Abstract
Pollen tubes are highly polarized tip-growing cells that depend on cytosolic pH gradients for signaling and growth. Autoinhibited plasma membrane proton (H+) ATPases (AHAs) have been proposed to energize pollen tube growth and underlie cell polarity, however, mechanistic evidence for this is lacking. Here we report that the combined loss of AHA6, AHA8, and AHA9 in Arabidopsis thaliana delays pollen germination and causes pollen tube growth defects, leading to drastically reduced fertility. Pollen tubes of aha mutants had reduced extracellular proton (H+) and anion fluxes, reduced cytosolic pH, reduced tip-to-shank proton gradients, and defects in actin organization. Furthermore, mutant pollen tubes had less negative membrane potentials, substantiating a mechanistic role for AHAs in pollen tube growth through plasma membrane hyperpolarization. Our findings define AHAs as energy transducers that sustain the ionic circuit defining the spatial and temporal profiles of cytosolic pH, thereby controlling downstream pH-dependent mechanisms essential for pollen tube elongation, and thus plant fertility.
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Introduction
Flowering plants evolved a complex process to deliver sperm cells for double fertilization and seed formation. When pollen, the male gametophyte, lands on a receptive stigma of a flower, it germinates to produce a cell extension, the pollen tube, which carries non-motile sperm cells. Pollen tubes grow through the female sporophytic tissues and discharge the sperm cells into the female gametophyte, the embryo sac1,2.
Pollen tubes elongate by tip growth, a mechanism of cell elongation in which secretory vesicles fuse with the plasma membrane exclusively at the growing apex, that is common to root hairs, filamentous fungi, and developing neurites3,4. Pollen tubes evolved to be streamlined chemotropic growing cells. They possess dramatically polarized cytosolic ion gradients at the tip (H+, Ca2+, Cl−), which are believed to modulate the cellular processes and structures involved in tip growth, including the actin cytoskeleton5,6,7. Although cytosolic buffering mechanisms were thought to preclude the existence of cytosolic pH gradients3,8, pollen tubes were shown to have apical gradients with up to one pH unit ranging over 10–30 µm from the extreme tip of the pollen tube7,9,10,11. These gradients correlate spatially with a loop of extracellular H+ fluxes, in which the pollen tube tip sinks the net effluxes generated all over the tube shank, thus creating an apparent H+ short-circuit9.
The conspicuous H+ effluxes along the pollen tube shank have been attributed to plasma membrane H+-ATPases (AHAs for Autoinhibited H +-ATPases; ref. 11), since they constitute the main family of H+ export proteins in plants12,13,14. Molecular cell biology and pharmacology analyses support the hypothesis that AHAs indeed generate extracellular H+ fluxes and sustain the cytosolic H+/pH gradient in growing pollen tubes8,15,16,17,18,19. For instance, in tobacco (Nicotiana tabacum), the isoform NtAHA1 localizes to the pollen tube plasma membrane only in the shank (the entire length of the pollen tube behind the tip-most region), being actively excluded from the tip17, in close spatial association with the patterns of cytosolic pH, extracellular H+ flux, and actin remodeling (Fig. 1 in ref. 5). However, direct evidence linking AHAs with cellular functions was lacking due to its high degree of genetic redundancy and difficulties in manipulating pollen tube dynamics in non-model species.
Here, we show that the pollen-specific plasma membrane H+-ATPase isoforms AHA6, AHA8, and AHA9 from Arabidopsis thaliana are essential for pollen tube growth and fertility. Triple mutants of these pumps have strongly reduced fertility due to premature pollen tube arrest, and mutant pollen tubes showed reduced extracellular ion fluxes, reduced plasma membrane potential, disturbed spatiotemporal patterns of cytosolic pH and disrupted actin organization. We conclude that the AHAs energize a loop of H+ current around the tip, which is essential for pollen tube function.
Results and discussion
AHA6, AHA8, and AHA9 are plasma membrane proton ATPases
The A. thaliana genome encodes 11 presumably functional H+-ATPases (AHA1–11)18, of which the three isoforms AHA6, AHA8, and AHA9, the closest homologs of NtAHA1, are predominantly expressed in pollen and pollen tubes14,20,21 (Supplementary Fig. 1). Since genetic evidence for the involvement of plasma membrane H+-ATPases in pollen tube tip growth is lacking, we investigated the role of the three pumps encoded by these genes in pollen tube growth.
To confirm the expression of AHA6, AHA8, and AHA9 in the male gametophyte, we performed a β-glucuronidase (GUS) reporter-aided analysis of the AHA6, AHA8, and AHA9 promoter activities. Histochemical staining of GUS activity in AHA6 promoter pAHA6::GUS, pAHA8::GUS, and pAHA9::GUS transgenic lines revealed that all three promoters were active in pollen and pollen tubes (Fig. 1a, left). When the same promoters were used to drive expression of chimeras between AHA6, AHA8, and AHA9, and green fluorescent protein (GFP), fluorescence was evident at the pollen tube shank (Fig. 1a, right), whereas the three proteins were excluded from the apex of the pollen tubes (Fig. 1a, Supplementary Fig. 2b), closely resembling the distribution of NtAHA1 in tobacco16. AHA6 localized along the entire length of the pollen tube, whereas AHA8 was absent from shank regions further away from the tip, and AHA9 was present only at the shank close to the pollen germination pore (Fig. 1a, Supplementary Fig. 2b).
In the aha6/8 double mutant, AHA6::GFP fully complemented the loss of AHA6 (Supplementary Fig. 4a). AHA8::GFP partially rescued the aberrant phenotype (whereas AHA8 without GFP fully rescued it). AHA9::GFP fully rescued the aha6/9 phenotype of reduced seed setting (Supplementary Fig. 4a).
We confirmed the H+ pump activity of each of these proteins by heterologously expressing cDNA containing their coding region in the yeast strain RS-72, in which the native proton pump PMA1 is under the control of a galactose-inducible promoter22. This strain can only grow in the absence of galactose when a functional plasma membrane H+ pump is expressed. As a C-terminal autoinhibitory domain has been identified in plasma membrane H+-ATPases13,14, we also expressed gene versions that encode truncated pumps lacking 92 C-terminal amino acid residues. The autoinhibitory C-terminal domain of AHAs does not block the activity of the pump, but controls the degree of coupling between ATP hydrolysis and H+ pumping, i.e., the pumping efficiency23. Thus, the ability of full-length AHAs to complement S. cerevisiae pma1 depends on the size of the electrochemical H+ gradient the pumps are pumping against and, if growth is only reduced, the period of time of the growth assay. The truncated versions of all three pumps complemented pma1 even at an external pH of 3.5, confirming a H+-extrusion pump function (Fig. 1b). Expression of full-length cDNA did not complement growth, suggesting that the autoinhibitory domain strongly reduces proton pumping in the yeast system (Fig. 1b).
We then assayed the specific ATPase activity of the C-terminally truncated pumps as a function of pH. All three gametophyte-specific pumps had their maximum activities close to pH 6.5 (Fig. 1c). This is similar to the pH optimum of AHA2, an isoform strongly expressed in the vegetative parts of the plant (the sporophyte)24. Moreover, all pumps had overlapping Km values for ATP (Fig. 1d), suggesting that sporophyte and gametophyte H+-ATPases have similar pump properties.
aha6/8/9 pollen tubes have severe growth phenotypes
We investigated the roles of AHA6, AHA8, and AHA9 genetically by characterizing T-DNA insertion lines in A. thaliana (Fig. 2a). The aha6-1, aha8-1, aha8-3, aha9-4, and aha9-5 mutant plants were confirmed to have undetectable levels of the corresponding RNA transcript in mature flowers of homozygous T-DNA insertion lines (Fig. 2b, c). Of the single mutant plants, only aha6 showed mild phenotypes (Supplementary Table 1; Supplementary Fig. 3a–c).
Given that genetic redundancy is a well-established phenomenon in ion transporter families of pollen25,26, we crossed the individual lines to generate homozygous double and triple mutant plants. When self-fertilized, the three combinations of double mutants (aha6/8, aha6/9, and aha8/9) showed different degrees of early pollen tube growth arrest (Fig. 2d, e), reduced pollen tube elongation rates (Fig. 2e), and reduced fertility (Fig. 2f). aha6/8 pollen tubes grew at a similar rate as those of the wild-type but terminated growth much earlier, whereas aha6/9 pollen tubes germinated later and grew slower than those of the wild-type but grew almost as long. This suggests that AHA6 and AHA9 together function in pollen tube germination and in the early phases of tube elongation, whereas AHA6 and AHA8 together are important for sustained pollen tube growth. All reported phenotypes could be functionally complemented by transforming the absent AHA isoforms under their native promoters back into the mutant lines (Supplementary Fig. 4). Male transmission of the fertility defects was confirmed by reciprocal crosses between the WT and plants bearing aha alleles (Supplementary Table 2).
Aiming to further reduce the effects of redundancy in AHA function, we generated aha6, aha8, and aha9 triple mutants (Table 1). Pollen maturity and viability were confirmed with DAPI and Alexander stain, respectively (Supplementary Fig. 5). Pollen tube growth in planta was strongly affected, with only a few pollen tubes succeeding to grow through the stigma into the ovary, resulting in a reduction to about 3–10 seeds per plant (Fig. 2d–f). Likewise, in vitro germination of the triple mutant pollen was significantly reduced (Fig. 2g), with erratic or wavy pollen tubes forming that were significantly shorter than those of the wild-type (Fig. 2i).
Although aha6/8/9 exhibited premature pollen tube growth arrest, initial growth still occurred but at a reduced rate (Fig. 2h, Supplementary Fig. 6). A likely explanation is that one or more additional AHA isoforms is involved in pollen tube growth during the early growth phases. AHA7 is also expressed in pollen tubes22, but at a much lower level than AHA6, AHA8, and AHA9 (Supplementary Fig. 1). Loss of AHA7 led to a 30% reduction in seed set, but only when AHA6 and AHA9 were also lacking (Supplementary Fig. 7).
Even after genotyping >500 progeny of triple mutant plants that were pollinated with pollen from plants that were heterozygous for the fourth allele, aha6/7/8/9 quadruple mutants were not identifiable (Supplementary Fig. 7). This suggests that AHA7 functions redundantly with the other isoforms, and may weakly sustain pollen tube growth in the aha6/8/9 mutant. Another possible candidate is AHA3, which is expressed in microspores27. However, this possibility could not be studied, since AHA3 deletion mutants failed to produce pollen28. Together, our data suggest that AHA6, AHA7, AHA8, and AHA9 are needed for proper pollen tube germination and elongation and that these pumps function redundantly in the pollen tube.
Ion fluxes are reduced throughout aha6/8/9 pollen tubes
Having established the genetic basis of AHA function in pollen tube growth, we focused on its mechanistic basis in cell physiology. We used an extracellular ion-selective vibrating probe to measure H+ flux profiles along the pollen tube length, as these profiles can be taken as reporters of AHA activity17 (representative wild-type pollen tube in Fig. 3a). The growth rate reduction in all mutant combinations lacking AHA6 (Fig. 2e, h) was associated with reduced H+ influx at the tip (Fig. 3b), lower efflux at the shank, and a retraction of the influx/efflux reversal boundary towards the shank (Fig. 3c), with more dramatic effects in the triple mutant. Wild-type pollen tubes showed an inversion of net H+ influx at the tip to a net efflux at a distance of ca. 15–20 µm from the tip (Fig. 3c), while all mutant combinations lacking AHA6 have virtually no net efflux along the tube (Fig. 3c). Although aha8/9 shows an inversion point beyond 20 µm from the tip (Fig. 3c), the influx at the tip and efflux along the shank are comparable to those of the wild-type.
Large anionic fluxes were hypothesized to function in water movement, turgor, and elongation in growing pollen tubes29, with efflux at the apex and influx along the tube and a corresponding negative cytosolic concentration gradient at the tip30,31,32. Indeed, a striking reduction of anionic efflux was observed in the double and triple mutants lacking AHA6, while aha8/9 showed wild-type-like fluxes (Fig. 3d), in agreement with the growth phenotype observed in vivo and in vitro (Fig. 2e, h). Anionic efflux at the tip, which contributes to the largest electrical currents in growing lily (Lilium longiflorum) pollen tubes33, appears to respond to the electrochemical imbalance generated by AHAs at the shank, which would be expected to contribute to a net hyperpolarization of the plasma membrane32,34. Indeed, cationic influx at the tip can be elicited by hyperpolarizing pulses applied to the shank of lily pollen tubes32, supporting a link between tip fluxes and shank membrane potential.
A cytosolic gradient of H+ is reduced in aha6/8/9 tubes
Since mutants lacking AHA6 virtually lacked H+ efflux at the shank of the pollen tube, while retaining some, albeit a reduced, influx at the tip (Fig. 3b, c), we expected their pollen tubes to have a higher cytosolic H+ concentration and a smaller gradient between the tip and shank. We assessed cytosolic H+ concentrations by transforming all mutant lines with the ratiometric probe pHluorin, which was calibrated using the H+ ionophore nigericin and medium with pH 5.8–8.0 (Supplementary Fig. 8a). The pH gradients were estimated using a custom protocol35.
A. thaliana wild-type pollen tubes had a cytosolic [H+] gradient, with a higher pH in the shank than in the tip region, in agreement with the localization pattern of the H+-exporting AHA6, AHA8, and AHA9 pumps (Fig. 3a). Accordingly, a lower cytosolic pH was observed at the tip and shank in all mutant combinations lacking AHA6 than in the wild-type (Fig. 3e). In the apex, the pH of the aha6/8/9 pollen tubes was ca. 0.3 units lower than that of the wild-type (Fig. 3e, Supplementary Fig. 8b and exemplified in Fig. 4a). Even more pronounced differences were observed in the shank, where the pH of the mutant was ca. 0.5 units lower than that of the wild-type (Fig. 3e; Supplementary Fig. 8c; Fig. 4a). These changes in cytosolic pH translate into a shallower tip-to-shank pH gradient (Fig. 3f, detailed in Fig. 4a). The reduction in growth rate observed in AHA mutants is thus associated with the difference in pH and the gradient itself, suggesting a mechanistic relationship between growth and cytosolic pH. However, only the tip/shank gradient showed a significant correlation with average growth rate both across (Fig. 3g) and within the time series (Supplementary Fig. 9), while absolute pH at the tip did not (Supplementary Fig. 9).
Tip pH is considered to be involved in growth regulation, since H+ influx into the tip, but not the shank, can change the directionality of pollen tube growth as previously shown in tobacco. Application of the cation ionophore gramicidin A to the apex, where NtAHA1 is absent, resulted in cytosol acidification concomitant with reorientation of pollen tube growth, but had no effect when applied to the shank, where NtAHA1 is present17. Similarly, growing lily pollen tubes subjected to an altered pH regime at the tip induced by water electrolysis on an active electrode either bent away from the electrode, stopped growing, or bursted36. Ion gradients have been implicated in multiple roles directly related to growth regulation, such as orienting actin polymerization and consequently cytoplasmic streaming, and vesicle/organellar dynamics34. Oriented vesicle movement has been hypothesized to occur spontaneously in pollen tubes by three basic mechanisms: (i) up a concentration gradient, (ii) towards the most depolarized plasma membrane domains, or (iii) along with osmotically driven fluid motion34. Changes in gradient steepness are expected to affect all such processes, thus possibly accounting for the reduction in average growth rate found in mutants lacking AHA6. These results indicate that AHAs are key regulators of the mean level and gradient of cytosolic H+ concentration.
Mutant tubes have a lower frequency of H+ oscillations
When cytosolic pH was quantified as a function of time using CHUKNORRIS37, we observed pronounced pH oscillations in all genotypes (Fig. 4b, c, Supplementary Fig. 10). The aha6/8/9 triple mutant showed the largest difference from the wild-type, with an increased period of synchronized oscillations between the growth rate and H+ cytosolic concentration [H+]cyt (Fig. 4d). The triple mutant is also more irregular in terms of variability in oscillation period between different pollen tubes (Supplementary Fig. 11a, b), changes in phase relationship (Fig. 4e), and highly variable delays between growth and [H+]cyt (Supplementary Fig. 11c).
All genotypes showed complex synchronized oscillations between [H+]cyt and growth rate, with multiple frequencies co-existing in the same sequence, but with drastic changes in period over time (Supplementary Fig. 10), although with no overall difference in amplitude (Supplementary Fig. 11d). Slower oscillations could contribute to the drastically premature growth arrest of AHA6 mutants (Fig. 2d, e), presumably through critical effects on time-sensitive processes such as actin polymerization and cell wall rigidity7. AHAs could affect tip oscillations through the electrochemical imbalance generated in the shank plasma membrane, leading to hyperpolarization in the shank and a more depolarized tip6,32,34, or via pH/voltage sensitive channels localized throughout the pollen tube, such as the recently characterized H+/Cl– co-transporter TMEM1638.
Turgor pressure is not altered in mutant pollen tubes
After having identified spatio-temporal changes in intracellular pH and extracellular ion fluxes in AHA mutants, we investigated its possible effect on the mechanism underlying the observed defect in pollen tube growth. The plasma membrane H+-ATPase has been proposed to be the powerhouse driving pollen tube growth13,14. Plasma membrane H+-ATPases energize the plasma membrane and drive the uptake of solutes through H+-coupled co-transporters and channel proteins, followed by the uptake of water, which results in an increase in turgor pressure. The reduced ion fluxes in the mutant pollen tubes could thus lead to a decrease in turgor pressure, which could underlie the observed elongation defects. To test this hypothesis, we estimated turgor in growing pollen tubes using the incipient plasmolysis technique39,40. Despite severe tube growth phenotypes in aha6/8/9 (Fig. 2e, i), turgor pressure in wild-type and mutant pollen tubes was not significantly different, with an average of ~0.2 MPa (Fig. 5a), which is in agreement with the results of previous studies38,39.
The lack of correlation between internal turgor pressure and growth rate of pollen tubes39 (reviewed in refs. 40,41) contradicts the assumption that turgor is modulated during oscillatory growth42,43. Our results support a tip growth model, which is not dependent on increased turgor pressure, and suggest that the combined fluxes of the opposing circuits of cations and anions at the tip and shank balance each other out, so that there is no net build-up of osmotically relevant ionic concentrations34.
Actin cytoskeleton organization at the tip is compromised
We then investigated the actin cytoskeleton as a possible target of the pH alterations that could explain the aberrant growth of aha6/8/9 pollen tubes (Fig. 2i). Actin is essential for pollen tube growth and is organized in bundles along the shank of the tube, ending in a basket- or cortical fringe-like structure in the sub-apical region (~12–20 µm from the tip in lily, likely ~3–6 µm in Arabidopsis) and as a meshwork of very short, highly dynamic thin microfilaments in the apical dome44,45. The sub-apical structures are fundamental for tip growth. Actin bundles along the shank end at this location where they are reorganized to sustain the inverted-fountain streaming pattern, with cortical motion towards the tip, and central motion towards the grain. The molecular mechanisms underlying this actin remodeling mechanism and, fundamentally, its spatial definition, remain poorly understood. Yet, pH is an established regulator of the ADF/cofilin family of actin remodeling proteins46,47,48, which drives the turnover and depolymerization of entangled F-actin49 and has been shown to function in actin organization in pollen tubes44,50.
We thus explored the role of pH in regulating actin turnover in pollen tubes, by staining actin with Alexa 488 phalloidin51,52. In addition to lacking a sub-apical actin fringe, the volume of the apical 5 µm of aha6/8/9 mutant pollen tubes was devoid of actin (Fig. 5b). Given the alterations in cytosolic pH and the tip-focused H+ gradient in the absence of AHAs, the changes in actin distribution are likely caused by differences in the threshold of this tip-focused gradient. This interpretation is further in accordance with the cytosol acidification-induced disruption of actin filament organization in lily pollen tubes44.
On the other hand, cytosol alkalinization promoted by plasma membrane H+-ATPase was proposed to stimulate ADF, leading to depolymerization of F-actin and more plus ends, which then stimulate actin filament polymerization and, eventually, growth44. Interestingly, aha6/8/9 phenocopies mutants in actin turnover factors that also display disrupted apical actin fringes and wavy growth, such as adf10 (normally present throughout the tube)53, CAP1 (which acts in synergy with the ADF/cofilin family)54,55,56, and A. thaliana formin homology3 (AtFH3) and AtFH557. A shallower pH gradient (Fig. 3e, f) could also impact the orientation of actin fibers, since a gradient in pH should result in a gradient of ADF activity, which is pH dependent46,47,48 and hence could spatially define domains of re-organization and de novo polymerization.
Together, these results suggest that the abnormal growth and erratic shape (Fig. 2i) of AHA mutant pollen tubes are caused by a defect in actin turnover at the pollen tube tip (Fig. 5b), induced by reductions in cytosolic pH, pH gradient, and frequency of H+ oscillations (Fig. 4 and Supplementary Fig. 11).
Membrane potentials are less hyperpolarized in aha mutants
AHAs are electrogenic pumps that establish a pH gradient across the membrane by pumping H+ out of the cell, thus hyperpolarizing the cell to more negative values of membrane potential. For quantitative comparisons of the membrane potentials in wild-type and mutant pollen tubes, we took advantage of ANNINE-6 plus (Fig. 5d), which is a voltage-sensitive fast-response dye that has been used for sensitive optical recording of neuronal excitation58. Although methodological proof-of-principle demonstrations have been published59,60, this dye has not been used for plant cell phenotyping. We focused on the sub-apical zone (10–20 µm distal from the tip, where AHA labeling fades away) and the AHA-stabilized shank (40–50 µm from the tip) (Supplementary Fig.12 a–e). From this analysis, it was evident that the aha6/8/9 mutants had less hyperpolarized membrane potentials than the wild-type, (<50% fluorescence) (Fig. 6d). The wild-type membrane potential has previously been determined to be at –127 mV61. As the linearity of the ANNINE6-plus response at such negative values has not been determined, one cannot extrapolate exact values for the mutant, but given the linearity of the dye response over 120 mV (reviewed in ref. 58), values more positive than –70 mV should be expected for the triple mutant. We further confirmed this result using the oxonol dye DiBAC4(3), a slow-response voltage-sensitive dye that enters depolarized cells and is excluded from hyperpolarized cells62. We have assayed DiBAC4(3) under normal conditions and after wortmannin treatment to prevent possible endocytosis artifacts on dye uptake. Under all conditions, the aha6/8/9 triple mutant had an increased degree of DiBAC4(3) uptake compared to the WT, which is indicative of a less negative potential (Supplementary Fig. 12f).
The quantitative accuracy of ANNINE-6 and the confirmation of its main conclusion using DiBAC4(3) provide compelling evidence that pollen tubes of AHA mutants, which are impaired in growth and fertility, have less hyperpolarized membrane potentials, thus substantiating a mechanistic role for AHAs in pollen tube growth through plasma membrane energization.
This work provides the first genetic evidence that plasma membrane H+-ATPases energize the plasma membrane and control dynamic H+ fluxes in growing pollen tubes and are required for apical elongation of pollen tubes and hence successful fertilization. Furthermore, these proton pumps underlie the spatiotemporal control of the pH homeostasis set point, establishing a more acidic apex than shank region and a pattern of proton oscillations that is synchronized with pollen tube growth. We propose that the spatial distribution of plasma membrane H+-ATPases, which are present only at the tube shank, mediates the formation of a [H+]cyt gradient that directs actin bundling near the growing tip, and generates a proton motive force that drives the anion efflux and H+ influx at the tip, producing an oscillatory ion circuit that coordinates pollen tube growth (Fig. 6). Local ionic fluxes precede pattern formation and polarized growth in a diverse array of tip-growing cells such as algal zygotes, fungal hyphae, and growing neurons (reviewed in ref. 33), such that depolarization of the tip may be a pre-condition to sense external stimuli5. Indeed, ion gradients have been reported in virtually all biological models for polar growth63, while H+ has long been proposed as a crucial signal for pollen tube growth in particular64,65. Our results are in line with such models, supporting the notion that AHAs have multiple effects on tip growth. Furthermore, the approach presented here might help elucidate the mechanisms driving growth in other types of tip-growing cells.
Methods
Plant materials and growth conditions
Arabidopsis thaliana ecotype Columbia (Col-0) was used as the wild-type plant. T-DNA insertion lines were obtained from the Nottingham Arabidopsis Stock Centre. Seeds were sown on soil and vernalized in darkness at 4 °C for 2 days before being transferred to climate chambers maintained at 22 °C with 70% humidity and a 16-h-light/8-h-dark cycle (100 μmol.m−2.s−1). For ion flux measurements, plants were grown at 22 °C with 70% humidity and a 12 h light/12 h dark cycle (100 μmol m−2 s−1).
Characterization of T-DNA insertion mutants
Genomic DNA was used to identify heterozygous and homozygous lines by PCR. Gene-specific primers together with specific T-DNA left border primers (Supplementary Table 3) were used to genotype T-DNA insertion lines. All T-DNA insertion lines were verified by sequencing. AHA9 transcript levels in Col-0 and the respective mutants. Total RNA was extracted from flowers (10 flowers per sample; at flower stage 1266) using a Plant RNeasy Kit (Qiagen) according to the manufacturer’s instructions. To synthesize cDNA, 1 mg RNA was reverse transcribed using the iScript cDNA Synthesis Kit (BioRad), according to the manufacturer’s instructions. RT-PCR was performed using 5 ng cDNA (or 1 ng gDNA extracted from a Col-0 plant) as template and cDNA-specific primer pairs (Supplementary Table 3) were used to determine the levels of full-length and partial transcripts. PP2AA3 (At1g13320) was amplified as a positive control for RT-PCR analysis67 (Supplementary Table 3).
The aha9-1 allele had a pleiotropic phenotype for heterozygous, but not homozygous, plants, probably due to chromosomal rearrangements68, and was thus not further characterized.
Segregation analysis
Plants heterozygous for a T-DNA insertion allele were allowed to self-fertilize and the resulting seeds were sown on soil in 96-cell plug trays. Genomic DNA was extracted from leaves as described below and the alleles in question were amplified by PCR using sets of optimized primer pairs (Supplementary Table 3). For reciprocal crosses, unopened flowers of plants heterozygous for a T-DNA insertion were emasculated and stigmas were hand pollinated with WT pollen. Flowers of ms1 plants were pollinated with plants heterozygous for a T-DNA insertion. Developed seeds were collected from these siliques and sown on soil in 96-cell plug trays, and the genotypes were determined as described above.
DNA extraction
DNA was extracted in 96-well format. Leaves of young plants were collected in tubes each containing a 3 mm steel ball (Dansk Kugleleje Center). Samples were frozen in liquid nitrogen and homogenized using a Retsch Tissue Lyser (QIAGEN). Then, 280 µl Edward’s solution (200 mM Tris-HCl [pH 7.5], 250 mM NaCl, 25 mM EDTA, and 0.5% (w/v) sodium dodecyl sulfate)69 was added to each sample and the 96-well plates were centrifuged for 15 min at 5900 rcf at room temperature. Then, 125 µl buffer was transferred to fresh 96-well plates containing 125 µl 2-propanol and mixed by pipetting. Plates were centrifuged for 15 min at 5900 rcf. The supernatant was pipetted off and discarded, 300 µl 70% (v/v) ethanol was added to the pellet without resuspending it, and the samples were centrifuged for 5 min at 5900 rcf and room temperature to wash the pellets. The ethanol was removed and the samples were left to dry overnight at room temperature. The DNA was resuspended in 300 µl deionized water and the samples were maintained at room temperature for at least 3 h. DNA samples were diluted 10-fold in deionized water and for genotyping purposes 5 µl DNA was used per 20-µl PCR reaction.
Construction of the promoter::gene::GFP fusions
To construct the pAHA6::AHA6::GFP, pAHA8::AHA8::GFP, and pAHA9::AHA9::GFP expression plasmids, genomic A. thaliana Col-0 DNA was amplified by Phusion High-Fidelity DNA-polymerase (NEB) using primer pairs that included the region 1747 (AHA6), 673 (AHA8), or 762 (AHA9) bp upstream of the start codon and the entire gene except for the stop codon (Supplementary Table 3). The resulting PCR products were cloned into pENTR/D-TOPO vectors (Invitrogen) by TOPO cloning, according to the manufacturer’s instructions, and the inserts were fully sequenced. Using LR recombinase (Invitrogen), the inserts were subsequently transferred into the pMDC107 destination vector, such that the C-termini of the inserts were fused in-frame to EGFP70. The resulting expression vectors were then introduced into Col-0 and the aha6/8 and aha6/9 double mutant lines.
Construction of the pAHA8∷AHA8 construct
To construct the pAHA8::AHA8 expression plasmid, genomic A. thaliana Col-0 DNA was amplified by Phusion High-Fidelity DNA-Polymerase (NEB) using the same forward primer as used for cloning the GFP construct, and reverse primer including the stop codon (Supplementary Table 3). The resulting PCR product was cloned into pENTR/D-TOPO vectors (Invitrogen) by TOPO cloning, according to the manufacturer’s instructions, and the inserts were fully sequenced. Using LR recombinase (Invitrogen), the inserts were subsequently transferred into the pMDC99 destination vector70. The resulting expression vector was then introduced into the aha6/8 double mutant line.
Construction of the promoter∷GUS constructs
To construct the pAHA6::GUS, pAHA8::GUS, and pAHA9::GUS expression plasmids, genomic A. thaliana Col-0 DNA was amplified by Phusion high-fidelity DNA-polymerase (NEB) using the same forward primer as used for cloning the GFP constructs, and reverse primers complementary to sequences in the second exon of the respective gene (Supplementary Table 3). The resulting PCR products were cloned into pENTR/D-TOPO vectors (Invitrogen) by TOPO cloning, according to the manufacturer’s instructions, and the inserts were fully sequenced. Using LR recombinase (Invitrogen), the inserts were subsequently transferred into the pMDC162 destination vector70.
Construction of pLat52::pHluorin constructs
Ratiometric pHluorin is a pH-sensitive GFP variant71,72, which carries a cryptic intron72, leading to aberrant mRNA processing and the absence of protein expression. Silent mutations were introduced into the pHluorin coding sequence, using a primer pair (Supplementary Table 3), to eliminate the cryptic intron sequence and restore pHluorin expression in A. thaliana. The resulting amino acid sequence is 100% identical to the original pHluorin. The aha9-4 line is resistant to kanamycin, most likely due to a kanamycin resistant marker being associated with the T-DNA inserted into AHA9. Therefore, the pLat52::pHluorin sequence was shuttled into pMDC9970, which in plants is selected for by hygromycin B. Briefly, pLat52::pHluorin plasmid and pMDC99 were mixed and digested using XbaI and HindIII (NEB), effectively excising pLat52::pHluorin and the Gateway Cassette. The digestion product was ligated with T4 DNA ligase (NEB) and transformed into Escherichia coli strain TOP10. Positive clones containing the resulting pMP5249 vector were selected on LB plates supplemented with 50 mg ml–1 kanamycin (Supplementary Fig. 13 for vector map).
Construction of the pK1.1 R CRISPR/Cas9 constructs
As aha6/8/9 produced too few seeds to allow transformation with the pLat52::pHluorin construct, the aha6/8/9::pHluorin line was produced using CRISPR. CRISPR/Cas9-mediated gene knockout of AHA6 or AHA8 in the aha6/9::pHluorin or aha8/9::pHluorin lines was done using the pKAMA-ITACHI vector pKI1.1 R (Addgene)73. sgDNA was designed to target the first exon of either AHA6 or AHA8 using CRISPOR74 and CRISPR-P 2.075. Primers for cloning were designed to include the sgDNA sequence and the AarI restriction digestion site (Supplemental Table 3). Primers were annealed using T4 polynucleotide kinase (NEB) and the pKI1.1 R vector was digested using AarI (Thermo Scientific) before being dephosphorylated using Shrimp Alkaline Phosphatase (rSAP, NEB). Vector and hybridized primers were ligated using the T4 ligase (NEB), transformed into E. coli and selected on LB plates supplemented with 100 mg/L spectinomycin. Plants were transformed as described below. Transformants showing red fluorescence in the seed due to TagRFP were selected using a Leica FM Stereo Microscope M205 FA with a DsRED Filter (excitation, 546/10 nm; emission, 600/40 nm). The aha6/8/9 triple knockout plants were selected based on their strongly reduced seed setting phenotype.
Plant transformation
Plasmids were transformed by electroporation into Agrobacterium tumefaciens strain GV3101::pMP9076 and transformants were selected on YEP plates (1% [w/v] yeast extract, 1% [w/v] bacto peptone, 0.5% [w/v] NaCl, 1.5% [w/v] bacto agar) containing 50 mg ml–1 kanamycin and 25 mg ml–1 gentamycin. Destination vectors extracted from A. tumefaciens single colonies were sequenced to verify the inserts. A. thaliana plants were transformed with A. tumefaciens (strain GV3101::pMP90) containing the desired vectors. For plant transformation, a modification of the floral-dip method was used77. Briefly, A. tumefaciens cells were grown on three plates containing YEP, 50 mg ml–1 kanamycin, and 25 mg ml–1 gentamycin for 48 h. Cells were then resuspended in 150 ml infiltration solution containing 5% (w/v) sucrose and 0.03% (v/v) Silwet L-77 (Lehle seeds). Inflorescences of newly bolted A. thaliana plants were dipped in the infiltration solution for 30 s and subsequently covered with a plastic bag overnight. This was repeated three times, allowing the plants to recover for 5–7 days between infiltration treatments.
Selection of transformed plants
Seeds of infiltrated plants were surface sterilized by washing in 70% (v/v) ethanol for 10 min, bleach solution with 0.05% (v/v) Tween-20 for 5 min, and 70% (v/v) ethanol for 5 min, and then rinsing three times in milliQ water. Seeds were plated on ½ strength Murashige-Skoog (MS) medium78 supplemented with 1% (w/v) sucrose and 50 mg ml–1 hygromycin B. The plates were stored at 4 °C for 48 h in darkness, and then transferred to growth chambers at 20 °C with a 16-h light period. After 2 weeks, seedlings showing resistance to hygromycin B were transferred to soil and tested by PCR for the presence of the correct insert.
Isolation of pollen
Unless stated otherwise, pollen grains were isolated in the morning from newly opened flowers. For this, flowers occupying a volume of about 500 µl were collected in a microcentrifuge tube and 700 µl pollen germination medium (5 mM CaCl2, 5 mM KCl, 1 mM MgSO4, 0.01% [w/v] H3BO3, 15% [w/v] sucrose, pH 7.5) was added to each tube. The samples were vortexed for 2 min, and the pollen pelleted by centrifugation at 11,200g for 2 min. Flowers and medium were removed and pollen were resuspended in fresh pollen germination medium.
GUS staining and analysis
To determine the tissue-specific expression of AHA6, AHA8, and AHA9, plants for each GUS-expressing line were selected and inflorescences were stained for GUS activity. Samples were vacuum infiltrated for 5 min with 5-bromo-4-chloro-3-indolyl β-D-glucuronic acid (X-glca; Duchefa) solution (3 mM K3(Fe(CN)6), 3 mM K4(Fe(CN)6), 0.4% [w/v] Tween-20, 50 mM KH2PO4/K2HPO4, pH 7.2, 2 mM X-glca) and incubated in the solution at 37 °C in darkness for 6 h (inflorescences). Pollen were incubated for 3 h at 22 °C before staining for GUS activity at 22 °C for 20 h. After incubation, inflorescences were cleared in 70% (v/v) ethanol overnight. Pollen were imaged directly. Stained samples were observed with a Leica DMR HC light microscope (pollen) and a Canon ELPH100HS camera (inflorescences).
Subcellular localization studies
The subcellular localization of AHA6, AHA8, and AHA9 tagged with EGFP in mature pollen and pollen tubes from the A. thaliana complementation lines was determined by confocal microscopy. Images were obtained with a Leica SP5, using a 40× oil immersion objective (NA 1.0; Leica). EGFP was excited with the 488-nm line of an argon laser and emission recorded from 495 to 550 nm. Optical sections were captured, and images were prepared by generating max-intensity projections (using ImageJ) of the optical sections through an individual pollen grain or pollen tube. Autofluorescence (monitored in wild-type mature pollen and pollen tubes) was negligible relative to EGFP fluorescence.
Full-length and C-terminally truncated cDNA constructs
Total RNA was extracted from A. thaliana Col-0 seedlings using an RNeasy Plant Mini Kit (Qiagen) and RNA was reverse transcribed using the iScript cDNA Synthesis Kit (BioRad) according to the manufacturers’ instructions. The PCR products of full-length coding sequences and C-terminally truncated sequences (see Supplemental Table 3 for primer sequences) were cloned into the pENTR/D-TOPO vectors (Invitrogen) by TOPO cloning, according to the manufacturer’s instructions, and the inserts were fully sequenced. Using LR recombinase (Invitrogen), the inserts were subsequently transferred into the destination vector pMP4409. pMP4409 was generated by cutting pMP625 containing the promoter and terminator of PMA1 (yeast endogenous plasma membrane H+-ATPase79) with XhoI and SpeI, removing AHA2, and inserting the gene into Gateway Cassette A (Invitrogen); the correct orientation of the Gateway Cassette A was verified by sequencing.
Yeast complementation assays
AHA6, AHA8, and AHA9 expression clones were transformed into Saccharomyces cerevisiae strain RS-72 (Mat a; ade1-100 his4-519 leu2-3 leu112 pPMA1-pGAL1) to be used for complementation tests80. In RS-72 the natural constitutive promoter of the endogenous yeast plasma membrane H+-ATPase PMA1 is replaced by the galactose-dependent promoter of GAL1.Since PMA1 is essential for yeast growth, RS-72 grows only on galactose medium. Using this strain, plasmid-borne plant H+-ATPases brought under control of the constitutive PMA1 promoter can be tested for their ability to rescue pma1 mutants on glucose medium. Yeast was grown for 3 days at 30 °C in liquid medium containing 2% galactose. Each complementation experiment was replicated independently three times. In drop tests, cells were diluted in sterile water and 5 μl was spotted on selective media. Growth was recorded after incubation for 3 days at 30 °C.
Protein expression, purification, and characterization
Microsomes harboring recombinant plasma membrane H+-ATPase were isolated from transformed yeast cells81. In brief, plasmids harboring the truncated AHA6, AHA8 and AHA9 was transformed into the RS-72 strain and transformed yeast strains were grown on minimal media w/o leucine. Positive clones were grown for two days in minimal medium with 2% galactose. Cells were transferred to YPD media for 20 h and harvested by centrifugation at 4.000g for 10 min. The cell pellets were washed with cold MilliQ water twice and resuspended in a buffer containing 20% glycerol, 50 mM MES/KOH (pH 6.5), 10 mM EDTA, 1 mM dithiothreitol (DTT) and 0.4 mM phenylmethylsulfonyl fluoride. Cells were lysed by vortexing with glass beads (0.5 mm in diameter) 5 times 1 min. The cell debris was removed by centrifugation at 10.000g for 15 min followed by an ultra-centrifuge spin at 200.000g for 1 h to pellet the total membranes. The membrane pellet was washed with a buffer containing 20% glycerol, 50 mM MES/KOH (pH 6.5), 1 mM EDTA, 1 mM DTT and 0.4 mM phenylmethylsulfonyl fluoride, centrifuged again and homogenized in the same buffer. The protein concentration was determined using the Bradford reagent and bovine serum albumin as standard. The resuspended membrane fractions were either assayed directly or flash frozen in liquid nitrogen and stored at −80 °C until use. The ATPase activity was determined by assaying the liberation of phosphate according to the Baginski assay82 in microtiter plates with a total volume of 60 μL in a buffer containing 50 mM MOPS/MES, 8 mM MgSO4, 5 mM NaN3, 0.25 mM NaMoO4, 25 mM KNO3, 2 mM phosphoenolpyruvate, and 30 μg/mL pyruvate kinase from rabbit muscle (Sigma-Aldrich). The assay buffers were equilibrated to 30 °C, and the assays were started by adding ATP and 150 ng isolated microsomes. The ATPase activity was measured in a pH range 5.4–8.1 and with 3 mM ATP to determine the pH optima. For kinetic characterization of the ATPase activity, the pH was constant at 6.5 and 12 ATP concentrations were tested in the range 0–3 mM. All experiments were performed in triplicate with ± SE.
Aniline blue staining
Pollen tubes in pistils were stained with Aniline blue83. Briefly, unpollinated ms1 pistils (NASC ID: N75)84,85 were pollinated either with wild-type or mutant pollen. After the indicated period, flowers with pollinated pistils were collected, vacuum infiltrated with fixing solution containing ethanol:acetic acid (3:1, v/v), and incubated overnight at room temperature. The fixed flowers were rehydrated stepwise (10 min each) with 70%, 50%, and 30% ethanol, and finally milliQ water, followed by incubation in softening solution (8 M NaOH) overnight. The softening solution was removed, and pistils were stained in 2 mL aniline blue solution (0.05% (w/v) aniline blue in 0.1 M PSB buffer, pH 9) with 2% (v/v) glycerol overnight in the absence of light and at room temperature.
Pollen tubes inside pistils were observed using a Leica DMR HC fluorescence light microscope with a ×5 objective and filter cube A (excitation filter BP 340/380, beam splitter at 400 nm, emission filter LP 425) (Leica Microsystems). Pollen tube lengths were measured using ImageJ software (https://imagej.nih.gov/ij/).
DAPI stain for pollen development
Ten newly opened flowers were collected in a microcentrifuge tube and 750 µL pollen isolation buffer (PIB) (100 mM NaPO4, pH 7.5, 1 mM EDTA, 0.1% [v/v] Triton X-100) was added86. Samples were vortexed for 1 min and centrifuged for 30 s at 1,500 rcf and room temperature. Flowers and supernatant were carefully removed. Pollen were resuspended in 50 µL of 2.5 µg/ml DAPI (4’,6-diamidino-2-phenylindole) stain in PIB buffer and incubated at room temperature for 15 min. Images were acquired with a Leica SP5-X confocal microscope (×63 water objective; NA 1.2; 355 nm excitation; emission recorded between 419 and 500 nm).
Alexander stain for pollen viability
About 20 newly opened flowers were collected in a microcentrifuge tube and 1 mL of simplified Alexander stain87 was added. Samples were vortexed for 2 min to release pollen, and then centrifuged for 2 min at 12,000 rcf and room temperature. Flowers and supernatant were carefully removed. Pollen were resuspended in residual supernatant and assayed with a Leica DMR HC light microscope.
Seed setting assays
The fertility of wild-type, mutant, and complemented plants was evaluated by counting the number of seeds in mature siliques produced on the main stem. Siliques were cleared in 70% (v/v) ethanol and images of cleared siliques were captured with a Leica DM5000B light microscope using a ×1.25 objective.
Extracellular proton and anionic flux measurements
An ion-selective vibrating probe (VP) was used to estimate extracellular anionic and proton fluxes at the tip and shank of pollen tubes germinated in vitro17,30. For that, wild-type and mutant pollen grains were collected from fresh flowers grown under short-day conditions and then germinated in liquid medium containing 500 μM KCl, 500 μM CaCl2, 125 μM MgSO4, 0.005% (w/v) H3BO3, 125 μM HEPES, and 16% (w/v) sucrose at pH 7.588. Pollen grains were incubated at 21.5 °C for at least 3 h and then growing pollen tubes with a length of ≥150 μm were measured. To build the ion specific electrodes, we used the Hydrogen Ionophore Cocktail B (number 95293 Sigma) for proton fluxes measurements, and the Cl−-selective liquid exchange cocktail (number 24899 Sigma) to measure anionic fluxes. As the chloride ionophore detected other anions in addition to Cl–, the estimates were referred to anionic fluxes and not chloride fluxes. All measurements were obtained as close as possible to the plasma membrane without touching the pollen tube. Fluxes were calculated using Fick’s law and Cl− (−2.03 × 10−5 cm−2 s−1) and proton (9.37 × 10−5 cm−2 s−1) diffusion coefficient in aqueous solution at 25 °C. Simultaneous widefield imaging of pollen tubes was performed on a custom-made device using an inverted Nikon Eclipse TE300 equipped with an Andor iXon3 camera on the bottom Kohler port, and a Lumen 200Pro Fluorescence Illumination System (Prior Scientific).
Ratiometric [H+]cyt imaging and pHluorin calibration
Transgenic wild-type pollen tubes expressing the modified ratiometric pHluorin driven by the LAT52 promoter89 were imaged every 4 s on an Applied Precision Deltavision Core system, mounted on an Olympus inverted microscope, equipped with a front-illuminated sCMOS camera (2560 × 2160, pixel size 6.45 μm), and an InsightSSI fluorescence illuminator, using a ×63 1.2NA water immersion objective. Filter sets were as follows: excitation 390/18 nm (DAPI) and 475/28 nm (FITC); emission 435/48 nm (DAPI) and 523/36 nm (FITC). To assess cytosolic pH in pollen tubes, ratiometric pHluorin was calibrated using 140 mM KCl, 30 µM nigericin (Tocris Bioscience), and 10 mM sodium phosphate with molar ratios of mono- and dibasic forms appropriate for the given pH (5.8–8.0). Ratiometric images of wild-type and mutant pollen tubes were obtained with the same acquisition protocol, and the calibration curve fitted with linear regression was applied to estimate the intracellular pH in all lines analyzed. Kymographs were generated from time-lapse images using ImageJ (Multiple Kymograph plugin) averaging over a 7-pixel neighborhood along a manual trace through the pollen tube midline for both DAPI and FITC channels.
Time series and gradient analysis
The CHUKNORRIS algorithm was used to analyze and extract oscillatory parameters from ratiometric kymographs36. CHUKNORRIS detects the pollen tube tip with subpixel resolution in each time point of the kymographs by fitting a linear model to the fluorescence decay of the cytosolic fluorescence signal towards the background. Tip detection allows aligning kymographs by the apex and extracting growth and fluorescence time series throughout the tube. Each time series is detrended and smoothed using a discrete wavelet transform, which separates changes in baseline (trend) and noise from the periodic signal that is then further analyzed. Wavelet transforms are used to provide time-explicit estimates of period and amplitude for individual series, additionally with phase relationships and delays for pairs. Synchronization oscillations between tip pH and growth rate oscillations were compared across genotypes using averages of the significant periodic components detected with a cross-wavelet transform for each pair of series. Although periods are often distributed in multiples modes, extracting only the main mode yielded similar results. Gradients throughout the pollen tube were analyzed by averaging a tip-aligned kymograph with a local polynomial fit (loess) across all time points within the same growth regime (protocol detailed in ref. 34).
Turgor pressure measurement
The turgor pressure of pollen tubes was measured using the incipient plasmolysis method39. Pollen tubes were germinated for 3 h in liquid pollen germination medium in glass bottom dishes. After the germination period, 60 μl of growth medium was collected for osmolality measurement (denoting πe). Pollen tubes were observed under an inverted bright-field microscope (Leica inverted DMI4000B), and one growing pollen tube was selected for analysis. Liquid pollen germination medium with 10% (w/v) sucrose and 10% (w/v) mannitol was added to the growth medium until the plasma membrane retracted from the cell wall of the tube tip (πi). An aliquot of 60 μl of the solution was collected for osmolality measurement denoting πi. The osmolality was measured using an osmometer (Gonotec). Turgor pressure is given by πi − πe and the measured values in osmol*kg–1 were converted to MPa at 25 °C.
Alexa 488 phalloidin actin staining
Pollen tubes were germinated and grown on solid pollen growth medium for 5 h at 23 °C. For actin staining51,90, the pollen tubes were fixed in fixation buffer (300 µM 3-maleimidobenzoic acid N-hydroxysuccinimide ester in liquid pollen germination medium) for 1 h. After fixation, pollen tubes were washed three times in wash buffer (50 mM Tris-HCl, pH7.4, 200 mM NaCl, 14% [w/v] sucrose, 0.05% [w/v] Nonidet P-40) for 10 min and reacted with 200 nM Alexa 488 phalloidin in wash buffer supplemented with 1% (w/v) bovine serum albumen (BSA) overnight in darkness at 4 °C. The stained pollen tubes were washed twice for 10 min with wash buffer and actin was observed using a confocal laser scanning microscope (Leica; TCS SP5) equipped with a ×100 oil objective (1.4-numerical aperture HC PLAN).
Actin imaging and analysis
The images of actin in pollen tubes were captured using a Leica TCS SP5 confocal laser scanning microscope with a ×100 oil objective (1.4 numerical aperture HC PLAN). Fluorescence of Alexa 488 phalloidin was excited with a 488-nm argon laser and the emission wavelength was set at 500–545 nm. Pollen tube images were generated by stacking all optical sections at a z-step size of 0.5 µm and analyzed using the LAS AF Lite software (Leica; Version 2.6.0). To measure the distance from the tip of the pollen tube to the start of the dense sub-apical actin fringe, five individual lines were drawn parallel to the pollen tube, from the plasma membrane at the tip to the end of an actin filament structure. The length is expressed as the average value calculated for the distance from the plasma membrane to the point of maximum fluorescence intensity on each of the five lines.
Measurement of plasma membrane potential
For Annine-6-plus membrane potential measurements, wild-type and mutant pollen grains were collected and germinated as described above. Pollen grains were incubated at 21.5 °C for at least 2 h before adding the membrane potential dye Annine-6-plus to a final concentration of 10 µg.ml–1. Fluorescence images were acquired on a Zeiss LSM 980 Airyscan 2 Laser Scanning Confocal using a x63 NA1.4 oil immersion objective, in the Super-Resolution mode, and were processed with Airy Scan Super Resolution processing software in Zen lite. The estimated resolution was better than 0.2 µm. Filter settings were as follows: excitation, 475 nm and emission, 499–549 nm (dual-band BP) and 573–627 nm (BP). Images were analyzed in ImageJ by drawing transects that were 2 µm apart and perpendicular to the pollen tube growth axis (see Supplementary Fig. 12). Membrane fluorescence values were averaged from the three maxima pixels in each transect for both the left and right sides of the shank (Supplementary Fig. 12c), corresponding to better than a tenth of the theoretical resolution, and well above the Nyquist criteria in terms of resolution and device pixel resolution oversampling. Images were acquired in strictly the same settings and normalized between different biological replicates by (1) background fluorescence and (2) average cytosolic fluorescence. Final values are the median of fluorescent intensities between 10–20 µm and 40–50 µm from the tip (D, E).
For analysis using DiBAC4(3), pollen tubes of wild-type and aha6/8/9 plants were germinated and grown for 3 h and thereafter stained with 2.5 µM DiBAC4(3) for 10 min right before observation. Controls for endocytosis of the dye were made by treating the pollen tubes with 0.8 µM wortmannin in the liquid pollen germination medium for 1 h after pollen growth and staining with FM4-64 (2 µM) for 10 min immediately before observation. FM4-64 and DiBAC4(3) were excited with a 514-nm and 488-nm argon laser, respectively. The emission wavelength of FM4-64 was set at 620–660 nm, and that of DiBAC4(3) at 515–565 nm using a confocal microscope (Leica SP5). DiBAC4(3) fluorescence was measured as the intensity in the cytosol area in the pollen tube tip and shank (40–50 µm from the tip) using ImageJ software (https://imagej.nih.gov/ij/).
Accession numbers
Sequence data from this article can be found in GenBank/EMBL or the Arabidopsis Genome Initiative database under the following accession numbers: AHA6 (AT2G07560), AHA7 (AT3G60330), AHA8 (AT3G42640), and AHA9 (AT1G80660). The following T-DNA insertion lines were used in this study: SAIL_1293_D09 (aha6-1), SALK_042485 (aha7-1), SALK_105742C (aha7-2), SAIL_823_E09 (aha8-1), SALK_208753 (aha8-3), SALK_064821 (aha9-1; showed aborted male and female gametophytes is heterozygous lines; probably having chromosomal rearrangement and was not further analyzed), SALK_127945 (aha9-4), and GK-764H12 (aha9-5).
Reporting summary
Further information on research design is available in the Nature Research Reporting Summary linked to this article.
Data availability
All data supporting the findings of this study are included in this published article, its Supplementary Information, and the Source Data file. Any other data and material will be made available upon reasonable request.
Change history
15 July 2020
The original version of this Article was updated shortly after publication following an error that resulted in the ORCID IDs of Lene Irene Olsen, Daniel Santa Cruz Damineli, Maki Hayashi, José A. Feijó and Michael Palmgren being omitted.
References
Boavida, L., Becker, J. D., Vieira, A. M. & Feijó, J. A. Gametophyte interaction and sexual reproduction: how plants make a zygote. Int. J. Dev. Biol. 49, 615–632 (2005).
Johnson, M. A., Harper, J. F. & Palanivelu, R. A fruitful journey: pollen tube navigation from germination to fertilization. Annu. Rev. Plant Biol. 70, 809–837 (2019).
Parton, R. M. et al. Pronounced cytoplasmic pH gradients are not required for tip growth in plant and fungal cells. J. Cell Sci. 110, 1187–1198 (1997).
Keteelar, T., Galway, M. E., Mulder, B. M. & Emons, A. M. Rates of exocytosis and endocytosis in Arabidopsis root hairs and pollen tubes. J. Microsc. 231, 265–273 (2008).
Hepler, P. K., Vidali, L. & Cheung, A. Y. Polarized cell growth in higher plants. Annu. Rev. Cell Dev. Biol. 17, 159–187 (2001).
Michard, E., Simon, A. A., Tavares, B., Wudick, M. M. & Feijó, J. A. Signaling with ions: The keystone for apical cell growth and morphogenesis in pollen tubes. Plant Physiol. 173, 91–111 (2017).
Cameron, C. & Geitmann, A. Cell mechanics of pollen tube growth. Curr. Opin. Genet. Dev. 51, 11–17 (2018).
Fricker, M. D., White, N. S. & Obermeyer, G. pH gradients are not associated with tip growth in pollen tubes of Lilium longiflorum. J. Cell Sci. 110, 1729–1740 (1997).
Feijó, J. A., Saínhas, J., Hackett, G. R., Kunkel, J. G. & Hepler, P. K. Growing pollen tubes have a constitutive alkaline band on the clear cap and a growth-dependent acidic tip. J. Cell Biol. 144, 483–496 (1999).
Michard, E., Alves, F. & Feijó, J. A. The role of ion fluxes in polarized cell growth and morphogenesis: the pollen tube as an experimental paradigm. Int. J. Dev. Biol. 53, 1609–1622 (2009).
Baxter, I. et al. Genomic comparison of P-type ATPase ion pumps in Arabidopsis and rice. Plant Physiol. 132, 618–628 (2003).
Sze, H. H+-translocating ATPases: advances using membrane vesicles. Annu. Rev. Plant Physiol. 36, 175–208 (1985).
Palmgren, M. G. Plant plasma membrane H+-ATPases: powerhouses for nutrient uptake. Annu. Rev. Plant Physiol. Plant Mol. Biol. 52, 817–845 (2001).
Lang, V., Pertl-Obermeyer, H., Safiarian, M. J. & Obermeyer, G. Pump up the volume - a central role for the plasma membrane H+ pump in pollen germination and tube growth. Protoplasma 251, 477–488 (2014).
Feijó, J. A., Malhó, R. & Pais, M. S. S. A cytochemical study on the role of ATPases during pollen germination in Agapanthus umbelatus L´Her. Sex. Plant Reprod. 5, 138–145 (1992).
Lefebvre, B. et al. Identification of a Nicotiana plumbaginifolia plasma membrane H+-ATPase gene expressed in the pollen tube. Plant Mol. Biol. 58, 775–787 (2005).
Certal, A. C. et al. Exclusion of a proton ATPase from the apical membrane is associated with cell polarity and tip growth in Nicotiana tabacum pollen tubes. Plant Cell 20, 614–634 (2008).
Rodriguez-Rosales, M. P., Roldan, M., Belver, A. & Donaire, J. P. Correlation between in vitro germination capacity and proton extrusion in olive pollen. Plant Physiol. Biochem. 27, 723–728 (1989).
Axelsen, K. & Palmgren, M. Inventory of the superfamily of P-type ion pumps in Arabidopsis. Plant Physiol. 126, 696–706 (2001).
Pina, C., Pinto, F., Feijó, J. A. & Becker, J. D. Gene family analysis of the Arabidopsis pollen transcriptome reveals novel biological implications for cell growth and division control and gene expression regulation. Plant Physiol. 138, 744–756 (2005).
Bock, K. W. et al. Integrating membrane transport with male gametophyte development and function through transcriptomics. Plant Physiol. 140, 1151–1168 (2006).
Hoffmann, R. D. et al. Roles of plasma membrane proton ATPases AHA2 and AHA7 in normal growth of roots and root hairs in Arabidopsis thaliana. Physiol. Plant. 166, 848–861 (2019).
Pedersen, J. T., Falhof, J., Ekberg, K., Buch-Pedersen, M. J. & Palmgren, M. Metal fluoride inhibition of a P-type H+ pump: Stabilization of the phosphoenzyme intermediate contributes to posttranslational pump activation. J. Biol. Chem. 290, 20396–20406 (2015).
Haruta, M. & Sussman, M. R. The effect of a genetically reduced plasma membrane protonmotive force on vegetative growth of Arabidopsis. Plant Physiol. 158, 1158–1171 (2012).
Bock, K. W. et al. Integrating membrane transport with male gametophyte development and function through transcriptomics. Plant Physiol. 140, 1151–1168 (2006).
Wudick, M. M. et al. CORNICHON sorting and regulation of GLR channels underlie pollen tube Ca2+ homeostasis. Science 360, 533–537 (2018).
DeWitt, N. D., Harper, J. F. & Sussman, M. R. Evidence for a plasma membrane proton pump in phloem cells of higher plants. Plant J. 1, 121–128 (1991).
Robertson, W., Clark, K., Young, J. & Sussman, M. An Arabidopsis thaliana plasma membrane proton pump is essential for pollen development. Genetics 168, 1677–1687 (2004).
Zonia, L., Cordeiro, S. & Feijo, J. A. Ion dynamics and the control of hydrodynamics in the regulation of pollen tube growth. Sex. Plant Reprod. 14, 111–116 (2001).
Gutermuth, T. et al. Pollen tube growth regulation by free anions depends on the interaction between the anion channel SLAH3 and calcium-dependent protein kinases CPK2 and CPK20. Plant Cell 25, 4525–4543 (2013).
Gutermuth, T. et al. Tip-localized Ca2+-permeable channels control pollen tube growth via kinase-dependent R- and S-type anion channel regulation. New Phytol. 218, 1089–1105 (2018).
Tavares, B., Dias, P. N., Moura, T. F., Feijó, J. A. & Bicho, A. Calcium regulated anion channels from pollen of Lilium longiflorum. New Phytol. 192, 45–60 (2011).
Lipchinsky, A. Electromechanics of polarized cell growth. Biosystems. pii: S0303-2647(18)30296-X. doi: 10.1016/j.biosystems.2018.10.004 (2018).
Damineli, D. S. C., Portes, M. T. & Feijo, J. A. in Pollen and Pollen Tube Biology - Methods and Protocols (Ed. Geitmann, A.). (Springer US, 2020). In press. https://doi.org/10.1007/978-1-0716-0672-8.
Hu, C. et al. High precision, localized proton gradients and fluxes generated by a microelectrode device induce differential growth behaviors of pollen tubes. Lab Chip. 17, 671–680 (2017).
Damineli, D. C. S., Portes, M. T. & Feijó, J. A. Oscillatory signatures underlie growth regimes in Arabidopsis pollen tubes: computational methods to estimate tip location, periodicity, and synchronization in growing cells. J. Exp. Bot. 68, 3267–3281 (2017).
Domingos, P. et al. Molecular and electrophysiological characterization of anion transport in Arabidopsis thaliana pollen reveals regulatory roles for pH, Ca2+ and GABA. New Phytol. 223, 1353–1371 (2019).
Benkert, R., Obermeyer, G. & Bentrup, F. The turgor pressure of growing lily pollen tubes. Protoplasma 198, 1–8 (1997).
Chen, L. Y. et al. The Arabidopsis alkaline ceramidase TOD1 is a key turgor pressure regulator in plant cells. Nat. Commun. 6, 6030 (2015).
Winship, L. J., Obermeyer, G., Geitmann, A. & Hepler, P. K. Pollen tubes and the physical world. Trends Plant Sci. 16, 353–355 (2011).
Obermeyer, G. in Pollen Tip Growth (eds. Obermeyer, G. & Feijó, J.) 13–34 (Springer International Publishing, 2017).
Messerli, M. A. & Robinson, K. R. Ionic and osmotic disruptions of the lily pollen tube oscillator: testing proposed models. Planta 217, 147–157 (2003).
Zonia, L. & Munnik, T. Understanding pollen tube growth: the hydrodynamic model versus the cell wall model. Trends Plant Sci. 16, 347–352 (2011).
Lovy-Wheeler, A., Kunkel, J. G., Allwood, E. G., Hussey, P. J. & Hepler, P. K. Oscillatory increases in alkalinity anticipate growth and may regulate actin dynamics in pollen tubes of lily. Plant Cell 18, 2182–2193 (2006).
Cheung, A. Y. et al. The dynamic pollen tube cytoskeleton: Live cell studies using actin-binding and microtubule-binding reporter proteins. Mol. Plant 1, 686–670 (2008).
Yonezawa, N., Nishida, E. & Sakai, H. pH control of actin polymerization by cofilin. J. Biol. Chem. 260, 14410–14412 (1985).
Hawkins, M., Pope, B., Maciver, S. K. & Weeds, A. G. Human actin depolymerizing factor mediates a pH-sensitive destruction of actin filaments. Biochemistry 32, 9985–9993 (1993).
Hepler, P. K. The cytoskeleton and its regulation by calcium and protons. Plant Physiol. 170, 3–22 (2016).
McCall, P. M., MacKintosh, F. C., Kovar, D. R. & Gardel, M. L. Cofilin drives rapid turnover and fluidization of entangled F-actin. Proc. Natl Acad. Sci. USA 116, 12629–12637 (2019).
Chen, C. et al. The regulation of actin organization by actin-depolymerizing factor in elongating pollen tubes. Plant Cell 14, 2175–2190 (2002).
Zhang, H. et al. Arabidopsis VILLIN5, an actin filament bundling and severing protein, is necessary for normal pollen tube growth. Plant Cell 22, 2749–2767 (2010).
Vidali, L., McKenna, S. T. & Hepler, P. K. Actin polymerization is essential for pollen tube growth. Mol. Biol. Cell. 12, 2534–2545 (2001).
Jiang, Y., Wang, J., Xie, Y., Chen, N. & Huang, S. ADF10 shapes the overall organization of apical actin filaments by promoting their turnover and ordering in pollen tubes. J. Cell Sci. 130, 3988–4001 (2017).
Chaudry, F., Guérin, C., von Witsch, M., Blanchoin, L. & Staiger, C. J. Identification of Arabidopsis cyclase-associated protein 1 as the first nucleotide exchange factor for plant actin. Mol. Biol. Cell 18, 3002–3014 (2007).
Chaudry, F. et al. Srv2/cyclase-associated protein forms hexameric shurikens that directly catalyze actin filament severing by cofilin. Mol. Biol. Cell 24, 31–41 (2013).
Jiang, Y., Chang, M., Lan, Y. & Huang, S. Mechanism of CAP1-mediated apical actin polymerization in pollen tubes. Proc. Natl Acad. Sci. USA 116, 12084–12093 (2019).
Lan, Y., Liu, X., Fu, Y., & Huang, S. Arabidopsis class I formins control membrane-originated actin polymerization at pollen tube tips. PLoS Genet. 14, e1007789 (2018).
Kuhn, B. & Roome, C. J. Primer to voltage imaging with ANNINE dyes and two-photon microscopy. Front Cell Neurosci. 13, 321 (2019).
Flickinger, B., Berghöfer, T., Hohenberger, P., Eing, C., & Frey, W. Transmembrane potential measurements on plant cells using the voltage-sensitive dye ANNINE-6. Protoplasma 247, 3–12.
Berghoefer, T., Flickinger, B. & Frey, W. Aspects of plant plasmalemma charging induced by external electric field pulses. Plant Signal. Behav. 7, 322–324 (2012).
Mouline, K. et al. Pollen tube development and competitive ability are impaired by disruption of a Shaker K+ channel in Arabidopsis. Genes Dev. 16, 339–350 (2002).
Podolyan, A., Maksimov, N. & Breygina, M. Redox-regulation of ion homeostasis in growing lily pollen tubes. J. Plant Physiol. 243, 153050 (2019).
McLaughlin, K. A. & Levin, M. Bioelectric signaling in regeneration: mechanims of ionic controls of growth and form. Dev. Biol. 433, 177–189 (2017).
Felle, H. H. pH: Signal and messenger in plant cells. Plant Biol. 3, 577–591 (2001).
Shipley, A. M., & Feijó, J. A. in Fertilization in Higher Plants (eds. Cresti, M., Cai, G., & Moscatelli, A.) 235–252 (Springer, Berlin, Heidelberg, 1999).
Smyth, D. R., Bowman, J. L. & Meyerowitz, E. M. Early flower development in Arabidopsis. Plant Cell. 2, 755–767 (1990).
Czechowski, T., Stitt, M., Altmann, T., Udvardi, M. K. & Scheible, W. R. Genome-wide identification and testing of superior reference genes for transcript normalization in Arabidopsis. Plant Physiol. 139, 5–17 (2005).
Ruprecht, C., Carroll, A. & Persson, S. T-DNA-Induced chromosomal translocations in feronia and anxur2 mutants reveal implications for the mechanism of collapsed pollen due to chromosomal rearrangements. Mol. Plant 7, 1591–1594 (2014).
Edwards, K., Johnstone, C. & Thompson, C. A simple and rapid method for the preparation of plant genomic DNA for PCR analysis. Nucleic Acids Res. 19, 1349 (1991).
Curtis, M. D. & Grossniklaus, U. A gateway cloning vector set for high-throughput functional analysis of genes in planta. Plant Physiol. 133, 462–469 (2003).
Miesenbock, G., De Angelis, D. A. & Rothman, J. E. Visualizing secretion and synaptic transmission with pH-sensitive green fluorescent proteins. Nature 394, 192–195 (1998).
Haseloff, J., Siemering, K. R., Prasher, D. C. & Hodge, S. Removal of a cryptic intron and subcellular localization of green fluorescent protein are required to mark transgenic Arabidopsis plants brightly. Proc. Natl Acad. Sci. USA 94, 2122–2127 (1997).
Tsutsui, H. & Higashiyama, T. pKAMA-ITACHI vectors for highly efficient CRISPR/Cas9-mediated gene knockout in Arabidopsis thaliana. Plant Cell Physiol. 58, 46–56 (2017).
Concordet, J. P. & Haeussler, M. CRISPOR: intuitive guide selection for CRISPR/Cas9 genome editing experiments and screens. Nucleic Acids Res. 46, W242–W245 (2018).
Liu, H. et al. CRISPR-P 2.0: An improved CRISPR-Cas9 tool for genome editing in plants. Mol. Plant 10, 530–532 (2017).
Koncz, C. & Schell, J. The promoter of TL-DNA gene 5 controls the tissue-specific expression of chimaeric genes carried by a novel type of Agrobacterium binary vector. Mol. Gen. Genet. 204, 383–396 (1986).
Logemann, E., Birkenbihl, R., Ülker, B. & Somssich, I. An improved method for preparing Agrobacterium cells that simplifies the Arabidopsis transformation protocol. Plant Methods 2, 16 (2006).
Murashige, T. & Skoog, F. A revised medium for rapid growth and bio assays with tobacco tissue cultures. Physiol. Plant. 15, 473–497 (1962).
Villalba, J. M., Palmgren, M. G., Berberián, G. E., Ferguson, C. & Serrano, R. Functional expression of plant plasma membrane H+-ATPase in yeast endoplasmic reticulum. J. Biol. Chem. 267, 12341–12349 (1992).
Buch-Pedersen, M. J. & Palmgren, M. G. Conserved Asp684 in transmembrane segment M6 of the plant plasma membrane P-type proton pump AHA2 is a molecular determinant of proton translocation. J. Biol. Chem. 278, 17845–17851 (2003).
Wielandt, A. G. et al. Specific activation of the plant P-type plasma membrane H+-ATPase by lysophospholipids depends on the autoinhibitory N- and C-terminal domains. J. Biol. Chem. 290, 16281–16291 (2015).
Baginski, E. S., Foà, P. P. & Zak, B. Microdetermination of inorganic phosphate, phospholipids, and total phosphate in biologic materials. Clin. Chem. 13, 326–332 (1967).
Mori, T., Kuroiwa, H., Higashiyama, T. & Kuroiwa, T. GENERATIVE CELL SPECIFIC 1 is essential for angiosperm fertilization. Nat. Cell Biol. 8, 64–71 (2006).
Vanderveen, J. H. & Wirtz, P. EMS-induced genic male sterility in Arabidopsis thaliana: a model selection experiment. Euphytica 17, 371–377 (1968).
Wilson, Z. A., Morroll, S. M., Dawson, J., Swarup, R. & Tighe, P. J. The Arabidopsis MALE STERILITY1 (MS1) gene is a transcriptional regulator of male gametogenesis, with homology to the PHD-finger family of transcription factors. Plant J. 28, 27–39 (2001).
Backues, S. K., Korasick, D. A., Heese, A. & Bednarek, S. Y. The Arabidopsis dynamin-related protein2 family is essential for gametophyte development. Plant Cell. 22, 3218–3231 (2010).
Peterson, R., Slovin, J. P. & Chen, C. A simplified method for differential staining of aborted and non-aborted pollen grains. Int. J. Plant Biol. 1, 13 (2010).
Boavida, L. C. & McCormick, S. Temperature as a determinant factor for increased and reproducible in vitro pollen germination in Arabidopsis thaliana. Plant J. 52, 570–582 (2007).
Twell, D., Yamaguchi, J., Wing, R. A., Ushiba, J. & McCormick, S. Promoter analysis of genes that are coordinately expressed during pollen development reveals pollen-specific enhancer sequences and shared regulatory elements. Genes Dev. 5, 496–507 (1991).
Wu, Y. et al. Arabidopsis FIMBRIN5, an actin bundling factor, is required for pollen germination and pollen tube growth. Plant Cell 22, 3745–3763 (2010).
Acknowledgements
M.P. laboratory was supported by grants from the Danish National Research Centre “Centre for Membrane Pumps in Cells and Disease” (PumpKin) and Innovation Fund Denmark (LESSISMORE). J.A.F. laboratory was supported in PT by the Fundação para a Ciência e Tecnologia (PTDC/BIA-PLA/4018/2012) and in the US by the National Science Foundation (MCB 1616437/2016 and 1930165/2019) and the University of Maryland. D.D. was funded by the grant 19/23343-7 from the São Paulo Research Foundation (FAPESP). Purchase of the Zeiss LSM 980 Airyscan 2 was supported by the National Institutes of Health award 1S10OD025223-01A1 to the Imaging Core of the Univ. Maryland.
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R.H., M.T.P., L.O., D.D., M.H., J.F., and M.P. designed the research; R.H., M.T.P., L.O., D.D., M.H., C.N., J.P., P.L., and C.C. performed the research. R.H., M.T.P., L.O., D.D., M.H., C.N., J.P., P.L., J.F., and M.P. analyzed the data. R.H., M.T.P., L.O., D.D., M.H., J.F., and M.P. wrote the paper.
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Hoffmann, R.D., Portes, M.T., Olsen, L.I. et al. Plasma membrane H+-ATPases sustain pollen tube growth and fertilization. Nat Commun 11, 2395 (2020). https://doi.org/10.1038/s41467-020-16253-1
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DOI: https://doi.org/10.1038/s41467-020-16253-1
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