Specific Inhibition of Lignification in Bryonia dioica: Effects on Thigmomorphogenesis

Rubbing-induced lignification in Bryonia dioica internodes is significantly impaired by N(o-hydroxyphenyl) and N(o-aminophenyl) sulfinamoyl tertiobutyl acetate, specific inhibitors of cinnamyl alcohol dehydrogenase, an enzyme which is strictly associated with lignin monomer synthesis. Along with the reduction of lignification, these inhibitors counteract the inhibition of elongation due to rubbing. These results indicate that lignification participates in the thigmomorphogenetic growth response of Bryonia dioica internodes. In a general way, the data point to the causal role of lignification in the limitation of plant growth.     

Carry-over of thigmomorphogenetic characteristics in calli derived fromBryonia dioica internodes

Calli have been initiated in vitro from young internodes (control and rubbed) ofBryonia dioica, where previously it had been shown, using intact plants, that rubbing induced limited growth through enhanced lignification. Calli derived from rubbed internodes were somewhat more compact and showed biochemical changes, i.e. enhanced activity of total peroxidase and isoperoxidases, enhanced production of 1-aminocyclopropane-1-carboxylic acid (ACC) and ethylene, enhanced tissue capacity to convert ACC into ethylene, enhanced activity of phenylalanine ammonia-lyase (PAL) and higher content of lignin, which characterized rubbed internodes. Differences in ethylene metabolism between the two types of calli tended to fade from the third week onwards of initial culture, whereas lignin content, peroxidase activity and peroxidase isoenzyme pattern appeared to be more persistant rubbing-induced markers for several subcultures. The results point to the persistance of environmentally induced changes in gene expression.     

Thigmomorphogenesis inBryonia dioica: Changes in soluble and wall peroxidases,phenylalanine ammonia-lyase activity,cellulose, lignin content and monomeric constituents

Rubbing young internodes ofBryonia dioica results in a reduced elongation and an increased diameter of the internodes. In the present study activities of some enzymes involved in the lignification process and levels of lignification were compared in rubbed and non-rubbed internodes. Rubbing caused an increase in the activities of phenylalanine ammonia-lyase and soluble and ionically- and covalently-bound cell wall peroxidases. Sensitivity of the covalently-bound wall peroxidase assay was markedly increased if syringaldazine was used as a substrate. Mechanical perturbation induced an increase in lignin, lignin monomer (sinapylic, coniferylic and p-coumarylic alcohols) content and the number of lignifying vessels. Conversely, rubbing resulted in a decrease in cellulose content. The hypothetical interpretation of the thigmomorphogenetic response through cell wall lignification and hence rigidification is consistent with all the presented results. A comparison is possible between this accelerated lignification and induced lignification as a mechanism of disease resistance. the thigmomorphogenetic response inBryonia dioica can be considered as a mechanism of resistance in order to withstand further environmental mechanical perturbation.Research partly supported by the Belgian FRFC grant 2.9009 to T.G. and by the French CNRS (LA 45, RCP 474).     

Cobalt inhibition of thigmomorphogenesis in Bryonia dioica: possible role and mechanism of ethylene production

Rubbing-induced inhibition of elongation in Bryonia dioica was completely prevented by 10⁻⁷ M cobalt chloride. Cellular redistribution of peroxidases, mainly characterized by transiently enhanced membrane-binding of soluble peroxidases, occurred as an immediate consequence of rubbing and was not inhibited by Co²⁺. Ethylene synthesis and 1-aminocyclopropane-1-carboxylic acid (ACC) conversion readily increased upon rubbing and fell soon afterwards, but ACC conversion then increased again progressively. Co²⁺ did not drastically counteract these changes, except for the second rise in ACC conversion which was completely eliminated. The rubbing-induced rise in ethyiene production and ACC conversion was closely correlated to microsomal ACC conversion and peroxidase activity, but only during the first hours after rubbing. The presented approach enables us to correlate stress-induced ethylene production to membrane-binding of peroxidases. It is suggested that ACC conversion in Bryonia dioica is triggered by two different, sequentially ordered mechanisms. The difference in the effects of Co²⁺ on elongation and ethylene production is discussed with respect to the role of ethylene in thigmomorphogensis.     

Reponses a des signaux mecaniques: Communications inter et intracellulaires chez les vegetaux

In their environment, plants are continuously submitted to natural stimuli such as wind, rain, temperature changes, wounding, etc. These signals induce a cascade of events which lead to metabolic and morphogenetic responses.In this paper the different steps are described and discussed starting from the reception of the signal by a plant organ to the final morphogenetic response. In our laboratory two plants are studied: Bryonia dioica for which rubbing the internode results in reduced elongation and enhanced radial expansion (Boyer et al., 1979) and Bidens pilosa for which the response occurs at distance, hence pricking the cotyledon of a plantlet induces the growth inhibition of both the hypocotyl (Desbiez et al., 1981) and the axillary bud of the pricked cotyledon (Desbiez, 1973). Reception of the signal and transmission of the message. In Bryonia the signal is received by epidermal cells (Boyer & De Jaegher, 1986) while in Bidens they are the cells adjacent to the midrib of the cotyledon which receive the mechanical signal. In both plants the message is transmitted via a wave of electric depolarization (De Jaegher & Boyer, 1989; Desbiez, 1973; Frachisse et al., 1985b). This latter is composed of an action potential associated with a slow wave whose transmission rates are respectively 1cm s^–1 and 1 mm s^–1. Recent results have shown the involvement of Ca²⁺ in the triggering of the slow wave and the role of the H⁺ pump during the slow wave. Transient and fast biochemical responses. An entry of extraceilular Ca²⁺ into the cells and a transient increase in IP³ occur within seconds following the mechanical stimulus. At the same time, the membrane becomes more fluid, correlated with qualitative changes in phospholipids. The rapid increase in the concentration of peroxidated lipids may be correlated with ethylene biosynthesis which is stimulated after rubbing (Crouzillat et al., 1985; De Jaegher et al., 1987a).Other parameters such as cytoplasmic pH, relative water content, hydric potential, membrane potential and modifications of K⁺, Mg²⁺-ATPase and Ca²⁺-ATPase activities, play a key role in the early responses induced by the traumatisms. Irreversible-biochemical responses. The mechanical stimulus performed on a Bryonia internode induces an acceleration of: i) enzymatic activities related to the lignification (PAL and cell wall peroxydases), ii) esterification of phenolic acids in the cell wall. Consequently the lignification process is accelerated. Storage of the information. After being received by the target cells (axillary bud of hypocotyl) the information can be stored during several days before being expressed. At the level of cotyledonary bud, the first message, previously stored, can be expressed or not by a second treatment (symmetrical prickings, cold temperature ...). Bidens thus behaves as if it was able to store and to retrieve morphogenetic messages, using a sort of rudimentary memory. The nuclei of the bud cells of the pricked cotyledon show that these cells, initially in G₂ phase, divide and then remain in the G₁ phase.In Bryonia, calli derived from young stimulated internodes, keep thigmomorphogenetic characteristics during several weeks (high peroxidase and PAL activity, modified isoperoxidase pattern, high content in ACC and lignine).In the last part of this paper the particularity of our plant model which permits a study of the transmission and storage of the message, is underlined. The links between the different steps induced by the stimulus are discussed. Special attention is devoted to second messengers and to the amplification of the message.     

Error-proneness as a handicap signal

This paper describes two discrete signalling models in which the error-proneness of signals can serve as a handicap signal. In the first model, the direct handicap of sending a high-quality signal is not large enough to assure that a low-quality signaller will not send it. However, if the receiver sometimes mistakes a high-quality signal for a low-quality one, then there is an indirect handicap to sending a high-quality signal. The total handicap of sending such a signal may then still be such that a low-quality signaller would not want to send it. In the second model, there is no direct handicap of sending signals, so that nothing would seem to stop a signaller from always sending a high-quality signal. However, the receiver sometimes fails to detect signals, and this causes an indirect handicap of sending a high-quality signal that still stops the low-quality signaller of sending such a signal. The conditions for honesty are that the probability of an error of detection is higher for a high-quality than for a low-quality signal, and that the signaller who does not detect a signal adopts a response that is bad to the signaller. In both our models, we thus obtain the result that signal accuracy should not lie above a certain level in order for honest signalling to be possible. Moreover, we show that the maximal accuracy that can be achieved is higher the lower the degree of conflict between signaller and receiver. As well, we show that it is the conditions for honest signalling that may be constraining signal accuracy, rather than the signaller trying to make honest signals as effective as possible given receiver psychology, or the signaller adapting the accuracy of honest signals depending on his interests.