AutoStructure Theory: Difference between revisions

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<span style="font-size: 11pt; font-family: Arial;">AutoStructure </span><ref>Huang, Y.J., Swapna, G.V., Rajan, P.K., Ke, H., Xia, B., Shukla, K., Inouye, M., and Montelione, G.T., Solution NMR structure of ribosome-binding factor A (RbfA), a cold-shock adaptation protein from Escherichia coli. J Mol Biol, 2003. 327(2): p. 521-36.</ref><span style="font-size: 11pt; font-family: Arial;"> is an automated NOESY assignment engine, which&nbsp;<span class="Apple-style-span" style="font-family: sans-serif; font-size: 13px;"><span lang="FR" style="font-size: 11pt; font-family: Arial;">uses a distinct bottom-up</span> topology-constrained approach for iterative NOE interpretation and structure determination. <span style="font-size: 11pt; font-family: Arial;">AutoStructure first builds an initial chain fold based on
AutoStructure&nbsp;<ref>Huang, Y.J., Tejero, R., Powers, R., and Montelione, G.T., A topology-constrained distance network algorithm for protein structure determination from NOESY data. Proteins, 2006. 62(3): p. 587-603.</ref> is an automated NOESY assignment engine, which&nbsp;uses a distinct bottom-up topology-constrained approach for iterative NOE interpretation and structure determination. AutoStructure first builds an initial chain fold based on intraresidue and sequential NOESY data, together with characteristic NOE patterns of secondary structures, including helical medium-range NOE interactions and interstrand b-sheet NOE interactions, and unambiguous long-range NOE interactions, based on chemical shift matching and NOESY spectral symmetry considerations. NOESY cross peaks that cannot be uniquely assigned using these methods are not used in the initial structure calculations.&nbsp;Once initial structures are generated and validated, additional NOESY cross peaks are iteratively assigned using the intermediate 3D structures and contact maps, together with knowledge of high-order topology constraints of alpha-helix and beta-sheet packing geometries. This protocol, in principle, resembles the method that an expert would utilize in manually solving a protein structure by NMR.  
intraresidue and sequential NOESY data, together with characteristic NOE
patterns of secondary structures, including helical medium-range NOE
interactions and interstrand </span><span style="font-size: 11pt; font-family: Symbol;">b</span><span style="font-size: 11pt; font-family: Arial;">-sheet NOE interactions, and unambiguous long-range
NOE interactions, based on chemical shift matching and NOESY spectral symmetry
considerations. NOESY cross peaks that cannot be uniquely assigned using these
methods are not used in the initial structure calculations.<span style="">&nbsp; </span>Once initial structures are generated and validated, additional NOESY cross peaks are iteratively assigned using the intermediate 3D structures and contact maps, together with knowledge of high-order topology constraints of alpha-helix and beta-sheet packing geometries</span><span style="font-size: 11pt; font-family: Arial;">. This protocol, in
principle, resembles the method that an expert would utilize in manually
solving a protein structure by NMR.<span style=""> </span></span></span></span><span />


The input data for AutoStructure are: (i) resonance assignment table, (ii) 2D, 3D, and/or 4D NOESY peak lists, (iii) list of scalar coupling, RDC and slow amide exchange data. AutoStructure generates distance constraint lists and utilizes the programs DYANA/CYANA, Xplor for 3D structure generation on a Linux-based computer cluster. Fig. 1 shows AutoStructure results for three different human protein NMR test data sets: FGF-2, IL-13 and MMP-1, ranging in size from 113 to 169 amino-acid residues. The mean coordinate differences between structures determined by AutoStructure and by manual analysis (0.5 to 0.8 Å for backbone atoms of ordered residues) demonstrate good accuracy of these automated methods.


 
[[Image:AS.jpg|left|307x229px|Ribbon diagrams of representative structures of FGF-2, MMP-1 and IL-13 proteins used for the validation of the AutoStructure process]]  
<span /><span>The input data for AutoStructure are: (i) resonance assignment
table, (ii) 2D, 3D, and/or 4D NOESY peak lists, (iii) list of scalar
coupling, RDC and slow amide exchange data. AutoStructure generates
distance constraint lists and utilizes the programs DYANA/CYANA, Xplor&nbsp;</span><span>for 3D structure
generation on a Linux-based computer cluster. </span><span>Fig. 1 shows AutoStructure results for three different human protein NMR
test data sets: FGF-2, IL-13 and MMP-1, ranging in size from 113 to 169
amino-acid residues. The mean coordinate differences between structures
determined by AutoStructure and by manual analysis (0.5 to 0.8 Å for backbone
atoms of ordered residues) demonstrate good accuracy of these automated
methods.</span>
 
<span>[[Image:AS.jpg|left|307x229px|Ribbon diagrams of representative structures of FGF-2, MMP-1 and IL-13 proteins used for the validation of the AutoStructure process]]</span>


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<span style="font-size: 11pt; font-family: Arial;">AutoStructure's ‘bottom up’ strategy is quite different from the “top down”
AutoStructure's ‘bottom up’ strategy is quite different from the “top down” strategies used by the alternative programs CANDID and ARIA, which rely on “ambiguous constraints”.&nbsp; For NOESY spectra with poor signal-to-noise ratios, such automatically assigned ‘ambiguous constraint” sets may not include any true NOESY assignments, and result in small distortions of the protein structure which maybe avoided by the “bottom up” approach of AutoStructure. CANDID/CYANA also uses a ‘network anchoring” approach similar to, but less comprehensive than, the topology-constrained approach used by AutoStructure. For these reasons, some users may prefer to use both AutoStructure and CANDID/CYANA or ARIA in parallel to assess potential errors in automated NOESY cross peak assignments  
strategies used by the alternative programs CANDID and ARIA, which rely on
“ambiguous constraints”.<span style="">&nbsp; </span>For NOESY spectra with poor signal-to-noise ratios, such automatically assigned ‘ambiguous constraint” sets may not include any true NOESY assignments, and result in small distortions of the protein structure which maybe avoided by the “bottom up” approach of AutoStructure</span><!--[if supportFields]><span
style='font-size:11.0pt;mso-bidi-font-size:12.0pt;font-family:Arial'><span
style='mso-element:field-end'></span></span><![endif]--><span style="font-size: 11pt; font-family: Arial;">.<span style="">&nbsp; </span>CANDID/CYANA also uses a ‘network anchoring” approach similar to, but less comprehensive than, the topology-constrained approach used by AutoStructure</span><!--[if supportFields]><span
style='font-size:11.0pt;mso-bidi-font-size:12.0pt;font-family:Arial'><span
style='mso-element:field-end'></span></span><![endif]--><span style="font-size: 11pt; font-family: Arial;">.<span style="">&nbsp; </span>For these reasons, some users may prefer to use both AutoStructure and CANDID/CYANA or ARIA in parallel to assess potential errors in automated NOESY cross peak assignments </span><!--[if supportFields]><span
style='font-size:11.0pt;mso-bidi-font-size:12.0pt;font-family:Arial'><span
style='mso-element:field-begin'></span><span style="mso-spacerun:
yes">&nbsp;</span>ADDIN EN.CITE
&lt;EndNote&gt;&lt;Cite&gt;&lt;Author&gt;Liu&lt;/Author&gt;&lt;Year&gt;2005&lt;/Year&gt;&lt;RecNum&gt;193&lt;/RecNum&gt;&lt;record&gt;&lt;rec-number&gt;193&lt;/rec-number&gt;&lt;foreign-keys&gt;&lt;key
app=&quot;EN&quot;
db-id=&quot;fe29atzr4stwaueev2lxf2fgp5xx5pavz2a5&quot;&gt;193&lt;/key&gt;&lt;/foreign-keys&gt;&lt;ref-type
name=&quot;Journal
Article&quot;&gt;17&lt;/ref-type&gt;&lt;contributors&gt;&lt;authors&gt;&lt;author&gt;Liu,
G.&lt;/author&gt;&lt;author&gt;Shen, Y.&lt;/author&gt;&lt;author&gt;Atreya, H.
S.&lt;/author&gt;&lt;author&gt;Parish, D.&lt;/author&gt;&lt;author&gt;Shao,
Y.&lt;/author&gt;&lt;author&gt;Sukumaran, D. K.&lt;/author&gt;&lt;author&gt;Xiao,
R.&lt;/author&gt;&lt;author&gt;Yee, A.&lt;/author&gt;&lt;author&gt;Lemak,
A.&lt;/author&gt;&lt;author&gt;Bhattacharya,
A.&lt;/author&gt;&lt;author&gt;Acton, T.
A.&lt;/author&gt;&lt;author&gt;Arrowsmith, C.
H.&lt;/author&gt;&lt;author&gt;Montelione, G.
T.&lt;/author&gt;&lt;author&gt;Szyperski,
T.&lt;/author&gt;&lt;/authors&gt;&lt;/contributors&gt;&lt;auth-address&gt;Department
of Chemistry, University at Buffalo, State University of New York, Buffalo, NY
14260, USA.&lt;/auth-address&gt;&lt;titles&gt;&lt;title&gt;NMR data collection
and analysis protocol for high-throughput protein structure determination&lt;/title&gt;&lt;secondary-title&gt;Proc
Natl Acad Sci U S
A&lt;/secondary-title&gt;&lt;/titles&gt;&lt;periodical&gt;&lt;full-title&gt;Proc
Natl Acad Sci U S
A&lt;/full-title&gt;&lt;/periodical&gt;&lt;pages&gt;10487-92&lt;/pages&gt;&lt;volume&gt;102&lt;/volume&gt;&lt;number&gt;30&lt;/number&gt;&lt;keywords&gt;&lt;keyword&gt;Comparative
Study&lt;/keyword&gt;&lt;keyword&gt;Data Collection/methods&lt;/keyword&gt;&lt;keyword&gt;Fourier
Analysis&lt;/keyword&gt;&lt;keyword&gt;*Models,
Molecular&lt;/keyword&gt;&lt;keyword&gt;Nuclear Magnetic Resonance,
Biomolecular/*methods&lt;/keyword&gt;&lt;keyword&gt;Protein
Conformation&lt;/keyword&gt;&lt;keyword&gt;Proteins/*chemistry&lt;/keyword&gt;&lt;keyword&gt;Research
Support, N.I.H., Extramural&lt;/keyword&gt;&lt;keyword&gt;Research Support,
Non-U.S. Gov&amp;apos;t&lt;/keyword&gt;&lt;keyword&gt;Research Support, U.S.
Gov&amp;apos;t, Non-P.H.S.&lt;/keyword&gt;&lt;keyword&gt;Research Support, U.S.
Gov&amp;apos;t, P.H.S.&lt;/keyword&gt;&lt;/keywords&gt;&lt;dates&gt;&lt;year&gt;2005&lt;/year&gt;&lt;pub-dates&gt;&lt;date&gt;Jul
26&lt;/date&gt;&lt;/pub-dates&gt;&lt;/dates&gt;&lt;accession-num&gt;16027363&lt;/accession-num&gt;&lt;urls&gt;&lt;related-urls&gt;&lt;url&gt;http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&amp;amp;db=PubMed&amp;amp;dopt=Citation&amp;amp;list_uids=16027363
&lt;/url&gt;&lt;/related-urls&gt;&lt;/urls&gt;&lt;/record&gt;&lt;/Cite&gt;&lt;/EndNote&gt;<span
style='mso-element:field-separator'></span></span><![endif]--><span style="font-size: 11pt; font-family: Arial;">.&nbsp;</span><br><!--EndFragment-->
 
<span style="font-size: 11pt; font-family: Arial;" />


<references />
<br> <references />

Latest revision as of 21:00, 18 December 2009

AutoStructure [1] is an automated NOESY assignment engine, which uses a distinct bottom-up topology-constrained approach for iterative NOE interpretation and structure determination. AutoStructure first builds an initial chain fold based on intraresidue and sequential NOESY data, together with characteristic NOE patterns of secondary structures, including helical medium-range NOE interactions and interstrand b-sheet NOE interactions, and unambiguous long-range NOE interactions, based on chemical shift matching and NOESY spectral symmetry considerations. NOESY cross peaks that cannot be uniquely assigned using these methods are not used in the initial structure calculations. Once initial structures are generated and validated, additional NOESY cross peaks are iteratively assigned using the intermediate 3D structures and contact maps, together with knowledge of high-order topology constraints of alpha-helix and beta-sheet packing geometries. This protocol, in principle, resembles the method that an expert would utilize in manually solving a protein structure by NMR.

The input data for AutoStructure are: (i) resonance assignment table, (ii) 2D, 3D, and/or 4D NOESY peak lists, (iii) list of scalar coupling, RDC and slow amide exchange data. AutoStructure generates distance constraint lists and utilizes the programs DYANA/CYANA, Xplor for 3D structure generation on a Linux-based computer cluster. Fig. 1 shows AutoStructure results for three different human protein NMR test data sets: FGF-2, IL-13 and MMP-1, ranging in size from 113 to 169 amino-acid residues. The mean coordinate differences between structures determined by AutoStructure and by manual analysis (0.5 to 0.8 Å for backbone atoms of ordered residues) demonstrate good accuracy of these automated methods.

Ribbon diagrams of representative structures of FGF-2, MMP-1 and IL-13 proteins used for the validation of the AutoStructure process


Fig. 1. Ribbon diagrams of representative structures of FGF-2, MMP-1 and IL-13 proteins used for the validation of the AutoStructure process: (a) final structures from AutoStructure using XPLOR for stucture generation, (b) manual-analyzed structures deposited in PDB, analyzed using the same NMR data set, (c) structures determined by X-ray crystallography or third NMR group. Tabulated on the right are mean coordinate differences (Å) in secondary structure regions for backbone atoms between structures (a), (b) and (c).




AutoStructure's ‘bottom up’ strategy is quite different from the “top down” strategies used by the alternative programs CANDID and ARIA, which rely on “ambiguous constraints”.  For NOESY spectra with poor signal-to-noise ratios, such automatically assigned ‘ambiguous constraint” sets may not include any true NOESY assignments, and result in small distortions of the protein structure which maybe avoided by the “bottom up” approach of AutoStructure. CANDID/CYANA also uses a ‘network anchoring” approach similar to, but less comprehensive than, the topology-constrained approach used by AutoStructure. For these reasons, some users may prefer to use both AutoStructure and CANDID/CYANA or ARIA in parallel to assess potential errors in automated NOESY cross peak assignments


  1. Huang, Y.J., Tejero, R., Powers, R., and Montelione, G.T., A topology-constrained distance network algorithm for protein structure determination from NOESY data. Proteins, 2006. 62(3): p. 587-603.