predictSecondaryStructure: Predicts the secondary structure of a given RNA sequence
In ncRNAtools: An R toolkit for non-coding RNA
Description
Usage
Arguments
Value
References
Examples
View source: R/ncRNAtools_secondaryStructurePredictionFunctions.R
Description
Predicts the secondary structure of the provided RNA sequence, using the chosen
prediction method. Secondary structure predictions are carried out with the
rtools RNA Bioinformatics Web server.
Usage
1
2
Arguments
sequence
string with an RNA sequence whose secondary structure should
be predicted. Should contain only standard RNA symbols (i.e., "A", "U", "G"
and "C").
method
method that should be used for the prediction of RNA secondary
structure. Possible values are "centroidFold", "centroidHomFold" and "IPknot".
Only IPknot is able to predict pseudoknots. For a detailed description of each
method, see respectively Hamada et al., 2008; Hamada et al., 2009,
and Sato et al., 2011.
gammaWeight
weight factor for predicted base pairs. It directly affects
the number of predicted base pairs. A higher value leads to a higher number of
base pairs predicted. It should be a positive number. In the default behavior,
when no specific value is provided, the default value for each secondary
structure prediction method in the rtools webserver is used (4 for centroidFold
and IPknot, and 8 forcentroidHomFold).
inferenceEngine
engine used to identify optimal secondary structures.
Possible values are "BL", "Turner" and "CONTRAfold". In the first two cases, a
McCaskill partition function is applied, using respectively the Boltzmann
likelihood model or Turner's energy model. In the third case, the CONTRAfold
engine, based on conditional log-linear models, is applied. Additionally, if
IPknot is chosen as the method for secondary structure prediction, "NUPACK" is
also a possible value if the sequence has 100 nucleotides or less. In this case,
the NUPACK scoring model is used. In the default behavior, when no specific
value is provided, the default inference engine in the rtools webserver is,
which is a McCaskill partition function with a Boltzmann likelihood model.
alignmentEngine
engine used to perform pairwise alignments of the query
sequence and Rfam homologous sequences during the application of centroidHomFold.
Possible values are "CONTRAlign" and "ProbCons". For details on each alignment
engine, see Do et al., 2006 and Do et al., 2005 respectively.
In the default behavior, when no value is specified, CONTRAlign is used.
eValueRfamSearch
e-value used to select homologous sequences from the
Rfam database during the application of centroidHomFold. Should be a number
equal to or greater than 0. In the default behavior, when no value is specified,
a value of 0.01 is used.
numHomSeqsRfamSearch
maximum number of homologous sequences to be considered
during the application of centroidHomFold. Should be a positive integer.In the
default behavior, when no value is specified, a value of 30 is used.
Value
If either centroidFold or centroidHomFold are used for predicting secondary
structure, a list of three elements comprising the query RNA sequence, the predicted
secondary structure and a table of base pair probabilities. The secondary structure
is represented as a string in the Dot-Bracket format. The three elements of the list
are:
sequence
Query RNA sequence
secondaryStructure
Predicted secondary structure
basePairProbabilities
A dataframe where each line corresponds to a nucleotide
of the query RNA sequence. The first column indicates the position number, the
second column indicates the corresponding nucleotide type and additional columns
indicating the probability of forming a base pair with other nucleotides. The
potentially pairing nucleotides and their corresponding probabilities are provided
as strings, where a colon separates both fields
If IPknot is used for predicting secondary structure, no table of base pair
probabilities is returned. Therefore, the output is a list of only two elements
(sequence and secondaryStructure). Additionally, the secondary structure is
provided in the extended Dot-Bracket format if required to represent pseudoknots
unambiguously.
References
Andronescu M, Condon A, Hoos HH, Mathews DH, Murphy KP. Computational approaches
for RNA energy parameter estimation. RNA. 2010;16(12):2304-2318.
doi:10.1261/rna.1950510
Do C.B., Gross S.S., Batzoglou S. CONTRAlign: Discriminative Training for
Protein Sequence Alignment. In: Apostolico A., Guerra C., Istrail S., Pevzner P.A.,
Waterman M. (eds) Research in Computational Molecular Biology. 2006.
Lecture Notes in Computer Science, vol 3909. Springer, Berlin, Heidelberg
doi:10.1007/11732990_15
Do CB, Mahabhashyam MS, Brudno M, Batzoglou S. ProbCons: Probabilistic
consistency-based multiple sequence alignment. Genome Res. 2005;15(2):330-340.
doi:10.1101/gr.2821705
Do CB, Woods DA, Batzoglou S. CONTRAfold: RNA secondary structure prediction
without physics-based models. Bioinformatics. 2006;22(14):e90-e98.
doi:10.1093/bioinformatics/btl246
Hamada M, Kiryu H, Sato K, Mituyama T, Asai K. Prediction of RNA secondary
structure using generalized centroid estimators. Bioinformatics. 2009;25(4):465-473.
doi:10.1093/bioinformatics/btn601
Hamada M, Ono Y, Kiryu H, et al. Rtools: a web server for various secondary
structural analyses on single RNA sequences. Nucleic Acids Res. 2016;44(W1):W302-W307.
doi:10.1093/nar/gkw337
Hamada M, Yamada K, Sato K, Frith MC, Asai K. CentroidHomfold-LAST: accurate
prediction of RNA secondary structure using automatically collected homologous
sequences. Nucleic Acids Res. 2011;39(Web Server issue):W100-W106.
doi:10.1093/nar/gkr290
Mathews DH, Sabina J, Zuker M, Turner DH. Expanded sequence dependence of
thermodynamic parameters improves prediction of RNA secondary structure.
J Mol Biol. 1999;288(5):911-940. doi:10.1006/jmbi.1999.2700
Sato K, Kato Y, Hamada M, Akutsu T, Asai K. IPknot: fast and accurate prediction
of RNA secondary structures with pseudoknots using integer programming.
Bioinformatics. 2011;27(13):i85-i93. doi:10.1093/bioinformatics/btr215
http://rtools.cbrc.jp/
Examples
1
2
3
4
5
6
7
8
# Predict the secondary structure of an RNA sequence with IPknot:
structurePrediction <- predictSecondaryStructure("UGCGAGAGGCACAGGGUUCGAUUCCCUGCA
UCUCCA", "IPknot", inferenceEngine = "NUPACK")
# Extract the string representing the secondary structure prediction:
structurePrediction$secondaryStructure
ncRNAtools documentation built on Nov. 8, 2020, 8:14 p.m.
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Description Usage Arguments Value References Examples
View source: R/ncRNAtools_secondaryStructurePredictionFunctions.R
Description
Predicts the secondary structure of the provided RNA sequence, using the chosen prediction method. Secondary structure predictions are carried out with the rtools RNA Bioinformatics Web server.
Usage
1 2 |
Arguments
sequence |
string with an RNA sequence whose secondary structure should be predicted. Should contain only standard RNA symbols (i.e., "A", "U", "G" and "C"). |
method |
method that should be used for the prediction of RNA secondary structure. Possible values are "centroidFold", "centroidHomFold" and "IPknot". Only IPknot is able to predict pseudoknots. For a detailed description of each method, see respectively Hamada et al., 2008; Hamada et al., 2009, and Sato et al., 2011. |
gammaWeight |
weight factor for predicted base pairs. It directly affects the number of predicted base pairs. A higher value leads to a higher number of base pairs predicted. It should be a positive number. In the default behavior, when no specific value is provided, the default value for each secondary structure prediction method in the rtools webserver is used (4 for centroidFold and IPknot, and 8 forcentroidHomFold). |
inferenceEngine |
engine used to identify optimal secondary structures. Possible values are "BL", "Turner" and "CONTRAfold". In the first two cases, a McCaskill partition function is applied, using respectively the Boltzmann likelihood model or Turner's energy model. In the third case, the CONTRAfold engine, based on conditional log-linear models, is applied. Additionally, if IPknot is chosen as the method for secondary structure prediction, "NUPACK" is also a possible value if the sequence has 100 nucleotides or less. In this case, the NUPACK scoring model is used. In the default behavior, when no specific value is provided, the default inference engine in the rtools webserver is, which is a McCaskill partition function with a Boltzmann likelihood model. |
alignmentEngine |
engine used to perform pairwise alignments of the query sequence and Rfam homologous sequences during the application of centroidHomFold. Possible values are "CONTRAlign" and "ProbCons". For details on each alignment engine, see Do et al., 2006 and Do et al., 2005 respectively. In the default behavior, when no value is specified, CONTRAlign is used. |
eValueRfamSearch |
e-value used to select homologous sequences from the Rfam database during the application of centroidHomFold. Should be a number equal to or greater than 0. In the default behavior, when no value is specified, a value of 0.01 is used. |
numHomSeqsRfamSearch |
maximum number of homologous sequences to be considered during the application of centroidHomFold. Should be a positive integer.In the default behavior, when no value is specified, a value of 30 is used. |
Value
If either centroidFold or centroidHomFold are used for predicting secondary structure, a list of three elements comprising the query RNA sequence, the predicted secondary structure and a table of base pair probabilities. The secondary structure is represented as a string in the Dot-Bracket format. The three elements of the list are:
sequence |
Query RNA sequence |
secondaryStructure |
Predicted secondary structure |
basePairProbabilities |
A dataframe where each line corresponds to a nucleotide of the query RNA sequence. The first column indicates the position number, the second column indicates the corresponding nucleotide type and additional columns indicating the probability of forming a base pair with other nucleotides. The potentially pairing nucleotides and their corresponding probabilities are provided as strings, where a colon separates both fields |
If IPknot is used for predicting secondary structure, no table of base pair probabilities is returned. Therefore, the output is a list of only two elements (sequence and secondaryStructure). Additionally, the secondary structure is provided in the extended Dot-Bracket format if required to represent pseudoknots unambiguously.
References
Andronescu M, Condon A, Hoos HH, Mathews DH, Murphy KP. Computational approaches for RNA energy parameter estimation. RNA. 2010;16(12):2304-2318. doi:10.1261/rna.1950510
Do C.B., Gross S.S., Batzoglou S. CONTRAlign: Discriminative Training for Protein Sequence Alignment. In: Apostolico A., Guerra C., Istrail S., Pevzner P.A., Waterman M. (eds) Research in Computational Molecular Biology. 2006. Lecture Notes in Computer Science, vol 3909. Springer, Berlin, Heidelberg doi:10.1007/11732990_15
Do CB, Mahabhashyam MS, Brudno M, Batzoglou S. ProbCons: Probabilistic consistency-based multiple sequence alignment. Genome Res. 2005;15(2):330-340. doi:10.1101/gr.2821705
Do CB, Woods DA, Batzoglou S. CONTRAfold: RNA secondary structure prediction without physics-based models. Bioinformatics. 2006;22(14):e90-e98. doi:10.1093/bioinformatics/btl246
Hamada M, Kiryu H, Sato K, Mituyama T, Asai K. Prediction of RNA secondary structure using generalized centroid estimators. Bioinformatics. 2009;25(4):465-473. doi:10.1093/bioinformatics/btn601
Hamada M, Ono Y, Kiryu H, et al. Rtools: a web server for various secondary structural analyses on single RNA sequences. Nucleic Acids Res. 2016;44(W1):W302-W307. doi:10.1093/nar/gkw337
Hamada M, Yamada K, Sato K, Frith MC, Asai K. CentroidHomfold-LAST: accurate prediction of RNA secondary structure using automatically collected homologous sequences. Nucleic Acids Res. 2011;39(Web Server issue):W100-W106. doi:10.1093/nar/gkr290
Mathews DH, Sabina J, Zuker M, Turner DH. Expanded sequence dependence of thermodynamic parameters improves prediction of RNA secondary structure. J Mol Biol. 1999;288(5):911-940. doi:10.1006/jmbi.1999.2700
Sato K, Kato Y, Hamada M, Akutsu T, Asai K. IPknot: fast and accurate prediction of RNA secondary structures with pseudoknots using integer programming. Bioinformatics. 2011;27(13):i85-i93. doi:10.1093/bioinformatics/btr215
http://rtools.cbrc.jp/
Examples
1 2 3 4 5 6 7 8 | # Predict the secondary structure of an RNA sequence with IPknot:
structurePrediction <- predictSecondaryStructure("UGCGAGAGGCACAGGGUUCGAUUCCCUGCA
UCUCCA", "IPknot", inferenceEngine = "NUPACK")
# Extract the string representing the secondary structure prediction:
structurePrediction$secondaryStructure
|
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