ADVENTITIOUS ROOT DEVELOPMENT IN TYPHA GLAUCA,WITH EMPHASIS ON THE CORTEX

Adventitious root development was investigated in Typha glauca plants grown under experimental conditions with the previous year's dead, sterile stalk either emerged above or submerged below the surface of Hoagland's solution. Adventitious roots emerged from buds in which most primordia had been earlier formed. Most roots elongated to 14–19 cm in 3–4 weeks and produced abundant lateral roots to their tips. Root apical meristem organization was typically monocotyledonous with a single tier of ground meristem/protoderm over the procambium. The ground meristem had zones of periclinal divisions in its innermost and outermost layers; the innermost layer initiated the endodermis and midcortex, and the outermost layers initiated the hypodermis. Crystalliferous cells with raphides were produced in the midcortex, and aerenchyma resulted from the radial expansion of schizogenous air spaces and some lysigeny in the midcortex. The procambium produced a vascular cylinder with 10–13 phloem and xylem poles, 6–9 large metaxylem elements, and central sclerenchyma. As roots stopped elongating, they narrowed, the vascular cylinder diminished in size, typical aerenchyma was lost from the cortex, crystal production ceased, and the rootcap diminished in size with its storage starch used up. Growth was determinate in these adventitious roots. The results suggested that a periclinally derived outer ground meristem was a prerequisite for a hypodermis, which, in turn, was necessary as a structural framework for aerenchyma. Without a hypodermis, typical aerenchyma was not present.     

DEVELOPMENTAL ANATOMY IN ROOTS OF IPOMOEA PURPUREA. II. INITIATION AND DEVELOPMENT OF SECONDARY ROOTS

In seedlings of Ipomoea purpurea secondary roots are initiated in the primary root pericycle opposite immature protoxylem. Cells derived from immature endodermis, pericycle, and incipient protoxylem and stelar parenchyma contribute to the primordium. The derivatives of the endodermis become a uniseriate covering over the tip and flanks of the primordium and emerged secondary root; the endodermal covering is sloughed off when the lateral root reaches 1–5 mm in length. A series of periclinal and anticlinal divisions in the pericycle and its derivatives gives rise to the main body of the secondary root. The initials for the vascular cylinder, cortex, and rootcap-epidermis complex are established very early during primordium enlargement. After emergence from the primary root, the cortical initials undergo significant structural modifications related to enlargement of the ground meristem and cortex, and the rootcapepidermal initials are partitioned into columellar initials and lateral rootcapepidermal initials. Procambium diameter increases by periclinal divisions in peripheral sectors. The mature vascular cylinder is comprised of several vascular patterns, ranging from diarch to pentarch, that are probably related ontogenetically. Cells derived from incipient protoxylem and stelar parenchyma cells of the primary root form the vascuar connection between primary and secondary roots.     

Histological analysis of adventitious rooting in Arabidopsis thaliana (L.) Heynh seedlings

ABSTRACT

Adventititous rooting is essential for the post-embryonic growth of the root apparatus in various species. In Arabidopsis thaliana, adventitious rooting has been reported in some mutants, and auxin seems to be the inducer of the process. The objective of the study was to identify the tissues involved in adventitious rooting in the most commonly used ecotypes for molecular and genetic studies (i.e. Columbia, Wassilewskija and Landsberg erecta) both in the presence and absence of exogenous auxin. Seedlings of the three ecotypes were grown under various conditions. When grown under 16 hours light/day for 11 days, all seedlings showed adventitious roots, both with and without auxin, however, both adventitious and lateral rooting were enhanced by exogenous auxin (2 µM naphthaleneacetic acid). Independently of the presence of auxin and of the ecotype, the hypocotyl pericycle produced adventitious roots directly (i.e., according to the same pattern of lateral root formation by the pericycle cells in the primary root). However, in the presence of auxin, roots of indirect origin also, and mainly, formed and their formation was preceded by the exfoliation of the tissues external to the stele. Exfoliation was caused by cell hypertrophy, separation, and disintegration, which mainly involved the endodermis. At the exfoliation site, the pericycle, with a minor contribution of a few endodermal cells, produced the callus from which indirect roots arose. The finding that adventitious rooting occurs in the absence of auxin (all ecotypes) indicates that this process is part of the normal root apparatus in Arabidopsis, with the hypocotyl pericycle as the target tissue of the process. Exogenous auxin alters adventitious rhizogenesis mainly affecting the endodermis response.     

DEVELOPMENTAL ANATOMY OF CORALLOID ROOTS IN CYCADS

Coralloid roots of cycads were found to originate endogenously from the pericycle of apogeotropic secondary roots or adventitious roots that have become exposed or nearly exposed to the soil surface. All mature coralloid roots are susceptible to infection by algal endophytes, which seem to enter from the soil through a break in the dermal layers. In the coralloid roots the algae inhabit intercellular spaces in a definite zone that arises from the protoderm, and in which the cells elongate radially following algal infection. The zone is completely surrounded by a persistent rootcap which is interpreted by most authors as a secondary cortex. The secondary cortex was shown to be derived from the rootcap in this investigation.     

Anatomical aspects of angiosperm root evolution

Background and Aims

Anatomy had been one of the foundations in our understanding of plant evolutionary trends and, although recent evo-devo concepts are mostly based on molecular genetics, classical structural information remains useful as ever. Of the various plant organs, the roots have been the least studied, primarily because of the difficulty in obtaining materials, particularly from large woody species. Therefore, this review aims to provide an overview of the information that has accumulated on the anatomy of angiosperm roots and to present possible evolutionary trends between representatives of the major angiosperm clades.

Scope

This review covers an overview of the various aspects of the evolutionary origin of the root. The results and discussion focus on angiosperm root anatomy and evolution covering representatives from basal angiosperms, magnoliids, monocots and eudicots. We use information from the literature as well as new data from our own research.

Key Findings

The organization of the root apical meristem (RAM) of Nymphaeales allows for the ground meristem and protoderm to be derived from the same group of initials, similar to those of the monocots, whereas in Amborellales, magnoliids and eudicots, it is their protoderm and lateral rootcap which are derived from the same group of initials. Most members of Nymphaeales are similar to monocots in having ephemeral primary roots and so adventitious roots predominate, whereas Amborellales, Austrobaileyales, magnoliids and eudicots are generally characterized by having primary roots that give rise to a taproot system. Nymphaeales and monocots often have polyarch (heptarch or more) steles, whereas the rest of the basal angiosperms, magnoliids and eudicots usually have diarch to hexarch steles.

Conclusions

Angiosperms exhibit highly varied structural patterns in RAM organization; cortex, epidermis and rootcap origins; and stele patterns. Generally, however, Amborellales, magnoliids and, possibly, Austrobaileyales are more similar to eudicots, and the Nymphaeales are strongly structurally associated with the monocots, especially the Acorales.     

Resumption of DNA Synthesis and Cell Division in Wheat Roots as Related to Lateral Root Initiation

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.     

CORTICAL ONTOGENY IN ROOTS. I. ZEA MAYS

Serial growth stages of young Zea mays primary roots were analyzed for patterns of ground meristem ontogeny. The number of cell layers in the cortex decreases from approximately 15 to 11 during early root growth. The cortex arises mostly by periclinal divisions in the outer portions of the ground meristem at levels 50–150 μm from the meristem tip, although some layers of outer cortex arise beyond 150 μm. The proendodermis contributes 3–5 cell layers to the cortex, but this contribution diminishes during early seedling growth as anticlinal divisions occur in the proendodermis. The relationship between the ground meristem and protoderm changes at the tip of the meristem during root elongation.     

Suberin lamella development in maize seedling roots grown in aerated and stagnant conditions

Hypoxia can stimulate the development of a suberized exodermis in aquatic plants; however, its influence on this aspect of terrestrial root development is sparsely documented. To determine the effects of hypoxia on maize (Zea mays cv. Seneca Horizon) roots, seedlings were grown in vermiculite (VERM), aerated hydroponics (AER), stagnant hydroponics with agar (STAG), or aerated hydroponics with agar (AERAG). The endo- and exodermis were examined for wall modifications. Lateral root emergence and aerenchyma formation were documented qualitatively. The endodermal Casparian band formation was unaffected by treatment. Endodermal and exodermal suberin lamella formation was earliest and most extensive in VERM. Suberization, especially in the exodermis of aerated treatments, was depressed in all hydroponic media. In comparison with AER, STAG exodermal lamellae were increased, but endodermal lamellae were decreased. Since the suberized exodermis forms a barrier to radial oxygen loss from roots to the medium, its stimulation in STAG roots (which also developed extensive aerenchyma) would help retain oxygen in the root. The reduction of endodermal lamellae should facilitate oxygen diffusion into the stele. Clearly, the response to environmental conditions is variable within individual cortical cell layers. Additionally, the observed patterns of lamellae, aerenchyma and lateral root development indicate a tight radial co-ordination of root development.     

Cortical Aerenchyma formation in hypocotyl and adventitious roots of Luffa cylindrica subjected to soil flooding

BACKGROUND AND AIMS: Aerenchyma formation is thought to be one of the important morphological adaptations to hypoxic stress. Although sponge gourd is an annual vegetable upland crop, in response to flooding the hypocotyl and newly formed adventitious roots create aerenchyma that is neither schizogenous nor lysigenous, but is produced by radial elongation of cortical cells. The aim of this study is to characterize the morphological changes in flooded tissues and the pattern of cortical aerenchyma formation, and to analyse the relative amount of aerenchyma formed. METHODS: Plants were harvested at 16 d after the flooding treatment was initiated. The root system was observed, and sections of fresh materials (hypocotyl, tap root and adventitious root) were viewed with a light or fluorescence microscope. Distributions of porosity along adventitious roots were estimated by a pycnometer method. KEY RESULTS: Under flooded conditions, a considerable part of the root system consisted of new adventitious roots which soon emerged and grew quickly over the soil surface. The outer cortical cells of these roots and those of the hypocotyl elongated radially and contributed to the development of large intercellular spaces. The elongated cortical cells of adventitious roots were clearly T-shaped, and occurred regularly in mesh-like lacunate structures. In these positions, slits were formed in the epidermis. In the roots, the enlargement of the gas space system began close to the apex in the cortical cell layers immediately beneath the epidermis. The porosity along these roots was 11-45 %. In non-flooded plants, adventitious roots were not formed and no aerenchyma developed in the hypocotyl or tap root. CONCLUSIONS: Sponge gourd aerenchyma is produced by the unique radial elongation of cells that make the expansigeny. These morphological changes seem to enhance flooding tolerance by promoting tissue gas exchange, and sponge gourd might thereby adapt to flooding stress.     

Inhibition of tobacco mosaic virus replication in lateral roots is dependent on an activated meristem-derived signal

Summary. Viral invasion of the root system of Nicotiana benthamiana was studied noninvasively with a tobacco mosaic virus (TMV) vector expressing the green-fluorescent protein (GFP). Lateral root primordia, which developed from the pericycle of primary roots, became heavily infected as they emerged from the root cortex. However, following emergence, a progressive wave of viral inhibition occurred that originated in the lateral-root meristem and progressed towards its base. Excision of source and sink tissues suggested that the inhibition of virus replication was brought about by the basipetal movement of a root meristem signal. When infected plants were inoculated with tobacco rattle virus (TRV) expressing the red-fluorescent protein, DsRed, TRV entered the lateral roots and suppressed the host response, leading to a reestablishment of TMV infection in lateral roots. By infecting GFP-expressing transgenic plants with TMV carrying the complementary GFP sequence it was possible to silence the host GFP, leading to the complete loss of fluorescence in lateral roots. The data suggest that viral inhibition in lateral roots occurs by a gene-silencing-like mechanism that is dependent on the activation of a lateral-root meristem. Received July 23, 2001 Accepted October 11, 2001     

Aerenchyma formation and recovery from hypoxia of the flooded root system of nodulated soybean

BACKGROUND AND AIMS: Flooding results in hypoxia of the root system to which N2 fixation of nodulated roots can be especially sensitive. Morphological adaptions, such as aerenchyma formation, can facilitate the diffusion of oxygen to the hypoxic tissues. Using soybean, the aim of the study was to characterize the morphological response of the nodulated root system to flooding and obtain evidence for the recovery of N metabolism. METHODS: Sections from submerged tissues were observed by light microscopy, while sap bleeding from the xylem was analysed for nitrogenous components. KEY RESULTS: Flooding resulted in the rapid formation of adventitious roots and aerenchyma between the stem (immediately above the water line), roots and nodules. In the submerged stem, taproot, lateral roots and adventitious roots, lysigenous aerenchyma arose initially in the cortex and was gradually substituted by secondary aerenchyma arising from cells derived from the pericycle. Nodules developed aerenchyma from cells originating in the phellogen but nodules situated at depths greater than 7-8 cm showed little or no aerenchyma formation. As a result of aerenchyma formation, porosity of the taproot increased substantially between the 4th and 7th days of flooding, coinciding with the recovery of certain nitrogenous products of N metabolism of roots and nodules transported in the xylem. Thus, on the first day of flooding there was a sharp decline in xylem ureides and glutamine (products of N2 fixation), together with a sharp rise in alanine (product of anaerobic metabolism). Between days 7 and 10, recovery of ureides and glutamine to near initial levels was recorded while recovery of alanine was partial. CONCLUSIONS: N metabolism of the nodulated soybean root system can recover at least partially during a prolonged period of flooding, a process associated with aerenchyma formation.     

Lateral root development and saponin accumulation as affected by IBA or NAA in adventitious root cultures of <Emphasis Type="Italic">Panax ginseng</Emphasis> C.A. Meyer

Summary The effect of indole-3-butyric acid (IBA) and 1-naphthaleneacetic acid (NAA) on lateral root formation was investigated in adventitious root culture of Panax ginseng. Lateral root formation was affected by IBA (24.6 μM) or NAA (9.8 μM). Lateral root primordia emerged from the explant root pericycle after about 7 d of culture when the roots were cultured on Schenk and Hildebrandt (SH) medium supplemented with 24.6 μM IBA or 9.8 μM NAA. However, no changes were observed in the explant root pericycle on auxin-free medium. The IBA treatment was more effective for lateral root induction and root growth compared to NAA. In morphological and histological aspects, the lateral roots formed under IBA treatment developed normally, while NAA-treated roots exhibited abnormal growth. The accumulation of total saponin was greater in roots treated with IBA than with NAA.     

Formation and function of secondary aerenchyma in hypocotyl, roots and nodules of soybean (Glycine max) under flooded conditions

Flooding is a major problem in many areas of the world and soybean is susceptible to the stress. Understanding the morphological mechanisms of flooding tolerance is important for developing flood-tolerant genotypes. We investigated secondary aerenchyma formation and function in soybean (Glycine max) seedlings grown under flooded conditions. Secondary aerenchyma, a white and spongy tissue, was formed in the hypocotyl, tap root, adventitious roots and root nodules after 3 weeks of flooding. Under irrigated conditions aerenchyma development was either absent or rare and phellem was formed in the hypocotyl, tap root, adventitious roots and root nodules. Secondary meristem partially appeared at the outer parts of the interfascicular cambium and girdled the stele, and then cells differentiated to construct secondary aerenchyma in the flooded hypocotyl. These morphological changes proceeded for 4 days after the initiation of the flooding. After 14 days of treatment, porosity exceeded 30% in flooded hypocotyl with well-developed secondary aerenchyma, while it was below 10% in hypocotyl of irrigated plants that had no aerenchyma. When Vaseline was applied to the hypocotyl of plants from a flooded treatment to prevent the entry of atmospheric oxygen into secondary aerenchyma, plant growth, especially that of roots, was sharply inhibited. Thus secondary aerenchyma might be an adaptive response to flooding.     

THE ROOT APEX OF MALVA SYLVESTRIS. III. LATERAL ROOT DEVELOPMENT AND THE QUIESCENT CENTER

Both histological and autoradiographic procedures were used to follow lateral root initiation and development. Lateral roots of M. sylvestris were initiated in the pericycle, and although the endodermis became multiseriate, endodermal derivatives were not incorporated into the lateral root primordium. Apical organization of pre-emergent roots, characterized by two tiers of cortical initials, did not change with growth. During pre-emergent development there was no evidence of cortical lysogeny or quiescent center formation. Quiescent centers were present in both secondary and tertiary roots longer than 0.5 cm.     

ADVENTITIOUS ROOT DEVELOPMENT FROM THE SEEDLING HYPOCOTYL OF LYCOPERSICON ESCULENTUM

Tomato seedlings five through ten days old were used for this investigation. Adventitious roots were initiated from the pericycle of the tomato hypocotyl. The position of adventitious root development was irregular in the rhizogenic hypocotyl; however, the cellular pattern of individual root development was very regular. Four layers of pericycle derivatives participated in root histogenesis and a bi- or triseriate endodermal cover was derived from the endodermis. Fluorescent microscopy showed that Casparian strips on the meristematic endodermal cell walls were not removed biochemically but were displaced around the root primordium by anticlinal divisions and cell enlargement. Casparian strips were not synthesized by endodermal cover cells. The emergent root had a typical three tiered or closed pattern of apical organization, and quiescent centers were present in all emergent roots longer than 0.5–0.6 cm.     

Cortical development in roots of the aquatic plant Pontederia cordata (Pontederiaceae)

Adventitious roots of marsh-grown Pontederia cordata were examined to determine cortical development and structure. The innermost layer of the ground meristem forms the endodermis and aerenchymatous cortex. The outermost layer of the early ground meristem undergoes a precise pattern of oblique and periclinal cell divisions to produce a single or double layer of prohypodermis with an anchor cell for each radial file of aerenchyma cells. At maturity, endodermal cell walls are modified only by narrow Casparian bands. The central regions of the ground meristem become proaerenchyma and exhibit asymmetric cell division and expansion. They produce an aerenchymatous zone with barrel-shaped large cells and irregularly shaped small cells traversing the aerenchyma horizontally along radii; some crystalliferous cells with raphides are present in the aerenchyma. The walls of the hypodermis are modified early by polyphenols. The outermost layer of the hypodermis later matures into an exodermis with Casparian bands that are impermeable to berberine, an apoplastic tracer dye. The nonexodermal layer(s) of the hypodermis has suberin-modified walls. Radial files of aerenchyma are usually connected by narrow protuberances near their midpoints, the aerenchyma lacunae having been produced by expansion of cells along walls lining intercellular spaces. We are terming this type of aerenchyma development, which is neither schizogenous nor lysigenous, "differential expansion."     

The Relationship Between Lateral-Root Distribution and Endodermis and Pericycle Cell Length in Allium cepa L. Adventitious Roots

Endodermis and pericycle cell lengths were measured in intactand decapitated adventitious roots of Allium cepa L. Decapitationhad no effect on cell length in mature portions of the root,although it affected more immature cells, impeding normal elongation.Cell length shows a characteristic pattern in different zonesof the adventitious root: cells in the medial region were moremarkedly elongated. The number of lateral root primordia wasalso determined in different zones of the adventitious root.The possible relationship between lateral root distributionpattern and cell length in the endodermis and pericycle is discussed. Allium cepa, onion, endodermis, pericycle, lateral root, cell length     

Lateral root initiation by asymmetrical transverse divisions of pericycle cells in adventitious roots ofAllium cepa

Summary In onion adventitious roots cellular events have been identified that indicate that lateral root initiation occurs earlier and nearer the apex than previously documented. Lateral roots are not initiated when a pericycle cell divides periclinally but earlier, when a pair of neighbouring pericycle cells in the same column divide transversely and asymmetrically, with both mitoses close to the end towards the neighbouring pericycle cell. Each cell therefore produces two cells of unequal length. The shorter cells produced by the mother pericycle cells are adjacent, while the longer cells are located above and below the shorter cells. This objective morphological criterion allows clear identification of the site of lateral root initiation. Subsequent to these asymmetric divisions, both the longer pericycle cells again divide transversely and asymmetrically producing more short cells adjacent to the previous ones. The first periclinal division occurs in one of these short pericycle cells.     

白鲜根的发育解剖学研究

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。     

Molecular mechanism of adventitious root formation in rice

Adventitious roots account for the majority of the rice root system and play an irreplaceable role in rice growth and development. Rice adventitious roots are formed by division of the innermost ground meristem cells in the central cylinder, and some lateral roots are observable in the adventitious root system. Multiple hormones have been implicated in the regulation of root development. Auxin is involved in the initiation of adventitious roots, whereas cytokinin inhibits adventitious root initiation, but promotes adventitious root elongation. Other phytohormones such as nitric oxide, ethylene, brassinosteroid, jasmonic acid and gibberellin may be also involved in regulating adventitious root initiation and development. Additionally, more than 600 root development related quantitative trait loci (QTLs) have been located by QTL analysis of root traits.