Abstract
Stem slices (1-mm thick) cut from apple microshoots were cultured on a modified Murashige-Skoog medium with indole-3-acetic acid (IAA) or α-naphthaleneacetic acid (NAA), and increasing concentrations of various phenolic compounds. Both auxins were added at a concentration suboptimal for rooting. Indole-3-acetic acid is metabolized through oxidation and conjugation but NAA through conjugation only; which might have affected the results. With IAA, all tested orthodiphenols, paradiphenols and triphenols promoted adventitious root formation from the stem slices. Ferulic acid (FA, a methylated orthodiphenol) had the largest effect and increased the number of adventitious roots from 0.9 to 5.8. With NAA there was little or no promotion after addition of phenolics. Phloroglucinol (a triphenol) and FA were examined in detail. Their effects on the dose–response curve of IAA and the timing of their action indicated that both acted as antioxidants protecting IAA from decarboxylation and the tissue from oxidative stress. Experiments with carboxyl-labelled IAA showed that IAA was massively decarboxylated by the slices and that decarboxylation was strongly reduced by phenolics. Decarboxylation was to a great extent attributable to the wound response and did not occur to such an extent in non-wounded plant tissues. In shoots, FA promoted little rooting. Slices were cultured on top of the medium and shoots were stuck into the medium. Possibly, the anaerobic conditions in the medium near the basal part of the stem of shoots reduced the wound response and consequently decarboxylation of IAA. The monophenolic compound salicylic acid (SA) promoted IAA decarboxylation. Accordingly, SA reduced rooting when added during the initial days of the rooting process (the period during which auxin enhances rooting), and promoted outgrowth of root primordia later on (the period during which auxin inhibits rooting).
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Introduction
A few years after the discovery of indole-3-acetic acid (IAA), Thimann and Went (1934) reported that this auxin promotes adventitious root formation. Today, auxin is still considered crucial to achieve rooting. Many researchers have reported that phenolics also enhance rooting. Phloroglucinol (PG, a triphenol) has been examined most intensively (Hammatt 1994). Wilson and Van Staden (1990) suggested that phenolics protect auxins from decarboxylation so that after application of phenolics more auxin is available to induce roots. The effectiveness of phenolic compounds depends among others on the number of OH-groups and on their position at the aromatic ring (Bandurski et al. 1995). In Eucalyptus gunnii (Curir et al. 1990) and in Chamaelaucium uncinatum (Curir et al. 1993), rooting ability is correlated with the presence of certain phenolic compounds suggesting that rooting depends on inhibition of decarboxylation of IAA. However, it is unlikely that decarboxylative catabolism of auxins plays a significant role in plants. Major arguments for this are that the compounds produced by decarboxylative oxidation of IAA occur in plants only at very low levels and that in transgenic plants overexpressing enzymes that oxidize IAA in vitro, the levels of IAA are not affected (Normanly 1997; Ljung et al. 2002).
Phenolic compounds have various roles in plants. Most importantly, they protect plants from oxidative stress (Jaleel et al. 2009). There are many examples of this. In genetically modified tobacco plants with a reduced level of phenolic acids, premature cell death occurs, presumably because phenolics protect cells from active oxygen species (Tamagnone et al. 1998). In Arabidopsis mutants with reduced phenolics, injury by ultraviolet-B and oxidative damage are enhanced (Landry et al. 1995). An Arabidopsis mutant tolerant of high ultraviolet-B contains high levels of phenolics (Bieza and Lois 2001). Phenolic compounds have also been linked with auxins in ways other than protecting them from oxidation. Flavonoids may also act as auxin transport inhibitors (Murphy et al. 2000; Peer and Murphy 2007). Flavonoids interact with PIN2 or affect the distribution of PIN proteins (Buer et al. 2010). To our knowledge, inhibition of IAA-decarboxylation by phenolics has not been examined in relation with adventitious root formation.
Rooting of apple microshoots has been examined intensively. In apple, during rooting three distinct steps may be distinguished on the basis of hormonal requirements: dedifferentiation (0–24 h), induction (24–96 h), and differentiation (from 96 h onwards) (De Klerk et al. 1995). To study the underlying mechanisms operating during adventitious root formation, a system has been developed consisting of 1-mm stem slices cut from microshoots produced in tissue culture (Van Der Krieken et al. 1993). A major advantage of slices is that interferences by other parts of the shoot do not occur. The present paper reports a major promotive effect of phenolic compounds on rooting of 1-mm slices.
Materials and methods
Plant material
Shoot production of Malus ‘Jork 9’ was carried out as described previously (De Klerk et al. 1995). Shoots were sub-cultured in tubes (2.2 × 15 cm) with 15 ml of an adapted Murashige-Skoog medium consisting of macro- and microelements according to Murashige and Skoog, vitamins of the N6 medium, 100 mg l−1 myo-inositol, 4.4 μM benzylaminopurine, 0.5 μM indolebutyric acid and 0.6% (w/v) agar (Becton and Dickinson granulated). After five weeks at 25°C and a 16 h photoperiod (35 μmol m−2 s−1 provided by cool white fluorescent lamps), tufts consisting of 5–10 shoots had been formed by axillary branching. The shoots were excised and used for experiments (shoots of 1.5–3 cm in length), for further shoot proliferation (shoots of 1–1.5 cm in length), or discarded (shoots of <1 cm in length).
The rooting experiments were carried out with 1-mm slices cut from stems and with intact excised shoots (shoots of 1.5–3 cm in length). The 1-mm slices were prepared as follows. From long shoots (2–3 cm in length) leaves and apex were removed and from the defoliated stems, 1-mm stem slices were cut (10 per stem) with a special device consisting of razor blades (Gillette) separated by 10 1 mm metal plates. Adjacent slices were distributed over several treatments because there exists a weak correlation between the ability to root of adjacent segments. There is no correlation between the ability to root of non-adjacent slices (De Klerk and Caillat 1994).
Rooting conditions
The rooting medium was a modified Murashige-Skoog medium with KNO3 and MgSO4 at half the standard concentration, 200 mg l−1 NH4NO3, 135 mg l−1 KH2PO4, 600 mg l−1 Ca(NO3)2·4H2O, 0.6% (w/v) agar (Becton and Dickinson granulated) and 3% (w/v) sucrose (De Klerk et al. 1995). CaCl2 was not added. The pH was adjusted to 5.5 before adding the agar.
The slices were cultured with the apical side down on a nylon mesh (4 × 4 cm) on top of 25 ml of rooting medium in a 9 cm Petri dish (30 slices per dish). The Petri dishes were incubated upside down in the dark in a culture room at 25°C. After five days, the slices were transferred to fresh rooting medium (without auxin and without phenolic compounds), and to the light (16 h photoperiod; 35 μmol m−2 s−1) unless indicated otherwise. For transfer from one medium to another, the nylon mesh with the slices attached was placed for 5 s on filter paper to remove excess liquid and then transferred to a Petri dish with the fresh medium. In the 24 h pulse treatments, the slices were transferred to fresh medium with the appropriate concentrations of auxin and phenolic compound. After 24 h pulsing the slices were transferred back to the original medium. Shoots were rooted in 2 cm high 9 cm Petri dishes with 35 ml of rooting medium. Each Petri dish contained 10 shoots. Roots were counted after 21 days under a dissecting microscope.
The phenolic compounds monophenols coumaric acid and salicylic acid (SA); the o-diphenols catechol, caffeic acid and chlorogenic acid; the m-diphenol chlororesorcinol; the methylated o-diphenols ferulic acid (FA) and vanillin; the triphenols gallic acid, phloroglucinol, pyrogallol and tannic acid were examined at a range of concentrations (3, 10, 30, 100, 300, 1,000, or 3,000 μM). Indole-3-acetic acid, NAA and the phenolic compounds were added after autoclaving.
Experiments with [1-14C]IAA
With the exception of the experiment shown in Table 2, the experiments were performed in 2 cm high 9 cm Petri dishes with 20 ml rooting medium containing 3 μM IAA per Petri dish and a tracer amount of 1 kBq [1-14C]IAA (Sigma, 1.48 × 106 kBq mmol−1) was added. The amounts of 14C in the explants and in the head space (14CO2 formed by decarboxylation of [1-14C]IAA) were measured. In the experiment shown in Table 2, the explants were cultured in 100 ml Erlenmeyer flasks at an orbital shaker (50 rpm) in 20 ml liquid rooting medium containing 10 μM IAA and a tracer amount of 1 kBq [1-14C]IAA.
To determine the amount of labelled compound in the explants, samples of three slices were taken at random and digested in 200 μl Soluene-350 (Packard) overnight at 40°C. Then 4.5 ml Hionic-Fluor (Packard) were added. Samples of three shoots were digested in 2 ml Soluene-350 and the amount of labelled compound/ion was determined in an aliquot (200 μl) by adding 4.5 ml Hionic-Fluor (Packard). 14CO2 in the headspace was trapped in 300 μl of 2 M KOH in a small vial with a piece of filter paper. To determine the trapped radioactivity, the KOH-solution and the filter paper were transferred to a counting vial and 4.5 ml Ultima Gold (Packard) were added. The amount of label was determined by a liquid scintillation counter.
Statistics
In the rooting experiments, each treatment consisted of three Petri dishes with 30 segments or 10 shoots. In the graphs and tables, the means of 90 slices or 30 shoots are given ± SE. Where no error bar is shown, it is smaller than the symbol. 14CO2 in the head space was determined in two Petri dishes and uptake in four samples of 3 slices/shoots, each taken from two Petri dishes/flasks. To test significance, the Student’s t-test was used.
Results
Effect of phenolic compounds on root formation on apple stem slices
The effect of several mono-, di- and triphenols was studied. From the diphenols, orthodiphenols, paradiphenols and methylated orthodiphenols were examined. The phenolics were added to rooting medium along with suboptimal concentrations of IAA (3 μM) or NAA (0.3 μM) (De Klerk et al. 1997). The main difference between NAA and IAA was that the latter is decarboxylated and the former is not (Lau et al. 1978; Smulders et al. 1990). For all phenolics dose–response curves were made. When IAA was used, most phenolics increased rooting (Table 1). The optimal concentration ranged from 3 μM to 1,000 μM. With NAA, rooting was far less promoted or inhibited. The monophenol SA reduced rooting both with IAA and NAA. When no auxin was added, no rooting occurred at any phenolic concentration. The highest promotion (from 0.9 ± 0.3 to 5.8 ± 0.3) was achieved with ferulic acid (FA, a methylated orthodiphenol).
The dose–response curves of FA and PG are shown in Fig. 1. The optimal concentrations of FA and PG were 300 and 1,000 μM, respectively. At the optimal concentration (300 μM), FA increased rooting with 0.3 μM NAA from 0.7 ± 0.2 to 2.1 ± 0.2 (P < 0.001). At the optimal concentration of PG (1,000 μM), rooting with 0.3 μM NAA was not significantly promoted (P = 0.09). The monophenol SA resulted only in inhibition. Inhibition was stronger with IAA than with NAA (Fig. 5b). Antioxidants such as ascorbic acid also promoted rooting when combined with IAA but the effect was less than that of FA (Table 1).
For a better understanding of the mode of action, FA and SA (300 and 30 μM, respectively) were added at a range of IAA concentrations (Fig. 2). The control without phenolics showed a typical bell-shaped dose–response curve with a peak at 30 μM IAA. Note that this bell-shaped curve is narrow (compare with the curve of shoots in Fig. 8). From Fig. 2a, several observations can be made about the dose–response curve in the presence of FA. (1) FA shifted the optimal auxin concentration to the left; the estimated IAA-optimums for IAA only, and IAA with FA were 30 μM, and 15 μM respectively. (2) FA widened the bell-shaped curve. (3) FA had a major effect at low IAA concentrations and no effect at high auxin concentrations. (4) FA increased the maximum number of roots. The effect of SA on the dose–response curve of IAA is shown in Fig. 2b. With SA, maximum rooting was reached at 100 μM instead of 30 μM IAA. SA had opposite effects depending on the IAA concentration. At 30 μM IAA, addition of SA reduced the number of adventitious roots from 6.3 ± 0.3 to 3.4 ± 0.3 and at 100 μM IAA (P < 0.001), a supra-optimal IAA concentration, addition of SA increased the number of roots from 3.6 ± 0.3 to 5.5 ± 0.3 (P < 0.001).
In the experiment shown in Fig. 3, it was examined whether the effects of FA and PG were additive. At 3 μM IAA, the number of roots was 0.6 in the absence and 3.5 in the presence of 300 μM PG. Increasing concentrations of FA were added to rooting medium with 3 μM IAA only and to rooting medium with both 3 μM IAA and 300 μM PG. At 300 μM FA, the number of roots reached a maximum of ca. 5.5 both with or without PG, showing that there was no additive effect between both compounds at the optimal FA concentration. A similar result was obtained at 1 μM IAA.
Effect of phenolics is influenced by the timing of application
Previously, it was shown that adventitious root formation can be divided into three consecutive phases (De Klerk et al. 1995). To study the effect of timing on the action of phenolics, 24 h pulse treatment was done using FA, PG or SA during the first 5 days of the rooting process. FA and PG pulses were applied at a sub-optimal IAA concentration (3 μM) and SA at the optimal IAA concentration (30 μM). The control treatments showed that transfer to fresh medium itself had no or little effect (<5%). Figure 4 shows that all three compounds had the strongest effect between 24 and 48 h, with FA and PG eliciting augmenting effect and SA an inhibitory effect. Pulses given on the other days had less effect. The period during which auxin has its maximum rhizogenic effect is on the 2nd–4th day (De Klerk et al. 1995).
Once the root primordia have been formed, after ca. 120 h (Jásik and De Klerk 1997), concentrations of auxin that are required for induction are inhibitory for outgrowth of the primordia (De Klerk et al. 1999). Therefore, the slices were routinely transferred after 5 days from medium with auxin and other plant growth regulators to medium with only inorganic and organic nutrients and vitamins. In the experiment shown in Fig. 5, the effect on the outgrowth of root primordia was examined. The IAA concentration optimal for root formation (30 μM) resulted in ca. 40% inhibition of rooting when applied during the outgrowth (differentiation) phase at 120–240 h. FA increased and SA reduced the inhibition of outgrowth by IAA and PG had no clear effect (Fig. 5a). The effects of SA and FA were statistically significant at all concentrations of IAA.
The contrasting effects of SA were examined in more detail. SA was added at increasing concentrations together with IAA or NAA either during the initial 5 days (0–120 h) or during the next 5 days (120–240 h) (Fig. 5b). When SA was given from 120 to 240 h, the slices had first been cultured from 0 to 120 h at 30 μM IAA to induce root primordia. SA inhibited rooting when added during the initial 5 days and inhibition was larger with IAA than with NAA. When given from 120 h to 240 h, SA promoted rooting when added together with IAA, but had almost no effect with NAA (Fig. 5b).
Oxidation of 14C-labelled IAA
Because phenolic compounds enhanced adventitious root formation with IAA and had little or no effect with NAA, they supposedly acted by inhibiting IAA-decarboxylation as suggested in several papers. This was examined by adding carboxyl-labelled IAA ([1-14C]IAA). In decarboxylative catabolism, the 14C-atom is removed from [1-14C]IAA as 14CO2 (Bandurski et al. 1995). The released 14CO2 can be captured with a KOH solution. In this way, the extent of decarboxylative catabolism can be monitored. Figure 6 shows that there were two main causes of decarboxylation. When the Petri dishes without plant tissue were kept in the light, massive decarboxylation of IAA occurred. Under conditions of a normal culture room, in a 9 cm Petri dish with 20 ml medium, close to 50% of IAA was decarboxylated after 24 h in the light. In the dark, decarboxylation of IAA occurred only when stem-slices were cultured on the medium. When increasing concentrations of IAA were applied, the amount of IAA taken up by the tissue and the amount of decarboxylated IAA were equal up to 10 μM IAA (data not shown). Uptake of IAA was linear with the concentration up to at least 100 μM, but relative IAA decarboxylation (decarboxylation as a percentage of the IAA in the medium) decreased with increasing IAA concentration (data not shown). Both photo-oxidation and decarboxylation by plant tissues were almost completely inhibited by FA (Fig. 6). All tested di- and tri-phenolic compounds had such effects (Table 1). The monophenol coumaric acid had hardly any effect and the monophenol SA promoted decarboxylation. The amount of 14C in the slices increased when decarboxylation was inhibited (Table 1).
The development of IAA-decarboxylation during culture was studied in more detail. Pulses (24 h) with 14C-IAA were given during the initial 5 days of the rooting treatment (Fig. 7) and the highest decarboxylation occurred during the first day. After that, decarboxylation decreased and at 96–120 h decarboxylation was about 30% of the initial intensity. The insert in Fig. 7 shows the results with 4 h pulses and demonstrates that decarboxylation peaked ca. 12 h after the start of culture. FA inhibited decarboxylation almost completely in all periods. Other phenolics had a similar effect (data not shown).
Effect of applied phenolic compounds on root-formation on shoots
Shoots were treated with increasing IAA concentration for the initial 5 days and after that transferred to the light and auxin-free medium. The optimal IAA concentration was 10 μM. The dose–response curve was bell-shaped and was far wider than the dose–response curve of slices (compare Fig. 2). When 300 μM FA was added together with IAA, the dose–response curve changed only slightly (Fig. 8). This was found in repeated experiments. PG, though, frequently increased rooting of shoots with ca. 50% but the results were not consistent (data not shown).
A major difference between shoots and slices is that the basal part of the stem of shoots from where the roots are formed is stuck into the semisolid medium, whereas the slices are on top of the semisolid medium. So, the tissue from where the roots regenerate is under aerobic conditions in the case of slices and under partial anaerobic conditions in the case of shoots. Therefore, the effect of FA was examined under anaerobic conditions. Slices were stuck into the semisolid medium, ca. 2 mm below the medium surface. The medium closed over the slices so that they were not in direct contact with the head space. Addition of 300 μM FA did not increase the number of roots (at 1 μM IAA 0.12 ± 0.08 per slice vs 0.22 ± 0.13 per slice). However, root formation was strongly inhibited under these conditions (2.0 ± 0.3 for slices on top of the medium), so the submerged condition may have been too adverse.
To determine decarboxylation by shoots, at first experiments were carried out on solid medium. This resulted in low decarboxylation rates but also in erratic results, supposedly because most decarboxylation occurred close to the cut surface which is 2–3 mm below the surface of the solid medium. Accidental factors, e.g., how far the stem is stuck into medium and whether the medium fits tightly around the stem or not, determine the flow of gases to and from the cut surface, and because of this the intensity of the wound reaction, the rate of IAA-decarboxylation, and 14CO2 flow to the head space. Therefore, the experiments were done in liquid medium (Table 2). Uptake by shoots was 10 times higher than by slices. The surface area of shoots (surface of stem, and leaves) is at least 50 times larger than the surface area of the 2-mm segments. Decarboxylation was ca. twice higher with segments than with shoots. This is consistent with the cut surface area (two cut surfaces in segments and one in shoots). Similarly, when segments from increasing length were examined (1–4 mm), uptake and decarboxylation were similar for all lengths (Table 2).
Discussion
Oxidative decarboxylation of auxins during adventitious root formation
When apple stem slices were cultured on medium with IAA, massive decarboxylative catabolism occurred (Table 1; Fig. 7). Shoots incubated in liquid medium showed less IAA-decarboxylation than 2-mm slices (1.0 nmol IAA shoot−1 day−1 vs. 2.3 nmol IAA slice−1 day−1), in spite of the higher IAA-uptake by shoots (7.8 nmol IAA shoot−1 day−1 vs. 0.8 nmol IAA slice−1 day−1). In this experiment, shoots and slices were cultured in liquid medium, so both cut surfaces of the slices were exposed to medium. Thus, decarboxylation by slices was related to two cut surfaces and decarboxylation by shoots to only one. If in both slices and shoots decarboxylation is ca. 1 nmol IAA per cut surface per day, our experiments indicate that in non-wounded tissue hardly any decarboxylation occurs. This is also reported by other authors (Ljung et al. 2002).
Chamarro et al. (2001) suggested that IAA decarboxylation is caused by a wound-induced increase of extracellular peroxidase activity and that decarboxylative catabolism unlikely plays a significant role in regulating auxin levels in plants. Preparation of cuttings involves wounding. It should be noted that auxin uptake via the epidermis is low and that most uptake is via the cut surface (Guan and De Klerk 2000), so via the area where the wound reaction is localized. Therefore, oxidative decarboxylation of auxin does play a major role in rooting of cuttings. The significance of decarboxylation during rooting is also shown by an increase of apoplastic peroxidase with high IAA-oxidase activity during rooting of Vitis microshoots (Vatulescu et al. 2004). In apple slices, peroxidase is released into the medium from the cut surface and there is no or only little release from the intact epidermis (Huisman and De Klerk, unp. results). The previously reported continuation of oxidative decarboxylation of IAA in the medium after the removal of apple stem slices (De Klerk et al. 2008) also indicates release of apoplastic IAA-oxidase from the slices into the medium. The relatively low uptake by shoots (uptake per surface area) corresponds with previous findings that uptake occurs predominantly via the cut surface (Guan and De Klerk 2000).
In the light, IAA is massively oxidized. Photochemical oxidation of IAA has been reported before (Yamakawa et al. 1979; Dunlap and Robacker 1988). It is very important that tissue culturists are aware of the instability of IAA in the light.
Phenolics influence rooting by reducing auxin decarboxylation
Various authors have reported that phenolics increase rooting. The present article reports that phenolic compounds increased rooting of stem slices, in particular in the presence of a sub-optimal concentration of IAA (Table 1). An increase was observed with ortho- and para-diphenols, methylated orthodiphenols and triphenols. It has been suggested that phenolics influence rooting by inhibiting IAA decarboxylation (Bandurski et al. 1995; Wilson and Van Staden 1990). Various results presented in this paper demonstrate protection of IAA by phenolics. (1) Phenolics strongly reduced the massive decarboxylation of IAA (Table 1). (2) Promotion of rooting was strongest with IAA and no or only little promotion occurred with NAA (Table 1; Fig. 1a). NAA is not decarboxylated and inactivated only by conjugation; IAA is both decarboxylated and conjugated (Lau et al. 1978; Smulders et al. 1990). (3) The optimal concentration of IAA was lowered by phenolics (Fig. 2a). (4) Addition of FA promoted rooting during the initial 5 days (the period during which auxin promotes rooting) (Fig. 1), but inhibited rooting when applied during the next 5 days (the period during which auxin inhibits rooting) (Fig. 5a). Protection from decarboxylation by phenolics has been reported previously (Lee 1980; Volpert et al. 1995). In the experiments with [1-14C]IAA, the highest decarboxylation occurred during the first day of culture (Fig. 7). The timing of the rhizogenic action of auxin is from 24 h to 96 h (De Klerk et al. 1995). These data explain the timing of the maximum effect of FA and PG at day 2. Thus, a major effect of phenolics is to protect IAA from decarboxylation brought about by the wound reaction.
It is remarkable that FA had a vast effect with slices but only little or no effect with shoots (Fig. 8). This was supposedly caused by the anaerobic conditions near the cut surface of the stem which is submerged in the agar (Chung and Ferl 1999). A low oxygen concentration inhibits the wound response (Butler et al. 1990; Geigenberger 2003). A similar effect of differences in gas exchange between the head space and the lower part of the stem and slices has previously been observed for the gaseous hormone ethylene. Silverthiosulphate (STS, an inhibitor of ethylene action) had a strong promotive effect with shoots and hardly any effect with slices. This was attributed to poor escape of ethylene from the basal end of the stem when the shoot was stuck into the medium, in contrast with the easy escape from slices that were on top of the medium. Therefore, ethylene may accumulate to an inhibitory concentration in the basal part of the stem that is surrounded by solid medium, but no such accumulation occurs in slices (De Klerk et al. 1999).
Many authors have reported PG to be effective with shoots but discrepant results have been reported (see introduction). This may be attributed to uncontrolled occurrence of the wound response by accidental factors, e.g., how far the shoots are stuck into the medium, and cracks in the solid medium. Both factors influence the gas exchange at the cut surface of the shoots.
Other effects of applied phenolics
When FA was applied, the level in the tissue increased from 0.58 nmol IAA equivalents to 0.80 nmol (Table 1). According to the dose–response curve for IAA (Fig. 2a), the expected increase of the number of roots is from 1.3 to 1.7. However, the number increased far more, viz., to 6.6 (Fig. 2a). Thus, the promotion of rooting by FA was far more than expected probably due to the increased content in the tissue. A similar discrepancy was observed for PG. There may be several causes for the unexpected high rooting after application of FA and PG. It might be that phenolics increased the amount of free IAA by inhibiting IAA conjugation or that the distribution of IAA in the tissue was altered by phenolics. The discrepancy may also be explained by effects that are not related to auxin: Various data indicate that phenolics have other promotive effects besides auxin-protection such as (1) When NAA was used, there was a small but significant increase in rooting for some phenolic compounds (Table 1). (2) PG and FA both increased the number of roots at optimal (30 μM) and PG also at supraoptimal (100 μM) IAA concentration (data not shown). (3) The phenolics widened the dose–response curve of IAA. The wound reaction and the rooting conditions may have had some effect on the tissue such that rooting was promoted by alleviating oxidative stress. Reduced regeneration due to oxidative stress has been reported by various authors (Tang et al. 2004; Gong et al. 2005).
It was mentioned before that FA and PG widened the dose–response curve of slices. The dose–response curve of slices is very narrow in comparison with shoots. The dose-reponse curve of 3 mm segments is considerably wider when compared with 1 mm slices (H Guan, unp. results). The narrow curve of 1 mm slices may be related to an intensive wound reaction, and to intensive oxidative stress. In the 1 mm slices, the oxidative stress is reduced by FA and PG resulting in a wider dose–response curve.
Type of phenolic compound and salicylic acid
The aromatic ring of phenolic compounds may carry one, two or three OH-groups. With more than one OH group, the position of the groups may differ. Thus, for diphenols there are meta-, para-, and ortho-diphenols. It has been reported that meta- and ortho-diphenols and polyphenols inhibit auxin decarboxylation (Bandurski et al. 1995). In our experiments, triphenols, o-diphenols and m-diphenols reduced IAA decarboxylation and promoted rooting with IAA (Table 1). Monophenols have been reported to act as cofactors of IAA-oxidase and because of that to enhance IAA decarboxylation (Bandurski et al. 1995). The monophenol coumaric acid had no such effect but salicylic acid (SA) increased IAA-decarboxylation (Table 1). SA shifted the dose–response curve of IAA to the right (Fig. 2b), had much less effect with NAA (Table 1), and reduced the inhibition by IAA when added during the outgrowth of the root primordia (NB, during this period IAA is inhibitory). Salicylic acid increases the production of active oxygen species (Chen et al. 1993). The timing (inhibition of rooting during the initial 5 days, especially from 24 to 48 h; reversal of inhibition by IAA after the meristems have been formed) and the direction of action (during the initial 5 days promotion at a supra-optimal IAA concentration and inhibition at the optimal IAA concentration) also correspond with enhancement of IAA decarboxylation.
Another major difference amongst phenolic compounds concerns their acid dissociation constant (pK a). The pK a determines uptake in cells. The pK a of PG is 9.2 (Mitsunaga et al. 2002) and the pK a of FA 4.4 (Poquet et al. 2008). Thus, PG likely penetrates more easily into the symplast. The wounding-related oxidative stress is localized in the apoplast (Blokhina et al. 2003; Kobayashi et al. 2006) and in the medium. Other oxidative stresses are located in the symplast, such as oxidative stress related to anaerobiosis (Blokhina et al. 2003). Reactive oxygen species (with the exception of H2O2) are charged and cannot penetrate biological membranes, hence local antioxidant protection is required and the effectiveness of applied antioxidants depends on uptake in the symplast. Preliminary experiments suggest that the timing of action of PG in shoots is almost exclusively during the first day of the rooting treatment (De Klerk and Ter Brugge, unp. results) before the time of action of auxin which is on the 2nd, 3rd and 4th day (De Klerk et al. 1995).
Conclusions
In conclusion, our data indicate that di- and polyphenolic compounds act as protective antioxidants. They protect IAA that would otherwise be destructed as a consequence of the wound response. Phenolics have an additional promotive effect by reducing the wound response that may inhibit regeneration processes. A wound response is inherent in preparation of cuttings. When the wound response is inhibited by anaerobic conditions, there is hardly any effect of phenolics. This explains the large effect of FA with slices (aerobic conditions) and the negligible effect in shoots (basal part of the stem under anaerobic conditions). The monophenol SA promoted IAA decarboxylation and the wound response. It has correspondingly a negative effect on rooting.
Abbreviations
- FA:
-
Ferulic acid
- IAA:
-
Indole-3-acetic acid
- NAA:
-
α-naphthaleneacetic acid
- PG:
-
Phloroglucinol
- SA:
-
Salicylic acid
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This research was partly financed by the Dutch Product Board for Horticulture (Productschap Tuinbouw).
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De Klerk, GJ., Guan, H., Huisman, P. et al. Effects of phenolic compounds on adventitious root formation and oxidative decarboxylation of applied indoleacetic acid in Malus ‘Jork 9’. Plant Growth Regul 63, 175–185 (2011). https://doi.org/10.1007/s10725-010-9555-9
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DOI: https://doi.org/10.1007/s10725-010-9555-9