Provided by: vienna-rna_2.4.17+dfsg-2build2_amd64 
NAME
RNAaliduplex - manual page for RNAaliduplex 2.4.17
SYNOPSIS
RNAaliduplex [options] <file1.aln> <file2.aln>
DESCRIPTION
RNAaliduplex 2.4.17
Predict conserved RNA-RNA interactions between two alignments
The program reads two alignments of RNA sequences in CLUSTAL format and predicts optimal
and suboptimal binding sites, hybridization energies and the corresponding structures. The
calculation takes only inter-molecular base pairs into account, for the general case use
RNAcofold. The use of alignments allows one to focus on binding sites that are
evolutionary conserved. Note, that the two input alignments need to have equal number of
sequences and the same order, i.e. the 1st sequence in file1 will be hybridized to the 1st
in file2 etc.
The computed binding sites, energies, and structures are written to stdout, one structure
per line. Each line consist of: The structure in dot bracket format with a "&" separating
the two strands. The range of the structure in the two sequences in the format "from,to :
from,to"; the energy of duplex structure in kcal/mol. The format is especially useful for
computing the hybrid structure between a small probe sequence and a long target sequence.
-h, --help
Print help and exit
--detailed-help
Print help, including all details and hidden options, and exit
-V, --version
Print version and exit
General Options:
Below are command line options which alter the general behavior of this program
-e, --deltaEnergy=range
Compute suboptimal structures with energy in a certain range of the optimum
(kcal/mol). Default is calculation of mfe structure only.
-s, --sorted
print output sorted by free energy
(default=off)
Model Details:
-T, --temp=DOUBLE
Rescale energy parameters to a temperature of temp C. Default is 37C.
-4, --noTetra
Do not include special tabulated stabilizing energies for tri-, tetra- and hexaloop
hairpins. Mostly for testing.
(default=off)
-d, --dangles=INT
How to treat "dangling end" energies for bases adjacent to helices in free ends and
multi-loops
(default=`2')
With -d1 only unpaired bases can participate in at most one dangling end. With -d2
this check is ignored, dangling energies will be added for the bases adjacent to a
helix on both sides in any case; this is the default for mfe and partition function
folding (-p). The option -d0 ignores dangling ends altogether (mostly for
debugging). With -d3 mfe folding will allow coaxial stacking of adjacent helices
in multi-loops. At the moment the implementation will not allow coaxial stacking of
the two interior pairs in a loop of degree 3 and works only for mfe folding.
Note that with -d1 and -d3 only the MFE computations will be using this setting
while partition function uses -d2 setting, i.e. dangling ends will be treated
differently.
--noLP Produce structures without lonely pairs (helices of length 1).
(default=off)
For partition function folding this only disallows pairs that can only occur
isolated. Other pairs may still occasionally occur as helices of length 1.
--noGU Do not allow GU pairs
(default=off)
--noClosingGU
Do not allow GU pairs at the end of helices
(default=off)
--nsp=STRING
Allow other pairs in addition to the usual AU,GC,and GU pairs.
Its argument is a comma separated list of additionally allowed pairs. If the first
character is a "-" then AB will imply that AB and BA are allowed pairs. e.g.
RNAfold -nsp -GA will allow GA and AG pairs. Nonstandard pairs are given 0
stacking energy.
-P, --paramFile=paramfile
Read energy parameters from paramfile, instead of using the default parameter set.
Different sets of energy parameters for RNA and DNA should accompany your
distribution. See the RNAlib documentation for details on the file format. When
passing the placeholder file name "DNA", DNA parameters are loaded without the need
to actually specify any input file.
REFERENCES
If you use this program in your work you might want to cite:
R. Lorenz, S.H. Bernhart, C. Hoener zu Siederdissen, H. Tafer, C. Flamm, P.F. Stadler and
I.L. Hofacker (2011), "ViennaRNA Package 2.0", Algorithms for Molecular Biology: 6:26
I.L. Hofacker, W. Fontana, P.F. Stadler, S. Bonhoeffer, M. Tacker, P. Schuster (1994),
"Fast Folding and Comparison of RNA Secondary Structures", Monatshefte f. Chemie: 125, pp
167-188
R. Lorenz, I.L. Hofacker, P.F. Stadler (2016), "RNA folding with hard and soft
constraints", Algorithms for Molecular Biology 11:1 pp 1-13
The energy parameters are taken from:
D.H. Mathews, M.D. Disney, D. Matthew, J.L. Childs, S.J. Schroeder, J. Susan, M. Zuker,
D.H. Turner (2004), "Incorporating chemical modification constraints into a dynamic
programming algorithm for prediction of RNA secondary structure", Proc. Natl. Acad. Sci.
USA: 101, pp 7287-7292
D.H Turner, D.H. Mathews (2009), "NNDB: The nearest neighbor parameter database for
predicting stability of nucleic acid secondary structure", Nucleic Acids Research: 38, pp
280-282
AUTHOR
Ivo L Hofacker, Ronny Lorenz
REPORTING BUGS
If in doubt our program is right, nature is at fault. Comments should be sent to
rna@tbi.univie.ac.at.
SEE ALSO
RNAduplex(1) RNAcofold(1) RNAfold(1)