Provided by: melting_5.2.0-2_all bug

NAME

       melting - compute the melting temperature of nucleic acid duplex

DESCRIPTION

       More  information  is  available  in  the  user-guide.  Type `man melting' to access it or
       consult one of the melting.xxx files, where xxx states for ps (postscript), pdf or html.

OPTIONS

       Information about MELTING 5:

       -h Displays this help and quit.

       -L Displays legal information and quit.

       -V Print the version number.

       -p Return path where to find the calorimetric tables.

       Mandatory options:

       -S [sequence]

              Nucleic acid sequence, mandatory. The sens of this sequence must be 5'-3'.

       -C [complementary sequence]

              Nucleic acid complementary sequence, mandatory only if there is  inosine  bases  or
              azobenznes  in  the  sequence  entered with the opton -S. The sens of this sequence
              must be 3'-5''.

       -E [agent1=concentration1:agent2=concentration2]

              Different agent concentrations in the solution. The agents can be cations  (Na,  K,
              Tris,  Mg for Na+, K+, Tris+ and Mg2+), dNTP or other agents (DMSO, formamide). The
              concentrations must be in  Mol/L  but  there  are  some  exceptions  :  DMSO  is  a
              percentage,  formamide is a percentage if the method lincorr is chosen and in Mol/L
              if the method bla96 is chosen. At least one cation concentration is mandatory,  the
              other  agents  are optional. See the documentation for the concentration limits. It
              depends on the used correction.

       -P [nucleotide concentration]

              Concentration in mol/L of the nucleic acid strand in excess, mandatory.

       -H [hybridization]

              Type of hybridization, mandatory. Four types of hybridization are allowed :  dnadna
              (DNA duplex), rnarna (RNA duplex), dnarna or rnadna (hybrid DNA/RNA) and mrnarna or
              rnamrna (2-o-methyl RNA/ RNA). The type of hybridization defines the  kind  of  the
              sequence and its complementary.

              Ex  :  dnarna = the sequence (entered with the option -S) is a DNA sequence and its
              complementary (entered with the option -C) is a RNA sequence.  Ex :  rnadna  =  the
              sequence  (entered  with  the  option  -S)  is a RNA sequence and its complementary
              (entered with the option -C) is a DNA sequence

       General options:

       -v

              Switch ON the verbose mode, issuing lot more info. Default is OFF.

       -T [threshold value]

              Threshold for approximative computation. Default is 60.

       -nnpath [folder pathway]

              Change the default pathway (Data) where to find  the  default  calorimetric  tables
              (thermodynamic parameters).

       -O [filename]

              To  write the results in an output file. filename is the name or the pathway of the
              file.

       -self

              To precise that the sequence entered with the option -S is self  complementary.  No
              complementary  sequence  is  mandatory. The program automatically can detect a self
              complementary sequence for perfect matching sequences or  sequences  with  dangling
              ends.  In  these  cases,  the  option  -self is not necessary, otherwise we need to
              precise that the sequences are self complementary.

       -F [factor value]

              Correction for the concentration of nucleic acid.  F  is  automatically  1  if  the
              sequences  are self complementary. Otherwise F is 4 if the both strands are present
              in equivalent amount and 1 if one strand is in excess. The default factor value  is
              4.

              Set of thermodynamic parameters and methods :

       By  default, the approximative mode is used for oligonucleotides longer than 60 bases (the
       default threshold value), otherwise the nearest neighbor model is used.

       -am [optional name]

              Forces to use a specific approximative formula. You can use one of the following :

       (DNA)  ahs01 (from von Ahsen et al. 2001) che93 (from Marmur 1962, Chester  et  al.  1993)
              che93corr  (from  von  Ahsen  et al. 2001, Marmur 1962, Chester et al. 1993) schdot
              (Marmur-Schildkraut-Doty formula)  owe69  (from  Owen  et  al.  1969)  san98  (from
              Santalucia et al. 1998) wetdna91 (from Wetmur 1991)  (by default)

       (RNA)  wetrna91 (from Wetmur 1991)  (by default)

       (DNA/RNA)
              wetdnarna91 (from Wetmur 1991)  (by default)

              If  there  is  no  formula  name  after the option -am, we will compute the melting
              temperature with the default approximative formula.

       -nn [optional name]

              Forces to use a specific nearest neighbor model. You can use one of the following :

       (DNA)  all97 (from Allawi and Santalucia 1997) (by default) bre86 (from Breslauer  et  al.
              1986)  san04  (from  Hicks and Santalucia 2004) san96 (from Santalucia et al. 1996)
              sug96 (from Sugimoto et al 1996) tan04 (from Tanaka et al. 2004)

       (RNA)  fre86 (from Freier al. 1986) xia98 (from Xia et al. 1998)  (by default)

       (DNA/RNA)
              sug95 (from Sugimoto et al. 1995)  (by default)

       (mRNA/RNA)
              tur06 (from Kierzek et al. 2006)  (by default)

              If there is no formula name after the option  -nn,  we  will  compute  the  melting
              temperature  with  the default nearest neighbor model.  Each nearest neighbor model
              uses a specific xml file containing the thermodynamic values. If you  want  to  use
              another  file,  write  the  file  name  or  the  file  pathway preceded by ':' (-nn
              [optionalname:optionalfile]).

              Ex : -nn tan04:fileName if you want to use the nearest neighbor model  from  Tanaka
              et  al.  2004  with  the  thermodynamic  parameters in the file fileName.  Ex : -nn
              :fileName if  you  want  to  use  the  default  nearest  neighbor  model  with  the
              thermodynamic parameters in the file fileName.

       -sinMM [name]

              Forces  to  use  a  specific  nearest neighbor model for single mismatch(es) in the
              sequences. You can use one of the following :

       (DNA)  allsanpey (from Allawi, Santalucia and Peyret 1997, 1998 and 1999)  (by default)

              (DNA/RNA)

              wat10 (from Watkins et al. 2011) (by default) (RNA)

       tur06 (from Lu et al. 2006)
              zno07 (from Davis et al. 2007)  (by default) zno08 (from Davis et al. 2008)

              To change the file containing the  thermodynamic  parameters  for  single  mismatch
              computation, the same syntax as the one for the -nn option is used.

       -GU [name]

              Forces to use a specific nearest neighbor model for GU base pairs in RNA sequences.
              You can use one of the following :

              tur99 (from Turner et al. 1999).  ser12 (from Serra et al. 2012) (by default)

              To change the file containing  the  thermodynamic  parameters  for  GU  base  pairs
              computation, the same syntax as the one for the -nn option is used.

       -tanMM [name]

              Forces  to  use  a  specific  nearest  neighbor  model for tandem mismatches in the
              sequences. You can use one of the following :

       (DNA)  allsanpey (from Allawi, Santalucia and Peyret 1997, 1998 and 1999)  (by default)

       (RNA)  tur99 (from Mathews et al. 1999)  (by default)

              To change the file containing the thermodynamic parameters  for  tandem  mismatches
              computation, the same syntax as the one for the -nn option is used.

       -intLP [name]

              Forces to use a specific nearest neighbor model for internal loop in the sequences.
              You can use one of the following :

       (DNA)  san04 (from Hicks and Santalucia 2004)  (by default)

       (RNA)  tur06 (from Lu et al. 2006)  (by default) zno07 (from Badhwarr et  al.  2007,  only
              for 1x2 loop)

              To  change  the  file  containing  the  thermodynamic  parameters for internal loop
              computation, the same syntax as the one for the -nn option is used.

       -sinDE [name]

              Forces to use a specific nearest neighbor model for single dangling end(s)  in  the
              sequences. You can use one of the following :

       (DNA)  bom00  (from  Bommarito  et  al.  2000)  (by default) sugdna02 (from Ohmichi et al.
              2002, only for polyA dangling ends)

       (RNA)  sugrna02 (from Ohmichi et al. 2002, only  for  polyA  dangling  ends)  ser08  (from
              Miller et al. 2008)  (by default)

              To  change the file containing the thermodynamic parameters for single dangling end
              computation, the same syntax as the one for the -nn option is used.

       -secDE [name]

              Forces to use a specific nearest neighbor model for second dangling end(s)  in  the
              sequences. You can use one of the following :

       (DNA)  sugdna02 (from Ohmichi et al. 2002, only for polyA dangling ends)  (by default)

       (RNA)  sugrna02  (from  Ohmichi  et  al.  2002,  only for polyA dangling ends) ser05 (from
              O'toole et al. 2005) ser06 (from O'toole et al. 2006)  (by default)

              To change the file containing the thermodynamic parameters for second dangling  end
              computation, the same syntax as the one for the -nn option is used.

       -lonDE [name]

              Forces  to  use  a  specific nearest neighbor model for long dangling end(s) in the
              sequences (self complementary sequences). You can use one of the following :

       (DNA)  sugdna02 (from Ohmichi et al. 2002, only for polyA dangling ends)  (by default)

       (RNA)  sugrna02 (from Ohmichi et al. 2002, only for polyA dangling ends)  (by default)

              To change the file containing the thermodynamic parameters for  long  dangling  end
              computation, the same syntax as the one for the -nn option is used.

       -sinBU [name]

              Forces  to  use  a  specific nearest neighbor model for single bulge loop(s) in the
              sequences. You can use one of the following :

       (DNA)  san04 (from Hicks and Santalucia  2004)  tan04  (from  Tanaka  et  al.  2004)   (by
              default)

       (RNA)  ser07 (from Blose et al. 2007) tur06 (from Lu et al. 1999 and 2006)  (by default)

              To  change  the  file containing the thermodynamic parameters for single bulge loop
              computation, the same syntax as the one for the -nn option is used.

       -lonBU [name]

              Forces to use a specific nearest neighbor model  for  long  bulge  loop(s)  in  the
              sequences. You can use one of the following :

       (DNA)  san04 (from Hicks and Santalucia 2004)  (by default)

       (RNA)  tur06 (from Mathews et al. 1999 and Lu et al 2006)  (by default)

              To  change  the  file  containing  the thermodynamic parameters for long bulge loop
              computation, the same syntax as the one for the -nn option is used.

       -CNG [name]

              Forces to use a specific nearest neighbor model for RNA sequences composed  of  CNG
              repeats  (G(CNG)xC  where N is a single N/N mismatch). You can only use bro05 (from
              Magdalena et al. 2005).  To change the file containing the thermodynamic parameters
              for  RNA  sequences composed of CNG repeats computation, the same syntax as the one
              for the -nn option is used.

       -ino [name]

              Forces to use a specific nearest  neighbor  model  for  inosine  base  (I)  in  the
              sequences. You can use one of the following :

       (DNA)  san05 (from Watkins and Santalucia 2005)  (by default)

       (RNA)  zno07 (from Wright et al. 2007)  (by default)

              To  change  the  file  containing  the  thermodynamic  parameters  for inosine base
              computation, the same syntax as the one for the -nn option is used.

       -ha [name]

              Forces to use a specific nearest neighbor model for hydroxyadenine base (A*) in DNA
              sequences.  You can only use sug01 (from Kawakami et al. 2001).  To change the file
              containing the thermodynamic parameters for hydroxyadenine  base  computation,  the
              same syntax as the one for the -nn option is used.

       -azo [name]

              Forces  to  use  a  specific  nearest  neighbor  model for DNA sequences containing
              azobenzene (cis : X_C or trans : X_T). You can only use asa05 (from Asanuma et  al.
              2005).   To  change the file containing the thermodynamic parameters for azobenzene
              computation, the same syntax as the one for the -nn option is used.

       -lck [name]

              Forces to use a specific nearest neighbor model for DNA sequences containing locked
              nucleic  acid  (Al,  Tl, Cl or Gl). You can use mct04 (from McTigue et al. 2004) or
              owc11 (from Owczarzy et al. 2011, by default).  To change the file  containing  the
              thermodynamic  parameters  for  locked acid nucleic computation, the same syntax as
              the one for the -nn option is used.

       -tanLck [name]

              Forces to use a specific  nearest  neighbor  model  for  DNA  sequences  containing
              consecutive  locked  nucleic  acid (Al, Tl, Cl or Gl). You can only use owc11 (from
              Owczarzy et al. 2011, by default).  To change the file containing the thermodynamic
              parameters  for locked acid nucleic computation, the same syntax as the one for the
              -nn option is used.

       -sinMMLck [name]

              Forces to use a specific  nearest  neighbor  model  for  DNA  sequences  containing
              consecutive  locked  nucleic acid with one single mismatch (Al, Tl, Cl or Gl).  You
              can use only owc11 (from Owczarzy et al. 2011, by default).   To  change  the  file
              containing  the  thermodynamic  parameters for locked acid nucleic computation, the
              same syntax as the one for the -nn option is used.

              Set of melting temperature corrections

       -ion [name]

              Forces to use a  specific  ion  correction.  You  can  use  one  of  the  following
              corrections : Sodium corrections :

       (DNA)  ahs01  (from  von  Ahsen  et  al.  2001)  kam71 (from Frank-Kamenetskii et al 2001)
              owc1904 (equation 19 from Owczarzy et al. 2004) owc2004 (equation 20 from  Owczarzy
              et  al.  2004) owc2104 (equation 21 from Owczarzy et al. 2004) owc2204 (equation 21
              from Owczarzy et al. 2004)  (by default) san96 (from Santalucia et al. 1996)  san04
              (from  Santalucia  et  al.  1998,  2004)  schlif (from Schildkraut and Lifson 1965)
              tanna06 (from Tan et al. 2006) wetdna91 (from Wetmur 1991)

       (RNA or 2-o methyl RNA)
              tanna07 (from Tan et al. 2007)  (by default) wetrna91 (from Wetmur 1991)

       (RNA/DNA)
              wetdnarna91 (from Wetmur 1991)  (by default)

              Magnesium corrections :

       (DNA)  owcmg08 (from Owczarzy et al. 2008)  (by default) tanmg06 (from Tan et al. 2006)

       (RNA or 2-o methyl RNA)
              tanmg07 (from Tan et al. 2007)  (by default)

              Mixed Na Mg corrections

       (DNA)  owcmix08 (from Owczarzy et al. 2008)  (by default) tanmix07 (from Tan et al. 2007)

       (RNA or 2-o methyl RNA)
              tanmix07 (from Tan et al. 2007)  (by default)

              By default, the program use the algorithm from Owczarzy et al 2008 : ratio = Mg^0.5
              and monovalent = Na + Tris + K

              if  monovalent  =  0,  a  magnesium  correction is used.  if ratio < 0.22, a sodium
              correction is used.  if 0.22 <= ratio < 6, a mixed Na Mg correction  is  used.   if
              ratio >= 6, a magnesium correction is used.

       -naeq [name]

              Forces   to  use  a  specific  ion  correction  which  gives  a  sodium  equivalent
              concentration if other cations are present. You can use one of the following :

       (DNA)  ahs01 (from von Ahsen et al 2001)  (by default) mit96 (from Mitsuhashi et al. 1996)
              pey00 (from Peyret 2000)

              For  the other types of hybridization, the DNA default correction is used but there
              is no guaranty of accuracy.

       -DMSO [name]

              Forces to use a specific DMSO correction (DMSO is always in percent). You  can  use
              one of the following :

       (DNA)  ahs01  (from von Ahsen et al 2001)  (by default) mus81 (from Musielski et al. 1981)
              cul76 (from Cullen et al. 1976) esc80 (from Escara et al. 1980).

              For the other types of hybridization, the DNA default correction is used but  there
              is no guaranty of accuracy.

       -for [name]

              Forces to use a specific formamide correction. You can use one of the following :

       (DNA)  bla96  (from  Blake et al 1996) with formamide concentration in mol/L  (by default)
              lincorr (linear correction) with a percent of formamide volume

              For the other types of hybridization, the DNA default correction is used but  there
              is no guaranty of accuracy.

AUTHOR

        This manpage was written by Pranav Ballaney for the Debian distribution and
        can be used for any other usage of the program.