Autorzy
Skontaktuj Się z Nami

Zaloguj się

Aby wyświetlić tę treść, wymagana jest subskrypcja JoVE. Zaloguj się lub rozpocznij bezpłatny okres próbny.

W tym Artykule

  • Podsumowanie
  • Streszczenie
  • Wprowadzenie
  • Protokół
  • Wyniki
  • Dyskusje
  • Ujawnienia
  • Podziękowania
  • Materiały
  • Odniesienia
  • Przedruki i uprawnienia

Podsumowanie

This manuscript describes an in vitro ovule cultivation method that enables live-cell imaging of Arabidopsis zygotes and embryos. This method is utilized to visualize the intracellular dynamics during zygote polarization and the cell fate specification in developing embryos.

Streszczenie

In most flowering plants, the zygote and embryo are hidden deep in the mother tissue, and thus it has long been a mystery of how they develop dynamically; for example, how the zygote polarizes to establish the body axis and how the embryo specifies various cell fates during organ formation. This manuscript describes an in vitro ovule culture method to perform live-cell imaging of developing zygotes and embryos of Arabidopsis thaliana. The optimized cultivation medium allows zygotes or early embryos to grow into fertile plants. By combining it with a poly(dimethylsiloxane) (PDMS) micropillar array device, the ovule is held in the liquid medium in the same position. This fixation is crucial to observe the same ovule under a microscope for several days from the zygotic division to the late embryo stage. The resulting live-cell imaging can be used to monitor the real-time dynamics of zygote polarization, such as nuclear migration and cytoskeleton rearrangement, and also the cell division timing and cell fate specification during embryo patterning. Furthermore, this ovule cultivation system can be combined with inhibitor treatments to analyze the effects of various factors on embryo development, and with optical manipulations such as laser disruption to examine the role of cell-cell communication.

Wprowadzenie

The basic body plan of an organism develops from a unicellular zygote. In most flowering plants, zygotic division generates an apical and a basal cell, which develop into the shoot and root, respectively1. Therefore, it is important to understand how the plant body is formed during embryogenesis, but there has not been an effective tool to directly observe the dynamics of living zygotes and embryos because they develop deep in the flower. In several monocot species, such as maize and rice, an in vitro fertilization method has been established2,3. In this method, isolated sperm and egg cells are fused electrically or chemically, and the generated cell can develop into a fertile plant. However, in dicot plants, there is no in vitro fertilization method that can produce proper embryos, presumably because of the non-synchronized cell cycle state of male and female gametes4,5. In addition, the embryo-surrounding tissue (endosperm) plays important roles in embryo development6.

In a model dicot species, A. thaliana, an in vitro cultivation method was developed by focusing on the whole ovule, which contains both the embryo and endosperm7. This system was successfully used to analyze the effects of various chemical reagents on embryogenesis, but it is not suitable for time-lapse imaging because it has a low survival rate. Therefore, a novel in vitro ovule cultivation system was developed in order to start as early as the zygote stage and produce fertile plants at a high ratio8. After various trials, it was found that Nitsch medium and trehalose significantly improved the survival rate of ovules8. In addition, because the ovule expands as it grows and thus frequently moves away from the observation field of the microscope, a PDMS device was developed to fix the ovule in the medium9. The PDMS device enabled the long-term imaging for 3 - 4 days, which is sufficient to trace the development from a zygote to a heart-stage embryo. Using this method, it becomes possible to visualize the dynamics of zygote polarization and embryo patterning, not only under normal conditions, but also in the presence of chemical inhibitors or in various mutant backgrounds8,10,11.

figure-introduction-2699
Figure 1: Schematic Diagram of the Specific Fluorescent Markers used to Visualize Zygotes and Embryos Through the Ovule.
The Arabidopsis zygote develops into an embryo in the ovule, which is generated deep inside the flower. In this in vitro cultivation system, the zygote and embryo are observed through the ovule, and thus it is important to use specific fluorescent markers that are not expressed in other ovule tissues. Please click here to view a larger version of this figure.

Protokół

1. Preparation of the In Vitro Ovule Culture Medium

  1. Make the liquid medium forthe in vitro ovule culture ("N5T medium") containing 1x Nitsch basal salt mixture, 5% (w/v) trehalose dihydrate, 0.05% (w/v) 2-(N-morpholino)ethanesulfonic acid (MES)-KOH (pH 5.8), and 1x Gamborg's vitamin solution.
  2. Adjust the pH to 5.8 with KOH.
  3. Sterilize the medium by autoclaving it (121 °C, 20 min) or filtering it through a 0.22-µm filter.
    NOTE: The sterilized medium can be stored at 4 °C for 2 - 3 months.

2. Preparation of the PDMS Micropillar Array Device

  1. Cut the PDMS micropillar device by a knife, razor blade or scissors to fit into the glass part (14 mm φ) of a 35 mm glass-bottom dish.
    NOTE: The full procedure of the PDMS device construction is described in previous papers8,9, and thus the details are omitted here. Glass-bottom dishes with smaller volumes, such as 4-well or 96-well plates, can be used for short-term imaging without the device.
  2. Sterilize the upper side of the PDMS device under UV light for 15 min.
  3. Turn the PDMS device over by using square tip tweezers, and keep it under UV light for 15 min to sterilize the bottom.
  4. Transfer the sterilized PDMS device into a 35 mm culture dish and add the N5T medium until the device is completely soaked in the medium (approximately 5 - 7 mL).
  5. Put the dish into a vacuum chamber, and reduce the pressure to degas. Keep vacuuming for 3 h to overnight until the air in the device is replaced by medium.
    NOTE: The device can be detached by air bubbles under a strong vacuum.
  6. Take the device from the dish by holding it with square tip tweezers and put it on a paper towel to remove the extra medium on the side and bottom.
    NOTE:The medium on the micropillar array (upper surface) should not be removed because this will be used for the ovule cultivation.
  7. Transfer the device onto a 76 mm x 26 mm slide glass, ensuring to keep the micropillar part as the upper side, and cover the device with 35 mm culture dish lid to prevent the medium from drying out during the following ovule extraction.

3. Silique Dissection and Ovule Extraction

  1. Sterilize a needle (0.40 mm G) and fine tweezers by wiping with 70% ethanol. The needle is easily handled by attaching it to a syringe or wood stick.
  2. Check the inflorescence of the plant, and select the proper siliques for the experiment. The approximately 5 mm siliques contain zygotes, and the 8 - 10 mm siliques include young globular embryos.
  3. Excise the siliques by using tweezers, and place them on double-sided tape on a 76 x 26 mm slide glass. One silique contains about 40 - 60 ovules, and 3 - 4 siliques (i.e., 120 - 240 ovules) are sufficient for one device.
  4. Open the silique (ovary wall) to see the ovules inside using the sterilized needle and tweezers under a stereomicroscope. Cut only the ovary wall so that the ovules are not damaged.
  5. Transfer the opened silique into the N5T medium on the PDMS device (prepared in step 2.7), and release the ovules into the medium with the needle or tweezers.
  6. Put a small cover glass (18 mm x 18 mm) onto the PDMS device to push the ovules into the spaces in the micropillar array.
  7. Take the cover glass off by pulling it horizontally using tweezers or fingers to remove extra medium.
  8. Turn the PDMS device upside down, place it into a 35 mm glass-bottom dish, and slightly press the device by pushing using the square tip tweezers to stick it to the glass.
  9. Pour N5T medium gently into the glass-bottom dish by decanting the medium bottle until the PDMS device is completely soaked in the medium, and seal the dish with paraffin film.
    NOTE: The PDMS device can be recycled, but devices that are too old are easily detached from the glass bottom. Additionally, the device may float if it is not completely degassed in step 2.5 or the medium is poured too quickly.

figure-protocol-4305
Figure 2: Schematic Procedure for Sample Preparation.
This schematic flow corresponds to steps 3.5 to 4.1. Please click here to view a larger version of this figure.

4. Time-lapse Imaging

  1. Place the glass-bottom dish that was prepared in step 3.9 on an inverted microscope, and select suitable ovules to focus on.
    NOTE: Because the ovules vary in stage, position, and direction, suitable ovules should be found by checking their marker fluorescence.
  2. Start the live-imaging according tothe manufacturer's instructions of the microscope system.
    NOTE: The microscope equipment and parameters are diverse, and thus the users should choose the proper settings that fit to the experiment purpose. As an example, the settings used in this manuscript are listed in Table 1.
Equipment/settingFigure 3 (A) and Supplemental Videos 1 and 4Figure 3 (B) and Supplemental Video 2Supplemental Video 3
Microscopelaser-scanning inverted microscope (A1R MP)spinning-disk confocal inverted microscope (CSU-W1)box-type inverted confocal microscope system with a stable incubation chamber (CV1000)
LaserTi:sapphire femtosecond pulse laser488-nm and 561-nm LD lasers488-nm and 561-nm LD laser
Objective lens 40X water-immersion objective lens (NA = 1.15) with immersion medium60X silicone oil immersion objective lens (NA = 1.30), mounted on a Piezo focus drive40X objective lens (NA = 0.95)
Detectorexternal non-descanned GaAsP PMT detectorEMCCD cameraEMCCD camera
Dichroic mirrorDM495 and DM560DM488/561DM400-410/488/561
Filterband-pass filters; 534/30 nm and 578/105 nmband-pass filters; 520/35 nm, and 593/46 nmband-pass filters; 520/50 nm and 617/73 nm
Slice along z-axis31 z-stacks with 1-µm intervals17 z-stacks with 3-µm intervals7 z-stacks with 5-µm intervals
Time interval20 min5 min10 min

Table 1: The Microscope Systems and Settings Used in This Manuscript.
The microscopes and parameters are diverse, and thus each user should choose the suitable system for the experiment.

  1. Check the acquired image sequence, and convert it to the general movie format, such as .avi or .mov for presentation.
    NOTE: If the microscope software cannot output the images as a movie format, it is possible to save the images as .tif and then open them in ImageJ, an open source program inspired by NIH Image, to change the file type. ImageJ is provided at: https://imagej.nih.gov/ij/. ImageJ can also be used to make a Z-stuck movie, such as the maximum-intensity projection, as described at: https://imagej.net/Z-functions.

Wyniki

By using this ovule cultivation system, this method can trace the living dynamics of zygote polarization and embryo patterning. This is an achievement because previously there was no technique to visualize the real-time behavior of the zygote and embryo, which are hidden deep in the mother tissue. Figure 3A and Supplemental Video 1 show that the microtubules (MTs) in the young zygote accumulate as a transverse ring in the subapical region

Dyskusje

This manuscript introduces a simple in vitro ovule cultivation protocol that is efficient for use in the live-cell imaging of developing zygotes and embryos.

The design of the PDMS device may need optimization according to the embryo stage. The first developed device was a microcage array to adjust the orientation and to fix the position of the ovules9, and then a micropillar device was constructed to trap ovules more efficiently8. Furth...

Ujawnienia

The authors have nothing to disclose.

Podziękowania

Microscopy in this work was conducted at the Institute of Transformative Bio-Molecules (WPI-ITbM) of Nagoya University and supported by the Japan Advanced Plant Science Network. This work was supported by grants from the Japan Science and Technology Agency (ERATO project to T.H. and M.U.) and from the Japan Society for the Promotion of Science: a Grant-in-Aid for Scientific Research on Innovative Areas (Nos. JP24113514, JP26113710, JP15H05962, and JP15H05955 for M.U., and Nos. JP16H06465, JP16H06464 and JP16K21727 for T.H), a Grant-in-Aid for Young Scientists (B, Nos. JP24770045 and JP26840093 for M.U.), and a Grant-in-Aid for challenging Exploratory Research (No. JP16K14753 for M.U.).

Materiały

NameCompanyCatalog NumberComments
Nitsch basal salt mixtureDuchefaN0223
trehalose dihydrateWako Pure Chemical206-18455
MESDojindo345-01625
Gamborg’s vitamin solutionSigma-AldrichG1019
35-mm glass-bottom dishMatsunami GlassD111300
35 mm culture dishCorning430588
PDMSDow Corning Co.Sylgard184
76 × 26 mm slide glassMatsunami GlassS1225
18 × 18 mm slide glassMatsunami GlassC018181
needle (gauge 0.40mm)TerumoNN-2719S
Immersion medium Immersol W 2010Zeiss444969-0000-000
A1R MPNikonA1RsiMP(1080) Ti-E-TIRF
CSU-W1Yokogawa ElectricIt is a customized equipment, and thus Catalog Number is not avairable.
CV1000Yokogawa ElectricCV1000-SP84

Odniesienia

  1. Natesh, S., Rau, M. A., Johri, B. M. . Embryology of Angiosperms. , 377-443 (1984).
  2. Kranz, E., Lorz, H. In vitro fertilisation of maize by single egg and sperm cell protoplast fusion mediated by high calcium and high pH. Zygote. 2 (2), 125-128 (1994).
  3. Uchiumi, T., Uemura, I., Okamoto, T. Establishment of an in vitro fertilization system in rice (Oryza sativa L.). Planta. 226 (3), 581-589 (2007).
  4. Sun, M. X., Moscatelli, A., Yang, H. Y., Cresti, M. In vitro double fertilization in Nicotiana tabacum (L.): the role of cell volume in cell fusion. Sex Plant Rep. 13 (4), 225-229 (2001).
  5. Tian, H. Q., Yuan, T., Russell, S. D. Relationship between double fertilization and the cell cycle in male and female gametes of tobacco. Sex Plant Rep. 17 (5), 243-252 (2004).
  6. Costa, L. M., et al. Central cell-derived peptides regulate early embryo patterning in flowering plants. Science. 344 (6180), 168-172 (2014).
  7. Sauer, M., Friml, J. In vitro culture of Arabidopsis embryos within their ovules. Plant J. 40 (5), 835-843 (2004).
  8. Gooh, K., et al. Live-cell imaging and optical manipulation of Arabidopsis early embryogenesis. Dev Cell. 34 (2), 242-251 (2015).
  9. Park, J., Kurihara, D., Higashiyama, T., Arata, H. Fabrication of microcage arrays to fix plant ovules for long-term live imaging and observation. Sens Act B-Chem. 191, 178-185 (2014).
  10. Kimata, Y., et al. Cytoskeleton dynamics control the first asymmetric cell division in Arabidopsis zygote. Proc Natl Acad Sci U S A. 113 (49), 14157-14162 (2016).
  11. Nambo, M., et al. Combination of Synthetic Chemistry and Live-Cell Imaging Identified a Rapid Cell Division Inhibitor in Tobacco and Arabidopsis thaliana. Plant Cell Physiol. 57 (11), 2255-2268 (2016).
  12. Mizuta, Y., Kurihara, D., Higashiyama, T. Two-photon imaging with longer wavelength excitation in intact Arabidopsis tissues. Protoplasma. 252 (5), 1231-1240 (2015).

Przedruki i uprawnienia

Zapytaj o uprawnienia na użycie tekstu lub obrazów z tego artykułu JoVE

Zapytaj o uprawnienia

Przeglądaj więcej artyków

Keywords In Vitro Ovule CultivationLive cell ImagingZygote PolarizationEmbryo PatterningArabidopsis ThalianaPDMS Micropillar ArrayN5T MediumSilique DissectionOvule TransferCover Glass

This article has been published

Video Coming Soon

JoVE Logo

Prywatność

Warunki Korzystania

Zasady

Skontaktuj Się z Nami

Poleć Bibliotece

BIULETYNY JoVE

Badania

Edukacja

Autorzy

Bibliotekarze

O JoVE

Copyright © 2025 MyJoVE Corporation. Wszelkie prawa zastrzeżone