1 / 11

HTP Structure Determination Using X-ray Crystallography

HTP Structure Determination Using X-ray Crystallography. MAD phasing with SeMet labeled proteins. What is Needed for HTP Structure Determination Using X-ray Crystallography?. X-ray quality mono-crystal Size >50x50x50 μm 3 Diffraction limit <3 Å

boyce
Download Presentation

HTP Structure Determination Using X-ray Crystallography

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. HTP Structure Determination Using X-ray Crystallography MAD phasing with SeMet labeled proteins

  2. What is Needed for HTP Structure Determination Using X-ray Crystallography? • X-ray quality mono-crystal • Size >50x50x50 μm3 • Diffraction limit <3 Å • Ordered “heavy atom” (Se, Br, U, Hg, Xe, La, etc) for MAD analysis • on average 1 “heavy atom”/50-150 residues • Cryo-protection • “Crystallization grade” protein must be produced in quantities that permit: • Achieving protein concentration in the range 5-25 mg/ml • Testing 2x102 - 5x102 crystallization conditions • Growing X-ray quality mono-crystals • Producing derivative of similar quality and quantity that contains a “heavy atom” for structure determination • Establishing cryo-conditions

  3. “Crystallization Grade” Quality #1 • Folded and soluble • Chemically and functionally homogeneous • As compact as possible • Flexible regions and affinity tags issues • In quantity and concentration suitable for crystallization experiments • Suitable for incorporation of a rational “heavy atom” for structure determination

  4. “Crystallization Grade” Quality #2 • Free of critical contaminants that: • degrade, denature, destabilize or modify protein • interfere with crystallization • interfere with structure determination • Stable during crystallization trails • Must be functionally relevant

  5. How to Get “Crystallization Grade” Protein? • Make your choice wisely – purification, concentration, storage and handling procedures play a critical role in obtaining “crystallization grade” protein samples • Quality of the protein sample depends on the method of preparation • Purification procedure should rapidly produce pure, homogeneous sample, however, a complete purity is not an absolute requirement for initial crystallization • Protein crystals are often obtained from mixtures • Crystallization was used to purify protein samples • Purification must be highly reproducible to supply milligram quantities of protein and its derivative containing “heavy atom”

  6. Post-Purification Handling of Protein Samples • Protein concentration method • Short and long term storage conditions • Cross-contaminations • Protein denaturation and loses • During freezing • On solvent/air interface • Due to binding to surfaces during concentration and storage • Due to aggregation • Screening for metal-binding and other ligands

  7. Characterization of Proteins for X-ray Crystallography • UV/VIS spectroscopy • Polyacrylamide gel electrophoresis (1D, 2D, N) • Dynamic and static light scattering • Circular dichroism spectroscopy • Mass spectroscopy • HSQC NMR spectroscopy • X-ray spectroscopy • Crystallization screens

  8. “Crystallization Grade” Quality Membrane Proteins • Requirements for membrane proteins are, in general, similar to soluble proteins, but present a number of specific challenges: • Protein denaturation and long-term stability in detergents, detergent exchange procedures • Quality of detergents • Reconstitution of proteins into membrane environments • Removing affinity tags in the presence of detergents • Introduction of “heavy atom(s)” into membrane proteins

  9. Challenges of Protein Sample Preparation Specific to HTP and Structural Genomics Projects • Large and diverse set of proteins: • From all three kingdoms of life • With low or no sequence similarity • With poorly characterized properties spanning a very wide range • Developing HTP universal procedures: “one size fits all” • Limited number of expression host strains and vectors • Widespread presence of codons infrequently used by the host • Host protein folding and assembly machinery is insufficient for folding of foreign proteins • A specific cofactor synthesis/import or post-translational modification function is missing in the host • Co-expression of a key interacting partner is missing • Errors in ORF annotation, domain assignment, sequencing etc • Introduction of heavy atom marker in vivo/in vitro is inefficient

  10. In some cases gene/protein sequence errors do not seemto cause a problem Sequence Errors Ser  Arg AGU  CGU His  Ile CAU  AUU

  11. Challenges of Protein Sample Preparation Specific to HTP and Structural Genomics Projects • Large scale requires parallel processing of multiple protein samples throughout all steps • Use LIMS to develop “database” driven procedures: • Maintaining large databases in “real time” • Database mining to improve/optimize methods and procedures • Assuring public access • Low cost

More Related