PERMANENT GENETIC RESOURCES: Development of microsatellite markers for two nonviviparous mangrove species, Acanthus ilicifolius and Lumnitzera racemosa.

Eight and nine of microsatellite loci were isolated from two nonviviparous mangrove species, Acanthus ilicifolius and Lumnitzera racemosa, respectively. The number of alleles per locus ranged from two to eight in A. ilicifolius and two to nine in L. racemosa. The observed heterozygosities ranged from 0.200 to 0.875 in A. ilicifolius and from 0.025 to 0.350 in L. racemosa. These loci would be effective for analysing genetic diversity and population genetic structure of these two mangrove species.

Outcrossing and paternity analysis of Pinus densiflora (Japanese red pine) by microsatellite polymorphism.

This study employed microsatellite loci to analyse outcrossing rate and pollen dispersal in Japanese red pine (Pinus densiflora) in an isolated stand. The average offspring outcrossing rate for 29 cones was 0.955. Significant differences in outcrossing rates between offspring groups on individual branches that extended in different directions at different heights were not detected. Male parents of 874 offspring collected from the maternal tree were assessed by exclusion using polymorphisms at three microsatellite loci. Paternity analysis indicated that at least 31% of the offspring were fertilized by pollen from trees outside the stand. The average distance of pollen migration within the study stand was 68 m, with a maximum value of 325 m. There was excess mating with nearby P. densiflora trees, of which only a few were predominant pollen donors. In addition, a weakly directional bias in P. densiflora pollination was also detected in the study stand, suggesting that female strobili on a branch of the maternal tree were more easily fertilized by pollen from trees in that direction.

Polymorphism of simple sequence repeats reveals gene flow within and between ectomycorrhizal Suillus grevillei populations.

• Gene flow within and between two populations of the ectomycorrhizal fungus Suillus grevillei is shown here using co-dominant simple sequence repeat (SSR) markers. • Co-dominant SSR markers were developed for S. grevillei. Distribution and frequency of alleles at the three codominant SSR markers were analysed within two S. grevillei populations in two Larix Kaempteri stands located 700 m apart. • Among eight SSR loci isolated from S. grevillei, five loci (designated SG1-5) were polymorphic and SG1-3 were co-dominant. Genets (73) previously identified by inter-simple sequence repeat markers at the Larix stands were divided by the combination of SG1-3 into 22 genotypes. Most of the SSR genotypes were spatially clustered, indicating that the dispersal distance of S. grevillei spores was relatively short. • There was no conspicuous genetic differentiation within or between the two S. grevillei populations, indicating extensive gene flow. The spread of alleles within or between populations might be by repeats of short-distance spore dispersal rather than long-distance spore dispersal.

Mechanism for formation of the secondary wall thickening in tracheary elements: Microtubules and microfibrils of tracheary elements of Pisum sativum L. and Commelina communis L. and the effects of amiprophosmethyl.

Arrangements of microfibrils (MFs) and microtubules (MTs) were examined in tracheary elements (TEs) of Pisum sativum L. and Commelina communis L. by production of replicas of cryo-sections, and by immunofluorescence microscopy, respectively. The secondary wall thickenings of TEs of Pisum and Commelina roots have pitted and latticed patterns, respectively. Most MFs in the pitted thickening of Pisum TEs retain a parallel alignment as they pass around the periphery of pits. However, some groups of MFs grow into the pits but then terminate at the edge of the thickening, indicating that cellulose-synthase complexes are inactivated in the plasma membrane under the pit. Microtubules of TEs of both Pisum and Commelina are localized under the secondary thickening and few MTs are detected in the areas between wall thickenings. In the presence of the MT-disrupting agent, amiprophosmethyl, cellulose and hemicellulose, which is specific to secondary thickening, are deposited in deformed patterns in TEs of Pisum roots, Pisum epicotyls and Commelina roots. This indicates that the localized deposition of hemicellulose as well as cellulose involves MTs. The deformed, but heterogeneous pattern of secondary thickening is still visible, indicating that MTs are involved in determining and maintaining the regular patterns of the secondary thickening but not the spatial heterogeneous pattern of the wall deposition. A working hypothesis for the formation of the secondary thickening is proposed.

Arrangement of cortical microtubules in the shoot apex of Vinca major L. : Observations by immunofluorescence microscopy.

The arrangements of cortical microtubules (MTs) and of cellulose microfibrils in the median longitudinal cryosections of the vegetative shoot apex of Vinca major L., were examined by immunofluorescence microscopy and polarizing microscopy, respectively. The arrangement of MTs was different in the various regions of the apex: the MTs tended to be arranged anticlinally in tunica cells, randomly in corpus cells, and transversely in cells of the rib meristem. However, in the inner layers of the tunica in the flank region of the apex, cells with periclinal, oblique or random arrangements of MTs were also observed. In leaf primordia, MTs were arranged anticlinally in cells of the superficial layers and almost randomly in the inner cells. Polarizing microscopy of cell walls showed that the arrangement of cellulose microfibrils was anticlinal in tunica cells, random in corpus cells, and transverse in cells of the rib meristem; thus, the patterns of arrangement of microfibrils were the same as those of MTs in the respective regions. These results indicate that the different patterns of arrangement of MTs and microfibrils result in specific patterns of expansion in the three regions. These differences may be necessary to maintain the organization of the tissues in the shoot apex.

Re-formation of microtubules in Closterium ehrenbergii Meneghini after cold-induced depolymerization.

Immunofluorescence microscopy was used to examine the re-formation of microtubules (MT), after cold-induced depolymerization, in Closterium ehrenbergii. The C. ehrenbergii cells undergo cell division followed by semicell expansion in the dark period of daily light-dark cycles. Five types of MTs, namely the MT ring, hair-like MTs around the nuclei, spindle MTs, radially arranged MTs and transverse wall MTs, appeared and disappeared sequentially during and following cell division. The wall MTs were distributed transversely only in the expanding new semicells. When cells were chilled in ice water, wall MTs in expanding cells were fragmented, and then disappeared as did the other types of MTs, within 5 min. When cells were warmed at 20°C after 2 h chilling, wall MTs and the other types of MTs re-formed. At the early stage of wall-MT re-formation in expanding cells, small, star-like MTs were formed, and then randomly oriented MTs developed in both the expanding new and the old semicells. The MT ring was also re-formed at the boundary between the new and old semicells. There were no obvious MT-organizing centers in the random arrangement. As time passed, the randomly oriented wall MTs in the old semicells disappeared and those in the expanding new semicells gradually assumed a transverse orientation. These results indicate that wall MTs can be rearranged transversely after they have been re-formed and that nucleation of wall MTs is separable from the mechanism for ordering them.

Immunofluorescence microscopy of microtubule arrangement in Closterium acerosum (Schrank) Ehrenberg.

The microtubule (MT) arrangement in Closterium acerosum cells was observed by indirect immunofluorescence microscopy both during and following cell division, and during cell expansion without cell division. (During the division period, some cells of this alga divide whereas other cells expand in their middle region without division.) Before septum formation, all cells had a ring-like MT bundle (MT ring) in their middle. Both septum formation and expansion without cell division occurred at the position of this ring. During the periods of division, short, hair-like MTs appeared around the nucleus in some of the cells, in addition to the MT ring. In dividing cells, spindle MTs appeared as the chromosomes were condensed. During the early stages of expansion of the semicells, after cell division, the spindle MTs assumed a radial arrangement, moved, and settled in a position between the daughter chloroplasts. These MTs disappeared about 1.5 h after septum formation. As the new semicells were growing, wall MTs appeared, arranged transversely along the expanding wall. These transverse MTs disappeared gradually 4-5 h after septum formation, and only an MT ring remained near the boundary between the new and old semicells. The MT ring was present until the next cell division or expansion without cell division. During the latter course of development, transverse wall MTs were present only at the band-like expanding region. At the earlier stage of expansion without cell division, the short, hair-like MTs remained around the nucleus, but as time passed, both the hair-like MTs and, somewhat later, the transverse ones disappeared and only the MT rings remained. The remaining MT ring was not always positioned at the boundary between the expanding and the old cell region. The temporal relationships between the changes in MT arrangement, and the orientation and localization of cellulose-microfibril deposition are discussed.

Temporal and spatial changes of cellulose synthesis inClosterium acerosum (Schrank) Ehrenberg during cell growth.

The amount and distribution of wall microfibril synthesis were investigated in the cell-division cycle ofClosterium acerosum. Electron-microscopic examination and a methylation analysis of alkali-extracted wall fragments showed that alkali-extracted wall was mainly composed of microfibrils and that the microfibrils ofC. acerosum were 4-linked glucans, i.e., cellulose. Cellulose synthesis was measured as incorporation of(14)C, fed to cells as NaHCO3, into extracted wall fragments. Extensive cellulose synthesis was coincident with septum formation, continued for more than 6 h and then ceased. It was found by microautoradiography that cellulose synthesis after cell division was essentially restricted to the expanding new semicells. Such a restricted distribution of cellulose synthesis was maintained for more than 6 h after septum formation, i.e., for more than 2 h after the cessation of expansion; afterwards, cellulose synthesis in some, but not all, cells became extended to the old semicells, and then ceased. Considerable cellulose synthesis also took place in the band-like expanding part of non-divided cells, indicating that cell division was not necessarily required for the induction of cellulose synthesis and the latter was coupled with cell expansion. Extension of cellulose synthesis to old semicells was brought about in divided cells by treatment with 3 mM colchicine, 28 µM vinblastine, 50 µM isopropyl-N-phenylcarbamate or 1 µM isopropyl-N(3-chlorophenyl)carbamate, indicating that microtubules are involved in the limitation of cellulose synthesis to the new semicells.

The change of pattern in microfibril arrangement on the inner surface of the cell wall of Closterium acerosum during cell growth.

Closterium acerosum (Schrank) Ehrenberg cells cultured on cycles of 16 h light and 8 h dark, undergo cell division synchronously in the dark period. After cell division, the symmetry of the daughter semicells is restored by controlled expansion, the time required for this restoration, 3.5-4 h, being relatively constant. The restoration of the symmetry is achieved by highly oriented surface expansion occurring along the entire length of the new semicell. During early semicell expansion, for about 2.5 h, microfibrils are deposited parallel to one another and transversely to the cell axis on the inner surface of the new wall. Wall microtubules running parallel to the transversely oriented microfibrils are observed during this period. About 2.5 h after septum formation, preceding the cessation of cell elongation, bundles of 7-11 microfibrils running in various directions begin to overlay the parallel-arranged microfibrils already deposited. In the fully elongated cells, no wall microtubules are observed.

Effects of colchicine on cell shape and on microfibril arrangement in the cell wall of Closterium acerosum.

Cell morphogenesis in Closterium acerosum (Schrank) Ehrenberg was greatly influenced by colchicine. Addition of colchicine to the medium led to production of "tadpole-shaped" cells, by decreasing the length and increasing the thickness of the new semicells. Transversely oriented wall microtubules and microfibrils, characteristic of normally elongating semicells, were not observed in colchicine-treated semicells, randomly oriented microfibrils being present instead. About 3.5 h after septum formation, the randomly oriented microfibrils began to be overlaid by bundles of microfibrils as seen in normal semicells at the later stage of elongation. When colchicine treatment was terminated 1 h after septum formation, cell elongation was partially restored and microfibrils were deposited parallel to each other and transversely to the cell axis, indicating that the effect of colchicine on microfibril arrangement in growing semicells is reversible.