1. Introduction to ABACUS: Difference between revisions

From NESG Wiki
Jump to navigation Jump to search
(Created page with '  <div>ABACUS (''A''pplied ''BACUS'') is a novel approach for protein structure determination that has been applied successfully for more than 20 NESG targets. ABACUS is cha…')
 
No edit summary
Line 1: Line 1:
&nbsp;
&nbsp;  
<div>ABACUS (''A''pplied ''BACUS'') is a novel approach for protein structure determination that has been applied successfully for more than 20 NESG targets. ABACUS is characterized by use of BACUS, a procedure for automated probabilistic interpretation of NOESY spectra in terms of unassigned proton chemical shifts based on the known information on "connectivity" between proton resonances. BACUS is used in both the resonance assignment and structure calculation steps. The ABACUS<span> is distinguished from conventional approaches to NMR structure determination mostly by its resonance assignment strategy (see Fig.1.1A). </span></div>
<div>ABACUS (''A''pplied ''BACUS'') is a novel approach for protein structure determination that has been applied successfully for more than 20 NESG targets. ABACUS is characterized by use of BACUS, a procedure for automated probabilistic interpretation of NOESY spectra in terms of unassigned proton chemical shifts based on the known information on "connectivity" between proton resonances. BACUS is used in both the resonance assignment and structure calculation steps. The ABACUS<span> is distinguished from conventional approaches to NMR structure determination mostly by its resonance assignment strategy (see Fig.1.1A). </span></div>
<br>


<br>'''Figure 1.1A.'''&nbsp;&nbsp;Flowchart of resonance assignmnent by ABACUS''.&nbsp;''


&nbsp;


'''Figure 1.1B.''' Schematic description of two types of molecular fragments: traditional spin-system (AA-fragment)<span> include all the atoms belonging to the same residue; PB-fragment includes all the atoms from one residue except the backbone amide group, plus the amide group from the next residue in the protein</span>


Figure 1.1A.&nbsp;&nbsp;
&nbsp;  
 
<div>'''<span>Some features /advantages of the ABACUS protocol:</span>'''</div>
&nbsp;
*<span><span>&nbsp; </span></span>It does not rely on sequential connectivities from less sensitive experiments such as HNCACB indispensable for most traditional sequential assignment procedures;  
 
*Inter-residue sequential connectivities are established mainly from NOE data, which saves time at a later stage in “troubleshooting” NOE and resonance assignments.;  
Figure 1.1B.
*Probabilistic nature of the ABACUS procedure provides measure of reliability of assignments, and therefore one can obtain a partial, yet highly reliable assignment (even when the NMR data are sub-optimal) with the knowledge of where to focus manual intervention<font size="3">;</font>  
 
&nbsp;
 
&nbsp;
 
&nbsp;
 
&nbsp;
<div><span>Some features /advantages of the ABACUS protocol:</span></div>
*<span><span>&nbsp; </span></span>It does not rely on sequential connectivities from less sensitive experiments such as HNCACB indispensable for most traditional sequential assignment procedures;
*Inter-residue sequential connectivities are established mainly from NOE data, which saves time at a later stage in “troubleshooting” NOE and resonance assignments.;
*Probabilistic nature of the ABACUS procedure provides measure of reliability of assignments, and therefore one can obtain a partial, yet highly reliable assignment (even when the NMR data are sub-optimal) with the knowledge of where to focus manual intervention<font size="3">;</font>
*It can make use of&nbsp;partial spin-systems;  
*It can make use of&nbsp;partial spin-systems;  
*It can efficiently identify manual errors in the input peak lists;
*It can efficiently identify manual errors in the input peak lists;
<div></div>
<div></div>

Revision as of 22:28, 25 November 2009

 

ABACUS (Applied BACUS) is a novel approach for protein structure determination that has been applied successfully for more than 20 NESG targets. ABACUS is characterized by use of BACUS, a procedure for automated probabilistic interpretation of NOESY spectra in terms of unassigned proton chemical shifts based on the known information on "connectivity" between proton resonances. BACUS is used in both the resonance assignment and structure calculation steps. The ABACUS is distinguished from conventional approaches to NMR structure determination mostly by its resonance assignment strategy (see Fig.1.1A).



Figure 1.1A.  Flowchart of resonance assignmnent by ABACUS

 

Figure 1.1B. Schematic description of two types of molecular fragments: traditional spin-system (AA-fragment) include all the atoms belonging to the same residue; PB-fragment includes all the atoms from one residue except the backbone amide group, plus the amide group from the next residue in the protein

 

Some features /advantages of the ABACUS protocol:
  •   It does not rely on sequential connectivities from less sensitive experiments such as HNCACB indispensable for most traditional sequential assignment procedures;
  • Inter-residue sequential connectivities are established mainly from NOE data, which saves time at a later stage in “troubleshooting” NOE and resonance assignments.;
  • Probabilistic nature of the ABACUS procedure provides measure of reliability of assignments, and therefore one can obtain a partial, yet highly reliable assignment (even when the NMR data are sub-optimal) with the knowledge of where to focus manual intervention;
  • It can make use of partial spin-systems;
  • It can efficiently identify manual errors in the input peak lists;