Molecular and Physiological Responses to Water Deficit in Drought-Tolerant and Drought-Sensitive Lines of Sunflower . Accumulation of Dehydrin Transcripts Correlates with Tolerance

doi:10.1104/pp.116.1.319

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Molecular and Physiological Responses to Water Deficit in Drought-Tolerant and Drought-Sensitive Lines of Sunflower¹
Accumulation of Dehydrin Transcripts Correlates with Tolerance

Françoise Cellier^*, Geneviève Conéjéro, Jean-Christophe Breitler, and Francine Casse

Biochimie et Physiologie Moléculaire des Plantes, Ecole Nationale Supérieure Agronomique de Montpollier/Institut National de la Recherche Agronomique/Centre National de la Recherche Scientifique (Unité de Recherche Associée no. 2133), Université Montpellier II, place Viala 34060 Montpellier cedex 1, France

ABSTRACT

Top
Abstract
Introduction
Methods
Results
Discussion
References

To investigate correlations between phenotypic adaptation to water limitation and drought-induced gene expression, we havestudied a model system consisting of a drought-tolerant line (R1)and a drought-sensitive line (S1) of sunflowers (Helianthus annuusL.) subjected to progressive drought. R1 tolerance is characterizedby the maintenance of shoot cellular turgor. Drought-induced genes(HaElip1, HaDhn1, and HaDhn2) were previously identified in thetolerant line. The accumulation of the corresponding transcriptswas compared as a function of soil and leaf water status in R1and S1 plants during progressive drought. In leaves of R1 plantsthe accumulation of HaDhn1 and HaDhn2 transcripts, but not HaElip1transcripts, was correlated with the drought-adaptive response.Drought-induced abscisic acid (ABA) concentration was not associatedwith the varietal difference in drought tolerance. Stomata ofboth lines displayed similar sensitivity to ABA. ABA-induced accumulationof HaDhn2 transcripts was higher in the tolerant than in the sensitivegenotype. HaDhn1 transcripts were similarly accumulated in thetolerant and in the sensitive plants in response to ABA, suggestingthat additional factors involved in drought regulation of HaDhn1expression might exist in tolerant plants.

INTRODUCTION

Top
Abstract
Introduction
Methods
Results
Discussion
References

Whole plants respond to drought through morphological, physiological, and metabolic modifications occurring in all plant organs.At the cellular level plant responses to water deficit may resultfrom cell damage, whereas other responses may correspond to adaptiveprocesses. Although a large number of drought-induced genes havebeen identified in a wide range of plant species, a molecularbasis for plant tolerance to water stress remains far from beingcompletely understood (Ingram and Bartels, 1996). The rapid translocationof ABA in shoots via xylem flux and the increase of ABA concentrationin plant organs correlate with the major physiological changesthat occur during plant response to drought (Zeevaart and Creelman,1988). It is widely accepted that ABA mediates general adaptiveresponses to drought. However, there is evidence suggesting thatadditional signals are involved in this process (Munns and King,1988; Trejo and Davies, 1991; Munns et al., 1993; Griffiths andBray, 1996).

Six cDNAs corresponding to transcripts up-regulated by water stress were isolated previously from a drought-tolerant sunflower(Helianthus annuus L.) line, R1 (Ouvrard et al., 1996). Comparisonof the steady-state level of transcripts between the R1 line anda closely related drought-sensitive line, S1, has shown that threeof those transcripts (HaElip1, HaDhn1, and HaDhn2) were differentlyaccumulated in tolerant compared with sensitive plants duringwater deficit. In response to exogenous ABA in leaves of the R1genotype, HaDhn1 and HaDhn2 transcripts were up-regulated andthe steady-state level of HaElip1 transcripts was not modified(Ouvrard et al., 1996). HaDhn1- and HaDhn2-deduced proteins belongto the dehydrin family, and HaElip1 is a related homolog of early-light-inducedprotein (ELIP).

Among the water-stress-induced proteins so far identified, dehydrins, the D-11 subgroup of late-embryogenesis-abundant (LEA)proteins (Dure et al., 1989) are frequently observed, and morethan 65 plant dehydrin sequences are available (Close, 1997).Dehydrins are highly abundant in desiccation-tolerant seed embryosand accumulate during periods of water deficit in vegetative tissues.These proteins display particular structural features such asthe highly conserved Lys-rich domain predicted to be involvedin hydrophobic interaction leading to macromolecule stabilization(Close, 1996).

Very little is known about dehydrin functions in planta. Studies have established correlations between drought adaptationand dehydrin accumulation in wheat and poplar (Labhilili et al.,1995; Pelah et al., 1997). Positive correlations were also reportedfor species tolerant to stresses that have a dehydrative componentsuch as salt stress (Galvez et al., 1993; Moons et al., 1995)and freezing and cold stress (Arora and Wisniewski, 1994; Danyluket al., 1994; Close, 1996; Artlip et al., 1997). Physiologicalobservations associated with the varietal difference in tolerancehave been reported (Moons et al., 1995; Pelah et al., 1997). Inmost of the published studies gene expression was described asa function of time after the stress was applied rather than asa function of parameters describing the plant's water status.Therefore, it is difficult to determine from these data preciserelationships between plant physiological responses to droughtand drought-induced gene expression.

In the present paper we report putative correlations between the preferential accumulation of dehydrins and HaElip1 transcriptsin tolerant plants and physiological parameters describing planthydric status during progressive drought. The accumulation oftranscripts is compared between the two lines as a function ofsoil water content and leaf water potential. Drought-induced ABAlevel, ABA-induced stomatal closure, and ABA-induced accumulationof HaDhn1 and HaDhn2 transcripts is compared between both lines.Results are discussed with regard to a possible role of the genesrelated to drought adaptation in plants.

	MATERIALS AND METHODS

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Plant Material and Growth

The R1 (drought-tolerant) and S1 (drought-sensitive) genotypes of sunflowers (Helianthus annuus L.) were supplied by Rhône-PoulencAgrochimie (Lyon, France) and have been described previously (Ouvrardet al., 1996

). Seeds of each genotype were surface sterilizedwith 1% (w/v) sodium hypochlorite and germinated on water-moistenedfilter paper for 48 h in the dark at 25°C. Depending on the treatment,seedlings were transferred in composite soil (peat compost:vermiculite,1:1) or in vermiculite. Plants were grown in a greenhouse under16 h of light, 24/25°C (night/day), 60 to 80% RH, and 300 µE m² s¹ minimum light.

Drought Treatment

Plants of each line were grown in composite soil (peat compost:vermiculite, 1:1) for 15 d in a 0.5-L pot and were then transferredto a 3-L pot. Plants were watered daily and fertilized weeklywith a complete nutrient solution. One-month-old plants of eachline were subjected to progressive drought by withholding water.Control plants of each line were watered daily. Every day, young,fully expanded leaves were collected from individual plants ofeach line for physiological measurements and frozen separatelyfor RNA extraction. Each pot was weighed daily at 9 am and gravimetricsoil water content was measured as grams of water per gram ofoven-dried soil. The predawn leaf water potential (Tardieu etal., 1990

) and the leaf water potential were measured daily, 1h before sunrise (5 am, solar time) and at midday (12 pm, solartime), respectively, using a pressure chamber. Each measurementwas replicated on four to six individual, nonirrigated plantsand three control plants of each line. At midday, 100 µL of xylemsap was extracted at a pressure of about 0.5 MPa above the balancingpressure. Sap samples were stored at $-$ 80°C for subsequent ABAanalysis by radioimmunoassay (Quarrie et al., 1988

). Throughoutthe experiment, the light intensity measured at midday was between600 and 800 µE m² s¹. The experiment was repeated once.

ABA Treatment

Forty seedlings of each line were transferred to a 0.5-L pot containing vermiculite and grown in a greenhouse. Pots were soakedevery day in complete nutrient solution. Three-week-old plantswere transferred to hydroponic conditions in 1× Hoagland solution(Hewitt and Smith, 1975

), which was renewed every 2 d. ABA wasadded to a final concentration of 10 µm 5 d after the transferat 6 am (solar time). Stomatal conductance was measured from 8am to 4 pm (solar time) using a diffusion porometer (Delta T,Cambridge Life Sciences, Cambridge, UK). Twenty plants of eachline were treated with ABA as described above and the other plantswere used as controls. The experiment was repeated once.

Nomenclature

Nomenclature for sdi genes corresponding to specific cDNA clones isolated previously from sunflowers (Ouvrard et al., 1996

)will be introduced here according to the homology of the deducedprotein with known proteins. sdi-1 (accession No. X02646),sdi-5 accession No. X92647), and sdi-8 (accession No. X92650)were renamed HaElip1, HaDhn1, and HaDhn2, respectively.

Northern Analysis

Total RNA was extracted as described previously (Ausubel et al., 1991

). Total RNA samples (10 µg) were resolved by electrophoresison Mops-formaldehyde agarose gel (Lehrach et al., 1977

) and blottedto a Hybond-N nylon membrane (Amersham). Northern-blot hybridizationsto randomly primed radiolabeled probes (Prime-a-Gene LabelingSystem, Promega) were performed at 46°C in 50% formamide, 5× SSPE(0.72 m NaCl, 0.05 m NaH₂PO₄, and 5 mm EDTA, pH 7.4), 1% Sarkosyl(Sigma), 10% dextran sulfate, and 100 µg/mL salmon sperm DNA.Membranes were washed at room temperature in 2× SSC and 0.1% SDSfor 20 min, at 46°C in the same buffer for 20 min, and then twiceat 55°C in 0.1× SSC and 0.1% SDS for 20 min. The BamHI 25S rDNAfragment from H. annuus HA89 was used as a control probe (Choumaneand Heizmann, 1988

). Signal intensities of autoradiograms werequantified with imaging software (version 2.03, Appligene, Pleasanton,CA) and subsequently analyzed with NIH Images version 1.57 software.Each signal determination was repeated at least twice, and eachblot was triplicated. Loading differences were less than 10% inblots presented in this paper.

Isolation of Genomic DNA and Southern Analysis

Genomic DNA was extracted from leaves according to the method of Dellaporta et al. (1983)

. DNA (15 µg) was digested by restrictionendonucleases and resolved by electrophoresis on 0.8% Tris-acetate-EDTA-agarosegels. DNA was blotted to a Hybond-N⁺ nylon membrane (Amersham) in 0.4 n NaOH. Hybridization at 42°Cand washes were performed as described for the northern analysis.

	RESULTS

Top Abstract Introduction Methods Results Discussion References

Amino Acid Sequence Comparison of HaDhn1 and HaDhn2 Dehydrins

The HaDhn1 cDNA sequence was reported previously (Ouvrard et al., 1996

). The complete nucleotide sequence of the full-lengthHaDhn2 cDNA was determined. HaDhn1- and HaDhn2-deduced proteinsbelong to the dehydrin family (Ouvrard et al., 1996

) and sharethe characteristic features of these proteins. Dehydrins are characterizedby three consensus sequences referred to as segments Y, S, andK (Close, 1996

). Dehydrins were classified into five distincttypes using the YSK nomenclature and depending on the copy numbersof each segment (Close, 1996

). HaDhn1 belongs to the YnSK2 typeof dehydrin and HaDhn2 belongs to the SK2 type.

Genomic Organization of HaDhn1, HaDhn2, and HaElip1 Genes

Southern experiments were performed using each cDNA insert as a probe (Fig. 1A). Hybridization patterns indicated that homologsof the R1 genes were present in the S1 genome.

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Figure 1. Southern analysis of genomic DNA from R1 and S1 sunflower genotypes. Total DNA was digested with EcoRI (E) and HindIII (H),separated on an agarose gel, and transferred to a nylon membrane.A, Membranes were probed with ³²P-labeled cDNA as indicated. B, Membrane was probed with the 3 $'$ noncoding region of HaElip1 cDNA (nucleotides 559 to 795 of HaElip1cDNA full-length sequence).

Complex hybridization patterns were observed with HaElip1 cDNA in both genotypes, indicating that this sequence belongs toa multigenic family. R1 and S1 genotypes displayed similar hybridizationpatterns, except for the presence of two additional low-molecular-weightHindIII fragments in the R1 genome. The experiment was repeatedusing the 3 $'$ noncoding region of HaElip1 (HaElip1/3 $'$ end) cDNAas a probe (Fig. 1B). Southern analysis with the 3 $'$ end-specificprobe revealed a single hybridizing fragment in both genotypes,indicating that this probe is probably specific to one of theHaElip1 genes that are common to both genotypes. Therefore, theHaElip1/3 $'$ end-specific probe was used for all of the northernexperiments described in this paper.

Identical hybridization patterns showing a single hybridizing fragment were obtained with HaDhn1 cDNA in both lines. HaDhn1is likely to be present as a single-copy gene in both genotypes.A low number of hybridizing fragments was obtained with HaDhn2cDNA, suggesting that the corresponding genes are present in thegenome at a low copy number. The hybridization pattern obtainedwith HaDhn2 was identical in both genotypes, indicating that theHaDhn2 genomic organization is similar in the two lines.

Physiological Characterization of Drought Stress

Progressive drought was initiated by withholding water from plants grown in soil. Soil and leaf water statuses of R1 and S1plants were monitored by measuring the gravimetric soil watercontent and the leaf water potential. The leaf water potentialevaluates the water-stress intensity sensed by leaves (Hsiao,1973

). Soil water potential was estimated by measuring the predawnleaf water potential, as described previously (Tardieu et al.,1990

). The predawn leaf water potential is an averaged indicatorof soil water status near the root system. The predawn leaf waterpotential and the gravimetric soil water content evaluate thehydric conditions experienced within the soil. Both parametersdecreased similarly for R1 and S1 lines after the last watering(Fig. 2A). The predawn leaf water potential of irrigated plantsremained between $-$ 0.2 and $-$ 0.25 MPa during the experiment.

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Figure 2. Soil and leaf water status of R1 ( $bullet$ ) and S1 ( $square$ ) plants during progressive drought initiated by withholding water. A, Predawnleaf water potential as a function of gravimetric soil water content(grams of water per gram of dry soil). B, Leaf water potentialas a function of gravimetric soil water content (grams of waterper gram of dry soil). Leaf water potential and gravimetric soilwater content values are the means ± se of four to six measurementsdetermined from four to six individual plants.

As reported previously (Ouvrard et al., 1996), the leaf water potential of the tolerant, nonirrigated plants started to declineafter a delay, and this rate of decrease was lower than the leafwater potential of sensitive, nonirrigated plants (Fig. 2B). Wiltingof S1 leaves was observed with a soil water content of 2.1 g waterg¹ dry soil, whereas R1 leaves were wilted with a soil water contentvalue of less than 0.5 g water g¹ dry soil.

Time Course of Accumulation of HaDhn1, HaDhn2, and HaElip1 Transcripts in R1 and S1 Sunflower Plants during Progressive Drought

The accumulation of HaDhn1, HaDhn2, and HaElip1 transcripts was compared in the R1 and S1 sunflower lines as a function ofsoil and leaf water status during progressive drought. Fully expandedleaves from four to six individual plants of each line were collectedand analyzed separately (Fig. 2B). Total RNA was extracted andanalyzed by northern hybridization using each cDNA as a probe.An equal amount of RNA loading was systematically assessed byprobing each blot with a 25S rDNA (Choumane and Heizmann, 1988

The accumulation of HaDhn1, HaDhn2, and HaElip1 transcripts was compared in plants of the two lines as a function of soilwater content (Fig. 3). The steady-state level of HaElip1 transcriptsincreased rapidly in response to soil dehydration in both lines.HaElip1 transcripts did not accumulate simply as a function ofsoil water content. The pattern of accumulation was similar inthe two lines, although weak differences were observed. HaDhn1and HaDhn2 transcripts, which were not detected in plants watereddaily, accumulated in response to soil dehydration in leaves ofboth lines. Major differences were observed between the R1 andthe S1 plants. In the sensitive plants, the steady-state levelof these transcripts increased gradually until the soil watercontent reached a value of 2 g water g¹ dry soil and then remained unchanged as the soil water contentdecreased. In the R1 plants, when the soil water content declinedbelow this value, the steady-state levels of HaDhn1 and HaDhn2transcripts were strongly increased. For a soil water contentof 1.1 g water g¹ dry soil, HaDhn1 and HaDhn2 transcripts accumulated 5- and 3-foldhigher, respectively, in leaves of R1 compared with S1 plants.

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Figure 3. Accumulation of HaDhn1, HaDhn2, and HaElip1 transcripts in leaves of R1 and S1 plants subjected to progressive drought asa function of gravimetric soil water content (grams of water pergram of dry soil). Total RNA was purified from R1 ( $bullet$ ) or S1 ( $square$ )individual leaves collected as indicated from all of the plantsdescribed in Figure 2B. RNA (10 µg) was analyzed by northern-blothybridization using HaDhn1, HaDhn2, and HaElip1/3 $'$ end as probes.Hybridization signals were quantified by densitometric analysis.The strongest hybridization signal was set at 10 and the otherswere quantified on the basis of this signal. The relative mRNAlevels are the means ± se of four to six measurements quantifiedseparately from individual plants. Gravimetric soil water contentvalues are the means of measurements determined on the correspondingplants described in Figure 2B.

Because plants of the two lines clearly displayed different leaf water potentials when the gravimetric soil water contentwas the same, the above data are not fully representative of therelationship between transcript accumulation and leaf hydric status.Therefore, the accumulation of each transcript was compared inR1 and S1 plants as a function of their leaf water potential (Fig.4). Equivalent leaf water potentials were observed in R1 and S1plants for different soil water contents (Fig. 2B). In leaveswith water potentials between $-$ 0.3 and $-$ 0.6 MPa, each transcriptaccumulated at a similar level in both lines. Below these values,the accumulation of HaElip1, HaDhn1, and HaDhn2 transcripts wasdifferent between R1 and S1 plants.

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Figure 4. Accumulation of HaDhn1, HaDhn2, and HaElip1 transcripts as a function of leaf water potential in R1 and S1 plants subjectedto progressive drought. Total RNA was purified from R1 (blackbars) or S1 (white bars) individual leaves collected separatelyfrom the plants described in Figure 2B. RNA (10 µg) was analyzedby northern-blot hybridization using HaDhn1, HaDhn2, and HaElip1/3 $'$ end as probes. Hybridization signals were quantified by densitometricanalysis. The strongest hybridization signal was set at 10 andthe others were quantified on the basis of this signal. The relativemRNA levels are the means ± se of 6 to 10 measurements quantifiedseparately from individual plants.

In leaves of R1 plants, the steady-state level of each transcript increased gradually as the water potential declined. Inthe S1 plants the fluctuations of the steady-state level of HaElip1transcripts were not correlated with the decreases in leaf waterpotential. Similar levels of HaElip1 transcripts were accumulatedin S1 and R1 plants except in leaves with water potentials between $-$ 0.9 and $-$ 1.2 MPa. Steady-state levels of HaDhn1 and HaDhn2 transcriptsin S1 plants remained low and constant in leaves with a waterpotential of less than $-$ 0.6 MPa. At an equivalent water potential,they accumulated at a higher level in R1 than in S1 leaves. Ata leaf water potential between $-$ 1.2 and $-$ 1.5 MPa, steady-statelevels were 9- and 5-fold higher, respectively, in leaves of R1compared with S1 plants.

Changes in Xylem ABA Concentration upon Progressive Drought and ABA-Induced Expression of HaDhn1 and HaDhn2 Genes

Time-course measurements of ABA concentration in xylem sap upon progressive drought were compared in both R1 and S1 sunflowerlines (Fig. 5). The decline in soil water content induced a similarincrease in xylem ABA concentration in R1 and S1 plants.

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Figure 5. Concentration of ABA in R1 ( $bullet$ ) and S1 ( $square$ ) xylem sap as a function of soil water content (grams of water per gram of dry soil).Each point represents a coupled value of xylem ABA of one leafand the soil water content of the corresponding plant. Data arethe result of one representative experiment.

R1 and S1 plants were grown under hydroponic conditions to allow an exogenous supply of ABA. ABA was added 6 h before midday(6 am solar time). To monitor the response of plants to exogenousABA, the stomatal conductance of R1 and S1 sunflower plants wasmeasured during ABA treatment (Fig. 6). For plants of both linesthe stomatal closure occurred within 6 h after the addition ofABA. From midday to 4 pm stomatal conductance of ABA-treated plantswas lower in R1 than in S1. At midday untreated R1 plants displayedhigher maximal conductances than untreated S1 plants. However,when the abaxial and adaxial stomata were counted, this differencewas found not to be due to a higher density of stomata in R1 thanin S1 leaves (data not shown).

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Figure 6. Stomatal conductance of R1 (A) and S1 (B) in response to ABA. Plants were grown in hydroponic conditions supplemented ( $bullet$ , $black-square$ ) or not ( $open circle$ , $square$ ) with 10 µm ABA. The addition of ABA was performedat 6 am (solar time). Stomatal conductance was determined from8 am to the end-of-the-day period on control and ABA-treated R1and S1 plants. Each point is the mean value of two opposite leavesfrom the same plant. The bar at the top indicates the light/darkperiod under which the plants were grown (white bar, light period;black bar, dark period). Hours refer to the solar time at whichthe measurements were determined.

Total RNA was purified from fully expanded leaves collected separately from three to four individual plants of each line andanalyzed by northern hybridization. Because previous work demonstratedthat the accumulation of HaDhn1 and HaDhn2 transcripts, but notHaElip1 transcripts, was modified in response to ABA, only HaDhn1and HaDhn2 cDNAs were used as probes (Fig. 7). HaDhn1 and HaDhn2transcripts were detected in both lines after 6 h of treatment.The steady-state level of HaDhn1 transcripts accumulated was equivalentin both lines, regardless of the time after the treatment. Itdeclined to a barely detectable level 12 h after the additionof ABA at the end of the 1st d, then increased to a maximum after28 h during the 2nd d, and finally decreased again at the beginningof the 3rd d after 48 h of treatment.

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Figure 7. Time course of accumulation of HaDhn1 and HaDhn2 transcripts in response to ABA in leaves of tolerant (black bars) and sensitive(white bars) plants. Total RNA was purified from leaves of R1and S1 sunflowers cultivated in hydroponic medium supplementedor not with 10 µm of ABA. RNA (10 µg) extracted from plants 6,12, 28, and 48 h after the addition of ABA or from control plants(lane C) was analyzed by northern-blot hybridization with theindicated probes. Hybridization signals were quantified by densitometricanalysis. The strongest hybridization signal was set at 10 andthe others were quantified on the basis of this signal. Valuesare means ± se of three to four independent replicates. The barsat the top indicate the light/dark period under which the plantswere grown (white bar, light period; black bar, dark period).Hours refer to the solar time at which the samples were collected.

The oscillation in the amount of ABA-induced HaDhn1 transcripts seemed to follow the day/night cycle of the greenhouse usedto grow the plants. The steady-state level of HaDhn2 transcriptsthat accumulated in response to ABA was equivalent after 6 h oftreatment in both lines but later increased to a much higher levelin R1 than in S1 plants. In the R1 line the steady-state levelof transcripts continued to increase, reaching a maximum after28 h and then decreasing at 48 h. In S1 only slight variationsin the steady-state level of HaDhn2 transcripts were observedand paralleled those occurring in R1.

	DISCUSSION

Top Abstract Introduction Methods Results Discussion References

To investigate correlations between phenotypic adaptation to water limitation and drought-induced gene expression, we havecharacterized a model system consisting of a drought-tolerant(R1) and a drought-sensitive (S1) line of sunflowers subjectedto progressive drought. Drought was monitored by measuring thegravimetric soil water content, the predawn leaf water potential,and the leaf water potential. The predawn leaf water potential,which is considered to be an indicator of hydric conditions experiencedwithin the soil (Tardieu et al., 1990), decreased similarly forboth lines as a function of the decline of gravimetric soil watercontent. Therefore, both lines were subjected to an equivalentwater limitation.

In anisohydric plants, including sunflowers, leaf water potential has been shown to decrease in response to soil dehydration(Sadras et al., 1993a, 1993b). This was also observed here inthe R1 and S1 plants. However, compared with S1, decreases inleaf water potential and wilting were delayed in R1 leaves. Inanisohydric species, avoiding a rapid decrease of leaf water potentialin response to soil dehydration is likely to correspond to a drought-tolerancemechanism. Since, as shown previously, the osmotic potential decreasessimilarly in both lines during progressive drought (Ouvrard etal., 1996), R1 tolerance can be characterized by the maintenanceof shoot cellular turgor. The maintenance of cellular turgor bylowering the osmotic potential in plants exposed to low-water-potentialconditions may be explained by osmotic adjustment (Turner andJones, 1980), which may occur either through the uptake of solutesor by the breakdown of osmotically inactive compounds (Turnerand Jones, 1980). Osmotic adjustment is considered to be one ofthe most important mechanisms of plant adaptation to environmentalstresses affecting water content (Turner, 1986; Munns, 1988).Additional experiments are needed to determine whether such amechanism is involved in the maintenance of cellular turgor inleaves of R1 plants subjected to water limitation.

Drought-induced genes were previously identified in the drought-tolerant line of sunflowers (Ouvrard et al., 1996). The accumulationof HaDhn1, HaDhn2, and HaElip1 transcripts was compared in tolerantand sensitive plants subjected to progressive drought. The threegenes were up-regulated in leaves of plants subjected to soildehydration. The kinetics of HaElip1 transcript accumulation asa function of soil water content were complex in both lines. Insensitive plants the large fluctuations of the steady-state levelof the transcripts suggest that, in addition to water stress,other environmental factors also influenced HaElip1 gene expression.It was reported that light is an essential positive factor regulatingdehydration-mediated expression of the Elip-like dsp22 gene (Bartelset al., 1992). In addition, in barley the level of accumulationof the Elip transcript Hv90 was found to depend on light intensity(Montané et al., 1997). Therefore, although leaf samples werecollected daily at midday, variations of light intensity duringthe experiment could have influenced HaElip1 gene expression.

R1 and S1 plants subjected to progressive drought display differential accumulation of HaDhn1 and HaDhn2 transcripts in leaves.Both transcripts accumulated to much higher levels in R1 thanin S1 plants as the soil water content declined toward low values.This difference was also observed in R1 and S1 plants with similarleaf water potentials but with different soil water content. Thus,the low level of HaDhn1 and HaDhn2 transcripts in S1 leaves wasnot related to the low leaf water potential resulting from waterlimitation. Furthermore, because HaElip1 transcripts continuedto accumulate in S1 leaves with a water potential was of lessthan $-$ 0.9 MPa, it is unlikely that a general shutdown of the transcriptionrate might occur in the S1 plants during progressive drought.These results suggest that the preferential accumulation of transcriptsof the dehydrins HaDhn1 and HaDhn2 in R1 leaves is associatedwith the adaptive response occurring in these plants subjectedto water limitation. However, we cannot rule out the possibilitythat changes in mRNA processing or stability may be the underlyingcause of the observed increase in the mRNA levels.

The differential accumulation of HaDhn1 and HaDhn2 transcripts in tolerant and sensitive plants may result from differencesin the genomic organization of the corresponding genes betweenthe two lines. Results of Southern hybridization demonstrate thatthe R1 line does not possess additional genes compared with theS1 one. We therefore hypothesize that HaDhn1 and HaDhn2 genesare subjected to a different regulation in the two lines.

Varietal differences in tolerance may be associated with increases of ABA levels in response to various environmental stresses.This includes drought tolerance of maize (Pekic and Quarrie, 1987),chilling tolerance of rice seedlings (Lee et al., 1993), and salttolerance of rice (Moons et al., 1995). Extensive studies haveshown that the decrease in leaf conductance is closely relatedto the increase in xylem ABA, suggesting that ABA can act as awater-stress signal to regulate stomatal conductance (Zhang andDavies, 1989, 1991; Davies and Zhang, 1991; Tardieu et al., 1992).

In sunflowers stomatal control depends only on the concentration of ABA in the xylem sap (Tardieu et al., 1996); stomatalclosure in response to water stress is one of the drought-adaptationmechanisms. However, the concentration of ABA in xylem sap wasequivalent in tolerant and sensitive sunflowers subjected to waterdeficit, indicating that this parameter is not related to varietaldifferences in tolerance of the R1 and S1 lines. Furthermore,the kinetics of stomatal closure in response to exogenous ABAwere equivalent in both lines, indicating that R1 and S1 plantsdisplay similar sensitivity to ABA in regard to this physiologicalresponse.

ABA is involved in drought regulation of many genes (Chandler and Robertson, 1994; Giraudat et al., 1994). Dehydrin genesare up-regulated in response to exogenous ABA in vegetative tissues(for review, see Bray, 1994). ABA-induced expression of HaDhn1and HaDhn2 was compared in the two varieties. HaDhn2 transcriptsaccumulated to a higher level in the R1 compared with the S1 plantsin response to exogenously applied ABA. Therefore, the preferentialaccumulation of HaDhn2 transcripts in the tolerant plants in responseto drought could be ABA mediated. The accumulation of HaDhn2 transcriptsat a low level in the S1 line during drought may result from differentABA sensitivities of the corresponding genes between R1 and S1plants.

The changes in the steady-state levels of HaDhn1 transcripts in response to ABA were equivalent in both lines, regardlessof the duration of the treatment. Even though xylem ABA was equivalentin both lines, the total leaf ABA content varied and could thereforeexplain the preferential accumulation of HaDhn1 transcripts inthe R1 plants in response to drought. Additional specific factorsother than ABA might also be present in the R1 plants, triggeringHaDhn1 transcript accumulation upon drought conditions.

Although HaDhn1 and HaDhn2 belong to the same protein family, they respond differently to applied ABA, both in the tolerantand in the sensitive plants. A differential response of dehydrin-relatedgenes to ABA treatments has already been described in rice (Yamaguchi-Shinozakiet al., 1989), pea (Robertson and Chandler, 1994), and Arabidopsisthaliana (Welin et al., 1994), suggesting that the various membersof this family may have different functions in drought responsesin plants.

It has been reported that dehydrin accumulation is correlated with slow dehydration when dehydrin accumulation was comparedin slowly or rapidly dried cereal seedlings, (for review, seeClose et al., 1993). This is supported by the observation in thepresent study that dehydrin transcripts were preferentially accumulatedin leaves in which the water potential decreased slowly in responseto drought. Additional experiments have also confirmed that, inR1 sunflowers subjected to a rapid soil dehydration, dehydrintranscripts were accumulated at a lower level than in plants subjectedto progressive drought (data not shown).

Although the function of dehydrin in plant cells has not been yet elucidated, several hypotheses, mainly deduced from theprotein structure, have been proposed. It has been suggested thatdehydrins may stabilize macromolecules through detergent and chaperone-likeproperties and may act synergistically with compatible solutes(Close, 1996). Dehydrin would protect cytosolic structures fromthe deleterious effects of cellular dehydration (Baker et al.,1988; Dure et al., 1989; Close, 1996). In R1 leaves dehydrin transcriptaccumulation is associated with a tolerance mechanism leadingto the maintenance of cellular turgor, suggesting that dehydrinsmight also be involved in preventing cellular dehydration. However,the accumulation of dehydrin transcripts does not necessarilycorrelate with the content of the corresponding proteins. Thisstudy needs to be extended at the protein level.

	FOOTNOTES

¹ This work was financially supported by the Bio Avenir program financed by Rhône-Poulenc and by Action Incitative Programmeéno. 924840 from the Institut National de la Recherche Agronomique.
^* Corresponding author; e-mail cellier{at}ensam.inra.fr; fax 33-467-525737.

Received July 18, 1997; accepted October 10, 1997.

ACKNOWLEDGMENTS

We are very grateful to Drs. Alain Gojon, Marc Lepetit, and Jean-Pierre Renaudin for stimulating discussions and criticalreading of the manuscript. We also wish to thank Philippe Barrieu(Ecophysiologie des Plantes sous Stress Environnementaux, InstitutNational de la Recherche Agronomique, Montpellier, France) forendogenous ABA measurements and Hugues Baudot for help with raisingthe plants.

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Molecular and Physiological Responses to Water Deficit in Drought-Tolerant and Drought-Sensitive Lines of Sunflower1 Accumulation of Dehydrin Transcripts Correlates with Tolerance

Copyright Clearance Center: 0032-0889/98/116/0319/10 © 1998 American Society of Plant Physiologists

Molecular and Physiological Responses to Water Deficit in Drought-Tolerant and Drought-Sensitive Lines of Sunflower¹
Accumulation of Dehydrin Transcripts Correlates with Tolerance

Copyright Clearance Center: 0032-0889/98/116/0319/10

© 1998 American Society of Plant Physiologists