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1.
Summary In the apical meristem of the adventitious root ofAllium cepa, all pericycle cells show a marked increase in cross-sectional area between 400 and 800 m behind the tip, this transversal growth ceasing in the 1,200–1,400 m interval. However, different pericycle cell types (opposite xylem, intervening and opposite phloem) show different transversal growth kinetics. Along the meristem, the opposite xylem cells are narrower than both the intervening and opposite phloem cells, and these latter are similar in cross-sectional area. Another relevant difference is in the polarity of the transversal expansion, which in turn gives rise to changes in cell shape. In fact, in apical most portions of the meristem, the opposite phloem cells mainly expand tangentially, while the intervening cells do so radially, and the opposite xylem cells undergo a similar tangential and radial expansion. By contrast, in basal most portions of the meristem, radial expansion continues in the opposite phloem cells when it has ceased in the intervening cells. These latter expand tangentially once again when tangential expansion has ceased in the opposite phloem cells. As a consequence of this transversal growth, the opposite xylem cells, which can initiate lateral root primordia, retain their isodiametric transversal shape along the meristem, whereas the transversal shape of the opposite phloem and intervening cells initially changes from isodiametric to markedly enlarged tangentially (opposite phloem) or radially (intervening), after which both cell types tend to become more rounded in shape.  相似文献   

2.
The length of cells of the pericycle, endodermis and middlecortex not actively involved in lateral root primordia (LRP)development was measured in primary roots of Allium cepa, Pisumsativum and Daucus carota. The presence of two cell populationsin the pericycle was demonstrated in all three species. In Alliumcepa and Pisum sativum, pericyclic cells located opposite xylempoles were significantly shorter than cells lying opposite phloempoles. In both species, LRP originated opposite xylem poles.Our results, furthermore, strongly suggest that in regions ofthe root far from the apical meristem, numerous pericyclic cellsundergo transverse division both previous to and during LRPinitiation, decreasing in mean length throughout this period.In Daucus carota, LRP begin to form in pericyclic cells locatednext to the phloem poles, such cells were significantly shorterthan those opposite xylem poles, even in areas of the primaryroot located close to the root tip. Cells also appear to dividetransversely in regions far from the root tip in this species,leading to a conspicuous drop in the mean length of those cellslocated in portions of the pericycle destined to give rise toLRP. Two different cell populations can also be distinguishedin the endodermis of Allium cepa and Pisum sativum, althoughobservations were less conclusive in Daucus carota. In all threespecies, length of cortical cells was unaffected by their positionopposite xylem or phloem poles Allium cepa, carrot, cell division, cell length, Daucus carota, endodermis, lateral root development, onion, pea, pericycle, Pisum sativum  相似文献   

3.
Mitotic activity does not stop for different meristematic cells of the root apex at the same distance from the initials. The differences are connected with the functional heterogeneity of the apical meristem of the root. The arrangement of vascular bundles,i.e. the alternation of independent xylem and phloem groups, is of major importance. In broad bean roots, the protophloem sieve elements stop dividing first. The centre of the stelei. e. late metaxylem elements stop dividing next. Division in the stele gradually ceases centrifugally, while it ceases centripetally in the peripheral part of the root. The cylindrical region with prolonged cell division includes internal layers of the cortex including endodermis, pericycle and adjoining cells of the stele. Proximally apical meristem is reduced to isolated strands of cells adjacent to the protoxylem poles. Pericycle cells stop dividing last at a distance of approx. 9–10 mm from the initials. The number of the division cycles is limited and is specific for individual cell types. Epidermal and cortical cells divide in broad bean roots transversely approximately seven times, cells of late metaxylem approximately five times. Root apical meristem is an asynchronous cell population with a different duration of the mitotic cycle. We determined local variations in the duration of the mitotic cycle in the apical meristem of broad bean root by means of colchicine-induced polyploidy. The cells of the quiescent centre had the longest mitotic cycle after colchicine treatment. The region of the proper root adjacent to the quiescent centre was mixoploid (2n and 4n). Isolated cells with a long cycle occurred also in the cortex and in the central cylinder. Cells with a division cycle of 18h were found in the root cap, in the epidermis, in the cortex and in the central cylinder. Relatively numerous cells with the shortest division cycle, approx. 12 h, occurred farther of the quiescent centre in the epidermis, in the cortex, in the pericycle, and in adjacent layers of the stele through-out the entire meristematic region. The results derived from the analysis of the apical meristem are discussed in connection with the ontogenesis of different types of cells taking part in the primary structure of the root.  相似文献   

4.
In contrast with other cells generated by the root apical meristem in Arabidopsis, pericycle cells adjacent to the protoxylem poles of the vascular cylinder continue to cycle without interruption during passage through the elongation and differentiation zones. However, only some of the dividing pericycle cells are committed to the asymmetric, formative divisions that give rise to lateral root primordia (LRPs). This was demonstrated by direct observation and mapping of mitotic figures, cell-length measurements, and the histochemical analysis of a cyclin-GUS fusion protein in pericycle cells. The estimated duration of a pericycle cell cycle in the root apical meristem was similar to the interval between cell displacement from the meristem and the initiation of LRP formation. Developmentally controlled LRP initiation occurs early, 3 to 8 mm from the root tip. Thus the first growth control point in lateral root formation is defined by the initiation of primordia in stochastic patterns by cells passing through the elongation and young differentiation zones, up to where lateral roots begin to emerge from the primary root. Therefore, the first growth control point is not restricted to a narrow developmental window. We propose that late LRP initiation is developmentally unrelated to the root apical meristem and is operated by a second growth control point that can be activated by environmental cues. The observation that pericycle cells divide and lateral root primordia form without intervening mitotic quiescence suggests that lateral organ formation in roots and shoots might not be as fundamentally different as previously thought.  相似文献   

5.
The root apical meristem of Asplenium bulbiferum Forst. f. has a prominent four-sided pyramidal cell with its base in contact with the rootcap. Derivatives (merophytes) that contribute to the main body of the root are produced from the three proximal faces of the apical cell. The rootcap has its origin from the fourth (distal) face of the apical cell. The first division in a proximal merophyte is periclinal to the root surface, separating an outer cell and an inner cell. The outer cell is the origin of the outer part of the cortex and the epidermis; the larger inner cell is the origin of the inner cortex, endodermis, pericycle, and vascular tissue. After the establishment of the basic number of cells in a unilayered merophyte, the cells undergo transverse divisions forming longitudinal files of cells. The mitotic index of the apical cell indicates that it is not a quiescent cell. Also, the first plane of division in a newly formed merophyte dictates that the apical cell is the originator of merophytes.  相似文献   

6.
白鲜根的发育解剖学研究   总被引:1,自引:0,他引:1  
应用半薄切片、常规石蜡切片并结合离析法,对药用植物白鲜(Dictamnus dasycarpus Turcz.)根的发生发育过程进行了研究。结果表明:白鲜根的发生发育过程包括4个阶段,即原分生组织阶段、初生分生组织阶段、初生结构阶段以及次生结构阶段。原分生组织位于根冠内侧及初生分生组织之间,衍生细胞分化为初生分生组织。初生分生组织由原表皮、基本分生组织以及中柱原组成。原表皮分化为表皮,基本分生组织分化为皮层,中柱原分化为维管柱,共同组成根的初生结构;在初生结构中,部分表皮细胞外壁向外延伸形成根毛,皮层中分布有油细胞,内皮层有凯氏带,初生木质部为二原型或偶见三原型,外始式;根初生结构有髓或无。次生结构来源于原形成层起源的维管形成层的活动以及中柱鞘起源的木栓形成层的活动;白鲜次生韧皮部宽广,其中多年生根中可占根横切面积的85%,另外除基本组成分子外,还分布有油细胞;周皮发达,木栓层厚;初生皮层、次生木质部和次生韧皮部薄壁细胞中常充满丰富的淀粉粒。  相似文献   

7.
The arrest of DNA synthesis and termination of cell division in basal meristematic cells as well as the resumption of these processes as related to the initiation of lateral root primordia (LRP) were studied in tissues of Triticum aestivumroots incubated with 3H-thymidine. All cells of the stelar parenchyma and cortex as well as most endodermal and pericycle cells left the mitotic cycle and ceased proliferative activity at the basal end of the meristem and at the beginning of the elongation zone. Some endodermal and pericycle cells started DNA synthesis in the basal part of the meristem and completed it later on during their elongation, but they did not divide. In the cells of these tissues, DNA synthesis resumed above the elongation zone, the cells being located much closer to the root tip than the first newly dividing cells. Thus, the initiation of LRP started much closer to the root tip than it was previously believed judging from the distance of the first dividing pericycle cells from the root tip. DNA synthesizing and dividing cells first appeared in the stelar parenchyma, then, in the pericycle, and later, in the endodermis and cortex. It seems likely that a release from the inhibition of DNA synthesis allows the cells that completed mitotic cycle in the basal part of meristem in the G1phase to cease the proliferative arrest above the elongation zone and to continue their cycling. The location of the first DNA synthesizing and dividing cells in the stelar parenchyma and pericycle did not strictly correspond to the LRP initiation sites and proximity to the xylem or phloem poles. This indicates that LRP initiation results from the resumption of DNA synthesis in all pericycle and stelar parenchyma cells that retained the ability to synthesize DNA and occurs only in the pericycle sector situated between the two tracheal protoxylem strands, all cells of which terminated their mitotic cycles in the G1phase.  相似文献   

8.
Summary Far from the apical meristem of adventitious roots ofAllium cepa, the pericycle shows great proliferative activity related to lateral root initiation. A group of mother pericycle cells undergoes asymmetrical transverse and periclinal divisions following a well-established pattern. Successive asymmetrical transverse divisions, progressing from one end of the cell to the other, divide the original mother cell into very short derivatives. Later, these short derivative cells undergo periclinal divisions. This proliferative activity starts nearly simultaneously in two elongated and highly vacuolated pericycle cells located in the same column in front of one of the xylem poles. Then proliferation expands centrifugally towards other pericycle cells in the same and adjacent columns. The proliferative activity of the pericycle cells decreases progressively outwards. Only the most central of these cells produce derivatives which contribute to the future lateral root.  相似文献   

9.
A panel of monoclonal antibodies that recognize a class of cell wall proteins, related to the hydroxyproline-rich glycoproteins, has been assembled and characterized in relation to their restricted patterns of binding amongst the cells comprising the carrot root apex. The occurrence of the epitopes at the surface of cells and intercellular spaces in the region of the apex between the meristematic initials and the region of cell expansion indicates dynamic patterns that reflect aspects of the development of the anatomical pattern. The monoclonal antibody JIM11 reacts with the surface of cells in the central root cap and the region of the meristem. As the cortex/stele boundary becomes established the reactivity is seen in the inner cortical layers and finally in the whole cortex. Later in development the JIM11 epitope is also expressed by two pairs of pericycle cell files adjacent to the phloem region and also by the epidermis. The JIM12 monoclonal antibody is unreactive with cells in the region of the root cap and the meristem but is reactive with intercellular spaces formed at the junction of the oblique and radial walls in the double-layered sectors of the pericycle opposite the xylem poles. This epitope is also transiently expressed by the two phloem sieve tube element mother cells. Later in development JIM12 recognizes the future metaxylem cells. The antibody JIM20 recognizes all the cells and intercellular spaces recognized by JIM11 and JIM12. Immuno-chemical analyses indicate cross-reactivity with carrot taproot extensin and Solanaceous lectins.  相似文献   

10.
Pea roots have open apical organization, where discrete initial cells do not exist. Differentiation of all tissues occurs in cylinders and vascular sectors that blend gradually with each other. This study reports the distribution of dividing cells and their relationship to maturation events in the 2 mm root tip, and in the 8–10 and 18–20 mm segments. Up to 200 μm from the root body/cap junction, cell division is uniformly distributed throughout all meristem regions. By 350 to 500 μ, xylem tracheary elements and cells of the pith parenchyma and middle cortex have stopped dividing. At this level cell division is almost entirely restricted to two cylinders, one composed of the inner root cap, the epidermis, and the outer cortex (outer cortex cylinder) and another composed of cells of the inner cortex, the pericycle and vascular tissue (inner cortex cylinder). When the protophloem matures, all cells in the phloem sector of the inner cortex cylinder, including the 1 layered pericycle, the endodermis and the phloem parenchyma, stop dividing. The 3–4 layered pericycle in the xylem sectors continues dividing until about 10 mm from the body/cap junction following the maturation of the protoxylem tracheary elements.  相似文献   

11.
Anomalous secondary thickening occurs in the main axis of Bougainvillea spectabilis as a result of a primary thickening meristem which differentiates in pericycle. The primary thickening meristem first appears in the base of the primary root about 6 days after germination and differentiates acropetally as the root elongates. It begins differentiating from the base of the hypocotyl toward the shoot apex about 33 days after germination. The primary thickening meristem is first observable at the base of the first internode about 60 days after germination. It then becomes a cylinder in the main axis of the seedling. No stelar cambial cylinder forms in the primary root, hypocotyl, or stem because vascular cambium differentiation occurs neither in the pericycle opposite xylem points in the primary root nor in interfascicular parenchyma in the hypocotyl or stem. The primary vascular system of the stem appears anomalous because an inner and an outer ring of vascular bundles differentiate in the stele. Bundles of the inner ring anastomose in internodes, whereas those of the outer ring do not. Desmogen strands each of which is composed of phloem, xylem with both tracheids and vessels, and a desmogic cambium, differentiate from prodesmogen strands in conjunctive tissue. The parenchymatous cells surrounding desmogen strands then differentiate into elongated simple-pitted fibers and thick-walled fusiform cells that are about the same length as the primary thickening meristem initials.  相似文献   

12.
13.
Lateral roots of Typha glauca arose from the pericycle of the parent adventitious root. Periclinal divisions of the pericycle gave rise to two layers; the outermost initially produced the ground meristem and protoderm, and the innermost produced the procambium. The immature endodermis of the parent root contributed to the early stages of the root tip as an endodermal covering. Prior to emergence, the ground meristem/protoderm produced cells into the endodermal covering. After emergence, the endodermal covering was replaced by a calyptrogen, which was derived from the ground meristem/protoderm and which, in turn, formed the rootcap. A typical monocotyledonous three-tiered meristem was then produced. An outer ground meristem also arose before emergence to form a hypodermis in many lateral roots; in these, crystalliferous cell production began in midcortex cells before emergence, and a small aerenchyma developed in their cortices. The rootcap columella stored small amounts of starch shortly after emergence. Lateral roots of T. glauca were smaller than their parental adventitious roots; they normally had only two to six poles of xylem and phloem, and the cortex was less than six cells across. During 1–3-cm elongation, the lateral root apical meristem and mature regions narrowed, stored starch disappeared, fewer crystals formed, aerenchyma production ceased, and the roots stopped elongation.  相似文献   

14.
Roots of Marsilea vestita ranging from 1–120 mm in length, as well as root primordia, were analyzed to determine mitotic activity and ploidy levels in the apical cell, five well-defined regions of the root proper, and two regions in the root cap. The mitotic index of the apical cell tended to be above the overall mean mitotic index for the entire apical meristem. No diurnal rhythm in mitotic index was apparent. The cell-cycle duration of the apical cell ranged from 12.1–25.2 hr, that of other regions of the root from 16.1–41.5 hr. There was no indication of polyploidy in any part of the apical meristem except in a few procambial cells. Thus, the results support the classical concept that the apical cell is the ultimate source of cells in the root.  相似文献   

15.
Seedlings of Atriplex hortensis were studied to ascertain; 1) in which organ the primary thickening meristem (PTM) first differentiates; 2) the direction of differentiation of the PTM, and 3) the pattern of differentiation of conjunctive tissue. The PTM initially differentiates in pericycle of the primary root base 11 days after emergence of the primary root. It then differentiates in the transition region of the hypocotyl, mostly in cells of pericycle between pairs of vascular bundles. In the upper hypocotyl, PTM differentiates by day 20 in the inner layer of cortical parenchyma. In the epicotyl, PTM apparently differentiates in the inner layer of cortex, by day 24. Desmogic xylem differentiates from radial files of internal conjunctive tissue cells and desmogic phloem differentiates opposite desmogic xylem strands from newly formed cells of external conjunctive tissue. No interfascicular cambium differentiates in the root, hypocotyl, or epicotyl.  相似文献   

16.
The outer tissues of dicotyledonous plant roots (i.e. epidermis, cortex, and endodermis) are clearly organized in distinct concentric layers in contrast to the diarch to polyarch vascular tissues of the central stele. Up to now, the outermost layer of the stele, the pericycle, has always been regarded, in accordance with the outer tissue layers, as one uniform concentric layer. However, considering its lateral root-forming competence, the pericycle is composed of two different cell types, with one subset of cells being associated with the xylem, showing strong competence to initiate cell division, whereas another group of cells, associated with the phloem, appears to remain quiescent. Here, we established, using detailed microscopy and specific Arabidopsis thaliana reporter lines, the existence of two distinct pericycle cell types. Analysis of two enhancer trap reporter lines further suggests that the specification between these two subsets takes place early during development, in relation with the determination of the vascular tissues. A genetic screen resulted in the isolation of mutants perturbed in pericycle differentiation. Detailed phenotypical analyses of two of these mutants, combined with observations made in known vascular mutants, revealed an intimate correlation between vascular organization, pericycle fate, and lateral root initiation potency, and illustrated the independence of pericycle differentiation and lateral root initiation from protoxylem differentiation. Taken together, our data show that the pericycle is a heterogeneous cell layer with two groups of cells set up in the root meristem by the same genetic pathway controlling the diarch organization of the vasculature.  相似文献   

17.
Mitotic activity was investigated in the primary meristem of horizontally oriented excised root tips of Zea mays during the first six hours of their georeaction. The only statistically significant change that could be detected in the meristem was a decrease of the length of its upper half. No significant difference in mitotic activity was found between the upper and lower halves of roots kept continuously horizontal for 6 h. Cell proliferation thus seems relatively insensitive to changes in the redistribution of endogenous growth regulators that are believed to occur within the meristem during the onset of geotropism. In the zone of bending proximal to the meristem cell length was significantly greater in the upper half than in either the lower half or in the equivalent position in vertical control roots. Thus, cell elongation seems to be promoted in the upper half of the horizontal root. Thus, The differences in cell length were not accompanied by any change in the proportion of nuclei synthesising DNA in these elongating, non-meristematic cells.  相似文献   

18.
19.
Differentiation of the primary thickening meristem (PTM) was investigated in seedlings and older plants of Phytolacca americana L. Initiation of the PTM occurs in pericycle or inner cortex at the hypocotyl-primary root junction of young plants. Differentiation of the PTM in stems occurs acropetally in a cylinder of randomly dividing cells termed the diffuse lateral meristem (DLM). The PTM produces secondary tissue to the inside (internal conjunctive tissue) and to the outside (external conjunctive tissue). Patches of xylem and phloem differentiate, opposite each other, in recently produced internal and external conjunctive tissue, respectively. The resulting strands (desmogen strands) of xylem and phloem are secondary in origin, and are peripheral to primary vascular tissues. Phloem of desmogen strands usually differentiates first. Xylem of desmogen strands is composed of both tracheids and vessel elements; the latter sometimes becoming occluded with tyloses and unidentified substances. As root and hypocotyl increase in diameter, cylinders of PTMs differentiate successively and centrifugally in external conjunctive tissue. Even though the first PTM differentiates in pericycle or inner cortex and later PTMs differentiate in external conjunctive tissue, all are referred to as PTMs because of their similar activity. Multiple rings of desmogen strands can be observed in transections of lateral roots, primary roots and hypocotyls. Throughout the length of the stem, only one ring of desmogen strands is present. Fewer rings of desmogen strands are present in the top of the hypocotyl and cotylendonary node, as compared to the subjacent hypocotyl, due to anastomoses of centrifugally differentiating desmogen strands.  相似文献   

20.
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