Abstract
During the double fertilization process, pollen tubes deliver two sperm cells to an ovule containing the female gametes. In the pollen tube, the vegetative nucleus and sperm cells move together to the apical region where the vegetative nucleus is thought to play a crucial role in controlling the direction and growth of the pollen tube. Here, we report the generation of pollen tubes in Arabidopsis thaliana whose vegetative nucleus and sperm cells are isolated and sealed by callose plugs in the basal region due to apical transport defects induced by mutations in the WPP domain-interacting tail-anchored proteins (WITs) and sperm cell-specific expression of a dominant mutant of the CALLOSE SYNTHASE 3 protein. Through pollen-tube guidance assays, we show that the physiologically anuclear mutant pollen tubes maintain the ability to grow and enter ovules. Our findings provide insight into the sperm cell delivery mechanism and illustrate the independence of the tip-localized vegetative nucleus from directional growth control of the pollen tube.
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Introduction
In angiosperms, the pollen grain is the male gametophyte and consists of two sperm cells within a larger vegetative cell, which produces a pollen tube1. The tip-growing pollen tube transports the cytoplasm and sperm cells to the apical region through the periodical production of thick callose plugs, unique cell wall structures enriched in callose (β-1,3 glucan)2. Deep inside the pistil, the pollen tube perceives attractant peptides at the tip region and precisely targets the ovule3, where two sperm cells are released from the pollen tube in one of the two synergid cells and fertilize the egg cell and the central cell4. The apical transport of the two sperm cells is a prerequisite for these double fertilization events.
Although the pollen tubes produce callose-enriched cell walls, the pair of sperm cells are generally devoid of conventional cell walls. Sperm cells are wholly enclosed by an endocytic membrane called the inner vegetative plasma membrane and a long tail-like protrusion from a sperm cell is tethered to the vegetative nucleus to form an assemblage termed the male germ unit5. During pollen-tube growth in Arabidopsis thaliana, the vegetative nucleus enters the pollen tube before the two sperm cells. Klarsicht/ANC-1/Syne-1 Homology (KASH) proteins such as WPP domain-interacting tail-anchored protein 1 (WIT1) and WIT2 are located on the outer nuclear envelope and are involved in the transport of the vegetative nucleus6. In the wit1 wit2 double mutant, the relative positions of the vegetative nucleus and sperm cells are inverted compared with those in the wild-type, and the vegetative nucleus appears to be dragged by the sperm cells. The phenotype of this double mutant suggests the existence of the putative KASH-independent transport of sperm cells6. However, the nature of this mechanism remains poorly understood.
Transcriptome and translatome data have demonstrated considerable changes in gene expression patterns after the production of pollen tubes7,8,9,10. The genes specifically expressed in the pollen tubes include those that code for receptors, ligands, and enzymes that are indispensable for active tip growth as well as communication with female gametophytic cells. In A. thaliana, mutants lacking sperm cells do not affect the growth control and discharge of the pollen tube, supporting the idea that the vegetative nucleus and its transcriptional activity regulate pollen-tube growth and functions11,12.
Here, we report that the over-accumulation of callose through the expression of the dominant mutant of CALLOSE SYNTHASE 3 from a sperm cell-specific promoter could induce severe defects in the apical transport of sperm cells. By introducing this fusion gene into the vegetative nucleus-immotile wit1 wit2 double mutant, we generated pollen tubes whose vegetative nuclei and sperm cells were retained in the grain and separated from the growing apical region after the formation of a callose plug. Despite this physiologically anuclear condition, the pollen tube exhibited normal directional growth behavior. Our data not only supported sperm cell-specific motive force, but also demonstrated the independence of vegetative nucleus position from various pollen-tube functions.
Results
Callose accumulation on the sperm cell periphery reduced male fertility
Callose is involved in various cellular events, such as cell plate formation, plasmodesmata-mediated protein/RNA transport, response to wounding stress, and pollen-tube growth13,14,15,16. To test the importance of the absence of cell wall components around sperm cells, we induced ectopic callose deposition by expressing a putative constitutively active mutant of CALLOSE SYNTHASE 3 (cals3m)17. In the wild-type A. thaliana pollen, no callose accumulation was observed after aniline blue staining (Fig. 1a). However, approximately half of the pollen from transgenic lines hemizygous for cals3m under the control of the sperm cell-specific HISTONE THREE RELATED 10 (pHTR10:cals3m, designated hereafter SC-cal) displayed callose deposition around the sperm cells (Fig. 1b)18. To examine fertility, we performed a reciprocal cross experiment. When pistils from five independent SC-cal T1 lines were fertilized by wild-type pollen, four of these lines showed ~50% hygromycin resistance in their F1 siblings (Fig. 1c), which is indicative of the normal inheritance of the SC-cal transgenes from female gametophytes. In contrast, hygromycin resistance in the F1 siblings was less than ~25% after cross-pollination between wild-type pistils and pollen from the SC-cal transgenic lines (Fig. 1d). We observed a full set of seeds in the siliques of wild-type plants (Fig. 1e), whereas the SC-cal transgenic lines showed aborted ovules in their siliques (Fig. 1f). We concluded that ectopic callose deposition on sperm cells caused partial male sterility.
To investigate the callose-induced fertilization defect, we introduced SC-cal with a constitutive nuclear marker pRPS5A:HISTONE 2B-tdTomato (RHT)19 and selected new hemizygous A. thaliana plants displaying genetically linked callose accumulation and nuclear tdTomato signal (Fig. 2a; hereafter designated as SC-cal RHT hemizygous plants). In the SC-cal RHT hemizygous plants, we did not observe any defects during pollen formation (Supplementary Fig. 1). To examine whether callose deposition causes abnormalities in gene expression and protein localization to the plasma membrane in sperm cells, we generated SC-cal RHT hemizygous plants that were homozygous for the pGCS1:GCS1-Clover, which is a translational Clover fusion reporter of sperm cell-specific plasma membrane protein GENERATIVE CELL-SPECIFIC 1 (GCS1)/HAPLESS220,21. The Clover signal was observed in ~80% of pollen irrespective of whether the pollen was tdTomato-negative (SC-cal − RHT −) or tdTomato-positive (SC-cal + RH +) (Fig. 2b–d), indicating that callose deposition around sperm cells had little or no effect on their differentiation.
The alteration of the sperm cell wall by callose accumulation might affect the inner vegetative plasma membrane enclosing two sperm cells (Fig. 2a)1,5,6. Thus, we generated SC-cal RHT hemizygous plants that were homozygous for pACA3:Lyn24-mNeonGreen, which expresses mNeonGreen fused with the 24 N-terminus amino acids of Mus musculus Lyn protein (Lyn24) from a vegetative cell-specific ACA3 promoter22. The Lyn24 contains the targeting signals of both myristoylation and palmitoylation; the GFP-fused Lyn24 has been previously shown to label a structure with an eyeglass-shaped outline corresponding to the inner vegetative plasma membrane23. Such eyeglass-shaped pattern was observed in 76.9% of the SC-cal − RHT − pollen (Fig. 2e, g). In contrast, the mNeonGreen signal was uniformly diffused and the frequency of the eyeglass-shaped pattern decreased to 30.8% in tdTomato-positive SC-cal pollen (Fig. 2f, g). These data implied the possible alteration of the outer environment of the sperm cell by callose accumulation.
Apical transport defects were observed in callose-accumulating sperm cells
To analyze the origin of the partial male sterility of the pollen with callose around sperm cells, we observed in vitro-germinated pollen tubes from the SC-cal RHT hemizygous plant shown in Fig. 2a. In wild-type pollen tubes from the RHT transgenic line, two sperm nuclei and one vegetative nucleus were observed in the apical region (Fig. 3a). However, in the pollen tubes from the SC-cal RHT hemizygous plants, sperm cells were surprisingly present in the basal part of the pollen tube, behind the vegetative nucleus relative to the apical region (Fig. 3b). To further investigate this pollen-tube phenotype, wild-type pistils pollinated with the SC-cal RHT hemizygous plant were dissected and incubated on a pollen-tube growth medium containing the nuclear staining dye SYBR Green I. Then, pollen tubes that emerged from the cut styles were analyzed using confocal laser scanning microscopy (Fig. 3c, e). In tdTomato-negative pollen tubes (SC-cal − RHT −), nuclear triplets of the vegetative nucleus and sperm nuclei were observed at the apical region of the pollen tubes (Fig. 3d, e, Normal). However, among the 81 pollen tubes labeled with both tdTomato and SYBR Green I in the vegetative nucleus (SC-cal +, RHT +), 69% did not contain sperm nuclei in the apical region (Fig. 3d, e, VN only). Although most of the remaining SC-cal + RHT + pollen tubes (25%) had three nuclei, sperm cells were further away from the vegetative nucleus than SC-cal − RHT − pollen tubes (Fig. 3d, e, Long VN-SN and Supplementary Fig. 2). Time-lapse imaging and kymographs in SC-cal − RHT − pollen tubes showed that sperm nuclei maintained 5–10 μm intervals from the vegetative nucleus. However, in the SC-cal + RHT + pollen tubes, the distance between the vegetative nucleus and the sperm nuclei fluctuated (Fig. 3f–i and Supplementary Movie 1). The unstable nuclear positions in SC-cal + RHT + could result from the loss of physical tethering between the vegetative nucleus and sperm cells. This hypothesis was confirmed using the nuclear envelope reporter pRANGAP1:RANGAP1-mNeonGreen to visualize the physical tethering (Supplementary Movie 2)6.
To analyze the effect of callose production around sperm cells on pollen-tube discharge, wild-type pistils were pollinated with pollen from the SC-cal RHT hemizygous plant, and Congo red staining was performed to elucidate pollen-tube growth patterns 16 h after pollination (Fig. 4). We found that 92.6% of ovules received one or two pollen tubes (n = 498). Therefore, pollen-tube attraction by the ovules appeared to be normal. When the SC-cal − RHT − wild-type pollen tubes reach the ovules and release sperm cells and vegetative nucleus, the ovules show no male-derived tdTomato signal around the micropyle and terminate further pollen-tube attraction following double fertilization24. Consistently, 45.6% of the ovules received a single pollen tube and no tdTomato signals were observed (Fig. 4a). Conversely, ovules receiving single pollen tubes often had a single focus of the vegetative nucleus (25.9%, Fig. 4b), but rarely contained multiple tdTomato-labeled nuclei (2.2%, Fig. 4c). After the reception of the SC-cal + RHT + pollen tube, double fertilization could not occur because two sperm cells were not present. We also observed ovules with the characteristic physiological response of fertilization failure marked by multiple pollen-tube insertions resulting from the persistent attraction of the pollen tube after the reception of a fertilization-defective pollen tube (15%, Fig. 4e, f)24, partial seed coat formation, and seed abortion (Supplementary Fig. 3)25. We concluded that the loss of sperm cell transport, induced by callose accumulation, was the primary reason for the partial male sterility observed in the SC-cal line.
Genetic dissections of vegetative nucleus transport and sperm cell transport
The pollen-tube growth assays described above revealed the defective transport of sperm cells that accumulated callose. We measured sperm cell positions to characterize this phenotype. We generated three independent lines of the SC-cal RHT hemizygous plants and wild-type RHT hemizygous plants and then analyzed their pollen tubes with the tdTomato-labeled nuclei at 6 h after incubation on the growth medium. In wild-type RHT hemizygous plants, the vegetative nucleus positioned ahead of the two sperm cells was observed in the apical region in 96–100% of pollen tubes (VN&SN apical, VN ahead, Fig. 5a, f, g). In the SC-cal RHT hemizygous plants with strong genetic linkage between SC-cal and RHT, sperm nuclei were retained in the basal region in 68–79% of pollen tubes (VN apical, SN basal, Fig. 5b, f). Indeed, the distance from the pollen-tube tip to the sperm nuclei significantly lengthened in the SC-cal RHT plants than in the wild-type RHT plants, but their vegetative nucleus positions were comparable (Fig. 5i, j). We concluded that callose expression in sperm cells inhibited transport of the sperm cells to the apical region of the pollen tube without adversely affecting the transport of the vegetative nucleus.
According to our results, the SC-cal line could be used to distinguish sperm cell transport from vegetative nucleus transport, which is specifically affected in the wit1 wit2 double mutation (hereafter, wit1/2)6. To assay the interaction between these two genetic backgrounds, we used a wit1/2 homozygous mutant6. We generated three independent wit1/2 mutant plants hemizygous for the RHT nuclear marker and analyzed the tdTomato-positive nuclei in the pollen tube 6 h after germination. The vegetative nucleus remained in the basal part of 8–23% of the wit1/2 mutant pollen tubes (Fig. 5d, f, SN apical, VN basal), which was in contrast with the sperm cell-immotile SC-cal RHT pollen tubes (Fig. 5b). As previously reported6, most the other pollen tubes (77–90%) displayed apical transport of the unit of vegetative nucleus and sperm cells, while the orientation of the unit was inverted with the sperm nuclei first in 93–96% of the wit1/2 pollen tubes (Fig. 5c, f, g, wit1/2 RHT, VN&SN apical, SN ahead). Although the vegetative nucleus was apparently distant from the pollen-tube tip, the positions of sperm nuclei were similar to those in the wild-type (Fig. 5i, j), highlighting the specificity of the apical transport defect in the vegetative nucleus of the wit1/2 pollen tubes.
Generation of a physiologically enucleated pollen tube
In wit1/2 double mutants hemizygous for the SC-cal and RHT with strong genetic linkage (hereafter, wit1/2 SC-cal RHT hemizygous plants), we observed that the vegetative nucleus and sperm cells were isolated in the basal region in 50–76% of the tdTomato-positive pollen tubes 6 h after germination (Fig. 5e, fwit1/2 SC-cal RHT, VN&SN basal). Time-lapse movies of germinating pollen tubes from the wit1/2 SC-cal RHT hemizygous plants showed that the sperm nuclei actively moved in the pollen grain (Supplementary Movie 3), indicating that the transport defect of the wit1/2 mutant vegetative nucleus enhanced by SC-cal was likely due to the loss of pulling force by sperm cells rather than tethering by sperm cells inside the pollen grain.
As shown in Fig. 5e, the immotile sperm nuclei and vegetative nucleus were located behind the first callose plug. The Columbia-0 (Col-0) ecotype used in this study formed the first callose plug, approximately 50 μm of the pollen grain26. To examine callose-plug formation in the wit1/2 SC-cal RHT hemizygous plants, we analyzed a time course of pollen-tube germination. The wit1/2 SC-cal RHT pollen tubes containing three tdTomato-labeled immotile nuclei generated the first callose plug within 3 h after germination, which was similar in Col-0 wild-type pollen tubes (Supplementary Fig. 4a–i). The number of callose plugs in a single pollen tube was also similar in the wit1/2 SC-cal RHT hemizygous plants to that in the Col-0 wild-type (Supplementary Fig. 4j), suggesting that the deposition of callose plugs is independent of the positions of the sperm cells and vegetative nucleus.
The isolation of the sperm nuclei and vegetative nucleus at the basal region may terminate nascent transcript supply to the apical region that contains no nucleus. To investigate this possibility, we observed cross-sections around the first callose plug in pollen tubes containing three tdTomato-labeled immotile nuclei in wit1/2 SC-cal RHT by transmission electron microscopy (Supplementary Fig. 5). A cross-section of the non-callose-plug area had a large vacuole (Supplementary Fig. 5b). In contrast, another section exhibited the congregation of vesicles containing non-membranous material with medium electron density that resembled callose grains in the Petunia pollen tube27, which likely corresponds to the growing region of the first callose plug (Supplementary Fig. 5c). Furthermore, we found this non-membranous material inside the pollen tube in other sections (Supplementary Fig. 5d, n = 3), suggesting the integrity of the first callose plug is completed.
To further examine the callose-plug integrity, we performed a fluorescence loss in photobleaching (FLIP) assay using a wit1/2 SC-cal RHT hemizygous plant that was also hemizygous for a vegetative-cell-specific cytosolic marker, pLAT52:mTurquoise2 (Fig. 6 and Supplementary Movie 4). At 3 h after germination on the growth medium, mTurquoise2 was distributed in the enucleated apical region and in the basal region containing immotile sperm cells and a vegetative nucleus (Prebleach, Timepoint 1–4 in Fig. 6a–c). Photobleaching by 10 rounds of 405 nm laser irradiation rapidly reduced the mTurquoise2 signal in the apical half of the pollen tubes (Postbleach at Timepoint 24 in Fig. 6a–c; ‘Middle’ in Fig. 6d, e). Accompanied by the signal change in the apical region, the mTurquoise2 signal also decreased in the basal area of the pollen tube before the formation of the first callose-plug (n = 3, Fig. 6b; ‘Basal’ in Fig. 6d). However, we did not observe the signal reduction in the basal area behind the callose plug after the formation of the first callose-plug (n = 3, Fig. 6c; ‘Basal’ in Fig. 6e). This indicates that the presence of the callose plug is preventing the movement of the mTurquoise2 protein from the basal regions to the growing regions of the pollen tube, and that potentially the movement of other molecules is also prevented. Taken together, the apical portion of the pollen tube may appear in a physiologically enucleated condition following callose-plug formation, since the callose plug likely terminates the de novo transcript supplied from the immotile vegetative nucleus in the basal region.
Growth and guidance of physiologically enucleated pollen tubes
The wit1/2 SC-cal RHT hemizygous plants showed a variety of defects in the positions of the sperm cells and vegetative nucleus in the pollen tubes (Fig. 5f). Nevertheless, the length of the pollen tubes in wit1/2 SC-cal RHT hemizygous plants was similar to that in the wild-type, implying that the retention and isolation of the vegetative nucleus had a limited effect on pollen-tube growth (Fig. 5h). The resilience of enucleated pollen tubes may be sustained by transcripts or proteins synthesized before callose-plug formation. To analyze protein stability, we used the pLAT52:mTurquoise2 and the pPRK6:PRK6-mRUBY2, two reporter genes expressed in mature pollen and growing pollen tube28,29. In pollen tubes from wit1/2 SC-cal RHT hemizygous plants carrying pLAT52:mTurquoise2, we observed cytosolic mTurquoise2 in the apical region even 8 h after the germination (Fig. 7a). We then analyzed pollen tubes from the wit1/2 SC-cal RHT hemizygous plants harboring the pPRK6:PRK6-mRUBY2 (Fig. 7b). PRK6 is a receptor-like kinase that perceives pollen-tube attractant AtLURE peptides28. In the enucleated pollen tubes, the signal of tip-localized PRK6-mRUBY2 was detected in the same level as that in the tdTomato-negative control pollen tubes segregated from the same plant (Fig. 7c).
According to the stability of PRK6-mRUBY2, the enucleated pollen tubes may retain the capability to respond to pollen-tube attractant signals. Thus, we performed a modified semi-in vitro pollen-tube attraction assay to investigate the ovular-targeting behavior of a single pollen tube (Fig. 8a)30. In each assay, a pollen grain was attached to a papilla cell of a dissected pistil on pollen-tube growth medium and incubated with wild-type ovules for more than 14 h, followed by aniline blue staining to analyze the growth patterns of the pollen tubes. We validated the single pollen-tube guidance assay by using ovules from wild-type Col-0 and myb98 homozygous mutant defective in the attraction of pollen tubes31. We confirmed that 20.4% of wild-type pollen tubes entered Col-0 ovules (n = 54, Supplementary Fig. 6a, c, d), but none penetrated myb98 ovules (n = 54, Supplementary Fig. 6b–d). When we analyzed the wild-type Col-0 pollen, 80% of the pollen tubes penetrated the cut style (n = 115, Fig. 8b). The wit1/2 double mutant, which was also hemizygous for the SC-cal RHT, produced tdTomato-positive wit1/2 SC-cal pollen and tdTomato-negative wit1/2 pollen. After assessing the tdTomato signal under a fluorescent microscope, each pollen grain was subjected to a single pollen-tube attraction assay. Pollen tubes that emerged through the cut style were observed in 57.5% of pistils pollinated with the tdTomato-positive wit1/2 SC-cal pollen (n = 134). This frequency did not significantly differ from those of wild-type Col-0 pollen or tdTomato-negative wit1/2 pollen (54.8%, n = 104, Fig. 8c, e), confirming the growth capability of the tdTomato-positive wit1/2 SC-cal pollen tubes (Fig. 5e, h). Surprisingly, the insertion of the pollen tube into the ovule occurred with 28.6% of tdTomato-positive wit1/2 SC-cal pollen (Fig. 8d, f, wit1/2 SC-cal + RHT +), which was comparable to that in Col-0 pollen (23.9%, Fig. 8b, f, Col-0) and tdTomato-negative wit1/2 pollen (42.1%, Fig. 8c, f, wit1/2 SC-cal − RHT −). Among the 22 wit1/2 SC-cal RHT pollen tubes displaying successful attraction, 73% were found to have the unit of vegetative nucleus and sperm nuclei confined to the basal area around the papilla cells (Fig. 8d, right panels). These data revealed a previously hidden pollen-tube ability to grow and respond to the female signal even in the absence of the vegetative nucleus and sperm cells at their tip.
Discussion
The features of the pollen tube, including active tip growth and response to female tissues, were thought to be controlled by gene expression from the vegetative nucleus11. By inducing sperm cell-specific callose accumulation in the wit1/2 double mutant, we generated pollen tubes whose vegetative nucleus and sperm cells were isolated in the basal region by callose-plug formation. This aberrant apical nuclear transport revealed the unexpected independence of the directional growth control of the pollen tube from the tip-localization of the vegetative nucleus.
We found that the dominant mutant of CALLOSE SYNTHASE 3 expressed from a sperm cell-specific HTR10 promoter (SC-cal) could induce defects in the apical transport of sperm cells (Fig. 3). Independent motive forces of the vegetative nucleus and sperm cell have been discussed in previous studies32,33. This idea was supported by another previous report that observed the compromised apical transport of the vegetative nucleus in the wit1/2 double mutant6. SC-cal-induced loss of sperm cell motility is important evidence for determining the independence of vegetative nucleus transport and sperm cell transport.
It is unclear why SC-cal impaired sperm cell transport. In A. thaliana, heat shock stress also results in the retention of sperm cells in the basal area of the pollen tube34. Since heat-induced transport defects are accompanied by the separation of a pair of sperm cells, the dissociation of the inner vegetative plasma membrane enclosing the sperm cells might be involved in the loss of sperm cell motility. Although Lyn24-mNeonGreen was less frequently localized at the inner vegetative plasma membrane in the SC-cal pollen (Fig. 2e–g), sperm cells were usually observed as pairs (Fig. 3e, g, i and Supplementary Movies 1–3). Therefore, callose accumulation on the sperm cells may affect their transport via alterations in the lipid or protein composition of the inner vegetative plasma membrane, rather than the disappearance of the inner vegetative plasma membrane. In contrast to animals and non-flowering plants, the sperm cells of flowering plants do not have structures generating motive force such as flagella or pilli1. Hence, the mechanism of sperm cell migration in pollen tubes has been a long-standing mystery of plant reproduction. Further biochemical and genetic approaches would provide answers to remaining questions regarding the relevance of callose levels, alteration of the inner vegetative plasma membrane, and motility of sperm cells.
The retention of the unit of vegetative nucleus and sperm cells and subsequent callose-plug formation would likely interrupt nascent transcript supply to the apical region (Fig. 6), but the growth and ovular-targeting behavior of the pollen tubes were normal (Fig. 5h and Fig. 8f). Many plants, including A. thaliana, show tolerance against transcription inhibitors during germination and tip growth, but the effect varies among species7,35, suggesting that the early stages of pollen tubes use mRNA accumulated before pollen germination. However, transcriptome or translatome analyses have identified subsets of genes expressed after germination7,8,9,10. Indeed, some of these genes have been shown to play important roles in the late stage of pollen tubes, such as ovular-targeting behavior9,10. Most likely, even the late-stage pollen-tube functions can be sufficiently maintained by transcripts expressed for a few hours after germination until callose-plug formation. Conversely, not all pollen-tube functions might be sustained by pre-set gene expression. Previous studies reported that the wit1/2 double mutant showed defects in discharging pollen-tube contents into synergid cells; nevertheless, the extent to which the pollen-tube reception relies on the apically localized vegetative nucleus remains to be shown owing to the passive migration of the vegetative nucleus by motile sperm cells6,36. In the present study, we did not conduct a quantitative analysis of pollen-tube reception. However, the SC-cal wit1/2 pollen tube can provide an ideal tool for answering this question and will provide new insights into the sophisticated delivery system of the male genome in flowering plants.
Methods
Gene identifiers
The AGI codes of the genes in the present study are as follows: WIT1 (AT5G11390), WIT2 (AT1G68910), CALS3/GSL12 (AT5G13000), HISTONE 2B (AT1G07790), GCS1/HAPLESS2 (AT4G11720), RANGAP1(AT3G63130), HTR10/MGH3 (AT1G19890), SYP132 (AT5G08080), PRK6 (AT5G20690), and ACA3 (AT5G04180).
Plant materials and growth conditions
Arabidopsis thaliana Columbia-0 (Col-0) was used as the wild-type plant and the background of all mutants. The wit1-1 wit2-1 double null mutant was kindly provided by Dr. Meier and Dr. Tamura6. Plants were grown on soil at 22 °C under continuous light or standard long-day conditions (16 h light: 8 h dark).
Plasmids
A DNA fragment of the HTR10 promoter (1215 bp upstream region from the ATG of the HTR10 gene) was amplified from Col-0 genomic DNA using the primers ‘pHTR10HindIII_F’ and ‘pHTR10HindIII_R’ (Supplementary Table 1), and cloned into the HindIII site of the pGWB501 destination vector to produce pDM25218,37. pOR084, an entry clone containing mRUBY2-SYP132, was constructed as follows: (1) A pENTR/D-TOPO vector (Invitrogen) containing the mRUBY2 gene was amplified using the primers ‘FP_SpeI_F’ and ‘FP_EcoRI_R’ (Supplementary Table 1);38 (2) the coding region of the SYP132 was amplified from a cDNA of a Col-0 seedling using the primers ‘SYP132_EcoRI_F’ and ‘SYP132_SpeI_R’ (Supplementary Table 1); and (3) these two PCR products were assembled using the NEBuilder HiFi DNA Assembly Cloning Kit (New England Biolabs, MA, USA) to produce pOR084. LR recombination between pDM252 and pOR084 was performed using LR Clonase II (Invitrogen) to produce pDM439, a vector containing pHTR10:mRUBY2-SYP132. Another LR recombination between pDM252 and pENTR cals3m gave rise to MNv231, a plasmid carrying the pHTR10:cals3m (SC-cal). A DNA fragment of the ACA3 promoter22 (1607 bp upstream region from the ATG of the ACA3 gene) was amplified from Col-0 genomic DNA using the primers ‘pACA3HindIII_F’ and ‘pACA3HindIII_R’ and cloned into the HindIII site of the pGWB501 destination vector to produce pDM527 (Supplementary Table 1)37. A DNA fragment of mNeonGreen was amplified using primers ‘Lyn24-mNG_F’ and ‘FP_R’ and cloned into pENTR/D-TOPO to produce pOR158 (Supplementary Table 1)39. LR recombination between pDM527 and pOR158 was performed to produce pDM549, a vector containing pACA3:Lyn24-mNeonGreen. dHT1, a plasmid carrying the pRANGAP1:RANGAP1-mNeonGreen, was constructed as follows: (1) mNeonGreen was amplified using primers ‘Linker1_FP_F’ and ‘mNG_R’ (Supplementary Table 1);39 (2) the genomic sequence of the RANGAP1 (1214 bp upstream of the start codon to the end of the protein-coding region without the stop codon of AT3G63130) was amplified using primers ‘RANGAP1pro_F’ and ‘RANGAP1_R’ (Supplementary Table 1);6 and (3) these two DNA fragments were mixed with the plasmid backbone of HTv896, a pPZP21140-based plasmid containing the NOS terminator after the AviTagTM sequence (Avidity), and assembled using the NEBuilder HiFi DNA Assembly Cloning Kit to generate dHT1. The LAT52 promoter (593 bp) originated from LAT52-729 was amplified using primers ‘pLAT52HindIII_F’ and ‘pLAT52HindIII_R’ (Supplementary Table 1), and cloned into the HindIII site of the pGWB501 destination vector to produce pDM24937. A DNA fragment of mTurquoise241 was amplified using primers ‘pENTR_CFP_F’ and ‘FP_R’ and cloned into pENTR/D-TOPO to produce pOR120 (Supplementary Table 1). LR recombination between pDM249 and pOR120 was performed to produce pDM473, a vector containing pLAT52: mTurquoise2. A pPZP22140 plasmid containing pPRK:PRK6-mRUBY2 was described previously28. pGCS1:GCS1-Clover was provided by Dr. Tomokazu Kawashima, Kentucky University. pRPS5A:H2B-tdTomato (RHT) was provided by Dr. Daisuke Kurihara19.
Preparation of transgenic plants
Agrobacterium-mediated plant transformation was performed by the floral dipping method using Agrobacterium strain GV310142. The simultaneous transformation of SC-cal and RHT was conducted as follows: (1) Agrobacterium suspensions of SC-cal and RHT were independently prepared and mixed just before the floral dipping procedure; (2) transformants harboring both SC-cal and RHT were selected on Murashige and Skoog medium containing 50 μg/mL hygromycin B and 50 μg/mL kanamycin; (3) screening of the SC-cal RHT transgenic lines was performed by fluorescent observation of mature pollen mounted in aniline blue solution (0.1% [w/v] aniline blue, 0.1 M K3PO4); and (4) to select transgenic lines with a strong genetic linkage between SC-cal and RHT, we confirmed the 1:1 segregation of the tdTomato-positive and -negative pollen and then determined whether the presence or absence of the tdTomato signal corresponded to the aniline blue signals on the sperm cells in more than 90% of those pollen.
Analysis of pollen grains
In the analysis of callose deposition during microsporogenesis, stamens in various flowering stages were mounted in the aniline blue solution (see the ‘Methods’ section on ‘Preparation of transgenic plants’) and squashed to release pollen from the anthers. Fluorescent images of tdTomato and aniline blue were photographed using an Olympus IX73 inverted microscope (Tokyo, Japan) equipped with an sCMOS camera (Zyla 4.2; Andor, Belfast, UK) using RFP and CFP filters, respectively. To obtain a super-resolution image, we used the deconvolution software Huygens Ver. 17.04. (Scientific Volume Imaging, Hilversum, the Netherlands) from an image acquired using the photon-counting mode of a confocal laser scanning microscope (Leica TCS SP8, Wetzlar, Germany). Pollen from SC-cal RHT carrying the pGCS1:GCS1-Clover or pACA3:Lyn24-mNeonGreen reporter gene were mounted in 5% sucrose and observed by the TCS SP8.
Staining of ovules or seeds
Congo red staining was performed as follows: (1) Pistils one-day-after-pollination were dissected and covered by a coverslip with 5% sucrose; (2) through the narrow space between the glass slide and cover slip, the samples were stained with 0.4% Congo red solution for 1 min and rinsed several times with 5% sucrose; (3) fluorescent signals were observed by the RFP filter set using the Olympus IX73 inverted microscope. In vanillin staining, seeds at 2 days post pollination were treated with a 6 N HCl solution containing 1% vanillin (w/v) for more than 1 h at room temperature43.
In vitro and semi-in vitro pollen-tube growth
To observe the pollen tubes in vitro, pollen grains were incubated on a pollen germination medium (0.01% boric acid, 5 mM CaCl2, 5 mM KCl, 1 mM MgSO4, 10% sucrose, adjusted pH to 7.5 with 1 N KOH, 1.5% NuSieve GTG agarose supplemented with 10 μM epibrassinolide44) and observed by an Axio Imager A2 upright microscope (Zeiss, Jera, Germany) equipped with a cooled CCD camera (AxioCam HRm; Zeiss), by an LSM780-DUO-NLO laser scanning microscope (Zeiss), or by Axio Imager M1 upright microscope (Zeiss). For the semi-in vitro pollen-tube growth, we modified the protocol described by Susaki et al.29. In brief, pollen-tube growth medium (0.01% boric acid, 5 mM CaCl2, 5 mM KCl, 1 mM MgSO4, 10% sucrose, adjusted pH to 7.5 with 1 N KOH, 1.5% NuSieve GTG agarose) was melted at 65 °C and solidified on a glass bottom dish (D11130H, Matsunami Glass IND., LTD., Japan) to form a thin layer. Stigmas from emasculated wild-type pistils were cut with a needle and placed on the medium, followed by hand-pollination with pollen from transgenic plants. After 3–5 h of incubation, pollen tubes that emerged from the cut pistils were observed by the TCS SP8 microscope. To label with DNA in the sperm nuclei and vegetative nucleus, we used pollen tube growth medium containing 2000-fold diluted SYBR Green I. Note that the SYBR Green I staining was only used in the semi-in vitro pollen-tube growth assay; SYBR Green I extensively labeled cytosol when pollen tubes were directly germinated on the SYBR Green I-containing medium. For time-lapse imaging, 0.5 h after pollination, pollen grains were placed on a pollen tube germination medium for observation. Z-series images were captured every 2 min using a spinning-disk confocal system (CSU-WI; Yokogawa Electric, Tokyo, Japan) with a 60× objective lens (UPLSAPO, NA.1.3; Olympus, Tokyo, Japan) and an electron-multiplying CCD camera (iXON3 888; Andor).
Photobleaching assay
Pollen was placed on a thin layer of growth medium in a ϕ35 mm petri dish and incubated for 2 h at 22 °C. The germinated pollen tubes were transferred to a large coverslip (24 mm × 40 mm, Matsunami) with the growth medium, sandwiched by another smaller coverslip, and gently squashed to observe whole pollen tubes in a single focal plane (18 × 18 mm, Matsunami). Then, viable pollen tubes displaying rapid protoplasmic streaming were subjected to 10 rounds of photobleaching by the SP8 TCS microscope (Leica). In each photobleaching procedure, the apical half of the pollen tube was scanned 10 times with a 405 nm diode laser at 100% laser power.
Electron microscopy
In vitro-germinated pollen tubes were observed 8 h after germination under the Olympus MVX10 fluorescence stereomicroscope (Olympus) using the RFP filter set. Pollen tubes whose vegetative nucleus and sperm nuclei remained in the basal area were dragged out one-by-one and aligned in one place on the medium with a 27 gauge needle. Those pollen tubes were collected with small pieces of growth medium and fixed with 2% glutaraldehyde and 2% paraformaldehyde in 50 mM cacodylate buffer pH 7.4 at 4 °C. The tissue segments were washed in buffer and post-fixed for 3 h in 2% aqueous osmium tetroxide at 4 °C. The tissue was then dehydrated in a graded ethanol series, transferred into propylene oxide, infiltrated, and embedded in Quetol 651. Cross-sections around the basal area of the pollen tubes (90 nm thickness) were stained with 2% aqueous uranyl acetate and lead citrate and examined using a JEOL JEM 1400Plus electron microscope at 100 kV.
Single pollen-tube attraction assay
Pollen grains were spread on glass slides using an eyelash attached to a toothpick. From the glass slides, single pollen grains were picked up by the eyelash and subjected to semi-in vitro pollen-tube growth as described above. In the case of the wit1 wit2 mutant hemizygous for the SC-cal-linked RHT, the presence or absence of the tdTomato signal was assessed using an upright Axio M1 Imager microscope (Zeiss) before pollination. Three fresh ovules from the wild-type or myb98 mutant were placed adjacent to the cut style and incubated overnight. After the aniline blue staining, pollen tube and pollen grains on the stigma were observed by the IX73 microscope (Olympus).
Reporting summary
Further information on research design is available in the Nature Research Reporting Summary linked to this article.
Data availability
All data that support the findings of this study are available from the corresponding authors upon reasonable request. Source data are provided with this paper.
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Acknowledgements
We thank K. Tamura and I. Mayer for wit1 wit2 mutant; Y. Helariutta and S. Miyashima for cals3m construct; D. Kurihara for pRPS5A:H2B-tdTomato; T. Kawashima for pGCS1:GCS1-Clover; K. Matsuura-Tokita for in vitro germination assay, M. Tsukatani, H. Ikeda, and H. Kakizaki for technical supports, F. Berger for advise on the research, Y. Nakaoka for image processing, Tokai Electron Microscopy, Inc. for transmission electron microscopy, and Editage for English language editing. This work was supported: by JSPS KAKENHI Grant Numbers (Nos. 16H06173, 17H05846, 19H04869, 20H03280, 20K21432, 20H05422, 20H05778, and 20H05781 to D.M., Nos. 16J02257, 19K23759, and 20K15822 to K.M., Nos. 16H06464, 16H06465, 16K21727, and JP16H06280 to T.H.); by JST PRESTO Grant Numbers (No. JPMJPR20D9 to K.M.); by Grant for academic research from Yokohama City University (to D.M.); by the grant for 2016–2021 Research Development Fund of Yokohama City University (to D.M.); by the grant for 2019–2021 Strategic Research Promotion (Nos. SK1903) of Yokohama City University (to D.M.); by the Sasakawa Scientific Research Grant from The Japan Science Society (to K.M.); and by the Third-Phase R-GIRO Research from the Ritsumeikan Global Innovation Research Organization, Ritsumeikan University (to K.M. and A.T.).
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M.N. and D.M. conceived the idea of gametophyte-specific cals3m expression system. K.M. and D.M. performed most of experiments, directed the project, and wrote the manuscript. H. Tsuchi constructed a plasmid of the pRANGAP1:RANGAP1-mNeonGreen. H. Takeuchi, A.T., T.K., and T.H. provided pivotal suggestions on the manuscript.
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Motomura, K., Takeuchi, H., Notaguchi, M. et al. Persistent directional growth capability in Arabidopsis thaliana pollen tubes after nuclear elimination from the apex. Nat Commun 12, 2331 (2021). https://doi.org/10.1038/s41467-021-22661-8
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DOI: https://doi.org/10.1038/s41467-021-22661-8
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