699 lines
30 KiB
Text
699 lines
30 KiB
Text
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@0. B 1 @MEP
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This is a program for analysing families of nucleotide sequences in
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order to find common motifs and potential binding sites. The ideas
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in this program were described in Staden, R. "Methods for
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discovering novel motifs in nucleic acid sequences". Computer
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Applications in the Biosciences, 5, 293-298, (1989).
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The program can read sequences stored in either of two
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formats: 1) all sequences aligned in a single file; 2) all sequences
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in separate files and accessed through a file of file names.
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The program contains functions that can answer several
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questions about a set of sequences:
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Which words are most common?
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Which words occur in the most sequences?
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Which words contain the most information?
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Which words occur in equivalent positions in the sequences?
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Which words are inverted repeats?
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Which words occur on both strands of the sequences?
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Where are the inverted repeats?
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Where are the fuzzy words?
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Most of the program is concerned with analysing what it terms
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"fuzzy words" within the set of sequences. The analysis is explained
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below. Note that the standard version of the programs is limited to
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words of maximum length 8 letters, and a maximum fuzziness of 2.
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The following analyses (preceded by their option numbers) are
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included:
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? = Help
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! = Quit
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3 = Read new sequences
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4 = Redefine active region
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5 = List the sequences
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6 = List text file
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7 = Direct output to disk
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10 = Clear graphics
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11 = Clear text
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12 = Draw ruler
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13 = Use cross hair
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14 = Reset margins
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15 = Label diagram
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16 = Draw map
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17 = Search for strings
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18 = Set strand
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19 = Set composition
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20 = Set word length
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21 = Set number of mismatches
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22 = Show settings
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23 = Make dictionary Dw
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24 = Make dictionary Ds
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25 = Make fuzzy dictionary Dm from Dw
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26 = Make fuzzy dictionary Dm from Ds
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27 = Make fuzzy dictionary Dh from Dm
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28 = Examine fuzzy dictionary Dm
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29 = Examine fuzzy dictionary Dh
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30 = Examine words in Dm
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31 = Examine words in Dh
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32 = Save or restore a dictionary
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33 = Find inverted repeats
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Some of these methods produce graphical results and so the
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program is generally used from a graphics terminal (a vdu on which
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lines and points can be drawn as well as characters).
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The positions of each of the plots is defined relative to a users
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drawing board which has size 1-10,000 in x and 1-10,000 in y. Plots
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for each option are drawn in a window defined by x0,y0 and
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xlength,ylength. Where x0,y0 is the position of the bottom left hand
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corner of the window, and xlength is the width of the window and
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ylength the height of the window.
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--------------------------------------------------------- 10,000
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1 1
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1 -------------------------------------- ^ 1
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1 1 1 1 1
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1 1 1 1 1
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1 1 1 ylength 1
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1 1 1 1 1
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1 1 1 1 1
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1 -------------------------------------- v 1
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1 x0,y0^ 1
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1 <---------------xlength--------------> 1
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--------------------------------------------------------- 1
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1 10,000
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All values are in drawing board units (i.e. 1-10,000, 1-10,000).
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The default window positions are read from a file "MEPMARG" when the
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program is started. Users can have their own file if required.
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The options for the program are accessed from 3 main menus:
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general, screen control and dictionary analylsis. Both menus and
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options are selected by number.
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The most important and novel part of the program is its use of
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"fuzzy dictionaries" and an information theory measure, to help show
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the most interesting motifs. Central to the method is the idea of a
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fuzzy dictionary of word frequencies. A dictionary of word
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frequencies is an ordered list of all the words in the sequences and
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a count of the number of times that they occur. A fuzzy dictionary
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is an equivalent list but which contains instead, for each word, a
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count of the number of times similar words occur in the sequences.
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We term words that are similar "relations". The fuzziness is defined
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by the number of letters in a word that are allowed to be different.
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So if we had a fuzziness of 1 we allow 1 letter to be different. For
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example, with a fuzziness of 1, the entry in the fuzzy dictionary
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for the word TTTTTT would contain a count of the numbers of times
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TTTTTT occured plus the number of times all words differing by
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exactly one letter from TTTTTT occured.
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Once the fuzzy dictionary has been created we can examine it
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in several ways to find candidate control sequences. The simplest
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question we can ask is which word in the dictionary is the most
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common. Sometimes this simple criterion of "most common" may be
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adequate to discover a new motif but in general we would not expect
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it to be sufficient. For example some words will be common simply
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because of a base composition bias in the sequences being analysed.
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In addition a word can be the most frequent and yet not be "well
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defined". This last point is best explained by an example.
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Suppose we were looking at two letter words and allowing one
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mismatch, and that there were 10 occurences of TT and 5 of AC. We
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could align the 10 words that were one letter different from TT and
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the 5 that were related to AC. Then we could count the number of
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times each base occured in each position for each of these two sets
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of words. Suppose we got the two base frequency tables shown below.
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TT AC
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T 6 4 T 1 0
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C 1 3 C 0 4
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A 1 2 A 4 1
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G 2 1 G 0 0
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These tables show that although TT occurs (with one letter mismatch)
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more often than AC, the ratio of base frequencies for AC at 4/5, 4/5
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is higher than those for TT at 6/10, 4/10. Hence we would say that
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AC was better defined than TT. Expressing this another way we would
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say that the definition of AC contained more information than that
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for TT. The program calculates the information content in a way that
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takes into account both the sequence composition and the level of
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definition of the motif.
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Definitions
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Here we deal only with the dictionary analysis. Suppose we
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are dealing with a set of sequences and are examining them for words
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that are six characters in length.
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Dictionary Dw contains a count of the number of times each
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word occurs in the set of sequences. For example the entry for
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TTTTTT contains a value equal to the number of times the word TTTTTT
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occurs in the set of sequences.
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Dictionary Ds contains a count of the number of different
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sequences in which each word occurs. For example if the entry for
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word TTTTTT contains the value 10, it denotes that the word TTTTTT
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occurs in ten different sequences. Unlike Dw it only counts words
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once for each sequence. For example if we had a set of 100
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sequences, the maximum possible value that Ds could take is 100, and
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this would only happen if a word occurred in every sequence. However
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for the same set of sequences, Dw could contain values greater than
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100, and this would show that a word had occurred more than once in
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at least one sequence.
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From either of the two dictionaries Dw or Ds we can calculate
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a fuzzy dictionary Dm. For each word, the entry in the fuzzy
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dictionary Dm contains the sum of the dictionary values (taken from
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either Dw or Ds) for all words that differ from it by up to m
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letters. For example if m=2 the entry for TTTTTT contains the number
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of times that TTTTTT occurs in the dictionary, plus the counts for
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all words that differ from TTTTTT by 1 or 2 letters. Obviously the
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interpretation of the values in Dm depends on which of the two
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dictionaries Dw or Ds they were derived from. When derived from Dw
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the entry for any word in Dm gives the total number of times it, and
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its relations, occur in the set of sequences. When derived from Ds
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the entry for any word in Dm gives the total number of different
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sequences that contain a word and each of its relations.
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Finally, from fuzzy dictionary Dm we can derive fuzzy
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dictionary Dh. All entries in Dh are zero except for the word(s),
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within each set of relations, that are most frequent. For example if
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TTTTTT occurred 20 times but had a relation that occurred more
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often, then the entry for TTTTTT would be zero. However if TTTTTT
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did not have a more frequently occurring relation, then the entry
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for TTTTTT would contain the value 20.
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@1. B 1 @Help
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This option gives online help. The user should select option numbers
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and the current documentation will be given. Note that option 0
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gives an introduction to the program, and that ? will get help from
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anywhere in the program. The following analyses (preceded by their
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option numbers) are included:
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? = Help
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! = Quit
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3 = Read new sequences
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4 = Redefine active region
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5 = List the sequences
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6 = List text file
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7 = Direct output to disk
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10 = Clear graphics
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11 = Clear text
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12 = Draw ruler
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13 = Use cross hair
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14 = Reset margins
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15 = Label diagram
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16 = Draw map
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17 = Search for strings
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18 = Set strand
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19 = Set composition
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20 = Set word length
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21 = Set number of mismatches
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22 = Show settings
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23 = Make dictionary Dw
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24 = Make dictionary Ds
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25 = Make fuzzy dictionary Dm from Dw
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26 = Make fuzzy dictionary Dm from Ds
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27 = Make fuzzy dictionary Dh from Dm
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28 = Examine fuzzy dictionary Dm
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29 = Examine fuzzy dictionary Dh
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30 = Examine words in Dm
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31 = Examine words in Dh
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32 = Save or restore a dictionary
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33 = Find inverted repeats
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@2. B 1 @Quit
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This function stops the program.
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@3. B 1 @Read a new sequence.
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It can read sequences stored in either of two formats: 1) all
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sequences aligned in a single file; 2) all sequences in separate
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files and accessed through a file of file names. Typical dialogue
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follows:
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X 1 Read file of aligned sequences
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2 Use file of file names
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? 0,1,2 =
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? File of aligned sequences=F1
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Number of files 88
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@4. B 1 @Define active region
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For its analytic functions the program always works on a region of
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the sequence called the active region. When new sequences are read
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into the program the active region is automatically set to start at
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the beginning of the sequences and go up to the end of the longest
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one.
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@5. B 1 @List a sequence.
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The sequence can be listed with line lengths of 50 bases with each
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sequence numbered in the order in which they were read. Output can
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be directed to a disk file by first selecting disk output. Typical
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dialogue follows.
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? Menu or option number=5
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10 20 30 40 50
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1 TAGCGGATCCTACCTGACGCTTTTTATCGCAACTCTCTACTGTTTCTCCA
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2 CAAATAATCAATGTGGACTTTTCTGCCGTGATTATAGACACTTTTGTTAC
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3 TAATTTATTCCATGTCACACTTTTCGCATCTTTGTTATGCTATGGTTATT
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4 ACTAATTTATTCCATGTCACACTTTTCGCATCTTTGTTATGCTATGGTTA
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5 AGGCACCCCAGGCTTTACACTTTATGCTTCCGGCTCGTATGTTGTGTGGA
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6 TAATGTGAGTTAGCTCACTCATTAGGCACCCCAGGCTTTACACTTTATGC
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7 ACACCATCGAATGGCGCAAAACCTTTCGCGGTATGGCATGATAGCGCCCG
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8 GGGGCAAGGAGGATGGAAAGAGGTTGCCGTATAAAGAAACTAGAGTCCGT
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9 AGGGGGTGGAGGATTTAAGCCATCTCCTGATGACGCATAGTCAGCCCATC
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10 AAAACGTCATCGCTTGCATTAGAAAGGTTTCTGGCCGACCTTATAACCAT
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60
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1 TACCCGTTTTT
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2 GCGTTTTTGT
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3 TCATACCATAAG
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4 TTTCATACC
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5 ATTGTGAGC
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6 TTCCGGCTCG
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7 GAAGAGAGT
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8 TCAGGTGT
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9 ATGAATG
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10 TAATTACG
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@6. B 1 @List a text file.
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Allows the user to have a text file displayed on the screen. It will
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appear one page at a time.
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@7. B 1 @Direct output to disk
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Used to direct output that would normally appear on the screen
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to a file.
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Select redirection of either text or graphics, and supply the
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name of the file that the output should be written to.
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The results from the next options selected will not appear on
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the screen but will be written to the file. When option 7 is
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selected again the file will be closed and output will again appear
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on the screen.
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@10. B 1 @Clear graphics
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Clears the screen of both text and graphics.
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@11. B 1 @Clear text
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Clears only text from the screen.
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@12. B 1 @Draw a ruler.
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This option allows the user to draw a ruler or scale along the x
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axis of the screen to help identify the coordinates of points of
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interest. The user can define the position of the first amino acid
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to be marked (for example if the active region is 1501 to 8000, the
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user might wish to mark every 1000th amino acid starting at either
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1501 or 2000 - it depends if the user wishes to treat the active
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region as an independent unit with its own numbering starting at its
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left edge, or as part of the whole sequence). The user can also
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define the separation of the ticks on the scale and their height. If
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required the labelling routine can be used to add numbers to the
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ticks.
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@13. B 1 @Use crosshair.
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This function puts a steerable cross on the screen that can be used
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to find the coordinates of points in the sequence. The user can move
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the cross around using the directional keys; when he hits the space
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bar the program will print out the coordinates of the cross in
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sequence units and the option will be exited.
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If instead, you hit a , the position will be displayed but the
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cross will remain on the screen.
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If a letter s is hit the sequence around the cross hair is
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displayed and the cross remains on the screen.
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@14. B 1 @Reposition plots
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The positions of each of the plots is defined relative to a users
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drawing board which has size 1-10,000 in x and 1-10,000 in y. Plots
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for each option are drawn in a window defined by x0,y0 and
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xlength,ylength. Where x0,y0 is the position of the bottom left hand
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corner of the window, and xlength is the width of the window and
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ylength the height of the window.
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--------------------------------------------------------- 10,000
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1 1
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1 -------------------------------------- ^ 1
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1 1 1 1 1
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1 1 1 1 1
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1 1 1 ylength 1
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1 1 1 1 1
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1 1 1 1 1
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1 -------------------------------------- v 1
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1 x0,y0^ 1
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1 <---------------xlength--------------> 1
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--------------------------------------------------------- 1
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1 10,000
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All values are in drawing board units (i.e. 1-10,000, 1-10,000).
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The default window positions are read from a file "MEPMARG" when the
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program is started. Users can have their own file if required. As
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all the plots start at the same position in x and have the same
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width, x0 and xlength are the same for all options. Generally users
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will only want to change the start level of the window y0 and its
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height ylength. This option allows users to change window positions
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whilst running the program. The routine prompts first for the
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number of the option that the users wishes to reposition; then for
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the y start and height; then for the x start and length. Note that
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changes to the x values affect all options. If the user types only
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carriage return for any value it will remain unchanged. The cross-
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hair can be used to choose suitable heights.
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@15. B 1 @Label a diagram
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This routine allows users to label any diagrams they have produced.
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They are asked to type in a label. When the user types carriage
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return to finish typing the label the cross-hair appears on the
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screen. The user can position it anywhere on the screen. If the user
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types R (for right justify) the label will be written on the diagram
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with its right end at the cross-hair position. If the user types L
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(for left justify) the label will be written on the diagram with its
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left end at the cross hair position. The cross-hair will then
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immediately reappear. The user may put the same label on another
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part of the diagram as before or if he hits the space bar he will be
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asked if he wishes to type in another label.
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@16. B 1 @Display a map.
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It is often convenient to plot a map alongside graphed analysis in
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order to indicate features within the sequence. This function allows
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users to draw maps using files arranged in the form of EMBL feature
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tables. Of course the EMBL table are usually only used for nucleic
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acid sequence annotation but, as long as the features are written in
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the correct format, they can be employed by this routine. The map is
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composed of a line representing the sequence and then further lines
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denoting the endpoints of each feature the user identifies. The user
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is asked to define height at which the line representing the
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sequence should be drawn; then for the feature height; then for the
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features to plot.
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@17. B 1 @Search for strings
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Search for strings perfoms searches of all the sequences for
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selected words and shows which sequences they are found in. The user
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types in a word and defines the allowed number of mismatches. The
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results are listed or plotted. If listed the display includes the
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sequence number, the position in the sequence and the matching
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string. The results are plotted in the following way. The x axis of
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the plot represents the length of the aligned sequences and the y
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direction is divided into sufficient strips to accommodate each
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sequence. So if a match is found in the 3rd sequence at a position
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equivalent to halfway along the longest of the sequences then a
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short vertical line will be drawn at the midpoint of the 3rd strip.
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If the sequences are aligned it can be useful if the motifs happen
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to appear in related positions. For example see the original
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publication. Typical dialogue follows.
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? Menu or option number=17
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X 1 Plot match positions
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2 Plot histogram of matches
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? 0,1,2 =
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? Word to search for=TTGACA
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? Minimum match (0-6) (6) =5
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? (y/n) (y) Plot results N
|
||
|
2 35 TAGACA
|
||
|
5 14 TTTACA
|
||
|
6 37 TTTACA
|
||
|
11 14 TAGACA
|
||
|
14 14 TTGACA
|
||
|
17 14 GTGACA
|
||
|
17 22 TTAACA
|
||
|
20 1 TTGACA
|
||
|
@18. B 1 @Set strand
|
||
|
Set strand allows the user to define which strand(s) of the
|
||
|
sequences to analyse: input stand, complement of input, or both.
|
||
|
@19. B 1 @Set composition
|
||
|
Set composition gives the user three choices for setting the
|
||
|
composition of the sequences for use in the calculation of the
|
||
|
information content of words. The user can select the overall
|
||
|
composition of the sequences as read, an even composition, or can
|
||
|
type in any other 4 values.
|
||
|
@20. B 1 @Set word length
|
||
|
Set word length sets the length of word for which dictionaries will
|
||
|
be made.
|
||
|
@21. B 1 @Set number of mismatches
|
||
|
Set number of mismatches sets the level of fuzziness for the
|
||
|
creation of dictionary Dm.
|
||
|
@22. B 1 @Show settings
|
||
|
Show settings show the current settings for all parameters
|
||
|
associated with dictionary analysis. A typical diaplsy follows:
|
||
|
? Menu or option number=22
|
||
|
Current word length = 6
|
||
|
Number of mismatches = 1
|
||
|
Start position = 1
|
||
|
End position = 63
|
||
|
Input strand only
|
||
|
Observed composition
|
||
|
Dictionary Dw unmade
|
||
|
Dictionary Ds unmade
|
||
|
Dictionary Dm unmade
|
||
|
Dictionary Dh unmade
|
||
|
@23. B 1 @Make dictionary Dw
|
||
|
Make dictionary Dw creates a dictionary that contains a count of
|
||
|
the frequency of occurrence of each word in the collected sequences.
|
||
|
@24. B 1 @Make dictionary Ds
|
||
|
Make dictionary Ds creates a dictionary that contains a count of the
|
||
|
number of different sequences that contain each word.
|
||
|
@25. B 1 @Make dictionary Dm from Dw
|
||
|
Make dictionary Dm from Dw creates a dictionary from dictionary Dw
|
||
|
that contains the frequency of occurrence of each word (say X) in Dw
|
||
|
plus the frequency of occurrence of each word in Dw that differs
|
||
|
from X by up to m letters. Dm is called a fuzzy dictionary as it
|
||
|
contains the frequencies of occurrence of all words plus the
|
||
|
frequencies of all the words that are similar to them.
|
||
|
@26. B 1 @Make dictionary Dm from Ds
|
||
|
Make dictionary Dm from Ds creates a dictionary from dictionary Ds
|
||
|
that contains the frequency of occurrence of each word (say X) in Ds
|
||
|
plus the frequency of occurrence of each word in Ds that differs
|
||
|
from X by up to m letters. Dm is called a fuzzy dictionary as it
|
||
|
contains the frequencies of occurrence of all words plus the
|
||
|
frequencies of all the words that are similar to them.
|
||
|
@27. B 1 @Make dictionary Dh from Dm
|
||
|
Make dictionary Dh creates a dictionary from dictionary Dm and
|
||
|
whose entries are zero except for those words in any set of related
|
||
|
words that are most frequent. It finds the dominant words in each
|
||
|
set of relations and stores their counts.
|
||
|
@28. B 1 @Examine dictionary Dm
|
||
|
Examine dictionary Dm allows users to analyse the contents of
|
||
|
dictionary Dm to find the most common words or those words that
|
||
|
contain the most information. The user supplies a frequency or
|
||
|
information cutoff and chooses to have the results sorted on either
|
||
|
value. The program will find the top 100 words that achieve the
|
||
|
cutoff values and present them to the user sorted as selected. The
|
||
|
information content will be calcutated from either Dw or Ds
|
||
|
depending which was used to create Dm, and using the current
|
||
|
composition setting. Typical dialogue follows:
|
||
|
|
||
|
? Menu or option number=28
|
||
|
Looking for highest scoring words
|
||
|
The highest word score = 115
|
||
|
? Minimum word score (0-115) (0) =60
|
||
|
? Minimum information (0.00-1.00) (0.00) =.62
|
||
|
X 1 Sort on information
|
||
|
2 Sort on word score
|
||
|
? 0,1,2 =
|
||
|
|
||
|
? Maximum number to list (0-100) (100) =
|
||
|
|
||
|
The words are
|
||
|
Total words= 9 Maximum information= 0.7385326
|
||
|
TTGACA 60 0.73850
|
||
|
AAAAAC 64 0.66460
|
||
|
AAAAAA 90 0.64880
|
||
|
GTTTTT 66 0.64300
|
||
|
TTTTTG 73 0.64070
|
||
|
TTTTGT 63 0.63820
|
||
|
TTTTTC 65 0.63810
|
||
|
AAAATA 63 0.62670
|
||
|
TATAAT 65 0.62510
|
||
|
The highest word score = 115
|
||
|
? Minimum word score (0-115) (0) =60
|
||
|
? Minimum information (0.00-1.00) (0.00) =.62
|
||
|
X 1 Sort on information
|
||
|
2 Sort on word score
|
||
|
? 0,1,2 =2
|
||
|
? Maximum number to list (0-100) (100) =
|
||
|
|
||
|
The words are
|
||
|
Total words= 9 Maximum information= 0.7385326
|
||
|
AAAAAA 90 0.64880
|
||
|
TTTTTG 73 0.64070
|
||
|
GTTTTT 66 0.64300
|
||
|
TTTTTC 65 0.63810
|
||
|
TATAAT 65 0.62510
|
||
|
AAAAAC 64 0.66460
|
||
|
TTTTGT 63 0.63820
|
||
|
AAAATA 63 0.62670
|
||
|
TTGACA 60 0.73850
|
||
|
The highest word score = 115
|
||
|
? Minimum word score (0-115) (0) =!
|
||
|
|
||
|
@29. B 1 @Examine dictionary Dh
|
||
|
Examine dictionary Dh allows users to analyse the contents of
|
||
|
dictionary Dh to find the most common words or those words that
|
||
|
contain the most information. The user supplies a frequency or
|
||
|
information cutoff and chooses to have the results sorted on either
|
||
|
value. The program will find the top 100 words that achieve the
|
||
|
cutoff values and present them to the user sorted as selected. The
|
||
|
information content will be calcutated from either Dw or Ds
|
||
|
depending which was used to create Dh and using the current
|
||
|
composition setting. Typical dialogue follows:
|
||
|
|
||
|
? Menu or option number=29
|
||
|
Looking for highest scoring words
|
||
|
The highest word score = 115
|
||
|
? Minimum word score (0-115) (0) =60
|
||
|
? Minimum information (0.00-1.00) (0.00) =.6
|
||
|
X 1 Sort on information
|
||
|
2 Sort on word score
|
||
|
? 0,1,2 =
|
||
|
|
||
|
? Maximum number to list (0-100) (100) =
|
||
|
|
||
|
The words are
|
||
|
Total words= 4 Maximum information= 0.7385326
|
||
|
TTGACA 60 0.73850
|
||
|
AAAAAA 90 0.64880
|
||
|
TATAAT 65 0.62510
|
||
|
TTTTTT 115 0.60630
|
||
|
The highest word score = 115
|
||
|
? Minimum word score (0-115) (0) =50
|
||
|
? Minimum information (0.00-1.00) (0.00) =.5
|
||
|
X 1 Sort on information
|
||
|
2 Sort on word score
|
||
|
? 0,1,2 =
|
||
|
|
||
|
? Maximum number to list (0-100) (100) =
|
||
|
|
||
|
The words are
|
||
|
Total words= 8 Maximum information= 0.7385326
|
||
|
TTGACA 60 0.73850
|
||
|
TCTTGA 54 0.66080
|
||
|
AAAAAA 90 0.64880
|
||
|
TATAAT 65 0.62510
|
||
|
ACTTTA 57 0.61960
|
||
|
TTTTTT 115 0.60630
|
||
|
AGTATA 51 0.60540
|
||
|
TTATAA 55 0.59300
|
||
|
The highest word score = 115
|
||
|
? Minimum word score (0-115) (0) =50
|
||
|
? Minimum information (0.00-1.00) (0.00) =
|
||
|
|
||
|
X 1 Sort on information
|
||
|
2 Sort on word score
|
||
|
? 0,1,2 =
|
||
|
|
||
|
? Maximum number to list (0-100) (100) =
|
||
|
|
||
|
The words are
|
||
|
Total words= 8 Maximum information= 0.7385326
|
||
|
TTGACA 60 0.73850
|
||
|
TCTTGA 54 0.66080
|
||
|
AAAAAA 90 0.64880
|
||
|
TATAAT 65 0.62510
|
||
|
ACTTTA 57 0.61960
|
||
|
TTTTTT 115 0.60630
|
||
|
AGTATA 51 0.60540
|
||
|
TTATAA 55 0.59300
|
||
|
The highest word score = 115
|
||
|
? Minimum word score (0-115) (0) =!
|
||
|
|
||
|
@30. B 1 @Examine words in Dm
|
||
|
Examine words in Dm allows users to analyse the contents of
|
||
|
dictonary Dm at the level of individual words to find their
|
||
|
frequency, information content, and to see their base frequency
|
||
|
table. The user types in a word to examine and the program displays
|
||
|
the values and table. The information content will be calcutated
|
||
|
from either Dw or Ds depending which was used to create Dm, and
|
||
|
using the current composition setting. Typical dialogue follows:
|
||
|
? Menu or option number=30
|
||
|
? Word to examine=TTGACA
|
||
|
TtgacA 60 0.7385326
|
||
|
56 56 6 7 5 11
|
||
|
4 3 2 1 52 1
|
||
|
1 4 2 53 3 48
|
||
|
3 1 54 3 4 4
|
||
|
TTGACA
|
||
|
? Word to examine=TATAAT
|
||
|
taTAat 65 0.6251902
|
||
|
56 3 53 4 4 60
|
||
|
6 1 5 5 5 3
|
||
|
3 60 5 57 57 4
|
||
|
4 5 6 3 3 2
|
||
|
TATAAT
|
||
|
? Word to examine=
|
||
|
|
||
|
@31. B 1 @Examine words in Dh
|
||
|
Examine words in Dh allows users to analyse the contents of
|
||
|
dictonary Dh at the level of individual words to find their
|
||
|
frequency, information content, and to see their base frequency
|
||
|
table. The user types in a word to examine and the program displays
|
||
|
the values and table. The information content will be calcutated
|
||
|
from either Dw or Ds depending which was used to create Dm, and
|
||
|
using the current composition setting. Typical dialogue follows:
|
||
|
|
||
|
? Menu or option number=31
|
||
|
? Word to examine=TTGACA
|
||
|
TtgacA 60 0.7385326
|
||
|
56 56 6 7 5 11
|
||
|
4 3 2 1 52 1
|
||
|
1 4 2 53 3 48
|
||
|
3 1 54 3 4 4
|
||
|
TTGACA
|
||
|
? Word to examine=TATAAT
|
||
|
taTAat 65 0.6251902
|
||
|
56 3 53 4 4 60
|
||
|
6 1 5 5 5 3
|
||
|
3 60 5 57 57 4
|
||
|
4 5 6 3 3 2
|
||
|
TATAAT
|
||
|
? Word to examine=GGGGGG
|
||
|
gggggg 0 0.6199890
|
||
|
3 1 1 2 3 4
|
||
|
1 3 1 2 2 1
|
||
|
2 1 1 1 1 1
|
||
|
11 12 14 12 11 11
|
||
|
GGGGGG
|
||
|
? Word to examine=
|
||
|
|
||
|
@32. B 1 @Save or restore a dictionary
|
||
|
Save or restore dictionary allows users to write or read any
|
||
|
dictionary to and from disk files. The user is asked te define the
|
||
|
dictionary and file. The function is useful if the machine being
|
||
|
used is very slow at calculating because the files can be handled
|
||
|
quickly. However note that the files cannot be processed by any
|
||
|
other program.
|
||
|
@33. B 1 @Find inverted repeats
|
||
|
Find inverted repeats performs searches for simple inverted repeat
|
||
|
sequences in each sequence. They are defined by a range of loop
|
||
|
sizes and a minimum number of potential basepairs. The results can
|
||
|
be plotted or listed. The x axis of the plot represents the length
|
||
|
of the aligned sequences and the y direction is divided into
|
||
|
sufficient strips to accommodate each sequence. So if an inverted
|
||
|
repeat is found in the 3rd sequence at a position equivalent to
|
||
|
halfway along the longest of the sequences then a short vertical
|
||
|
line will be drawn at the midpoint of the 3rd strip. Alternatively,
|
||
|
if the results are listed, the potential hairpin loops are drawn
|
||
|
out, with the sequence number and the position of the loop. Typical
|
||
|
dialogue follows.
|
||
|
|
||
|
? Menu or option number=33
|
||
|
Define the range of loop sizes
|
||
|
? Minimum loop size (0-10) (3) =0
|
||
|
? Maximum loop size (1-20) (3) =
|
||
|
? Minimum number of basepairs (1-20) (6) =
|
||
|
? (y/n) (y) Plot results N
|
||
|
Searching
|
||
|
|
||
|
Sequence 3 34
|
||
|
C
|
||
|
G.T
|
||
|
T-A
|
||
|
A-T
|
||
|
T.G
|
||
|
T.G
|
||
|
G.T
|
||
|
ATCTTT TATTTCA
|
||
|
33
|
||
|
|
||
|
Sequence 5 35
|
||
|
T
|
||
|
G.T
|
||
|
T.G
|
||
|
A-T
|
||
|
T.G
|
||
|
G.T
|
||
|
C-G
|
||
|
T.G
|
||
|
TCCGGC AATTGTG
|
||
|
34
|
||
|
|
||
|
|
||
|
@ End of help
|