Apical photoception: A^aC model.

In cases where perception of light is found to be purely apical, the previous dependency, equation 4, is expressed as A(L, t)−A_P. The photosensitivity corresponding to the inclination of the apex in relation to the light beam is translated into a secondary signal, propagated basipetally along the organ through asymmetric polar transport of the plant hormone auxin [10]. As auxin transport is faster than the characteristic time of the movement, this long-distance signaling along the organ can be approximated as instantaneous, so that, at any position s, a small segment of the organ is submitted to a signal proportional to A(L, t)−A_P (SI). Indeed, it can be shown that the propagation of the signal has only slight effects on the dynamics and the steady state of the organ, as long as the characteristic time of propagation (the time for the signal to go from the apex to the base) is smaller than the characteristic time of movement (given by the elongation rate [25]) (SI). The perceived signal is thus the value at the apex, A(L, t), and this is the only value accessible along the organ.

Let us now assume for a moment that the light is zenithal, A_P = 0, so that the phototropic reaction tends to bring the tip to the vertical.

The conditions of symmetry described in [2] are then fulfilled. The behavior remains the same, according to the change A(s, t) → −A(s, t) and then C(s, t) → −C(s, t).

According to hypotheses H1–4, in the case of zero gravity or zero graviception (agravitropic mutants), the most basic linear equation for an apical perception can then be formulated as (5) where νA(L, t) is the apical photoceptive term, readily transmitted all along the organ, and γ C(s, t) is the proprioceptive term. This will be referred to as the apical photo-proprioceptive model, or the A^aC model, with ^a expressing the apical perception of the stimulus (see Table 1). As noted, this model assumes that the transmission is instantaneous. Every part of the organ is able at any point to perceive the exact orientation of the apex. It is also assumed that the transmission is homogenous along the coleoptile, meaning that ν is not dependent on the position s (see SI).

Now let us assume the following initial conditions: a straight but tilted organ and the boundary conditions of perfect basal clamping: (6) It is easy to see that the A^aC model is in fact independent of space coordinate s. First, the organ is initially straight, so the initial curvature is the same everywhere. Then as the perception of the light is purely apical, at any given time all parts of the organ receive the same signal, proportional to the apical orientation at that time. The variation of curvature, and hence the curvature, are the same at any point of the organ. The solution of the A^a model is then given by (7) (8)

It is possible to define a dimensionless number D, the photoproprioceptive number, that expresses the ratio between photoception and proprioception: (9)

Local photoception: AC model.

If the perception of light is set to be local (as observed, for example, in Arabidopsis hypocotyls), equation 5 should be modified to the local photoceptive equation (10) with the same initial conditions as described in equation 6. Equation 11, which describes the photoceptive model, is now strictly equivalent to the graviproprioceptive equation 1, i.e., the AC model [2].

Local perception: A_RC model.

When the organ lies in the plane defined by the direction of gravity and of light, the local equation of purely local photogravitropism, called the local photo-gravi-proprioceptive equation, is given by (11) The two external tropisms act in the same way through perception of the local angle, except for the constant angle A_P, indicating the direction of phototropism.

Simple variable substitution can be performed to simplify equation 12: (12) where A_R is a Resultant Angle linked to the balance of the two tropic factors through combined gravi- and photo-ception (13) Equation 12 can be rewritten in a more compact form (14) with no constant term. Starting with the set of initial conditions defined in equation 6, the initial conditions to be considered are then (15)

The variable substitutions and calculations shown above are equivalent to the case in which the plant has been rotated at an angle A_R, such that the two tropisms then act together in the same direction. The local photo-gravi-proprioceptive equation 15 can thus be named the A_RC model.

Another dimensionless number M, called the photograviceptive number, can then be defined as the ratio between the gravisensitivity and the photosensitivity: (16) Note that M is not independent from the graviproprioceptive number B and the photoproprioceptive number D but instead can be expressed as (17)

Apical photoception: $A_R^{a}C$ model.

In the case in which the perception of light is apical, the equation that describes this apical-photo/local-gravi-proprioception-driven movement, called the $A_R^{a}C$ model, is given by (18) Using the variable substitutions shown in equation 13, the dynamical equation 19 can be simplified to (19) This equation converges to a steady-state shape that is described as (20) (21)

Apical photoception and light intensity in the A_RC model.

The sensitivity of the outputs of the photo-gravi-proprioceptive models A_RC and $A_R^{a}C$ can vary as a function of the photoceptive, graviceptive or proprioceptive sensitivities (captured in the dimensionless ratios D, B, and M). Variations in these sensitivities could be due, for example, to natural or artificial genetic variations within or across species, such as those reported by [2] for B. However, the photograviceptive number, M, may also depend on a current environmental factor, namely, the intensity of the light I (in addition to the angle with the incident light direction A_p). Many studies have indeed reported that the light fluence rate (irradiance) I influences the rate and strength of the phototropic reaction (e.g [17, 34]). It is thus expected that the photoceptive term ν in our model, and therefore the photograviceptive number M, should be a function of I, the fluence rate of the incident light beam. For example, [34] proposed a biochemical model of photoception in which the rate constant of the primary photosensitive reaction is proportional to the fluence rate I reaching the photosensitive tissues. The situation may be even more complex, as there have been reports of a “tonic” effect of light intensity on gravisensitivity (acting through other photoreceptors besides phototropins) [8]. Therefore, in cases in which the intensity of the incident light is subject to change, it seems that at least the photograviceptive number M should depend on the intensity of the incident light. Clearly, however, this dependence has yet to be quantitatively and experimentally elucidated. Several forms for the intensity dependency has been proposed in the literature but there are no clear theoretical or empirical reasons for choosing one specific formulation over another. The photobiology literature has classically assumed that this relation is given by the linear relation between the stimulus and the plant’s response, the Bunsen-Roscoe reciprocity law [35–37]. However, this law seems to be valid for only a small range of light dosage levels. The Schwarzschild law (a power-law generalization of the reciprocity law) appears to more accurately describe the relationship between the response and the intensity of the light stimuli, for a wide range of materials and systems [38] and has been found to be a fairly generic approximation, where the Bunsen-Roscoe reciprocity law can be seen as a special case of the power law. Galland [17] used a logarithm relation to express the relation between the observed PGEA and the intensity of the light, but [17] does not fully assess or discuss whether the assumption of a logarithmic relation is indeed preferable to the use of a power law.

The lack of an unequivocal formulation of the dependency on the intensity of the signal is also reflected in the broader domain of sensory biology, where two competing general models of the relation between sensation and stimuli from sensory biology are considered. The first is the Weber-Fechner Law [39], which postulates that the intensity of the response is proportional to the logarithm of the stimulus. The second is Stevens’ law, which postulates a power law relationship between the stimulus and the sensation [40]. Although these relations have been assessed primarily in the domain of human behavior, quantitative similarities in sensing relations between animals and plants have been identified [22]. The question of which model better describes the effect of the intensity of the stimulus (in our case light) thus remains open, and the adoption of a given law seems to be mostly dependent on the context and on the conventions of the discipline. Therefore, in what follows, we will consider the two types of formulations (log or power law) in the following and will subsequently compare them using experimental data.

We may now extend the photograviproprioceptive model by incorporating a new working hypothesis stating that

(H5) the photograviceptive number M is a function of the fluence rate of the incident light, i.e., (22)

This yields light-intensity-dependent photo-gravi-proprioceptive models A_R(I)C and $A_R^a(I)C$. The function Φ can be expressed either by a power law (23) or by logarithmic relation (24)

Lateral light experiments with Wheat coleoptile (LLE experiment).

In order to asses the effect of lateral light on vertical organs, experiments were conducted on 12 etiolated wheat coleoptiles (Recital). Wheat seeds were grown in in vermiculite in the dark at 23°C until their size reached at least 2cm (approximatively 72h). In order to avoid effects of already curved coleoptiles, the straightest coleoptiles were selected for the experiment. The coleoptiles were then displayed in front of a camera (Nikon DS5200) with a source of blue light (LED VAOL-5701SBY4-ND collimated with a parabolic mirror RCphotonics) perpendicular to the vertical. Timelapse were taken every five minutes for 24h.

Galland experiments.

Galland carried out a detailed quantitative study of the relationship between the PGEA (equation 2) and the fluence rate I in light-grown Avena coleoptiles under continuous light [17], hence contrary to our experiment the detailed kinematics were not reported. In these experiments, the coleoptiles were tilted at different angles from the vertical while the tip of each coleoptile was illuminated orthogonally and in the plane of bending at different fluence rates. The experiments comprised 15 replicates. Data have been reprocessed from [17]. Two experimental protocols were used, called PROT1 and PROT2 here.

PROT1 The coleoptiles were tilted at different initial angles A₀, while the light was always maintained perpendicular to the initial orientation of the organ, A_P = A₀ + π/2. The dependency of the PGEA on the fluence rate of the incident light I was then assessed by varying I at each value of the initial angle A₀. PGEA can be plotted as a function of I for the different values of A₀ (and the corresponding A_P = A₀ + π/2).

PROT2 The position of the PGEA was also measured for different values of A₀, where A_P = A₀ + π/2. However, the fluence rate of the incident light I was tuned experimentally so that the angle of the straight organ was immediately steadied at A_R = A₀ stated in terms of the A_RC model,. This provides an estimate of the value of I(A_R = A₀) at photogravitropic equilibrium. The results of both protocols can be used to independently assess the $A_R^a(I)C$ model.

The data produced in [17] according to the two protocols have been reprocessed. Linear orthogonal fit was carried out in a log-log plot and in a semi-log plot. A straight line in a log-log plot (as in Fig. 2.A) would reflect a power law, whereas a linear fit in a semi-log plot (as in Fig. 2.B) would reflect a logarithmic relation.

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Figure 2. A. −1 + A_P/A_R as a function of the fluence rate of the light.

Data are reprocessed from Figs. 4, 5 and 6 in [17] Solid lines correspond to the fit $log(-1+\frac{A_P}{A_R})=a^{\prime }+b^{\prime }\log (I)$. An etiolated Avena coleoptile is tilted from the vertical for different values of the angle A₀ (0, 10, 30, 90 and 120) while a light beam is collimated on the tip of the coleoptile. For different fluence rates, controlled by a neutral density filter, the apical angle is measured after variable duration. This is said to be the equilibrium angle. B. −1 + A_P/A_R as a function of the fluence rate of the light; data are reprocessed from Figs. 4, 5 and 6 of [17]. Solid lines correspond to the fit $-1+\frac{A_p}{A_R}=a^{\prime }+b^{\prime }\log (I)$. C. −1 + A_p/A_R as a function of the fluence rate of the light; data are reprocessed from Figure 8 in in [17]. The solid lines correspond to the fits from A. The empty black symbols (circles and squares) correspond to the measured fluence rates that precisely compensate the gravitropic reaction. The equilibrium state then corresponds to the case in which no movement is observed and A_R = A₀. Empty circles: A₀<90°; empty squares: A₀>90°. D. A_p/A_R as a function of the fluence rate of the light. Solid lines correspond to the fits from A.

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Apical photoception: A^aC model.

When photoception is only apical (the A^aC model; equation 7), the curvature is constant along the organ (no dependency on s), so the shape of the organ is an arc of a circle (Fig. 5.A). This can be understood as the organ trying to bring the apical part towards the vertical with an identical driving signal everywhere. Finally, at the steady state, the curvature is also constant along the organ so that the orientation A(s) changes linearly from the base to the tip, where it reaches the vertical (Fig. 5.B). The solution of equation 7 depends only on the photoproprioceptive number D and on the propriosensitivity γ, but in a contrasted way.

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Figure 5. A. Straightening dynamics of the A_aC model (D = 4).

At each time the shape is an arc of circle. B. Steady-state shape of the A^aC model. The shape is an arc of circle. As photoception dominates over proprioception, D increases (from blue to red); the apical angle reorients in the direction of the light field vector.

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The apical angle of the steady state of the A^a model is given by (27) and the curvature of the steady state is simply defined by (28)

The apical angle and the curvature at the steady state are thus direct indicators of the ratio D between photoception and proprioception. When the photoceptive term dominates over the proprioceptive term (D → ∞), the apical angle tends to approach the direction of the light (Fig. 5.B). In sharp contrast to what was found for gravitropism [2], when apical perception is involved, proprioception is not necessary to reach a steady state. If γ = 0, the movement stops when the apical part is parallel to the direction of the light. Consequently (and concurrently), all parts of the organ near the base also cease to curve. Proprioception only modifies the maximal curvature that the system can reach. When proprioception increases (i.e., D decreases) the apical angle at steady state no longer reaches the vertical. In any case, however, the apical perception shapes the organ as an arc of a circle.

Considering now the transient dynamics before convergence to the steady state, the characteristic time at which the apical part of the organ reaches the vertical is given by (29) Note that this characteristic time depends on both the proprioceptive and the photoceptive terms. This differs from the case in the AC model [2], in which, due to the purely local control, the characteristic time depends only on the proprioceptive term. The inclusion of a non-local photoceptive term thus makes the organ converge to its steady state faster than in the case of purely local perception. Also in contrast to the case of gravitropic movement [2], the dynamics of phototropic movement, governed by photoception and proprioception, cannot not be fully described by a unique dimensionless number, such as in this case D.

Local photoception: Back to the AC model.

In the case in which light perception is local, the photoproprioceptive model takes the form of an AC model (equation 11). The dynamics and the steady- state shape are thus fully described by the dimensionless number, in this case D, alone. The salient features of the movement can then be summarized as follows: i) Initially the whole part of the plant that responds to the stimuli starts curving; ii) then, the curvature concentrates near the base while the apical part straightens; and iii) the number of oscillations around the vertical before convergence to the steady state increases with D. The dimensionless number D also reflects the ratio between the length of the organ and the length of the curved zone at steady state, in a strict analogy with what was found for the dimensionless number B in the AC model for gravitropism [2]. And in this case proprioception is necessary to avoid infinite oscillations and reach a steady state.

Having established a clear understanding of the behavior under the sole influence of either phototropism or gravitropism [2], we can now discuss the interaction between phototropism and gravitropism.

Local photoception: the A_RC model.

The dynamics of the A_RC model (equation 15), where graviception and photoception both occur locally, is strictly equivalent to the dynamics of the graviproprioceptiveAC model [2]. It is thus controlled by a unique dimensionless number. This dimensionless number drives the shape of the steady state (for example, the length L_c over which the organ is curved at steady state), as well as the number of transient oscillations before the steady state is reached. But there are some differences between the two models: the dimensionless number, denoted B^′, that drives the full dynamics of the A_RC model is a composition of the graviproprioceptive number $B=\frac{\beta L}{\gamma }$ and of the photoproprioceptive number D (30) As D ≥ 0, the dimensionless number B^′ is larger than the graviproprioceptive number B, B^′ ≥ B. The convergence length L_c is then modified (31) This involves quantitative differences in the dynamics of the A_RC model compared to that of the graviproprioceptive AC model. As B^′ is larger than B (D ≥ 0), the tropic movement driven by the local photograviproprioceptive A_RC model (equation 12) exhibits more transient oscillations than does the graviproprioceptive tropic movement driven by the AC model (for the same B), as well a smaller convergence length L_c.

In this case we can demonstrate that the tip is converging to the resultant photogravitropic angle A_R. Indeed, according to equation 15, the apical angle of the steady state of the A_RC model is given by (32) (33) In the absence of light, D = 0, if the apical part of the organ reaches the vertical, A(L, t → ∞) ∼ 0, it is expected that e^−B ∼ 0. As the length of convergence is smaller when phototropism and gravitropism interact than in the gravitropic case, B+D>B, the term e^{−(B + D)} can therefore be neglected (34)

Just as for B in the gravitropism case [2], it then becomes possible to design a simple morphometric estimate of M (the ratio between photoception and graviception at the current incident light intensity) for a plant organ with local and distributed gravisensitivity and photosensitivity, such as the Arabidopsis hypocotyl. The measurement of the apical angle of the steady state provides a simple way to directly measure A_R and the ratio between photoception and graviception M can then be readily estimated using equation 27.

Apical photoception: $A_R^{a}C$ model.

The $A_R^{a}C$ model (equation 19), in which photoception is apical and graviception is local (as in the case of grass coleoptiles), is now explored. The steady-state shape of the $A_R^{a}C$ model is given by equation 21. The left term inside the brackets of the steady-state shape defined by A^′(s, t → ∞) (equation 21) is the steady-state shape of the graviproprioceptive solution, the AC model, alone (35) whereas the right term can be considered as a corrective term resulting from the interaction between photoception and graviception. (36)

This $A_R^{a}C$ model shares some properties with the A_RC model. The perceptions of light and gravity act together to bring the system in the direction A_R, which results from the combination of the two different tropisms. But unlike the empirical equation for the photogravitropic equilibrium PGEA assumed by [17] (equation 2), the angle A_R defined through the equation 26 does not depend on the addition of the two stimuli but on the ratio between the two sensitivities, the photograviceptive number M. The length of the curved zone, L_c, depends only on the graviproprioceptive term B, $L_c=\frac{\gamma }{\beta }=\frac{L}{B}$. However, in contrast to the case in which graviception is dominated by proprioception, L_c → ∞, the curvature is not necessarily equal to 0 (see equation 22) and depends on the value of the photograviceptive number M.

Finally, it is still possible to design a simple morphometric estimate of A_R, of the ratio between photosensitivity and gravisensitivity M and of the ratio between gravisensitivity and propriosensitivity B. But this now requires the combination of two experiments, one in the light, and one in the dark. As in the A_RC model, the measurement of the apical angle of the steady state in a photogravitropic experiment provides a simple way to directly measure A_R (this will be further investigated when studying the limit cases of the $A_R^{a}C$ model in the next section). B can then be estimated independently using a gravitropic tilting experiment in the dark on the same organ (as in [2]). Finally the ratio between photosensitivity and gravisensitivity M can be calculated using the steady-state (equation 21) at s = L.

Limit cases and sensitivity analysis of the $A_R^{a}C$ model.

The behavior of the $A_R^{a}C$ model is complex. To obtain a better understanding of it, in this section we explore the limit cases. The model’s dynamics can be described using only B, the ratio between graviception and proprioception, and M, the ratio between photoception and graviception. Therefore only four different limit cases are to be considered: B → ∞, B → 0, M → ∞, M → 0. In what follows we characterize each case. Moreover, starting from each given limit case, we gather insights regarding the control dynamics by varying one of the dimensional numbers. This essentially constitutes an analysis of sensitivity of the output of the photo-gravi-proprioceptive model at steady state to changes in its dimensionless control parameters B and M.

i) B → ∞. Graviception dominates proprioception. This case has already been shown to be a non-physiological case [2]. Indeed, in this case there is no steady state. The organ cannot converge to the vertical and oscillates indefinitely, displaying no tropism.

ii) B → 0. Proprioception dominates graviception. A_R is given by the direction of the light A_R = A_P. The final shape is then given by (37) This is the solution of the A^aC model, equation 3.

Starting from this limit case of pure photoproprioceptive equilibrium, it is now useful to consider the changes of the steady-states of the photograviproprioceptive model that occur when the graviproprioceptive number B is increased from 0 while the photoproprioceptive number D is maintained at a constant value (Fig. 6.A). This corresponds to increasing the gravisensitivity β relative to the photosensitivity ν, and hence to increasing the photograviceptive number M. As this change first affects the graviproprioceptive part of the $A_R^{a}C$ model, the changes in steady state of the graviproprioceptive AC model with increasing B are also plotted for comparison (dashed lines in Fig. 6.A). Starting from the arc-shaped solution of the photoproprioceptive A^aC model, increasing B (and M) for a constant D brings the photo-gravi-proprioceptive model into steady states in which the apical part orients toward the changing A_R (see insert in Fig. 6.A), whereas the curved zone becomes more and more concentrated at the base. Note also that the solution for the photo-gravi-proprioceptive $A_R^{a}C$ model is no longer equivalent to a rotation of the graviproprioceptive AC model toward A_R, but it is striking that the alignment of the apical part toward A_R is maintained and actually increases with B.

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Figure 6. A. Steady-state shape of the $A_R^{a}C$ model for D = 4.

The black line is the solution when B = 0. As B increases (solid colored line from red to blue), the orientation and the shape of the organ is modified. The dashed line shows the steady-state shape of the graviceptive equation. The expected orientation of the organ A_R is shown at the bottom. B. Steady-state shape of the $A_R^{a}C$ model for B = 4. The black line is the solution when D = 0. As D increases (solid colored line from red to blue), the organ’s orientation and shape are modified. The dashed line shows the steady-state shape of the photoceptive equation, A^aC model. The expected orientation of the organ A_R is shown at the bottom.

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iii) M → ∞. Graviception dominates photoception. For a given graviproprioceptive ratio B, this also means a very low photoproprioceptive number D, i.e., D → 0. The direction of the expected orientation is the direction of gravity, A_R = 0. It follows easily that the steady state is given by: (38) This is the solution of the graviproprioceptive equation, the AC model, equation 1.

We may now study the effect of increasing photosensitivity, i.e., increasing the photo-graviceptive number D and, by necessity, decreasing the photograviceptive number M (Fig. 6.B) for a constant value of B. As this change is first affecting the photoproprioceptive part of the model, the changes in the steady state of the photoproprioceptive A^aC model with increasing D are also plotted for comparison (dashed lines in Fig. 6.B). When increasing D (and decreasing M) at constant B, changes in the steady-state shapes of the photo-gravi-proprioceptive $A_R^{a}C$ model are driven by changes in A_R (Fig. 6.B). However, the solution never converges toward the photoproprioceptive solution of the A^a C model. The orientation of the stem changes as D changes, but the length of the curved zone remains the same (as B is fixed). Even if graviception and photoception contribute equally towards orienting the apical part, they play different roles in the control of the global shape of the organ.

iv) M → 0. Photoception dominates graviception. In this case, the expected orientation is driven simply by the direction of the light, A_R = A_P. The steady-state shape is then given by (39) (40) It should be noted that, for any B that is not equal to zero, this solution is not the photo-proprioceptive A^aC model but rather is a modification of the graviproprioceptive AC model (compare the plain line and the dashed lines in Fig. 6.B, especially for high values of D; green and blue-colored curves). The photoception sets the apical angle (41) but the global shape is just a perturbation of the graviproprioceptive shape of the AC model. So even if photoception dominates over graviception, if the graviception does not tending towards B = 0, the distribution of the curvature in the steady state is still clearly determined by graviception and proprioception and thus by B.

The complete mechanism of control over the steady-state shape in the case of photogravitropism can now be summarized. The orientation of the apical part is determined by the ratio between graviception and photoception, the photograviceptive number M, whereas the length of the curved zone is determined only by the ratio between graviception and proprioception, the dimensionless number B. This can be illustrated clearly by considering the case in which the two tropisms act in the same direction (A_P = 0, Fig. 7.A). As in previous examples, the initial condition is D = 0 (pure graviproprioceptive steady state) but with a lower value of B (so that proprioception prevents the tip from aligning in the direction of gravity). In these conditions, decreasing the value of M (by increasing D for a constant B) modifies the apical angle toward the vertical (phototropism reinforces gravitropism in this case), but the length of the curved zone remains unchanged (being determined solely by the graviproprioceptive process, and thus by the value of B).

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Figure 7. A. Steady-state shape of the $A_R^{a}C$ model for B = 2.

The solid black line is the solution when D = 0; the dashed line is the solution when D → ∞ and B = 0. As M increases (from red to blue), the organ’s orientation and shape are modified. B. Straightening dynamics of the $A_R^{a}C$ model (B = 2 D = 20). The solid black line is the solution when D = 0; the dashed line is the solution when D → ∞ and B = 0. During the movement, the organ reaches the steady state of the photoceptive equation but then goes to the steady state of the gravi-photo-proprioceptive equation. C. Space-time mapping of the curvature C(s, t) during straightening.

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It is possible to use a similar analysis procedure to investigate the dynamics of movement within the $A_R^{a}C$ model, before convergence to the steady state (i.e. shape of the transients and time to converge to a steady state).. The first cases are straightforward.

i) B → ∞ Graviception dominates proprioception. The organ never reaches the vertical [2].

ii) B → 0 Proprioception dominates graviception. The dynamics are described by apical phototropism alone, i.e. the dynamics of the A^aC model, as described in the corresponding section (Fig. 5).

iii) M → ∞ Graviception dominates photoception. The dynamics of the $A_R^{a}C$ model are equivalent to the dynamics of the graviproprioceptive AC model as described in [2]. Briefly, for higher values of B (i.e., greater dominance of graviception over proprioception), the transients are more contorted, and the organ oscillates for a longer time around the steady state before converging.

iv) M → 0 Photoception dominates graviception. This case must be discussed more carefully. In this case, the two processes, graviception and photoception, act as dominant drivers at two different time scales. In the photo-gravi-proprioceptive $A_R^{a}C$ model, photosensitivity has a faster effect than gravisensitivity does. This can be illustrated clearly by considering again the case in which the two tropisms act in the same direction (A_P = 0, Fig. 7.B). The model predicts that the organ will bend faster towards the light in order to bring the apical part to the direction of the light, and to reach the steady-state shape of the photoproprioceptive equation. Then, the graviproprioceptive process takes over. The curvature concentrates near the base while the apical part remains oriented in the direction of A_P (Fig. 7.B and C). This behavior can be compared to the experiments of the Fig. 3. First, the whole coleoptile is curving and the apical tip reaches an angle bigger the angle at steady state. Then the curvature concentrates near the base as the apical straightens. Similarities between the theoritical behavior and the experimental behavior are then observed. However due in part to the specific dynamics of the coleoptile and the inner leaf, it seems difficult to discuss further away the similarities and disparities between experiments and theory.