Auxiliary version for preparing course notes

| 2019-02-21 || (BB) Introduction to Perl [[#Lperl|Lecture]], [[#HWperl|Homework]]

| 2019-02-28 || (BB) Command-line tools, Perl one-liners [[#Lbash|Lecture]], [[#HWbash|Homework]]

| 2019-03-07 || (BB) Job scheduling and make [[#Lmake|Lecture]], [[#HWmake|Homework]]

| 2019-03-14 || (BB) Python and SQL for beginners [[#Lpython|Lecture]], [[#HWpython|Homework]]

| 2019-03-21 || (VB) Web crawling, HTML parsing in Python [[#Lweb|Lecture INF]], [[#HWweb|Homework INF]]

| 2019-03-28 || (VB) Text data processing, flask [[#Lflask|Lecture INF]], [[#HWflask|Homework INF]]  

| || (BB) Bioinformatics 2 (gene finding, RNA-seq) [[#Lbioinf2|Lecture BIN]], [[#HWbioinf2|Homework BIN]]

| 2019-04-04 || (VB) Data visualization in JavaScript [[#Ljavascript|Lecture INF]], [[#HWjavascript|Homework INF]]

| 2019-04-11 || (BB) R, part 1 [[#Lr1|Lecture]], [[#HWr1|Homework]]

| 2019-04-18 || Easter (project proposals due Wednesday April 17)

| 2019-04-25 || (BB) no lecture

| 2019-05-02 || (BB) R, part 2 [[#Lr2|Lecture]], [[#HWr2|Homework]]

| 2019-05-09 || (VB) Cloud computing [[#Lcloud|Lecture]], [[#HWcloud|Homework]]

| 2019-05-16 || no lecture

* [http://compbio.fmph.uniba.sk/~tvinar/ Mgr. Tomáš Vinař, PhD.], miestnosť M-163 <!-- , [[Image:e-tv.png]] -->

This course is offered at the Faculty of Matematics, Physics and Informatics, Comenius University in Bratislava for the students of the second year of the bachelor Bionformatics study program and the students of the bachelor and master Computer Science study programs. It is a prerequisite of the master-level state exams in Bioinformatics and Machine Learning. However, the course is open to students from other study programs if they satisfy the following informal prerequisites.  

We assume that the students are proficient in programming in at least one programming language and are not afraid to learn new languages. We also assume basic knowledge of work on the Linux command-line (at least basic commands for working with files and folders, such as cd, mkdir, cp, mv, rm, chmod). Although most technologies covered in this course can be used for processing data from many apication areas, we will illustrate some of them on examples from bioinformatics. We will explain necessary terminology from biology as needed.

Computer science courses cover many interesting algorithms, models and methods that can used for data analysis. However, when you want to use these methods for real data, you will typically need to make considerable efforts to obtain the data, pre-process it into a suitable form, test and compare different methods or settings, and arrange the final results in informative tables and graphs. Often, these activities need to be repeated for different inputs, different settings, and so on. For example in bioinformatics, it is possible to find a job where your main task will be data processing using existing tools, possibly supplemented by small custom scripts. This course will cover some programming languages and technologies suitable for these activities.

This course is particularly recommended for students whose bachelor or master thesis involves substantial empirical experiments (e.g. experimental evaluation of your methods and comparison with other methods on real or simulated data).  

As you know, in programming it is recommended to adhere to certain practices, such as good coding style, modular desgn, thorough testing etc. Such practices add a little extra work, but are much more efficient in the long run. Similar good practices exist for data analysis. As an introduction we recommend the following article by a well-known bionformatician William Stafford Noble (his advice applies outside of bionformatics as well):

** Therefore it is better to use techniques that allow you to keep all detailes of your workflow and to repeat them if needed

** Try to avoid manually changing files, because this makes reruning analyses harder and more error-prone

** Good documentation is also indispensable for collaorative projects

** Often big files may hide some problems in the format, unexpected values etc.  These may confuse your programs and make the results meaningless

** Also check intermedate results as often as possible (by manual inspection, computing various statistics etc) to detect errors in the data and your code

 

* Protokol môže byť vo formáte .txt alebo .pdf a jeho meno má byť '''protocol.pdf''' alebo '''protocol.txt''' (nakopírujte ho do odovzdaného adresára)

* V prípade použitia txt formátu a diakritiky ju kódujte v UTF8, ale pre jednoduchosť môžete protokoly písať aj bez diakritiky. Ak je protocol v pdf formáte, mali by sa v ňom dať selektovať texty.  

* Na vrchu protokolu uveďte meno, číslo domácej úluhy a vaše vyhodnotenie toho, ako sa vám úlohu podarilo vyriešiť. Vyhodnotenie je prehľadný zoznam všetkých príkladov zo zadania, ktoré ste aspoň začali riešiť a kódov označujúcich ich stupeň dokončenia:

** '''Postupnosť všetkých spustených príkazov,''' prípadne iných krokov, ktorými ste dospeli k získaným výsledkom. Tu uvádzajte príkazy na spracovanie dát a spúšťanie vašich či iných programov. Netreba uvádzať príkazy súvisiace so samotným programovaním (spúšťanie editora, nastavenie práv na spustenie a pod.), s kopírovaním úlohy na server a pod. Uveďte aj stručné '''komentáre''', čo bolo účelom určitého príkazu alebo skupiny príkazov.

Cieľom projektu je vyskúšať si naučené zručnosti na konkrétnom projekte spracovania dát. Vašou úlohou je zohnať si dáta, tieto dáta analyzovať niektorými technikami z prednášok, prípadne aj inými technológiami a získané výsledky zobraziť v prehľadných grafoch a tabuľkách. Ideálne je, ak sa vám podarí prísť k zaujímavým alebo užitočným záverom, ale hodnotiť budeme hlavne voľbu vhodného postupu a jeho technickú náročnosť. Rozsah samotného programovania alebo analýzy dát by mal zodpovedať zhruba trom domácim úlohám, ale celkovo bude projekt náročnejší, lebo na rozdiel od úloh nemáte postup a dáta vopred určené, ale musíte si ich vymyslieť sami a nie vždy sa prvý nápad ukáže ako správny. V projekte môžete využiť aj existujúce nástroje a knižnice, ale pokiaľ možno používajte nástroje spúšťané na príkazovom riadku.  

Zhruba v dvoch tretinách semestra budete odovzdávať '''návrh projektu''' (formát txt alebo pdf, rozsah 0.5-1 strana). V tomto návrhu uveďte, aké dáta budete spracovávať, ako ich zoženiete, čo je cieľom analýzy a aké technológie plánujete použiť. Ciele a technológie môžete počas práce na projekte mierne pozmeniť podľa okolností, mali by ste však mať počiatočnú predstavu. K návrhu vám dáme spätnú väzbu, pričom v niektorých prípadoch môže byť potrebné tému mierne alebo úplne zmeniť. Za načas odovzdaný vhodný návrh projektu získate 5% z celkovej známky. Návrh odporúčame pred odovzdaním konzultovať s vyučujúcimi.

Cez skúškové obdobie bude určený termín '''odovzdania projektu'''.  Podobne ako pri domácich úlohách odovzdávajte adresár s požadovanými súbormi:

* '''Správu k projektu''' vo formáte pdf. Na rozdiel od menej formálneho protokolu by správu mal tvoriť súvislý text v odbornom štýle, podobne ako napr. záverečné práce. Môžete písať po slovensky alebo po anglicky, ale pokiaľ možno gramaticky správne. Správa by mala mať tieto časti:

Ako nájsť tému projektu:

* A samozrejme môžete niekde na internete vyhrabať zaujímavé dáta a snažiť sa z nich niečo vydolovať.

 

 

* Máte povolené sa so spolužiakmi a ďalšími osobami rozprávať o domácich úlohách resp. projektoch a stratégiách na ich riešenie. Kód, získané výsledky aj text, ktorý odovzdáte, musí však byť vaša samostatná práca. Je zakázané ukazovať svoj kód alebo texty spolužiakom.

 

* Pri riešení domácej úlohy a projektu očakávame, že budete využívať internetové zdroje, najmä rôzne manuály a diskusné fóra k preberaným technológiám. Nesnažte sa však nájsť hotové riešenia zadaných úloh. Všetky použité zdroje uveďte v domácich úlohách a projektoch.

 

* Ak nájdeme prípady opisovania alebo nepovolených pomôcok, všetci zúčastnení študenti získajú za príslušnú domácu úlohu, projekt a pod. nula bodov (t.j. aj tí, ktorí dali spolužiakom odpísať) a prípad ďalej podstúpime na riešenie disciplinárnej komisii fakulty.

 

 

Zadania a materiály k predmetu sú voľne prístupné na tejto stránke. Prosím vás ale, aby ste nezverejňovali ani inak nešírili vaše riešenia domácich úloh, ak nie je v zadaní povedané inak. Vaše projekty môžete zverejniť, pokiaľ to nie je v rozpore s vašou dohodou so zadávateľom projektu a poskytovateľom dát.

* There's more than one way to do it

* Easy things should be easy and hard things should be possible

* Swith <tt>-w</tt> switches warnings on, e.g. if we manipulate with an undefined value (equivalent to <tt>use warnings;</tt>)

==The first input file for today: sequence repeats==

* In genomes some sequences occur in many copies (often not exactly equal, only similar)

* We have downloaded a table containing such sequence repeats on chromosome 2L of the fruitfly ''Drosophila melanogaster''

* It was done as follows: on webpage [http://genome.ucsc.edu/ http://genome.ucsc.edu/] we select drosophila genome, then in main menu select  Tools, Table browser, select group: variation and repeats, track: ReapatMasker, region: position chr2L, output format: all fields from the selected table a output file: repeats.txt

* Each line of the file contains data about one repeat in the selected chromosome. The first line contains column names. Columns are tab-separated.

* Here are the first two lines, each line split into three lines for better readability

  chr2L  1       154    -23513558  +

  HETRP_DM        Satellite      Satellite      1519    1669    -203    1

* The file can be found at our server under filename <tt>/tasks/perl/repeats.txt</tt> (17185 lines)

* A small randomly selected subset of the table rows is in file <tt>/tasks/perl/repeats-small.txt</tt> (159 lines)

For each type of repeat (column 11 of the file when counting from 0) we want to compute the number of repeats of this type

#!/usr/bin/perl -w

#associative array (hash), with repeat type as key

     # check input - should have at least 17 columns

     die "Bad input '$line'" unless @columns >= 17;

     my $type = $columns[11];

     $count{$type}++;

foreach my $type (sort keys %count) {

     print $type, " ", $count{$type}, "\n";

perl -F'"\t"' -lane 'next if /^#/; die unless @F>=17; $count{$F[11]}++;

* Analogicaly <tt>shift</tt> and <tt>unshift</tt> on the left end of the array (slower)

* Module <tt>Data::Dumper</tt> has function <tt>Dumper</tt>, which recursively prints complex data structures (good for debuging)

* Regular expressions are powerful tool for working with strings, now featued in many languages

# the string matching part of expression in (..) is stroed in $1

Undefined value, number 0 and strings <tt>""</tt> and <tt>"0"</tt> evaluate as false, but we recommmend always explicitly using logical values in conditional expressions, e.g. <tt>if(defined $x)</tt>, <tt>if($x eq "")</tt>, <tt>if($x==0)</tt> etc.

* Reading one line from standard input: <tt>$line = <STDIN></tt>

* If no more input data available, returns <tt>undef</tt>

cd perl   # change to the new directory

ln -s /tasks/perl/repeats-small.txt . # small version of the repeat file

ln -s /tasks/perl/repeats.txt .       # full version of the repeat file

We recommend writing your protocol starting from an outline provided in  <tt>/tasks/perl/protocol.txt</tt>. Make your own copy of the protopcol and open it in an editor, e.g. kate:

cp -ip /tasks/perl/protocol.txt . # copy protocol

kate protocol.txt &                # open editor, run in the backgrund

* Directory /submit/perl/your_username will be created for you

* Copy required files to this directory, including the protocol named protocol.txt or protocol.pdf

===Task A (repeats)===

* Consider the program for counting repeat types in the [[#Lperl#A_sample_Perl_program|lecture 1]], save it to file <tt>repeat-stat.pl</tt>

** Open editor running in the background: <tt>kate repeat-stat.pl</tt>

** Copy and paste text to the editor, save it  

** Make the script executable: <tt>chmod a+x repeat-stat.pl</tt>

* Extend the script to compute the average length of each type of repeat

** Each row of the input table contains the start and end coordinates of the repeat in columns 7 and 6. The length is simply the difference of these two values.

* Output a table with three columns: type of repeat, the number of occurrences, the average length of the repeat.  

** Use [http://perldoc.perl.org/functions/printf.html printf] to print these three items right-justified in columns of sufficient width, print the average length to 1 decimal place.

./repeat-stat.pl < repeats-small.txt

                DNA         5    377.4

                LTR       13    355.4

      Low_complexity       22      47.2

                  RC        8     236.2

       Simple_repeat      106      39.0

* Run your script also on the large file: <tt>./repeat-stat.pl < repeats.txt</tt>

* '''Submit''' only your script, <tt>repeat-stat.pl</tt>

** The sequence itself is on the second line, long sequences are split into multiple lines

** you can try to use [http://perldoc.perl.org/perlop.html#Quote-Like-Operators tr or s operators] (see also [[#Lperl#Regular_expressions|lecture]])

** ASCII value can be computed by function [http://perldoc.perl.org/functions/ord.html ord]

'''Note''': in this task set, you have created tools which can be combined, e.g. you can first trim FASTQ and then convert it to FASTA (no need to submit these files)

'''Parsing command-line arguments''' in this task (they will be stored in variables $Q and $L):

# do not forget to quote > in other uses, e.g. when searching for string ">" in a file sequences.fasta

Other interesting possibilites:

* In a Perl one-liner, you can create a state variable which will remember if the previous line was a comment and based on that you decide of you print the current line.  

* Instead of using Perl, you can play with grep. Option <tt>-A 1</tt> prints the matching lines as well as one line ofter each match

** They will run on computer cpu02

** This cluster is only temporarily available until next Thursday

Basic commad: <tt>qsub -b y -cwd 'command < input > output 2> error'</tt>

* job 28 is running of  server cpu02 (status <t>r</tt>), job 29 is waiting in queue (status <tt>qw</tt>)

------------------------------------------------------------------------------

     28 0.50000 s3        bbrejova    r    03/15/2016 22:12:18 main.q@cpu02

main.q@cpu02.compbio.fmph.unib BIP  0/2/8         0.03     lx26-amd64

        hc:threads=0

    28 0.75000 s3        bbrejova    r    03/15/2016 22:12:18     1

    29 0.25000 s3        bbrejova    r    03/15/2016 22:14:18     1

* therefore it is a good idea to run <tt>qrsh</tt> within <tt>screen</tt>

** run <tt>screen</tt> command, this creates a new shell  

** within this shell, run <tt>qrsh</tt>, then whatever commands

** by pressing <tt>Ctrl-a d</tt> you "detach" the screen, so that both shells (local and <tt>qrsh</tt>) continue running but you can close your local window

** later by running <tt>screen -r</tt> you get back to your shells

For example, we many need run some computation for each human gene (there are roughly 20,000 such genes). Here are some possibilties:

** It will automatically skip tasks which are already finished, so restart os easy

Running make with option <tt>-j 4</tt> will run up to 4 commands in parallel if their dependencies are already finished. Ths allows easy parallelization on a single computer.

* There are many tools developed for automating computational pipelines, see e.g. this review: [https://academic.oup.com/bib/article/doi/10.1093/bib/bbw020/2562749/A-review-of-bioinformatic-pipeline-frameworks Jeremy Leipzig; A review of bioinformatic pipeline frameworks. Brief Bioinform 2016.]

* For example [https://bitbucket.org/snakemake/snakemake/wiki/Home Snakemake]

===Motivation: Building Phylogenetic Trees===

* The process is typically split into severla stages shown below

''Orthologs'' are proteins from different species that "correspond" to each other. Ortholog are found based on sequence similarity and we can use a tool called [http://blast.ncbi.nlm.nih.gov/Blast.cgi?CMD=Web&PAGE_TYPE=BlastDocs&DOC_TYPE=Download blast] to identify sequence similarities between pairs of proteins. The result of ortholog group identification will be a set of groups, each group having one sequence from each of the 9 species

This lecture introduces the basics of the Python programming language. We will also cover basics of working with databases using the SQL language.  

* Computer science students will use Python and SQLite3 and several advanced Python libraries for complex data processing

* A very concise cheat sheet: [http://www.cogsci.rpi.edu/~destem/igd/python_cheat_sheet.pdf]

* A more detailed tutorial: [https://docs.python.org/3/tutorial/]

* Typical database systems are complex, use server-client srchitecture. SQLite3 is a simple "database" stored in one file. You can think of SQLite3 not as a replacement for Oracle but as a replacement for <tt>fopen()</tt>.

* [https://www.sqlite.org/docs.html] SQLite3 documentation]

* [[https://docs.python.org/3/library/sqlite3.html SQLite3 in Python documentation]

 

* We look at several python scripts for processing this data set

* Solve task A, where you create another such a script

* From this dataset, we have selected only 10 series with the highest average number of voting users

Print the second column (series title) from <tt>series.csv</tt>

Print the list of series of each TV channel

* For illustration we also separately count the series for each channel, but the count could be obtained as the length of the list

for channel in channel_counts:

     % (channel, channel_counts[channel]))

 

     print("series for channel \"%s\": %s" % (channel,list))

Find the episode with the highest number of votes among all episodes

* We use a library for csv parsing to deal with quotation marks.

#keep maximum number of votes and its episode

Example of function definition, reading the whole file into a 2d array

SQLite3 database is a file with your data stored in some special format. To load our csv file to a SQLite database, run command:

* The two <tt>CREATE TABLE</tt> commnds create two tables naamed <tt>series</tt> and <tt>episodes</tt>

* For each column (attribute) of the table we list if name and type.

* Then type the following queries which illustrate the basic features of SQL

   WHERE votes>50000 ORDER BY votes desc;

   ORDER BY votes desc limit 10;

SELECT channel, COUNT() as series_count

'''Now do [[#HWpython]], tasks B1, B2'''

 

==Accessing a database from Python==

We will use sqlite3 library for Python to access data from the database and to process in further in the Python program.

* The following script illustrates running a SELECT query and the getting results

'''Now do [[#HWpython]], task C'''

* The table should be ordered by the difference between the last two columns, i.e. from seasons with the highest increase to seasons to the highest drop.

In this lecture, we will extract information from a website using Python and existing Python libraries. We will store the results in an SQLite database. These results will be analyzed further in the following lectures.

In Python, the simplest tool for scraping webpages is <tt>[https://docs.python.org/2/library/urllib2.html urllib2]</tt> library. Example usage:

You can also use <tt>requests</tt> package:

We will use <tt>beautifulsoup4</tt> library for parsing HTML.

* In your code, we recommend following the examples at the beginning of the [http://www.crummy.com/software/BeautifulSoup/bs4/doc/ documentation] and the example of [http://www.crummy.com/software/BeautifulSoup/bs4/doc/#css-selectors CSS selectors].

* To find out, how is the document structured, use Inspect element feature in Chrome (right click on the text of interest within the website)

* Based on this information, create a CSS selector

== Other usefull tips ==

* Don't forget to commit to your SQLite3 database (call <tt>db.commit()</tt>).

* SQL command <tt>CREATE TABLE IF NOT EXISTS</tt> can be usefull at the start of your script.

* All packages are installed on our server. If you use your own laptop, you need to install them using <tt>pip</tt> (preferably in an <tt>virtualenv</tt>).

 

* For fewer points: Script which gets URL of a user (e.g. http://ekonomika.sme.sk/diskusie/user_profile.php?id_user=157432) and crawls his comments from the last month.

* We will display information about individual users as a dynamic website written in Flask frmework

flask run --port=4247

Flask starts a webserver and serves the pages created in your Flask application,. Keep it running while you need to access these pages.  

 

 

It transforms a text into a bag of words representation. In this representation we get the list of word and the count for each word. Example:

Array <tt>t</tt> in the example above is a NumPy array provided by the [https://numpy.org/ NumPy library]. This librray has also lots of nice tricks. First lets create two matrices:

This lesson requires crawled data from previous lesson, if you don't have one, you can find it at (and thank Baska): <tt>/tasks/flask/db.sqlite3</tt>

* Has a homepage with is a list of all users (with links to their pages).

For each user preprocess and store

* the list 10 most frequently used words  

* the list of top 10 words typical for this user (words which this user uses much more often than other users, come up with some simple heuristics for measuring this)

* You can write your data into JavaScript data structures in a Flask template. It is a bad practice, but sufficient for this lecture. (A better way is to load data in JSON format through API).

Show a word tree for a user using [https://developers.google.com/chart/interactive/docs/gallery/wordtree word tree from Google Charts]. Try to normalize the text before building the tree(convert to lowercase, remove accents). <tt>CountVectorizer</tt> has <tt>build_analyzer</tt> method, which returns a function, which does this for you.

** '''Oxford nanopore sequencers''' produce longer reads (thousands of basepairs or more), but the error rates are higher (10-15%)  

* Alignments can be stored in many formats and visualised as dotplots

* The reverse process is done by <tt>gunzip filename.ext.gz</tt>

* However, we can access the file withou uncompressining it. Command <tt>zcat filename.ext.gz</tt> prints the content of a gzipped file and keep the gzipped file as is. We can use pipe to do ruther processing on the file.

* Some bioinformatics tools can work directly with gzipped files

 

(b) How long are individual reads in the miseq files?

* We will assemble Illumina reads by program SPAdes and nanopore reads by miniasm

* Press Enter to get command-line, then run the follwing command:<br>

* Create file <tt>minimap.sh</tt> containing the following commands:

* Run <tt>screen -S minimap</tt>

* In screen, run <tt>source ./minimap.sh</tt>

(a) How many contigs quast reported in the two assemblies? Does it agree with your counts in part B?

(c) What portion of the reference sequence is covered by the two assemblies (reported as genome fraction)? Which assembly is better in this aspect?

As in other tasks, write '''commands''' and '''answers''' to your '''protocol'''

(a) Create dotplot comparing miniasm assembly to the reference sequence

/usr/local/share/miniasm/miniasm/minidot -f 12 ref-miniasm2.paf | ps2pdf -dEPSCrop - ref-miniasm2.pdf

# displaying dotplot - if this does not work, copy the pdf file to your commputer and view there

(b) Use analogous commands to create dotplot for spades assembly, call it <tt>ref-spades.pdf</tt>  

(c) Use analogous commands to create dotplot of reference to itself, call it <tt>ref-ref.pdf</tt>

* Do you see any self-alignments, showing repeated sequences in the reference? Does this agree with dotplot in part (b)?

# minimap produces SAM file, samtools view converts to BAM, samtools sort orders by coordinate

minimap2 -a -x sr --secondary=no -t 1 ref.fasta  miseq_R1.fastq.gz miseq_R2.fastq.gz | samtools view -S -b - |  samtools sort - ref-miseq

'''Beware: It needs a lot of memory, do not keep open unnecessarily'''

* If we know the exact position of coding regions of a gene, we can use genetic code to predict the protein sequence encoded by it

* Gene finders use statistical features observed from known genes, such as typical sequence motifs near the start codons, stop codons and splice sites, typical codon frequences, typical exon and intron lengths etc.

* We will use a gene finder called [http://bioinf.uni-greifswald.de/augustus/ Augustus]

* Not all genes undergo transcription and translation all the time and at the same level

* The processes of transcription and translation are regulated according to cell needs

* The term "gene expression" has two meanings

** the process of transcription and translation (synthesis of a gene product)

** the amount of mRNA or protein produced from a single gene (genes with high or low expression)

 

* <tt>ref.fasta</tt> is a 38kb piece of genome of the fungus ''[https://www.ncbi.nlm.nih.gov/genome?term=aspergillus%20fumigatus Aspergillus nidulans]''

* one trained specifically for ''A. nidulas'' genes

(a) How many reads were in the the FASTQ file? How many of them were successfully mapped?

Write anwsers to the '''protocol'''. '''Submit''' the file <tt>rnaseq.bam</tt>.

(c) Zoom in to one of the genes with high expression level and try to find spliced read alignments supporting the annotated intron boundaries. Store the image as <tt>c.png</tt>.

* [https://ghr.nlm.nih.gov/primer/genomicresearch/snp SNP]: single-nucleotide polymorphism (a polymorphism which is a substitution of a single nucletide)

* Then we look for positions where a substantial fraction of reads does not agree with the reference (SNP-calling)

* For SNP calling, we will use [https://github.com/ekg/freebayes Freebayes]

* Select a genome and its version, optionally enter position or keyword, press submit

* On the browser screen top image shows chromosome map, selected region in red

* Below a view of the selected region and various track with information about this region

===Task A: read mapping and SNP calling===

bwa mem humanChr7Region.fasta  motherChr7Region.fastq | samtools view -S -b - |  samtools sort - motherChr7Region