Citations

Software Citation

If you use the khmer software, you must cite:

Crusoe et al., The khmer software package: enabling efficient sequence analysis. 2014. http://dx.doi.org/10.6084/m9.figshare.979190
@article{khmer2014,
    author = "Crusoe, Michael and Edvenson, Greg and Fish, Jordan and Howe,
Adina and McDonald, Eric and Nahum, Joshua and Nanlohy, Kaben and
Ortiz-Zuazaga, Humberto and Pell, Jason and Simpson, Jared and Scott, Camille
and Srinivasan, Ramakrishnan Rajaram and Zhang, Qingpeng and Brown, C. Titus",
    title = "The khmer software package: enabling efficient sequence
analysis",
    year = "2014",
    month = "04",
    publisher = "Figshare",
    url = "http://dx.doi.org/10.6084/m9.figshare.979190"
}

If you use any of our published scientific methods, you should also cite the relevant paper(s), as directed below. Additionally some scripts use the SeqAn library for read parsing: the full citation for that library is also included below.

To see a quick summary of papers for a given script just run it without using any command line arguments.

Graph partitioning and/or compressible graph representation

The load-graph.py, partition-graph.py, find-knots.py, load-graph.py, and partition-graph.py scripts are part of the compressible graph representation and partitioning algorithms described in:

Pell J, Hintze A, Canino-Koning R, Howe A, Tiedje JM, Brown CT. Scaling metagenome sequence assembly with probabilistic de Bruijn graphs Proc Natl Acad Sci U S A. 2012 Aug 14;109(33):13272-7. http://dx.doi.org/10.1073/pnas.1121464109. PMID: 22847406
@article{Pell2012,
    author = "Pell, Jason and Hintze, Arend and Canino-Koning, Rosangela and
Howe, Adina and Tiedje, James M. and Brown, C. Titus",
    title = "Scaling metagenome sequence assembly with probabilistic de Bruijn
graphs",
    volume = "109",
    number = "33",
    pages = "13272-13277",
    year = "2012",
    doi = "10.1073/pnas.1121464109",
    abstract ="Deep sequencing has enabled the investigation of a wide range of
environmental microbial ecosystems, but the high memory requirements for de
novo assembly of short-read shotgun sequencing data from these complex
populations are an increasingly large practical barrier. Here we introduce a
memory-efficient graph representation with which we can analyze the k-mer
connectivity of metagenomic samples. The graph representation is based on a
probabilistic data structure, a Bloom filter, that allows us to efficiently
store assembly graphs in as little as 4 bits per k-mer, albeit inexactly. We
show that this data structure accurately represents DNA assembly graphs in low
memory. We apply this data structure to the problem of partitioning assembly
graphs into components as a prelude to assembly, and show that this reduces the
overall memory requirements for de novo assembly of metagenomes. On one soil
metagenome assembly, this approach achieves a nearly 40-fold decrease in the
maximum memory requirements for assembly. This probabilistic graph
representation is a significant theoretical advance in storing assembly graphs
and also yields immediate leverage on metagenomic assembly.",
    URL = "http://www.pnas.org/content/109/33/13272.abstract",
    eprint = "http://www.pnas.org/content/109/33/13272.full.pdf+html",
    journal = "Proceedings of the National Academy of Sciences"
}

Digital normalization

The normalize-by-median.py and count-median.py scripts are part of the digital normalization algorithm, described in:

A Reference-Free Algorithm for Computational Normalization of Shotgun Sequencing Data Brown CT, Howe AC, Zhang Q, Pyrkosz AB, Brom TH arXiv:1203.4802 [q-bio.GN] http://arxiv.org/abs/1203.4802
@unpublished{diginorm,
    author = "C. Titus Brown and Adina Howe and Qingpeng Zhang and Alexis B.
Pyrkosz and Timothy H. Brom",
    title = "A Reference-Free Algorithm for Computational Normalization of
Shotgun Sequencing Data",
    year = "2012",
    eprint = "arXiv:1203.4802",
    url = "http://arxiv.org/abs/1203.4802",
}

K-mer counting

The abundance-dist.py, filter-abund.py, and load-into-counting.py scripts implement the probabilistic k-mer counting described in:

These Are Not the K-mers You Are Looking For: Efficient Online K-mer Counting Using a Probabilistic Data Structure Zhang Q, Pell J, Canino-Koning R, Howe AC, Brown CT. http://dx.doi.org/10.1371/journal.pone.0101271
@article{khmer-counting,
    author = "Zhang, Qingpeng AND Pell, Jason AND Canino-Koning, Rosangela
AND Howe, Adina Chuang AND Brown, C. Titus",
    journal = "PLoS ONE",
    publisher = "Public Library of Science",
    title = "These Are Not the K-mers You Are Looking For: Efficient Online
K-mer Counting Using a Probabilistic Data Structure",
    year = "2014",
    month = "07",
    volume = "9",
    url = "http://dx.doi.org/10.1371%2Fjournal.pone.0101271",
    pages = "e101271",
    abstract = "<p>K-mer abundance analysis is widely used for many purposes in
nucleotide sequence analysis, including data preprocessing for de novo
assembly, repeat detection, and sequencing coverage estimation. We present the
khmer software package for fast and memory efficient <italic>online</italic>
counting of k-mers in sequencing data sets. Unlike previous methods based on
data structures such as hash tables, suffix arrays, and trie structures, khmer
relies entirely on a simple probabilistic data structure, a Count-Min Sketch.
The Count-Min Sketch permits online updating and retrieval of k-mer counts in
memory which is necessary to support online k-mer analysis algorithms. On
sparse data sets this data structure is considerably more memory efficient than
any exact data structure. In exchange, the use of a Count-Min Sketch introduces
a systematic overcount for k-mers; moreover, only the counts, and not the
k-mers, are stored. Here we analyze the speed, the memory usage, and the
miscount rate of khmer for generating k-mer frequency distributions and
retrieving k-mer counts for individual k-mers. We also compare the performance
of khmer to several other k-mer counting packages, including Tallymer,
Jellyfish, BFCounter, DSK, KMC, Turtle and KAnalyze. Finally, we examine the
effectiveness of profiling sequencing error, k-mer abundance trimming, and
digital normalization of reads in the context of high khmer false positive
rates. khmer is implemented in C++ wrapped in a Python interface, offers a
tested and robust API, and is freely available under the BSD license at
github.com/ged-lab/khmer.</p>",
    number = "7",
    doi = "10.1371/journal.pone.0101271"
}

FASTA and FASTQ reading

Several scripts use the SeqAn library for FASTQ and FASTA reading as described in:

SeqAn An efficient, generic C++ library for sequence analysis Döring A, Weese D, Rausch T, Reinert K. http://dx.doi.org/10.1186/1471-2105-9-11
@Article{SeqAn,
  AUTHOR = {Doring, Andreas and Weese, David and Rausch, Tobias and Reinert,
    Knut},
  TITLE = {SeqAn An efficient, generic C++ library for sequence analysis},
  JOURNAL = {BMC Bioinformatics},
  VOLUME = {9},
  YEAR = {2008},
  NUMBER = {1},
  PAGES = {11},
  URL = {http://www.biomedcentral.com/1471-2105/9/11},
  DOI = {10.1186/1471-2105-9-11},
  PubMedID = {18184432},
  ISSN = {1471-2105},
  ABSTRACT = {BACKGROUND: The use of novel algorithmic techniques is pivotal
  to many important problems in life science. For example the sequencing of
  the human genome [1] would not have been possible without advanced assembly
  algorithms. However, owing to the high speed of technological progress and
  the urgent need for bioinformatics tools, there is a widening gap between
  state-of-the-art algorithmic techniques and the actual algorithmic
  components of tools that are in widespread use. RESULTS: To remedy this
  trend we propose the use of SeqAn, a library of efficient data types and
  algorithms for sequence analysis in computational biology. SeqAn comprises
  implementations of existing, practical state-of-the-art algorithmic
  components to provide a sound basis for algorithm testing and development.
  In this paper we describe the design and content of SeqAn and demonstrate
  its use by giving two examples. In the first example we show an application
  of SeqAn as an experimental platform by comparing different exact string
  matching algorithms. The second example is a simple version of the well-
  known MUMmer tool rewritten in SeqAn. Results indicate that our
  implementation is very efficient and versatile to use. CONCLUSION: We
  anticipate that SeqAn greatly simplifies the rapid development of new
  bioinformatics tools by providing a collection of readily usable, well-
  designed algorithmic components which are fundamental for the field of
  sequence analysis. This leverages not only the implementation of new
  algorithms, but also enables a sound analysis and comparison of existing
  algorithms.},
}
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