Difference between revisions of "Main Page/BPHS 4090/Lysozyme Crystallization"

From Physics Wiki
Jump to navigation Jump to search
 
(9 intermediate revisions by 3 users not shown)
Line 96: Line 96:
 
<p>Describe the results! Do you see any trends? How many drops are clear? How many
 
<p>Describe the results! Do you see any trends? How many drops are clear? How many
 
drops have precipitate? Do any drops contain crystals?</p>
 
drops have precipitate? Do any drops contain crystals?</p>
 +
 +
<table width=500 align=left ><td>
 +
<p align=justify>[[File:Figure4_gallery.png|500px|center]]
 +
<br clear=right>
 +
</p>
 +
</td></table>
 +
<br style="clear: both" />
 +
 +
<h2>Protien Crystal Mounting</h2>
 +
<p>Many protein crystals are extremely sensitive to changes in temperature and
 +
surrounding conditions (i.e., presence of original solvent). As well, the protein crystals
 +
5
 +
undergo radiation damage upon exposure to X-rays. Therefore, the crystal must be
 +
flash-cooled to 100K in a stream of liquid nitrogen to prevent damage from the highintensity
 +
x-rays. Cryoprotectants such as glycerol are used to prevent freezing of the
 +
water surrounding the protein crystal which may destroy the protein crystal.</p>
 +
 +
<table width=300 align=left ><td>
 +
<p align=justify>[[File:Fig5_pins.png|300px|center]]
 +
<b>Figure 5:</b> Different pins containing a loop on the top end.
 +
<br clear=right>
 +
</p>
 +
</td></table>
 +
<br style="clear: both" />
 +
 +
<table width=300 align=left><td>
 +
<p align=justify>[[File:Fig6_mount.png|300px|center]]
 +
<b>Figure 6:</b> Using a pin to mount a crystal in a loop.
 +
<br clear=right>
 +
</p>
 +
</td></table>
 +
<br style="clear: both" />
 +
 +
<table width=300 align=left ><td>
 +
<p align=justify>[[File:Fig7_loop.png|300px|center]]
 +
<b>Figure 7:</b> Using a pin to mount a crystal in a loop observed through
 +
the microscope. The size of the crystal dictates the size of the loop. The crystal will be
 +
scooped into the loop and mounted on the goniometer head for diffraction analysis.
 +
<br clear=right>
 +
</p>
 +
</td></table>
 +
<br style="clear: both" />
 +
 +
<p>You will be given an opportunity to mount the lysozyme crystals into the loops during
 +
the lab.</p>
 +
 +
<table width=600 align=left ><td>
 +
<p align=justify>[[File:Fig8_setup.png|600px|center]]
 +
<b>Figure 8:</b> Showing the pin containing the protein crystal mounted on the goniometer head
 +
on the diffractometer.
 +
<br clear=right>
 +
</p>
 +
</td></table>
 +
<br style="clear: both" />
 +
 +
<p>You will test the diffraction potential of your lysozyme crystals using a Rigaku 007HF
 +
Microfocus X-ray machine equipped with a Saturn 944+ CCD.</p>
 +
 +
<p>Describe the results. What is the diffraction resolution of your lysozyme crystals? What
 +
is the space group?</p>

Latest revision as of 07:39, 19 July 2011

Introduction

Three-dimensional Protein Structures

X-Ray Crystallography

What is a Protein Crystal?

Suggested Reading:

Introduction to Macromolecular X-Ray Crystallography by Esko Oksanen and Adrian Goldman (Chapter 10 in Comprehensive Natural Products II Chemistry and Biology, Editors-in-Chief: Lew Mander and Hung-Wen (Ben) Liu ISBN: 978-0-08- 045382-8).

Alexander McPherson. Introduction to protein crystallization. Methods, 34, 254-265.

Protein X-Ray Crystallography Methods by Roger S. Rowlett, Department of Chemistry, Colgate University

Websites

Experimental

You will be provided with the pure protein (lysozyme) that you will be crystallizing. You will also be provided with the crystallization solution. In real life you perform crystallization trials with your homogeneously pure protein and examine your plates looking for protein crystals.

Crystallization Experiment I

Stock Solutions

Protein

Lysozyme at 25, 50, 75 and 100 mg/ml dissolved in 0.02 M sodium acetate pH 4.6

Lysozyme Crystallization Solution

  • 0.6 M sodium chloride
  • 0.1 M sodium acetate pH 4.6
  • 25% Glycerol

Procedure

Fig1 crystallization plate.png

Figure 1: Crystallization Plate


  1. Fill reservoirs with 500 μl of lysozyme crystallization solution.
  2. Add 1 μl of the crystallization solution to 1 μl of lysozyme on the cover.
  3. Figure2.png

    Figure 2


  4. Repeat for the remaining lysozyme concentrations. You should have 4 drops on each cover. Keep in mind where you place the different lysozyme concentrations by referring to the notch.
  5. Screw cover on reservoir.
  6. Repeat for the remaining reservoirs in your row.
  7. Incubate at room temperature.
  8. Observe and document conditions in drops with microscope immediately after setup and 1, 2 and 3 weeks later.

Describe the results! Do you see any trends? How many crystals do you see per drop? Which drop contains the largest crystals? Which drop contains the most crystals?

Describe Vapor Diffusion as it pertains to crystal growth.

Fig3 vapour diffusion.png

Figure 3: Well setup for crystal growth by the vapour diffusion method



Crystallization Experiment II

Stock Solutions

Protien

Lysozyme at 25, 50, 75 and 100 mg/ml dissolved in 0.02 M sodium acetate pH 4.6

Crystallization Conditions

Qiagen JCSG+ Screen

This crystallization screen contains 96 known solutions. You will use 24 of these conditions to setup an initial crystallization screen for the 4 different lysozyme concentrations.

Prepare the crystallization plate as above but remember to use a different crystallization condition in each well. The crystallization conditions are labeled 1-24. Each group will set up 6 different conditions in one row.

Observe and document the drops with microscope. Shown below are typical drop results. Most drops will be either clear (no crystals, no precipitate) or contain precipitate (protein).

Describe the results! Do you see any trends? How many drops are clear? How many drops have precipitate? Do any drops contain crystals?

Figure4 gallery.png



Protien Crystal Mounting

Many protein crystals are extremely sensitive to changes in temperature and surrounding conditions (i.e., presence of original solvent). As well, the protein crystals 5 undergo radiation damage upon exposure to X-rays. Therefore, the crystal must be flash-cooled to 100K in a stream of liquid nitrogen to prevent damage from the highintensity x-rays. Cryoprotectants such as glycerol are used to prevent freezing of the water surrounding the protein crystal which may destroy the protein crystal.

Fig5 pins.png

Figure 5: Different pins containing a loop on the top end.


Fig6 mount.png

Figure 6: Using a pin to mount a crystal in a loop.


Fig7 loop.png

Figure 7: Using a pin to mount a crystal in a loop observed through the microscope. The size of the crystal dictates the size of the loop. The crystal will be scooped into the loop and mounted on the goniometer head for diffraction analysis.


You will be given an opportunity to mount the lysozyme crystals into the loops during the lab.

Fig8 setup.png

Figure 8: Showing the pin containing the protein crystal mounted on the goniometer head on the diffractometer.


You will test the diffraction potential of your lysozyme crystals using a Rigaku 007HF Microfocus X-ray machine equipped with a Saturn 944+ CCD.

Describe the results. What is the diffraction resolution of your lysozyme crystals? What is the space group?