4mum thick accompanying an additional granular layer between the preexisting layer and embryo to form a distinctive two-layer structure. The granular layer is also composed of aragonite crystals sharing their c-axes perpendicular to the shell surface, but the crystals are arranged with a flexible rotation around the c-axes and not restricted solely to the {110} twin relation. No evidence to suggest the existence of amorphous calcium carbonate (ACC) was found through the observation. The well-regulated crystallographic properties found in the present sample imply initial shell formation probably via a direct deposition of crystalline aragonite.

Metamorphosis in Balanomorphan, Pedunculated, and Parasitic Barnacles: A Video-Based Analysis

Cypris metamorphosis was followed using video microscopy in four species of cirripeds representing the suspension-feeding pedunculated and sessile Thoracica and the parasitic Rhizocephala. Cirripede metamorphosis involves one or more highly complex molts that mark the change from a free cypris larva to an attached suspension feeder (Thoracica) or an endoparasite (Rhizocephala). The cyprids and juveniles are so different in morphology that they are functionally incompatible. The drastic reorganization of the body implicated in the process can therefore only commence after the cyprid has irreversibly cemented itself to a substratum. In both Megabalanus rosa and Lepas, the settled cyprid first passes through a quiescent period of tissue reorganization, in which the body is raised into a position vertical to the substratum. In Lepas, this is followed by extension of the peduncle. In both Lepas and M. rosa, the juvenile must free itself from the cypris cuticle by an active process before it can extend the cirri for suspension feeding. In M. rosa, the juvenile performs intensely pulsating movements that result in shedding of the cypris carapace ∼8 h after settlement. Lepas sp. sheds the cypris cuticle ∼2 days after settlement due to contractile movements of the peduncle. In Lepas anserifera, the juvenile actively breaks through the cypris carapace, which can thereafter remain for several days without impeding cirral feeding. Formation of the shell plates begins after 1-2 days under the cyprid carapace in Lepas. In M. rosa, the free juvenile retains its very thin cuticle and flexible shape for some time, and shell plates do not appear until sometime after shedding of the cypris cuticles. In Sacculina carcini, the cypris settles at the base of a seta on the host crab and remains quiescent and aligned at an angle of ∼60° to the crab’s cuticle. The metamorphosis involves two molts, resulting in the formation of an elongated kentrogon stage with a hollow injection stylet. Due to the orientation of the cyprid, the stylet points directly towards the base of the crab’s seta. Approximately 60 h after settlement the stylet penetrates down one of the cyprid antennules and into the crab. Almost immediately afterwards the unsegmented vermigon stage, preformed in the kentrogon, passes down through the hollow stylet and into the crab’s hemocoel in a process lasting only 30 s. In S. carcini, the carapace can remain around the metamorphosing individual without impeding the process.

The Coprinopsis cinerea septin Cc.Cdc3 is involved in stipe cell elongation.

We have identified and characterized a Coprinopsis cinerea mutant defective in stipe elongation during fruiting body development. In the wild-type, stipe cells elongate at the maturation stage of fruiting, resulting in very slender cells. In the mutant, the stipe cells fail to elongate, but become rather globular at the maturation stage. We found that the mutant phenotype is rescued by a gene encoding a homolog of Saccharomyces cerevisiae CDC3 septin, Cc.Cdc3. The C. cinerea genome includes 6 septin genes, 5 of which, including Cc.cdc3, are highly transcribed during stipe elongation in the wild type. In the mutant, the level of Cc.cdc3 transcription in the stipe cells remains the same as that in the mycelium, and the level of Cc.cdc10 transcription is approximately 100 times lower than that in the wild-type stipe cells. No increase in transcription of Cc.cdc3 in the mutant may be due to the fact that the Cc.cdc3 gene has a 4-base pair insertion in its promoter and/or that the promoter region is methylated in the mutant. Overexpressed EGFP-Cc.Cdc3 fusion protein rescues the stipe elongation in the transformants, localizes to the cell cortex and assembles into abundant thin filaments in the elongating stipe cells. In contrast, in vegetative hyphae, EGFP-Cc.Cdc3 is localized to the hyphal tips of the apical cells of hyphae. Cellular defects in the mutant, combined with the localization of EGFP-Cc.Cdc3, suggest that septin filaments in the cell cortex provide the localized rigidity to the plasma membrane and allow cells to elongate cylindrically.

Intact structure of EGAM1 homeoproteins and basic amino acid residues in the common homeodomain of EGAM1 and EGAM1C contribute to their nuclear localization in mouse embryonic stem cells

Recently, we identified the structurally related homeoproteins EGAM1, EGAM1N, and EGAM1C in both preimplantation mouse embryos and mouse embryonic stem (ES) cells. These EGAM1 homeoproteins act as positive or negative regulators of differentiation and cell growth in mouse ES cells, such that these proteins are considered transcriptional regulators. In this study, we investigated their nuclear localization and identified the amino acid residues crucial for the nuclear translocation of EGAM1 and EGAM1C. When expressed exogenously in pluripotent ES cells and somatic NIH3T3 cells, all EGAM1 homeoproteins localized to the nucleus. Analysis using the web-based tool PSORTII predicted a potential nuclear localization signal (NLS) motif, RKDLIRSWFITQRHR, in the homeodomain shared by EGAM1 and EGAM1C. The introduction of mutations, such as mutations from K or R, both basic amino acid residues, to A, in this potential NLS resulted in significant impairment of the nuclear localization of both EGAM1 and EGAM1C. In contrast, GFP fusion proteins of all the full-length EGAM1 homeoproteins failed to localize to the nucleus. These results, when taken together, suggest that basic amino acid residues in the common homeodomain of EGAM1 and EGAM1C and the intact structures of the EGAM1 homeoproteins contribute, at least in part, to the nuclear localization of these proteins in mouse ES cells.

Determination of birefringence and slow axis distribution using an interferometric measurement system with liquid crystal phase shifter

It is known that liquid crystal (LC) cells are useful as compact and easy-to-handle phase shifters that are readily coupled into the optics of standard microscope systems. Here, a uniformly aligned molecular LC phase shifter is introduced into a polarization microscope to attain a birefringence imaging system, using the phase-shift interferometric technique. Since the birefringence can be determined accurately only when the optical axis of the sample is parallel or perpendicular to the slow axis (variable axis) of the LC phase shifter, an improved data analysis method is proposed for determining the birefringence independently of the direction; a simple method of determining the slow axis distribution is also demonstrated. Measurements of the birefringence and slow axis distribution properties of a potato starch particle are demonstrated to confirm the novel determination method.

Differential interference contrast imaging using a pair of twisted nematic cells.

Nematic liquid crystal behaves like an optically uniaxial crystal whose optical axis coincides with the direction of molecular orientation. When an electric field is applied, a lateral shear of incident light is induced, depending on the angle of molecular inclination. While this may degrade the image quality for display applications, the precise electrical tunability of the lateral shear distance is desirable for differential interference contrast (DIC) imaging. In this Letter, a pair of twisted nematic (TN) cells is used for DIC imaging instead of the normal DIC prisms, and the unique optical properties of the TN cell are investigated for DIC imaging applications.

Microscopic birefringence imaging by phase-shift interferometry using a liquid crystal phase shifter

It is known that the phase-shift intererometry is promising measurement method for the precise optical test. Liquid crystal (LC) phase shifter is very attractive as an electrically tunable phase sifter for the key component of the test system. We adopt here a bend aligned liquid crystal cell for the fast phase shifting, and mount it on the optical system of polarization microscope. A potential application for precise 2D birefringence measurement system is investigated and as high as a few tenths of a wavelength resolution can be obtained by the simple 4-step phase shifting technique. Obtained image data show the phase profile which corresponds to retardation distribution of the prepared sample, and then it becomes possible to perform quantitative analysis of 2D birefringence distribution in planar sample. Since there is basically a setting angle dependency of the test sample, measurement phase data have information of birefringence sign (positive or negative) and we can distinguish between the direction parallel and perpendicular to the anisotropic axis. We observe tiny marine zooplankton as a weakly anisotropic actual sample, and the birefringence of the muscle can be clearly detected. It is also successfully pick up that the elongated direction of muscles show higher index value.

Identification of Barnacle Shell Proteins by Transcriptome and Proteomic Approaches

In barnacle shell, the calcified shell layer is laid on top of the epicuticle. Here, we report our strategy and some preliminary results on the identification of potential shell proteins of the barnacle Megabalanus rosa. At first, M. rosa proteins from acid-soluble and acid-insoluble shell extracts were subjected to proteomic analysis and searched against M. rosa complete transcriptome. Then using the information that the calcified shell is formed just after the larval-adult molt, juvenile differentially expressed genes against larval stages were screened. Sixty secretory protein sequences were identified as primary candidates of M. rosa shell proteins, among which 37 are novel proteins.

Rice Plant Biomineralization: Electron Microscopic Study on Plant Opals and Exploration of Organic Matrices Involved in Biosilica Formation

Biologically formed amorphous silica (biosilica) is widely found in diatoms, marine sponges, terrestrial plants, and bacteria, some of which have been well characterized. Although rice plants produce large amounts of biosilica (plant opal) in their leaf blades and rice husks, the molecular mechanism of biomineralization is still poorly understood. In the present study, we investigated the fundamental properties of plant opal in leaf blades of the rice plants (Oryza sativa) by scanning electron microscopy (SEM) equipped with energy-dispersive X-ray spectroscopy. The number of fan-shaped plant opal increases in the motor cells (bubble-shaped epidermal cells) during heading time. High-resolution SEM analysis revealed that the plant opals are composed of nanoparticles, as is the case with diatom silica and siliceous spicule of sponge. Organic matrices in biominerals have been considered to control mineralization. Biosilicas in diatom and marine sponge are formed under ambient conditions using organic matrices, unique proteins, and long-chain polyamines. In this study, we report the establishment of purification method of plant opals from rice leaf blades. Finally, we succeeded in extracting organic matrices from the purified plant opal.

Lateral shearing properties of twisted nematic liquid-crystal cell and its potential application to differential interference contrast imaging

A liquid crystal (LC) cell behaves as an optically uniaxial crystal and lateral shear properties can be obtained under considerably low voltage, because an oblique optical axis distribution state appears in the middle voltage level between ON and OFF. In this work, a pair of twisted nematic (TN) LC cells is introduced to the normal polarization microscope system to implement differential interference contrast (DIC) imaging, which is a powerful observation tool for weak phase samples such as a bio cell. DIC imaging is usually obtained using a pair of Nomarski prisms, which are inserted at the back focal plane of the objective and condenser lenses to separate and combine the input image laterally. However, if we use LC cells, DIC images can be easily obtained by just sandwiching the test sample between a pair of LC cells. The lateral shear distance, which influences DIC sensitivity, becomes tunable with fast response speed by using LC cells, although the shear distance is fixed in the normal DIC system. Furthermore, unique lateral shearing properties of the TN cell help in achieving self-compensation of optical retardation, and we can then use the incoherent illumination of a normal microscope system for DIC observation as usual. Here, fundamental lateral shearing properties and the operational mode for DIC imaging are investigated using a pair of TN cells.