Plant and Cell Physiology Advance Access originally published online on April 15, 2009
Plant and Cell Physiology 2009 50(6):1041-1048; doi:10.1093/pcp/pcp055
| ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Application of Lifeact Reveals F-Actin Dynamics in Arabidopsis thaliana and the Liverwort, Marchantia polymorpha
1Department of Biological Sciences, Graduate School of Science, The University of Tokyo, Bunkyo-ku, Tokyo, 113-0033 Japan
2Molecular Membrane Biology Laboratory, RIKEN Advanced Science Institute, Wako, Saitama, 351-0198 Japan
3Graduate School of Biostudies, Kyoto University, Kyoto, 606-8502 Japan
*Corresponding author: E-mail, tueda{at}biol.s.u-tokyo.ac.jp; Fax, +81-3-5841-7613.
 |
Abstract |
|---|
 Top Abstract IntroductionResults and DiscussionMaterials and MethodsSupplementary dataFundingAcknowledgmentsReferences |
|---|
Actin plays fundamental roles in a wide array of plant functions, including cell division, cytoplasmic streaming, cell morphogenesis and organelle motility. Imaging the actin cytoskeleton in living cells is a powerful methodology for studying these important phenomena. Several useful probes for live imaging of filamentous actin (F-actin) have been developed, but new versatile probes are still needed. Here, we report the application of a new probe called Lifeact for visualizing F-actin in plant cells. Lifeact is a short peptide comprising 17 amino acids that was derived from yeast Abp140p. We used a Lifeact–Venus fusion protein for staining F-actin in Arabidopsis thaliana and were able to observe dynamic rearrangements of the actin meshwork in root hair cells. We also used Lifeact–Venus to visualize the actin cytoskeleton in the liverwort Marchantia polymorpha; this revealed unique and dynamic F-actin motility in liverwort cells. Our results suggest that Lifeact could be a useful tool for studying the actin cytoskeleton in a wide range of plant lineages.
Keywords: Actin - Arabidopsis thaliana - Lifeact - Liverwort - Marchantia polymorpha
Abbreviations: ABD, actin-binding domain; BA, bistheon-ellide A; BDM, 2,3-butanedione-2-monoxime; CaMV, cauliflower mosaic virus; F-actin, filamentous actin; GFP, green fluorescent protein; PBS, phosphate-buffered saline
|
Introduction |
|---|
|
TopAbstractIntroductionResults and DiscussionMaterials and MethodsSupplementary dataFundingAcknowledgmentsReferences |
|---|
Actin microfilaments are a major component of the cytoskeleton and play crucial roles in a wide variety of cellular activities in eukaryotic cells. In animal cells, actin plays essential roles in cell migration and cytokinesis. In plants, actin is utilized differently, probably reflecting the immobile nature of the cells due to the rigid cell wall. Many cellular functions in plants, including cytoplasmic streaming, cell division, cell elongation, cell morphogenesis and organelle movement, require filamentous actin (F-actin) (Ketelaar and Emons 2001
, Hasezawa and Kumagai 2002, Hussey et al. 2006).
The establishment of fluorescent probes, particularly green fluorescent protein (GFP), to visualize F-actin in living cells has dramatically facilitated the understanding of actin dynamics. Initially, actin–GFP fusion proteins were used successfully to visualize F-actin. However, direct labeling of actin impaired its function; thus, the actin–GFP fusion protein had to be mixed with non-tagged actin (Westphal et al. 1997). In addition, the fluorescence from unpolymerized GFP–actin in the cytosol could impair clear visualization of F-actin. These problems were overcome with the advent of GFP-tagged actin side-binding proteins. These comprised GFP fused to the actin-binding domain (ABD) from mouse talin (mTn) (Kost et al. 1998) or the ABD from fimbrin1 of Arabidopsis thaliana (ABD2) (Sheahan et al. 2004). These two probes are currently the state of the art for visualizing F-actin in plant cells. They allow investigators to identify various structures and dynamics of actin filaments concomitant with various plant functions (for example, Mathur et al. 2003, Cheung and Wu 2004, Holweg et al. 2004, Gu et al. 2005, Voigt et al. 2005, Higaki et al. 2007, Yoneda et al. 2007, Higaki et al. 2008, Staiger et al. 2009). On the other hand, these F-actin probes have also been reported to exert unexpected side effects on actin organization or myosin-dependent motility of organelles (Ketelaar et al. 2004, Sheahan et al. 2004, Higaki et al. 2007, Holweg 2007). This spurred interest in developing a new F-actin marker with different molecular properties.
It was recently demonstrated that a peptide comprising the first 17 amino acids of the yeast protein Abp140p is sufficient for localizing GFP to F-actin. This short peptide, called ‘Lifeact’ (Riedl et al. 2008), did not affect actin polymerization or depolymerization in vitro. The usefulness of Lifeact was also demonstrated in vivo with the expression of the Lifeact–GFP fusion protein. In mammalian cells, Lifeact–GFP did not influence actin-dependent processes, including neuronal polarization, lamellipodia flow and leukocyte chemo-taxis. These features are probably due to the following facts: (i) the low binding affinity of Lifeact for F-actin presents little competition against major endogenous actin-binding proteins; and (ii) the absence of homologous sequences in higher eukaryotes obviates the titration of endogenous proteins (Riedl et al. 2008). Furthermore, the small size of Lifeact allows construction of chimeric markers with a single round of PCR amplification.
We hypothesized that these properties would also be advantageous in plants. In this study, we used Lifeact to visualize F-actin in Arabidopsis thaliana and an emerging bryophyte model, Marchantia polymorpha (Bowman et al. 2007, Ishizaki et al. 2008). Our study demonstrated that Lifeact could be a useful tool for the live imaging of F-actin in broad lineages of plants, including angiosperms and bryophytes.
|
Results and Discussion |
|---|
|
TopAbstractIntroductionResults and DiscussionMaterials and MethodsSupplementary dataFundingAcknowledgmentsReferences |
|---|
Lifeact–Venus-labeled actin microfilaments in A. thaliana
We constructed a chimeric gene that contained the cauliflower mosaic virus (CaMV) 35S promoter, the Lifeact actin-binding sequence and the Venus protein sequence (modified yellow fluorescent protein). The resulting Lifeact–Venus fusion protein comprised the two peptides, separated by a four amino acid linker (Gly–Gly–Ser–Gly) (Fig. 1). To verify the availability of Lifeact in plant cells, we introduced Lifeact–Venus into A. thaliana. We observed actin structures and dynamics under a spinning-disk confocal laser scanning microscope in homozygous or hemizygous plants for the transgene in which a marked deleterious effect of Lifeact–Venus on plant growth was not observed (Supplementary Fig. S1).
|
Lifeact–Venus permitted the visualization of filamentous networks in various types of A. thaliana cells, including cotyledon epidermal cells (Fig. 2A), guard cells (Fig. 2A, arrow), hypocotyl cells (Fig. 2B), root cells (Fig. 2C) and true leaf epidermal cells (Fig. 2D). The observed networks of fine and dense filaments were quite similar to the actin networks observed with GFP–ABD2 (Sheahan et al. 2004
, Higaki et al. 2007), suggesting that Lifeact had been successfully integrated into Arabidopsis cells. To confirm that Lifeact was bound to F-actin, we used rhodamine-conjugated phalloidin to stain F-actin in root epidermal cells that expressed Lifeact–Venus. As shown in Fig. 2E, the signal from rhodamine entirely overlapped the fluorescence from Venus, indicating that Lifeact–Venus does successfully visualize actin filaments by binding to F-actin.
|
We observed F-actin buckling in several tissues (data not shown), consistent with observations in previous reports when F-actin was visualized with other probes (Sheahan et al. 2004
, Higaki et al. 2007, Staiger et al. 2009). Among the observed A. thaliana tissues presented in Figs. 2 and 3, the most dynamic behavior of F-actin was observed in growing root hair cells. Dense actin cables were aligned along the long axis of root hair cells and seemed to branch into a fine meshwork at the apex (Fig. 3A). This pattern was similar to the distribution of endogenous F-actin visualized with immunostaining (Miller et al. 1999), further supporting the reliability of this new probe. Time-sequential observations of actin filaments in root hair cells revealed that the fine actin filaments in the apical region were highly dynamic (Fig. 3B, Supplementary Movie 1). In contrast, the longitudinally oriented dense actin cables were more static, but they did exhibit lateral waving movements. Recently, GFP–ABD2 expression was used to observe dynamic behavior of fine actin filaments that was dominated by rapid growth and severing activity in hypocotyl cells of A. thaliana (Staiger et al. 2009). We found that fine actin filaments at the cortical region of the cytoplasm in root hair cells, between the plasma membrane and the static dense actin cables, were also dynamically rearranged (Fig. 3C, Supplementary Movie 2). These results suggest that hypocotyl and root hair cells may share a common mechanism for actin filament dynamics. Thus, these results demonstrated that Lifeact could be a new and useful probe for visualizing F-actin in A. thaliana.
|
Actin filaments in M. polymorpha are highly dynamic
Given its importance in the evolutionary chain, M. polymorpha is expected to be a new model bryophyte (Bowman et al. 2007
). The F-actin dynamics in M. polymorpha have not been well characterized; thus, we introduced Lifeact–Venus into this emerging model plant for the characterization of F-actin organization. We transformed M. polymorpha by co-cultivating immature thalli with Agrobacterium tumefaciens that harbored a binary vector containing Lifeact–Venus (Ishizaki et al. 2008). This probe allowed the visualization of filamentous networks and fragmented filaments in thalli and growing rhizoids (Fig. 4A, B). The Lifeact fluorescence pattern completely overlapped with the signal from Alexa Fluor 568-conjugated phalloidin (Fig. 4D); thus Lifeact– Venus also efficiently bound to the actin filaments in M. polymorpha cells. The identity of the filamentous structures was also confirmed by the observation that the fluorescence was dispersed throughout the cytosol upon treatment with the actin-depolymerizing drug, bistheonellide A (BA) at a concentration of 4 µM for 2 h (Fig. 4C). These results indicate that Lifeact is applicable to studies on a wide range of plant taxa, ranging from bryophytes to angio-sperms.
|
It has been reported that actin filaments can actively swing or move laterally in plant cells, depending on the myosin activity (Sheahan et al. 2004
, Higaki et al. 2006). To examine whether actin filaments also have dynamic behavior in M. polymorpha cells, we performed time-sequential imaging of the actin filaments in epidermal cells of developing M. polymorpha thalli. We found that the actin filaments of M. polymorpha cells were highly dynamic. In most cells that we observed, actin networks were rapidly moving with motilities that depended on their thickness; fine actin filaments were highly motile, while dense actin cables appeared only slightly motile (Fig. 5A, Supplementary Movie 3). Stabilization of actin filaments by thickening was also reported in vitro and in A. thaliana hypocotyl cells (Michelot et al. 2007, Staiger et al. 2009). In addition to lateral movement, we observed actin cables that could slide directionally (Fig. 5B, Supplementary Movie 4). The sliding movement was reminiscent of the gliding assay performed with F-actin on coverslips coated with myosin. Therefore, we examined whether myosin was involved in the F-actin sliding in M. polymorpha cells. We treated young thalli expressing Lifeact–Venus with 30 mM 2,3-butanedione-2-monoxime (BDM), an inhibitor of myosin ATPase (Tominaga et al. 2000, Funaki et al. 2004). The F-actin movement completely ceased in the presence of this drug (Fig. 5C, Supplementary Movie 5); this suggested that the motility of F-actin was dependent on myosin in M. polymorpha. However, this result did not rule out the possible involvement of actin assembly proteins (e.g. formins) or actin-nucleating proteins (e.g. the Arp2/3 complex) in the actin dynamics of M. polymorpha.
|
There appeared to be a track that defined the path of actin cable movements, because actin cables were frequently observed sliding along the same routes in cells. This notion was supported by the observation that sliding actin cables sometimes merged and bundled into a dense cable (Fig. 6A, Supplementary Movie 6). Intriguingly, in one observation, two actin cables moving in opposite directions met on the same track (Fig. 6B, Supplementary Movie 7). This observation may reflect the flexibility of the motor proteins that enables movement in opposite directions in M. polymorpha cells. It is also an interesting possibility that an actin bundle functions as a track for the bundle oriented in the opposite direction.
|
Another interesting behavior of F-actin in M. polymorpha was the branching of actin bundles. As shown in Fig. 7 and Supplementary Movie 8, bundled actin filaments were observed to branch into two or more sub-bundles. The branching of actin bundles has been observed in vivo in animal cells (Schaefer et al. 2002
), but has not yet been clearly reported in plant cells, although some time-lapse micrographs in Staiger et al. (2009) imply the existence of a similar phenomenon in A. thaliana. It would be interesting in a future study to investigate the molecular mechanisms underlying the actin filament dynamics.
|
Intriguingly, we did not observe definitive cytoplasmic streaming, even in cells with highly dynamic actin filaments. This was surprising, because actin–myosin-dependent cytoplasmic streaming is generally observed in other plants, from charophytes to angiosperms (Shimmen and Yokota 1994
). From this observation, we can speculate that the actin–myosin system might have distinctive functions in M. polymorpha. Further analysis of actin involvement in various physiological events, including organelle motility, cell morphogenesis and cell division, might reveal novel functional roles for actin in M. polymorpha. In addition, future investigations could compare the dynamics and function of actin among different plant lineages. It might be particularly insightful to compare the previous model bryophyte, Physcomitrella patens, with M. polymorpha. The unique characteristics of Lifeact, particularly its conveniently small size, will facilitate future studies. |
Materials and Methods |
|---|
|
TopAbstractIntroductionResults and DiscussionMaterials and MethodsSupplementary dataFundingAcknowledgmentsReferences |
|---|
Plant materials and growth conditions
Seeds of A. thaliana (accession Col-0) were surface-sterilized and plated on Murashige and Skoog medium [x 1 Murashige–Skoog salt mixture, 1% (w/v) sucrose, 0.01% (w/v) myoino-sitol and 0.5% (w/v) gellangum, pH 5.8], incubated for 4 d at 4°C in the dark, and grown in a growth chamber under continuous light at 23°C. Seedlings were transferred to soil and grown in a temperature-controlled (23°C) growth room under continuous light.
Marchantia polymorpha was asexually maintained and propagated through gemma growth as previously described (Okada et al. 2000, Takenaka et al. 2000).
Construction and transformation of plants
The chimeric gene encoding Lifeact–Venus was generated by PCR using the following primers: 5'-CACCATGGGTG TCGCAGATTTGATCAAGAAATTCGAAAGCATCT CAAAGGAAGAAGGCGGCAGCGGCATGGTGAG CAAGGGCGAGGA-3' and 5'-TTACTTGTACAGCTCGTC CA-3'. The forward primer contained the whole sequence for Lifeact and linker peptides. The PCR product was cloned into the pENTR vector (Invitrogen, Carlsbad, CA, USA), and then transferred by recombination into the pGWB2 binary vector containing the CaMV 35S promoter (a kind gift from T. Nakagawa). The transformation of A. thaliana plants was performed by floral dipping using A. tumefaciens (strain GV3101::pMP90) (Clough and Bent 1998). Transgenic plants with the T-DNA in one locus were selected, and homozygous or hemizygous T2 plants were observed. The transformation of M. polymorpha was performed by the co-cultivation of immature thalli with A. tumefaciens (strain GV3101 : : pMP90) carrying the binary vector as described previously (Ishizaki et al. 2008).
Drug treatments
Young thalli approximately 5 mm at the longest diameter were treated for 2 h at room temperature with 30 mM BDM (Wako Pure Chemical Industries, Osaka, Japan) or 4 µM BA (Sigma) dissolved in water.
Microscopy
For the observation of actin filaments visualized by Lifeact–Venus in A. thaliana and M. polymorpha, samples were observed under a fluorescence microscope (model BX51; Olympus, Tokyo, Japan) equipped with a confocal scanner unit (model CSU10, Yokogawa Electric, Tokyo, Japan) and cooled CCD camera (model ORCA-AG or ORCA-ER, Hamamatsu Photonics, Hamamatsu, Japan). Serial confocal images were obtained every 0.5 µm. Images were processed with the IPLab (BD Biosciences, Rockville, MD, USA) or iVision Mac (BioVision Technologies, Exton, PA, USA) software, and projection images were constructed using VoxBlast (VayTek, Fairfield, IA, USA) or ImageJ software (http://rsb.info.nih.gov/ij/).
For the double labeling of actin filaments with Lifeact–Venus and rhodamine–phalloidin in A. thaliana, 4-day-old A. thaliana plants expressing Lifeact–Venus were fixed with 4% paraformaldehyde in MTSB (50 mM PIPES, 5 mM MgSO4, 5 mM EGTA, pH 7.0) for 1 h at room temperature. Fixed plants were rinsed with wash buffer (0.1% Triton X-100 in MTSB) three times and then with distilled water three times. The samples were then treated with 2% driserase (Sigma) in MTSB for 40 min at room temperature, rinsed with wash buffer three times and treated with MTSB plus 10% dimethylsulfoxide (DMSO) and 3% NP-40 for 1 h. After rinsing with wash buffer, samples were stained with 100 nM rhodamine–phalloidin (Molecular Probes, Eugene, OR, USA) in MTSB for 20 min. After rinsing with wash buffer, samples were mounted on a glass slide in MTSB and observed under a confocal microscope (model LSM510; Carl Zeiss, Tokyo, Japan). Actin filaments in M. polymorpha expressing Lifeact–Venus were double-stained by phalloidin conjugated to Alexa Fluor 568. Young thalli were fixed with 2% glycerol PMEG [50 mM PIPES, 1 mM MgSO4, 5 mM EGTA and 2% (v/v) glycerol, pH 6.8] for 1 h, washed three times in phosphate-buffered saline (PBS), stained with 165 nM Alexa Fluor 568–phalloidin in PBS, and then observed using a confocal microscope (model LSM710, Carl Zeiss, Tokyo, Japan).
|
Supplementary data |
|---|
|
TopAbstractIntroductionResults and DiscussionMaterials and MethodsSupplementary dataFundingAcknowledgmentsReferences |
|---|
Supplementary data are available at PCP online.
|
Funding |
|---|
|
TopAbstractIntroductionResults and DiscussionMaterials and MethodsSupplementary dataFundingAcknowledgmentsReferences |
|---|
The Ministry of Education, Culture, Sports, Science and Technology of Japan Grants-in-Aid for Scientific Research and the Targeted Proteins Research Program (TPRP) (to A.N. and T.U.); Japan Society for the Promotion of Science research fellowship for young scientists (No. 195010 to K.E.).
|
Acknowledgments |
|---|
|
TopAbstractIntroductionResults and DiscussionMaterials and MethodsSupplementary dataFundingAcknowledgmentsReferences |
|---|
We thank Dr. Tsuyoshi Nakagawa (Shimane University) for providing the pGWB2 vector.
|
References |
|---|
|
TopAbstractIntroductionResults and DiscussionMaterials and MethodsSupplementary dataFundingAcknowledgmentsReferences |
|---|
Bowman JL, Floyd SK, Sakakibara K. Green genes—comparative genomics of the green branch of life. Cell (2007) 129:229–234.[CrossRef][Web of Science][Medline]
Cheung AY, Wu HM. Overexpression of an Arabidopsis formin stimulates supernumerary actin cable formation from pollen tube cell membrane. Plant Cell (2004) 16:257–269.
Clough SJ, Bent AF. Floral dip: a simplified method for Agrobacterium-mediated transformation of Arabidopsis thaliana. Plant J. (1998) 16:735–743.[CrossRef][Web of Science][Medline]
Funaki K, Nagata A, Akimoto Y, Shimada K, Ito K, Yamamoto K. The motility of Chara corallina myosin was inhibited reversibly by 2,3-butanedione monoxime (BDM). Plant Cell Physiol. (2004) 45:1342–1345.
Gu Y, Fu Y, Dowd P, Li S, Vernoud V, Gilroy S, et al. A Rho family GTPase controls actin dynamics and tip growth via two counteracting downstream pathways in pollen tubes. J. Cell Biol. (2005) 169:127–138.
Hasezawa S, Kumagai F. Dynamic changes and the role of the cytoskeleton during the cell cycle in higher plant cells. Int. Rev. Cytol. (2002) 214:161–191.[Web of Science][Medline]
Higaki T, Kutsuna N, Okubo E, Sano T, Hasezawa S. Actin microfilaments regulate vacuolar structures and dynamics: dual observation of actin microfilaments and vacuolar membrane in living tobacco BY-2 cells. Plant Cell Physiol. (2006) 47:839–852.
Higaki T, Kutsuna N, Sano T, Hasezawa S. Quantitative analysis of changes in actin microfilament contribution to cell plate development in plant cytokinesis. BMC Plant Biol. (2008) 8:80.[CrossRef][Medline]
Higaki T, Sano T, Hasezawa S. Actin microfilament dynamics and actin side-binding proteins in plants. Curr. Opin. Plant Biol. (2007) 10:549–556.[CrossRef][Web of Science][Medline]
Holweg CL. Living markers for actin block myosin-dependent motility of plant organelles and auxin. Cell Motil. Cytoskel. (2007) 64:69–81.[CrossRef][Web of Science][Medline]
Holweg C, Susslin C, Nick P. Capturing in vivo dynamics of the actin cytoskeleton stimulated by auxin or light. Plant Cell Physiol. (2004) 45:855–863.
Hussey PJ, Ketelaar T, Deeks MJ. Control of the actin cytoskeleton in plant cell growth. Annu. Rev. Plant Biol. (2006) 57:109–125.[CrossRef][Medline]
Ishizaki K, Chiyoda S, Yamato KT, Kohchi T. Agrobacterium-mediated transformation of the haploid liverwort Marchantia polymorpha L. an emerging model for plant biology. Plant Cell Physiol. (2008) 49:1084–1091.
Ketelaar T, Anthony RG, Hussey PJ. Green fluorescent protein–mTalin causes defects in actin organization and cell expansion in Arabidopsis and inhibits actin depolymerizing factor’s actin depolymerizing activity in vitro. Plant Physiol. (2004) 136:3990–3998.
Ketelaar T, Emons MC. The cytoskeleton in plant cell growth: lessons from root hairs. New Phytol. (2001) 152:409–418.[CrossRef][Web of Science]
Kost B, Spielhofer P, Chua NH. A GFP–mouse talin fusion protein labels plant actin filaments in vivo and visualizes the actin cytoskeleton in growing pollen tubes. Plant J. (1998) 16:393–401.[CrossRef][Web of Science][Medline]
Mathur J, Mathur N, Kernebeck B, Hulskamp M. Mutations in actin-related proteins 2 and 3 affect cell shape development in Arabidopsis. Plant Cell (2003) 15:1632–1645.
Michelot A, Berro J, Guerin C, Boujemaa-Paterski R, Staiger CJ, Martiel JL, et al. Actin-filament stochastic dynamics mediated by ADF/cofilin. Curr. Biol. (2007) 17:825–833.[CrossRef][Web of Science][Medline]
Miller DD, de Ruijter NCA, Bisseling T, Emons AMC. The role of actin in root hair morphogenesis: studies with lipochito-oligosaccharide as a growth stimulator and cytochalasin as an actin perturbing drug. Plant J. (1999) 17:141–154.[CrossRef][Web of Science]
Okada S, Fujisawa M, Sone T, Nakayama S, Nishiyama R, Takenaka M, et al. Construction of male and female PAC genomic libraries suitable for identification of Y-chromosome-specific clones from the liverwort, Marchantia polymorpha. Plant J. (2000) 24:421–428.[CrossRef][Web of Science][Medline]
Riedl J, Crevenna AH, Kessenbrock K, Yu JH, Neukirchen D, Bista M, et al. Lifeact: a versatile marker to visualize F-actin. Nat. Methods (2008) 5:605–607.[CrossRef][Web of Science][Medline]
Schaefer AW, Kabir N, Forscher P. Filopodia and actin arcs guide the assembly and transport of two populations of microtubules with unique dynamic parameters in neuronal growth cones. J. Cell Biol. (2002) 158:139–152.
Sheahan MB, Staiger CJ, Rose RJ, McCurdy DW. A green fluorescent protein fusion to actin-binding domain 2 of Arabidopsis fimbrin highlights new features of a dynamic actin cytoskeleton in live plant cells. Plant Physiol. (2004) 136:3968–3978.
Shimmenm T, Yokota E. Physiological and biochemical aspects of cytoplasmic streaming. Int. Rev. Cytol. (1994) 155:97–139.[CrossRef][Web of Science]
Staiger CJ, Sheahan MB, Khurana P, Wang X, McCurdy DW, Blanchoin L. Actin filament dynamics are dominated by rapid growth and severing activity in the Arabidopsis cortical array. J. Cell Biol. (2009) 184:269–280.
Takenaka M, Yamaoka S, Hanajiri T, Shimizu-Ueda Y, Yamato KT, Fukuzawa H, et al. Direct transformation and plant regeneration of the haploid liverwort Marchantia polymorpha L. Transgenic Res. (2000) 9:179–185.[CrossRef][Web of Science][Medline]
Tominaga M, Yokota E, Sonobe S, Shimmen T. Mechanism of inhibition of cytoplasmic streaming by a myosin inhibitor, 2,3-butanedione monoxime. Protoplasma (2000) 213:46–54.[CrossRef][Web of Science]
Voigt B, Timmers AC, Samaj J, Muller J, Baluska F, Menzel D. GFP–FABD2 fusion construct allows in vivo visualization of the dynamic actin cytoskeleton in all cells of Arabidopsis seedlings. Eur. J. Cell Biol. (2005) 84:595–608.[CrossRef][Web of Science][Medline]
Westphal M, Jungbluth A, Heidecker M, Muhlbauer B, Heizer C, Schwartz JM, et al. Microfilament dynamics during cell movement and chemotaxis monitored using a GFP–actin fusion protein. Curr. Biol. (1997) 7:176–183.[CrossRef][Web of Science][Medline]
Yoneda A, Kutsuna N, Higaki T, Oda Y, Sano T, Hasezawa S. Recent progress in living cell imaging of plant cytoskeleton and vacuole using fluorescent-protein transgenic lines and three-dimensional imaging. Protoplasma (2007) 230:129–139.[CrossRef][Web of Science][Medline]
(Received April 2, 2009; Accepted April 10, 2009)
CiteULike 
Connotea 
Del.icio.us What's this?
| ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||