A Second Mechanism for Aluminum Resistance in Wheat Relies on the Constitutive Efflux of Citrate from Roots

doi:10.1104/pp.108.129155

A Second Mechanism for Aluminum Resistance in Wheat Relies on the Constitutive Efflux of Citrate from Roots¹^,[W]^,[OA]

Peter R. Ryan^*, Harsh Raman, Sanjay Gupta², Walter J. Horst and Emmanuel Delhaize

CSIRO Plant Industry, Canberra, Australian Capital Territory 2601, Australia (P.R.R., S.G., E.D.); EH Graham Centre for Agricultural Innovation, Wagga Wagga, New South Wales 2650, Australia (H.R.); and Institute for Plant Nutrition, University of Hannover, D–30419 Hannover, Germany (W.J.H.)

ABSTRACT

TOP
ABSTRACT
RESULTS
DISCUSSION
CONCLUSION
MATERIALS AND METHODS
LITERATURE CITED

The first confirmed mechanism for aluminum (Al) resistance inplants is encoded by the wheat (Triticum aestivum) gene, TaALMT1,on chromosome 4DL. TaALMT1 controls the Al-activated effluxof malate from roots, and this mechanism is widespread amongAl-resistant genotypes of diverse genetic origins. This studydescribes a second mechanism for Al resistance in wheat thatrelies on citrate efflux. Citrate efflux occurred constitutivelyfrom the roots of Brazilian cultivars Carazinho, Maringa, Toropi,and Trintecinco. Examination of two populations segregatingfor this trait showed that citrate efflux was controlled bya single locus. Whole-genome linkage mapping using an F₂ populationderived from a cross between Carazinho (citrate efflux) andthe cultivar EGA-Burke (no citrate efflux) identified a majorlocus on chromosome 4BL, Xce_c, which accounts for more than50% of the phenotypic variation in citrate efflux. Mendelizingthe quantitative variation in citrate efflux into qualitativedata, the Xce_c locus was mapped within 6.3 cM of the microsatellitemarker Xgwm495 locus. This linkage was validated in a secondpopulation of F_2:3 families derived from a cross between Carazinhoand the cultivar Egret (no citrate efflux). We show that expressionof an expressed sequence tag, belonging to the multidrug andtoxin efflux (MATE) gene family, correlates with the citrateefflux phenotype. This study provides genetic and physiologicalevidence that citrate efflux is a second mechanism for Al resistancein wheat.

Because 30% of the world's ice-free land area has a topsoilpH < 5.5, soil acidity remains a serious obstacle for sustainablefood production (von Uexküll and Mutert, 1995

). Acid soilspresent a range of stresses to plants, including nutrient deficienciesand mineral toxicities (Matsumoto, 2000

; Kochian et al., 2004

),but the major limitation to plant productivity on most acidsoils is aluminum (Al) toxicity (Taylor, 1988

). Soil acidityaccelerates the release of Al from minerals such as gibbsiteand increases the concentration of the toxic Al³⁺ ions in thesoil solution. The Al³⁺ ions can inhibit root growth at micromolarconcentrations by disrupting the metabolically active cellsat the root apex (Ryan et al., 1993

; Sivaguru and Horst, 1998

Some plant species cope with the toxic Al cations better thanothers. Even genotypes within certain species vary widely intheir ability to grow and yield on acid soils. Wheat (Triticumaestivum) shows a large intraspecific variation in Al resistance(Polle et al., 1978; Garvin and Carver, 2003; Stodart et al.,2007; Raman et al., 2008), but establishing the genetic basisfor this variation has proved controversial. Reports are generallydivided into those that propose a single gene model for resistanceand those that argue two or more genes are involved. These conflictingresults arise, in part, from the genetic material used. Forinstance, where near-isogenic lines (NILs) are deliberatelydeveloped to differ at a single locus, the trait can be shownto be monogenic. Where different conclusions have emerged fromstudies of the same parental genotypes, the screening conditions,especially the severity of Al treatment, might have influencedthe conclusions. Clearly, our understanding of the genetic controlfor Al resistance in wheat is incomplete (Garvin and Carver,2003).

Many studies have proposed that a single major gene can accountfor most of the variation in resistance in a range of genotypes(Kerridge and Kronstad, 1968; Camargo, 1981; Delhaize et al.,1993a; Luo and Dvorak, 1996; Somers and Gustafson, 1995; Riedeand Anderson, 1996; Raman et al., 2005, 2008). Indeed, accumulatingevidence is consistent with a major locus on the long arm ofchromosome 4D (4DL) being conserved among wheats of diverseorigins (Luo and Dvorak, 1996; Riede and Anderson, 1996; Maet al., 2005; Raman et al., 2005, 2008; Cai et al., 2008). Themechanism of resistance encoded on the 4DL locus has now beenattributed to the Al-dependent release of malate anions fromroots (Delhaize et al., 1993b; Ryan et al., 1995a, 1995b). Thismodel proposes that malate released from roots protects thesensitive growing apices by binding with and detoxifying theharmful Al³⁺ cations in the apoplast (Delhaize et al., 1993b;Delhaize and Ryan, 1995; Ryan et al., 2001; Kinraide et al.,2005). Sasaki et al. (2004) isolated a cDNA from the root apicesof an Al-resistant wheat genotype ET8, which encodes a membraneprotein (TaALMT1) belonging to a member of a previously uncharacterizedgene family (Delhaize et al., 2007). TaALMT1 is more highlyexpressed in the root apices of Al-resistant wheat lines thansensitive lines and cosegregates with malate efflux and Al resistancein several mapping populations (Sasaki et al., 2004, 2006; Maet al., 2005; Raman et al., 2005; Cai et al., 2008; Raman etal., 2008). Heterologous expression of TaALMT1 in tobacco (Nicotianatabacum) suspension cells and barley (Hordeum vulgare) confirmedTaALMT1 to be an Al-resistance gene (Delhaize et al., 2004;Sasaki et al., 2004). Electrophysiological studies support amodel whereby TaALMT1 functions as a ligand-activated and voltage-dependentanion channel to facilitate malate efflux across the plasmamembrane of root cells (Ryan et al., 1997, 2001; Zhang et al.,2001, 2008; Yamaguchi et al., 2005; Piñeros et al., 2008).TaALMT1 homologs recently characterized in Arabidopsis (Arabidopsisthaliana; AtALMT1) and Brassica napus (BnALMT1, BnALMT2) havealso been shown to encode Al-activated malate transport proteins(Hoekenga et al., 2006; Ligaba et al., 2006). Furthermore, acluster of TaALMT1 homologs on chromosome 7R of rye (Secalecereale; ScALMT1-M39.1 to M39.5) colocalize with a locus-controllingorganic anion efflux and Al resistance (Fontecha et al., 2007;Collins et al., 2008).

Other studies propose that Al resistance in wheat is controlledby two or more genetic loci. Examination of ditelosomic linesgenerated from Chinese Spring identified multiple loci on 5AS,6AL, 7AS, 2DL, 3DL, and 4DL that were contributing to Al resistancein this moderately resistant genotype (Aniol and Gustafson,1984; Aniol, 1990; Papernik et al., 2001). Camargo (1981) mademultiple crosses between Al-resistant genotypes (Atlas 66 andBH1146) with Al-sensitive genotypes (Tordo and Siete Cerros)and concluded that Atlas 66 possessed two dominant genes forAl resistance and that BH1146 possessed a locus geneticallydistinct to either of them. Berzonsky (1992) and Tang et al.(2002) similarly concluded that resistance in Atlas 66 was amultigenic trait. Tang et al. (2002) examined two separate BC₃-derivedNILs developed with Altas 66 and the Al-sensitive genotypesChisholm and Century. Atlas 66 possesses the major locus on4DL, but neither of the NILs was as resistant to Al stress,released as much malate, or was able to exclude Al from theirroot apices as well as Atlas 66. The authors offered two explanationsfor these observations: either multiple loci encode for a singlemechanism of Al resistance (based on malate efflux) or "modifierloci" operate to enhance the malate efflux encoded by the 4DLlocus. This study was unable to support an earlier report thatphosphate efflux contributed to the Al resistance of Atlas 66(Pellet et al., 1996). More recently, a second quantitativetrait locus (QTL) for Al resistance in Atlas 66 was localizedto the long arm of chromosome 3B (3BL) in a population of recombinantinbred lines derived from Chisholm (Zhou et al., 2007). Whilethe loci on 4DL and 3BL collectively accounted for approximately50% of the variation, their effects were not additive becauseexpression of the minor QTL on 3BL (accounting for approximately11% of the variation) was suppressed by the major locus on 4DL(accounting for approximately 45% of the variation). Three significantQTLs for Al resistance on 4DL, 3BL, and 2A were also identifiedin a recombinant inbred line population from a cross betweenChinese wheat lines FSW (Al-resistant) and ND35 (Al-sensitive;Cai et al., 2008). The three QTLs collectively accounted forapproximately 80% of the phenotypic variation for Al resistance,and their effects were additive, which contrasts with the reportby Zhou et al. (2007). Collectively, these studies present acompelling case for a widespread Al-resistance locus on 4DL,as well as multigenic control of Al resistance in some genotypesof wheat.

The efflux of organic anions is an important mechanism for Alresistance in cereal and non-cereal species (for review, seeMa et al., 2001; Ryan et al., 2001; Kochian et al., 2004). Thenature of organic anions released from roots differs betweenspecies. Malate is released from Arabidopsis as well as wheat(Hoekenga et al., 2006), citrate is released from maize (Zeamays), barley, snapbean (Phaseolus vulgaris), and Cassia tora(Miyasaka et al., 1991; Pellet et al., 1995; Ma et al., 1997),and oxalate is released from buckwheat (Fagopyrum esculentumMoench) and taro (Colocasia esculenta; Ma and Miyasaka, 1998;Zheng et al., 1998a). The Al-activated citrate efflux from barleyand sorghum (Sorghum bicolor) is not controlled by ALMT1-likegenes but by members of the multidrug and toxin efflux (MATE)family of genes. For instance, the Al-activated efflux fromsorghum is encoded by SbMATE (Magalhaes et al., 2007), and citrateefflux from barley is encoded by HvAACT1, also designated asHvMATE1 (Furukawa et al., 2007; Wang et al., 2007). More recently,Stass et al. (2008) reported Al-activated citrate efflux fromroots of the highly resistant Brazilian wheat cultivar Carazinhoand suggested that it can influence the Al resistance of triticale(xTriticosecale Wittmack) generated from crosses between Carazinhoand rye.

This study investigates the efflux of citrate from wheat rootsin detail. We provide genetic and physiological evidence thatthis trait is controlled by a single major locus on the longarm of chromosome 4B (4BL) and that it contributes to Al resistance.We also identify a MATE gene whose expression correlates withthe citrate efflux phenotype across several genotypes and ina segregating population of F_2:3 families. These findings areconsistent with citrate efflux being a second major Al resistancemechanism in wheat. To our knowledge, we provide the first physiologicalevidence that Al resistance in wheat can be a multigenic traitinvolving distinct mechanisms.

RESULTS

TOP
ABSTRACT
RESULTS
DISCUSSION
CONCLUSION
MATERIALS AND METHODS
LITERATURE CITED

Characterization of Citrate Efflux from Carazinho

We characterized citrate efflux from the roots of the Braziliangenotype Carazinho using intact seedlings and excised root segments.Cumulative organic anion efflux from intact wheat seedlingswas monitored through time from the Al-resistant genotype Carazinhoand the Al-sensitive genotype Egret. Consistent with the previouslycharacterized mechanism of Al resistance in wheat controlledby TaALMT1 (see introduction), Carazinho released malate fromits roots when exposed to Al but not in control solution (Fig. 1 ).Carazinho also released citrate and, in contrast to the malateefflux, the rates were comparable in the presence and absenceof Al treatment. Egret released little or no malate or citratein either treatment (Fig. 1).

View larger version (13K):
[in this window]
[in a new window]
[as a PowerPoint slide]

Figure 1. Malate and citrate efflux from intact wheat seedlings. Carazinho ( $bullet$ ) or Egret ( ${circ}$ ) seeds were surface sterilized and grown in conical flasks (12 seeds per flask) on a platform shaker with 20 mL of sterile 0.2 mM CaCl₂, pH 4.3. After 6 d, the solution was replaced with similar solutions with (solid line) or without (dashed line) 50 µM AlCl₃. Solutions were replaced at each time point. Malate (A) and citrate (B) concentrations were measured with enzyme assays. Data show the mean and SE (n = 4).

The variation in malate and citrate efflux along Carazinho andEgret roots was monitored using excised root segments (Fig. 2 ).As for intact seedlings, malate efflux from Carazinho was activatedby Al, especially in the apical zone, whereas citrate effluxwas similar in control and Al treatments. Egret showed no changesin the efflux of either anion with Al treatment and very littlevariation along the root. The effluxes measured in Egret areviewed as background rates that include the residual leakagefrom the cut surfaces of the excised tissue. Malate efflux decreasedsteadily back from the root apices of Carazinho so that rates15 mm back were similar to those measured in Egret. Citrateefflux also decreased behind the apex, but there were indicationsthat the rates back from the apex were slightly larger thanin Egret.

View larger version (24K):
[in this window]
[in a new window]
[as a PowerPoint slide]

Figure 2. Distribution of citrate and malate efflux along the root. Malate and citrate efflux were measured in excised root segments of Carazinho and Egret in the presence (black bars) and absence (gray bars) of Al. Root segments were excised from 6-d-old seedlings (six segments per replicate). Treatment solutions were 0.2 mM CaCl₂, pH 4.3, with or without 50 µM AlCl₃. After 2 h, malate (using 0.1 mL of each sample) and citrate (using 0.9 mL) concentrations were measured with enzyme assays. Data show the mean efflux and SE from each section (n = 3).

Citrate efflux from excised root apices was about 10-fold smallerthan malate efflux, which contrasts with the findings from intactseedlings. This may be due to a wider distribution of citrateefflux along the root, but it will also be explained, in part,by the more rapid decrease in citrate efflux from the excisedroot tissues. Malate efflux from excised root apices of Carazinhodecreased by only 40% over 6 h in Al treatment, whereas thecitrate efflux decreased by 90% over the same period and wasunaffected by Al (Supplemental Fig. S1). Subsequent experimentson excised root apices were run for less than 2.5 h.

Citrate Efflux in Other Genotypes of Wheat

Genotypes from China (Chuan Mai 18, Chinese Spring), USA (Atlas66), Australia (EGA-Burke, Egret, Tasman, ES8, ET8, CD87, Currawong,Vigor 18, Cranbrook, Spica, Kukri, Sunco, Halberd, Janz, Diamondbird),and South America (Carazinho, Toropi, Trintecinco, Maringa,Petiblanco, Veranopolis, Fronteira, BH1146) were tested forcitrate efflux to determine how widely the phenotype is distributed.Figure 3 shows that of the 26 genotypes tested here, constitutivecitrate release was detected only in Carazinho, Maringa, Toropi,and Trintecinco.

View larger version (30K):
[in this window]
[in a new window]
[as a PowerPoint slide]

Figure 3. Survey of citrate efflux among different genotypes of wheat. Citrate efflux was measured from root apices excised from 6-d-old seedlings in the absence of Al. Al-resistant genotypes are denoted by the gray bars and Al-sensitive genotypes by the white bars. Two separate measurements for Carazinho are presented to show the variability between experiments. Data show the mean and SE (n = 3).

Genetic Control of Citrate Efflux

The genetics of citrate efflux was investigated in two wheatpopulations segregating for the trait that was derived fromcrosses between the Brazilian cultivar Carazinho and two Australiancultivars. These included an F₂ population generated from Carazinhoand EGA-Burke (low citrate efflux) and a set of F_2:3 familiesdeveloped from Carazinho and Egret (low citrate efflux).

F₂ Population Derived from EGA-Burke/Carazinho
Carazinho and EGA-Burke are both Al-resistant cultivars, butCarazinho is more resistant, averaging 50% greater relativeroot growth over a range of Al concentrations (data not shown).Both parents possess the same resistance allele for TaALMT1,the major resistance gene on chromosome 4DL that controls Al-activatedmalate efflux. EGA-Burke/Carazinho F₁ plants show an intermediatephenotype for Al resistance and for citrate efflux, whereasmalate efflux was similar in all three lines (Fig. 4 ). Variationdid occur between experiments, and on other occasions, malateefflux was 10% to 20% greater from Carazinho than from EGA-Burke.We also scored 13 BC₁F₁ plants (back-crossed to EGA-Burke) forcitrate efflux and found five with low efflux (similar to EGA-Burke)and eight with an intermediate efflux between the parental lines(Supplemental Fig. S2).

View larger version (17K):
[in this window]
[in a new window]
[as a PowerPoint slide]

Figure 4. Phenotypes of Carazinho, EGA-Burke, and their F₁ progeny. RRL (A) was calculated from net root growth after 4 d in 0 and 30 µM Al (n = 7). To account for the accumulation of errors associated with deriving RRL, the errors were calculated as follows: SE_RRG = RRG [(SE_x/x)² + (SE_y/y)²]^1/2, where x and y represent the mean net root length in the control treatment and the mean net root length in the Al treatment. Malate (B) and citrate (C) efflux from excised root apices were measured in the presence of 50 µM Al. Data show the mean and SE (n = 3).

Citrate efflux in 132 individual F₂ plants showed a continuousdistribution with a peak toward the EGA-Burke parental line(Fig. 5 ). In 37 of these F₂ seedlings, Al resistance (netroot growth in 30 µM Al), malate efflux, and citrate effluxwere measured in each seedling. Al resistance varied 2-fold,malate efflux 4-fold, and citrate efflux by 20-fold among theF₂ seedlings. The variation in malate efflux was larger thanexpected, considering that both parents have the malate effluxphenotype. Although part of this spread may reflect experimentalvariation, it could also indicate that more than one locus influencesmalate efflux in Carazinho. This idea would be consistent withCarazinho showing greater malate efflux than EGA-Burke in someexperiments. Average malate efflux from the Carazinho and EGA-Burkeparental lines was 1.78 ± 0.10 and 1.35 ± 0.25nmol apex^–1 h^–1 and citrate efflux was 26.5 ±3.7 and 3.0 ± 1.2 pmol apex^–1 h^–1, respectively(Fig. 6 ). The average net root growth for the lowest and highestnine seedlings in the distribution was 19.0 ± 0.5 mmand 30.0 ± 0.6 mm, respectively, and average citrateefflux from these same plants was 8.2 ± 1.0 mm and 23.8± 3.7 pmol apex^–1 h^–1, respectively. Al resistancefor each seedling was then plotted against the efflux of eachanion. Malate efflux was not correlated with Al resistance,and, therefore, was not responsible for the variation in Alresistance in this population (Fig. 6B). By contrast, citrateefflux showed a positive and significant correlation with Alresistance and accounted for 27% of the variation (r = 0.52;Fig. 6C). This result indicates that citrate efflux contributesto Al resistance in this F₂ population over and above the effectof malate efflux.

View larger version (27K):
[in this window]
[in a new window]
[as a PowerPoint slide]

Figure 5. Frequency distribution of citrate efflux among F₂ seedlings. Citrate efflux was measured in root apices excised from 132 F₂ 6-d-old seedlings derived from EGA-Burke/Carazinho (four to five apices per seedling). Carazinho was included in each experiment to account for the variation between experiments. The apices were washed and treated with 1 mL of 0.2 mM CaCl₂, pH 4.3, for 2 h on a shaker. The data are presented as a percentage of the efflux from Carazinho seedlings and grouped into bins as shown. Mean values for the parental lines are indicated.

View larger version (22K):
[in this window]
[in a new window]
[as a PowerPoint slide]

Figure 6. Net root growth and organic anion efflux from F₂ seedlings derived from EGA-Burke/Carazinho. A, Net root growth was measured after 4 d in nutrient solution with 30 µM AlCl₃. The seedlings were moved to a control solution and allowed to recover for 3 d. Root apices were then excised from the seedlings (four to five apices per seedling), washed, and treated with 1 mL of 0.2 mM CaCl₂, pH 4.3, on a shaker. After 2 h, 0.1 mL of each sample was used for malate assays (B) and 0.9 mL was dried down for citrate assays (C). The triangles in B and C indicate the mean values for the Carazinho parent and the squares indicate the mean values for the EGA-Burke parent. The dashed lines indicate linear regressions with regression coefficients shown.

F_2:3 Families Derived from Egret/Carazinho
Egret is an Al-sensitive cultivar that possesses neither Al-activatedmalate efflux nor citrate efflux (see Fig. 1). Egret/CarazinhoF₁ seedlings showed a phenotype for citrate efflux that wasintermediate between the parental genotypes (Supplemental Fig.3). Insufficient F₁ seeds were available to measure relativeroot length (RRL). The malate and citrate effluxes were measuredin the presence of 50 µM Al in a set of 45 F_2:3 familiesderived from this cross, and the results indicate that thesephenotypes segregate independently from one another (SupplementalTable S1). The frequency of the fluxes is summarized in Figure 7 .The families were then scored as either being similar to oneof the parental genotypes or intermediate between the parents.This analysis generated a ratio of 13:23:9 (low to intermediateto high) for malate efflux and 13:27:5 for citrate efflux (seeFig. 7). Chi-squared tests indicate that these ratios fit a1:2:1 segregation (P > 0.05). Collectively, these resultsare consistent with malate and citrate efflux each being controlledby single independent loci.

View larger version (29K):
[in this window]
[in a new window]
[as a PowerPoint slide]

Figure 7. Frequency distribution of malate and citrate efflux from F_2:3 families derived from Egret/Carazinho. Six to eight seedlings from each of the 45 F_2:3 families were grown in nutrient solution for 6 d. Measurements of citrate efflux were either made separately on the individual seedlings in each family and the average value used to represent the family, or root apices were bulked from all seedlings (two apices per seedling) and a single bulked sample was measured per family. The data are presented as a percentage of Carazinho seedlings and grouped into bins as shown. Carazinho was included in each experiment to account for the variation between experiments. The hatched bars were scored as being similar to either of the parental genotypes (arrows) to estimate the segregation ratios.

The independent segregation of malate efflux and citrate effluxallowed us to test whether citrate efflux was contributing toAl resistance in the F_2:3 families. We identified one F_2:3 family(family no. 30) from the 45 tested that was null for malateefflux and homozygous for citrate efflux. We also selected additionalfamilies that were either null for malate and citrate efflux(family no. 29) or null for malate efflux and segregating forcitrate efflux (family nos. 9, 43B, and 44). The Al resistanceof these lines was compared with Egret, which is null for malateefflux and citrate efflux (Fig. 8 ). All four families withcitrate efflux were more Al resistant than Egret at one or moreof the Al treatments. The single family homozygous for citrateefflux, number 30, showed the greatest level of resistance comparedto Egret, with 50% to 100% greater RRL over the range of Alconcentrations. We also compared the resistance conferred bycitrate efflux with the resistance conferred by malate efflux.Figure 8B shows the RRL in 10 µM Al of Egret and two additionalfamilies that are homozygous for malate efflux but null forcitrate efflux (nos. 3 and 5; Supplemental Table S1). The malateefflux conferred significantly greater resistance than the citrateefflux. These data are consistent with the relatively lowerefflux of citrate compared with malate.

View larger version (22K):
[in this window]
[in a new window]
[as a PowerPoint slide]

Figure 8. RRL of F_2:3 families compared to Egret. A, RRL was measured in Egret (white) and five F_2:3 families. The identities and phenotypes of the F_2:3 families are as follows: null for malate and citrate efflux (no. 29, white hatched), null for malate and homozygous for citrate efflux (no. 30, black), and null for malate efflux and segregating for citrate efflux (no. 9, dark gray; no. 44, light gray; no. 43B, gray dotted). RRL was calculated by measuring net root growth in 10 seedlings for each line in four Al treatments (0, 2, 5, and 10 µM AlCl₃). B, RRL was measured in Egret (white) and two F_2:3 families that are null for citrate efflux and homozygous for malate (no. 3, dark gray; no. 5 light gray). RRL was calculated by measuring net root growth in 10 seedlings for each line in 0 and 10 µM Al treatments. Data show the mean and SEs. SEs were calculated using the formula presented in the legend to Figure 4.

Molecular Mapping and Validation of Xce_c

Because Chinese Spring does not show the citrate efflux phenotype(see Fig. 3), we were unable to map this trait to a physicalmap using deletion lines. Instead, the locus conditioning citrateefflux, Xce_c, was tagged by whole-genome linkage mapping. DNAof the Carazinho and EGA-Burke parental lines and 67 F₂ individualswas analyzed with the diversity microarray technology (DArT).DArT analysis identified 676 polymorphic markers covering all21 chromosomes of the wheat genome, except 5D (data not shown).A skeleton linkage map was used to find a genomic region associatedwith citrate efflux. Single marker regression analysis identifieda major QTL, Qce_c-4BL, on the long arm of chromosome 4B thatexplained more than 50% of the phenotypic variation for citrateefflux. The association between DArT markers and citrate effluxwas highly significant (P < 0.0001), with a likelihood ratiostatistic (LRS) of 46 (Table I ; Fig. 9 ; Supplemental Fig.S4). Interval mapping indicated that Qce_c-4BL is delimited byDArT markers Xwpt-8397/Xwpt-8292 with Xwpt-8397 explaining mostof the phenotypic variation for citrate efflux in this population.Marker analysis confirmed that citrate efflux was inheritedfrom the Carazinho parent.

View this table:
[in this window]
[in a new window]

Table I. DArT and SSR markers closely linked with a major QTL for citrate efflux

The QTL was identified on the long arm of chromosome 4B (Qce_c-4BL) in an F₂ population derived from EGA-Burke/Carazinho. Linked markers were determined using simple regression analysis (Manly et al., 2001).

View larger version (19K):
[in this window]
[in a new window]
[as a PowerPoint slide]

Figure 9. Mapping the Xce_c locus. Graphical representation of an integrated map based upon DArT and SSR markers showing the position of a major locus conditioning citrate efflux on the long arm of chromosome 4B in an F₂ population from Carazinho (Al resistant, positive for citrate efflux) and EGA-Burke (Al resistant, negative for citrate efflux). The bold marker loci Xgwm495 (SSR) and Xwpt-8397 (DArT) flank the Xce_c for citrate efflux and account for 51% and 50% of phenotypic variation in citrate efflux, respectively. The thin line on the right side indicates Qce_c-4BL, the genomic region that is significantly associated with citrate efflux (P < 0.05). The solid bold line indicates the genomic region for Qce_c-4BL that is highly significantly associated with citrate efflux (P < 0.001). The numbers on the right side refer to linkage distance in centimorgans. Variation in citrate efflux was calculated as a percentage of the Carazinho donor parent.

DArT markers are dominant and, therefore, cannot distinguishheterozygotes in segregating populations. Codominant markersare more useful for marker-assisted selection, so we mappedthe Qce_c-4BL region using microsatellite markers, also calledsingle sequence repeat markers (SSR), specific to chromosome4B. SSR markers Xwmc349, Xbarc163, Xgwm251, Xgwm495, Xgwm513,and Xbarc340 were polymorphic in the F₂ population and wereused to construct a linkage map of chromosome 4B. Regressionanalysis revealed a highly significant QTL Qce_c-4BL (P <0.001) for citrate efflux, with SSR marker Xgwm495 detecting51% of the phenotypic variation for citrate efflux (Table I;Supplemental Fig. S4). Integration of SSR and DArT marker datawith citrate efflux phenotypes for the EGA-Burke/Carazinho F₂population revealed that the Xce_e was flanked with Xgwm495 andXwpt-8397 loci (Fig. 9; Table I).

The two polymorphic SSR markers closely linked with Xce_c, Xgwm495and Xgwm513, were further validated in an independent F_2:3 populationderived from Egret/Carazinho. These markers predicted 96% and91%, respectively, of phenotypic variation for citrate effluxin this population.

We also investigated the linkage between Al resistance and citrateefflux in the F₂ seedlings from EGA-Burke/Carazinho (see Fig. 6).The Xce_c locus conditioning citrate efflux showed a significanteffect on net root growth (P > 0.05) and explained 56% ofphenotypic variance in this phenotype in the F₂ population,which is consistent with the results presented in Figure 6.This result indicates that while the contribution of citrateefflux to Al resistance is smaller than the contribution frommalate efflux (see Fig. 8), its effect is significant and additive.

Citrate Efflux Cosegregates with Expression of a MATE Gene on Chromosome 4BL

Several SSR markers closely linked with Xce_c have been mappedwith the Chinese Spring deletion lines. Markers Xgwm513 andXgwm251/Xbarc163 are allocated to 4BL-5 (fraction length C to0.71) and 4BL-1 (fraction length 0.86–1.00), respectively(http://wheat.pw.usda.gov/cgi-bin/graingenes; Sourdille et al.,2004). This region (4BL-1 fraction length 0.71–0.86) alsoincludes a wheat EST (GenBank accession no. BE605049) that showsa predicted 94% amino acid sequence identity with a MATE genefrom barley, HvAACT1, also designated HvMATE1 (Furukawa et al.,2007; Wang et al., 2007). HvAACT1 controls Al resistance inbarley by facilitating Al-activated citrate efflux (Furukawaet al., 2007). Primers to an EST (GenBank accession no. BE498331)representing the putative 3' end of a wheat gene encoding theMATE located at 4BL (TaMATE1) were used to quantify gene expressionby real-time PCR (qRT-PCR) in all genotypes listed in Figure 3.TaMATE1 expression was detected only in the four genotypes showingcitrate efflux (Carazinho, Toropi, Maringa, and Trintecinco).We then tested TaMATE1 expression in the F_2:3 families derivedfrom Egret/Carazinho. Families with TaMATE1 expression belowthe limits of detection were also null for citrate efflux (Fig. 10 ;Supplemental Fig. S5). All other F_2:3 families tested showedcitrate efflux and detectable TaMATE1 expression.

View larger version (11K):
[in this window]
[in a new window]
[as a PowerPoint slide]

Figure 10. Relationship between TaMATE1 expression and citrate efflux in F_2:3 families derived from Egret/Carazinho. TaMATE1 expression in 3-mm root apices was measured by qRT-PCR and is shown relative to the expression of the wheat PT-1 gene. Citrate efflux was assayed as described in the legend of Figure 7 and is expressed as a percent of Carazinho. White circles ( ${circ}$ ) indicate families that have detectable TaMATE1 expression and black circles ( $bullet$ ) are families with undetectable TaMATE1 expression.

	DISCUSSION

TOP ABSTRACT RESULTS DISCUSSION CONCLUSION MATERIALS AND METHODS LITERATURE CITED

This study has identified a second mechanism of Al resistancein wheat that relies on citrate efflux. We show that citrateefflux is controlled by a single codominant locus on chromosome4BL. The first mechanism relies on malate efflux and is controlledby the TaALMT1 gene on chromosome 4DL (Delhaize et al., 1993b

;Ryan et al., 1995b

; Raman et al., 2005

). Our results demonstratethat Al resistance is a multigenic trait in some genotypes andthat these genes do not necessarily act by modifying the functionof TaALMT1.

Stass et al. (2008) first reported citrate efflux from the rootsof Carazinho while investigating the Al resistance of triticale.They found that citrate was activated by Al treatment and thatthe wheat parent could influence the Al resistance of progenyfrom wheat/rye crosses. The current study provides a detailedcharacterization of citrate efflux from wheat roots. We haveextended the work of Stass et al. (2008) by demonstrating thatcitrate efflux actually occurs constitutively in Carazinho andseveral other highly Al-resistant Brazilian cultivars. Thisfinding contrasts with the citrate efflux characterized in othercereal species such as barley, sorghum, and maize where thecitrate efflux is activated by Al in much the same way thatmalate efflux is activated from Al-resistant wheat plants (Pelletet al., 1995; Furukawa et al., 2007; Magalhaes et al., 2007).We show that the expression of an EST from the MATE family,designated here as TaMATE1, is greater in genotypes with highcitrate efflux than in genotypes with low efflux and is correlatedwith citrate efflux in 45 F_2:3 families segregating for thistrait. The close similarity of TaMATE1 with HvAACT1, a MATEgene that controls citrate efflux in barley, identified thisgene as a candidate controlling the citrate efflux phenotypein wheat.

Our conclusion that citrate efflux is controlled by a singlecodominant locus relies on two results: (1) the segregationof citrate efflux in F_2:3 families (Egret/Carazinho) is consistentwith a 1:2:1 ratio (low to intermediate to high); and (2) whole-genomemapping identified a single highly significant QTL on 4BL inan F₂ population derived from EGA-Burke/Carazinho as well F_2:3families derived from Egret/Carazinho. Distribution of citrateefflux in F₂ plants did not show the expected 1:2:1 segregationbut instead produced a skewed distribution toward the EGA-Burkeparent. The difficulty in scoring this trait on single seedlingscould have obscured the underlying inheritance. The observedbias of data toward the lower fluxes is consistent with someloss of sensitivity in the measurements. The 4-fold variationin malate efflux in this F₂ population was unexpected, becauseboth genotypes possess the malate efflux phenotype controlledby TaALMT1. This may be explained, in part, by experimentalerror, but it could also indicate that other loci contributeto this phenotype in Carazinho.

Citrate efflux from excised root apices of Carazinho is about10-fold smaller than malate efflux, while in intact seedlings,the efflux of citrate and malate are comparable. At least partof this discrepancy is likely to be due to the faster decreasein citrate efflux from excised root tissue compared to malateefflux (Supplemental Fig. S1), which means the citrate effluxfrom excised tissue becomes relatively smaller the longer themeasurements are made after excision. We also argue that a comparisonbetween Carazinho and Egret indicates that the citrate effluxextends farther along the root than malate efflux (Fig. 2).Nevertheless, tricarboxylic anions such as citrate form strongercomplexes with Al than dicarboxylic anions such as malate (Hueet al., 1986), and a relatively small efflux of citrate fromthe root apices could afford significant protection from Alstress. Growth experiments support this idea by showing thatcitrate is approximately 8-fold more effective than malate atameliorating the inhibition of root growth by Al (Delhaize etal., 1993b; Ryan et al., 1995b; Zheng et al., 1998b; Zhao etal., 2003).

Our conclusion that citrate efflux contributes to Al resistancerelies on three results: (1) Al resistance in a population ofF₂ plants (EGA-Burke/Carazinho) was significantly correlatedwith citrate efflux; (2) Al resistance was linked with Xce_c,the citrate efflux locus on 4BL; and (3) F_2:3 families (Egret/Carazinho)that displayed citrate efflux were more Al resistant than Egretand another family that did not show citrate efflux. Furtherexperiments are required to confirm that these citrate and malatemechanisms are additive. The intermediate phenotypes of theEGA-Burke/Carazinho F₁ plants (both of which show malate efflux)and the correlation between citrate efflux and Al resistancein the F₂ seedlings also support this idea. Therefore, citrateefflux does contribute to the Al resistance of wheat, but thedegree of protection is smaller than that provided by malateefflux. This is demonstrated in Figure 8B, where Egret/CarazinhoF_2:3 families, which are null for citrate efflux but homozygousfor malate efflux, are significantly more resistant to 10 µMAlCl₃ than the F_2:3 family 30, which is homozygous for the citrateefflux phenotype but null for malate efflux. It is importantto note that Al resistance in this study was measured at a singlepH. The relative effectiveness of citrate and malate effluxin protecting plants from Al stress will also vary with externalpH due to the speciation of both Al (Al³⁺ ${leftrightarrow}$ AlOH²⁺ + H⁺ ${leftrightarrow}$ Al₂(OH)₂⁺+ 2H⁺, etc.) and the organic anions (citrate^3– + 3H⁺ ${leftrightarrow}$ citrate^2– + 2H⁺ ${leftrightarrow}$ citrate^– + H⁺, etc.).

The evidence to date indicates that citrate efflux is restrictedto a relatively few highly resistant genotypes from Brazil,including Carazinho, Toropi, Maringa, and Trintecinco. Interestingly,this trait is not present in Fronteira, Veranopolis, and Petiblanco,which are either derived from those genotypes or are among theirprogenitors. Surveys are on-going to establish how widely thistrait is distributed among other cultivars, landraces, and subspeciesof wheat. Atlas 66 (USA) and BH1146 (Brazil) are two highlyAl-resistant cultivars that have been widely used in geneticstudies. Many of those studies conclude that Atlas 66 and BH1146possess more than one resistance gene (see introduction). Becausethe ancestries of Carazinho, Atlas 66, and BH1146 have severalgenotypes in common (e.g. Polyssu, Alfredo Chaves 6, Fronteira),we investigated whether they also have similar resistance mechanisms(de Sousa, 1998). Although both Atlas 66 and BH1146 show theAl-activated malate efflux, neither shows citrate efflux. Itappears that citrate efflux does not contribute to the strongresistance of these two genotypes. Instead, a recently identifiedlocus on chromosome 3BL of Atlas 66 and a Chinese genotype FSWappears to be important (Zhou et al., 2007; Cai et al., 2008),and this could encode a third mechanism conserved among geneticallydiverse genotypes.

CONCLUSION

TOP
ABSTRACT
RESULTS
DISCUSSION
CONCLUSION
MATERIALS AND METHODS
LITERATURE CITED

This study describes a second mechanism for Al resistance inwheat located on chromosome 4BL, a region of the genome notpreviously associated with this phenotype. We provide evidencethat the trait is likely encoded by a member of the MATE familyof genes, TaMATE1. These results provide physiological evidencethat Al resistance in wheat is a multigenic trait encoding fordifferent mechanisms. Finally, we have identified SSR markersthat will allow the rapid introgression of this locus into elitebreeding material.

MATERIALS AND METHODS

TOP
ABSTRACT
RESULTS
DISCUSSION
CONCLUSION
MATERIALS AND METHODS
LITERATURE CITED

Plant Material

Seeds for the genotypes investigated here were obtained fromcollections at CSIRO Plant Industry in Canberra, Australia,or from the Australian Winter Cereal Collection of the NSW Departmentof Primary Industries, Tamworth.

Parents of the segregating populations used in this study includedCarazinho, an Al-resistant Brazilian wheat that carries theTaALMT1-1 allele associated for Al resistance (Raman et al.,2008). Carazinho is derived from Polyssu/Alfredo Chaves 6//Fronteira/Mentana//Frontana/Egret.EGA-Burke (TaALMT1-1 allele) is an Australian Al-resistant cultivarderived from Sunco and Hartog. The third parental line is Egret,an Al-sensitive cultivar (TaALMT1-2 allele) with a pedigreeof Heron/2*WW15. The F₂ population derived from EGA-Burke/Carazinhoand 13 BC₁F₁ plants (EGA-Burke/Carazinho//EGA-Burke) were generatedat CSIRO Plant Industry in Canberra, Australia. The 45 F_2:3families derived from Egret/Carazinho were also generated atCSIRO Plant Industry.

Growth Conditions and Measurements of RRL

Seeds were germinated for 2 d on moist filter paper and thenplanted over 20 L of aerated nutrient solution (Delhaize etal., 2004) on laboratory benches. Seedlings were grown for 4d before being used in experiments. To estimate RRL, the lengthof the longest root was measured before and after 4 d of growthin the same nutrient solution with a range of Al concentrations.RRL was calculated as (net root growth in Al treatment/net rootgrowth in control solution) x 100. RRL could not be measuredfor single F₂ seedlings. Instead, net root growth was measuredafter 4 d in 30 µM Al treatment.

Measurement of Citrate and Malate Efflux

The measurement of organic anion efflux from intact seedlingsfollowed the procedure of Delhaize et al. (1993b) and Ryan etal. (1995a). Briefly, seeds were surface sterilized with bleachand thoroughly rinsed in sterile water. Twelve seeds were placedin sterile conical flasks with 20 mL of 0.2 mM CaCl₂, pH 4.3,and kept on a rotary shaker. After 6 d, the solution was replacedwith treatment solution, and aliquots were removed periodicallyfor malate and citrate analysis. The concentration of malateand citrate were estimated with coupled enzyme assays that detectthe production or consumption of NADH (Delhaize et al., 1993b;Wang et al., 2007).

Organic anion efflux from excised root apices could be measuredon individual seedlings using as few as four apices by modifyingthe method described by Ryan et al. (1995a) and Wang et al.(2007). Briefly, approximately 4-mm root segments were excisedin petri dishes and washed in 1 mL of control solution (0.2mM CaCl₂, pH 4.3) for 1 h on a platform shaker (60 rpm). Thesolutions were replaced by 1 mL of treatments solution (withor without Al) and returned to the shaker for 1.5 to 2.5 h.For citrate measurements, samples were dried on a rotary vacuumdrier and resuspended in 80 µL assay solution consistingof 100 mM Tris, pH 8.0, containing malate dehydrogenase (4 units),lactate dehydrogenase (1.5 units), and 15 µL NADH (preparedby dissolving 16 mg NADH and 15 mg NaHCO₃ in 2 mL water). Thechange in A₃₄₀ was monitored after the reaction was initiatedwith citrate lyase (0.01 units). All chemicals were obtainedfrom Sigma-Aldrich. Malate assay followed the procedure describedby Ryan et al. (1995a). In some experiments, the samples weredivided so that malate and citrate could be measured on thesame sample. To gauge the efficiency of citrate recovery afterdrying, samples were spiked with known amounts of citrate. Approximately40% of the citrate was unretrievable when citrate was driedin control solution (0.2 mM CaCl₂) and 60% was unretrievablewhen Al was present. These losses did not occur with malate,because the samples were not dried down prior to assaying. Alldata presented here show the corrected values for citrate efflux.

The variation observed between experiments probably relatesto differences in the tissue to solution ratio, the length ofthe treatment, and laboratory environment (especially temperature).To account for this variation, Carazinho, and often Egret, wereincluded in all experiments to act as internal standards. Insome figures, the results are expressed as a percentage of Carazinhomeasured in the same experiment.

Genetic Mapping of Citrate Efflux

Leaf tissue was excised from each F₂ line after phenotypingfor citrate efflux. Tissue samples were frozen in liquid nitrogenand pulverized using a Mixer-Mill (Retsch). Genomic DNA wasextracted using a standard phenol-chloroform method. For theEgret/Carazinho population, genotypes of the F₂ parents foreach F_2:3 family were reconstituted for mapping purposes byextracting DNA from bulks of leaf tissue from eight individualF_2:3 seedlings.

Qualitative (Xce_c) and quantitative (Qce_c) scores were usedfor mapping citrate efflux on the wheat genome. Xce_c was mappedby whole-genome mapping of 67 F₂ lines derived from EGA-Burke/Carazinho.Whole-genome profiling was performed using a DArT microarraychip (version 2.3) that contained approximately 5,000 uniqueDArT clones (www.triticarte.com.au). Twenty-five F₂ lines wererandomly selected and replicated to determine the accuracy ofDArT marker scores. DArT marker analysis was conducted as describedpreviously (Akbari et al., 2006). Clones with a call rate >80%and 98% to 100% allele-calling concordance across the replicatedassays were selected for mapping. The score of all segregatingDArT markers were converted into ‘A’ and ‘B’according to allele scores of the parental genotypes.

A skeleton linkage map was constructed with the Map Managerprogram, version QTX20b (Manly et al., 2001) using the Kosambifunction (Kosambi, 1944). This map was subsequently employedto identify genomic region(s) associated with citrate effluxin an F₂ population from EGA-Burke/Carazinho using simple andinterval mapping analyses as described in Manly et al. (2001).Accuracy of the order for DArT and SSR markers was checked withthe RECORD computer package (Van os et al., 2005) and previouslypublished maps (Akbari et al., 2006; www.triticarte.com.au).

Quantitative data on citrate efflux (relative to Carazinho)was used for QTL identification. Significance thresholds forthe test statistics were estimated by 1,000 permutations atthe significance of P = 0.001 (Churchill and Doerge, 1994; Doergeand Churchill, 1996) by following the algorithm implementedin Map Manager. The genomic region and chromosomal locationassociated with citrate efflux was designated as Qce_c-4BL.

SSR markers specific to chromosome 4B were tested for theirassociation with Xce_c (Roder et al., 1998; Pestova et al., 2000;Guyomarc'h et al., 2002; Somers et al., 2004; Sourdille et al.,2004; Song et al., 2005). Markers Xgwm251, Xgwm513, Xgwm495,Xcfd54, Xwmc48, Xwmc349, Xbarc340, Xcfd39, Xgwm165, Xgwm538,Xbarc163, and Xdupw43 were tested for polymorphisms betweenthe parental lines Carazinho and EGA-Burke. Polymorphic markerswere subsequently analyzed in each individual of an F₂ population.PCR amplifications were performed in 10-µL volumes ona Gene Amp PCR system 2700 (Applied Biosystems) thermal cyclerusing a touch-down PCR program (annealing temperature 65°Cto 55°C with a decrease of 1°C for 10 cycles) as describedpreviously by Raman et al. (2005). The 5' end of the forwardprimer from each primer pair was tailed with a 19-nucleotide-longM13 sequence. Amplicons generated with fluorescent-labeled primerswere analyzed using capillary electrophoresis on a CEQ8000 geneticanalysis system (Beckman Coulter) as described by Raman et al.(2005). The score of SSR markers were converted into ‘A’(homozygous for Carazinho), ‘B’ (homozygous forEGA-Burke), and ‘H’ (heterozygous allele from Carazinhoand EGA-Burke). An integrated map based upon DArT and SSR lociwas constructed using the RECORD program (Van os et al., 2005).

Quantitative citrate efflux data from an individual F₂ plantwere binned into three categories according to their percentageof Carazinho: low (0%–27%), medium (36.4%–71.2%),and high (>71.2%). These scores were then converted intoB, H, and A representing low, medium, and high citrate effluxphenotypes to predict homozygous and heterozygous alleles fromEGA-Burke and Carazinho. Chi-square tests were performed on67 F₂ lines to determine the goodness-of-fit of the phenotypesand markers into Mendelian segregation ratios. Citrate effluxand codominant SSR markers were used for linkage analysis usingthe Map Manager program. Linkage between citrate efflux andmolecular marker(s) was determined at a threshold of P = 0.001.Map distances were calculated using the Kosambi function (Kosambi,1944). Preferred orders of markers relative to Xce_c were checkedby the "ripple" command within the Map Manager and the RECORDprogram. These linkage data were exported into Map Chart package(Voorrips, 2002) to display the trait-marker data graphically.

Measurements of TaMATE1 Expression by Real-Time qRT-PCR

The expression level of a putative MATE gene from wheat (TaMATE1)was analyzed by qRT-PCR using procedures based on those describedby Delhaize et al. (2004). RNA from 4-mm root tips was extractedwith an RNeasy kit and used to synthesize first-strand cDNA,which was then diluted 64-fold prior to qRT-PCR. Primers GATTGCCGCGACCTCTCGTGTT(forward) and GATGCCGTCGAACACGAACG (reverse) were used to amplifya 199-bp fragment from the cDNA by qRT-PCR. Expression of aphosphate transporter gene (PT1; GenBank accession no. AF110180;primers GAAGGACATCTTCACGGCGATC and CACGGCCATGAAGAAGAAGC) wasused as an internal reference for each sample. PCR productswere sequenced to confirm their identities. Data were analyzedby comparative quantification using Rotor-Gene software version6.0 (Corbett Research), and expression of the TaMATE1 gene wasexpressed relative to the expression of the PT1 reference gene.

Sequence data from this article can be found in the GenBank/EMBLdata libraries under accession numbers BE605049, BE498331, andAF110180.

Supplemental Data

The following materials are available in the online versionof this article.

Supplemental Figure S1. Time course of malateand citrate effluxfrom excised root apices.

SupplementalFigure S2. Frequency distribution of citrate effluxin BC₁F₁seedlings derived from EGA-Burke/Carazinho.

Supplemental FigureS3. Comparison of citrate efflux from Carazinho,Egret, andtheir F₁ progeny.

Supplemental Figure S4. A major QTL forcitrate efflux mapsto chromosome 4B.

Supplemental FigureS5. Endpoint products from qRT-PCR usedto measure TaMATE1 expressionin F_2:3 families derived froma Carazhino by Egret cross.

SupplementalTable S1. Malate and citrate efflux from F_2:3 familiesderivedfrom Egret/Carazinho.

ACKNOWLEDGMENTS

We are grateful to Dr. Rosy Raman, NSW DPI, Wagga Wagga, forthe SSR analyses. The EH Graham Centre for Agricultural Innovationis an alliance between NSW Department of Primary Industriesand Charles Sturt University, Wagga Wagga NSW, Australia.

Received September 2, 2008; accepted November 7, 2008; published November 12, 2008.

FOOTNOTES

¹ This work was supported by the Department of Biotechnology inNew Delhi, India (S.G.'s travel to CSIRO Plant Industry, Canberra,and his participation in this project).

² Present address: ICAR Research Complex for NEH Region, Umiam,793103 Meghalaya, India.

The author responsible for distribution of materials integralto the findings presented in this article in accordance withthe policy described in the Instructions for Authors (www.plantphysiol.org)is: Peter R. Ryan (peter.ryan{at}csiro.au).

^[W] The online version of this article contains Web-only data.

^[OA] Open Access articles can be viewed online without a subscription.

www.plantphysiol.org/cgi/doi/10.1104/pp.108.129155

^{^*} Corresponding author; e-mail peter.ryan{at}csiro.au.

LITERATURE CITED

TOP
ABSTRACT
RESULTS
DISCUSSION
CONCLUSION
MATERIALS AND METHODS
LITERATURE CITED

Akbari M, Wenzl P, Caig V, Carling J, Xia L, Yang S, Uszynski G, Mohler V, Lehmensiek A, et al (2006) Diversity arrays technology (DArT) for high-throughput profiling of the hexaploid wheat genome. Theor Appl Genet 113: 1409–1420[CrossRef][Web of Science][Medline]

Aniol A (1990) Genetics of tolerance to aluminum in wheat (Triticum aestivum L. Thell). Plant Soil 123: 223–227[CrossRef][Web of Science]

Aniol A, Gustafson JP (1984) Chromosome location of genes controlling aluminum tolerance in wheat, rye and triticale. Can J Genet Cytol 26: 701–705[Web of Science]

Berzonsky WA (1992) The genomic inheritance of aluminium tolerance in ‘Atlas 66’ wheat. Genome 35: 689–693

Cai S, Bai GH, Zhang D (2008) Quantitative trait loci for aluminum resistance in Chinese wheat landrace FSW. Theor Appl Genet 117: 49–56[CrossRef][Web of Science][Medline]

Camargo CEO (1981) Wheat breeding. I. Inheritance of tolerance to aluminum toxicity in wheat. Bragantia 40: 33–45

Churchill GA, Doerge RW (1994) Empirical threshold values for quantitative trait mapping. Genetics 138: 963–971[Abstract]

Collins NC, Shirley NJ, Saeed M, Pallotta M, Gustafson JP (2008) An ALMT1 gene cluster controlling aluminum tolerance at the Alt4 locus of rye (Secale cereale L.). Genetics 179: 669–682[Abstract/Free Full Text]

de Sousa CNA (1998) Classification of Brazilian wheat cultivars for aluminum toxicity in acid soils. Plant Breed 117: 217–221[CrossRef]

Delhaize E, Craig S, Beaton CD, Bennet RJ, Jagadish VC, Randall PJ (1993a) Aluminum tolerance in wheat (Triticum aestivum L.) I. Uptake and distribution of aluminum in root apices. Plant Physiol 103: 685–693[Abstract]

Delhaize E, Gruber BD, Ryan PR (2007) The roles of organic anion permeases in aluminium tolerance and mineral nutrition. FEBS Lett 581: 2255–2262[CrossRef][Web of Science][Medline]

Delhaize E, Ryan PR (1995) Aluminum toxicity and tolerance in plants. Plant Physiol 107: 315–321[Web of Science][Medline]

Delhaize E, Ryan PR, Hebb DM, Yamamoto Y, Sasaki T, Matsumoto H (2004) Engineering high-level aluminum tolerance in barley with the ALMT1 gene. Proc Natl Acad Sci USA 101: 15249–15254[Abstract/Free Full Text]

Delhaize E, Ryan PR, Randall PJ (1993b) Aluminum tolerance in wheat (Triticum aestivum L.) II. Aluminum stimulated excretion of malic acid from root apices. Plant Physiol 103: 695–702[Abstract]

Doerge RW, Churchill GA (1996) Permutation tests for multiple loci affecting a quantitative character. Genetics 142: 285–294[Abstract]

Fontecha G, Silva-Navas J, Benito C, Mestres MA, Espino FJ, Hernandez-Riquer MV, Gallego FJ (2007) Candidate gene identification of an aluminum-activated organic acid transporter gene at the Alt4 locus for aluminum tolerance in rye (Secale cereale L.). Theor Appl Genet 114: 249–260[CrossRef][Web of Science][Medline]

Furukawa J, Yamaji N, Wang H, Mitani N, Murata Y, Sato K, Katsuhara M, Takeda K, Ma JF (2007) An aluminum-activated citrate transporter in barley. Plant Cell Physiol 48: 1081–1091[Abstract/Free Full Text]

Garvin DF, Carver BF (2003) Role of genotypes tolerant of acidity and aluminium toxicity. In Z Rengel, ed, Handbook of Soil Acidity. Marcel Dekker Inc, New York, pp 387–406

Guyomarc'h H, Sourdille P, Charmet G, Edwards KJ, Bernard M (2002) Characterization of polymorphic microsatellite markers from Aegilops tauschii and transferability to the D genome of bread wheat. Theor Appl Genet 104: 1164–1172[CrossRef][Web of Science][Medline]

Hoekenga OA, Maron LG, Cançado GMA, Piñeros MA, Shaff J, Kobayashi Y, Ryan PR, Dong B, Delhaize E, Sasaki T, et al (2006) AtALMT1, which encodes a malate transporter, is identified as one of several genes critical for aluminium tolerance in Arabidopsis. Proc Natl Acad Sci USA 103: 9738–9743[Abstract/Free Full Text]

Hue NV, Craddock GR, Adams F (1986) Effect of organic anions on aluminum toxicity in subsoil. Soil Sci Soc Am J 50: 28–34[Abstract/Free Full Text]

Kerridge PC, Kronstad WE (1968) Evidence of genetic resistance to aluminum toxicity in wheat (Triticum aestivum Vill., Host). Agron J 60: 710–711[Abstract/Free Full Text]

Kinraide TB, Parker DR, Zobel RW (2005) Organic acid secretion as a mechanism of aluminium resistance: a model incorporating the root cortex, epidermis, and the external unstirred layer. J Exp Bot 56: 1853–1865[Abstract/Free Full Text]

Kochian LV, Hoekenga OA, Piñeros MA (2004) How do crop plants tolerate acid soils? Mechanisms of aluminum tolerance and phosphorous efficiency. Annu Rev Plant Biol 55: 459–493[CrossRef][Medline]

Kosambi DD (1944) The estimation of map distances from recombination values. Ann Eugen 12: 172–175

Ligaba A, Katsuhara M, Ryan PR, Shibasaka M, Matsumoto H (2006) The BnALMT1 and BnALMT2 genes from Brassica napus L. encode aluminum-activated malate transporters that enhance the aluminum resistance of plant cells. Plant Physiol 142: 1294–1303[Abstract/Free Full Text]

Luo MC, Dvorak J (1996) Molecular mapping of an aluminum tolerance locus on chromosome 4D of Chinese Spring wheat. Euphytica 91: 31–35[CrossRef][Web of Science]

Ma HX, Bai GH, Carver BF, Zhou LL (2005) Molecular mapping of a quantitative trait locus for aluminum tolerance in wheat cultivar Atlas 66. Theor Appl Genet 112: 51–57[CrossRef][Web of Science][Medline]

Ma JF, Ryan PR, Delhaize E (2001) Aluminium tolerance in plants and the complexing role of organic acids. Trends Plant Sci 6: 273–278[CrossRef][Web of Science][Medline]

Ma JF, Zheng SJ, Matsumoto H (1997) Specific secretion of citric acid induced by Al stress in Cassia tora L. Plant Cell Physiol 38: 1019–1025[Abstract/Free Full Text]

Ma Z, Miyasaka SC (1998) Oxalate exudation by taro in response to Al. Plant Physiol 118: 861–865[Abstract/Free Full Text]

Magalhaes JV, Liu J, Guimaraes CT, Lana UGP, Alves VMC, Wang YH, Schaffert RE, Hoekenga OA, Piñeros MA, Shaff JE, et al (2007) A gene in the multidrug and toxic compound extrusion (MATE) family confers aluminum tolerance in sorghum. Nat Genet 39: 1156–1161[CrossRef][Web of Science][Medline]

Manly KF, Cudmore RH, Meer JM (2001) Map Manager QTX, cross-platform software for genetic mapping. Mamm Genome 12: 930–932[CrossRef][Web of Science][Medline]

Matsumoto H (2000) Cell biology of aluminum toxicity and tolerance in higher plants. Int Rev Cytol 200: 1–46[CrossRef][Web of Science][Medline]

Miyasaka SC, Buta JG, Howell RK, Foy CD (1991) Mechanisms of aluminum tolerance in snapbean. Plant Physiol 96: 737–743[Abstract/Free Full Text]

Papernik LA, Bethea AS, Singleton TE, Magalhaes JV, Garvin DF, Kochian LV (2001) Physiological basis of reduced Al tolerance in ditelosomic lines of Chinese Spring wheat. Planta 212: 829–834[CrossRef][Web of Science][Medline]

Pellet DM, Grunes DL, Kochian LV (1996) Multiple aluminum-resistance mechanisms in wheat. Roles for root apical phosphate and malate exudation. Plant Physiol 112: 591–597[Abstract]

Pellet DM, Papernik LA, Kochian LV (1995) Organic acid exudation as an aluminum-tolerance mechanism in maize (Zea mays L.). Planta 196: 788–795[CrossRef][Web of Science]

Pestova E, Ganal MW, Roder MS (2000) Isolation and mapping of microsatellite markers specific for the D genome of bread wheat. Genome 43: 689–697[Medline]

Piñeros MA, Cançado GMA, Kochian LV (2008) Novel properties of the wheat aluminum tolerance organic acid transporter (TaALMT1) revealed by electrophysiological characterization in Xenopus oocytes: functional and structural implications. Plant Physiol 147: 2131–2146[Abstract/Free Full Text]

Polle E, Konzak CF, Kittrick JA (1978) Visual detection of aluminum tolerance levels in wheat by hematoxylin staining of seedling roots. Crop Sci 18: 823–827[Abstract/Free Full Text]

Raman H, Ryan PR, Raman R, Stodart BJ, Zhang K, Martin P, Wood R, Sasaki T, Yamamoto Y, Mackay M, et al (2008) Analysis of TaALMT1 traces the transmission of aluminum resistance in cultivated common wheat (Triticum aestivum L.). Theor Appl Genet 116: 343–354[CrossRef][Web of Science][Medline]

Raman H, Zhang K, Cakir M, Appels R, Garvin DF, Maron LG, Kochian LV, Moroni JS, Raman R, Imtiaz M, et al (2005) Molecular mapping and characterization of ALMT1, the aluminium-tolerance gene of bread wheat (Triticum aestivum L.). Genome 48: 781–791[Medline]

Riede CR, Anderson JA (1996) Linkage of RFLP markers to an aluminum tolerance gene in wheat. Crop Sci 36: 905–909[Abstract/Free Full Text]

Roder MS, Korzun V, Wendehake K, Plaschke J, Tixier MH, Philippe L, Martin WG (1998) A microsatellite map of wheat. Genetics 149: 2007–2023[Abstract/Free Full Text]

Ryan PR, Delhaize E, Jones DL (2001) Function and mechanism of organic anion exudation from plant roots. Annu Rev Plant Physiol Plant Mol Biol 52: 527–560[CrossRef][Web of Science][Medline]

Ryan PR, Delhaize E, Randall PJ (1995a) Characterisation of Al-stimulated efflux of malate from the apices of Al-tolerant wheat roots. Planta 196: 103–111[Web of Science]

Ryan PR, Delhaize E, Randall PJ (1995b) Malate efflux from root apices and tolerance to aluminium are highly correlated in wheat. Aust J Plant Physiol 22: 531–536[Web of Science]

Ryan PR, DiTomaso JM, Kochian LV (1993) Aluminum toxicity in roots: investigation of spatial sensitivity and the role of the root cap in Al-tolerance. J Exp Bot 44: 437–446[Abstract/Free Full Text]

Ryan PR, Skerrett M, Findlay G, Delhaize E, Tyerman SD (1997) Aluminium activates an anion channel in the apical cells of wheat roots. Proc Natl Acad Sci USA 94: 6547–6552[Abstract/Free Full Text]

Sasaki T, Ryan PR, Delhaize E, Hebb DM, Ogihara Y, Noda K, Matsumoto H, Yamamoto Y (2006) Analysis of the sequence upstream of the wheat (Triticum aestivum L.) ALMT1 gene and its relationship to aluminium tolerance. Plant Cell Physiol 47: 1343–1354[Abstract/Free Full Text]

Sasaki T, Yamamoto Y, Ezaki BB, Katsuhara M, Ahn SJ, Ryan PR, Delhaize E, Matsumoto H (2004) A wheat gene encoding an aluminum-activated malate transporter. Plant J 37: 645–653[CrossRef][Web of Science][Medline]

Sivaguru M, Horst WJ (1998) The distal part of the transition zone is the most aluminum-sensitive apical root zone of Zea mays L. Plant Physiol 116: 155–163[Abstract/Free Full Text]

Somers DJ, Gustafson JP (1995) The expression of aluminum stress induced polypeptides in a population segregating for aluminum tolerance in wheat (Triticum aestivum L.). Genome 38: 1213–1220[Medline]

Somers DJ, Isaac P, Edwards K (2004) A high-density microsatellite consensus map for bread wheat (Triticum aestivum L.). Theor Appl Genet 109: 1105–1114[CrossRef][Web of Science][Medline]

Song QJ, Shi JR, Singh S, Fickus EW, Costa JM, Lewis J, Gill BS, Ward R, Cregan PB (2005) Development and mapping of microsatellite (SSR) markers in wheat. Theor Appl Genet 110: 550–560[CrossRef][Web of Science][Medline]

Sourdille P, Singh S, Cadalen T, Brown-Guedira GL, Gay G, Qi L, Gill BS, Dufour P, Murigneux A, Bernard M (2004) Microsatellite-based deletion bin system for the establishment of genetic-physical map relationships in wheat (Triticum aestivum L.). Funct Integr Genomics 4: 12–25[CrossRef][Medline]

Stass A, Smit I, Eticha D, Oettler G, Horst WJ (2008) The significance of organic anion exudation for the aluminum resistance of primary triticale derived from wheat and rye parents differing in aluminum resistance. J Plant Nutr Soil Sci 171: 634–642[CrossRef]

Stodart BJ, Raman H, Coombes N, Mackay M (2007) Evaluating landraces of bread wheat Triticum aestivum L. for tolerance to aluminium under low pH conditions. Genet Resour Crop Evol 54: 759–766[CrossRef]

Tang Y, Garvin DF, Kochian LV, Sorrells ME, Carver BF (2002) Physiological genetics of aluminum tolerance in the wheat cultivar Atlas 66. Crop Sci 42: 1541–1546[Abstract/Free Full Text]

Taylor GJ (1988) The physiology of aluminum phytotoxicity. In H Sigel, A Sigel, eds, Metal Ions in Biological Systems, Vol 24. Marcel Dekker, New York, pp 123–163

Van os H, Stam P, Visser RGF, van Eck HJ (2005) SMOOTH: a statistical method for successful removal of genotyping errors from high-density genetic linkage data. Theor Appl Genet 112: 187–194[CrossRef][Web of Science][Medline]

von Uexküll HR, Mutert E (1995) Global extent, development and economic impact of acid soils. Plant Soil 171: 1–15[CrossRef][Web of Science]

Voorrips RE (2002) MapChart: software for the graphical presentation of linkage maps and QTLs. J Hered 93: 77–78[Free Full Text]

Wang J, Raman H, Zhou M, Ryan PR, Delhaize E, Hebb DM, Coombes N, Mendham N (2007) High-resolution mapping of Alp, the aluminium tolerance locus in barley (Hordeum vulgare L.), identifies a candidate gene controlling tolerance. Theor Appl Genet 115: 265–276[CrossRef][Web of Science][Medline]

Yamaguchi M, Sasaki T, Sivaguru M, Yamamoto Y, Osawa H, Ahn SJ, Matsumoto H (2005) Evidence for the plasma membrane localization of Al-activated malate transporter (ALMT1). Plant Cell Physiol 46: 812–816[Abstract/Free Full Text]

Zhang WH, Ryan PR, Sasaki T, Yamamoto Y, Sullivan W, Tyerman SD (2008) Electrophysiological characterisation of the TaALMT1 protein in transfected tobacco (Nicotiana tabacum L.) cells. Plant Cell Physiol 49: 1316–1330[Abstract/Free Full Text]

Zhang WH, Ryan PR, Tyerman SD (2001) Malate-permeable channels and cation channels activated by aluminum in the apical cells of wheat roots. Plant Physiol 125: 1459–1472[Abstract/Free Full Text]

Zhao Z, Ma JF, Sato K, Takeda K (2003) Differential Al resistance and citrate secretion in barley (Hordeum vulgare L.). Planta 217: 794–800[CrossRef][Web of Science][Medline]

Zheng SJ, Ma JF, Matsumoto H (1998a) High aluminum resistance in buckwheat. I. Al-induced specific secretion of oxalic acid from root tips. Plant Physiol 117: 745–751[Abstract/Free Full Text]

Zheng SJ, Ma JF, Matsumoto H (1998b) Continuous secretion of organic acids is related to aluminum resistance during relatively long-term exposure to aluminium stress. Physiol Plant 103: 209–214[CrossRef]

Zhou LL, Bai GH, Ma HX (2007) Quantitative trait loci for aluminum resistance in wheat. Mol Breed 19: 153–161[CrossRef]

Related articles in Plant Physiol.:

On the Inside: Peter V. Minorsky
Plant Physiol. 2009 149: 352-353. [Full Text]

This article has been cited by other articles:

E. A. Kellogg and C. R. Buell
Splendor in the Grasses
Plant Physiology, January 1, 2009; 149(1): 1 - 3.
[Full Text] [PDF]

This Article

Free via Open Access: OA

OA Abstract

Full Text (PDF)

Supplemental Data

OA All Versions of this Article:
149/1/340 most recent
pp.108.129155v1

Alert me when this article is cited

Alert me if a correction is posted

Services

Email this article to a friend

Related articles in Plant Physiol.

Similar articles in this journal

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via CrossRef

Citing Articles via Google Scholar

Google Scholar

Articles by Ryan, P. R.

Articles by Delhaize, E.

Search for Related Content

PubMed

PubMed Citation

Articles by Ryan, P. R.

Articles by Delhaize, E.

Agricola

Articles by Ryan, P. R.

Articles by Delhaize, E.

Related Collections

The Grasses

A Second Mechanism for Aluminum Resistance in Wheat Relies on the Constitutive Efflux of Citrate from Roots1,[W],[OA]

A Second Mechanism for Aluminum Resistance in Wheat Relies on the Constitutive Efflux of Citrate from Roots¹^,[W]^,[OA]