We demonstrate the fabrication of a low-cost cryogenic stage designed to fit most reflected light microscopes. This lab-built cryogenic stage enables efficient and reliable correlative imaging between cryo-light and cryo-electron microscopy.
The coupling of cryo-light microscopy (cryo-LM) and cryo-electron microscopy (cryo-EM) poses a number of advantages for understanding cellular dynamics and ultrastructure. First, cells can be imaged in a near native environment for both techniques. Second, due to the vitrification process, samples are preserved by rapid physical immobilization rather than slow chemical fixation. Third, imaging the same sample with both cryo-LM and cryo-EM provides correlation of data from a single cell, rather than a comparison of “representative samples”. While these benefits are well known from prior studies, the widespread use of correlative cryo-LM and cryo-EM remains limited due to the expense and complexity of buying or building a suitable cryogenic light microscopy stage. Here we demonstrate the assembly, and use of an inexpensive cryogenic stage that can be fabricated in any lab for less than $40 with parts found at local hardware and grocery stores. This cryo-LM stage is designed for use with reflected light microscopes that are fitted with long working distance air objectives. For correlative cryo-LM and cryo-EM studies, we adapt the use of carbon coated standard 3-mm cryo-EM grids as specimen supports. After adsorbing the sample to the grid, previously established protocols for vitrifying the sample and transferring/handling the grid are followed to permit multi-technique imaging. As a result, this setup allows any laboratory with a reflected light microscope to have access to direct correlative imaging of frozen hydrated samples.
1. Fabrication and Assembly
2. Sample Preparation
3. Cryo-Light Microscopy
4. Cryo-Electron Microscopy
5. Representative Results
The cryogenic stage (Fig 1a) is an effective way to gather cryo-LM data for cryo-fluorescence microscopy and correlative cryo-LM/cryo-EM analysis. Figure 2 shows how the combination of low and high magnification cryo-LM images allows you to build reference maps that direct you to specific areas in cryo-EM. The resulting cryo-LM reference map (Fig 2b) was utilized during cryo-EM data acquisition to locate exact regions shown in Figure 3.
Figure 1. Cryogenic Stage. a) The layout of the cryogenic stage consists of a cryo-grid box transfer mount indicated with a
white arrow and an aluminum heat sink. Grids are transferred under lN2 from the cryo-grid box and placed directly on the heat sink’s viewing area as
indicated by the black arrow. b) Image depicting the cryogenic stage with loading screen. The hole in the loading screen is placed directly
over the cryo-grid box mount and acts as a port to transfer samples and for moving samples from the cryo-grid box to the sample viewing area on the heat sink with
tweezers. c) The cryogenic stage in position under the objective lenses with the viewing screen in place. The special cutout on the viewing
screen allows the objective lenses to easily swing into position without moving the cryogenic stage. The hole in the viewing screen away from the sample area acts
as a lN2 fill port to replenish lN2 levels if necessary.
Figure 2. Navigating in cryo-LM for correlative studies. a) Low magnification cryo-LM view of yeast cells adhered to a sample
grid. b) The same image in (a) overlaid with a high magnification fluorescence image of an area of interest and with a filled orange polygon marking
the center of the sample grid. The center consists of a group of four squares, three having an extra metal tab and the forth open. For the three squares with an extra
metal tab, two pairs share the tab about the long and short axes forming an asymmetric center. This asymmetric center can be seen in the upper left corner and was used
to indicate the rotation angle and handedness of the grid between cryo-LM and cryo-EM. From one low magnification image many areas of interest can be marked and used as
a reference map to locate identical areas in cryo-EM. c) A magnified fluorescence cryo-LM image of the area of interest in (b). HTA1-CFP, a c-terminal
CFP histone marker, can be seen as a green punctate structure labeling the location of the nucleus. d) A cryo-EM image of the corresponding area in
(c). Scale bars represent 50 microns.
Figure 3. Correlation of cryo-LM and cryo-EM. Two fields of view depicting identical yeast cells correlated with cryo-bright field (a,d),
cryo-fluorescence (b,e), and cryo-EM (c,f). Scale bars represent 5 microns.
Using our cryogenic stage and sample preparation techniques, correlative studies between cryo-LM and cryo-EM exhibit several benefits over traditional room temperature approaches including, but not limited to: rapid fixation1,2, reduced photobleaching3, and scanning of sample integrity prior to cryo-EM4,5 or chemical fixation/embedding6. One of the bottlenecks for cryo-EM data collection is the time required for both transferring the sample into a TEM and scanning the grid to find suitable regions to image. With cryo-LM’s rapid data acquisition5, time spent finding good cells can be greatly reduced. Thus, we can save both time and money and mitigate this bottleneck by pre-scanning and mapping areas of interest in cryo-LM.
More expensive or complex cryogenic stages may allow higher resolution cryo-LM imaging. However, the stage fabricated here is more than adequate for many applications. If cryo-LM imaging and sample grid transfers are performed with caution as described in the text and video, fully contamination free imaging can be accomplished. This method allows direct correlation of fluorescent and electron microscopy data of the same cell, organelle or macromolecular complex dispersed on the carbon support or contained within a thin tissue section7. It should be noted that the value of this cryogenic stage extends beyond cryo-LM/cryo-EM correlative studies to the field of light microscopy as a whole. This cryogenic stage is well suited for both delicate samples and fluorophore dyes/stains8, Quantum Dots, or fluorescently tagged proteins9 that may be unstable during room temperature chemical fixation and embedding with glutaraldehyde and paraformaldehyde. As a result, we hope that this cryogenic stage will provide greater access to those interested in cryo-LM, who have been previously deterred by cost and insufficient access.
Troubleshooting Cryo-Light Microscopy
1. Sample Adsorption: Different samples can exhibit variable adsorption characteristics to the carbon support. You may find it necessary to use other types of support grids such as continuous carbon, holey carbon, or formvar coated grids for sample support. Additionally, if the sample is binding to the copper bars of the grid and not the carbon surface, it may be necessary to adjust the carbon surface chemistry by incubating the grid with a wetting agent or by glow discharging prior to sample addition.
2. Stage stability: If you notice vibration, it is likely due to the sample stage being overloaded with weight rather than the bubbling of lN2. The added weight of the cryogenic stage, can sometimes cause low frequency vibrations to transmit along the standard 3-axis travel microscope stage, and negatively affect imaging via blurring. This can easily be corrected by supporting the microscope’s travel stage from underneath with either an adjustable mini-lift or an adjustable adapter with dual-screw arms, as shown in the video. Both of these adjustable support mechanisms interact with a non-moveable portion of the travel stage and therefore still permits X and Y-axis translation as required for imaging.
The authors have nothing to disclose.
The authors wish to thank Brandon J. Zipp and Ken B. Kaplan for providing access to the yeast strain used in this study. The authors also thank Julio Lenin Dominguez-Ramirez for assistance with videotaping. J.E.E. acknowledges NIH funding support from grant number 5RC1GM91755.
Table of specific reagents and equipment:
Name | Company | Catalog # | Yorumlar | Cost |
---|---|---|---|---|
1 – 22.86 cm (9″) pie pan with sloped edge | Good Cook | Local grocery store | $4.39 | |
1 – 22.86 cm (9″) cake pan | Good Cook | Local grocery store | $4.93 | |
4 pairs of chopsticks | Local grocery store | $.50 | ||
1 – Great Stuff spray foam | Great Stuff | Local hardware store | $5.98 | |
1 – 4cm x8cm x1cm block of aluminum | Local hardware store or metal scrap yard | $10.00 | ||
5 – #10 1.91 cm (3/4″) flat head slotted bolts w/ nuts | Local hardware store | $0.98 | ||
3 – #4 0.95 cm (3/8″) round slotted bolts w/ nuts | Local hardware store | $0.98 | ||
15 – #10 washers | Local hardware store | $0.98 | ||
2 – transparent plastic clipboards | Local office store | $6.84 | ||
1 – Cryo-EM grid box holder | Ted Pella | 160-41 | N/A | |
1 – Cryo-EM grid box handling rod | Ted Pella | 160-46 | N/A | |
1 – R2/1 holey carbon film, 400-mesh copper cryo-EM support grid | SPI Supplies | 4340C-XA | N/A |
Experimental materials