Neutral Red as a Probe for Confocal Laser Scanning Microscopy Studies of Plant Roots

doi:10.1093/aob/mcl045

AOBPreview originally published online on March 6, 2006
Annals of Botany 2006 97(6):1127-1138; doi:10.1093/aob/mcl045

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TECHNICAL ARTICLE

Neutral Red as a Probe for Confocal Laser Scanning Microscopy Studies of Plant Roots

JOSEPH G. DUBROVSKY¹^,*, MARTIN GUTTENBERGER², ANDRES SARALEGUI³, SELENE NAPSUCIALY-MENDIVIL¹, BORIS VOIGT⁴, FRANTI $S$ EK BALU $S$ KA⁴ and DIEDRIK MENZEL⁴

¹ Departamento de Biología Molecular de Plantas and ³ Unidad de Microscopía del Instituto de Biotecnología, Universidad Nacional Autónoma de México, Cuernavaca, Morelos, México, ² Universität Tübingen, Entwicklungsgenetik, Tübingen, Germany and ⁴ Institute of Cellular and Molecular Botany, University of Bonn, Bonn, Germany

^* For correspondence. E-mail jdubrov{at}ibt.unam.mx

Received: 13 July 2005 Returned for revision: 3 August 2005 Accepted: 19 January 2006 Published electronically: 6 March 2006

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
SUPPLEMENTARY INFORMATION
ACKNOWLEDGEMENTS
LITERATURE CITED

• Background and Aims Neutral red (NR), a lipophilic phenazinedye, has been widely used in various biological systems as avital stain for bright-field microscopy. In its unprotonatedform it penetrates the plasma membrane and tonoplast of viableplant cells, then due to protonation it becomes trapped in acidiccompartments. The possible applications of NR for confocal laserscanning microscopy (CLSM) studies were examined in variousaspects of plant root biology.

• Methods NR was used as a fluorochrome for living rootsof Phaseolus vulgaris, Allium cepa, A. porrum and Arabidopsisthaliana (wild-type and transgenic GFP-carrying lines). Thetissues were visualized using CLSM. The effect of NR on theintegrity of the cytoskeleton and the growth rate of arabidopsisprimary roots was analysed to judge potential toxic effectsof the dye.

• Key Results The main advantages of the use of NR arerelated to the fact that NR rapidly penetrates root tissues,has affinity to suberin and lignin, and accumulates in the vacuoles.It is shown that NR is a suitable probe for visualization ofproto- and metaxylem elements, Casparian bands in the endodermis,and vacuoles in cells of living roots. The actin cytoskeletonand the microtubule system of the cells, as well as the dynamicsof root growth, remain unchanged after short-term applicationof NR, indicating a relatively low toxicity of this chemical.It was also found that NR is a useful probe for the observationof the internal structures of root nodules and of fungal hyphaein vesicular–arbuscular mycorrhizas.

• Conclusions Ease, low cost and absence of tissue processingmake NR a useful probe for structural, developmental and vacuole-biogeneticstudies of plant roots with CLSM.

Key words: CLSM, Casparian band, xylem, vacuole biogenesis, lateral root development, root development, neutral red

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
SUPPLEMENTARY INFORMATION
ACKNOWLEDGEMENTS
LITERATURE CITED

Neutral red (NR; 3-amino-7-dimethylamino-2-methylphenazine),a lipophilic free base, has been widely used in various biologicalsystems for almost a century. The main application of NR isits use as a vital stain because it penetrates in viable cellsand accumulates in lysosomes of animal (Essig-Marcello and vanBuskirk, 1990), and in vacuoles of plant (Guilliermond, 1929;Timmers et al., 1995) and in fungus cells (Dixon et al., 1999).As a lysosomal stain, NR was implicated as a biomarker for environmentaltoxicology studies of soils (Weeks and Svendsen, 1996; Svendsenet al., 2004). NR in its unprotonated form easily penetratesthe plasma membrane and tonoplast. Due to protonation in acidiccompartments the dye is trapped in vacuoles (Oparka, 1991; Timmerset al., 1995; Ehara et al., 1996). Thus, NR is used for planttissues as an acidotropic stain accumulating in vacuoles (Smithand Raven, 1979; Timmers et al., 1995; Di Sansebastiano et al.,1998; Kawai et al., 1998; Ngo et al., 2005) and the peri-arbuscularspace of mycorrhizal roots (Guttenberger, 2000a, b) as wellas a general vital stain (Strugger, 1935; Stadelmann and Kinzel,1972; Crippen and Perrier, 1974; Nishimura, 1982; Timmers etal., 1995; Nobel et al., 1998). NR is known to stain variouscompounds due to its affinity for lipophilic structures (suberin,Conn, 1977; Lulai and Morgan, 1992; lipids, Conn, 1977; phenolicsubstances, Stadelmann and Kinzel, 1972), ionic interactionof the protonated dye with negative charges (cell walls, Stadelmannand Kinzel, 1972), intercalation (DNA, Zhang et al., 2004),and chemical binding (lignin, Conn, 1977). The acidotropic stainingis referred to as specific staining in contrast to non-specificstaining of cell walls. Accumulation of NR in vacuoles can alsobe due to interactions with phenolic substances dissolved inthe cell sap (‘full cell saps’), which frequentlygive rise to stained globular or dendritic structures in thecell sap (Stadelmann and Kinzel, 1972).

As a relatively non-toxic compound, NR has been widely usedfor root growth studies. Particularly, after pre-staining theroot with NR, new growth of unstained root portions can be analysed(Schumacher et al., 1983; Schumacher and Smucker, 1984). Theseauthors showed that NR did not have a significant effect onroot growth or respiration rate (Schumacher et al., 1983). Thismethod is currently widely used either for root growth studies(Watkin et al., 1998) or computerized determinations of rootlength or diameter (Bouma et al., 1997, 2000; Bates and Lynch,2000). Other studies also demonstrated the non-toxic effectof NR on plant root systems (Guttenberger, 2000b).

Fluorescence properties of NR were explored first by animaland later by plant physiologists. NR can be used for the determinationof pH in rat brains (LaManna and McCracken, 1984) and vacuolesof plant tissues (Timmers et al., 1995; Wilson et al., 1998).NR has a wide emission spectrum from <450 nm to >700 nmwith the maximum ranging from 550 nm to 650 nm (Chen et al.,1998). The maximum emission occurs at pH 7·06, whichbecomes reduced by 50 % at pH 8·00 (Chen et al., 1998).NR was used as a fluorochrome for the identification of suberizedtissues (Lulai and Morgan, 1992; De Simone et al., 2003a, b).The latter authors used the stain to detect the suberized hypodermison stem sections of some tree species.

Lateral root primordia in arabidopsis develop from pericyclecells adjacent to protoxylem poles. To recognize the stagesof lateral root development, the analysis is usually done onroots laying on a slide in the protoxylem plane (Malamy andBenfey, 1997). In previous studies of lateral root developmentin arabidopsis (Dubrovsky et al., 2000, 2001) it was noticedthat propidium iodide, commonly used for arabidopsis roots asan apoplasmic tracer (Van den Berg et al., 1995), does not penetrateinto the vascular cylinder of the differentiation zone of anintact living root. This shortcoming prompted us to search fora permeable fluorochrome, preferably not toxic, that can beappropriate for various studies of plant roots and, particularly,for the analysis of lateral root development using CLSM. Soranand La $z$ ar (1965) reported that NR very rapidly penetrates maizeroots tissues, including the pericycle. This observation indicatedthat NR can be used for the analysis of internal tissues ofplant roots. In the current study is an evaluation of the possibleapplications of NR in CLSM studies of the internal root structure.The use of NR in transgenic arabidopsis lines carrying GFP andenhancer trap lines have been tested in addition to other plants.Also discussed are possible limitations of using NR. As faras is known this is the first report of the use of NR as a probefor CLSM studies of intact plant organs.

MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
SUPPLEMENTARY INFORMATION
ACKNOWLEDGEMENTS
LITERATURE CITED

Plant material
The Arabidopsis thaliana lines used were wild-type Col-0 andLer, scr-3 (CS3997) mutant (Fukaki et al., 1998), enhancer traplines J0121and J1701 (http://www.plantsci.cam.ac.uk/Haseloff/Home.html)and other transgenic lines: GFP-mammalian microtubule-associatedprotein 4 (GFP-MAP4) (Marc et al., 1998), mouse talin actin-bindingdomain fused to the C-terminus of GFP, GFP-mTn (Kost et al.,1998), GFP-actin-binding domain 2 (GFP-FABD2) (Ketelaar et al.,2004; Voigt et al., 2005) and PIN-FORMED1:GFP (PIN1:GFP) (Benkováet al., 2003). These lines were selected to test general stainingproperties of NR (Col-0 and scr-3) and its effect on actin cytoskeleton(GFP-mTn and GFP-FABD2) and microtubule network (GFP-MAP4).Other GFP expressing lines (J0121, J1701 and PIN1:GFP) wereused to test the possibility for cross-talk between green emissionof GFP and red emission of NR (see below), as well as to examinehow appropriate NR is for developmental studies. The seeds weresurface sterilized for 10 min in 60 % (v/v) commercial bleachand 0·08 % (w/v) Triton X-100, rinsed four times withsterile distilled water and maintained at 4 °C for 48 h.Seeds were plated on 20 % Murashige and Skoog medium (MS), pH5·8, supplemented with 1 % (w/v) sucrose and solidifiedwith 0·8 % bacto-agar (Difco Laboratories, Detroit, MI,USA). Petri dishes were maintained in a vertical position at23 °C under an 8-h dark/16-h light cycle (105 µmolm^–2 s^–1). To prevent any root damage, seedlingswere selected with the root system growing on the agar surface.

Phaseolus vulgaris ‘Negro Jamapa’ seeds were surfacesterilized with ethanol for 1 min and subsequently with 20 %bleach for 5 min and washed six times with sterile water. Seedswere germinated aseptically in Petri dishes containing wet filterpaper to ensure germination. Germinated seeds were transferredto liquid Fahraeus medium (Fahraeus, 1957). The roots were inoculatedwithRhizobium etli, CE3 (Cárdenas et al., 2006).

Allium cepa seeds were germinated on filter paper moistenedwith distilled water. Growth and culture conditions of mycorrhizalplants (Glomus mosseae and Allium porrum) were described earlier(Guttenberger, 2000a, b).

Toxicity test
Arabidopsis plants were grown for 5 d on 0·2x MS medium,pH 5·8, and, for the toxicity test, transferred to thesame agar medium containing filter-sterilized NR (1 µMand 4 µM; Merck, Darmstadt, Germany). Alternatively, rootsof intact plants, 5 d after germination (dag), were incubatedfor 30 min in liquid 0·2x MS medium containing NR (1µM and 4 µM) and then transferred to NR-free 0·2xMS medium. Root growth increments were recorded each 24 h. Experimentswere repeated at least twice. Growth conditions were the sameas indicated above.

The actin cytoskeleton and the cortical microtubule networkare very sensitive to toxic compounds (see the Results section).Therefore, the effect of NR on the cytoskeleton was investigated.Oryzalin (1 µM; Sigma), an inhibitor of microtubule polymerization(Hugdahl and Morejohn, 1993), served as a positive control fordisruption of the microtubule network in living arabidopsis(Col-0 wild-type) roots.

Staining
All observations were done on living roots of intact arabidopsisseedlings, 6–8 dag unless indicated otherwise, on wholeroots of A. cepa 5 dag, and on excised portions of living rootsof P. vulgaris 13 dag. Day 0 of germination was considered theday when seeds were plated on 0·2x MS medium. NR wasused for the preparation of 4 mM stock solution in water andkept at 4 °C for 3 weeks. After that period a new stockwas used. The final concentration of NR ranged from 0·4µM to 40 µM and mostly was 1 µM or 4 µM.Only freshly prepared solutions were used. The pH of the stainingsolution was 5·8 (0·2x MS medium, optimal forgrowth) or 8·0 (for minimal background staining). AtpH 8·0 the staining solution solvent consisted of (a)0·1 M potassium phosphate buffer, (b) 1 M potassium phosphatebuffer, both prepared in water, (c) 0·2x MS medium supplementedwith 20 mM potassium phosphate buffer, or (d) medium (c) supplementedwith 50 mM KNO₃. Since for arabidopsis roots background stainingwas acceptable at pH 5·8, the staining solution was mostlyprepared in 0·2x MS medium. For staining of arabidopsisroots, 1–10 min of incubation was sufficient. In somecases material was kept in NR solution for up to 3·5h. When roots were stained with a very low concentration ofNR (0·4 µM, pH 5·8 and 8·0) the timerequired for staining was 20–30 min. Phaseolus vulgaris2-cm root portions were incubated with NR for 10–30 min(pH 5·8). In each particular case, the staining timeis indicated in the figure legends. For comparison, some materialwas stained with 1–10 µg ml^–1propidium iodide(Sigma) for 10–30 min. Mycorrhizal roots were stained(0·4 µM NR) and examined according to Guttenberger(2000a). Plant material was mounted directly in the solutionof NR or propidium iodide on a slide which was wrapped threetimes with two 1-mm-thick strips of parafilm 45 mm apart fromone another and covered by a 24 x 50 mm coverslip (No. 1). Whenobservations were done on an inverted microscope, after mounting,the coverslip was fixed in its position by another two thinstrips of parafilm.

Spectral characteristics of NR
At pH 7·5 NR has a wide excitation spectrum ranging from450 to 550 nm (Zhang et al., 2004) and a wide emission spectrumwith the maximum ranging from 550 to 650 nm (Chen et al., 1998).The reported emission spectra of NR include significant emissionbetween 500 and 550 nm (green). In the current work, GFP-expressingtransgenic lines were used. It is known that GFP emission peaksat 509 nm (Tsien and Wagooner, 1995), indicating that NR andGFP emissions overlap. This is why before observing tissuesexpressing GFP it was necessary to verify which tissues in non-transgenicmaterial emit green fluorescence when NR is used. In wild-typeCol-0 seedlings, neither Casparian bands and xylem nor vacuolesemitted significant green fluorescence. To avoid the possibilityof cross-talk, the laser power was maintained at the level thatkept green fluorescence from NR minimal or absent. In most casesthis approach permitted NR and GFP emissions to be detectedseparately.

The emission spectra of plant material stained with NR havenot been reported. The Zeiss LSM 510 Meta microscope made itpossible to acquire a series of images of the same object areaeach taken with different emission wavelengths in 10-nm steps.This stack is called a lambda stack (Dickinson et al., 2001).A lambda stack of various tissues and sub-cellular compartments(substrates) reacting with NR (4 µM diluted in 0·2xMS medium at pH 5·8; excitation at 488 nm) was acquiredand fluorescence intensities plotted against wavelengths toobtain emission curves. Considering these spectra, NR and GFPwere detected with the emission filters BP 565–615 andBP 500–530, respectively.

Microscopy and image acquisition
Confocal images were acquired on an upright Leica TCS4D (LeicaLasertechnik Heidelberg, Germany) and an inverted Zeiss LSM510 Meta (Carl Zeiss, Jena, Germany) microscopes. Leica x25(NA 0·75) oil immersion, Leica x63 (NA 0·9) waterimmersion and Zeiss x40 (NA 0·75, Plan Neofluar) dryand x63 (NA1·2, C-Apochromat) water immersion objectiveswere used. With a Leica miscroscope, 564 and 488 nm lines ofa Kr/Ar laser were used. With the Zeiss microscope, 543 nm lineof a He/Ne laser and 488 nm of an Ar laser were used for NRand GFP excitation.

To further decrease cross-talk and improve spectral separationduring image acquisition of samples containing GFP and NR, commonlythe sequential scan (time-separated data collection for eachchannel) was used, and different excitation wavelengths wereemployed (488 nm and 543 nm for GFP and NR, respectively). Fortransgenic lines, mutants and wild-type plants no autofluorescencewas detected (Supplementary Information, Fig. SF1).

Each single section represents an average of four scans. Somereported figures represent maximum intensity projections ofa stack of confocal optical sections. To obtain a transversesection (a section in the x–z plane) a longitudinal opticalsection was acquired, the zone of interest was detected anda tracing line perpendicular to the root axis was set over theimage. Then, with the Zeiss LSM 510 Meta microscope acquisitionsoftware, images along the tracing line of increasing depthof focus were taken and subsequently visualized at a 90°angle. At progressively deeper depth of focus, the fluorescencesignal decreased progressively. This explains why transversesections of the images were always brighter at the top and dimat the bottom. For image analysis, the Zeiss Image Examinersoftware, version 3·2 and Image J (National Institutesof Health, Bethesda, MD; http://rsb.info.nih.gov/ij/) were used.

RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
SUPPLEMENTARY INFORMATION
ACKNOWLEDGEMENTS
LITERATURE CITED

Spectral characteristics of NR
To allow unequivocal distinction of signals from NR and GFP,emission spectra of NR-stained structures were collected (Fig. 1).These data confirmed the wide emission spectra observed earlierand showed that the highest emission peak was 590 nm for vacuolesand 600 nm for protoxylem, metaxylem and Casparian bands. Itwas surprising to find that the emission spectra recorded instained arabidopsis tissues showed up to five peaks or shoulders.

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FIG. 1. Emission spectra of various NR-stained (4 µM, pH 5·8) Arabidospsis thaliana, Col-0, root tissues and sub-cellular compartments taken with the meta-channel option of the Zeiss LSM 510 Meta microscope; excitation at 488 nm. In each case the same area was analysed. Spectra of protoxylem and metaxylem were taken in young and mature differentiation zones, respectively. Spectra of Casparian bands and vacuoles were taken in mature differentiation and transition zones, respectively.

NR toxicity
To study the potential toxicity of NR at the concentrationsused for CLSM studies, arabidopsis root growth dynamics wereanalysed (Fig. 2). Roots grown in 0·2x MS medium supplementedwith 4 µM NR (pH 5·8) stopped growing and did notrecover for at least 5d of incubation in the medium (Fig. 2).However, after 5 d of growth in the medium supplemented with1 µM NR (pH 5·8), roots were only 18 % shorter(but still significant, P < 0·05) than the roots grownin normal medium (Fig. 2). Interestingly, short-term treatmentof 30 min in 4 µM NR (Fig. 2) or 1 µM NR (data notshown) did not inhibit subsequent root growth. These data indicatethat the toxicity of NR is relatively low at 1 µM, whichis the concentration sufficient to visualize Casparian band,xylem elements or vacuoles under CLSM.

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FIG. 2. Root growth dynamics in Arabidopsis plants, Col-0, subjected to short-term (30 min) and long-term (5d) treatment with NR (pH 5·8). Asterisk indicates the time of short-term treatment or time of transfer of the roots into medium supplemented with NR. Data are means ± 95 % confidence interval (n = 11). The experiment was repeated at least twice.

Both the microtubule network and the actin cytoskeleton arevery sensitive to disturbance and pharmacological treatments(for root cells, see Balu $s$ ka et al., 1993

, 1996

, 2001a

; Sivaguruet al., 1999

; Barlow and Balu $s$ ka, 2000

). To test whether NR affectsthe microtubule network or the actin cytoskeleton in livingroots, a comparative study was made of the roots of varioustransgenic lines where microtubules and the actin cytoskeletonwere observed. Under the influence of NR, no significant differenceswere detected in the distribution of cortical microtubules inthe elongated cells (Fig. 3A, B) of the GFP-MAP4 line [whereGFP is fused to the microtubule-binding domain of the mammalianmicrotubule-associated protein 4 (MAP4) gene; Marc et al., 1998

].When the roots of this line were incubated for 2 h with 1 µMoryzalin (pH 5·8) changes in the orientation of corticalmicrotubules were observed. The 4-h treatment induced completedisorganization of microtubules (Supplementary Information,Fig. SF2). Incubation of the roots with NR did not have anyof these effects. Also possible changes in the actin cytoskeletoninduced by NR (1 µM and 4 µM, pH 5·8) weretested. There were no significant changes in the actin cytoskeleton,either in cortical cells of the transition zone of arabidopsisroots or in the young differentiation zone. In GFP-mTn and GFP-FABD2lines, cells in the transition zone (root portion between themeristem and rapid elongation zone; Balu $s$ ka et al., 2001b

), bothwith and without NR treatments, had a similar distribution ofF-actin arrays (Fig. 3C, D, H, G), suggesting that NR does notaffect the actin cytoskeleton. Similarly, there were no significantdifferences in the actin cytoskeleton detected in recently elongatedcortical cells in the roots of a GFP-ABD2 line (Fig. 3E, F).These observations indicate that 1 µM and 4 µM ofNR is not cytotoxic for roots of arabidopsis when applied forup to 60 min.

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FIG. 3. Cortical microtubule array and actin cytoskeleton in Arabidopsis roots in relation to application of NR. (A and B) Cortical microtubules in GFP-MAP4 roots; cortical cells of the young differentiated zone in roots stained with 1 µM NR (A) and without staining (B). (C–F) Actin cytoskeleton in GFP-ABD2 roots; the cells of the transition zone (C and D) and differentiation zone (E and F) stained with 1 µM NR (C and E) and without staining (D and F). (G–I) Actin filaments in GFP-mTn line, in the transition zone (G and H) and pericycle adjacent to protoxylem within the differentiation zone (I) stained with 4 µM (G), 1 µM (I) or without staining (H). All panels are single optical sections. (A–D, G and H) Tangential longitudinal optical sections; (E, F and I) longitudinal median optical sections of roots positioned in the protoxylem plane. Staining time was 30–60 min. Arrowheads indicate Casparian band. ep, Epidermis; c, cortex; e, endodermis; p, pericycle; px, protoxylem. In all cases pH of NR solution was 5·8. Scale bars: H and I = 20 µm. Magnification on panels (A–H) is the same.

Staining kinetics
Upon vital staining of roots of Arabidopsis thaliana, Col-0and Ler, NR penetrated well into all root zones except the rootapical meristem (pH 5·8 and 8·0, 0·4–40µM of NR; Figs 4 and 5). Incubation in 0·4 µMNR prepared in 0·2x MS supplemented with 20 mM potassium-phosphatebuffer (pH 8·0) for 15 min was sufficient for visualizationof protoxylem, although the signal was still weak. After 3·5h of incubation, fluorescence from the protoxylem was stronger(Supplementary Information, Fig. SF3). The images were acquiredat the same laser settings. In this particular case, grey valuelevels increased 1·7 times after extensive staining.In the case of propidium iodide, even prolonged incubation ata high concentration (10 µg mL^–1 for 30 min insteadof the usual 1 min) did not result in penetration into the steleof living arabidopsis roots (10-d-old seedlings, mature rootzone with Casparian bands differentiated; Supplementary Information,Fig. SF4).

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FIG. 4. NR as a probe for visualization of the endodermal Casparian band, xylem elements and general root structure in living roots of wild-type arabidopsis, Col-0 (A, B, D and E), and in scr-3 mutant (C): (A) young differentiation zone, protoxylem elements are not yet differentiated; (B) Casparian bands of the endodermal cells and protoxylem elements; (C) metaxylem in scr-3 mutant; note the lack of one cell layer in ground tissue; (D) protoxylem and metaxylem elements and Casparian bands in the mature differentiation zone; (E) transverse optical section of the root in which Casparian bands and general radial tissue pattern can be visualized. Arrowheads indicate Casparian bands; ep, Epidermis; c, cortex; e, endodermis; p, pericycle; px, protoxylem; mx, metaxylem. Roots were stained with 4 µM (A, C and D) and 1 µM (E) NR at pH 5·8 and with 4 µM NR at pH 8·0 in 0·2x MS supplemented with 20 mM K-phosphate buffer (B). Staining time was 10–20 min (A and C–E) and 1 h 45 min (B). All panels show single optical sections except (B), projection of seven optical sections, total thickness of tissues scanned is 6 µm. Scale bars = 20 µm.

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FIG. 5. Staining properties of NR at pH 8·0 prepared in solutions of different ionic strength in arabidopsis Col-0 (A–D and F) and Ler (E) wild-type plants: (A) tangential longitudinal section, showing staining of cytoplasm in epidermis and cortex in the transition zone; (B) staining of cytoplasm in the epidermis in the transition zone; (C and D) vacuolar system in the cortical cells of the transition zone; (E) vacuolar system in the differentiation zone shown in partially tangential section; (F) staining of cytoplasm in near-median section of the root apical meristem. The arrowhead indicates Casparian bands. ep, Epidermis; c, cortex; e, endodermis; p, pericycle. Roots were stained with 4 µM (A–E) or 0·4 µM (F) NR. The staining solution was prepared in 0·2x MS supplemented with 20 mM K-phosphate buffer (A), in 0·1 M K-phosphate buffer (B and F), in 0·2x MS supplemented with 20 mM K-phosphate buffer and 50 mM KNO₃ (C and D) and in 1 M K-phosphate buffer (E). Staining time was 15–30 min (A–E) and 1 h (F). Single optical sections (A, E and F) and projection of three optical sections, total thickness of tissues scanned is 2·4 µm (B), projection of three optical sections, total thickness of tissues scanned is 2·6 µm (C), and projection of six optical sections, total thickness of tissue scanned is 5 µm (D). Scale bars: A, B, E and F = 20 µm; C = 10 µm; D = 5 µm.

Influence of the pH and ionic strength on NR staining
In comparison to experiments at pH 5·8, staining of thecell walls was, in general, very weak at pH 8·0. However,protoxylem and metaxylem elements were well stained (Fig. 4B)and Casparian bands could be detected (Figs 4B and 5E; Table 1).They even appeared to be stained more specifically as the thicknessof these stained structures at this pH was visually differentfrom samples at pH 5·8. For example, the lignified cellwall component of the protoxylem elements appeared thinner whenstained at alkaline pH in comparison to acidic pH (compare FigsSF3A and SF5A where roots were stained at 0·4 µMNR but at different pH; Supplementary Information). A similareffect could be observed upon addition of salt to the stainingsolution at pH 8·0 (50 mM KNO₃, data not shown). In addition,in the presence of salt (50 mM KNO₃) or concentrated buffer(1 M phosphate buffer), vacuoles of the transition zone (Fig. 5C, D)or transition and differentiation zone (Fig. 5E) were stainedat pH 8·0, respectively. High buffer concentrations (1M) induced plasmolysis in the root tissues and allowed visualizationof vacuoles in all root zones. This was the only staining conditionthat permitted detection of the vacuolar system in the differentiationzone (Fig. 5E). Upon prolonged incubation (1 h) the root meristemcould be stained consistently in a staining solution containing0·1 M phosphate buffer at pH 8·0 (Fig. 5F). Theother staining media were not effective in this case.

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TABLE 1. The staining properties of Neutral red in relation to the staining conditions

Casparian bands and xylem elements are visualized with NR
In the early differentiation zone, where the protoxylem is notyet differentiated, NR at pH 5·8 can be used as a generalstain that serves well for recognition of various root tissues(Fig. 4A). In the more mature portion of the root, NR was foundto be useful for detection of the Casparian bands of the endodermiscells (Fig. 4B) and proto- and metaxylem elements (Fig. 4B–E).Even the lowest concentration of NR tested (0·4 µM)was sufficient for visualization of these internal tissues (SupplementaryInformation, Fig. SF5, pH 5·8). At high concentrationsof NR, staining of cell walls was too intense to detect Casparianbands.

Under the same CLSM settings and the same staining time (0·4µM NR, 10 min) there was no difference in the fluorescenceintensity of cell walls in young and mature differentiationzones of the same root (comparing maximum fluorescence intensitiesestimated as grey values) (Supplementary Information, Fig. SF5B).However, some transgenic lines did show differences in the fluorescenceintensity in comparison to wild-type plants (data not shown).It was found that 1 µM NR (pH 5·8) was sufficientto obtain transverse images of arabidopsis roots that permittedvisualization of all tissues and the Casparian bands of theendodermis (Fig. 4E). Using NR and CLSM, Casparian bands couldalso be detected in a mutant with abnormal development of theground tissue (Fig. 4C).

NR as probe for the studies of vacuolar system biogenesis in root cells
The vacuolar system of root cortical cells in arabidopsis, A.cepa and P. vulgaris was studied for its NR-accumulation properties.At the basal portion of the root apical meristem, the vacuolarsystem of the cells is already formed in both arabidopsis andP. vulgaris roots. At this stage of cellular development, cellshave a system of many small vacuoles. Some of them are <1µm (Fig. 6A, 4 µM NR, pH 5·8, P. vulgaris).At the beginning of cell elongation in the transition zone,the vacuoles become progressively larger proportional to theincrease in cell length (Fig. 6 B–D). In this process,the vacuoles fuse and finally form a large central vacuole (Fig. 6D).In effect the same observations were made for arabidopsis andA. cepa roots (data not shown). Good penetration ability ofNR at pH 5·8 was also verified in such organs as theroot nodule in P. vulgaris. Using NR, the general morphologyof the nodule could be observed (Fig. 6E). NR mainly stainedthe vacuolar system of differentiated nodule cells. Centralvacuoles were formed in the peripheral tissues of the nodules(Fig. 6F). In this case, NR could not penetrate into internaltissues possibly due to binding to peripheral structures.

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FIG. 6. Vacuolar system in cortical cells and the root nodule of the root of Phaseolus vulgaris. (A–D) Vacuolar system in the cortex in P. vulgaris observed in tangential optical sections: (A) a vacuolar system in the proximal portion of the root apical meristem; (B–D) biogenesis of the vacuolar system in cortical cells along the root from the meristem (B) toward the transition zone (C, D) – note the progress of vacuolar fusions in the proximal direction; (D) central vacuoles are formed; (E) P. vulgaris young root nodule; (F) central vacuoles of nodule cells. Roots were stained with 4 µM NR, pH 5·8, for 10–20 min. Projection of 15 optical sections, total thickness of tissues scanned is 14 µm (A), projection of 23 optical sections, total thickness of tissues scanned is 16·5 µm (B), and projection of 30 optical sections, total thickness of tissues scanned is 21·8 µm (C). Panels (D–F) are single optical sections. Scale bars: A–D = 5 µm; E and F = 50 µm.

NR is a useful probe for developmental studies
Analysing an enhancer trap line of A. thaliana, J1701 whereER-GFP is expressed in the root cap and presumptive xylem elements,NR was visualized in the vacuolar system of the columella andlateral root cap cells (Fig. 7A, pH 5·8). In the protrudinglateral root primordium, the vacuolar system of root cap cellswas not detected (Fig. 7B, pH 5·8). At a more advancedstage, NR staining was similar in the primary and lateral rootsat pH 5·8 (data not shown) and at pH 8·0 (SupplementaryInformation Fig. SF6 A, B).

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FIG. 7. Examples of the use of NR for root developmental studies. (A and B) An enhancer trap line of Arabidopsis thaliana, J1701 – GFP is expressed in the root cap: (A) the root cap of the primary root; (B) recently emerged lateral root—note that no NR is detected in the root apical meristem. (C and D) The root of PIN1:GFP line stained with NR, which is primarily located in the protoxylem—lateral root primordia at stages II (C) and IV (D). (E and F) An enhancer trap line of Arabidopsis thaliana, J0121—GFP is expressed in the pericycle cells adjacent to the protoxylem; (E) tangential longitudinal optical section; (F) transverse optical section. Roots were stained with 4 µM (A and B) and 1 µM (C–F) NR, pH 5·8. p, Pericycle; px, prtoxylem; mx, metaxylem. Projection of seven optical sections, total thickness of tissues scanned is 6 µm (D) and projection of eight optical sections, total thickness of tissues scanned is 7 µm (E). Other panels are single optical sections. Scale bars = 20 µm.

Since NR rapidly penetrates into the tissues of the centralcylinder of the root, it is a very useful probe for in vivoanalysis of lateral root development. This is illustrated hereusing a PIN1:GFP line. NR-staining of xylem elements permitseasy recognition of the plane of orientation, while the expressionof PIN1:GFP highlights the lateral root primordia. In the rootsstained with NR, primordia at stages II and IV (stage definitionby Malamy and Benfey, 1997

) located in the protoxylem planecan be seen (Fig. 7C, D; pH 5·8).

Previously, the question about the minimum number of foundercells required for lateral root initiation in arabidopsis wasstudied and it was shown that three pericycle cells are sufficientto form a primordium (Dubrovsky et al., 2001). Analysing enhancertrap line J0121, where pericycle cells adjacent to protoxylem(detected by NR) express GFP, it was found that pericycle cellsfrom three cell files adjacent to the protoxylem express GFP.When the root is placed in a protophloem plane, these cellscan be observed above the protoxylem detected with NR in a longitudinaltangential (Fig. 7E) or transverse (Fig. 7F) optical sectionmade with a CLSM.

During lateral root development, a founder cell should theoreticallybe undergoing changes in the cytoskeleton as the cell polarityhas to be changed during the formation of a new organ. The studyof the cytoskeleton in deeper layers of living roots is notan easy task. The present attempt to visualize the cytoskeletonin the pericycle was possible when 4 µM NR (pH 5·8)was applied to living roots of GFP-mTn (Fig. 3I) and GFP-FABD2(Fig. 3E) lines. The use of NR permitted the protoxylem to berecognized and thus the identification of the pericycle cellswhich are competent for lateral root formation in living rootsof a transgenic line where GFP is fused either to mouse talin(Kost et al., 1998) or to the ABD2 actin-binding domain of plantfimbrin (Ketelaar et al., 2004; Voigt et al., 2005). In thetransition zone, central nuclei are surrounded with an F-actincage, which interacts with actin-rich end-poles (Fig. 3C and D).The use of NR will enable further studies of the underlyingdynamics in the cytoskeleton.

NR for endo-mycorrhiza studies
Fungal structures are barely visible in mycorrhizal roots withoutstaining. In earlier studies, NR was introduced as a suitablevital stain for detection of arbuscules within colonized roots(Guttenberger 2000a, b). Here, it is demonstrated that NR, usedas a fluorescent probe for CLSM, is suitable for improving thedetection of fungal structures within roots. While the colonizedplant cells show hardly any staining, the most intense fluorescencesignal lies within fungal structures (Fig. 8). CLSM permitted3-D reconstruction of fungal structures within roots (see MovieSM1, Supplementary Information).

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FIG. 8. Glomus mosseae in mycorrhizal roots of Allium porrum. Two arbuscules and two running hyphae connected by an anastomosis are shown. The brightly fluorescing globular and tubular structures within the hyphae are probably vacuoles. The staining solution was 0·4 µM NR in 10 mM MOPS/KOH-buffer, pH 8·0. Projection of 63 optical sections, each covers 116 µm², total thickness of tissues scanned is 28 µm. Scale bar = 10 µm.

DISCUSSION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
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Spectral properties of NR
The recorded emission spectra were necessary for the properselection of suitable emission filters to separate signals fromNR and GFP. Published emission spectra of NR in solvents orcytoplasm are characterized by a single broad peak (Chen etal., 1998). Since autofluorescence was not observed the complexspectra found in NR-stained roots most likely reflect the interactionof NR with different substrates, giving rise to a number ofdistinct emission spectra, which sum up to the observed complexity.The complex emission spectra might provide an explanation forthe occasional simultaneous observation of green and red signals(Fig. 7D), which in this case may be related to unknown propertiesof the given transgenic line. In future, analysis of emissionspectra might allow for the char-acterization of the physico-chemicalenvironment of NR in a given tissue or subcellular compartment.From such data the biochemical nature of the stained structureand the underlying staining mechanism could be deduced, e.g.spectra from NR bound to full cell saps should differ from thoseof NR trapped in an acidic compartment or dissolved in a lipiddroplet. Known physico-chemical factors that influence the spectralproperties of NR, its fluorescence intensity and/or emissionmaximum are pH (mainly intensity; Chen et al., 1998), solventpolarity (wavelength of maximum increases with increasing polarity;Sousa et al., 1996), concentration of NR (molar absorbance increaseswith decreasing concentration; Dell'Antone et al., 1972), andintermolecular interactions (changed excitation spectra andfluorescence intensity; Zhang et al., 2004).

NR toxicity and concentrations used for CLSM studies
Vital staining for bright-field microscopy is performed withconcentrations of NR ranging from 8 µM (Guttenberger,2000a, b) to 3·5 mM (Lulai and Morgan, 1992). Stadelmannand Kinzel (1972) recommend 346 µM of NR (0·01%). The most common concentrations of NR used in this studywere 1 µM and 4 µM which were not toxic if appliedat pH 5·8 for 5 d (1 µM) or 30 min (4 µM).This result is in line with the use of NR in toxicity assayswhere NR serves as a marker for vitality (Zhang et al., 1990).However, NR can also have toxic effects as a cancer cell photosensitizer(VanderWerf QM et al., 1997). Since the present culture systemdid not allow protection from the light, this property may explain,why in the present experiments NR inhibited root growth at concentrationsexceeding 4 µM, while NR did not exert a significant inhibitionof soybean root growth upon treatment with 1·73 mM for10 min (Schumacher et al., 1983). In addition, the sensitivityof roots to NR may vary among plant species. Selectively protectingroots from light is not an easy task with the tiny seedlingsof arabidopsis. In the case of algae, exclusion of light iseven more problematic. In fact, these organisms seem to be especiallysensitive to NR. In a study of Chlamydomonas reinhardtii, 8µM NR was almost lethal and 5 µM strongly inducedmany oxidative and general stress response genes (Fischer etal., 2005). NR further interacted with the photosynthetic apparatuscausing the down-regulation of many photosynthetic genes andthe inhibition of photosynthetic electron flow (Fischer et al.,2005). Even moderate concentrations of the weak base NR arealso capable of increasing the vacuolar pH by 0·2–0·3units (50 µM; Felle, 1988). Based on the authors' experiencesand the caveats from the literature, the concentration of NRand the staining time was kept to a minimum. Transfer of theprotocol to other plant species might require additional optimizationand should consider the photosensitizing property of the dye.

In the current study, a range of NR concentrations from 0·4to 40 µM at pH 5·8 and 8·0 was tested. Thelowest concentration tested with CLSM gave a red signal bothin the xylem and in Casparian bands though in some cases thisconcentration was too low for the dye to penetrate into internalroot tissues. It was demonstrated that even low concentrationsof NR rapidly penetrate internal tissues of intact living plantroots at pH 5·8. As such it can potentially be used inthe studies which require time-lapse analysis.

It has been reported that at acidic pH, NR in its predominantlycationic form stains only cell walls and cannot be detectedin vacuoles (Stadelmann and Kinzel, 1972). The fact that, atthis pH, vacuoles could be visualized, both in the root capand in the cells of the transition zone, indicates that NR canbe detected with a CLSM at relatively low concentrations (1µM and 4 µM at pH 5·8), whereas it was undetectableunder a bright-field microscope (346 µM; Stadelmann andKinzel, 1972).

NR for visualization of cell walls and its components with CLSM
The present results show that at both acidic and alkaline pH,NR even at the lowest concentration tested (0·4 µM)has high affinity to lignin and suberin. At acidic pH, cellwalls are also stained. In the present work, this non-specificstaining of cell walls proved beneficial, since under theseconditions all cell layers and, hence, the root anatomy canbe observed without sectioning. This approach is in clear contrastto the established histochemical protocols which aim at selectivestaining of acidic compartments (Stadelmann and Kinzel, 1972).Staining at the pH of the culture medium is, of course, alsogentler than a shift to an alkaline pH. For staining of specialcell wall regions like the Casparian band, an increase in pHimproved the specificity as observed in bright-field microscopy.

NR provides easy orientation in mutants with abnormal roots
In scr mutants, only one tissue layer is developed in the groundtissue (Fukaki et al., 1998; Fig. 4C). In scr-1 and scr-2 mutants,the single layer has features of both cortex and endodermis(Di Laurenzio et al., 1996). The question of whether this isalso the case for the scr-3 mutant had hitherto not been studied(H. Fukaki, pers. comm.). With the help of NR staining and CLSM,Casparian bands could be detected easily (Fig. 4C) without furtherprocessing of the roots. In mutants that have various defectsin the development of vascular tissue, such as wol, wooden leg(Scheres et al., 1995), eli, ectopic lignification (Caño-Delgadoet al., 2000) or elp, ectopic deposition of lignin in pith (Zhonget al., 2000), xylem elements were studied using either rootsections or fixed material. The prsent data indicate that withthe use of NR, similar studies can be done on living roots,which will simplify the analysis of ontogenetic changes in development.

Staining of subcellular compartments
While staining unmodified cell walls, lignin and suberin seemto work in the same way for bright-field microscopy and CLSM,staining of some subcellular compartments differs markedly betweenthe two techniques. The staining of cytoplasm has been observedin earlier light microscopical studies (Guttenberger, 2000a)and might be due to binding of NR to phospholipids (Okada, 2000)of endomembranes. However, differences in the staining of nucleiand vacuoles are new phenomena. Using bright-field microscopy,Guttenberger, 2000a) showed acidotropic staining of mature vacuolesof the differentiated root cortex and of the peri-arbuscularspace in mycorrhizal root systems. Here it is reported thatboth compartments are barely detectable in CLSM while structureswithin fungal hyphae are prominent (Fig. 8). The latter probablyarise from fungal vacuoles since these organelles are reportedto accumulate NR (Thatcher, 1939; Dixon et al., 1999). The markeddifference between bright-field and CLSM images is attributableto the fact that the spectral properties of NR, as well as thequantum yield of the fluorescence signal, strongly depend onthe physico-chemical environment of the dye (Dell'Antone etal., 1972; Li et al., 1991; Sousa et al., 1996). In addition,the concentrations of NR employed in the experiments differsubstantially (0·4 µM and 8 µM), which mightinfluence the partitioning between stained structures. Hence,staining properties judged by light and fluorescence microscopyare poorly comparable in the case of acidic compartments. Itshould be mentioned that the vacuolar system in the fully elongatedcells could only be detected at alkaline pH, while vacuolesin the root cap and in the transition zone were visualized witha similar resolution independent of the pH of the staining solution.This difference in the staining properties is probably due tothe presence of phenolic substances in the latter vacuoles (fullcell saps; Stadelmann and Kinzel, 1972).

The faint staining of nuclei in bright-field microscopy (Guttenberger,2000a), which is not visible in fluorescence images (Fig. 4Aand 8), is another example of differences between the microscopicaltechniques. Further studies are required to investigate theunderlying staining mechanisms and the exact subcellular localizationof NR.

The observed development of large central vacuoles from numeroussmall prevacuoles supports earlier findings (Marty, 1999; Abrahamset al., 2003). In the future, a combination of NR with differentforms of GFP-fusion proteins, such as the lytic vacuole markeror the protein storage vacuole marker (Flückiger et al.,2003), could be valuable for the studies of vacuolar systembiogenesis. In a different system, in GFP-marked Fusarium oxysporum,NR-stained vacuoles of the fungi also did not affect GFP fluorescence(Nonomura et al., 2003).

Neutral red for developmental studies
In developmental studies of living roots, it is frequently achallenge to detect internal root tissues within the differentiationzone. The apoplasmic tracer, propidium iodide, commonly usedfor plant roots, detects cell walls within the root apical meristem(Van den Berg et al., 1995), but in the differentiation zonedoes not penetrate deeper than the endodermis (Fig. SF4, SupplementaryInformation) even at high concentrations (J. G. Dubrovsky, pers.obs.). If the root can be sacrificed, the staining of 5–10mm root portions with propidium iodide gives satisfactory results(Dubrovsky et al., 2006). It is demonstrated here that the useof NR provides a solution for this problem. Good penetrationof NR into internal root tissues and detection of proto- andmetaxylem permits easy detection of pericycle cell layers andof the plane in which the root is oriented. For example, tangentiallongitudinal optical sections of the root oriented in the protophloemplane, and visualization of the protoxylem with NR, permittedprotoxylem-adjacent pericycle cells expressing GFP to be seen(Fig. 7E). These observations, together with transverse sections(Fig. 7F), confirm that three pericycle cell files adjacentto the protoxylem participate in primordium formation (Dubrovskyet al., 2001). It was found that the overall appearance of theactin cytoskeleton in these cells was similar, both in situand in vivo, to the pattern reported previously (Balu $s$ ka et al.,1997, 2001a; Voigt et al., 2005).

Potential limitations
Potential problems with toxicity have already been mentioned.If living roots are to be analysed, their thickness, level oftissue differentiation, lignification and autofluorescence,as well as metabolites that quench the fluorescence signal ofNR are important factors that may not permit the use of NR.In addition, it is known that laser light penetrates no deeperthan 10–200 µm depending on the refractive indexof the tissues (Paddock, 1999). When thick roots are studied,excised root portions (as for P. vulgaris in this study; Fig. 6E, F)or transverse hand sections can be analysed. The slow stainingkinetics is currently not encouraging for the use of NR in theroot apical meristem. Since the composition of the incubationmedium also had a strong influence on the staining of the meristemregion, further optimization is required in this case.

Conclusion
The current study demonstrates the usefulness of NR for variousCLSM studies of roots. NR emerges as an easily applied, inexpensiveprobe for CLSM with affinity to suberin and lignin, the abilityto penetrate rapidly into internal root tissues, accumulationin vacuoles, and low toxicity. Unlike widely used propidiumiodide, NR also penetrates into the inner parts of roots andserves as an apoplasmic as well as symplasmic stain. Apoplasmicstaining can be reduced by an increase in the pH of the stainingsolution. The staining properties of NR are summarized in Table 1.The most prominent application of NR in conjunction with CLSMis the possibility of analysing internal root structure withoutthe expensive and time-consuming procedures of tissue processingsuch as fixation, embedding and sectioning. The current workillustrates only some of the possible applications of NR. Itcertainly can be used to study further aspects of plant rootsas well as other plant organs.

SUPPLEMENTARY INFORMATION

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Supplementary figures and a movie, as detailed in the text,are available online at http://aob.oxfordjournals.org/.

ACKNOWLEDGEMENTS

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We thank Drs P. Benfey and J. Haseloff, and the ArabidopsisBiological Resource Center for seeds of scr-3, J0121 and J1701,as well as Drs J. Friml, R. Cyr and N.-H. Chua for their kinddonation of PIN1:GFP, GFP-MAP4 and GFP-mTn arabidopsis lines.We also thank Dr K. Schumacher for helpful discussions, theLeica Vertrieb Bensheim for help with the mycorrhiza images,Mr J. M. Hurtado-Ramirez for logistic help, Dr P. Brewer forcorrecting the English, and Dr N. Doktor for help with art work.J.G.D. was supported by Programa de Apoyo a Proyectos de Investigacióne Innovación Tecnológica (PAPIIT), UniversidadNacional Autónoma de México (UNAM), Projects IN210202 and IX225304, and by the Exchange Program between UNAM(Mexico) and DAAD (Germany).

LITERATURE CITED

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ABSTRACT
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RESULTS
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LITERATURE CITED

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				J. G. Dubrovsky, M. Sauer, S. Napsucialy-Mendivil, M. G. Ivanchenko, J. Friml, S. Shishkova, J. Celenza, and E. Benkova Auxin acts as a local morphogenetic trigger to specify lateral root founder cells PNAS, June 24, 2008; 105(25): 8790 - 8794. [Abstract] [Full Text] [PDF]