Metadata-Version: 1.1
Name: pydna
Version: 2.0.0a8
Summary: Contains classes and code for representing double
                     stranded DNA and functions for simulating homologous
                     recombination between DNA molecules.
Home-page: http://pypi.python.org/pypi/pydna/
Author: Björn Johansson
Author-email: bjorn_johansson@bio.uminho.pt
License: LICENSE.txt
Description: 
        |icon| pydna
        ============
        
        |Documentation Status| |GitHub stars|\ |GitHub issues|\ |Research
        software impact|\ |Code Climate|\ |Issue
        Count|\ |codecov|\ |icon11|\ |CircleCI|\ |icon1|\ |icon2|\ |PyPI
        version|\ |Anaconda-Server Badge0|\ |Anaconda-Server
        Badge1|\ |Anaconda-Server Badge2|\ |Anaconda-Server Badge3|
        
        Planning genetic constructs with many parts and assembly steps, such as
        recombinant metabolic pathways are often difficult to properly document.
        
        The Pydna python package provide a human-readable formal description of
        cloning and assembly strategies in Python which also allows for
        simulation and verification of cloning strategies. Pydna can be though
        of as executable documentation for molecular biology.
        
        Pydna provides simulation of:
        
        -  Restriction digestion
        -  Ligation
        -  PCR
        -  Primer design
        -  Gibson assembly
        -  Golden gate assembly
        -  Homologous recombination
        -  Gel electrophoresis of DNA with generation of gel images
        
        Virtually any sub-cloning experiment can be described in pydna, and its
        execution yield the sequence of the of intermediate and final resulting
        DNA molecule(s). A cloning strategy expressed in pydna is *complete*,
        *unambiguous* and can be made *stable*. Pydna has been designed to be
        understandable for biologists with only some basic understanding of
        Python.
        
        Pydna can formalize planning and sharing of cloning strategies and is
        especially useful for complex or combinatorial DNA molecule
        constructions.
        
        Look at some assembly strategies made in the Jupyter notebook format
        `here <http://nbviewer.ipython.org/github/BjornFJohansson/ypk-xylose-pathways/blob/master/index.ipynb>`__.
        
        There is an open access paper in BMC Bioinformatics describing pydna:
        
        |abstr|
        
        Please reference the above paper when using pydna.
        
        Usage
        -----
        
        Most pydna functionality is implemented as methods for the double
        stranded DNA sequence record classes Dseq and Dseqrecord, which are
        subclasses of the `Biopython <http://biopython.org/wiki/Main_Page>`__
        `Seq <http://biopython.org/wiki/Seq>`__ and
        `SeqRecord <http://biopython.org/wiki/SeqRecord>`__ classes.
        
        These classes make cut and paste cloning and PCR very simple:
        
        ::
        
            >>> import pydna
            >>> seq = pydna.Dseq("GGATCCAAA","TTTGGATCC",ovhg=0)
            >>> seq
            Dseq(-9)
            GGATCCAAA
            CCTAGGTTT
            >>> from Bio.Restriction import BamHI
            >>> a,b = seq.cut(BamHI)
            >>> a
            Dseq(-5)
            G
            CCTAG
            >>> b
            Dseq(-8)
            GATCCAAA
                GTTT
            >>> a+b
            Dseq(-9)
            GGATCCAAA
            CCTAGGTTT
            >>> b+a
            Dseq(-13)
            GATCCAAAG
                GTTTCCTAG
            >>> b+a+b
            Dseq(-17)
            GATCCAAAGGATCCAAA
                GTTTCCTAGGTTT
            >>> b+a+a
            Traceback (most recent call last):
              File "<stdin>", line 1, in <module>
              File "/usr/local/lib/python2.7/dist-packages/pydna/dsdna.py", line 217, in __add__
                raise TypeError("sticky ends not compatible!")
            TypeError: sticky ends not compatible!
            >>>
        
        As the example above shows, pydna keeps track of sticky ends.
        
        Notably, homologous recombination and Gibson assembly between linear DNA
        fragments can be easily simulated without any additional information
        besides the primary sequence of the fragments.
        
        Gel electrophoresis of DNA fragments can be simulated using the included
        gel module by `Bruno Silva <https://github.com/bruno2git>`__:
        
        .. figure:: docs/pics/gel.png
           :alt: simulated agarose gel
        
           alt text
        
        Look at an example notebook with a gel simulation
        `here <http://nbviewer.jupyter.org/github/BjornFJohansson/pydna/blob/py3dev/scripts/gel_inline_ex.ipynb>`__.
        
        Pydna can be very compact. The nine lines of Python below, simulates the
        construction of a recombinant plasmid. DNA sequences are downloaded from
        Genbank by accession numbers that are guaranteed to be stable over time.
        
        ::
        
            import pydna
            gb = pydna.Genbank("myself@email.com") # Tell Genbank who you are!
            gene = gb.nucleotide("X06997") # Kluyveromyces lactis LAC12 gene for lactose permease.
            primer_f,primer_r = pydna.parse(''' >760_KlLAC12_rv (20-mer)
                                                ttaaacagattctgcctctg
        
                                                >759_KlLAC12_fw (19-mer)
                                                aaatggcagatcattcgag
                                                ''', ds=False)
            pcr_prod = pydna.pcr(primer_f,primer_r, gene)
            vector = gb.nucleotide("AJ001614") # pCAPs cloning vector
            from Bio.Restriction import EcoRV
            lin_vector = vector.linearize(EcoRV)
            rec_vec =  ( lin_vector + pcr_prod ).looped()
        
        Pydna can automate the simulation of `sub
        cloning <http://en.wikipedia.org/wiki/Subcloning>`__ experiments using
        python. This is helpful to generate examples for teaching purposes.
        
        Read the `documentation <http://pydna.readthedocs.io/index.html>`__ or
        the
        `cookbook <https://www.dropbox.com/sh/4re9a0wk03m95z4/AABpu4zwq4IuKUvK0Iy9Io0Fa?dl=0>`__
        with example files for further information.
        
        Please post a message in the `google
        group <https://groups.google.com/d/forum/pydna>`__ for pydna if you have
        problems, questions or comments.
        
        Feedback is very welcome! ## Who is using pydna?
        
        `An Automated Protein Synthesis Pipeline with Transcriptic and
        Snakemake <http://blog.booleanbiotech.com/transcriptic_protein_synthesis_pipeline.html>`__
        
        `Pyviko: an automated Python tool to design gene knockouts in complex
        viruses with overlapping
        genes <https://www.ncbi.nlm.nih.gov/pubmed/28061810>`__
        
        Documentation
        -------------
        
        Documentation is built using `Sphinx <http://www.sphinx-doc.org/>`__
        from `docstrings <https://www.python.org/dev/peps/pep-0257/>`__ in the
        code and displayed at readthedocs |Documentation Status|
        
        The `numpy <www.numpy.org>`__ `docstring
        format <https://github.com/numpy/numpy/blob/py3dev/doc/HOWTO_DOCUMENT.rst.txt>`__
        is used.
        
        Installation using conda on Anaconda
        ------------------------------------
        
        The absolutely best way of installing and using pydna is to use the free
        `Anaconda <https://store.continuum.io/cshop/anaconda>`__ or
        `Miniconda <http://conda.pydata.org/miniconda.html>`__ python
        distributions.
        
        Anaconda is a large download (about 400 Mb) while Miniconda is about
        40-50 Mb.
        
        Once Anaconda (or Miniconda) is installed, the conda package manager can
        be used to install pydna. Pydna and its dependencies are available from
        the `BjornFJohansson <https://anaconda.org/bjornfjohansson>`__ package
        channel ast `Anaconda.org <https://anaconda.org>`__.
        
        The first step is to add the channel by typing the command below
        followed by return:
        
        ::
        
            conda config --append channels BjornFJohansson
        
        Then pydna can be installed by typing the command below followed by
        return:
        
        ::
        
            conda install pydna
        
        This works on Windows, MacOSX and Linux, and installs all necessary and
        optional dependencies automatically (see below).
        
        Installation using pip
        ----------------------
        
        The second best way of installing pydna is with pip, the officially
        `recommended <http://python-packaging-user-guide.readthedocs.org/en/latest>`__
        tool.
        
        Pip is included in recent Python versions.
        
        Pip installs the minimal installation requirements automatically, but
        not the optional requirements (see below). This will probably not work
        directly on windows, as biopython is not directly installable.
        
        Linux:
        ~~~~~~
        
        ::
        
            bjorn@bjorn-UL30A:~/pydna$ sudo pip install pydna
        
        Windows:
        ~~~~~~~~
        
        Installing biopython on Windows can be tricky. The biopython site has
        `executable installers <http://biopython.org/wiki/Download>`__. Read
        `here <http://biopython.org/DIST/docs/install/Installation.html>`__ on
        how to install biopython requirements such as Numpy. Christoph Gohlke at
        University of California, Irvine has compiled many `binary
        installers <http://www.lfd.uci.edu/~gohlke/pythonlibs/>`__ for Windows
        wich include most requirements.
        
        When the requrements are installed you can pip install pydna from the
        Windows terminal:
        
        ::
        
            C:\> pip install pydna
        
        Installation from Source
        ------------------------
        
        If you install from source, you need to install all dependencies
        separately (listed above). Download one of the source installers from
        the pypi site or from Github and extract the file. Open the pydna source
        code directory (containing the setup.py file) in terminal and type:
        
        ::
        
            python setup.py install
        
        Source Code
        -----------
        
        Pydna is developed on
        `Github <https://github.com/BjornFJohansson/pydna>`__.
        
        Minimal installation requirements
        ---------------------------------
        
        Pydna is currently developed on and for Python 3.5. Pydna versions
        before 1.0.0 were compatible with python 2.7 only. The list below is the
        minimal requirements for installing pydna. Biopython has c-extensions,
        but the other modules are pure python.
        
        -  `Python 3.5 <http://www.python.org>`__
        -  `biopython >= 1.65 <http://pypi.python.org/pypi/biopython>`__
        -  `networkx >= 1.8.1 <http://pypi.python.org/pypi/networkx>`__
        -  `pyparsing >= 2.1.10 <https://pypi.python.org/pypi/pyparsing>`__
        -  `appdirs >=1.3.0 <https://pypi.python.org/pypi/appdirs>`__
        -  `prettytable>=0.7.2 <https://pypi.python.org/pypi/PrettyTable>`__
        -  `ordered\_set>=2.0.1 <https://pypi.python.org/pypi/ordered-set>`__
        
        Optional Requirements
        ---------------------
        
        Pydna has been designed to be used from the Jupyter notebook. If
        `IPython <https://ipython.org/>`__ and `Jupyter <http://jupyter.org/>`__
        are installed, importing ipython notebooks as modules among are
        supported among other things.
        
        If the modules listed below are installed, gel simulation functionality
        is available.
        
        -  `numpy <http://www.numpy.org>`__
        -  `scipy <https://www.scipy.org>`__
        -  `matplotlib <http://matplotlib.org>`__
        -  `mpldatacursor <https://pypi.python.org/pypi/mpldatacursor>`__
        -  `pint >= 0.7.2 <https://pypi.python.org/pypi/pint>`__
        
        The pydna conda package installs the optional requirements listed above
        as well as:
        
        -  `ipython <https://pypi.python.org/pypi/ipython>`__
        -  `jupyter <https://pypi.python.org/pypi/jupyter>`__
        
        Requirements for running tests
        ------------------------------
        
        -  `pytest>=3.0.3 <https://pypi.python.org/pypi/pytest>`__
        
        Requirements for analyzing code coverage
        ----------------------------------------
        
        -  `python-coveralls >=
           2.9.0 <https://pypi.python.org/pypi/python-coveralls>`__
        -  `coverage >= 3.7.1 <https://pypi.python.org/pypi/coverage>`__
        -  `pytest-cov >= 2.3.1 <https://pypi.python.org/pypi/pytest-cov>`__
        
        Automatic testing
        -----------------
        
        The test suit is run automatically after each commit on:
        
        -  Ubuntu 14.04 using CircleCI
        -  OSX-64 using TravisCI
        -  Windows using AppveyorCI
        
        See the badges at the top of this page.
        
        Automatic builds
        ----------------
        
        `Conda <http://conda.pydata.org/docs/intro.html>`__ packages are built
        on CircleCI(Linux), TravisCI(MacOS) and AppveyorCI(Windows). Source
        setuptools packages and wheels are built on Linux for all systems.
        Binary setuptools packages are built for Windows and MacOSX.
        
        -  Conda packages |Anaconda-Server Badge0|
        -  Setuptools packages
        
        Builds are controlled by Git tags. Tags like 1.0.2a4 are considered test
        builds and are uploaded to
        `testpypi <https://testpypi.python.org/pypi?:action=display&name=pydna>`__
        and to Anaconda.org with a "test" label. These are only meant to test
        the finished packages and are not meant to be used.
        
        Tags like 1.0.3 are considered final builds and are built and uploaded
        to `Anaconda.org <https://anaconda.org/BjornFJohansson/pydna>`__ under
        the "main" label and to the regular
        `pypi <https://pypi.python.org/pypi/pydna>`__ server.
        
        Changelog
        ---------
        
        See the `change log <docs/CHANGELOG.md>`__ for recent changes.
        
        .. |icon| image:: docs/pics/pydna.resized.png
           :target: https://pypi.python.org/pypi/pydna/
        .. |Documentation Status| image:: https://readthedocs.org/projects/pydna/badge/?version=latest
           :target: http://pydna.readthedocs.io/?badge=latest
        .. |GitHub stars| image:: https://img.shields.io/github/stars/BjornFJohansson/pydna.svg
           :target: https://github.com/BjornFJohansson/pydna/stargazers
        .. |GitHub issues| image:: https://img.shields.io/github/issues/BjornFJohansson/pydna.svg
           :target: https://github.com/BjornFJohansson/pydna/issues
        .. |Research software impact| image:: http://depsy.org/api/package/pypi/pydna/badge.svg
           :target: http://depsy.org/package/python/pydna
        .. |Code Climate| image:: https://codeclimate.com/github/BjornFJohansson/pydna/badges/gpa.svg
           :target: https://codeclimate.com/github/BjornFJohansson/pydna
        .. |Issue Count| image:: https://codeclimate.com/github/BjornFJohansson/pydna/badges/issue_count.svg
           :target: https://codeclimate.com/github/BjornFJohansson/pydna
        .. |codecov| image:: https://codecov.io/gh/BjornFJohansson/pydna/branch/py3/graph/badge.svg
           :target: https://codecov.io/gh/BjornFJohansson/pydna
        .. |icon11| image:: https://www.versioneye.com/user/projects/553174c010e714f9e50010bb/badge.svg
           :target: https://www.versioneye.com/user/projects/553174c010e714f9e50010bb
        .. |CircleCI| image:: https://circleci.com/gh/BjornFJohansson/pydna/tree/py3dev.svg?style=shield
           :target: https://circleci.com/gh/BjornFJohansson/pydna/tree/py3dev
        .. |icon1| image:: https://travis-ci.org/BjornFJohansson/pydna.svg
           :target: https://travis-ci.org/BjornFJohansson/pydna
        .. |icon2| image:: https://ci.appveyor.com/api/projects/status/qdtk9biw5o0cae7u?svg=true
           :target: https://ci.appveyor.com/project/BjornFJohansson/pydna
        .. |PyPI version| image:: https://badge.fury.io/py/pydna.svg
           :target: https://badge.fury.io/py/pydna
        .. |Anaconda-Server Badge0| image:: https://anaconda.org/bjornfjohansson/pydna/badges/version.svg
           :target: https://anaconda.org/bjornfjohansson/pydna
        .. |Anaconda-Server Badge1| image:: https://anaconda.org/bjornfjohansson/pydna/badges/installer/conda.svg
           :target: https://conda.anaconda.org/bjornfjohansson
        .. |Anaconda-Server Badge2| image:: https://anaconda.org/bjornfjohansson/pydna/badges/license.svg
           :target: https://anaconda.org/bjornfjohansson/pydna
        .. |Anaconda-Server Badge3| image:: https://anaconda.org/bjornfjohansson/pydna/badges/downloads.svg
           :target: https://anaconda.org/bjornfjohansson/pydna
        .. |abstr| image:: docs/pics/BMC_resized.png
           :target: http://www.biomedcentral.com/1471-2105/16/142/abstract
        
Keywords: bioinformatics
Platform: CPython 3.5
Classifier: Development Status :: 4 - Beta
Classifier: Environment :: Console
Classifier: Intended Audience :: Education
Classifier: Intended Audience :: Developers
Classifier: Intended Audience :: Science/Research
Classifier: License :: OSI Approved :: BSD License
Classifier: Operating System :: OS Independent
Classifier: Programming Language :: Python :: 3.5
Classifier: Programming Language :: Python :: 3.6
Classifier: Topic :: Education
Classifier: Topic :: Scientific/Engineering :: Bio-Informatics
