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== '''SSA with GLOMSA (GLObal Method for Stereospecific Assignment) Module''' ==
== '''Introduction''' ==


=== '''Overview'''  ===
GLOMSA (GLObal Method for Stereospecific Assignment) is performed with the preliminary conformers and using all the local and global experimental data. If there are two NOEs of significantly different strength from a given proton to both diastereotopic substituents of a prochiral center and if the distances from the given proton to the two diastereotopic substituents differ consistently in the structures, the stronger NOE can be identified with the diastereotopic substituent that is closer to the given proton.  
 
GLOMSA is performed with the preliminary conformers and using all the local and global experimental data. If there are two NOEs of significantly different strength from a given proton to both diastereotopic substituents of a prochiral center and if the distances from the given proton to the two diastereotopic substituents differ consistently in the structures, the stronger NOE can be identified with the diastereotopic substituent that is closer to the given proton.


[[Image:Glomsa1.jpg]]  
[[Image:Glomsa1.jpg]]  
Line 20: Line 18:
</nowiki> <br> Only those atoms are considered, for which the difference between two constraints is larger than <tt>cutoff</tt> (in Å) and the corresponding average distance difference in the bundle of structure is larger than <tt>threshold</tt>. The minimal percentage of structures in which the sign of the distance difference must be consistent must be larger than <tt>fraction</tt> (in percent).
</nowiki> <br> Only those atoms are considered, for which the difference between two constraints is larger than <tt>cutoff</tt> (in Å) and the corresponding average distance difference in the bundle of structure is larger than <tt>threshold</tt>. The minimal percentage of structures in which the sign of the distance difference must be consistent must be larger than <tt>fraction</tt> (in percent).


=== '''Running GLOMSA''' ===
== '''Running GLOMSA''' ==
 
#Copy the latest manual refinement directory.
#Download the sample [[Media:Run_glomsa.cya|run_glomsa.cya]] script
#Start CYANA 2.1 on a workstation and execute <tt>run_glomsa.cya</tt>. This will generate <tt>glomsa.out</tt> file.
#Analyze the output (here <tt>glomsa.out</tt>). For each stereospecific assignments verify that it is justified. Add confirmed assignments to the <tt>stereofound.cya</tt> file.
#Run a manual structure calculation with the same <tt>CALC.cya</tt> as before. It will now use updated stereospecific assignments. Delete the <tt>glomsa.out</tt> file if you don't want it to be appended.
#Repeat steps 3-5 until no new stereospecific assignments can be made.
 
Important notes:


# Copy the latest manual refinement directory.
*GLOMSA requires that you load a structure and UPL constraints. You should also declare the previously established stereospecific assignments (e.g., for VAL and LEU methyl groups) so that these could be used to determine new tereospecific assignments.<br>  
# Download the sample [[NESG:%ATTACHURL%/run_glomsa.cya|run_glomsa.cya]] script
*'''Important!''' The UPL constraints supplied to GLOMSA must generated before distance modification with <tt>distance modify</tt>. When you follow the procedure in the [[ManualCYANARun|manual structure calculation]] example this would be the <tt>$name-in.upl</tt> file.  
# Start CYANA 2.1 on a workstation and execute <tt>run_glomsa.cya</tt>. This will generate <tt>glomsa.out</tt> file.
*At this point we usually assign only HB2/3 spins and HA2/3 spins of Gly, HD21/22 of Asn and HE21/22 of Gln. Methyl QG1/2 of Val and QD1/2 of Leu can be assigned at this stage if that has not been done previously with the help of a fractionally <sup>13</sup>C-labeled sample. Stereospecific assignments of other spin pair are usually not reliable.  
# Analyze the output (here <tt>glomsa.out</tt>). For each stereospecific assignments verify that it is justified. Add confirmed assignments to the <tt>stereofound.cya</tt> file.
*In the first iteration accept only stereospecific assignments supported by multiple third atoms.
# Run a manual structure calculation with the same <tt>CALC.cya</tt> as before. It will now use updated stereospecific assignments. Delete the <tt>glomsa.out</tt> file if you don't want it to be appended.
# Repeat steps 3-5 until no new stereospecific assignments can be made.


Important notes:
=== '''Acceptance criteria for stereospecific assignments from GLOMSA''' ===
* GLOMSA requires that you load a structure and UPL constraints. You should also declare the previously established stereospecific assignments (e.g., for VAL and LEU methyl groups) so that these could be used to determine new tereospecific assignments.<br/>
* '''Important!''' The UPL constraints supplied to GLOMSA must generated before distance modification with <tt>distance modify</tt>. When you follow the procedure in the [[NESG:ManualCYANARun|manual structure calculation]] example this would be the <tt>$name-in.upl</tt> file.
* At this point we usually assign only HB2/3 spins and HA2/3 spins of Gly, HD21/22 of Asn and HE21/22 of Gln. Methyl QG1/2 of Val and QD1/2 of Leu can be assigned at this stage if that has not been done previously with the help of a fractionally 13C-labeled sample. Stereospecific assignments of other spin pair are usually not reliable.
* In the first iteration accept only stereospecific assignments supported by multiple third atoms.


==== '''Acceptance criteria for stereospecific assignments from GLOMSA''' ====
1.&nbsp; No conflicting stereospecific assignments in the output of GLOMSA (for example, both <tt>as input</tt> and <tt>reversed</tt> assignments for the same atom pair).&nbsp;


# No conflicting stereospecific assignments in the output of GLOMSA (for example, both <tt>as input</tt> and <tt>reversed</tt> assignments for the same atom pair). Exceptions:
&nbsp;&nbsp;&nbsp;&nbsp; Exceptions:  
** Some conflicting results may be caused by NOE peaks to QD and QE pseudoatoms of aromatic rings, due to constituent HD1/2 and HE1/2 atoms being so far away from the pseudoatom and slow ring flipping.
** Some conflicting results may be caused by incorrect peak intensities (see next point).
# Verify that the NOE peak intensities (a-b1 and a-b2) are correct, and not biased by overlap with other peaks.
# Verify that the NOE peak intensities have not been misinterpreted (Example: HN-HB2 peak only resolved in <tt>n.peaks</tt>, and HN-HB3 - only in ali.peaks. Different NOE calibration constants for both peaklists may lead to incorrect stereospecific assignments.)
# Big violations should be detected if the opposite stereospecific assignment is used.


*Some conflicting results may be caused by NOE peaks to QD and QE pseudoatoms of aromatic rings, due to constituent HD1/2 and HE1/2 atoms being so far away from the pseudoatom and slow ring flipping.
*Some conflicting results may be caused by incorrect peak intensities (see next point).


==== '''run_glomsa.cya''' ====
2.&nbsp; Verify that the NOE peak intensities (a-b1 and a-b2) are correct, and not biased by overlap with other peaks.  


Here is an example script run_glomsa.cya:
3.&nbsp; Verify that the NOE peak intensities have not been misinterpreted (Example: HN-HB2 peak only resolved in <tt>n.peaks</tt>, and HN-HB3 - only in ali.peaks. Different NOE calibration constants for both peaklists may lead to incorrect stereospecific assignments).


<nowiki>
4.&nbsp; Big violations should be detected if the opposite stereospecific assignment is used.
protocol:=glomsa.out
 
<br>  
 
=== '''run_glomsa.cya'''  ===
 
Here is an example script run_glomsa.cya:
<pre>protocol:=glomsa.out
read pdb $name.pdb
read pdb $name.pdb
read upl $name-in.upl
read upl $name-in.upl
Line 56: Line 60:
atom glomsa
atom glomsa
protocol:=
protocol:=
</nowiki>
</pre>  
 
=== '''GLOMSA output'''  ===
==== '''GLOMSA output'''  ====


The output of glomsa will look like this:  
The output of glomsa will look like this:  
Line 64: Line 67:
                                   sum  min  sum  min  num mean  assign
                                   sum  min  sum  min  num mean  assign
     HB2/3  ARG    4
     HB2/3  ARG    4
       H    ARG    4  5.50  3.64  0.64  0.00  0.13  0.00 -15 -0.49       ?
       H    ARG    4  5.50  3.64  0.64  0.00  0.13  0.00 -15 -0.49       &nbsp;?
     HB2/3  LEU    6
     HB2/3  LEU    6
       HA    LEU    6  5.50  3.36  0.00  0.00  0.00  0.00  16  0.24       ?
       HA    LEU    6  5.50  3.36  0.00  0.00  0.00  0.00  16  0.24       &nbsp;?
     QD1/2  LEU    6
     QD1/2  LEU    6
       HA    LEU    6  5.22  4.44  0.00  0.00  0.63  0.00  12  0.38       ?
       HA    LEU    6  5.22  4.44  0.00  0.00  0.63  0.00  12  0.38       &nbsp;?
     HG12/3  ILE    8
     HG12/3  ILE    8
       HA    ILE    8  4.57  5.31  0.00  0.00  0.00  0.00 -10  0.00       ?
       HA    ILE    8  4.57  5.31  0.00  0.00  0.00  0.00 -10  0.00       &nbsp;?
       HB    ILE    8  4.29  3.52  0.00  0.00  0.00  0.00  18  0.34       ?
       HB    ILE    8  4.29  3.52  0.00  0.00  0.00  0.00  18  0.34       &nbsp;?
     HB2/3  LEU    9
     HB2/3  LEU    9
       H    VAL  10  3.76  4.38  5.27  0.00  0.00  0.00  20  1.16 reversed
       H    VAL  10  3.76  4.38  5.27  0.00  0.00  0.00  20  1.16 reversed
     QD1/2  LEU    9
     QD1/2  LEU    9
       HA    LEU    9  5.56  3.85  0.05  0.00  7.15  0.00  18  0.51       ?
       HA    LEU    9  5.56  3.85  0.05  0.00  7.15  0.00  18  0.51       &nbsp;?
     QG1/2  VAL  10
     QG1/2  VAL  10
       H    VAL  10  4.91  4.13  0.00  0.00  0.32  0.00  20  1.06 as input
       H    VAL  10  4.91  4.13  0.00  0.00  0.32  0.00  20  1.06 as input
       HA    VAL  10  3.70  4.72  0.00  0.00  1.10  0.00 -20 -0.90 as input
       HA    VAL  10  3.70  4.72  0.00  0.00  1.10  0.00 -20 -0.90 as input
       H    CYS  11  4.97  5.87  0.00  0.00  0.00  0.00 -13 -0.10       ?</pre>
       H    CYS  11  4.97  5.87  0.00  0.00  0.00  0.00 -13 -0.10       &nbsp;?</pre>  
 
<br> For every spin pair there are lines listing spins. NMR cross-peaks to these spins have been used in an attempt to determine stereospecific assignments.  
 
For every spin pair there are lines listing spins. NMR cross-peaks to these spins have been used in an attempt to determine stereospecific assignments.  
 
 


<br>  
<br>  


-- Main.GaohuaLiu - 29 Jan 2007


<br>


*[[NESG:%ATTACHURL%/run glomsa.cya|run_glomsa.cya]]: CYANA script to run GLOMSA
*[[Media:Run_glomsa.cya|run_glomsa.cya]]: CYANA script to run GLOMSA

Latest revision as of 21:52, 6 January 2010

Introduction

GLOMSA (GLObal Method for Stereospecific Assignment) is performed with the preliminary conformers and using all the local and global experimental data. If there are two NOEs of significantly different strength from a given proton to both diastereotopic substituents of a prochiral center and if the distances from the given proton to the two diastereotopic substituents differ consistently in the structures, the stronger NOE can be identified with the diastereotopic substituent that is closer to the given proton.

Glomsa1.jpg


If |Δb| > cutoff, and |Δd| > threshold, the diastereotopic pair is assigned as:

    • input (if Δb and Δd are both either positive or negative)
    • reversed (if Δb and Δd have opposite signs)

  • GLOMSA usage:
    Parameters: atom selection (default: all atoms) cutoff=c (default: 0.4) threshold=t (default: 0.4) fraction=f (default: 100)
    Only those atoms are considered, for which the difference between two constraints is larger than cutoff (in Å) and the corresponding average distance difference in the bundle of structure is larger than threshold. The minimal percentage of structures in which the sign of the distance difference must be consistent must be larger than fraction (in percent).

Running GLOMSA

  1. Copy the latest manual refinement directory.
  2. Download the sample run_glomsa.cya script
  3. Start CYANA 2.1 on a workstation and execute run_glomsa.cya. This will generate glomsa.out file.
  4. Analyze the output (here glomsa.out). For each stereospecific assignments verify that it is justified. Add confirmed assignments to the stereofound.cya file.
  5. Run a manual structure calculation with the same CALC.cya as before. It will now use updated stereospecific assignments. Delete the glomsa.out file if you don't want it to be appended.
  6. Repeat steps 3-5 until no new stereospecific assignments can be made.

Important notes:

  • GLOMSA requires that you load a structure and UPL constraints. You should also declare the previously established stereospecific assignments (e.g., for VAL and LEU methyl groups) so that these could be used to determine new tereospecific assignments.
  • Important! The UPL constraints supplied to GLOMSA must generated before distance modification with distance modify. When you follow the procedure in the manual structure calculation example this would be the $name-in.upl file.
  • At this point we usually assign only HB2/3 spins and HA2/3 spins of Gly, HD21/22 of Asn and HE21/22 of Gln. Methyl QG1/2 of Val and QD1/2 of Leu can be assigned at this stage if that has not been done previously with the help of a fractionally 13C-labeled sample. Stereospecific assignments of other spin pair are usually not reliable.
  • In the first iteration accept only stereospecific assignments supported by multiple third atoms.

Acceptance criteria for stereospecific assignments from GLOMSA

1.  No conflicting stereospecific assignments in the output of GLOMSA (for example, both as input and reversed assignments for the same atom pair). 

     Exceptions:

  • Some conflicting results may be caused by NOE peaks to QD and QE pseudoatoms of aromatic rings, due to constituent HD1/2 and HE1/2 atoms being so far away from the pseudoatom and slow ring flipping.
  • Some conflicting results may be caused by incorrect peak intensities (see next point).

2.  Verify that the NOE peak intensities (a-b1 and a-b2) are correct, and not biased by overlap with other peaks.

3.  Verify that the NOE peak intensities have not been misinterpreted (Example: HN-HB2 peak only resolved in n.peaks, and HN-HB3 - only in ali.peaks. Different NOE calibration constants for both peaklists may lead to incorrect stereospecific assignments).

4.  Big violations should be detected if the opposite stereospecific assignment is used.


run_glomsa.cya

Here is an example script run_glomsa.cya:

protocol:=glomsa.out
read pdb $name.pdb
read upl $name-in.upl
stereofound                     # ssa from previous step
atom glomsa
protocol:=

GLOMSA output

The output of glomsa will look like this:

    Atoms   residue  constraints    as input    reversed distances   assign
                                   sum   min   sum   min  num mean   assign
    HB2/3   ARG    4
      H     ARG    4  5.50  3.64  0.64  0.00  0.13  0.00 -15 -0.49        ?
    HB2/3   LEU    6
      HA    LEU    6  5.50  3.36  0.00  0.00  0.00  0.00  16  0.24        ?
    QD1/2   LEU    6
      HA    LEU    6  5.22  4.44  0.00  0.00  0.63  0.00  12  0.38        ?
    HG12/3  ILE    8
      HA    ILE    8  4.57  5.31  0.00  0.00  0.00  0.00 -10  0.00        ?
      HB    ILE    8  4.29  3.52  0.00  0.00  0.00  0.00  18  0.34        ?
    HB2/3   LEU    9
      H     VAL   10  3.76  4.38  5.27  0.00  0.00  0.00  20  1.16 reversed
    QD1/2   LEU    9
      HA    LEU    9  5.56  3.85  0.05  0.00  7.15  0.00  18  0.51        ?
    QG1/2   VAL   10
      H     VAL   10  4.91  4.13  0.00  0.00  0.32  0.00  20  1.06 as input
      HA    VAL   10  3.70  4.72  0.00  0.00  1.10  0.00 -20 -0.90 as input
      H     CYS   11  4.97  5.87  0.00  0.00  0.00  0.00 -13 -0.10        ?


For every spin pair there are lines listing spins. NMR cross-peaks to these spins have been used in an attempt to determine stereospecific assignments.