Homodimer Structure Calculation Using CYANA: Difference between revisions
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== ''' | == '''Introduction''' == | ||
CYANA versions 2.1 and up can perform structure calculation with automated NOE assignment for symmetric homodimers. The algorithm is slightly different from what is used to calculate monomers or asymmetric oligomers. Additional restraints are introduced to keep the molecule and the force field symmetric. A tutorial for homodimer structure calculation using CYANA 3.0 is avaliable [http://www.cyana.org/wiki/index.php/Homodimer_structure_calculation_with_automated_NOESY_assignment on-line]. | |||
== '''Input Data''' == | |||
Chemical shift assignment is performed for a single protein chain. Thus, the input for a symmetric homodimer calculation must include: | Chemical shift assignment is performed for a single protein chain. Thus, the input for a symmetric homodimer calculation must include: | ||
Line 11: | Line 11: | ||
*duplicated external constraint files, if any | *duplicated external constraint files, if any | ||
=== '''Duplicated Sequence File''' === | |||
The protein sequence must be repeated twice with a linker between protein chains as in this example:<br> | |||
<pre>MET 11 | |||
< | ALA 12 | ||
GLU 13 | |||
VAL 14 | |||
GLU 15 | |||
... | ... | ||
GLU 106 | |||
PL 107 | |||
LL2 108 | |||
... | ... | ||
LL2 128 | |||
LL2 129 | |||
LP 130 | |||
MET 211 | |||
ALA 212 | |||
GLU 213 | |||
VAL 214 | |||
GLU 215 | |||
... | ... | ||
GLU 306 | GLU 306</pre> | ||
</ | The CYANA residue library provides the following linker pseudo-residues: <tt>PL</tt>, <tt>LP</tt>, <tt>LL</tt>, <tt>LL2</tt> and <tt>LL5</tt>. The first two are special transition "residues", which are required to start and terminate the linker, respectively. The last three are intermediate linker "residues" of differing sizes, with "bonds" of standard length, double length and quintuple length. The "atoms" of these linker "residues" have zero mass and zero Van-der-Vaals radii, thus the linker can freely pass through the structure during simulated annealing. The "bonds" of the linker cannot be stretched, however, and it is necessary to use a linker of sufficient length to avoid putting unnatural strain on the subunits. | ||
It is convenient to have the residue numbers of the second subunit shifted by 100 or 200 compared to the first subunit. The first subunit in this example protein has residue numbers 11 to 106, while the second subunit has residue numbers from 211 to 306. It is not necessary to insert a linker exactly 94 residues long - hops in the residue numbers, such as between <tt>LP 130</tt> and <tt>MET 211</tt>, are accepted. | It is convenient to have the residue numbers of the second subunit shifted by 100 or 200 compared to the first subunit. The first subunit in this example protein has residue numbers 11 to 106, while the second subunit has residue numbers from 211 to 306. It is not necessary to insert a linker exactly 94 residues long - hops in the residue numbers, such as between <tt>LP 130</tt> and <tt>MET 211</tt>, are accepted. | ||
=== '''Duplicated Atom List''' === | |||
Chemical shifts in the atom list should be duplicated to include assignments for the second chain < | Chemical shifts in the atom list (.prot file) should be duplicated to include assignments for the second chain. | ||
<pre> 155 119.362 0.000 N 11 | |||
156 8.323 0.004 HN 11 | 156 8.323 0.004 HN 11 | ||
157 56.722 0.000 CA 11 | 157 56.722 0.000 CA 11 | ||
Line 59: | Line 55: | ||
1822 31.426 0.000 CB 211 | 1822 31.426 0.000 CB 211 | ||
1823 2.010 0.000 HB2 211 | 1823 2.010 0.000 HB2 211 | ||
1824 2.137 0.000 HB3 211 | 1824 2.137 0.000 HB3 211</pre> | ||
</ | === '''Duplicated External Constraints''' === | ||
All external constraints, such as intramolecular UPLs, ACOs and hydrogen bond constraints, must be duplicated to include both chains, otherwise the symmetry of the model will be broken. Intermolecular UPLs should also be given as symmetric pairs. | All external constraints, such as intramolecular UPLs, ACOs and hydrogen bond constraints, must be duplicated to include both chains, otherwise the symmetry of the model will be broken. Intermolecular UPLs should also be given as symmetric pairs. | ||
=== '''Modified init.cya''' === | |||
It is necessary to add a <tt>molecules define</tt> statement to the <tt>init.cya</tt> file. The statement tells CYANA to perform the symmetric homodimer calculation, and the residue ranges are used to maintain symmetry. | It is necessary to add a <tt>molecules define</tt> statement to the <tt>init.cya</tt> file. The statement tells CYANA to perform the symmetric homodimer calculation, and the residue ranges are used to maintain symmetry.<br> | ||
<pre>name:=hr2106-cyana | |||
< | |||
name:=hr2106-cyana | |||
cyanalib | cyanalib | ||
read seq $name.seq | read seq $name.seq | ||
rmsdrange:=12..104,212..304 | rmsdrange:=12..104,212..304 | ||
molecules define 11..106 211..306 | molecules define 11..106 211..306 </pre> | ||
</ | == '''Automatic Calculation''' == | ||
Run the same <tt>CALC.cya</tt> macro as usual. | Run the same <tt>CALC.cya</tt> macro as usual. | ||
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It is not necessary to generate constraints for every cross-peak in the X-filtered NOESY spectrum. Instead, one should focus on a few strong cross-peaks, which can be '''manually''' assigned with absolute certainty. For example, the structure calculation of StR106 converged to the correct dimer geometry after adding a single intermolecular UPL constraint between an aromatic ring proton and a methyl group. | It is not necessary to generate constraints for every cross-peak in the X-filtered NOESY spectrum. Instead, one should focus on a few strong cross-peaks, which can be '''manually''' assigned with absolute certainty. For example, the structure calculation of StR106 converged to the correct dimer geometry after adding a single intermolecular UPL constraint between an aromatic ring proton and a methyl group. | ||
== '''Manual Calculation''' == | |||
*Manual Run | |||
< | Similar to the automatic run, modify the <tt>seq</tt> file, <tt>prot</tt> list, <tt>init.cya</tt>, and run the CYANA manual CALC macro as usual. |
Latest revision as of 12:36, 28 August 2012
Introduction
CYANA versions 2.1 and up can perform structure calculation with automated NOE assignment for symmetric homodimers. The algorithm is slightly different from what is used to calculate monomers or asymmetric oligomers. Additional restraints are introduced to keep the molecule and the force field symmetric. A tutorial for homodimer structure calculation using CYANA 3.0 is avaliable on-line.
Input Data
Chemical shift assignment is performed for a single protein chain. Thus, the input for a symmetric homodimer calculation must include:
- duplicated sequence file
- duplicated atom list
- duplicated external constraint files, if any
Duplicated Sequence File
The protein sequence must be repeated twice with a linker between protein chains as in this example:
MET 11 ALA 12 GLU 13 VAL 14 GLU 15 ... GLU 106 PL 107 LL2 108 ... LL2 128 LL2 129 LP 130 MET 211 ALA 212 GLU 213 VAL 214 GLU 215 ... GLU 306
The CYANA residue library provides the following linker pseudo-residues: PL, LP, LL, LL2 and LL5. The first two are special transition "residues", which are required to start and terminate the linker, respectively. The last three are intermediate linker "residues" of differing sizes, with "bonds" of standard length, double length and quintuple length. The "atoms" of these linker "residues" have zero mass and zero Van-der-Vaals radii, thus the linker can freely pass through the structure during simulated annealing. The "bonds" of the linker cannot be stretched, however, and it is necessary to use a linker of sufficient length to avoid putting unnatural strain on the subunits.
It is convenient to have the residue numbers of the second subunit shifted by 100 or 200 compared to the first subunit. The first subunit in this example protein has residue numbers 11 to 106, while the second subunit has residue numbers from 211 to 306. It is not necessary to insert a linker exactly 94 residues long - hops in the residue numbers, such as between LP 130 and MET 211, are accepted.
Duplicated Atom List
Chemical shifts in the atom list (.prot file) should be duplicated to include assignments for the second chain.
155 119.362 0.000 N 11 156 8.323 0.004 HN 11 157 56.722 0.000 CA 11 158 4.318 0.005 HA 11 159 31.426 0.000 CB 11 160 2.010 0.000 HB2 11 161 2.137 0.000 HB3 11 ... 1818 119.362 0.000 N 211 1819 8.323 0.004 HN 211 1820 56.722 0.000 CA 211 1821 4.318 0.005 HA 211 1822 31.426 0.000 CB 211 1823 2.010 0.000 HB2 211 1824 2.137 0.000 HB3 211
Duplicated External Constraints
All external constraints, such as intramolecular UPLs, ACOs and hydrogen bond constraints, must be duplicated to include both chains, otherwise the symmetry of the model will be broken. Intermolecular UPLs should also be given as symmetric pairs.
Modified init.cya
It is necessary to add a molecules define statement to the init.cya file. The statement tells CYANA to perform the symmetric homodimer calculation, and the residue ranges are used to maintain symmetry.
name:=hr2106-cyana cyanalib read seq $name.seq rmsdrange:=12..104,212..304 molecules define 11..106 211..306
Automatic Calculation
Run the same CALC.cya macro as usual.
Though in principle CYANA is able to perform calculation of homodimer structures without external constraints, the proper convergence has not been observed yet, at least in Szyperski's lab. The typical result is two separate protein chains, instead of a dimer structure. The poor convergence is not that surprising given that symmetric homodimer calculation and NOE assignment is a massively degenerate problem, compared to the monomer case.
The standard approach of using external intraresidue- and short-range UPL together with ACOs from TALOS does not improve convergence, since these constraints are purely intramolecular. To "nudge" the structure calculation in the proper direction external intermolecular UPLs should be supplied. These are obtained from an X-filtered NOESY experiment on a 50:50 labeled/unlabeled protein mixture.
It is not necessary to generate constraints for every cross-peak in the X-filtered NOESY spectrum. Instead, one should focus on a few strong cross-peaks, which can be manually assigned with absolute certainty. For example, the structure calculation of StR106 converged to the correct dimer geometry after adding a single intermolecular UPL constraint between an aromatic ring proton and a methyl group.
Manual Calculation
- Manual Run
Similar to the automatic run, modify the seq file, prot list, init.cya, and run the CYANA manual CALC macro as usual.