Andrée Havelange

Physiological Signals That Induce Flowering.

The timing of the transition from vegetative growth to flowering is of paramount importance in agriculture, horticulture, and plant breeding because flowering is the first step of sexual reproduction. Studies to understand how this transition is controlled have occupied countless physiologists during the past half century and have produced an almost unmanageably large amount of information (Bernier et al., 1981a; Halevy, 1985-1989; Bernier, 1988; Kinet, 1993). A majority of plants use environmental cues to regulate the transition to flowering because all individuals of a species must flower synchronously for successful outcrossing and because all species must complete their sexual reproduction under favorable externa1 conditions. Any environmental variables exhibiting regular seasonal changes are potential factors that control the transition to flowering. The major factors are photoperiod, temperature, and water availability. Plants that do not require a particular photoperiod or temperature to flower, i.e., the so-called “autonomous-flowering” plants, are usually sensitive to irradiance. The environmental factors are perceived by different parts of the plant. Photoperiod and irradiance are perceived mainly by mature leaves in intact plants. Temperature is perceived by all plant parts, although low temperature (vernalization) is often perceived mainly by the shoot apex. Water availability is perceived by the root system. There are strong interactions between these different factors, so that each factor can change the threshold value for the effectiveness of the others. Plants, as opportunists, will thus make use of a different critical factor in different environments. Melilotus officinalis, for example, is a biennial with a vernalization requirement in temperate zones and an annual long-day (LD) plant with no cold requirement in arctic regions. In photoperiodic species, such as the short-day (SD) plant Pharbitis nil and the LD plant Silene armeria, flowering in unfavorable photoperiods can be caused by changing temperature, irradiance, or nutrition or by removing the roots. Similarly, in some late-flowering mutants of Arabidopsis, vernalization and an increase in the proportion of far-red light in the light source can substitute for one another in promoting the transition to flowering (Martinez-Zapater and Somerville, 1990; Bagnall, 1992). Clearly, there are alternate pathways to flowering in most, if

A novel high efficiency, low maintenance, hydroponic system for synchronous growth and flowering of Arabidopsis thaliana.

BackgroundArabidopsis thaliana is now the model organism for genetic and molecular plant studies, but growing conditions may still impair the significance and reproducibility of the experimental strategies developed. Besides the use of phytotronic cabinets, controlling plant nutrition may be critical and could be achieved in hydroponics. The availability of such a system would also greatly facilitate studies dealing with root development. However, because of its small size and rosette growth habit, Arabidopsis is hardly grown in standard hydroponic devices and the systems described in the last years are still difficult to transpose at a large scale. Our aim was to design and optimize an up-scalable device that would be adaptable to any experimental conditions.ResultsAn hydroponic system was designed for Arabidopsis, which is based on two units: a seed-holder and a 1-L tank with its cover. The original agar-containing seed-holder allows the plants to grow from sowing to seed set, without transplanting step and with minimal waste. The optimum nitrate supply was determined for vegetative growth, and the flowering response to photoperiod and vernalization was characterized to show the feasibility and reproducibility of experiments extending over the whole life cycle. How this equipment allowed to overcome experimental problems is illustrated by the analysis of developmental effects of nitrate reductase deficiency in nia1nia2 mutants.ConclusionThe hydroponic device described in this paper allows to drive small and large scale cultures of homogeneously growing Arabidopsis plants. Its major advantages are its flexibility, easy handling, fast maintenance and low cost. It should be suitable for many experimental purposes.

The frequency of plasmodesmata increases early in the whole shoot apical meristem of Sinapis alba L. during floral transition

Abstract. The frequency of plasmodesmata increases in the shoot apical meristem of plants of Sinapis alba L. induced to flower by exposure to a single long day. This increase is observed within all cell layers (L1, L2, L3) as well as at the interfaces between these layers, and it occurs in both the central and peripheral zones of the shoot apical meristem. The extra plasmodesmata are formed only transiently, from 28 to 48 h after the start of the long day, and acropetally since they are detectable in L3 4 h before they are seen in L1 and L2. These observations indicate that (i) in the Sinapis shoot apical meristem at floral transition, there is an unfolding of a single field with increased plasmodesmatal connectivity, and (ii) this event is an early effect of the arrival at this meristem of the floral stimulus of leaf origin. Since (i) the wave of increased frequency of plasmodesmata is 12 h later than the wave of increased mitotic frequency (A. Jacqmard et al. 1998, Plant cell proliferation and its regulation in growth and development, pp. 67–78; Wiley), and (ii) the increase in frequency of plasmodesmata is observed in all cell walls, including in walls not deriving from recent divisions (periclinal walls separating the cell layers), it is concluded that the extra plasmodesmata seen at floral transition do not arise in the forming cell plate during mitosis and are thus of secondary origin.

Immunocytochemistry of pectins in shoot apical meristems: consequences for intercellular adhesion

Summary.The nature of pectins (acidic, methyl-, or acetyl-esterified) in the shoot meristem of Sinapis alba was assessed by immunocytochemistry with the 2F4 monoclonal antibody in light and electron microscopy. This antibody is specific for “egg-boxes” – the polygalacturonic acid conformation induced by calcium as described in Liners et al. (Plant Physiol. 99: 1099–1104, 1992). Hardly any acidic pectin was detected in meristem walls; the pectins were largely methyl-esterified and esterified by acetyl groups and/or other esters. After in situ chemical or enzymatic de-esterification, labeling was distributed over the primary wall and the middle lamella of meristematic cells. Acidic pectin and Ca2+-cross-linked homogalacturonans were absent from the pit fields, where plasmodesmata traverse the middle lamella. The type and distribution of pectins are discussed in relation to cellular adhesion between active meristem cells.

The shoot apical meristem of Sinapis alba L. expands its central symplasmic field during the floral transition.

Abstract. The shoot apical meristem (SAM) is functionally subdivided into zones with distinct tasks. During vegetative growth the peripheral zone of the meristem gives rise to leaf primordia that develop into dorsiventral leaves under the influence of signals from the central zone. During the floral transition the function of the SAM is altered and its peripheral zone starts to form floral structures in a specific pattern. This requires alterations in the signal networks that coordinate the activities of the peripheral and central zone of the SAM. These signal networks are partly housed in the symplasmic space of the SAM. Dye-coupling experiments demonstrate that in the superficial layer of the Sinapis alba meristem this space is radially subdivided. The cells of the central zone are coupled into a symplasmic field, which is shielded from the peripheral zone by the positional closing of plasmodesmata. In the vegetative meristems, most of these central symplasmic fields have a triangular geometry and are relatively small in size. Plants that are induced to flower by exposure to a single long day alter the geometry as well as the size of their central symplasmic field. After two subsequent days under short photoperiod the central symplasmic fields exhibit a circular form. Simultaneously, their size strongly increases both in an absolute sense and relative to the enlarging meristem. The geometric change in the fields is hypothesized to be due to recruitment of extra initial cells, required to support the increase in phyllotactic complexity. The proportional increase in field size is interpreted as an adjustment in the balance between the central and peripheral zone of the SAM, accompanying the shift from leaf production to flower formation.

Floral morphogenesis in Anagallis : scanning-electron-micrograph sequences from individual growing meristems before, during, and after the transition to flowering

Non-destructive scanning electron microscopy allows one to visualize changing patterns of individual cells during epidermal development in single meristems. Cell growth and division can be followed in parallel with morphogenesis. The method is applied here to the shoot apex of Anagallis arvensis L. before, during, and after floral transition. Phyllotaxis is decussate; photoperiodic induction of the plant leads to the production of a flower in the axil of each leaf. As seen from above, the recently formed oval vegetative dome is bounded on its slightly longer sides by creases of adjacent leaf bases. The rounded ends of the dome are bounded by connecting tissue, horizontal bands of node cells between the opposed leaf bases. The major growth axis runs parallel to the leaf bases. While slow-growing at the dome center, this axis extends at its periphery to form a new leaf above each band of connecting tissue. Connecting tissue then forms between the new leaves and a new dome is defined at 90° to the former. The growth axis then changes by 90°. This is the vegetative cycle. The first observed departure from vegetative growth is that the connecting tissue becomes longer relative to the leaf creases. Presumably because of this, the major growth axis does not change in the usual way. Extension on the dome continues between the older leaves until the axis typically buckles a second time, on each side, to form a second crease parallel to the new leaf-base crease. The tissue between these two creases becomes the flower primordium. The second crease also delimits the side of a new apical dome with the major axis and growth direction altered by 90°. During this inflorescence cycle the connecting tissue is relatively longer than before. Much activity is common to both cycles. It is concluded that the complex geometrical features of the inflorescence cycle may result from a change in a biophysical boundary condition involving dome geometry, rather than a comprehensive revision of apical morphogenesis.

Growth behavior of single epidermal cells during flower formation: Sequential scanning electron micrographs provide kinematic patterns for Anagallis.

A non-destructive method for scanning electron microscopy allows individual developing flower surfaces to be imaged sequentially. Kinematic analysis, the quantitative characterization of expansion behavior, can be applied to consecutive images of the same primordium. The individual cell, delimited as a polygon by its anticlinal walls, is the unit of analysis. Growth in two dimensions is characterized by a right-angle cross giving the maximal and minimal rates of extension relative to a known side of the cell. Methods have been developed here to make the analysis rapid and the results easy to portray. Data were obtained for the flower primordium of Anagallis arvensis L. from its origin as a smooth dome through the development of five small stamens and an incipient gynoecium. The outermost sepal whorl arises synchronously as a fivefold undulation. This maneuver is closely coupled to the formation of five stamen buttresses alternating with the small sepals (petals form later). The most characteristic kinematics occur as the stamen buttresses expand rapidly at their tips. The sides of the buttresses, and the regions between them, show highly directed extension following the five radii of the flower. These unique expansions are associated with the origin of the filament as a stalked structure and also correlate with the future bilateral symmetry of the anther. The region interior to the stamens grows slowly as circumferentially oriented anticlinal divisions initiate a radial cell-file pattern for the gynoecium. The developmental sequence has many features of “feed-forward” where the previous structure is important for the generation of structure to come (e.g. stamens alternate precisely with sepals). Some of these features fit plausible biomechanical explanations for morphogenesis.We wish to thank Mr. N. Rasmussen, Department of Biology, Stanford University, for providing Fig. 1A, B. Use of the SEM facility of Professor G. Goffinet, Institute of Zoology, University of Liège, is greatly appreciated. We thank Dr. R. Jacques, C.N.R.S., Le Phytotron, Gif-sur-Yvette, France, for providing the experimental material, and Mr. Philippe Ongena and Dr. Suresh Tiwari for expert photography. Support was from grants from the U.S. Department of Agriculture and National Science Foundation and as well as from the Fonds National de la Recherche Scientifique, Fonds de la Recherche Fondamentale et Collective and the “Action de Recherche Concertée” of Belgium.

RNA synthesis in the cells of the apical meristem of Sinapis alba during transition from the vegetative to the reproductive condition

SummaryVegetative plants of Sinapis alba, a long-day species, were induced to flower by exposure to a single 20-hr long day. RNA synthesis in the apical meristem of vegetative (control) and induced plants was investigated by using 3H-uridine and autoradiography of sections.Light-microscope autoradiographs showed a sharp increase in total RNA synthesis per cell in induced meristems. This increase occurred as early as 18 hr after the start of the long day, i.e. at the presumed time of the arrival of the floral stimulus at the meristem. At the same time, electron-microscope autoradiographs showed that there were changes in the pattern of RNA synthesis in the meristematic cells. The ratio of the number of grains in the nucleus to that in the cytoplasm slightly decreased and the ratio of the number of grains in the chromatin to that in the nucleolus greatly increased.Experiments with 2-thiouracil (2-TU), a pyrimidine analogue which was shown to inhibit RNA synthesis in Sinapis, indicated that this compound was most inhibitory to floral induction between the 12th and the 20th hour after the start of the long day, i.e. at the same time as important quantitative and qualitative changes in RNA synthesis were detected in induced meristems by autoradiographic methods. It was thus assumed that 2-TU inhibits floral induction via its effect on these (or on one of these) changes.