Mass Spectrometry: Difference between revisions

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=== Calculate the expected molecular weight for the NC5 and NC sample  ===
=== Calculate the expected molecular weight for the NC5 and NC sample  ===
<br>


[http://www.scripps.edu/~cdputnam/protcalc.html Protein Calculator] is a nice tool that allows to calculate molecular mass of isotopically labeled proteins  
[http://www.scripps.edu/~cdputnam/protcalc.html Protein Calculator] is a nice tool that allows to calculate molecular mass of isotopically labeled proteins  


<br>Another way to calculate the molecular weight for a protein is using the [http://ca.expasy.org/tools/protparam.html ExPASY ProtParam] tool. Just paste your sequence into the web form. The atomic composition at the bottom of the results can be used to correct for the isotopic enrichment as in the examples below.  
<br>Another way to calculate the molecular weight for a protein is using the [http://ca.expasy.org/tools/protparam.html ExPASY ProtParam] tool. Just paste your sequence into the web form. The atomic composition at the bottom of the results can be used to correct for the isotopic enrichment as in the examples below.


=== Examples  ===
=== Examples  ===

Revision as of 16:12, 10 November 2009

Compare Mass Spectrometry m/z with Calculated Protein Mass

Mass Spectrometry Results from SPINE


The mass spectrum chromatogram for many of the purified samples is noted in SPINE:

  • Go to the Purification Batch page from the target page in SPINE for the sample
  • Go to the “Link to Mass Spectrum Image”
  • The peaks should correspond to your full-length protein mass.
  • The red information across the top is the base peak, BP (the peak with the greatest intensity), followed by the intensity
  • The other peaks are typically m/z (mass-to-charge ratio) with z = 2+, 1/2+, 1/3+, etc.
  • At Rutgers, spectra are collected on a MALDI-TOF/TOF (ABI-MDS SCIEX 4800) in single TOF mode.  Samples are prepared by mixing 1 ul of the final protein NMR sample with 10 ul of sinapinic acid (SA) matrix solution (10 mg/ml SA in 50% ACN/50% 0.1% TFA).


There will typically be mass spectrometry data for each NC5 sample, NC sample,and unlabelled sample. Error bars for this measurement are typically < 25 Da, but can be more.


Some reasons that the MS mass may not match your calculated mass are:

  1. The MS results might have large error because of instrument or calibration problems (unlikely).
  2. The sequence in the database is incorrect.
  3. There are mutations in your protein (very common).
  4. The protein has covalent modifications.
  5. Protein degradation occurs.
  6. The N-terminal methionine is cleaved in the E.coli due to N-terminal methione excision (NME) by methione aminopeptidases (MAPs).

Example Mass Spectrum of TaR80B

http://spine.nesg.org/batch.cgi?id=TaR80B-21.2-NCa-GF (password protected)

MS TaR80Bjpg.jpeg

N-terminal Methionine Cleavage


The propensity for cleavage has been analyzed in a 2006 bioinformatics paper by Frottin et al.:[1]



In summary, N-Met cleavage is:

  • Very likely if the second residue is: A, C, G, or P
  • Not likely if the second residue is V or T.
  • There are other more complicated influences from the 3rd and 4th residue.
  • Overexpressed proteins are less likely to be cleaved than less highly expressed proteins.

They developed a bioinformatics tool for prediction called TermiNator (also available through ExPASY):

Use these Terminator options for proteins overexpressed in E.coli:

  • expressed in: Prokaryote (Eubacteria or Archea)
  • Eubacteria
  • Recombinant, plasmid-encoded, overexpressed gene
  • LPR cleavage (leader peptide cleavage) – No
  • Paste your sequence

Calculate the expected molecular weight for the NC5 and NC sample


Protein Calculator is a nice tool that allows to calculate molecular mass of isotopically labeled proteins


Another way to calculate the molecular weight for a protein is using the ExPASY ProtParam tool. Just paste your sequence into the web form. The atomic composition at the bottom of the results can be used to correct for the isotopic enrichment as in the examples below.

Examples

FR629A example (no N-met cleavage)


MGHHHHHHSHGKSDFIKVNVSNSHNDAVAFEVKLAKDLTVAQLKTKLEILTGGCAGTMKVQVFKGDTCVSTMDNNDAQLGYYANSDGLRLHVVDS

FR629A has the following ProtParam results:
Molecular weight: 10343

Atomic composition:
Carbon C 447
Nitrogen N 133

So, the calculated MWs are:
Unlabeled: 10343 Da
NC5: 10343 + (133 Da for 15N) + (0.05 x 447 Da for 13C) = 10500 Da
NC: 10343 + (133 Da for 15N) + (447 Da for 13C) = 10923 Da

From Spine, the MS results are:
NC5a: 10488 Da (-11 Da from expected)
NC5c: 10497 Da (-3 Da from expected)
NCa: 10915 Da (+ 8 Da from expected)

This is a good match. Terminator3 does not predict N-terminal Met cleavage, even though the second residue, Gly, makes it possible.

MbR242E example (with N-Met cleavage)


MAGQSDRKAALLDQVARVGKALANGRRLQILDLLAQGERAVEAIATATGMNLTTASANLQALKSGGLVEARREGTRQYYRIAGEDVARLFALVQVVADEHLEHHHHHH

MbR242E has the following ProtParam results:

Molecular weight: 11726

Atomic composition:
Carbon C 505
Nitrogen N 165

So, the calculated MWs are:
Unlabeled: 11726 Da
NC5: 11726 + (165 Da for 15N) + (0.05 x 505 Da for 13C) = 11916 Da
NC: 11726 + (165 Da for 15N) + (505 Da for 13C) = 12396 Da

From Spine, the MS results are:
LBa: 11592 Da (-134 Da from expected)
NC5a: 11779 Da (-137 Da from expected)
NC5c: 11775 Da (-141 Da from expected)
NCa: 12247 Da (-149 Da from expected)

Since unlabelled Met is 131 Da (and for NC5 is 134, and NC is 137 Da), it seems likely that the N-terminal Met is cleaved.

Note. Terminator3 does not predict N-terminal Met cleavage, even though the second residue, Ala, makes it possible.


References