<![CDATA[BOL: Related items]]> https://bioinformaticsonline.com/related/26925?offset=20 https://bioinformaticsonline.com/bookmarks/view/27110/easyfig Fri, 29 Apr 2016 05:49:39 -0500 https://bioinformaticsonline.com/bookmarks/view/27110/easyfig <![CDATA[Easyfig]]> Easyfig has moved to github, for newer releases of Easyfig please visit our new webpage - https://mjsull.github.io/Easyfig.  Easyfig is a Python application for creating linear comparison figures of multiple genomic loci with an easy-to-use graphical user interface (GUI).

More at http://easyfig.sourceforge.net/

Address of the bookmark: http://easyfig.sourceforge.net/

]]> Poonam Mahapatra https://bioinformaticsonline.com/bookmarks/view/26972/understanding-fastqc-output Fri, 15 Apr 2016 05:47:40 -0500 https://bioinformaticsonline.com/bookmarks/view/26972/understanding-fastqc-output <![CDATA[Understanding Fastqc Output]]> Understanding Following table and graphs

  1. Duplication level
  2. kmer profile
  3. per base GC content
  4. per base N content
  5. per base quality
  6. per base sequence content
  7. per sequence GC content
  8. per sequence quality
  9. sequence length distribution

More at http://www.bioinformatics.babraham.ac.uk/projects/fastqc/Help/3%20Analysis%20Modules/

Address of the bookmark: http://www.bioinformatics.babraham.ac.uk/projects/fastqc/Help/3%20Analysis%20Modules/

]]> Jit https://bioinformaticsonline.com/bookmarks/view/28999/redundans Thu, 01 Sep 2016 08:28:11 -0500 https://bioinformaticsonline.com/bookmarks/view/28999/redundans <![CDATA[Redundans]]> Redundans pipeline assists an assembly of heterozygous genomes.
Program takes as input assembled contigspaired-end and/or mate pairs sequencing libraries and returns scaffolded homozygous genome assembly, that should be less fragmented and with total size smaller than the input contigs. In addition, Redundans will automatically close the gaps resulting from genome assembly or scaffolding more details.

The pipeline consists of three steps/modules:

  • redundancy reduction: detection and selectively removal of redundant contigs from an initial de novo assembly
  • scaffolding: joining of genome fragments using paired-end and/or mate-pairs reads
  • gap closing

Redundans is:

  • fast & lightweight, multi-core support and memory-optimised, so it can be run even on the laptop for small-to-medium size genomes
  • flexible toward many sequencing technologies (Illumina, 454 or Sanger) and library types (paired-end, mate pairs, fosmids)
  • modular: every step can be ommited or replaced by another tools

Address of the bookmark: https://github.com/Gabaldonlab/redundans

]]> Jit https://bioinformaticsonline.com/bookmarks/view/29995/hga Tue, 29 Nov 2016 07:25:53 -0600 https://bioinformaticsonline.com/bookmarks/view/29995/hga <![CDATA[HGA]]> HGA tool version 1.0 This tool helps to apply the Hierarchical Genome Assembly (HGA) method. The tool will apply: 1. Partitioning a given reads dataset into a given number of partitions. 2. Assembling each partitions using a pre-specified assembler (Velvet or SPAdes in this version) and using a given kmer size. 3. Merging all the assemblies of the partition. 4. Combining all the assemblies of the partition (using velvet with kmer value of 31). 5. Finaly, re-assembling the whole dataset with the merged contigs or the combined contigs, using a given kmer size.

https://github.com/aalokaily/Hierarchical-Genome-Assembly-HGA

Address of the bookmark: https://github.com/aalokaily/Hierarchical-Genome-Assembly-HGA

]]> Jit https://bioinformaticsonline.com/bookmarks/view/30090/standardized-velvet-assembly-report Fri, 09 Dec 2016 03:59:59 -0600 https://bioinformaticsonline.com/bookmarks/view/30090/standardized-velvet-assembly-report <![CDATA[Standardized velvet assembly report]]> Requirements:

  • velvet (velveth velvetg should be in your PATH)
  • R (with Sweave)
  • pdflatex (usually part of TeTeX)
  • ggplot2 (from R prompt type install.packages("ggplot2","proto","xtable"))
  • Perl

Optional:

  • BLAT or BLAST (to generate alignments against a reference genome). If using BLAT, add faToTwoBit,gfClient,gfServer to your PATH. If using BLAST, add blastall and formatdb.

Edit permute.sh to your liking, paying particular attention to the kmer, cvCut, expCov, and other flags

To Run:

  1. perl fastaAllSize mysequences.fa > mysequences.stat or gunzip -c mysequences.fa.gz | fastaAllSize > mysequences.stat Substitute fastqAllSize for fastq files.
  2. ./permute.sh mysequences (leave out the .fa)

https://github.com/leipzig/standardized-velvet-assembly-report

Address of the bookmark: https://github.com/leipzig/standardized-velvet-assembly-report

]]> Poonam Mahapatra https://bioinformaticsonline.com/bookmarks/view/30130/scaffmatch Tue, 13 Dec 2016 10:23:56 -0600 https://bioinformaticsonline.com/bookmarks/view/30130/scaffmatch <![CDATA[ScaffMatch]]> caffMatch is a novel scaffolding tool based on Maximum-Weight Matching able to produce high-quality scaffolds from NGS data (reads and contigs). The tool is written in Python 2.7. It also includes a bash script wrapper that calls aligner in case one needs to first map reads to contigs (instead of providing .sam files).

The arguments accepted by ScaffMatch are:

  -w) Working directory -- this is the directory where ScaffMatch files are stored. These are .sam files produced after mapping reads to contigs and the resulting scaffolds file `scaffolds.fa` fasta file;

  -c) Contig fasta file;

  -m) Command line argument with no options. It is used when .sam files are used instead of reads .fastq files. Do not use this option if you provide reads files;

  -1) (Comma separated list of) either .fastq or .sam file(s) corresponding to the first read of the read pair;

  -2) (Comma separated list of) either .fastq or .sam file(s) corresponding to the second read of the read pair;

  -i) (Comma separated list of) insert size(s) of the library(-ies);

  -s) (Comma separated list of) library(-ies) standard deviation(s) of insert size(s);

  -t) Bundle threshold. Pairs of contigs supported by number of read pairs less than the value of this argument are discarded. Optional argument, by default it is equal to 5;

  -g) Matching heuristics: use `max_weight` for Maximum Weight Matching heuristics with the Insertion step, use `backbone` for Maximum Weight Matching heuristics without the Insertion step, use `greedy` for Greedy Matching heuristics;

  -l) Log file - where to store the logs. Optional argument. By default, stdout is used.

Address of the bookmark: http://alan.cs.gsu.edu/NGS/?q=content/scaffmatch

]]> 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/30249/genome-assembly-tutorial Tue, 20 Dec 2016 07:56:01 -0600 https://bioinformaticsonline.com/bookmarks/view/30249/genome-assembly-tutorial <![CDATA[Genome Assembly Tutorial]]> If genomes were completely random sequences in a statistical sense, 'overlap-consensus-layout' method would have been enough to assemble large genomes from Sanger reads. In contrast, real genomes often have long repetitive regions, and they are hard to assemble using overlap-consensus-layout approach. De Bruijn graph-based assembly approach was originally proposed to handle the assembly of repetitive regions better.

More at http://www.homolog.us/Tutorials/index.php?p=1.4&s=1

Address of the bookmark: http://www.homolog.us/Tutorials/index.php?p=1.4&s=1

]]> Abhimanyu Singh https://bioinformaticsonline.com/bookmarks/view/30701/harvest Tue, 31 Jan 2017 10:57:56 -0600 https://bioinformaticsonline.com/bookmarks/view/30701/harvest <![CDATA[Harvest]]> Harvest is a suite of core-genome alignment and visualization tools for quickly analyzing thousands of intraspecific microbial genomes, including variant calls, recombination detection, and phylogenetic trees.

_images/screen.png

Tools

  • Parsnp - Core-genome alignment and analysis
  • Gingr - Interactive visualization of alignments, trees and variants
  • HarvestTools - Archiving and postprocessing

Citation

Treangen TJ, Ondov BD, Koren S, Phillippy AM. The Harvest suite for rapid core-genome alignment and visualization of thousands of intraspecific microbial genomes. Genome Biology, 15 (11), 1-15 [PDF]

Address of the bookmark: http://harvest.readthedocs.io/en/latest/index.html

]]> Jit https://bioinformaticsonline.com/bookmarks/view/31087/bedtools Fri, 24 Feb 2017 04:50:44 -0600 https://bioinformaticsonline.com/bookmarks/view/31087/bedtools <![CDATA[bedtools]]> Collectively, the bedtools utilities are a swiss-army knife of tools for a wide-range of genomics analysis tasks. The most widely-used tools enable genome arithmetic: that is, set theory on the genome. For example, bedtools allows one tointersectmergecountcomplement, and shuffle genomic intervals from multiple files in widely-used genomic file formats such as BAM, BED, GFF/GTF, VCF. While each individual tool is designed to do a relatively simple task (e.g., intersect two interval files), quite sophisticated analyses can be conducted by combining multiple bedtools operations on the UNIX command line.

bedtools is developed in the Quinlan laboratory at the University of Utah and benefits from fantastic contributions made by scientists worldwide.

Address of the bookmark: http://bedtools.readthedocs.io/en/latest/index.html

]]> Jit