<![CDATA[BOL: Related items]]> https://bioinformaticsonline.com/related/31300?offset=70 https://bioinformaticsonline.com/file/view/29108/assembly-tutorial-ppt Wed, 07 Sep 2016 03:12:53 -0500 https://bioinformaticsonline.com/file/view/29108/assembly-tutorial-ppt <![CDATA[Assembly tutorial PPT]]> Saved Cornell University assembly workshop PPT.

Reference: 

http://cbsu.tc.cornell.edu/lab/doc/assembly_workshop_20150420_lecture1.pdf

]]> Jit https://bioinformaticsonline.com/bookmarks/view/29142/opera-optimal-paired-end-read-assembler Fri, 09 Sep 2016 05:28:58 -0500 https://bioinformaticsonline.com/bookmarks/view/29142/opera-optimal-paired-end-read-assembler <![CDATA[OPERA : Optimal Paired-End Read Assembler]]> OPERA (Optimal Paired-End Read Assembler) is a sequence assembly program (http://en.wikipedia.org/wiki/Sequence_assembly). It uses information from paired-end/mate-pair/long reads to order and orient the intermediate contigs/scaffolds assembled in a genome assembly project, in a process known as Scaffolding. OPERA is based on an exact algorithm that is guaranteed to minimize the discordance of scaffolds with the information provided by the paired-end/mate-pair/long reads (for further details see Gao et al, 2011).

Note that since the original publication, we have made significant changes to OPERA (v1.0 onwards) including refinements to its basic algorithm (to reduce local errors, improve efficiency etc.) and incorporated features that are important for scaffolding large genomes (multi-library support, better repeat-handling etc.), in addition to other scalability and usability improvements (bam and gzip support, smaller memory footprint). We therefore encourage you to download and use our latest version: OPERA-LG. In our benchmarks, it has significantly improved corrected N50 and reduced the number of scaffolding errors. Furthermore, our latest release contains the wrapper script OPERA-long-read that enables scaffolding with long-reads from third-generation sequencing technologies (PacBio or Oxford Nanopore). The manuscript describing the new features and algorithms is available at Genome Biology. We look forward to getting your feedback to improve it further.

Address of the bookmark: https://sourceforge.net/p/operasf/wiki/The%20OPERA%20wiki/

]]> Jit https://bioinformaticsonline.com/bookmarks/view/29485/ribbon Fri, 21 Oct 2016 04:54:30 -0500 https://bioinformaticsonline.com/bookmarks/view/29485/ribbon <![CDATA[Ribbon !!]]> Visualization has played an extremely important role in the current genomic revolution to inspect and understand variants, expression patterns, evolutionary changes, and a number of other relationships. However, most of the information in read-to-reference or genome-genome alignments is lost for structural variations in the one-dimensional views of most genome browsers showing only reference coordinates. Instead, structural variations captured by long reads or assembled contigs often need more context to understand, including alignments and other genomic information from multiple chromosomes. We have addressed this problem by creating Ribbon (genomeribbon.com) an interactive online visualization tool that displays alignments along both reference and query sequences, along with any associated variant calls in the sample. This way Ribbon shows patterns in alignments of many reads across multiple chromosomes, while allowing detailed inspection of individual reads (Supplementary Note 1). For example, here we show a gene fusion in the SK-BR-3 breast cancer cell line linking the genes CYTH1 and EIF3H. While it has been found in the transcriptome previously, genome sequencing did not identify a direct chromosomal fusion between these two genes. After SMRT sequencing, Ribbon shows that there are indeed long reads that span from one gene to the other, going through not one but two variants, for the first time showing the genomic link between these two genes (Figure 1a). More gene fusions of this cancer cell line are investigated in Supplementary Note 2. Figure 1b shows another complex event in this sample made simple in Ribbon: the translocation of a 4.4 kb sequence deleted from chr19 and inserted into chr16 (Figure 1b). Thus, Ribbon enables understanding of complex variants, and it may also help in the detection of sequencing and sample preparation issues, testing of aligners and variant-callers, and rapid curation of structural variant candidates (Supplementary Note 3). In addition to SAM and BAM files with long, short, or paired-end reads, Ribbon can also load coordinate files from whole genome aligners such as MUMmer. Therefore, Ribbon can be used to test assembly algorithms or inspect the similarity between species. Supplementary Note 4 shows a comparison of gorilla and human genomes using Ribbon, highlighting major structural differences. In conclusion, Ribbon is a powerful interactive web tool for viewing complex genomic alignments.

Script at https://github.com/MariaNattestad/ribbon

Address of the bookmark: http://genomeribbon.com/

]]> Jit https://bioinformaticsonline.com/bookmarks/view/29586/eforgev12 Fri, 28 Oct 2016 09:06:59 -0500 https://bioinformaticsonline.com/bookmarks/view/29586/eforgev12 <![CDATA[eFORGE.v1.2]]> The eFORGE tool provides a method to view the tissue specific regulatory component of a set of EWAS DMPs. eFORGE analysis takes a set of DMPs, such as those hits above genome-wide significance threshold in an EWAS study, and analyses whether there is enrichment for overlap of putative functional elements compared to matched background DMPs. It assesses enrichment on a per cell type basis, since functional elements are differentially active in different cell types, and hence can expose tissue-specific signals of enrichment for the given test DMP set. This can reveal the sites of action underlying the EWAS signal, and provide confirmation of the validity of the EWAS where a tissue-specific mechanism is known or expected for the phenotype. Conversely unknown tissue involvements can also be revealed.

Address of the bookmark: http://eforge.cs.ucl.ac.uk/eFORGE.v1.2/?documentation

]]> Jit https://bioinformaticsonline.com/bookmarks/view/30236/pyscaf Mon, 19 Dec 2016 14:20:33 -0600 https://bioinformaticsonline.com/bookmarks/view/30236/pyscaf <![CDATA[pyScaf]]> pyScaf orders contigs from genome assemblies utilising several types of information:

Scaffolding 

In reference-based mode, pyScaf uses synteny to the genome of closely related species in order to order contigs and estimate distances between adjacent contigs.

Contigs are aligned globally (end-to-end) onto reference chromosomes, ignoring:

  • matches not satisfying cut-offs (--identity and --overlap)
  • suboptimal matches (only best match of each query to reference is kept)
  • and removing overlapping matches on reference.

In preliminary tests, pyScaf performed superbly on simulated heterozygous genomes based on C. parapsilosis (13 Mb; CANPA) and A. thaliana (119 Mb; ARATH) chromosomes, reconstructing correctly all chromosomes always for CANPA and nearly always for ARATH (Figures in dropboxCANPA tableARATH table).
Runs took ~0.5 min for CANPA on 4 CPUs and ~2 min for ARATH on 16 CPUs.

Important remarks:

  • Reduce your assembly before (fasta2homozygous.py) as any redundancy will likely break the synteny.
  • pyScaf works better with contigs than scaffolds, as scaffolds are often affected by mis-assemblies (no de novo assembler / scaffolder is perfect...), which breaks synteny.
  • pyScaf works very well if divergence between reference genome and assembled contigs is below 20% at nucleotide level.
  • pyScaf deals with large rearrangements ie. deletions, insertion, inversions, translocations. Note however, this is experimental implementation!
  • Consider closing gaps after scaffolding.

Address of the bookmark: https://github.com/lpryszcz/pyScaf

]]> Bulbul https://bioinformaticsonline.com/bookmarks/view/30074/minia Thu, 08 Dec 2016 05:07:00 -0600 https://bioinformaticsonline.com/bookmarks/view/30074/minia <![CDATA[Minia]]> Minia is a short-read assembler based on a de Bruijn graph, capable of assembling a human genome on a desktop computer in a day. The output of Minia is a set of contigs. Minia produces results of similar contiguity and accuracy to other de Bruijn assemblers (e.g. Velvet).

Download

Minia 2.0.7 Linux 64-bits binaries (Source code(Legacy codebase)

For the impatient

A typical Minia command line looks like:

./minia -in reads.fa -kmer-size 31 -abundance-min 3 -out output_prefix

Type

./minia

for a quick explanation of the parameters.

For more information, refer to the manual.

KmerGenie can be used to determine the best k-mer size, minimum abundance of correct k-mers, and genome size estimation for your dataset.

 

Address of the bookmark: http://minia.genouest.org/

]]> Jit https://bioinformaticsonline.com/bookmarks/view/30093/velvet-tutorial Fri, 09 Dec 2016 04:19:07 -0600 https://bioinformaticsonline.com/bookmarks/view/30093/velvet-tutorial <![CDATA[Velvet tutorial]]> The objective of this activity is to help you understand how to run Velvet in general, how to accurately estimate the insert size of a paired-end library through the use of Bowtie, the primary parameters of velvet, and the process involved in producing a de novo assembly from Illumina reads.

http://evomics.org/learning/assembly-and-alignment/velvet/

Address of the bookmark: http://evomics.org/learning/assembly-and-alignment/velvet/

]]> Poonam Mahapatra https://bioinformaticsonline.com/bookmarks/view/30153/e-mem-efficient-computation-of-maximal-exact-matches Thu, 15 Dec 2016 09:30:43 -0600 https://bioinformaticsonline.com/bookmarks/view/30153/e-mem-efficient-computation-of-maximal-exact-matches <![CDATA[E-MEM: Efficient computation of Maximal Exact Matches]]> E-MEM is a C++/OpenMP program designed to efficiently compute MEMs between large genomes. See the README file for instructions on how to use E-MEM. 

E-MEM source code

The source code can be downloaded here

If you use E-MEM, please cite:

  • N. Khiste, L. Ilie, E-MEM: Efficient computation of Maximal Exact Matches for very large genomes, Bioinformatics 31(4) (2015) 509 -- 514.

For any questions, please contact Lucian Ilie: ilie@uwo.ca 

Address of the bookmark: http://www.csd.uwo.ca/~ilie/E-MEM/

]]> Jit https://bioinformaticsonline.com/bookmarks/view/30212/pear Mon, 19 Dec 2016 09:28:30 -0600 https://bioinformaticsonline.com/bookmarks/view/30212/pear <![CDATA[PEAR]]> PEAR is an ultrafast, memory-efficient and highly accurate pair-end read merger. It is fully parallelized and can run with as low as just a few kilobytes of memory.

PEAR evaluates all possible paired-end read overlaps and without requiring the target fragment size as input. In addition, it implements a statistical test for minimizing false-positive results. Together with a highly optimized implementation, it can merge millions of paired end reads within a couple of minutes on a standard desktop computer.

Address of the bookmark: http://sco.h-its.org/exelixis/web/software/pear/doc.html

]]> Jit https://bioinformaticsonline.com/bookmarks/view/30304/mcscan Thu, 22 Dec 2016 03:53:58 -0600 https://bioinformaticsonline.com/bookmarks/view/30304/mcscan <![CDATA[MCscan]]> MCscan is a computer program that can simultaneously scan multiple genomes to identify homologous chromosomal regions and subsequently align these regions using genes as anchors. This is the toolset for generating the synteny correspondences in Plant Genome Duplication Database. It is intended as an easy-to-use and quick way to identify conserved gene arrays both within the same genome and across different genomes.

More at http://chibba.agtec.uga.edu/duplication/mcscan/

Address of the bookmark: http://chibba.agtec.uga.edu/duplication/mcscan/

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