The Orientation and Localization of Cortical Microtubules in Differentiating Conifer Tracheids during Cell Expansion

Arrays of cortical microtubules (MTs) on radial walls in differentiatingtracheids of Taxus cuspidata were randomly oriented when primarywalls formed. The orientation of MTs changed progressively fromlongitudinal to transverse as cells expanded. During formationof primary walls, MTs in differentiating tracheids disappearedlocally at sites of future intertracheal bordered pits. In furtherdifferentiated tracheids, circular bands of MTs were observedaround the edges of developing bordered pits. (Received July 17, 1996; Accepted November 11, 1996)     

Arrangement of Cellulose Microfibrils in Walls of Elongating Parenchyma Cells

The arrangement of cellulose microfibrils in walls of elongating parenchyma cells of Avena coleoptiles, onion roots, and celery petioles was studied in polarizing and electron microscopes by examining whole cell walls and sections. Walls of these cells consist firstly of regions containing the primary pit fields and composed of microfibrils oriented predominantly transversely. The transverse microfibrils show a progressive disorientation from the inside to the outside of the wall which is consistent with the multinet model of wall growth. Between the pit-field regions and running the length of the cells are ribs composed of longitudinally oriented microfibrils. Two types of rib have been found at all stages of cell elongation. In some regions, the wall appears to consist entirely of longitudinal microfibrils so that the rib forms an integral part of the wall. At the edges of such ribs the microfibrils can be seen to change direction from longitudinal in the rib to transverse in the pit-field region. Often, however, the rib appears to consist of an extra separate layer of longitudinal microfibrils outside a continuous wall of transverse microfibrils. These ribs are quite distinct from secondary wall, which consists of longitudinal microfibrils deposited within the primary wall after elongation has ceased. It is evident that the arrangement of cellulose microfibrils in a primary wall can be complex and is probably an expression of specific cellular differentiation.     

Changes in Cell Wall Architecture of Differentiating Tracheids of Pinus thunbergii during Lignification

The cell wall architecture, before and after lignification,of differentiating tracheids in Pinus thunbergii has been examinedusing a rapid-freeze deep-etching technique combined with transmissionelectron microscopy. Replicas of cells from the cambial zoneshowed that the unlignified primary cell wall was highly porouswith microfibrils extensively interconnected by crosslinks.The unlignified secondary cell wall has unidirectional microfibrils,more or less associated in bundles, forming a wavy pattern aroundpores of characteristic slit-like shape with narrowing ends.As the lignification progresses, the cell wall structure becomesdense, with no detectable pores. Delignification of wood samplesleads to the reappearance of crosslinks, individual microfibrilsand pores in the secondary cell wall, although in a somewhataltered shape. In addition, cellulose-synthesizing enzyme complexes(rosettes) have for the first time been detected on the plasmamembrane of differentiating xylem cells of softwood. (Received August 28, 1998; Accepted March 10, 1999)     

Reorientation of Microfibrils and Microtubules at the Outer Epidermal Wall of Maize Coleoptiles During Auxin-Mediated Growth

Auxin-mediated elongation growth of isolated subapical coleoptile segments of maize (Zea mays L.) is controlled by the extensibility of the outer cell wall of the outer epidermis (Kutschera et al., 1987). Here we investigate the hypothesis that auxin controls the extensibility of this wall by changing the orientation of newly deposited microfibrils through a corresponding change in the orientation of cortical microtubules. On the basis of electron micrographs it is shown that cessation of growth after removal of the endogenous source of auxin is correlated with a relative increase of longitudinally orientated microfibrils and microtubules at the inner wall surface. Conversely, reinduction of growth by exogenous auxin is correlated with a relative increase of transversely orientated microfibrils and microtubules at the inner wall surface. These changes can be detected 30–60 min after the removal and addition of auxin, respectively. The functional significance of directional changes of newly desposited wall microfibrils for the control of elongation growth is discussed.     

Changes in Microtubules in Onion Leaf Sheath Cells during Bulb Development

Cortical microtubules are oriented transversely to the cellaxis in leaf sheath cells of onion plants (Allium cepa L. cv.Osaka-Okute) that have not started bulb formation. As the bulbdevelops and the leaf sheath cells swell, the microtubules becomedisoriented and scattered and finally disappear. The microtubuleinhibitors colchicine and cremart [O-ethyl O-(3-methyl-6-nitrophenyl)N-sec-butylphosphorothioamidate]cause swelling of leaf sheath cells and make the basal partof the plant bulbous. The cortical microtubules may have animportant role in regulating bulb development in onion plants. (Received August 21, 1982; Accepted December 6, 1982)     

Effects of Gibberellin on the Arrangement and the Cold Stability of Cortical Microtubules in Epidermal Cells of Pea Internodes

Longitudinal microtubules are predominant in epidermal cellsof the 3rd internodes of dwarf pea (Pisum sativum L. cv. LittleMarvel) seedlings. In more than 50% of the cells, cortical microtubulesare running parallel to the cell axis. GA₃ promotes elongation of the internodes and gives rise toa predominance of transverse microtubules. In more than 60%of the GA₃-treatd cells, cortical microtubules are running transverseto the cell axis. Longitudinal microtubules in the GA₃-untreated cells are resistantto low-temperature treatment, but transverse microtubules inthe GA₃-treated cells are sensitive to it. Longitudinal microtubulesare present in GA₃-treated epidermal cells with low frequency.They are resistant to low-temperature treatment. Longitudinal, oblique and transverse microtubules are presentwith almost the same frequency in epidermal cells of the 3rdinternodes of tall pea (cv. Early Alaska) seedlings. GA₃ promoteselongation of the internodes also in tall pea seedlings, butit does not alter the direction of cortical microtubules sodistinctly as it does in dwarf pea seedlings. As in dwarf pea seedlings, longitudinal microtubules are resistantto low-temperature treatment, and transverse microtubules aresensitive to it in tall pea seedlings. (Received September 19, 1986; Accepted December 26, 1986)     

Effects of Root Excision on Swelling of Leaf Sheath Cells and on the Arrangement of Cortical Microtubules in Onion Seedlings

Unlike abundantly-leafed mature plants, 2- to 3-leafed youngonion seedlings (Allium cepa L. cv. Senshu-Chuko) showed noswelling of leaf sheaths even when they were kept under long-dayconditions. When their roots were excised, however, the seedlingsshowed sign of swelling. Before swelling became evident, changesin the arrangement of cortical microtubules occurred in leafsheath cells. The microtubules, which were oriented transverselyto the cell axis in unexcised seedlings, were oriented longitudinallyor obliquely in excised seedlings. Such effects of root excisionwere observed only in seedlings grown under long-day conditions,but not under short-day conditions. (Received July 14, 1984; Accepted September 26, 1984)     

微管骨架在苔藓植物适应干旱胁迫应答中的功能研究

植物体通过一系列生理生化反应的改变来适应干旱胁迫。对干旱/复水及秋水仙素处理后再干旱/复水的仙鹤藓(Atrichum undulatum)原丝体细胞中微管骨架的动态变化进行了研究,发现干旱处理后细胞内微管骨架从有规律排列的较细的丝状形式转换为无规律排列的较粗的微管束;复水后微管骨架的结构和分布与对照细胞中无明显区别;秋水仙素处理后再干旱/复水的细胞中,微管骨架呈分散的棒状或点状分布,而且原丝体丧失了干旱胁迫后正常复水的能力,进而导致细胞不能恢复正常的生理活动。因此认为,微管骨架在仙鹤藓原丝体适应干旱逆境的过程中起着重要作用。     

Metabolic and Energetic Changes During Apoptosis in Neural Cells

Abstract: Changes in cellular energetic and metabolic parameters were analyzed at several time points during apoptosis of differentiated PC12 cells following removal of nerve growth factor (NGF). As approximately 60% of the population died during the period of study (24 h), most of the measured metabolic indicators declined over time. However, this decline paralleled the overall decrease in cellular viability, suggesting that, in individual cells, a compromised metabolic state occurred suddenly and very late in the death process. For example, when expressed as a function of viable cells, protein and RNA synthesis did not decrease until 24 h. Glucose utilization in live cells was never significantly reduced relative to control levels; lactate production decreased slightly within 4–8 h after NGF removal, but eventually rebounded to 122% of control levels by 24 h. ATP levels dropped 27% in an early predeath period, but then returned to near control levels (on a per-live-cell basis) once the population actively began to die. The ATP/ADP ratio remained at least 84% of control throughout. UTP/UDP and GTP/GDP ratios did not change significantly at any time point.     

Arrangement of Cortical Microtubules in Avena Coleoptiles and Mesocotyls and Pisum Epicotyls

Cortical microtubules (MTs) in coleoptiles and mesocotyls ofAvena sativa and epicotyls of Pisum sativum were examined byimmunofluorescence. In elongating Avena coleoptiles whose elongationis less localized, the orientations of cortical MTs of parenchymaand adaxial epidermal cells, and abaxial epidermal cells aretransverse, and oblique or longitudinal, respectively, and doesnot differ between the upper, middle and lower parts. The transverseMTs in parenchyma and adaxial epidermal cells turns to obliqueor longitudinal ones after elongation stops. The obliquity ofMTs in abaxial epidermal cells also tends to become steeperas elongation comes to a stop. In Avena mesocotyls and Pisumepicotyls whose elongation is localized, the orientation ofcortical MTs of cortical cells in the elongating region is relativelytransverse. The epidermis has intermingling cells of transverseor oblique MTs. In the non-elongating region, MT orientationbecomes steeper both in the cortex and epidermis. The present results indicate that whatever the degree of localizationof the elongation, the obliquity of MTs in these organs is steeperin epidermal than in inner tissue cells and becomes steeperas elongation stops in both tissues. (Received October 26, 1987; Accepted April 19, 1988)     

Changes in the Pattern of Organization of Microtubules During Microspore Formation in Rice (Oryza sativa L.)

Changes in the pattern of organization of microtubules in the developing microspore of rice ( Oryza sativa L. ) have been followed using immunofluorescence confocal microscopy. At the microsporocyte stage of development the cell possessed a network of highly branched and thickened microtubule bundles. In the central cytoplasm numerous bundles mn circumferentially around the nucleus. From the circumferentially distributed microtubule bundle network some microtubule bundles radiated towards the conical region of the cell. The microsporocyte after Meiosis Ⅰ became a dyad. In the dyad cell microtubule bundles emanated radially from the nucleus. In the cortex of the dyad cell some of the microtubule bundles became randomly oriented. The dyad then underwent Meiosis Ⅱ to become tetrad. Microtubule bundles in the tetrad cell radiated from the nucleus. No randomly oriented microtubule bundles were present in the cortical region of the tetrad cell. Mter- wards the four cells that made up the tetrad dissociated from each other and each became a microspore. At the early stage of the microspore development most of the microtubule bundles were randomly distributed. Later, some of the microtubules converged towards a bud-like cytoplasmic protrusion. This bud-like protrusion later developed into a germ pore (or pollen pore). At the late stage of microspore formation, microtubule bundles became thinner and reticulately oriented to form a tightly knitted network.     

The Dynamics of Microtubules in Cultured Cells

The behavior of microtubules in cultured cells in a cooled matrix after the microinjection of fluorescent tubulin was studied using a frame recording with a digital camcorder. In the cell lamella, the positive ends of individual microtubules extend and shorten at random. The histograms of rate distribution have an almost normal distribution with a mode close to 0. The maximum rate of lengthening and shortening reaches 30 and 50 m/min, respectively. The positive ends of microtubules in PtK cells were in an equilibrium state, while in murine embryonic fibroblasts and Vero cells, they were usually displaced to the cell edge. Free microtubules were present in the cells of all three cultures. In the epithelial cells, they were numerous and relatively stable, while in the fibroblasts, they occurred rarely and were depolymerized at the proximal end. Free microtubules in PtK cells appeared mostly due to spontaneous assembly in the cytoplasm (not in the relationship with the preexisting microtubules) and, more rarely, due to breakage of long microtubules. Separation of microtubules from the centrosome is a very rare event. Unlike positive ends that were characterized by dynamic instability, negative ends were stable and were sometimes depolymerized. When long microtubules were broken, new negative ends were formed that were, as a rule, stable, while in the lamella of fibroblasts (in murine embryonic fibroblasts and Vero cells), new negative ends were immediately depolymerized: free microtubules existed in these cells no more than 1–2 min. A diffusion model has been proposed where the behavior of microtubule ends is considered as unidimensional diffusion. The coefficient of diffusion of positive ends in the epithelial cells is several times less than in the fibroblasts, thus suggesting a higher rate of tubulin metabolism in the fibroblasts as compared to the epithelium. The results obtained indicate that for the exchange of long microtubules, the dynamic instability is not sufficient. In the fibroblasts, their exchange takes place mostly at the expense of depolymerization of the liberating negative ends, which agrees with the previously proposed conveyer hypothesis of microtubule assembly on the centrosome.     

Re-Formation and Ordering of Wall Microtubules in Spirogyra Cells

Processes of re-formation and ordering of wall microtubules(wall MTs) in Spirogyra cells were examined using immunofluorescencemicroscopy. Wall MTs were usually arranged nearly transverselyto the cell axis at all stages of the cell cycle. Two-hour treatmentwith amiprophosmethyl (APM) completely disrupted wall MTs, butremoval of the APM led to re-formation of randomly orientedwall MTs at many sites over the cell. The re-formed wall MTsgradually assumed a transversely oriented order without anyspecific MT-ordering centers, indicating that initiation andordering of MTs are different processes. Removal of APM after24-h treatment caused reformation of randomly oriented wallMTs, followed in some cells by gradual ordering to obliquelyoriented instead of transversely oriented wall MTs. This orderingoccurred with the same sign of obliquity as that of chloroplastspirals. When cells were centrifuged along the cell axis, chloroplastssedimented on the cross wall, but the transverse wall MTs didnot. In centrifuged cells, wall MTs were re-formed and orderedtransversely after MT depolymerization by APM for 2 h as innon-centrifuged cells. When cells were centrifuged for the final30 min in 2-h treatment with APM, wall MTs that re-formed afterremoval of APM were sometimes ordered transversely over thatpart of the cell which contained sedimented chloroplasts, butremained at random over the other part, as though the MT-orderingfactor was sedimented by the centrifugation. The mechanism determiningthe wall MT orientation is discussed. (Received January 12, 1987; Accepted April 27, 1987)     

Terpenoid Biosynthesis and Specialized Vascular Cells of Conifer Defense

Defense-related terpenoid biosynthesis in conifers is a dynamic process closely associated with specialized anatomical structures that allows conifers to cope with attack from many potential pests and pathogens. The constitutive and inducible terpenoid defense of conifers involves several hundred different monoterpenes, sesquiterpenes and diterpenes. Changing arrays of these many compounds are formed from the general isoprenoid pathway by activities of large gene families for two classes of enzymes, the ter...     

粗茎鳞毛蕨原叶体细胞有丝分裂过程中微管列阵的变化

粗茎鳞毛蕨原叶体细胞有丝分裂过程中微管列阵的变化 何群 尤瑞麟 姆旺戈     

粗茎鳞毛蕨原叶体细胞有丝分裂过程中微管列阵的变化

应用Steedman‘s wax切片法,间接免疫荧光标记技术和激光共聚焦扫描显微镜技术研究了粗茎鳞毛蕨（Dryopteris crassirhizoma Nakai)原叶体大液泡化细胞和分生组织细胞有丝分裂过程中微管列阵的变化。结果显示：应用高浓度的多聚甲醛（8%）可以很好地保持大液泡化细胞的结构和微管的抗原性。结果也显示Steedman‘s wax切片法和间接免疫荧光标记技术的优点;（1）避免在微管标记过程中酶解细胞壁;（2）在乙醇脱水过程中样品中叶绿素的自发荧光被减到最小;（3）能够详细观察到有丝分裂过程中微管骨架的变化。因此,这种方法可以被广泛用来调查简单植物体和复杂植物体中细胞的有丝分裂过程以及发育过程中微管骨架的变化。