Spiralizations and tropisms in Arabidopsis roots.

When Arabidopsis seedlings are grown on a hard-agar plate, their primary roots show characteristic spiralling movements, apparent as waves, coils and torsions, together with a slanting toward the right-hand side. All these movements are believed to be the result of three different processes acting on the roots: circumnutation, positive gravitropism and negative thigmotropism. The basic movement of the roots is described as that of a growing right-handed helix, which, because of the root tip hitting the agar plate, is continuously switched from the right-hand to the left-hand of the growth direction, and vice versa. This movement also produces a slanting root-growth direction toward the right-hand because of the incomplete waves made by the right-handed root to the left-hand. By contrast, the torsions seen in the coils and waves are interpreted as artefacts that form as an adaptation of the three-dimensional root helix to the flat two-dimensional agar surface.     

Chiral and non-chiral nutations in Arabidopsis roots grown on the random positioning machine

Arabidopsis thaliana roots grown on a vertically set plate do not elongate straight down the gravitational vector, but by making waves and coils, and by conspicuously slanting towards the right-hand. This behaviour, in a previous paper, was ascribed to the simultaneous effect of three processes: circumnutation, positive gravitropism and negative thigmotropism. However, when the plants are grown on the Random Positioning Machine (RPM), in conditions that are believed to simulate space microgravitational conditions closely, the roots do not show the usual pattern. In the wild type, the roots make large loops to the right-hand side, whereas in the gravitropic and auxinic mutants aux1, eir1, rha1, they just move randomly around the initial direction. Therefore, if the movements made on the RPM are those produced by the exclusion of gravitropism and negative thigmotropism, as is apparent, the conclusion is that Arabidopsis roots are animated by a form of chiral circumnutation, that is lacking in the auxinic and gravitropic mutants aux1, eir1 and rha1. In addition, the 1 g condition appears to reduce the scatter among the circumnutating tracks produced by the roots of the wild types, but not among those of the mutants. Because there is a scarcity of literature regarding circumnutation in roots, it is not known how widely root chiral circumnutation is spread, but it is known that, in some previously studied species, just random nutations are observed. Two kinds of nutating movements seem to exist in plant roots and, whereas the random process does not seem to be connected with auxin physiology and transport, the chiral process appears to be connected in the same way as gravitropism is.     

Rha1, a new mutant of Arabidopsis disturbed in root slanting,gravitropism and auxin physiology

A new Arabidopsis mutant is characterized (rha1) that shows, in the roots, reduced right-handed slanting, reduced gravitropism and resistance to 2,4-D, TIBA, NPA and ethylene. It also shows reduced length in the shoot and root, reduced number of lateral roots and shorter siliques. The gene was cloned through TAIL-PCR and resulted in a HSF. Because none of the known gravitropic and auxinic mutants result from damage in a HSF, rha1 seems to belong to a new class of this group of mutants. Quantitative PCR analysis showed that the expression of the gene is increased by heat and cold shock, and by presence of 2,4-D in the media. Study of the expression through the GUS reporter gene revealed increased expression in clinostated and gravistimulated plants, but only in adult tissues, and not in the apical meristems of shoots and roots.Key words: auxin, ethylene, slanting, gravitropism, HSFsArabidopsis primary roots, and especially those from some ecotypes (Ws, Landsberg), when grown on an agar dish, tilted on the vertical, show a wavy pattern, and a clear slanting towards a direction that has been considered the right-hand.^1–4 In the case of the mutant rha1, the right-handed slanting is notably reduced, its primary roots growing partly to the right-hand, partly straight down and partly to the left-hand, even though a slight preference for the right-hand is apparent.In addition, its roots show resistance to the inhibitory action of the auxin 2,4-D, ethylene (ACC), and the auxin transport inhibitors TIBA and NPA. These characteristics qualify the mutant as an auxinic one, and therefore a connection between the reduced slanting and the auxinic disturbances could be imagined. It is not known, however, what controls the slanting process itself, even though it appears as the consequence of a chiral circumnutational process. As reported,⁴ it seems the result of a chiral circumnutation with preference for the right-hand, transformed in a lateral slanting movement, because of the impact of the helix with the hard agar surface. This process results in the formation of waves, when the circumnutation helix impactig the agar reverses direction at every half turn, or the formation of large loops and strict loops (coils) when there is no reversion. The latter case seems to be a consequence of the fact that gravity is no longer “felt”. This has been previously noted in some mutants, or sometimes in old roots.rha1 is not the only mutant known to show reduction or increase of slanting, because other mutants were reported by Rutherford and Masson,³ and subsequent publications from the same group. Almost all show an increase of slant, with the exception of rhd3 and its alleles that show a complete suppression of the process.⁵ The mutated gene in rha1 was cloned through TAIL-PCR and shown to be a HSF. No other auxinic mutant, among those for which the gene was cloned, is known to be mutated in a HSF.HSFs, that are characteristically involved in the activation of the HSPs (heat shock proteins), which protect the cells from damage arising from high temperature and other stresses, have been shown to be involved also in different processes.^6,7 Hence, also in the case of rha1, we can well imagine other different functions, beside that of counteracting the heat shock. In particular, since the connection with auxin regulated processes is evident, we can suppose that the action could be on the PP2A phosphatase, as in the case of the rcn1 mutant, or of the human HSF2. The RCN1 protein corresponds to one unit of the PP2A,⁸ and the HSF2⁹ has been shown to substitute itself for the C subunit and alter the function of the phosphatase (Fig. 1). Experiments directed to see if a heat shock can modify the slanting of the roots in the wild-type and rha1, gave negative results, even though these experiments will need to be repeated under more widely ranging conditions. These results seem to indicate that the mechanism which induces asymmetric growth in roots is complex, and it is not controlled by a single gene.Open in a separate windowFigure 1Model proposed for the regulation of the PP2A activity by the RHA1 protein. (modified after Hong and Sarge, 1999).On the other hand, another puzzling characteristic of rha1 is the fact that its roots are resistant only to the auxin 2,4-D, and not to NAA and IAA. Differences in the response of the primary roots to different auxins have already been reported, and it was suggested that the response to NAA should be different, because this substance can penetrate passively the cell membranes.¹⁰ In the case of rha1, however, it seems that IAA can also penetrate the cells passively. This is in line with the chemiosmotic hypothesis,¹¹ but seems in contrast with the previous supposition. The resistance to ethylene, however, could indicate that the reduced inhibitory effect of 2,4-D is a consequence of the ethylene production induced by the synthetic auxin. On the other hand, the resistance to the auxin transport inhibitors TIBA and NPA, cannot be explained so easily. Possibly, in the mutant rha1, there is a reduced level of receptors for the considered substances.Using semiquantitative PCR analysis it was shown that rha1 retains the function of a HSF, the gene being clearly upregulated by heat and cold stress, and also by 2,4-D, but not by rotation on a clinostat or gravistimulation. The upregulation of the expression by 2,4-D was confirmed by a study of GUS expression in a transformed rha1, and with this technique the effects of gravity and simulated microgravity appeared clearly stimulatory too. No GUS expression however was apparent in the shoot and root meristems, and consequently we propose that the gene does not influence the first part of the graviresponse, but possibly the general transport of auxin through the plant.Thus, the mutant seems to be disturbed in root gravitropism, as well as in responses to the auxines and circumnutation. However not in the general circumnutation process, but in its chiral aspect, which is the cause of the slanting to the right-hand. Gravitropism, circumnutation and auxin physiology, thus, seem to be in some way connected in a complex integrated process, that, hopefully, will be gradually revealed in all its different aspects, through the future efforts of plant scientists.     

Circumnutation and gravitropism cause root waving in Arabidopsis thaliana

Arabidopsis thaliana roots grow in a wavy pattern on inclinedagar plates. This waving behaviour has been interpreted as representinga gravitropism-dependent thigmotropic response. We argue insteadthat this root waving represents primarily a flattened spiralgrowth pattern resulting from circumnutation and gravitropism. Key words: Arabidopsis, circumnutation, gravitropism, roots, thigmotropism     

Temperature Sensing by Primary Roots of Maize

Zea mays L. seedlings, grown on agar plates at 26°C, reoriented the original vertical direction of their primary root when exposed to a thermal gradient applied perpendicular to the gravity vector. The magnitude and direction of curvature can not be explained simply by either a temperature or a humidity effect on root elongation. It is concluded that primary roots of maize sense temperature gradients in addition to sensing the gravitational force.     

A pleiotropic Arabidopsis thaliana mutant with inverted root chirality

Circumnutation is an oscillating movement of a growing plant organ that is believed to result from an endogenous rhythmic process intrinsic to growth. Circumnutating organs, as they extend, describe a helical trace. In Arabidopsis thaliana (L.) Heynh. circumnutation is particularly evident in primary roots and occurs, as in most plants, in a right-handed direction when viewed from above in the direction of the growing tips. We have discovered a pleiotropic mutant of Arabidopsis with left-handed root circumnutation. Major abnormalities of the mutant are: (i) a reduced size of all organs, mainly due to a defect in cell elongation or expansion; (ii) a zigzagging pattern of stem pith cells, reminiscent of the “erectoides” phenotype of the lk mutant of Pisum; (iii) roots of the mutant are gravitropic but as they grow, they form tight, left-handed coils. Genetically, the mutant depends on the presence of two independent monogenic recessive factors acting additively. The mutant alleles of both factors alter the growth of the aerial organs in a similar manner but differ at the root level: one mainly produces non-circumnutating roots, the other changes the direction of circumnutation from right to left hand. Received: 18 July 1996 / Accepted: 30 November 1996     

Root-gel interactions and the root waving behavior of Arabidopsis

Arabidopsis roots grown on inclined agarose gels exhibit a sinusoidal growth pattern known as root waving. While root waving has been attributed to both intrinsic factors (e.g. circumnutation) and growth responses to external signals such as gravity, the potential for physical interactions between the root and its substrate to influence the development of this complex phenotype has been generally ignored. Using a rotating stage microscope and time-lapse digital imaging, we show that (1) root tip mobility is impeded by the gel surface, (2) this impedance causes root tip deflections by amplifying curvature in the elongation zone in a way that is distinctly nontropic, and (3) root tip impedance is augmented by normal gravitropic pressure applied by the root tip against the gel surface. Thus, both lateral corrective bending near the root apex and root tip impedance could be due to different vector components of the same graviresponse. Furthermore, we speculate that coupling between root twisting and bending is a mechanical effect resulting from root tip impedance.     

An aluminum influence on root circumnutation in dark revealed by a new super-HARP (high-gain avalanche rushing amorphous photoconductor) camera

The circumnutation of a rice root under dark conditions was observed using a highly sensitive camera, a new super-HARP camera. A rice root showed regular rhythmic movement with fixed angle. When treated with Al (5 microM AlCl3), the rotation angle of the root tip was drastically decreased and then the movement was resumed again, whereas the root elongation rate was constant. With the increase of Al concentration, the cycle-fading period became shorter. This is the first report to show that an Al treatment ceased the rotation movement of the root but not elongation.     

Short-Root regulates primary, lateral, and adventitious root development in Arabidopsis

Short-Root (SHR) is a well-characterized regulator of radial patterning and indeterminacy of the Arabidopsis (Arabidopsis thaliana) primary root. However, its role during the elaboration of root system architecture remains unclear. We report that the indeterminate wild-type Arabidopsis root system was transformed into a determinate root system in the shr mutant when growing in soil or agar. The root growth behavior of the shr mutant results from its primary root apical meristem failing to initiate cell division following germination. The inability of shr to reactivate mitotic activity in the root apical meristem is associated with the progressive reduction in the abundance of auxin efflux carriers, PIN-FORMED1 (PIN1), PIN2, PIN3, PIN4, and PIN7. The loss of primary root growth in shr is compensated by the activation of anchor root primordia, whose tissues are radially patterned like the wild type. However, SHR function is not restricted to the primary root but is also required for the initiation and patterning of lateral root primordia. In addition, SHR is necessary to maintain the indeterminate growth of lateral and anchor roots. We conclude that SHR regulates a wide array of Arabidopsis root-related developmental processes.     

Growth conditions modulate root-wave phenotypes in Arabidopsis

The cause for the wave-like growth of Arabidopsis thaliana roots on semi-solid medium remains unclear. Researchers have hypothesized a gravity-induced touch-response, circumnutation, or combinations thereof act as the major stimuli. Our data demonstrate that the gaseous environment within the Petri dish can override gravitational effects. Furthermore, we show that medium ion concentrations and gelling polymers modify the wave response. Although the mechanisms driving our wide-ranging wildtype phenotypes are currently unknown, these results are of immediate significance for interpreting genetic and physiological modifications of environmentally and genetically induced characteristics.     

Arabidopsis thaliana sku mutant seedlings show exaggerated surface-dependent alteration in root growth vector.

Roots of wild-type Arabidopsis thaliana seedlings in the Wassilewskija (WS) and Landsberg erecta (Ler) ecotypes often grow aslant on vertical agar surfaces. Slanted root growth always occurs to the right of the gravity vector when the root is viewed through the agar surface, and is not observed in the Columbia ecotype. Right-slanted root growth is surface-dependent and does not result directly from directional environmental stimuli or gradients in the plane of skewing. We have isolated two partially dominant mutations in WS (sku1 and sku2) that show an exaggerated right-slanting root-growth phenotype on agar surfaces. The right-slanting root-growth phenotype of wild-type and mutant roots is not the result of diagravitropism or of an alteration in root gravitropism. It is accompanied by a left-handed rotation of the root about its axis within the elongation zone, the rate of which positively correlates with the degree of right-slanted curvature. Our data suggest that the right-slanting root growth phenotype results from an endogenous structural asymmetry that expresses itself by a directional root-tip rotation.     

Root movements: Towards an understanding through attempts to model the processes involved

Roots have the ability to change the direction of their forward growth. Sometimes these directional changes are rapid, as in mutations, or they are slower, as in tropisms. The gravitational force is always present and roots have an efficient graviperception mechanism which enables them to initiate gravitropic movements. In trying to model and simulate the course of gravitropic root movements with a view to analyse the component processes, the following aspects of the plant's interaction with gravity have been considered: (1) The level of organization (organism, organ, cell) at which the movement process is expressed; (2) whether the gravity stimulation event is dynamic or static (i.e. whether or not physiologically significant displacements take place with respect to the gravity vector); (3) the sub-systems involved in movement and the processes which they regulate; (4) the mathematical characterization of the relevant sub-systems. A further allied topic is the nature of nutational movements and whether they are linked with gravitropic movements in some way. In considering how they can best be modelled, two types of nutational movements are proponed: stochastic nutation and circumnutation. Most, if not all, natural movements developed in response to static gravistimulation can be viewed as gravimorphisms. This applies at the levels of cell, organ and organism. However, when a system at any one of these levels experiences dynamic gravistimulation, because of its inherent homeostatic properties, it is induced to regenerate a state similar to that previously held. Thus, gravitropism is a regenerative gravimorphic process at the level of the organ.     

Differential roles of Arabidopsis heterotrimeric G-protein subunits in modulating cell division in roots

Signaling through heterotrimeric G proteins is conserved in diverse eukaryotes. Compared to vertebrates, the simpler repertoire of G-protein complex and accessory components in Arabidopsis (Arabidopsis thaliana) offers a unique advantage over all other multicellular, genetic-model systems for dissecting the mechanism of G-protein signal transduction. One of several biological processes that the G-protein complex regulates in Arabidopsis is cell division. We determined cell production rate in the primary root and the formation of lateral roots in Arabidopsis to define individually the types of modulatory roles of the respective G-protein alpha- and beta-subunits, as well as the heterotrimer in cell division. The growth rate of the root is in part a consequence of cell cycle maintenance in the root apical meristem (RAM), while lateral root production requires meristem formation by founder pericycle cells. Thus, a comparison of these two parameters in various genetic backgrounds enabled dissection of the role of the G-protein subunits in modulation of cell division, both in maintenance and initiation. Cell production rates were determined for the RAM and lateral root formation in gpa1 (Arabidopsis G-protein alpha-subunit) and agb1 (Arabidopsis G-protein beta-subunit) single and double mutants, and in transgenic lines overexpressing GPA1 or AGB1 in agb1 or gpa1 mutant backgrounds, respectively. We found in the RAM that the heterotrimeric complex acts as an attenuator of cell proliferation, whereas the GTP-bound form of the Galpha-subunit's role is a positive modulator. In contrast, for the formation of lateral roots, the Gbetagamma-dimer acts largely independently of the Galpha-subunit to attenuate cell division. These results suggest that Arabidopsis heterotrimeric G-protein subunits have differential and opposing roles in the modulation of cell division in roots.     

Interaction of light and gravitropism with nutation of hypocotyls of Arabidopsis thaliana seedlings

Etiolated seedlings of Arabidopsis thaliana nutated under conditions of physiological darkness while about ten percent of monitored individuals exhibited regular elliptical nutation, circumnutation. Pre-irradiation with red light prevented occurrence of circumnutation without having an effect on the average rate of the nutational movement. Phototropic response of seedlings to unilateral blue light appeared to be superimposed over nutation. Throughout gravitropism, some seedlings continued to exhibit nutation suggesting that these two processes are independently controlled. Based on these results, we suggest that nutation in Arabidopsis probably is not controlled by the mechanism predicted by the theory of gravitropic overshoots.     

Effects of MAPKK inhibitor PD98059 on the gravitropism of primary roots of maize

Gravity plays a fundamental role in plant growth and development, yet the molecular details of gravitropism is not fully understood. Here, we report the effects of PD98059, a specific inhibitor of mitogen-activated protein (MAP) kinase kinase, on the gravitropism of primary roots of maize. Unilateral application of PD98059 to horizontal roots led to different gravitropic growth. Placing PD98059-containing agar on the upper side of the root tips accelerated gravitropic curvature, whereas placing the agar on the lower side inhibited gravitropic curvature. However, no effect was detected when asymmetric application of PD98059 to vertical roots. Global application of maize primary root with PD98059 suppressed root gravitropism. Furthermore, the effects of H₂O₂ on horizontal root gravitropism and vertical root bending were compromised by pretreatment with PD98059. These results suggest an involvement of MAP kinase pathway(s) in gravitropism of maize roots.     

Basipetal auxin transport is required for gravitropism in roots of Arabidopsis

Auxin transport has been reported to occur in two distinct polarities, acropetally and basipetally, in two different root tissues. The goals of this study were to determine whether both polarities of indole-3-acetic acid (IAA) transport occur in roots of Arabidopsis and to determine which polarity controls the gravity response. Global application of the auxin transport inhibitor naphthylphthalamic acid (NPA) to roots blocked the gravity response, root waving, and root elongation. Immediately after the application of NPA, the root gravity response was completely blocked, as measured by an automated video digitizer. Basipetal [(3)H]IAA transport in Arabidopsis roots was inhibited by NPA, whereas the movement of [(14)C]benzoic acid was not affected. Inhibition of basipetal IAA transport by local application of NPA blocked the gravity response. Inhibition of acropetal IAA transport by application of NPA at the root-shoot junction only partially reduced the gravity response at high NPA concentrations. Excised root tips, which do not receive auxin from the shoot, exhibited a normal response to gravity. The Arabidopsis mutant eir1, which has agravitropic roots, exhibited reduced basipetal IAA transport but wild-type levels of acropetal IAA transport. These results support the hypothesis that basipetally transported IAA controls root gravitropism in Arabidopsis.     

Movement of calcium across tips of primary and lateral roots of Phaseolus vulgaris

Calcium (Ca) movement across tips of primary and lateral roots of Phaseolus vulgaris was determined by applying 45Ca2+ to one side of the root and collecting radioactivity in an agar receiver block on the opposite side of the root. The ratios of cpm in receiver blocks on the bottom of primary roots : cpm in receiver blocks on the top of the primary roots were 1.87 and 2.47 after 1 and 2 hr, respectively. This polar transport of Ca across tips of primary roots correlated positively with a graviculture of 43 degrees after 2 hr. The ratio of cpm in receiver blocks on the bottom of lateral roots : cpm in receiver blocks on the top of lateral roots was 1.20 after 2 hr. The decreased polar movement of Ca across tips of lateral roots correlated positively with lateral roots being nongraviresponsive. These data 1) support the suggestion that gravistimulation induces polar movement Ca toward the lower side of tips of primary roots, and 2) suggest that the reduced polar movement of Ca across tips of lateral roots may be involved in uncoupling gravistimulation from gravicurvature in lateral roots.