The Structured Advanced Query Page
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Transcript The Structured Advanced Query Page
The Structured Advanced Query
Page
Tomer Altman &
Mario Latendresse
Bioinformatics Research Group
SRI, International
August 18, 2009
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Introduction
BioVelo
is a query language
Like SQL but simpler and easier to learn
Documentation: http://biocyc.org/bioveloLanguage.html
Free-Form Advanced Query Page allows Web submission of
BioVelo queries
Structured
Advanced Query Page (SAQP)
Web page for interactively constructing advanced and
precise queries to PGDBs
Queries are translated to BioVelo and sent to the server for
processing
SAQP: http://biocyc.org/query.html
Documentation: http://biocyc.org/webQueryDoc.html
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Why a query interface?
Allow
a structured way to access the rich data
representation stored in a PGDB.
Most advanced databases have a high-level,
declarative method of access (i.e., SQL).
Provides an intermediate level of access between
graphically browsing the PGDB and programmatically
processing the data using Lisp.
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The Structured Advanced Query
Page
'Advanced',
in that it allows you to ask more advanced
and complicated queries than the basic search
interface.
In other words, the SAQP allows you to search for a
precise set of answers given simple or complex
conditions
'Structured', in that it is a dynamic HTML form, that
provides greater ease in crafting queries, but trades
flexibility and power for simplicity (FFAQP).
'Page', in that it is accessed via the Web interface for
BioCyc (www.biocyc.org/query.html), or from your own
Pathway Tools Web server.
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SAQP Architecture
The
SAQP is built on top of a high-level functional
declarative language called BioVelo (Mario
Latendresse, SRI), which is built on top of Pathway
Tools.
On every result page, you will see the equivalent
BioVelo code that was generated from the SAQP,
which, in turn, generated the results.
You don't need to know anything about BioVelo to use
the SAQP, but it might be helpful later if you need the
ability to write even more complicated queries using
the Free Form Advanced Query Page (FFAQP).
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The Structure of the SAQP:
Database
specification
Class specification
'Where' constraints on attributes of classes
Output attributes description
Data format (HTML vs TXT)
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Example #1:
A
simple query usually consists of querying a
particular database about a particular class.
Find all the proteins in E. coli K-12.
Display the protein names.
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Structure of the Results
A
line that shows the equivalent BioVelo expression
that the SAQP generated to answer the query.
A HTML table of the results, with the corresponding
entries hyperlinked to the matching Pathway Tools
Web pages.
If a text data format was requested, then a tabdelimited text file is generated, with just the table data.
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Example #2:
Find
all the proteins of E. coli K-12 for which the DNAFOOTPRINT-SIZE is smaller than 10.
Display the protein name, and the DNA footprint size.
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Example #3:
In
EcoCyc, display polypeptides constrained by
experimentally determined molecular weight and
isoelectric point.
The
experimental molecular weight should be between
50 and 100 kD.
The
pI should be less than 7.
Display
the polypeptide name, the experimental
molecular weight, and the pI.
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Example #4:
The
SAQP allows for specifying quantifiers on
relations between PGDB classes.
Extend
example #3 to select only proteins whose
encoding gene is situated within the first 500 kilobases
of the E. coli chromosome.
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Example #5: Queries with
Several Components
A
second search component will search potentially
another database and another class of objects for each
element found in the first search component.
It is called a 'cross-product' search.
Any number of search components can be added. In
general, the new search component is done for each
set of objects found in the previous components.
Some restraints is needed not to build a query that
takes too long to answer. (The server gives a limit of a
few minutes for a query.)
Example: Search for MetaCyc pathways in the
taxonomic range of Bacteria that also exist in E. coli K12 using the common-name attribute.
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Introduction to BioVelo
BioVelo
is based on set and list comprehension.
In Mathematics, a set comprehension describes a set of
values as in: {x | x in Prime, x > 100}
The output is 'x', the body has a generator 'x in Prime' and
a condition 'x > 100'. Several conditions and several
generators could be used.
BioVelo used a concise syntax:
1) [ output-expression : generator, condition, ... ]
2) a generator has the form v ← database^^class
3) a condition uses logical and relational operators
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Examples of BioVelo Queries
[r : r <- ecoli^^reactions]
[p^name : p <- ecoli^^proteins]
[p^?name : p<- ecoli^^proteins]
[p^?name : p <- ecoli^^proteins, p^dna-footprint-size < 10]
[(g^?name, g^left-end-position): g <- ecoli^^genes,
g^left-end-position < 153000]
[(g^?name, k): g<- ecoli^^genes, k := abs(g^left-endposition – g^right-end-position)+1, k < 200 ]
[(r^?name, c^?name) : r<- ecoli^^reactions, c<- r^left, c in
r^right]
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