Interactions among PIN-FORMED and P-Glycoprotein Auxin Transporters in Arabidopsis

PGP19 mRNA and Protein Localization

The tissue-specific distribution patterns of PGP19 have not previously been described in detail; this information is important for understanding where PGP19 functions in the plant. In situ hybridization analysis showed that PGP19 was strongly expressed throughout the cotyledonary node and throughout the upper hypocotyl of light-grown seedlings (Figures 1A to 1D, 1G, and 1H ). PGP19 expression was increasingly restricted to the vascular tissue in hypocotyl regions distal to the node (Figure 1E). By contrast, PGP19 expression in dark-grown seedlings was observed throughout the hypocotyl (Figure 1F). PGP19 was also strongly expressed throughout the root (Figures 1I and 1J). This finding is consistent with previously published β-glucuronidase (GUS) expression analysis (Noh et al., 2001). PGP19 expression increased by 5-fold in dark-grown wild-type and pgp1 seedlings, whereas PGP1 expression increased by 14- and 8-fold in dark-grown wild-type and pgp19 seedlings, respectively. In real-time quantitative PCR analysis of upper inflorescence stems, PGP19 expression was enriched by approximately twofold in the inner tissues compared with the outer tissues, whereas PGP1 was equally expressed, consistent with microarray data (Suh et al., 2005).

• Download figure
• Open in new tab
• Download powerpoint

Figure 1.

PGP19 Localization in Light- and Dark-Grown Seedlings.

(A) to (J) Localization of PGP19 expression using in situ hybridization in 7-d-old seedlings. All seedlings are wild type (Wassilewskija [Ws]) unless indicated otherwise. Bars = 50 μm.

(A), (C) to (F), (H), and (J) Antisense probe.

(B), (G), and (I) Sense probe.

(A) to (E) and (G) to (J) Light-grown seedlings.

(F) Dark-grown seedling.

(A) Cotyledonary node and upper hypocotyl longitudinal section with an antisense probe shows signal in the vascular bundle.

(B) Cotyledonary node and upper hypocotyl longitudinal section with a sense probe shows no signal.

(C) Cotyledonary node cross section shows strong signal throughout the node.

(D) Upper hypocotyl (UH; below the cotyledonary node) cross section shows signal throughout the hypocotyl.

(E) Mid hypocotyl (MH) cross section shows signal restricted to the vascular bundle.

(F) Mid hypocotyl cross section of a dark-grown seedling shows signal throughout the hypocotyl.

(G) Hypocotyl cross section with a sense probe shows no signal.

(H) Hypocotyl cross section of a light-grown pgp19 seedling with an antisense probe shows no signal.

(I) Root cross section with a sense probe shows no signal.

(J) Root cross section with an antisense probe shows strong signal throughout the root.

(K) to (U) Immunohistochemical localization of PGP19 using PGP19-specific antiserum, unless indicated otherwise. All are 7-d-old wild-type (Ws) seedlings unless indicated otherwise. Bars = 50 μm.

(K) to (Q) and (S) to (W) Light-grown seedlings.

(N) and (R) Dark-grown seedlings.

(K) Cotyledonary node cross section shows strong signal throughout tissue.

(L) Upper hypocotyl (below the cotyledonary node) cross section shows signal throughout tissue.

(M) Mid hypocotyl cross section shows signal in the vascular bundle.

(N) Mid hypocotyl cross section of a dark-grown seedling shows signal throughout tissue.

(O) Cotyledonary node cross section of a pgp19 seedling does not show signal.

(P) Hypocotyl cross section of a pgp19 seedling does not show signal.

(Q) Bright-field overlay of (M).

(R) Bright-field overlay of (N).

(S) Whole mount root tip of a 5-d-old light-grown seedling shows signal in the stele, endodermis, pericycle, and cortex.

(T) Detail of the root tip shown in (S).

(U) Preimmune serum in whole mount root tip of a 5-d-old seedling does not show signal.

(V) Whole mount root tip of a 5-d-old pgp19 seedling does not show signal.

(W) KNOLLE, using anti-KNOLLE (green), signal localizes at the cell plate during cytokinesis in a 5-d-old seedling.

(X) Movement of [³H]IAA from stelar flow into the cortical/epidermal apoplast of mature root tissues before (gray bars) and after (black bars) application of additional cold IAA to the root–shoot transition zone. [³H]IAA was initially applied to the shoot apex in a discontinuous system to establish polar flow. Data are means ± sd (n = 10).

A PGP19-specific antiserum was prepared to a peptide derived from the soluble loop region of the protein (see Methods). Neither the preimmune serum in the wild type nor the PGP19 antiserum in pgp19 hypocotyls or roots had a signal (Figures 1O, 1P, 1U, and 1V). Using this PGP19 antiserum in the wild type, PGP19 localization coincided with PGP19 expression in the hypocotyls of light- and dark-grown seedlings (Figures 1K to 1N, 1Q, and 1R). In whole mount roots, a PGP19 signal at the plasma membrane was more abundant on the lower end of cells in the epidermis, cortex, and stele (Figures 1S and 1T); this signal was stably associated with the formation of lower cell walls (Figures 1S and 1T). However, the PGP19 signal was not associated with early cell plate formation, as seen with the cytokinesis marker KNOLLE (Figure 1W), indicating that PGP19 is not associated with early cell plate formation. Apolar PGP19 signals were observed in the pericycle, endodermis, and newly divided provascular cells of roots (Figures 1S and 1T).

PGP19 Functions in Long-Distance Auxin Transport and Auxin Retention in the Stele

Detailed analysis of auxin movement and mutant phenotypes indicates that PIN1 mediates the vectorial movement of auxin from the shoot apex to the root apex as well as localized auxin flow required for embryogenesis and aerial organ development (Tanaka et al., 2006). Consistent with localization in apical tissues (Figures 1G, 1K, 1S, and 1T), PGP19 appears to function coordinately with PGP1 in loading of auxin into basipetal streams at the shoot and root tip (Blakeslee et al., 2005b). However, PGP19 also plays an additional role in long-distance auxin transport, as shoot basipetal IAA transport is reduced by >50% in pgp19 (Noh et al., 2001) compared with a reduction of 27 ± 12% in pin1-7 using the same methods. This finding is consistent with PGP19 localization in the vascular bundle and immediately adjacent cells (Figures 1M, 1S, and 1T).

The localization of PGP19 in the root endodermis and pericycle suggests that PGP19 may enhance long-distance transport by preventing auxin entry into the plasmalemma of the cell layer adjacent to the primary vascular transport stream. We designed an experiment to measure the escape of auxin from the polar vascular stream by collection and counting of discontinuous cellulose/silica gel media strips supporting the mature portion of the seedling root (see Methods). Enhanced [³H]IAA efflux out of the stele was observed in pgp19 roots but not in wild type or pgp1 roots (P < 0.001; Figure 1X). A prediction from this model would be that increasing the auxin flux through the vascular stream would overwhelm the PGP19-mediated barrier effect and result in enhanced auxin export into the nonstelar apoplast. Consistent with that prediction, increasing the auxin flux by the addition of an extra 100 pmol of cold IAA resulted in increased stelar [³H]IAA efflux in the wild type and pgp1 but not in pgp19 (Figure 1X). This result is consistent with an increased lateral movement of auxin, presumed to be a factor in the hypergravitropic bending observed in pgp19 mutants (Noh et al., 2003).

PIN1 mRNA and Protein Localization in Arabidopsis Hypocotyls

PIN1 is abundant in inflorescence apices (Reinhardt et al., 2003; Heisler et al., 2005), and PIN1 expression becomes restricted to vascular tissues below the apex with >10-fold enrichment in the inner tissues of upper inflorescences in real-time quantitative PCR analysis, consistent with previous data (Gälweiler et al., 1998; Suh et al., 2005). By contrast, PIN7 expression was enriched by ∼1.2-fold in inner tissues of upper inflorescences in real-time quantitative PCR, consistent with microarray analysis (Suh et al., 2005). In light-grown hypocotyls, PIN1 expression, visualized with a Pro_PIN1:PIN1-GUS reporter, was strong at the apex and in the vascular tissue (Figure 2A ), and Pro_PIN1:PIN1–green fluorescent protein (GFP) signals were restricted to the vascular tissue below the cotyledonary node (Figure 2B). This suggests that a PIN1 immunolocalization signal previously observed in cortical and bundle sheath cells of light-grown hypocotyls (Noh et al., 2003) was nonspecific. It is also somewhat unlikely that signals observed outside the vascular strand in light-grown hypocotyls were the result of the PIN1 antiserum cross-reacting with PIN7, because, although PIN7 is expressed in these tissues (Figure 2C), Pro_PIN7:PIN7-GFP exhibits an apolar localization in these tissues (Figure 2D).

• Download figure
• Open in new tab
• Download powerpoint

Figure 2.

PIN1 Localization in Light- and Dark-Grown Seedlings.

(A) Pro_PIN1:GUS activity is observed at the shoot apex, in vascular tissue, and in the root tip of a light-grown seedling.

(B) Pro_PIN1:PIN1-GFP fluorescence is observed in the xylem parenchyma in hypocotyl and root tip in a light-grown seedling. MH, mid hypocotyl.

(C) Pro_PIN7:PIN7-GUS activity is observed at the node and throughout the hypocotyl in a dark-grown seedling. The abundance of PIN7 in leaf cells may contribute to the substrate specificity seen in protoplast transport assays (Geisler et al., 2005).

(D) Pro_PIN7:PIN7-GFP fluorescence is apolar in the epidermis of hypocotyls (top) and cotyledons (bottom).

(E) Expression of PGP19 and PIN1 in 5-d-old light- and dark-grown seedlings. The light-grown value was set to 100% for each gene. Data are means ± sd (n = 3). * P < 0.05.

(F) Pro_PIN1:PIN1-GFP fluorescence is observed in the xylem parenchyma and epidermis in the apical hook of a dark-grown seedling.

(G) Pro_PIN1:PIN1-GFP fluorescence is observed in the xylem parenchyma and adjacent cortical cell (arrow) in the hypocotyl of a dark-grown seedling.

Bars = 100 μm.

As was seen with PGP19, PIN1 expression increased in dark-grown seedlings (P < 0.05; Figure 2E). In dark-grown seedlings, PIN1 signal was observed in the vascular parenchyma and epidermis of the shoot apical hook (Figure 2F) and in the vascular parenchyma and the adjacent cortical cells in the mid hypocotyl (Figure 2G), consistent with previous reports (Blakeslee et al., 2004). Therefore, direct subcellular interactions of PIN1 and PGP19 are likely only at the shoot and root apices and in bundle sheath cells of dark-grown hypocotyls.

Colocalization: Overlapping Patterns of Expression and Localization

The expression patterns of PGP1, PGP19, PIN1, and PIN2 in roots from the AREX database (www.arexdb.org; Birnbaum et al., 2003) are presented in Figure 3A . PIN1 and PGP19 expression patterns appeared to overlap strongly in the stele and endodermis. In the cotyledonary node and upper hypocotyl, PIN1 and PGP19 expression overlapped in vascular and bundle sheath tissues in light- and dark-grown seedlings (Figures 1A, 1C, 2A, and 2F).

• Download figure
• Open in new tab
• Download powerpoint

Figure 3.

Overlapping Patterns of Expression and Localization.

(A) Heat map of root tips from the AREX database (www.arexdb.org) showing the expression of PGP1, PGP19, PIN1, and PIN2. Relative expression is proportional to color intensity.

(B) to (H) PGP localizations are shown in red; PIN and ATPase localizations are shown in green; colocalization is shown in yellow. All images show coimmunolocalizations in 5-d-old light-grown seedlings. Bar = 50 μm.

(B) PGP19 and Pro_PIN1:PIN1-GFP in the root.

(C) Pro_PGP19:PGP19-HA and PIN1 in the root. s, stele; p, pericycle; e, endodermis; c, cortex. Pro_PGP19:PGP19-HA complements the phenotype of pgp19. The PGP19-HA construct was used previously by Petrášek et al. (2006).

(D) Pro_PGP19:PGP19-HA and PIN1 in the hypocotyl.

(E) Pro_PGP1:PGP1-cmyc and PIN1 in the root.

(F) Pro_PGP1:PGP1-cmyc and PIN2 in the root.

(G) Pro_PGP19:PGP19-HA and PIN2 in the root.

(H) Pro_PGP19:PGP19-HA and plasma membrane (PM) ATPase in the root.

PGP19, PIN1, and PIN2 were coimmunolocalized in roots and hypocotyls. PGP19 and Pro_PIN1:PIN1-GFP signals overlapped in the stele, endodermis, and pericycle of roots (Figure 3B). Pro_PGP19:PGP19-hemagglutin (HA) and PIN1 signals were similar to those with the native PGP19 antibody and Pro_PIN1:PIN1-GFP, although the signal in the stele was reduced; a detail of the coimmunolocalization in roots is shown in Figure 3C. Pro_PGP19:PGP19-HA and PIN2 signals overlapped in cortical cells in the root (Figure 3G). As a control, Pro_PGP19:PGP19-HA was coimmunolocalized with plasma membrane H⁺-ATPase (AHA), and the signals overlapped in the root epidermal, cortical, and endodermal cells (Figure 3H).

Although PIN1 and PGP19 expression overlap at the node and vascular tissue in hypocotyls, in the mid hypocotyl of light-grown seedlings, polar PGP19 signals in bundle sheath and cortical cells did not overlap with Pro_PIN1:PIN1-GFP signals that were restricted to vascular parenchyma cells (Figure 3D). In addition to polar localization, a weaker PGP19 localization was observed on lateral membranes in cortical cells in hypocotyls (Figure 3D), where PIN3 was previously localized (Friml et al., 2002b). This finding suggests possible interactions with PIN3-mediated redirection of auxin from bundle sheath to vascular transport streams; those interactions are currently being pursued in the context of phototropic bending.

PGP1, PIN1, and PIN2 were also coimmunolocalized in roots. Pro_PGP1:PGP1-cmyc signal overlapped with PIN1 in stelar tissues between the lateral root cap and the distal elongation zone of the root (Figure 3E) and with PIN2 signal in cortical and epidermal cells in the same region (Figure 3F). This suggests that possible PGP1–PIN interactions in this region could mediate the delivery of redirected auxin accumulated in the lateral root cap by AUX1 and PGP4 to the elongation zone. Consistent with this function, auxin transport from the root apex has been shown to be reduced in this region in pgp1 mutants (Geisler et al., 2005).

Genetic Analysis Suggests Both Additive and Synergistic Auxin Transport Mechanisms

Crosses of pgp with pin mutants were made to determine whether there was a genetic interaction affecting shoot phenotypes. The phenotypes of the wild type and the single mutants are presented in Figures 4A to 4C . The wild-type plants had extended inflorescence stems as well as axillary and secondary inflorescences, rosette and cauline leaves were present and numerous, and flowers and siliques were present (Figure 4A). pgp1 pgp19 plants were dwarfed with short inflorescences, reduced axillary and secondary inflorescences, and reduced numbers of rosette and cauline leaves, which were smaller and curled; flowers and siliques were present (Figure 4B). pin1 mutants had a single pin-formed inflorescence stem, reduced secondary but no axillary inflorescences, wild type–like rosette, leaves, and no cauline leaves, flowers, or siliques (Figure 4C). The phenotypes of the single mutants were consistent with previously published reports (Okada et al., 1991; Gälweiler et al., 1998; Noh et al., 2001).

• Download figure
• Open in new tab
• Download powerpoint

Figure 4.

Phenotypes of pgp pin Mutants.

(A) Wild-type Columbia (Col-0) plant.

(B) pgp1 pgp19 plant.

(C) pin1 plant.

(D) pin1 pgp19 plant

(E) Another pin1 pgp19 plant.

(F) pin1 pgp1 pgp19 plant.

(G) Another pin1 pgp1 pgp19 plant.

(H) Root phenotypes of the wild type, pgp1 pgp19, pin2, and pin2 pgp1 pgp19. The number of roots in 30° sectors of a circle were counted and expressed as a percentage of the total number of roots. Vertical position represents normal gravitropic response. Values were calculated using 40 seedlings per experiment.

Bar = 5 cm in (A) to (G) and 1 cm in (H).

The pin1 pgp19 double mutants had a single pin-formed inflorescence, no axillary or secondary inflorescences, and no flowers, siliques, or cauline leaves. They also had dwarf stature, reduced number of rosette leaves that were curlier than pgp19 or pgp1 pgp19 leaves, altered leaf margins, and occasionally more trichomes (Figures 4D and 4E). Reductions in leaf number were also observed in pin1 as1 mutants not observed in the single mutants, because ASYMMETRIC LEAVES1 (AS1) and PIN1 are functionally redundant in leaf initiation (Hay et al., 2006). The pin1 pgp1 pgp19 triple mutants showed increased dwarf stature, loss of apical dominance, fused cotyledons, reduced number of rosette leaves, and curlier leaves with altered leaf margins (Figures 4F and 4G). Alterations in leaf margin phenotypes were observed in the double and triple mutants not observed in pin1 or pgp19 alone, consistent with leaf margin phenotypes in other mutants with perturbed local auxin gradients (Hay et al., 2006). Flowers develop in pin1 pgp1 pgp19 plants, unlike in pin1 or pin1 pgp19 (Figure 4G), suggesting that the loss of PGP1 is epistatic to PIN1 in the shoot apex, as it partially restores floral development, presumably as a result of ectopic auxin accumulation in the shoot apical meristem. This partial floral rescue is similar to that in pin1 bp double mutants (Hay et al., 2006), suggesting that the altered local auxin accumulations in pin1 pgp1 pgp19 may affect BREVIPEDICELLUS (BP) expression.

Crosses of pin2 with pgp mutants were also made to determine whether there was a genetic interaction affecting root gravitropic phenotypes. Gravitropic bending is only slightly affected in pgp19 (Geisler et al., 2005), pgp1 has no detectable gravitropic phenotype (Noh et al., 2003), and pin2 is agravitropic (Chen et al., 1998; Luschnig et al., 1998). In our hands, single pin and single or double pgp mutations exhibited only partial defects in gravitropic growth (Figure 4H). However, the pin2 pgp1 pgp19 triple mutant exhibited completely agravitropic root growth (Figure 4H), similar to what is seen in aux1 (Swarup et al., 2005). This finding suggests a synergistic interaction of PIN2 and PGPs in the root.

Loss of PIN1 or PGP19 Results in Decreased Transport Specificity in Planta

In whole plant auxin transport assays, BA is generally used as a control, because it is a weak organic anion that is poorly transported (Geisler et al., 2005). We had previously found that heterologous expression of PIN1, PIN2, PGP1, and PGP19 in nonplant systems activated increased levels of BA transport, suggesting that factors present in plants conferred additional auxin substrate specificity (Geisler et al., 2005; Bouchard et al., 2006; Petrášek et al., 2006). We reexamined basipetal BA transport in the wild type and pin1, pgp1, and pgp19 mutants to ascertain whether the loss of one of these transport components resulted in increased BA transport. Basipetal BA transport in wild-type and pgp1 seedlings was ∼5% of IAA transport but was enhanced significantly in pin1 and pgp19 (P < 0.05; Figure 5 ). These results indicate that the absence of either PIN1 or PGP19 in planta reduces the substrate specificity of the transported anion, suggesting a biochemical interaction.

• Download figure
• Open in new tab
• Download powerpoint

Figure 5.

Substrate Specificity in Planta.

[³H]BA transport in wild-type (Ws), pgp1, pgp19, and pin1 seedlings. Data are means ± sd and are expressed as percentages of wild-type values (n = 3). * P < 0.05.

Biochemical Interaction Studies Suggest Specific PIN–PGP Interactions

Two independent methods were used to determine whether protein–protein interactions could occur between PGPs and PINs: coimmunoprecipitation and yeast two-hybrid assays. The identities of the proteins detected were confirmed by protein gel blotting and mass spectral analysis.

Coimmunoprecipitation Assays

Detergent-solubilized microsomal membrane proteins (microsomal proteins) from wild-type seedlings were incubated with polyclonal antiserum recognizing PGP1 and PGP19 (PGP1/19), fractionated by fast protein liquid chromatography, and analyzed by SDS-PAGE and protein gel blot analysis. Protein gel blot analysis using anti-PIN1 showed a signal at ∼67 kD (Figure 6A ), indicating that PIN1 coimmunoprecipitated with anti-PGP1/19. We repeated the assay with PGP19 antiserum and saw that PIN1 coimmunoprecipitated with PGP19 (Figure 6A). As a control, we repeated the assays using plasma membrane ATPase AHA2 antiserum, and PIN1 did not coimmunoprecipitate (Figure 6A). Additional controls included coimmunoprecipitations with PIN1, PGP19, and PGP1/19 antisera in the pgp19, pgp1 pgp19, and pin1 mutant backgrounds; no signals were observed (see Supplemental Figure 2A online), indicating specificity of the antisera.

• Download figure
• Open in new tab
• Download powerpoint

Figure 6.

Protein–Protein Interactions Are Indicated in Coimmunoprecipitation and Yeast Two-Hybrid Assays.

(A) to (C) Coimmunoprecipitation assays.

(A) Detergent-solubilized proteins from 5-mg microsomal membranes from the wild type (Ws) immunoprecipitated (IP) with PGP1/19 antiserum (which strongly binds PGP1 but PGP19 less strongly; left), PGP19 antiserum (middle), or AHA2 antibody (right) as a control. The blots were probed with PIN1 antibody. PGP1/19, PGP19, and PIN1 coimmunoprecipitated. Samples were run on 12% gels.

(B) Detergent-solubilized proteins from 10-mg microsomal membranes from Pro_35S:PGP19-HA transformants coimmunoprecipitated with PIN1 antiserum (left). In the reciprocal experiment, PGP19 coimmunoprecipitated with PIN1-GFP in Pro_PIN1:PIN1-GFP transformants (right). Samples were run on 8% gels.

(C) Detergent-solubilized proteins from 10-mg microsomal membranes from Pro_PGP1:PGP1-cmyc transformants immunoprecipitated with cmyc antibody and probed with either PIN1 (left) or AHA2 (right) antiserum as a control. PGP1-cmyc coimmunoprecipitated PIN1 but not AHA2. A nonspecific band is observed on both blots. Coimmunoprecipitations are not quantitative. Samples were run on 8% gels.

(D) Yeast two-hybrid assays. Soluble loops of PIN1, PIN2, and the C terminus of PGP19 were used in yeast two-hybrid interaction assays and growth and α-galactosidase assays for MEL1 reporter gene expression. Empty binding domain (BD) or activation domain (AD) vectors were transformed with PGP19-AD vector or PGP19-BD vector, respectively, as negative controls. AD and BD constructs for reverse assays were also analyzed, and the results were the same as the data presented. In addition, the PIN-AD and PIN-BD assays showed no growth or α-galactosidase activity. Three transformants from 10 independent transformations for each pair of constructs were analyzed. Values shown are means ± sd (n = 2). * P < 0.001, as determined by Student's t test.

Microsomal proteins from Pro_35S:PGP19-HA transformants were incubated with PIN1 antiserum, and protein gel blots showed an ∼136-kD signal with anti-HA, indicating that PGP19-HA coimmunoprecipitated with PIN1 (Figure 6B). Reciprocal coimmunoprecipitations of microsomal proteins from PGP19-HA overexpression lines were performed using anti-HA, and protein gel blots probed with PIN1 antiserum showed a signal at ∼67 kD (see Supplemental Figure 2B online), supporting PIN1 and PGP19-HA coimmunoprecipitation. As a control, the supernatants and microsomal proteins from PGP19-HA and wild-type detergent-solubilized membranes were incubated with anti-HA, and no PIN1 signal was observed on the protein gel blots (see Supplemental Figure 2B online). As we were concerned that using PGP19-HA overexpression transformants for coimmunoprecipitation experiments might provide biased results, we repeated the experiments with Pro_PIN1:PIN1-GFP transformants. Microsomal proteins from Pro_PIN1:PIN1-GFP transformants were incubated with GFP antiserum, and the protein gel blots showed a signal with anti-PGP19 (Figure 6B). No signal was obtained when the experiments were repeated with wild-type microsomal proteins (see Supplemental Figure 2B online). This finding indicates that PIN1-GFP coimmunoprecipitated with PGP19.

Because the PGP1/19 antiserum reacts with both PGP1 and PGP19, we investigated PGP1 and PIN1 interactions. Microsomal proteins from Pro_PGP1:PGP1-cymc were incubated with cmyc antiserum. Protein gel blots probed with anti-PIN1 showed an ∼67-kD signal (Figure 6C), indicating that PGP1-cmyc and PIN1 coimmunoprecipitated. As a control, protein gel blots were probed with AHA2, and no signal was observed (Figure 6C). Coimmunoprecipitation assays with PGP19, PGP1, and PIN2 were also conducted, and no signal was observed. Additionally, no signal was observed in coimmunoprecipitations with PGP4 and PIN1 or PIN2. These data suggest that PIN1 interacts with both PGP1 and PGP19.

Functional Interactions in Heterologous Systems

We investigated whether the observed protein–protein interactions had functional implications by coexpressing PGP and PIN proteins in the HeLa and yeast heterologous systems used previously to demonstrate transport activity (Geisler et al., 2005; Teresaka et al., 2005; Bouchard et al., 2006; Petrášek et al., 2006). Immunolocalizations confirmed that proteins expressed in HeLa cells were present on the plasma membrane (see Supplemental Figures 3A and 3B online), and fluorescence-activated cell sorting assays confirmed that cells expressing or coexpressing PGPs and PINs did not transport Hs MDR substrates (see Supplemental Figure 3C online). The substrate efflux profiles of PGP1, PGP19, PIN1, and PIN2 expressed in the HeLa system are presented in Figure 7A for reference. In the HeLa system PGP1, PGP19, and PIN2 mediated the efflux of the natural auxins IAA and BA, and IAA efflux was reduced in the presence of naphthylphthalamic acid (NPA) (Figure 7A). PIN1 did not mediate IAA efflux, but it did mediate BA efflux, like PGP1, PGP19, and PIN2 (Figure 7A). Substrate specificity was further analyzed using the synthetic auxin analog 1-naphthaleneacetic acid (1-NAA), and PGPs and PINs showed poor efflux of 1-NAA, indicating low affinity for 1-NAA compared with IAA (Figure 7B).

• Download figure
• Open in new tab
• Download powerpoint

Figure 7.

Coexpression of PIN and PGP Transporters Increases Substrate Specificity, Inhibitor Sensitivity, and Efflux.

(A) to (F) Efflux of radiolabeled substrates from HeLa cells expressing PGP1, PGP19, PIN1, or PIN2. Data are means with sum sd (n = 3).

(A) Net efflux of [³H]IAA, [³H]IAA in the presence of NPA, or [³H]BA in HeLa cells expressing PGP1, PGP19, PIN1, PIN2, and AUX1. Baselines from a new set of experiments are presented only for the purpose of comparison with coexpression studies. Data for PGP1 and PIN2 were originally published by Geisler et al. (2005) and Petrášek et al. (2006). Efflux of substrates by PGP1 and PGP19 were significantly different from empty vector values (P < 0.05), and NPA inhibition of IAA efflux by PGP19 was significantly different compared with IAA alone (P < 0.05). BA efflux by PIN1 was significantly different from empty vector values (P < 0.05), as was IAA efflux by PIN2 (P = 0.05).

(B) [³H]1-NAA export by PGP1, PGP4, PGP19, PIN1, and PIN2. PIN1 specificity for 1-NAA was not different from IAA. PGPs and PIN2 had less affinity for 1-NAA than for IAA.

(C) Net efflux of [³H]IAA, [³H]IAA in the presence of NPA, or [³H]BA in HeLa cells coexpressing PIN1 with PGP1 or PGP19. IAA efflux by PIN1+PGP1 or PGP19 was significantly different from that of each protein alone (P < 0.05). NPA inhibition of IAA efflux by PIN1+PGP1 or PGP19 was significantly different compared with IAA alone (P < 0.05). BA efflux was not different from empty vector values (P > 0.05).

(D) Net efflux of [³H]IAA, [³H]IAA in the presence of NPA, or [³H]BA in HeLa cells coexpressing PIN2 with PGP1 or PGP19. IAA efflux by PIN2+PGP1 or PGP19 was significantly different from that of each protein alone (P < 0.05). NPA inhibition of IAA efflux by PIN2+PGP1 or PGP19 was significantly different compared with IAA alone (P < 0.05). BA efflux was not different from empty vector values (P > 0.05).

(E) Net efflux of [³H]IAA in HeLa cells coexpressing PGP4 with PIN1 or PIN2. Coexpression of PGP4 with PIN1 reversed PGP4-mediated influx, resulting in auxin efflux. Coexpression of PGP4 with PIN2 led to a synergistic increase in auxin influx. IAA efflux by PGP4 was significantly different from that of empty vector alone (P < 0.05). IAA efflux by PGP4+PIN1 or PIN2 was significantly different compared with each protein alone (P < 0.05).

(F) Net efflux of [³H]IAA in HeLa cells expressing AUX1, PGP1, or PGP4. AUX1 expressed in HeLa cells mediated IAA influx. When AUX1 was coexpressed with PGP4, an additive effect on net IAA influx was observed. When AUX1 was coexpressed with PGP1, net IAA transport was not observed.

(G) and (H) Efflux of radiolabeled IAA and BA from yeast cells expressing PGP1, PIN1, or PIN2. Data are means with se (n = 5 for IAA and n = 3 for BA).

(G) Net [³H]IAA export in yeast cells expressing PIN1, PIN2, or PGP1 or coexpressing PGP1 with PIN1 or PIN2. Coexpression of PGP1 with PIN1 synergistically increased auxin efflux, whereas coexpression of PGP1 with PIN2/AGR1/EIR1 led to decreased auxin efflux.

(H) Net [¹⁴C]BA export in yeast cells expressing PIN1, PIN2, or PGP1 or coexpressing PGP1 with PIN1 or PIN2. Cells coexpressing PGP1 with PIN1 or PIN2 exhibited reduced BA efflux.

When PIN1 was coexpressed with PGP1 or PGP19 in HeLa cells, IAA efflux increased by ∼1.8- or ∼2-fold, respectively, compared with when the proteins were expressed alone (Figure 7C), indicating a synergistic interaction between PIN1 and PGP1 or PGP19. No IAA efflux occurred in the presence of NPA, and no BA efflux was observed (Figure 7C). Therefore, coexpression enhanced both inhibitor sensitivity and substrate specificity, supporting a functional interaction between PIN1 and PGP1 or PGP19.

By contrast, when PIN2 was coexpressed with PGP1 or PGP19 in HeLa cells, IAA efflux was reduced (27 and 47%, respectively) compared with the sum of the transport activities observed when each protein was expressed alone (Figure 7D). IAA efflux was inhibited in the presence of NPA, but the sensitivity to the inhibitor was not enhanced by coexpression. However, substrate specificity was still enhanced, as BA efflux was negligible (Figure 7D).

To further investigate whether the functional activity of PGP–PIN pairings was specific or nonspecific, we coexpressed PIN1 and PIN2 with PGP4. PGP4 localization does not coincide with PIN1 but does coincide with PIN2 localization in three cell stories in the central elongation zone (Müller et al., 1998; Steinmann et al., 1999; Terasaka et al., 2005). When PGP4 and PIN1 were coexpressed in HeLa cells, IAA efflux was observed (Figure 7E). This finding indicates that PIN1 interaction with PGP4 reversed PGP4 uptake transport activity. Coexpression of PGP4 and PIN2 enhanced auxin retention by approximately threefold compared with PGP4 expressed alone (Figure 7E). This suggests that a synergistic interaction between these proteins can occur, similar to that observed with PIN1 and PGP1 or PGP19. These data suggest that, in specific tissues in which PINs and PGPs colocalize subcellularly, specific interactions can occur; they also suggest that PIN proteins may regulate the directionality of PGP-mediated cellular transport across the plasma membrane in those tissues.

We also investigated whether the auxin influx carrier AUX1 could interact with PINs or PGPs. No interactions between AUX1–yellow fluorescent protein and PIN1 or PIN2 or PGP1, PGP4, or PGP19 were observed in coimmunoprecipitation assays, although occasionally a weak PIN1 signal was seen from coimmunoprecipitation with AUX1–yellow fluorescent protein from root tissues. Yeast two-hybrid assays of AUX1 (full-length AUX1 in the split-ubiquitin system, and C- and N-terminal domains of AUX1 in the GAL4 system) with soluble loops of PIN1 or PIN2 and C-terminal regions PGP1, PGP4, or PGP19 were inconclusive. AUX1-expressing HeLa cells mediated IAA influx (Figure 7F), consistent with previous results (Yang et al., 2006). When AUX1 was coexpressed with PGP4, an additive effect on net IAA influx was observed (approximately the sum of each expressed alone), but when it was coexpressed with PGP1, net IAA transport was not observed (Figure 7F). These data suggest that AUX1-mediated auxin transport does not involve direct PIN or PGP interactors.

When coexpression studies were recapitulated in the yeast Saccharomyces cerevisiae with greatly reduced background ABC transporter activity (Geisler et al., 2005; Petrášek et al., 2006), PIN1-mediated IAA export in yeast cells was negligible, whereas PIN2 and PGP1 had higher levels of IAA export (Figure 7G); protein gel blot analysis confirmed that PIN1 and PIN2 were expressed in yeast (see Supplemental Figure 3D online). Consistent with the net efflux observed in HeLa cells, coexpression of PGP1 and PIN1 synergistically increased IAA export in yeast cells (169% of the sum of each expressed alone), whereas coexpression of PGP1 and PIN2 was antagonistic (49% of the sum of each expressed alone) (Figure 7G).

As seen in HeLa cells, yeast cells expressing PIN1 alone exported more BA than PGP1 or PGP19, suggesting PIN1 activation of endogenous organic anion transporters or monocarboxylic acid transporters; PIN2 export of BA was low, as in HeLa cells (Figure 7H). Coexpression of PGP1 with PIN1 or PIN2 reduced BA export (49 and 66%, respectively, of the sum of each expressed alone), suggesting that coexpression imparted increased substrate specificity. PGP19 is not expressed properly in S. cerevisiae as a result of hyperglycosylation (Noh et al., 2001; Geisler et al., 2005).

Substrate specificity in HeLa cells was examined in competition and inhibition assays. In HeLa cells expressing PGP19 and PIN2, BA partially competed with IAA efflux (see Supplemental Figure 3E online). However, PGP19 mediated BA efflux to a greater extent than PIN2, suggesting that PIN2 has greater specificity for IAA than does PGP19. Another concern was that HeLa cells have background organic ion transporter (OAT) activity (Campbell et al., 2004; Wang et al., 2005) that might contribute to increased auxin efflux when PIN2, PGP1, or PGP19 is expressed in these cells (Geisler et al., 2005; Bouchard et al., 2006; Petrášek et al., 2006). In the empty vector, the OAT inhibitor cardio green resulted in a 14 ± 8.4% increase in IAA retention. Cardio green inhibited IAA efflux by ∼17% in PGP19 (similar to empty vector) and by ∼56% in PIN2 compared with the untreated respective controls (see Supplemental Figure 3E online). This finding indicates that PIN2 not only mediated IAA efflux but also activated an endogenous OAT activity in HeLa cells. As OAT orthologs are found in Arabidopsis, the impact of PIN activation of these transporters is unclear.

Real-Time Quantitative PCR

Real-time quantitative PCR was as described previously (Peer et al., 2004). Arabidopsis thaliana seedlings were grown as described by Murphy and Taiz (1995). Epidermal peels of upper inflorescence stems were prepared as described by Suh et al. (2005).

In Situ Hybridization

The method used was described by Grigg et al. (2005). PGP19 cDNA was cloned into pBluescript SK+, and sense and antisense PGP19 probes were prepared. Sections of 5-d-old dark- and light-grown seedlings were probed. Hybridization was visualized by digoxigenin labeling.

Immunolocalization

Pro_PIN1:PIN1-GFP (Benkova et al., 2003) seedlings were grown in the dark, and visualization was performed as described previously (Noh et al., 2003; Blakeslee et al., 2004), except that the seedlings were not fixed before imaging. Immunolocalizations in roots using the Triton X-100 series were performed according to the protocols of Peer et al. (2004). For PGP19 localization, the anti-PGP19 antibody was used at 1:800 dilution. Pro_PIN1:PIN1-GFP seedlings were used for coimmunolocalization of PIN1 and PGP19 according to the protocol described by Peer et al. (2004).

Whole mount immunolocalization was performed on 3- to 4-d-old seedlings grown vertically on Murashige and Skoog plates using the InsituPro roboter as described by Friml et al. (2003), except for using PBS instead of microtubule stabilizing buffer. The antibodies used were PIN1 (Gälweiler et al., 1998; Paciorek et al., 2005) at a final dilution of 1:1000, PIN2 (Müller et al., 1998) at a final dilution of 1:1000, HA.11 monoclonal antibody (BAbCO) at a final dilution of 1:800, and H⁺-ATPase (Serrano et al., 1991) at a final dilution of 1:500. For the secondary antibodies, anti-rabbit fluorescein isothiocyanate and anti-mouse Cy3 (Dianova), the final dilution used was 1:600. Images were taken on Leica TSC and Zeiss LSM 210 META confocal microscopes.

PGP19 Antibody

Polyclonal anti-PGP19 antiserum was produced from a rabbit using 6× His–tagged PGP19 fragments containing amino acids 334 to 620. Anti-PGP19 antibodies were then purified form the antiserum using an antigen-blotted polyvinylidene difluoride membrane (Hybond-P; Amersham Biosciences). The amino acid sequence of antigen 334 to 620 is 5′-AGYKLMEIINQRPTIIQDPLDGKCLDQVHGNIEFKDVTFSYPSRPDVMIFRNFNIFFPSGKTVAVVGGSGSGKSTVVSLIERFYDPNSGQILLDGVEIKTLQLKFLREQIGLVNQEPALFATTILENILYGKPDATMVEVEAAASAANAHSFITLLPKGYDTQVGERGVQLSGGQKQRIAIARAMLKDPKILLLDEATSALDASSESIVQEALDRVMVGRTTVVVAHRLCTIRNVDSIAVIQQGQVVETGTHEELIAKSGAYASLIRFQEMVGTRDFSNPSTRRTRS-3′.

Pro_PGP19:PGP19-HA Construct

The genomic fragment of PGP19 (ATG to stop codon) was amplified by error-prone PCR and cloned to pGreenII-Kan (Hellens et al., 2000) through XhoI and XbaI sites. HA tag was introduced on the C terminus of the protein on the reverse primer. The 2-kb fragment of the PGP19 promoter was amplified by PCR and cloned to ApaI and SalI sites. The 400-bp terminator region of PGP19 was amplified and cloned with BstXI and NotI sites to create the final construct, pGreenPGP19-HA. The construct was transformed to Columbia wild-type plants by the standard floral-dip method (Clough and Bent, 1998). Transformants were selected on Murashige and Skoog medium plates with kanamycin (50 mg/L). The hypomorphic and epinastic phenotypes of pgp19 were complemented by transformation with Pro_PGP19:PGP19-HA, and these transformants were used to immunolocalize PGP19.

Coimmunoprecipitation Assays

Microsomal fractions were prepared from 2 to 3 g fresh weight of 21-d-old Arabidopsis plants and detergent-solubilized in ∼1 mL of resuspension buffer using 0.1% Brij and 0.05% CHAPS, as described previously (Murphy et al., 2002). Solubilized proteins were incubated with anti-PGP1/19 for 2 h at 4°C. The anti-PGP1 antibody was originally raised against a fragment of PGP1 (Sidler et al., 1998) and had broad specificity for PGPs. However, after repurification, the antibody reacts with PGP1 and PGP19 (Geisler et al., 2003). The antibody also reacts with a 97-kD band (Geisler et al., 2003) subsequently determined by tryptic digest and mass spectrometry analysis to consist of truncated forms of PGP19 and PGP4. Antibodies were conjugated to ReactiGel or protein A–Sepharose (Pierce Biotechnology) according to the manufacturer's protocol before incubation. Anti-PGP19, anti-PGP4, anti-PIN1, anti-PIN2, anti-AHA2, anti-GFP, anti-HA, and anti-cmyc were also used. The slurry was transferred to a fast protein liquid chromatography column (Pharmacia), washed in 10 bed volumes of buffer A (10 mM BTP-MES, pH 7.8, 1 mM DTT, 0.1% Triton X-100, 1 mM phenylmethylsulfonyl fluoride, 200 ng/mL leupeptin, and 200 μM benzamidine), and eluted using a 20-min, 0.25 mL/min, 0 to 100% linear gradient of buffer B (1 M NaCl, 0.1 M Na-citrate, pH 3.0, 1 mM DTT, 0.1% Triton X-100, 1 mM phenylmethylsulfonyl fluoride, 200 ng/mL leupeptin, and 200 μM benzamidine). Fractions (0.5 mL) were precipitated with trichloroacetic acid, washed three times in acetone, resuspended in SDS buffer, and analyzed via 10% SDS-PAGE and protein gel blotting. The blot was probed with PIN1 antibodies from two different sources (Gälweiler et al., 1998; Paciorek et al., 2005), which yielded identical results.

Yeast Two-Hybrid Analysis

Constructs were designed to test the protein–protein interactions between PIN1 (At1g73590), PIN2 (At5g57090), and PGP19 (At3g28860). The PIN2 soluble region (453 to 1509 bp) and the PIN1 soluble region (457 to 1443 bp) were amplified by PCR. The following primers were used: PIN2 (EIR1-EcoRI-5, 5′-CGGAATTCCTCCGTGGGGCTAAGCTTCTCATC-3′; EIR1-PST1-3, 5′-GCTGCAGTGTTAGGGTTTCGAATGAGTTTT-3′); PIN1 (PIN1MID-5, 5′-CCGGAATTCGAGTACCGTGGAGCTAAG-3′; PIN1MID-3, 5′-CGTCTGCAGGGAGTAAGAGTTGGGATT-3′). PCR products were cloned into pGBKT7 via EcoRI and PstI restriction sites to generate GAL4 DNA binding domain fusion proteins: MID-PIN2 and MID-PIN1. To generate GAL4 activation domain fusion partner proteins, the C terminus of PGP19 (2893 to stop) was amplified by PCR (MDR-C-5, 5′-CCGGAATTCGCAGCTCGAGCCGCAAAT-3′; MDR-PSTI-3, 5′-GCACTGCAGAATCCTATGTGTTTGAAG-3′). The PCR product was cloned into the pGAD424 vector (C-MDR1) as described above. Activation domain and binding domain constructs for reverse assays were also made as described above. Although some autoactivation of PGP19 was observed, the interaction of PGP19 with PINs was confirmed with reverse assays. All PCR-mediated cloned constructs were verified by sequencing. For interaction analysis, two combinatory constructs were transformed simultaneously into the AH109 yeast strain (Clontech) and tested for His3+, Trp+, Leu+, and Ade+ auxotrophy and MEL1 (α-galactosidase assay) reporter activity according to the manufacturer's protocols.

In Planta Transport Assays

HeLa Cell Transport Assays

For the radiolabeled substrate accumulation assay, PGP1 (At2g36910), PGP4 (At2g47000), PGP19 (At3g28860), PIN1 (At1g73590), PIN2 (At5g57090), and AUX1 (At5g01240) were expressed in mammalian HeLa cells using a vaccinia virus cotransfection system providing several advantages over other heterologous expression systems, including proper glycosylation and suppression of host protein synthesis after vaccinia infection (Elroy-Stein and Moss, 1990). The transient vaccinia expression system was used because stable cell lines develop mutations and express other endogenous drug-resistance mechanisms. Full-length PGP1, PGP19, PIN1, PIN2, and AUX1 cDNAs were cloned into the MCS of the pTM1 vector (Hrycyna et al., 1998). pTM1-PGP1, pTM1-PGP19, pTM-PGP4, and pTM-PIN2 were described previously (Geisler et al., 2005; Terasaka et al., 2005; Petrášek et al., 2006). For pTM1-PIN1, a PIN1 PCR fragment containing NcoI/BamHI restriction sites was generated using the following primers: PIN1-S, 5′-CATGCCATGGCAATGATTACGGCGGCGGAC-3′; PIN1-AS, 5′-CGCGGATCCAGCGTAATCTGGTACGTCGTATAGACCCAAGAGAATGTA-3′. For pTM1-AUX1, an AUX1 fragment containing NcoI/BamHI HA restriction sites was generated using the following primers: AUX1-S, 5′-CATGCCATGGGCATGTCGGAAGGAGTAGAA-3′; AUX1-AS, 5′-CGCGGATCCAGCGTAATCTGGTACGTCGTAAAGACGGTGGTGTAAAGC-3′. Assays for the accumulation of radiolabeled substrates were performed according to the method described by Geisler et al. (2005). Cells were transfected on six-well plates with 2 μg of DNA (pTM1 control vector, PGP1, PGP19, and PGP4) or 1.49 μg of DNA (PIN1 and PIN2) per well. The AUX1 amount transfected was 0.781 μg of DNA per well. For coexpression experiments, wells were transfected with 2 μg of PGP DNA and 1.49 μg of PIN DNA; the ratio of PGP to PIN DNA was empirically determined and found to be crucial for successful interaction.

For radiolabeled substrate accumulation assays, gradient conditions were developed wherein radiolabeled auxin was passively accumulated by empty vector control HeLa cells without induction of cellular damage. Confluent cells were transfected on six-well plates, and 16 to 24 h after transfection, cells were washed with 3 mL of prewarmed Dulbecco's modified Eagle's medium and 5% fetal bovine serum. Each transfection used 600,000 to 1,000,000 cells, and equal loading of wells was verified by sampled cell counts. Cells counts were determined by both Coulter counting and microscopic visualization (percentage confluence). Cells were then incubated with 2 mL of PBS citrate buffer, pH 5.5, and 5% calf serum containing either 10 or 62.5 nM of the following radiolabeled substrates: [³H]IAA (specific activity, 26 Ci/mmol; Amersham Biosciences), [³H]BA (specific activity, 20 Ci/mmol; American Rabiolabeled Chemicals), or [³H]1-NAA (specific activity, 20 Ci/mmol; American Radiolabeled Chemicals). Possibly as a result of buffer compatibility issues, it was difficult to maintain the solubilization of 1-NAA in loading assays.

For radiolabeled auxin degradation product assays, cells were loaded with 10 nM radiolabeled IAA breakdown products (specific activity, 25 Ci/mmol; American Radiolabeled Chemicals). Cells were incubated with radiolabeled substrate for 40 min at 37°C and 5% CO₂. For inhibitor studies, cells were incubated with radiolabeled IAA in the presence of 10 μM NPA. After incubation, cells were washed three times each with 3 mL of ice-cold PBS, removed from the wells by trypsinization, and added to 18 mL of scintillation fluid. Samples were counted in a Perkin-Elmer scintillation counter. Components of the radiolabeled auxin breakdown product mixture were determined and quantified via liquid chromatography–mass spectrometry. Fluorescent substrate accumulation assays were performed in the HeLa cell system as described previously (Hrycyna et al., 1998). Data points were normalized to the average empty control vector value of 2851.885 dpm/500,000 cells for auxin treatments. Cell viability after treatment was confirmed visually and via cell counting. Net efflux is expressed as dpm/500,000 cells: the amount of auxin retained by cells transfected with empty vector minus the amount of auxin retained by cells transfected with the gene of interest. Reductions in auxin retention (efflux) in transfected cells are presented as positive values, whereas increases of auxin retention are presented as negative values. In all cases, expression and localization of expressed Arabidopsis proteins were confirmed by RT-PCR (Peer et al., 2004) and protein gel blotting (Hrycyna et al., 1998) using standard protocols for the system. Substrate integrity was determined by organic phase partitioning and mass spectral analysis.

Immunolocalization in HeLa Cells

HeLa cells were transfected as described above. Sixteen hours after transfection, cells were harvested with a rubber policeman, spun down, and fixed in methanol at room temperature for 10 min. Cells were permeabilized with 0.05% Triton X-100 for 5 min, washed, and incubated with anti-HA antibody (Roche Applied Science) or anti-PIN1 antibody (from J. Friml) at 37°C for 2 h. After primary antibody incubation, cells were washed and incubated with secondary antibody, anti-rabbit Alexa Fluor 546 (Molecular Probes) or anti-mouse fluorescein isothiocyanate (Miles-Yeda), for 45 min. Cells were washed, harvested, and imaged via confocal microscopy using argon and helium-neon lasers. Bright-field images were captured on a spot RT-CCD camera (Diagnostics).

Yeast Auxin Transport Assays

PIN1 (At1g73590) was amplified by RT-PCR from total root RNA as described by Geisler et al. (2005) using the following primers: PIN1-RT, 5′-ATAGACCCAAGAGAATGTAGTAG-3′; PIN1-S, 5′-ACGCTGCAGATGATTACGGCGGCGGACTTC-3′; and PIN1-AS, 5′-ACGGTCGACTCACGGCGCGCCTAGACCCAAGAGAATGTAGTA-3′. PIN1 was inserted with PstI/SalI into pAD4M (Luschnig et al., 1998), resulting in pAD4M-PIN1, and the absence of PCR errors was verified by sequencing. Saccharomyces cerevisiae strain JK93da containing pNEV-PGP1 or empty vector pNEV (Geisler et al., 2005) were transformed with pAD4M-PIN1, pADE1-HA (Luschnig et al., 1998), or empty vector pAD4M, and single colonies were grown in synthetic minimal medium without uracil and Leu, supplemented with 2% (w/v) glucose. Auxin efflux experiments were performed as described recently (Geisler et al., 2005) with the following modifications. Cells were loaded for 15 min on ice with combinations of 1 μL/mL [5-³H]IAA (specific activity, 20 Ci/mmol; American Radiolabeled Chemicals) and [7-¹⁴C]BA (53 mCi/mmol; Moravek Biochemicals). All aliquots were filtered on Whatman GF/C filters and washed three times with cold water, and retained radioactivity was quantified by scintillation counting. All transport experiments were performed three to five times with independent transformants, with four replicas each. Cell viability after treatment was confirmed visually. Auxin efflux was calculated by subtracting vector control values (dpm); net auxin efflux is expressed as dpm/10⁻⁶ cells.

Accession Numbers

Sequence data from this article can be found in the GenBank/EMBL data libraries under the following accession numbers: PGP1 (At2g36910), PGP4 (At2g47000), PGP19 (At3g28860), PIN1 (At1g73590), PIN2 (At5g57090), and AUX1 (At5g01240).

Supplemental Data

The following materials are available in the online version of this article.

• Supplemental Figure 1. Summary of Auxin Transporter Localizations.

• Supplemental Figure 2. Control Protein Gel Blot Analyses.

• Supplemental Figure 3. Coimmunolocalization of PINs and PGPs on Plasma Membrane in HeLa cells, FACS Assays of HeLa Cells, Protein Gel Blot of PINs Expressed in Yeast, Cardio Green Inhibition of Auxin Transport, and BA Competition in HeLa Cells Expressing PIN2 or PGP19.