Abstract
Synchronized tissue polarization during regeneration or de novo vascular tissue formation is a plant-specific example of intercellular communication and coordinated development. According to the canalization hypothesis, the plant hormone auxin serves as polarizing signal that mediates directional channel formation underlying the spatio-temporal vasculature patterning. A necessary part of canalization is a positive feedback between auxin signaling and polarity of the intercellular auxin flow. The cellular and molecular mechanisms of this process are still poorly understood, not the least, because of a lack of a suitable model system. We show that the main genetic model plant, Arabidopsis (Arabidopsis thaliana) can be used to study the canalization during vascular cambium regeneration and new vasculature formation. We monitored localized auxin responses, directional auxin-transport channels formation and establishment of new vascular cambium polarity during regenerative processes after stem wounding. The increased auxin response above and around the wound preceded the formation of PIN1 auxin transporter-marked channels from the primarily homogenous tissue and the transient, gradual changes in PIN1 localization preceded the polarity of newly formed vascular tissue. Thus, Arabidopsis is a useful model for studies of coordinated tissue polarization and vasculature formation after wounding allowing for genetic and mechanistic dissection of the canalization hypothesis.
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Introduction
Development and patterning of vascular tissue require signaling and directional flow of the plant hormone auxin1,2,3. Two models to explain the pattern of vessel formation have been proposed. One model is based on the reaction-diffusion hypothesis4 and the other, the so-called canalization hypothesis, proposes a directional auxin flow as the main signal for vascular tissue development5,6.
The auxin flow direction has been shown to depend on the asymmetric position of the PIN-FORMED (PIN) auxin transporters at the plasma membranes of transporting cells7,8,9,10,11,12,13,14. Development of many plant organs, such as lateral roots or cotyledons, is strictly correlated with the establishment of local PIN-dependent auxin gradients that precede cell divisions and differentiation processes15. The constitutive recycling of PIN proteins from and to the plasma membranes that involves clathrin-dependent endocytosis16 allows dynamic changes in PIN localization and increased stabilization of PIN proteins at the plasma membrane in response to auxin17,18. Changes in PIN localization and tissue polarity in response to auxin that are presumably related to the directional vascular tissue patterning have been observed and modelled1,2,3,19,20. For example, when the auxin flow direction is interrupted (i.e. by wounding), the subcellular position of PIN proteins changes and the cell polarity is established de novo gradually concentrating the auxin flow for the formation of new auxin channels2,3. The auxin-dependent canalization is supported experimentally by studies on leaf vein patterning and on the role of the genes encoding the auxin response factor MONOPTEROS (MP) and the auxin transport protein PIN121. Both genes undergo the dynamic expression and subcellular positioning of PIN1 transporters that gradually change from nonpolar to polar, indicating the auxin flow direction during the vascular patterning21.
Vascular tissue disruption in experimental systems leads to regeneration processes. In nonwoody dicotyledonous plants, vasculature is regenerated in the wound neighborhood of primary tissues2,3,5,6,22. New vessels are arranged around the wound according to the presumable new auxin flow direction or form either the so-called bypass strands directly through the wound22 or bridges between the neighboring vascular bundles23. For decades, analysis of vascular pattern reconstruction from incised vascular cambium during its regeneration was restricted to trees and plants with well-developed secondary tissue architecture and thick cambium24,25,26. Thus far, cambium and its activity were analyzed mainly in trees27,28,29,30 and the results revealed an important role for cambium in secondary xylem formation and thickening of woody plants in the nondisturbed development. Because of the difficulties in using woody plants as a model system31, mechanisms of cambium regeneration are still poorly understood. However, in trees, vascular tissue regenerates very fast in the wounded areas and this process is accompanied by the development of enlarge amounts of callus, numerous shortening anticlinal divisions of cambial cells and intrusive growth32,33. Thus, following the canalization concept, regenerated vessels organized with threads of short cells above or around the wound34,35, support the emergence of auxin channels according to the new auxin transport direction in incised regions. In some instances, e.g. after wounding, the so-called circular vessels develop36,37,38. Circular vessels occur in the form of rings and are presumably induced as a consequence of the circular auxin flow route and the establishment of the circular polarity of individual cells that dedifferentiated into this type of vessels36. Accordingly, circular vessels develop as a response of individual cells to the auxin flux rather than to the local auxin concentration.
Thus far, studies on vascular cambium regeneration and accompanying changes in auxin distribution, flow directionality and cellular polarity of PIN transporters have been hampered by the inability to induce and follow these processes in Arabidopsis (Arabidopsis thaliana), making it impossible to use large collections of genetic material available for this model. Nonetheless, artificial weights applied to the apical parts of immature inflorescence stems of Arabidopsis (stems with primary tissue architecture) increase the basipetal auxin transport, stimulate stem growth and promote secondary growth in basal parts of these stems39. Secondary tissue architecture in mechanically stimulated immature inflorescence stems of Arabidopsis develops in a very short time, namely 3 days39 or 6 days40, which is much faster than in hypocotyls41,42,43 or mature inflorescence stems44,45,46,47,48. Therefore, decapitation of floral parts and weight application not only allow performing the experiments on much younger plants, but also to analyzing processes of vasculature regeneration with the whole complexity of the “tree-like” tissues40,49, hence, giving the opportunity to answer still open questions on the auxin-mediated canalization hypothesis in models with secondary growth and functional cambium.
Here, we induced wounding in Arabidopsis inflorescence stems with active cylinder of vascular cambium and analyzed the correlations between auxin distribution, tissue polarization and formation of PIN1-mediated auxin channels during vascular tissue regeneration.
Results
Histological analysis of vascular tissue regeneration after wounding
Plants were grown under special conditions, according to the method previously described39 and modified40 (Fig. 1a). An artificial weight (2.5 g) was applied to immature stems with decapitated apical parts (Fig. 1a). Axillary buds above the leaf rosette were not removed (Fig. 1a) and were a source of endogenous auxin (see also Supplementary Figs S1 and S4). The basal parts of the weight-applied stems were cut transversally to interrupt the longitudinal continuum of vascular cambium and secondary tissues, necessary to analyze the vasculature regeneration in wounded areas (Fig. 1b).
The secondary growth in weight applied stems of Arabidopsis has been described previously in detail40, therefore we present here the transition from primary to secondary tissue architecture (Fig. 2a,b) only as an introduction to events observed during vasculature regeneration. The applied weight triggered dedifferentiation of interfascicular parenchyma cells in sectors localized between the vascular bundles and their periclinal divisions (Fig. 2a). Finally, the vascular cambium developed into a closed ring on the stem circumference and produced secondary vascular tissues (Fig. 2b). Thus, 6 days after the weight application, secondary tissue architecture was observed in the basal parts of the previously immature Arabidopsis stems. Almost 90% of all analyzed stems were characterized by such a tissue arrangement (Fig. 2c).
As controls for the weight-applied stems, mature inflorescence stems (>25 cm tall) were also analyzed (Supplementary Fig. S2). Such plants were obtained in more than 2 months, showed secondary growth in narrow sectors of the basal parts (2 to maximum 3 mm thick), but fully closed ring of vascular cambium occurred in approximately 50% of the mature stems. Thus, in many of the old stems (more than 40%), secondary growth was fragmented, i.e. no secondary tissues developed on the whole stem circumference. Various cambial phenotypes, such as rays and intrusively grown fusiform cambial cell, were not found. Hence, for all experiments, we used young stems with applied weights.
Histological analysis of both nonincised controls and wounded stems revealed significant differences in vessels organization (Fig. 2d,g). A series of semi-thin sections were examined to get an idea about the vessel strand arrangements, but only one representative section was selected as illustration. In unwounded controls, vessels were organized in vertical strands parallel to the longitudinal stem axis and reflected the arrangement of cambial cells (Fig. 2d). Open perforations were localized at the opposite (apical-to-basal) ends of the neighboring cells that connected with each other in conductive strands (Fig. 2d). The developed vessels were always adjacent to other tracheary elements and emerged as cells with relatively enlarge lumen and thick secondary cell walls (Fig. 2d).
In wounded stems of Arabidopsis, the regenerated vessels were much shorter (Fig. 2e–g) than those developed in unwounded controls. Statistical analysis revealed that regenerated vessels were almost two-fold shorter than normal vessels in controls (45 μm versus 109 μm average cell length) (Fig. 2f). As a consequence, the regenerated vessels were arranged in threads of short elements that either circumvented the wound (Fig. 2e) or developed above the wound (Fig. 2g). In the latter case, the vessel arrangement was more or less parallel to the cut, but not parallel to the main stem axis. In the regenerated vessels, the perforations were localized mainly on the lateral cell walls and connected individual cells in vessel strands (Fig. 2e,g).
An interesting regeneration manner was observed in deeply wounded stems, few days after wound (DAW), in which the so-called circular vessels developed (Fig. 2h). In the case of the circular vessels, lateral openings were observed that closed into a ring (Fig. 2h).
The histological analysis revealed different ways of the vascular cambium regeneration and the gradual vasculature reconstruction in wounded Arabidopsis stems (Fig. 2i).
Vascular tissue regeneration monitored by AtHB8 expression
As the AtHB8 gene is known as a vessel formation marker50,51, its expression was analyzed to follow cambium regeneration and formation of new vasculature. The AtHB8::GUS transgenic line in Wassilevskija (Ws) background50 was used. High AtHB8 gene expression was found in the wounded stem regions (Fig. 3a–c). Primarily, the AtHB8::GUS signal was observed in small areas above a wound, 1 day after incision (Fig. 3a) and gradually extended in next 2 days. On day 4 after the transversal cut, the expression of the marker gene was very high in enlarged regions above and around the wound (Fig. 3b). Sometimes, new vasculature developed forming characteristic “bypass” vessel strands, directly through the wounding (Fig. 3c). These “bypass” vessels differentiated from callus cells inside the wound between 10 to 13 days after the incision. Analysis of semi-thin sections confirmed, as expected, the AtHB8 expression in the regenerating vasculature (Fig. 3d–f). The β-glucuronidase (GUS) signal was higher in differentiating vessels than in the surrounding cells (Fig. 3d–f). The regeneration process was clearly visible starting from day 4 after the cut. New vessels developed both above (Fig. 3e) and around the wound (Fig. 3f). Regenerated vessel elements were sometimes very short (Fig. 3f). Ring-arranged vessels, called circular vessels, developed also adjacent to the incision edge (Fig. 3f). Fully reconstructed vascular tissue was found at later regeneration stages, beginning from day 6 after wounding.
DR5-monitored local auxin response during vascular tissue regeneration
Overall changes in auxin responses after wounding were analyzed in the DR5::GUS transgenic line52 and the GUS expression was followed day by day from day 1 to 12. First, we attempted to analyze auxin responses in wounded areas on transversal sections (Supplementary Fig. S3), that were made around the wound/regenerated vasculature areas. Three and 4 days after incision, auxin responses were observed in almost all wounded tissues (even in cortex and epidermis), but they were poorly recognizable in the nearest neighborhood of the wounds and, thus, vasculature regeneration could hardly be identified in this sectioning plane. In contrast, the longitudinal sections were very informative and revealed that the DR5-monitored auxin responses were not uniform in the wounded areas. The most important changes were observed in the first 4 days (Fig. 4a–d). During the first 24 h after wounding (transversal cut), DR5::GUS was expressed both above and below the cut (Fig. 4a). However, during the next 48 h, the auxin response became restricted, with the highest signal in the regions that extended along the upper edge of the transversal cut and increased afterward (Fig. 4b,c). Thus, starting from day 3 after wounding, the highest auxin response was detected not only above, but importantly, also around the cut (Fig. 4d). Moreover, during this period, DR5 activity and elevated auxin responses did not occur in tissues below the cut (Fig. 4d).
Next, we looked more closely at the DR5 signal in cells during vascular tissue formation. Analysis of semi-thin sections revealed vascular tissue regeneration at different positions around the wound. Vasculature often regenerated above the upper wound edge, in the middle parts of the transversal cut (Fig. 4e, inset). In these areas, the auxin response was the highest and the new auxin channels developed not along the longitudinal stem axis, but approximately parallel to the cut (Fig. 4e).
A presumptive regeneration path indicated by the GUS expression was also observed around the wound, in areas generally marked by the elevated auxin response (Fig. 4f, inset). The top and bottom sectors of emerged channels were parallel to the longitudinal stem axis, but their middle parts developed around the wound, circumventing the transversal cut edge (Fig. 4f).
New vessels developed also in deeply incised stems, in places immediately above the wound (Fig. 4g,h). In such areas, the local DR5 auxin response was always very high (Fig. 5g, inset). Regenerated vasculature was organized in groups of vessel-like cells, surrounded by DR5-positive neighbors (Fig. 4g,h, magnification). Connected vascular strands were never observed in this situation, the cells were often very short and shapeless (Fig. 4g,h), but still had some features characteristic for vessels, such as secondary cell walls and open perforations between neighboring cells (Fig. 4h). Small cell groups (2 or 3 cells) induced for circular vessel development could be recognized (Fig. 4i,j). In such cells, the DR5::GUS reporter activity was elevated and intrusive end growth was commonly recognized as very characteristic (Fig. 4i). Because of the typical morphological features, shape and length of these DR5-positive cells and position within the tissues, these cells could be inferred to represent an early stage of the circular vessel development (Fig. 4i). In days 3 and 4 after wounding, first mature circular vessels were recognized (Fig. 4j) that were organized in closed rings and openings localized on lateral cell walls of individual cells connecting them with each other (Fig. 4j).
Emergence of PIN1-mediated auxin channels and PIN1 polarity rearrangement
Analysis of vascular tissue regeneration implied changes in tissue polarity and creation of channels with elevated auxin response. To support these observations, we analyzed the cellular and tissue localizations of the PIN auxin transport proteins by means of anti-PIN1 antibodies. We observed significant differences in the cellular localization of PIN1 in nonwounded controls when compared to wounded inflorescence stems. In the controls, PIN1 was localized polarly in the vascular cambium, strictly at the basal plasma membranes of the cambial cells (Fig. 5a), whereas in the wounded stems, the PIN1 position changed gradually in tissues above and around the wound (Fig. 5b–d). At early regeneration stage (day 1 after wounding), PIN1 occurred primarily in an enlarged expression zone above the wound basically, in all cells predicted to form the auxin channels, but with an undefined polarity at this stage (Fig. 5b). Later on, the polar localization of PIN1 was gradually established and became restricted to the narrow strands corresponding to the new PIN1-expressing auxin transport channels in the regenerated areas (Fig. 5c,d). Thus, starting from day 2 and next after incision, PIN1 transiently moved from basal to lateral plasma membranes of the cells in emerged auxin channels that were either parallel to the cut (Fig. 5c) or around the wound, circumventing the cuts (Fig. 5d). Interestingly, in the close vicinity to the incision, the cellular position of PIN1 was often still undefined, namely the PIN proteins were localized both on lateral and basal plasma cell membranes (Fig. 5d). Figure 5e,f visualize tissue organization in Fig. 5c,d, respectively.
Changes in auxin response and auxin transport were also analyzed in vivo, in wounded stems of the Arabidopsis transgenic lines pPIN1::PIN1:GFP15 and DR5::GFP9. Tissue polarity changed rapidly around a wound (Fig. 5g–j). As monitored by the PIN1-GFP, new positions of PIN1 were gradually established in first 2 DAW. The originally undefined PIN1 localization at the plasma membrane of the wound-surrounding cells (Fig. 5g,h) gradually shifted to the lateral plasma membranes, starting from day 2 after wounding (Fig. 5i,j). DR5-GFP analysis revealed dynamic changes in auxin response around the incised regions of Arabidopsis stems (Fig. 5k–n). New DR5-positive auxin channels emerged 3 DAW and developed in regions above and around the wound (Fig. 5k,l). Threads of GFP-positive cells were also observed in outer tissues above the wound, in the vicinity of the forming callus (Fig. 5k,l). Moreover, groups of unorganized vessels regenerated from outer tissues and callus were well visible and developed above the wound (Fig. 5k). Completely regenerated vessel strands were found 4 DAW (Fig. 5m) and later on, positive auxin-responsive channels emerged along and parallel just regenerated vessel strands (Fig. 5n). Thus, reconstructed vasculature extended in the next few days after incision.
Characteristics of the circular vessel formation after wounding
Circular vessels occurred, in the regions above and in the immediate vicinity of the transversal cut. The emergence of the circular vessels in wounded Arabidopsis stems enabled us to assess their characterization by features typical for vessels and the polarity of individual cells that differentiated into circular vessels. Our observations showed that mature circular vessels differentiated from vascular cambium and that they consisted of 2 or 3 single cells connected with each other by lateral openings mostly localized on the lateral cell walls (Fig. 6a–c). However, neighboring groups of circular vessels did not connect with each other (Fig. 6a). Secondary cell walls were also detected in mature circular vessels (Fig. 6c). Interestingly, in analyzed Arabidopsis stems, growth was commonly intrusive in differentiating circular vessels and surrounding neighbors (Fig. 6a–c).
Single vessel cells that formed circular vessels seemed much shorter than those found in controls. Therefore, the average length of the circular vessels in wounded stems and normal (longitudinal) vessels in unwounded controls was also analyzed and compared (Fig. 6d). The length of vessels differed significantly: longitudinal, control vessels were more than twice as long as the circular vessels (109 μm and 47 μm average cell length, respectively). Over 90% of the circular or ring-formed vessels found in Arabidopsis were arranged as two and few as three individual cells dedifferentiated into vessel elements (Fig. 6e).
In the circular vessels, the PIN1 localization rearranged in an unprecedented way (Fig. 6f,g). At early stages of the circular vessel development (days 1 and 2 after wounding), PIN1 localized apolarly in differentiating cells, i.e. on their apical and lateral plasma membranes (Fig. 6f). At later stages (days 3 and 4 after wounding), the polar PIN1 localization was established (Fig. 6g) and PIN1 became restricted to the lateral plasma membranes. Intriguingly, the PIN1 signal was always observed in two distinct places at the plasma membranes, separated from each other and, moreover, each belonging to the other neighboring cell that differentiated into the circular vessel (Fig. 6g, magnifications).
Discussion
De novo formation and regeneration of vascular tissues are instances of intercellular communication and coordinated tissue repolarization during developmental processes. More than 30 years ago, the canalization hypothesis had been proposed postulating the crucial role of the plant hormone auxin in these processes5,6. According to this hypothesis, position and patterning of new vasculature are established by the positive feedback between the auxin capacity and its flow directionality, leading to the establishment of canalized auxin channels. The exact molecular and cellular mechanisms underlying this feedback and emergence of polarized transport channels from the homogenous tissues are far from clarified. Regeneration of vasculature in response to wounding can best be studied in woody plants with active cylinders of vascular cambium and well developed secondary tissues32. However, studies in trees are limited because of the many experimental difficulties31. Thus, analysis of vascular tissue regeneration has been extended to the nonwoody dicotyledonous plants with primary tissue architecture, such as bean (Phaseolus vulgaris) or pea (Pisum sativum)2,3,5,6.
The major herbaceous model plant Arabidopsis is a well established model system for many molecular and genetic studies, including vascular development and secondary xylem formation31,53,54,55, because it can undergo secondary growth in hypocotyls42,43 and in inflorescence stems44,45,46,47,48. However, lack of some typical characteristics, such as cambial phenotypes, lack of secondary rays and variety of tracheary elements did not allow to employ Arabidopsis as a small “tree” with all vasculature features. Therefore, Arabidopsis could not be used to study some developmental processes that are characteristic to wood formation in trees and could not be regarded as a suitable model for research on the mechanisms of vascular cambium regeneration, vasculature reconstruction and development of new vessels predicted by canalization/polarization concepts. Although the regeneration process in Arabidopsis has been analyzed tentatively22,56, it had never been studied in Arabidopsis stems with an active cylinder of vascular cambium and secondary tissue architecture analogous to the situation in trees. The use of Arabidopsis as a suitable model for vascular tissue and vascular cambium regenerations is, to our knowledge, possible only with a method introduced and described previously39. As described, an artificial weight (2.5 g) applied to the apical parts of immature inflorescence stems of Arabidopsis promotes secondary growth in the basal stem parts39. Thus, with this protocol we obtained stems with closed vascular cambium rings and all main features mimicking secondary growth in trees40,49. Furthermore, we show that analysis of vascular cambium regeneration, strictly correlated with new vasculature reconstruction, is also possible in wounded Arabidopsis stems, recommending Arabidopsis as a good model system to study coordinated tissue polarization during auxin canalization and tissue regeneration.
Auxin is regarded as a primary signal that induces vascularization via promotion auxin channel formation. The canalization hypothesis-predicted behavior is observed during de novo formation and regeneration of vasculature, especially of new regenerated vessels after incision, i.e. wounding or grafting2,3,5,6,35,56. However, the feedback mechanism between auxin and its flow and the vessel formation as a response to concentration gradients or directional auxin fluxes remains unclear57. Our results from Arabidopsis stems suggest successive changes in auxin response in wounded areas and sequences of cellular events accompanying the regeneration process in cambium.The locally elevated auxin response occurred already a few hours after wounding and gradually increased in these places. After a few days, a high auxin response appeared to mark the alternative way of the auxin flow to circumvent the wound. A presumptive new path of auxin flow was well visible in the auxin channels, namely cells with elevated auxin responses and subsequently differentiating into vessel elements. This observation fits very well with predictions from the canalization hypothesis, i.e. that auxin channels during regeneration canalize the auxin flow and have very high auxin levels5,6.
Originally, the feedback between auxin and its flow had been proposed to be realized by an auxin effect on the polar, subcellular localization of the PIN auxin transport proteins that, in turn, determine the auxin flow directionality2,13,14. Thus, auxin channel emergence can be visualized via rearrangements of the cellular position of PIN proteins. Indeed, in auxin-treated Arabidopsis roots, in wounded pea stems, or locally auxin-supplemented pea stems, the PIN polarity was rearranged in the two latter cases, marking the position of future vessel strands2,3. In wounded Arabidopsis stems with fully developed ring of vascular cambium, we also observed gradual changes in the PIN1 position, reflecting repolarization and de novo establishment of this tissue polarity in wounded areas. Initially, PIN1 was expressed in cells around the wound whereafter auxin channels emerged and was localized less polarly at the plasma membranes. PIN1 expression became increasingly stronger and more focus, when more defined auxin channels began to emerge. In a few days, the subcellular PIN1 position was gradually stabilized and restricted only to cell sides along the presumable direction of the auxin flow. Probably, this polarized PIN1 position marked the prospective perforation plates in fully regenerated vessels.
The impact of auxin on the polar PIN1 positioning might be part of a mechanism for auxin-regulated canalization19, possibly requiring local auxin accumulation that would trigger the TIR1-mediated Aux/IAA-ARF signaling pathway58,59 for both PIN expression and PIN polarity2,60. Another aspect of the auxin effect on the PIN polarity may be connected to the action of the Auxin-Binding Protein1 (ABP1) or related proteins. ABP1 is classified as an auxin receptor of which its action has at least in part been proposed to reside in the apoplast20 and that is required for polarization of puzzle-shaped epidermis cells61 and has an auxin effect on clathrin-mediated PIN internalization17,18 and on PIN polarity in root meristems20. However, recently, the originally reported embryo lethality of the abp1 mutants has been shown to be due to mutations in the neighboring gene, necessitating additional analyses of the loss-of-function abp1 phenotypes62. Clarifying contributions of the different auxin perception mechanisms and other molecular canalization components are now within reach by means of the extensive collection of mutant, transgenic and marker lines in Arabidopsis.
In the course of our research on regeneration and canalization, we observed the interesting phenomenon of the so-called circular vessels that form isolated islands of differentiated vessel-like cells, indicative of small vortexes of circular auxin flow. Development of the circular vessels has been described previously36,37,38,63,64. Some features of the circular vessels, such as secondary cell walls and perforations63, resemble those of normal vessels. The occurrence of two perforation plates at the lateral side of the circular vessels supports their development through the auxin flow63, but the lateral openings could also be enlarged bordered pits developed between neighboring cells during their differentiation into circular vessels. Bordered pit fields have previously been referred to tracheary elements in trees65,66 and their development between adjacent cells is probably connected with local changes in cell wall composition, such as simultaneous dissolution and deposition of wall material65. The position of bordered pits during tracheid differentiation can be regulated by auxin and by its local accumulation in places of pit development66. Circular vessel development can be interpreted as the result of a circular auxin flow that establishes a circular polarity in (de)differentiating cells36. This intriguing scenario is supported by the asymmetric PIN1 localization in the differentiating circular vessels in Arabidopsis. PIN1 can be found at atypical positions in distinct, isolated patches at the plasma membranes of neighboring cells and such localization is in accordance with the suggested circular auxin flow and circular polarity of these cells. Thus, although these so-called circular vessels are often regarded as the out-of-function tracheary elements38, they might be spectacular examples of canalization that can be used to better understand (re)polarization processes. It remains entirely unclear by which mechanisms just a few (2 or maximum 3) cells are selected into the circular vessels for (de)differentiation, but this process involves obviously elevated auxin responses and atypical positions of the PIN1 auxin transporters.
Here we show that Arabidopsis comes out as a suitable model system for the analysis of vascular cambium regeneration that typically occurs in trees and provides the possibility to study this spectacular example of coordinated tissue differentiation and repolarization (Fig. 7). This process is accompanied with temporal and spatial events following new vessels development: (i) increase in local auxin responses in tissues above and around the wound; (ii) emergence of auxin channels marked by elevated auxin responses; (iii) tissue repolarization and de novo establishment of new polarity through the changed position of the PIN1 auxin transporters at plasma membranes of differentiating cells; (iv) development of new vessel strands along and around the wound; and (v) emergence of the phenomenon of the circular vessels in the vicinity of the wound. These processes were visualized by means of the auxin response marker DR5, the auxin transporter PIN1 and the vessel identity marker AtHB8.
Methods
Plant material and growth conditions
Wild-type Arabidopsis thaliana (L.) Heynh. ecotype Columbia 0 (Col-0) and transgenic lines DR5::GUS52, DR5::GFP10, pPIN1::PIN1:GFP15 and AtHB8::GUS in Wassilevskija (Ws) background50 were used. Seeds were obtained from Nottingham Arabidopsis Stock Centre (NASC, http://www.arabidopsis.info/BasicForm). Individual plants were grown in pots with a mixture of soil and vermiculite (1:1, v/v) in growth chambers and under stable conditions as described40. Each marker and conditions were analyzed at least twice on total of 432 inflorescence stems of Arabidopsis.
Design of the experiments
The experiments were divided in two critical steps. I STEP was done to obtain a closed ring of active vascular cambium and secondary tissue architecture in immature inflorescence stems (Supplementary Fig. S4a,b). This part of the experiment had been described previously40. Briefly, plants with immature inflorescence stems (9 to 10 cm tall) were used. Such stems were characterized by the primary tissue architecture, i.e. vascular bundles separated by interterfascicular parenchyma sectors. Stems were decapitated with a sharp razor blade, the apical floral parts (1 to 2 cm) were removed and the artificial weight, a 2.5-g lead ball connected with a plastic tube was applied (Supplementary Fig. S4a,b). Decapitated stems covered by the artificial weight were additionally supported by a wood stick to avoid their bending. With this method, secondary tissue architecture could be obtained in a short time (merely 6 days after weight application) in the basal parts of previously immature Arabidopsis stems (5-mm segments above the rosette). Active vascular cambium cylinder and secondary tissues, namely phloem and xylem, mimicked vascular tissues in woody plants (Supplementary Fig. S4b, shadow frame). In total, 432 plants were analyzed at this step.
II STEP was done to analyze regeneration of incised vascular cambium and formation of new vessels in wounded stems (Supplementary Fig. S4c). Inflorescence stems were cut precisely with a sharp razor blade 3 to 4 mm from the rosette in the transversal plane of the basal sectors with vascular cambium and secondary tissues to interrupt their longitudinal continuum (Supplementary Fig. S4c). Plants were still covered with the artificial weight during this experimental step. Axillary buds grown above the rosette leaves were not removed, thus remaining the source of endogenous auxin (Supplemental Figs S1 and S4a,c). Vasculature regeneration was analyzed in stems with fully developed, closed cambial rings and secondary tissues in their basal parts. Therefore, at this stage, stems were evaluated and selected for further analysis as follows: (i) after this step, basal stem parts were sectioned manually (2 to 3 hand-cut transverse sections were made); (ii) stained with 0.1% (w/v) Safranin O solution for a quick lignin test in the cell walls; and (iii) analyzed with a stereomicroscope to select stems with closed vascular cambium rings and secondary growth. Only stems selected in this manner were used to study vasculature regeneration. The efficiency of the method was very high. In over 88% of the weight-applied stems, the closed rings of secondary tissues were found and, among them, almost all stems were selected with fully regenerated vasculature after wounding (Supplementary Fig. S4c, shadow frame). In this step, 383 plants were analyzed.
In both experimental steps, immature stems without weight application were used as controls for the mechanical stimulus and weight-applied and nonwounded stems as controls for transversal cuts. Moreover, uncut mature inflorescence stems (>25 cm tall) were analyzed as well and used as additional controls for stems with weight-induced secondary growth. In mature stems, secondary growth developed in the basal parts. These observations and statistical analyses were done on a total of 46 mature plants (Supplementary Fig. S2).
Histological procedures
For detailed histological examination, 3-mm basal segments of the wounded stems were processed by fixation, embedding and sectioning as described40. Briefly, first, the samples were fixed with 2% (w/v) glutaraldehyde (Sigma-Aldrich) in phosphate buffer (pH 7.4) at 4 °C, overnight; then, they were washed in phosphate buffer for 3 × 15 min and dehydrated with successive water solutions of 99.9% (w/v) ethanol (graduate percentages 5% to 100%), 30 min for each change at room temperature (RT); afterward, they were infiltrated with propylene oxide (Serva) for 2 × 1 h at RT and with solutions of propylene oxide/PolyBed 812 epoxy resin (3:1, 1:1, 1:3, v/v) at 4 °C overnight; and finally, they were transferred to silicon-embedding molds and polymerized with 100% PolyBed 812 resin (Polysciences) at 35 °C, 45 °C, 60 °C, each temperature for 24 h. Polymerized samples were cut with an ultramicrotome (Leica EM UC6) into semi-thin sections (2-μm thick) with the glass knife, attached to microscope slides covered by Haupt’s adhesive and stained with Periodic Acid-Schiff’s + Toluidine Blue O67. Lastly, the series of semi-thin sections were examined, section by section to visualize changes in the wounded areas and the regeneration process. On average, series of 30 to 40 semi-thin (2-μm thick) sections were analyzed and compared, allowing a precise analysis of vessel connections in regenerated vasculature (presented as one representative picture in the figures).
Histochemical assays for GUS activity
The histochemical analysis was done as described previously52,68. Samples were incubated with X-Gluc solution at 37 °C, overnight and fixed with a 99.9% ethanol/99.6% acetic acid (9:1, v/v) solution at 4 °C overnight. The samples with positive GUS reaction were embedded in LR White acrylic resin (Polysciences) and then infiltrated with series of LR White/99.9% ethanol solutions (3:1, 1:1, 1:3, v/v) at 4 °C overnight, polymerized in gelatin capsules with 100% LR White at 50 °C for 24 h. Washing and dehydrating steps were omitted in this procedure.
Immunolocalization of PIN1 protein
Immunolocalization was done as described previously69. The PIN1 position was monitored with the anti-PIN1 antibody visualized by a fluorescence-labeled Cy3 secondary antibody17. For this procedure, samples were embedded in LR White acrylic resin40, subsequently cut with the ultramicrotome (Leica EM UC6) and the diamond knife in a series of semi-thin sections (1-μm thick), attached to microscope slides covered by Poly-l-lysine (Menzel-Glaser) and processed for immunolocalization. Briefly, slides were washed with phosphate buffered saline (PBS) (pH. 7.4), 2 × 15 min at RT, incubated first with 2% (w/v) blocking solution (bovine serum albumin in PBS) for 30 min at RT and then with a primary antibody (purified rabbit anti-PIN1 antibody, dilution 1:1000) in the humid chamber at 4 °C overnight. Then, the slides were washed with PBS, 5 × 10 min at RT, incubated with the fluorescence-labeled secondary antibody (goat, fluorescence-labeled anti-rabbit-Cy3, dilution 1:600) for 4 h at RT, again washed in PBS, 5 × for 10 min at RT. Finally, they were mounted with antifade FluoroMount Aqueous Mounting medium (Sigma-Aldrich) and analyzed with an epi-fluorescent or confocal laser-scanning microscope.
Analysis of GFP signal in vivo in cells
Changes in expression of genes regulating auxin response and tissue polarity were analyzed in vivo. The DR5::GFP and pPIN1::PIN1:GFP transgenic lines were used. Sections from non-fixed samples of incised stems were handly cut with a sharp razor blade, mounted in 25% (w/v) glycerol solution and analyzed with a confocal laser-scanning microscope.
Statistical analyses
Statistical significances were evaluated with the Student’s t-test (unpaired Student t-test, P < 0.05). Transition from primary to secondary tissue architecture in weight-applied immature stems was analyzed on a total of 432 plants. Differences in vessel lengths were compared: 100 individual cells from both vessel types (normal vessels in unwounded controls and regenerated vessels/circular vessels, in wounded stems) were selected and measured along the tangential dimensions. Additionally, regenerated vessels of 383 wounded stems were analyzed. The number of vessel cells in circular vessels was evaluated. In total, 156 plants with circular vessels were found in wounded stems. Statistical analyses were done with Office Excel 2003 (Microsoft).
Microscopy
Samples of wounded stems were analyzed with a stereomicroscope (NIKON MSZ1500) equipped with the charge-coupled device camera (DS-Fi1). Semi-thin sections were examined with a transmitted light microscope OLYMPUS BX41 equipped with fluorescence filters. PIN1 localization visualized by fluorescence-labeled anti-rabbit Cy3 and auxin response in wounded areas was analyzed using a confocal laser-scanning microscope ZEISS LSM5 Exciter or Zeiss Observer.Z1. Fluorescence of Cy3 and GFP (reporter lines DR5::GFP and pPIN1::PIN1:GFP) was excited with a multiband argon laser at wavelength of 561 nm and 488 nm, respectively. The acquired images were processed with ZEN 2008 and ZEN 2012 Light Edition softwares.
Additional Information
How to cite this article: Mazur, E. et al. Vascular cambium regeneration and vessel formation in wounded inflorescence stems of Arabidopsis. Sci. Rep. 6, 33754; doi: 10.1038/srep33754 (2016).
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Acknowledgements
We wish to thank Prof. Ewa U. Kurczyńska for initiation of this work and valuable advices. We thank Martine De Cock for help in preparing the manuscript. This work was supported by the European Research Council (project ERC-2011-StG-20101109-PSDP), the European Social Fund (CZ.1.07/2.3.00/20.0043) and the Czech Science Foundation GAČR (GA13-40637 S) to J.F., (GA 13-39982S) to E.B. and E.M. and in part by the European Regional Development Fund (project “CEITEC, Central European Institute of Technology”, CZ.1.05/1.1.00/02.0068).
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E.M. performed the experiments and figures, E.B. and J.F. analyzed the data, E.B., E.M. and J.F. discussed the data, E.M. and J.F. wrote the article. No conflict of interest declared.
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Mazur, E., Benková, E. & Friml, J. Vascular cambium regeneration and vessel formation in wounded inflorescence stems of Arabidopsis. Sci Rep 6, 33754 (2016). https://doi.org/10.1038/srep33754
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DOI: https://doi.org/10.1038/srep33754
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