Lateral Root Anlage Development in Excised Roots of Vicia faba L., Pisum sativum L., Zea mays L. and Phaseolus vulgaris L.

The development of lateral root primordia has been investigatedin excised roots of Vicia faba, Pisum sativum, Zea mays andPhaseolus vulgaris cultured in White's medium supplemented with2 per cent sucrose and compared with previously published dataon such development in primaries of the corresponding intactplants (control roots). Primordia were produced in each batchof excised roots over the 6 day culture period but at a lowerrate (number day^–1) than in the controls. Such primordia in cultured roots of Zea and Phaseolus completedtheir development and grew out as lateral roots over a periodsimilar in length to that found in the controls, but with acell number of only about 33 per cent of that attained at thetime of secondary emergence in the primaries of the latter roots.These lower cell numbers were at least partly a reflection ofincreases in mean cell doubling time over the period of anlagedevelopment investigated in the excised roots relative to thecorresponding values found in the controls. Primordia initiated in excised roots of Pisum and Vicia didnot complete their development in culture, i.e. no lateral rootsemerged and arrest took place with cell numbers of only 37 (Pisum)and 17 (Vicia) per cent of the numbers determined at the timeof secondary root emergence in the controls. Such arrested primordiahad few nuclei in S and none in mitosis. Moreover, at leastin Pisum, the frequency distribution of the relative DNA contentof the nuclei in the latter primordia approximated that foundin the apical meristem of primary roots following the establishmentof the stationary phase under conditions of carbohydrate starvation. It has also been demonstrated in the course of these investigationsthat lateral root primordium development in all four speciesis at least biphasic and possibly triphasic. Vicia faba L., broad bean, Pisum sativum L., garden pea, Zea mays L., maize, Phaseolus vulgaris L., dwarf bean, root primordia, anlage, cell doubling time, lateral root emergence     

Growth and branching of the taproot of young oak trees--a dynamic study

The growth and branching of the taproot of young oak trees werestudied on seedlings grown in root observation boxes over aperiod of 30–45 d. The development of shoots and rootswere recorded daily on a set of eight plants, and additionalobservations on the initiation of primordia were made on anotherset of 18 plants. Taproot growth was typically indeterminateand linear, with growth rates in the range of 1.5–2.5cm d^–1. In some cases, however, growth slowed down orstopped, and resumed a few days later. The growth of shootsand roots were not synchronized. Taproots branched in two ways:acropetal branches emerged from 4–8-d-old taproot tissues,and late branches emerged from older tissues (up to 30 d inour experiment). The latter appeared especially when taprootgrowth slowed down or stopped. New primordia were initiatedon tissues older than 1.4 d, and lateral roots emerged aftera minimal development duration of 2.3 d. These time-relatedparameters described the emergence of branching very effectivety,since they were quite stable over a wide range of taproot growthrates. However, emergence duration decreased slightly in fastgrowing taproots. Branching density tended to increase withthe taproot growth rate. Physiological significance and consequences for modelling rootsystem development are discussed. Key words: Quercus robur, root system, growth, branching, primordium initiation     

Development of Lateral Root Primordia in Vicia faba, Pisum sativum, Zea mays andPhaseolus vulgaris: Rates of Primordium Formation and Cell Doubling Times

Lateral root primordium development has been examined in primaryroots of Vicia faba L., Pisum sativum L., Zea mays L. and Phaseolusvulgaris L. Following their initiation from an estimated minimumnumber of 77–162, 20–57, 17 and 12 cells respectivelyin Vicia, Phaseolus, Pisum and Zea, the primordia rapidly increasedin cell number to emerge as secondary roots about 2.8–3.6days later depending on the species being examined. Cell doublingtimes were estimated directly from cell numbers at differenttimes following primordium inception and were found to increasewith increase in primordium size in each of the species investigated. The number of primordia formed per cm of root growth per daywas greatest in Zea and least in Pisum. A comparison of thedata obtained for Vicia with that in the literature led to theconclusion that although the number of primordia produced percm of root growth was independent of the rate of primary elongation,the number produced per day increased in a linear fashion withincrease in the rate at which the primary lengthened. Vicia faba L, Pisum sativum L, Zea mays L, Phaseolus vulgaris L, broad bean, garden pea, maize, dwarf bean, root primordia, cell division, cell doubling time     

Lateral Root Development in Attached and Excised Roots of Zea mays L. Cultivated in the Presence or Absence of Indol-3-yl Acetic Acid

The initiation of lateral root primordia and their subsequentemergence as secondary roots have been examined in attachedand excised roots of Zea mays grown in the presence or absenceof indol-3-yl acetic acid (IAA). Exposure to IAA enhanced anlageinception in both batches of roots. In the attached roots, theIAA-induced stimulation of primordium initiation was followedby a similar increase in lateral emergence. IAA treatment, however,had no effect on the number of laterals produced, per centimetreof root, in the excised primaries. Thus, exposure to IAA didnot directly enhance lateral emergence in the attached rootsnor did it stimulate such emergence in the excised ones. Nocorrelation was found between proliferative activity in themeristem at the apex of the primary or the rate of root elongationon the one hand, and either the number of primordia initiated,or the number of laterals produced, per centimetre of primary,on the other. Zea mays, maize, root, primordium, lateral, indol-3-yl acetic acid, meristematic activity     

The effects of diclofop-methyl on root growth of wild oat

Diclofop-methyl severely reduced the growth of seminal roots of wild oat ( Avena fatua L.) when applied in hydroponics at 0.01 and 0.05 μ M . Lateral roots emerged closer to the seminal root apex than in the controls, but coronal root number and length were unaffected at 0.01 μ M . However, doses of 0.05 to 0.1 μ M induced more but shorter coronal roots to emerge than for controls. At 1 μ M the number and length of coronal roots were less than for controls. Root-applied diclofop-methyl at 1 μ M inhibited emerging second leaf growth to the same extent as a foliar dip in 1 μ M diclofop-methyl without causing chlorosis as foliar treatment does. Because of limited basipetal transport of foliarly-applied diclofop-methyl, shoot treatment was ineffective in inducing abnormal root morphogenesis of the seminal and lateral root systems, although it caused abnormalities of the coronal root system. Time course studies were initiated to examine the effect of root-applied diclofop-methyl at 0.05 μ M . Seminal root growth was inhibited (by diclofop-methyl) soon after treatment, while controls continued elongating. The distance between the seminal root apex and the first lateral primordia increased in the controls within one day after treatment, but decreased in the herbicide-treated roots. The distance between the seminal root apex and the first emerged lateral root was reduced by three days after treatment. The number of lateral primordia and emerged roots was unaffected three days after treatment. These dose-response and kinetic results suggested that diclofop-methyl caused a loss of apical dominance in the seminal root.     

Development of Lateral Primordia in Decapitated Adventitious Roots of Allium cepa

In decapitated adventitious roots of Allium cepa L. var. French,the time taken for lateral primordia to appear in five sectorshas been studied. This time is approx. 4–5 d after theapex of the adventitious root gave rise to the primordial initialcells. Allium cepa, adventitious root, lateral primordia     

Effect of Main Root Decapitation on Root Branching in Flax Seedlings

Root branching patterns in intact and decapitated flax (Linum usitatissimumL.) roots were compared. The number of initiated primordia in the control and decapitated roots was similar, but decapitated roots produced an increased number of lateral roots owing to an increase in the number of primordia developed into the laterals. It is suggested that the apical meristem influences lateral root development only at the stage of root emergence from the parent root.     

Site, Scale and Time-course for Adjustments in Lateral Root Initiation in Wheat Following Changes in C and N Supply

The pattern of lateral root initiation in seminal roots of wheat(Triticum aestivumL. cv. Alexandria) and the location, scaleand time-course for adjustments in initiation were studied afterchanges in C and N supply. Macroscopically visible primordiaappeared in a non-acropetal sequence with the frequency (numberper unit length) increasing with distance behind the main rootapex to a maximum at 40–50 mm behind the root tip. Pruningthe root system to a single seminal axis increased the primordiafrequency by 23% within 15 h. After longer periods, the effectof root-pruning was greater. The enhanced primordia frequencywas first observed in tissue located 0–10 mm behind theapex at the start of treatment. Feeding glucose (50 mM) alsoincreased primordia frequency within 15 h, but to a greaterextent, and here additional primordia were initiated in tissuelocated 0–10and10–20 mm behind the apex at the startof treatment. Withdrawing NO₃^-from one part of a split-rootsystem, whilst maintaining the supply to the other, reducedprimordia frequency in the non-fed roots and, in some cases,a compensatory increase in the NO₃^--fed roots was observed.The location and scale of the adjustments were similar to thosefound with root-pruning and glucose-feeding, but were slightlyslower to appear. In spite of some differences in detail, therewas a broad similarity in site, scale and time-course for adjustmentsin lateral root initiation with these treatments, which is consistentwith the operation of a common mechanism. Whenever an increasein primordia frequency was observed, it was associated withan increase in the ethanol-soluble sugar content of the tissue.However, the reduction in frequency in NO₃^--deprived roots wasalso accompanied by an increase in sugar content. There wasno consistent relationship between total N content of the tissueand primordia frequency, but there was between primordia frequencyand the rate of net NO₃^-uptake. The possible mechanisms controllinglateral root initiation are discussed. Compensatory growth; correlative growth; glucose; initiation; lateral root; nitrate; primordium; split-root; Triticum aestivum; wheat     

Different Ways of Formation of Root System in Plants,Maize and Flax Seedlings Taken as Examples

Comparison of the appearance and development of lateral roots in the flax and maize seedlings has shown the way of root branching in the flax, as distinct from that in most plants. Some primordia in the flax main root did not develop immediately into lateral roots, but remained quiescent, which determines different reactions of the maize and flax root systems to experimental influences. Decapitation of the main root in the maize did not leads to a significant increase in the number of lateral roots, while in the flax, their number noticeably increased due to the development of previously quiescent primordia into lateral roots. The treatment with synthetic auxin did not induce the formation of additional primordia and lateral roots in the maize roots. In the flax, the number of primordia increased significantly and that of lateral roots increased to a somewhat lesser extent. Apparently, the development of a primordium into a lateral root proceeds in two stages and they have different regulation.     

Different methods of forming root systems in plants using maize and flax seedlings as examples

Comparison of the appearance and development of lateral roots in the flax and maize seedlings has shown the way of root branching in the flax, as distinct from that in most plants. Some primordia in the flax main root did not develop immediately into lateral roots, but remained quiescent, which determines different reactions of the maize and flax root systems to experimental influences. Decapitation of the main root in the maize did not leads to a significant increase in the number of lateral roots, while in the flax, their number noticeably increased due to the development of previously quiescent primordia into lateral roots. The treatment with synthetic auxin did not induce the formation of additional primordia and lateral roots in the maize roots. In the flax, the number of primordia increased significantly and that of lateral roots increased to a somewhat lesser extent. Apparently, the development of a primordium into a lateral root proceeds in two stages and they have different regulation.     

The Development of a Quiescent Centre in Lateral Roots of Vicia faba L.

During lateral root elongation there was a reduction in thenumber of cells present in the apical mm of the root, in thewidth of the root and in the number of rows of cells acrossthe root. At the same time, a quiescent centre, which was absentfrom large primordia and from lateral roots which had just emergedfrom the tissues of the primary root, was established. The quiescentcentre increased in size and cell number as the lateral rootelongated from 0·2 to 4 cm, the most rapid increase takingplace in roots between 0·2 and 0·5 cm in length.There was no correlation between root width and size of thequiescent centre in these roots. The cells in the quiescentcentre were smaller in size and had a lower labelling indexthan cells in other parts of the meristem. The distributionof labelled nuclei within the quiescent centrewas determinedand is discussed with respect to the site of root initial cells.     

The Response of Primordial Cells of Vicia faba to Colchicine

Whole root systems of Vicia faba were treated with 0.025 percent colchicine for 3 h. Meristems of roots and developing primordiawere examined immediately after treatment and 24 and 48 h later.Large primordia, i.e. those primordia that would emerge as lateralroots within approximately 24 h, are induced to form tetraploidcells. However, unlike lateral roots, they do not form a typicalc-tumour, their longitudinal growth is not inhibited, and theirmitotic index does not fall. Furthermore, the tetraploid cellsinduced in large primordia are not maintained when the primordiaemerge as lateral roots. Since the response of the very largestprimordia to a 3-h treatment with 0.025 per cent colchicineis similar in every way to that of lateral roots, it appearsthat the cells of primordia acquire the characteristics of lateralroot meristematic cells before the primordia emerge. From theevidence that induced tetraploid cells fail to survive as aprimordium grows out to form a lateral, it also seems that astructural reorganization accompanies the physiological reorganizationthat occurs as a primordium emerges.     

Distribution of Lateral Root Primordia in Root Tips of Musa

The distribution of lateral root primordia in the root tipsof four Musa landraces (Grande Naine, Pisang Berlin, Ngok Egomeand Yangambi Km5) grown in the field has been investigated toevaluate the range of genetic variation of lateral root initiation.In banana (Musa sp.), lateral roots are initiated in the roottip, 0.6–4 mm behind the root/cap junction and arise inseveral protoxylem-based longitudinal rows or ‘ranks’.Significant differences were observed among landraces for theposition of the most distal primordium, however the longitudinalspacing between successive primordia along the ranks was similarfor all landraces. All ranks were involved in lateral root initiation.The number of ranks also showed significant variations amonglandraces and was proportional to the stelar diameter. Hencethe density of lateral roots (roots cm^-1) was affected by stelardiameter variations. Finally, root elongation in the root tipwas landrace-specific and not necessarily exponential, unlikesuggested in previous studies. It is concluded that lateralroot initiation in Musa is not involved in the genetic variationsof root architecture in the field. A dissection of root architectureinto components which may account for these variations is proposedin relation to the improvement of root system architecture.Copyright 1999 Annals of Botany Company Lateral root initiation, root architecture, Musa, banana.     

Hormonal factors controlling the initiation and development of lateral roots

As the first part of a comprehensive study of the hormonal control of lateral root initiation and development, the effect of surgical treatments such as removal of the root tip, one or more cotyledons, the young epicotyl, or combination of these treatments, on the induction and emergence of lateral roots on the primary root of pea seedlings has been examined. Results show that removal of the root tip leads to a rapid but transitory increase in the number of lateral primordia, the largest number arising in the most apical segment of decapitated roots suggesting the accumulation of acropetally moving promoter substances in this region. The cotyledons appear to be the main source of promoter substances for both the induction and emergence of lateral roots, although one or more promoters also appear to be produced in the epicotyl. The data further indicate that the root tip is possibly the source of a substance which moves basipetally and interacts with acropetally moving promoters to regulate the zone for lateral primordia initiation; the root tip also appears to be the source of a powerful inhibitor of lateral root emergence.     

Cap Formation during the Elongation of Lateral Roots of Vicia faba L.

Cell proliferation was examined in the cap initials of newly-emerged0·2 and 4·0 cm long lateral roots of Vicia fabafrom an investigation of the passage of labelled cells throughmitosis following a 1-h pulse with tritiated thymidine. Celldoubling time was found to increase in this group of initialcells as the secondary roots elongated, this increase beinga result of a gradual lengthening in the duration of the mitoticcycle of both the fast and slow cycling meristematic cells andof a decrease in the size of both the growth fraction and thoseproliferating cells with a short cycle time. The rate of cellproduction by the cap initials was maximal in the newly emergedsecondary roots and showed a gradual decline with subsequentlateral elongation. This change in the rate of cell proliferationin the cap initials has been shown to be related to the initiationof the quiescent centre following lateral root emergence fromthe tissues of the primary. The number of cells making up the cap of 0·2–4·0cm long secondary roots is known to be constant and thus therate at which cells are sloughed off of the cap into the soilmust be the same as the rate of cap cell formation in theseroots, all of the cap cells being replaced every 6–9 days.The rate of cap cell formation in 0·2–4·0cm long secondary roots was used to calculate that one 11-dayold Vicia plant will have contributed between 56 000 and 85000 cap cells to the rhizosphere from its root system sincegermination.     

The Control of Lateral Root Development in Cultured Pea Seedlings. II. Root Fasciation Induced by Auxin Inhibitors

Lateral root development in cultured seedlings of Pisum sativum (cv. Alaska) was modified by the application of auxin transport inhibitors or antagonists. When applied either to replace the root tip or beneath the cotyledonary node, two auxin transport inhibitors, 2,3,5-triiodobenzoic acid (TIBA) and 3,3a-dihydro-2-(p-methoxyphenyl)-8H-pyrazolo[5,1-α]isoindol-8-one (DPX-1840), increased cell division activity opposite the protoxylem poles. This resulted in the formation of masses of cells, which we are calling root primordial masses (RPMs), 2 to 3 days after treatment. RPMs differed from lateral root primordia in that they lacked apical organization. Some roots however developed both RPMs and lateral roots indicating that both structures were similar in terms of the timing and location of cell division in the pericycle and endodermis leading to their initiation. Removal of the auxin transport inhibitors allowed many of the RPMs to organize later into lateral root primordia and to emerge in clusters. When the auxin, indoleacetic acid (IAA) was added to the growth medium along with DPX-1840, 3 ranks of RPMs now in the form of fasciated lateral roots emerged from the primary root. The auxin antagonist, p-chlorophenoxy-isobutyric acid (PCIB), also induced RPM formation. In contrast to DPX-1840 treatment, the addition of IAA during PCIB treatment caused normal lateral root development.     

Studies in the Regeneration of Horseradish: I. A Re-examination of the Morphology and Anatomy of Regeneration

1. Horseradish roots reach a stage of ‘ripeness to regenerate’at the age of 1–2 months, when secondary thickening hasbegun, a phellogen has formed, and the primary cortex has beenshed; provided that they are then detached from the parent plant. 2. New primordia arise (as is already known) only in associationwith the scars of lateral roots; but they are produced, notas previously believed from a callus, but individually as organizedmeristems whose cells are derived only from the phellogen ofthe main root. 3. The primordia appear to be undetermined (‘indifferent’)in nature; their subsequent differentiation into buds or rootsis described.     

Some Observations on Invertase Activity in Roots of Vicia faba L.

Invertase activity has been determined at intervals along primaryroots of Vicia faba as they elongated from 0·5 to 8 cm.Little activity was evident in 0·5–1·0 cmlong primaries but in those 2–8 cm in length the mainpeak of enzyme activity was associated with the region of cellelongation. Changes took place in the pattern of invertase activityalong the primary roots as they lengthened and these changeshave been correlated with fluctuations in both the rate of rootelongation and the supply of sucrose to the root from the cotyledons.The presence of a root cap did not increase the activity ofthis enzyme in the apical 1 mm of these roots. Invertase activity was higher in lateral root primordia thanin most parts of the primary root basal to the meristem, presumablybecause of the presence of sucrose in the adjacent cavity inthe cortex of the primary root. The peaks of invertase activityfound basal to the region of cell elongation in 3–8 cmlong primary roots probably resulted from the development ofroot pnmordia in these parts of the root.     

The Control of Lateral Root Development in Cultured Pea Seedlings. III. Spacing Intervals

The spacing of lateral root primordia in the primary root of Pisum sativum (cv. Alaska) seedlings is influenced by both predetermined lateral root initiation sites in the embryonic radicle and by factors present during seedling growth. When pea seeds were germinated in the presence of the mitotic inhibitor, colchicine, the triarch radicle produced three ranks of primordiomorphs indicating sites of embryonic lateral root primordia. The number of primordiomorphs was not the same along the three xylem strands in the radicle. Normally germinated seedling roots (5 days old) also showed a different number of lateral root primordia associated with the three strands. In both cases, the strand with the greatest number of primordia (or primordiomorphs) was associated with a cotyledonary trace. This indicated a possible role for the cotyledons in setting the pattern of lateral root distribution during radicle development. The spacing of lateral root primordia could be altered by the application of growth regulators. Seedling root tips (2 mm) were removed (? rt) and replaced with indoleacetic acid (+IAA), and in some instances seedlings were also treated with the auxin transport inhibitor, 3,3a-dihydro-2-(p-methoxyphenyl)-8H-pyrazolo[5, 1-α]isoindol-8-one (+DPX). In the growth regulator treatments, primary root elongation was inhibited, a greater number of lateral root primordia were initiated compared to controls, and the spacing intervals between primordia were greatly reduced. The — rt, +IAA, +DPX-treatment resulted in the closest possible spacing intervals (av. 0.4 ? 0.6 mm), but resulted in fused or fasciated laterals. The — rt, + IAA-treatment produced the shortest spacing intervals which resulted in “normal” lateral roots (0.8 ? 1.1 mm).     

Studies on induced changes in growth patterns and polarity in roots of Vicia faba L.

Summary Roots of Vicia faba were treated with colchicine (0.025%), or IAA (4.7×10^-6 M), or both, for 3 hours and fixed at various intervals over the following 11 days. The axis of spindle orientation and the distribution of mitotic figures, lateral root primordia and xylem vessel elements was examined in the apical 10 mm of median longitudinal sections of these roots.No effect of IAA was found on the orientation of the spindle. However, evidence was obtained indicating that the systems controlling the polarity of cell division and cell expansion differ in some way.The number of lateral root primordia formed was greater in roots treated with IAA or colchicine than in control roots. These primordia were always initiated adjacent to a xylem vessel. Thus, no primordium was closer to the apex than the most apical xylem vessel, suggesting that an endogenous factor involved in primordia initiation is transported in the xylem. The primordia which develop after colchicine treatment grow out as lateral roots; this is in contrast with those which form after IAA treatment and which do not undergo elongation. These results, which it must be emphasized apply only to the apical 1 cm of treated roots, indicate that lateral root primordia become sensitive to IAA at a certain stage in their development. Exogenous IAA acts as an inhibitor.The new meristem, which forms in the primary root apex after colchicine treatment, contains both diploid and polyploid cells, i.e. it was formed from cells that were unaffected and from cells that were affected by colchicine. Following colchicine treatment the size of the meristem shrinks and this can be prevented by treatment with IAA. This and other evidence presented here, suggests that IAA is a factor involved in the control of the size of the apical meristem in normal roots.