1,8-Cineole inhibits root growth and DNA synthesis in the root apical meristem ofBrassica campestris L.

1,8-cineole is a volatile growth inhibitor produced bySalvia species. We examined the effect of this allelopathic compound on the growth of other plants usingBrassica campestris as the test plant. Cineole inhibited germination and growth ofB. campestris in a dosedependent manner. WhenB. campestris was grown for 5 days with various concentrations of cineole, the length of the roots was found to be shorter as the concentration of cineole increased, whereas the length of the hypocotyl remained constant up to 400 μM cineole, indicating that cineole specifically inhibited growth of the root. The mitotic index in the root apical meristem of 3-day-old seedlings decreased from 5.6% to 1.6% when exposed to 400 μM cineole, showing that cineole inhibits the proliferation of root cells. We then examined the effect of cineole on DNA synthesis by indirect immunofluorescence microscopy using antibody raised against 5-bromo-2′-deoxyuridine (BrdU, an analogue of thymidine) in thin sections of samples embedded in Technovit 7100 resin. The results clearly demonstrated that cineole inhibits DNA synthesis in both cell nuclei and organelles in root apical meristem, suggesting that cineole may interfere with the growth of other plant species by inhibiting DNA synthesis in the root apical meristem.     

Geranylgeranyl-pyrophosphate (GGPP) synthase is down-regulated during differentiation of osteoblastic cell line MC3T3-E1

Isoprenylation of geranylgeranyl-pyrophosphate (GGPP) is critical for activation of small GTPases. We examined the roles of GGPP synthase (GGPPS) during the differentiation induced by the cell-to-cell contact in osteoblastic cell line MC3T3-E1 cells. We found that (1) both mRNA and protein expression of GGPPS was reduced with decrement of its activity during the differentiation, (2) GGOH, which is converted to GGPP in the cells, inhibited differentiation. These results suggest that the decrement of GGPP is critical for the cell-to-cell contact-induced differentiation, in which the down-regulation of GGPPS might be involved.     

Complete sequence and analysis of the plastid genome of the unicellular red alga Cyanidioschyzon merolae.

The complete nucleotide sequence of the plastid genome of the unicellular primitive red alga Cyanidioschyzon merolae 10D (Cyanidiophyceae) was determined. The genome is a circular DNA composed of 149,987 bp with no inverted repeats. The G + C content of this plastid genome is 37.6%. The C. merolae plastid genome contains 243 genes, which are distributed on both strands and consist of 36 RNA genes (3 rRNAs, 31 tRNAs, tmRNA, and a ribonuclease P RNA component) and 207 protein genes, including unidentified open reading frames. The striking feature of this genome is the high degree of gene compaction; it has very short intergenic distances (approximately 40% of the protein genes were overlapped) and no genes have introns. This genome encodes several genes that are rarely found in other plastid genomes. A gene encoding a subunit of sulfate transporter (cysW) is the first to be identified in a plastid genome. The cysT and cysW genes are located in the C. merolae plastid genome in series, and they probably function together with other nuclear-encoded components of the sulfate transport system. Our phylogenetic results suggest that the Cyanidiophyceae, including C. merolae, are a basal clade within the red lineage plastids.     

SYNCHRONIZATION OF CHLOROPLAST DIVISION IN THE ULTRAMICROALGA CYANIDIOSCHYZON MEROLAE (RHODOPHYTA) BY TREATMENT WITH LIGHT AND APHIDICOLIN

A system of highly synchronized chloroplast divisions was developed in the unicellular red alga Cyanidioschyzon merolae De Luca, Taddei, & Varano. Chloroplast divisions were examined by epifluorescence microscopy following treatments with light and inhibitors. When the cells during stationary phase were transferred into a new medium under a 12:12 h LD cycle, chloroplasts, mitochondria, and cell nuclei divided synchronously in that order soon after the initiation of dark periods. More than 40% of the cells contained dividing chloroplasts. To obtain a system of highly synchronized cell division and chloroplast division, the cells synchronized by a 12:12 h LD cycle were treated with various inhibitors. Nocodazole and propyzamide did not affect cell and organelle divisions, whereas aphidicolin markedly inhibited cell-nuclear divisions and cytokinesis and induced a delay in chloroplast division. More than 80% of the cells contained dividing chloroplasts when cells synchronized by light were treated with aphidicolin for 12 h. This synchronized system will be useful for studies of the molecular and cellular mechanisms of organelle divisions .     

Characterization of clofibrate-induced retrograde Golgi membrane movement to the endoplasmic reticulum: clofibrate distinguishes the Golgi from the trans Golgi network

Clofibrate-induced retrograde Golgi membrane movement was blocked or retarded when NRK cells were treated with sodium azide/2-deoxyglucose, nocodazole, taxol, and destruxin B, indicating that it depends on energy, and the dynamic state of microtubules, and being acidic or vacuolar-type ATPase function. PDMP and phospholipase A2 inhibitors also blocked it. These characteristics are similar to those of brefeldin A (BFA) and nordihydroguaiaretic acid (NDGA), inducers of retrograde Golgi membrane movement. However, clofibrate was distinguished from BFA in that BFA action was insensitive to phospholipase A2 inhibitors and from NDGA in that NDGA stabilized microtubules against nocodazole and its action was almost insensitive to taxol. The trans Golgi network (TGN) was resistant to clofibrate, while BFA and NDGA dispersed it. To our knowledge, clofibrate is the first drug to show such different effects on the Golgi and TGN and, therefore, is expected to be a useful tool to distinguish their architecture and/or membrane dynamics.     

Nuclease C Polymorphism of Calcium-Dependent Nucleases in Chlamydomonas reinhardtii

DNases were extracted from cells of Chlamydomonas reinhardtii.Their polymorphism and metal ion requirements were investigated.Most of the nucleases from this organism required Ca²⁺ for fullactivation; therefore, the name nuclease C has been given tothem. Zn²⁺ and Mn²⁺ restored activation, but their respectivepotencies were 1/8 and 1/32 that of Ca²⁺. An in situ nucleaseassay revealed that there are at least 6 species of nucleaseC. The molecular weights of the components were 26,000 (C1),25,000 (C2), 22,000 (C5), 21,000 (C6), 18,000 (C3) and 17,000(C4) by SDS PAGE. Ca²⁺-dependent nuclease activity was slightlyhigher in the female gamete than in the male gamete. There wasno marked change in the apparent nuclease activity during thefirst 3 h after mating. An in situ assay, however, showed thatnuclease C6 and C4 are present in smaller amounts in the malegamete in comparison to the female gamete, and that the contentsor activities of nuclease C5 and C6 diminish during the first30–60 min after mating. This evidence is discussed interms of the possible participation of nuclease C in the maternalinheritance of chloroplast genes in this organism. (Received October 8, 1984; Accepted January 21, 1985)     

Constraining OCT with Knowledge of Device Design Enables High Accuracy Hemodynamic Assessment of Endovascular Implants

Background

Stacking cross-sectional intravascular images permits three-dimensional rendering of endovascular implants, yet introduces between-frame uncertainties that limit characterization of device placement and the hemodynamic microenvironment. In a porcine coronary stent model, we demonstrate enhanced OCT reconstruction with preservation of between-frame features through fusion with angiography and a priori knowledge of stent design.

Methods and Results

Strut positions were extracted from sequential OCT frames. Reconstruction with standard interpolation generated discontinuous stent structures. By computationally constraining interpolation to known stent skeletons fitted to 3D ‘clouds’ of OCT-Angio-derived struts, implant anatomy was resolved, accurately rendering features from implant diameter and curvature (n = 1 vessels, r² = 0.91, 0.90, respectively) to individual strut-wall configurations (average displacement error ~15 μm). This framework facilitated hemodynamic simulation (n = 1 vessel), showing the critical importance of accurate anatomic rendering in characterizing both quantitative and basic qualitative flow patterns. Discontinuities with standard approaches systematically introduced noise and bias, poorly capturing regional flow effects. In contrast, the enhanced method preserved multi-scale (local strut to regional stent) flow interactions, demonstrating the impact of regional contexts in defining the hemodynamic consequence of local deployment errors.

Conclusion

Fusion of planar angiography and knowledge of device design permits enhanced OCT image analysis of in situ tissue-device interactions. Given emerging interests in simulation-derived hemodynamic assessment as surrogate measures of biological risk, such fused modalities offer a new window into patient-specific implant environments.     

Studies on the development and three-dimensional reconstruction of giant mitochondria and their nuclei in egg cells ofPelargonium zonale Ait.

Summary The preferential development of giant mitochondria and their nuclei (nucleoids) in the egg cells ofPelargonium zonale Ait. during megasporogenesis and megagametogenesis was examined by fluorescence microscopy, after Technovit embedding and 4,6-diamidino-2-phenylindole (DAPI) staining, fluorimetry for DNA content, using a video-intensified microscope photon-counting system (VIMPICS), and by three-dimensional reconstruction of mitochondrial nuclei (mt-nuclei). Reproductive cells during the megaspore mother cell, meiosis, tetrad, and functioning megaspore stages contained many small mitochondria with characteristic, uniformly DAPI-stained mt-nuclei about 0.3 m in diameter, containing a small amount of DNA (0.3 Mbp). During formation of the 2-, 4-, and 8-nucleate embryo sac, mt-nuclei did not markedly change in shape or DNA content. When the embryo sac formed and differentiation of each cell began, mitochondria and their nuclei in the egg cell took on a small ring or string-like shape. Accompanying the maturation of the embryo sac, they underwent progressive enlargement and gradually altered to long thick strings, or stacks of concentric or half concentric rings. By flower opening, they have developed to an extremely large size. One of these stacks of mt-nuclei was reconstructed in three dimensions; each ring in the stack was cup- or plate-shaped; 5 to 10 rings made up the stack, though each remained discontinuous from the others. From serial sections, we counted 44 mitochondria in one egg cell. Fluorometry using VIMPICS revealed that DNA amount within the stacked mitochondrion increased to 40 times that of the megaspore mother cell stage; a single stack of mitochondria contained 340–1700 Mbp DNA; which means that one egg cell contains at least 15000 Mbp mt-DNA, a value greater than the cell-nuclear DNA content.