<![CDATA[BOL: Related items]]> https://bioinformaticsonline.com/related/34867?offset=600 https://bioinformaticsonline.com/researchlabs/view/4873/vveks-lab Thu, 26 Sep 2013 11:11:39 -0500 <![CDATA[Vvek's Lab]]> Broad Area of Research: RNA biology (microRNA, lncRNA), Stem cells, Functional genomics, Epigenomics and Cancer

RNAs, especially non-coding RNAs (such as microRNA, long ncRNAs) are recently identified to be very abundant in mammalian organisms and play some key roles in gene expression regulation, gene silencing, and also implicated in disease progression, stem cell pluripotency etc. Current research activities of our lab include analysis of expression pattern of ncRNAs by microarray and next-gen sequencing data and understanding the role of miRNAs or other regulatory RNAs in various diseases, especially cancer and validation by reporter assays (renilla/luciferase) and other experimental tools.

More @ http://vvekslab.in/index.html

]]> https://bioinformaticsonline.com/researchlabs/view/14756/roderic-guigo-lab Mon, 01 Sep 2014 17:13:00 -0500 <![CDATA[Roderic Guigó Lab]]> Research in our group focuses on the investigation of the signals involved in gene specification in genomic sequences (promoter elements, splice sites, translation initiation sites, etc…). We are interested both in the mechanism of their recognition and processing, and in their evolution. In addition, but related to this basic component of our research, our group is also involved in the development of software for gene prediction and annotation in genomic sequences. Our group also actively participates in the analysis of many eukaryotic genomes and it in involved in the NIH-funded ENCODE project. Furthermore we are members of two large cancer-studies consortia (chronic lymphocytic leukemia "CLL" and Breast Cancer -Hospital del Mar/CRG/Roche-).

More at http://big.crg.cat/computational_biology_of_rna_processing

]]> https://bioinformaticsonline.com/researchlabs/view/25993/hoffman-lab Tue, 12 Jan 2016 02:47:41 -0600 <![CDATA[Hoffman Lab]]> They develop machine learning techniques to better understand chromatin biology. These models and algorithms transform high-dimensional functional genomics data into interpretable patterns and lead to new biological insight.

https://www.pmgenomics.ca/hoffmanlab/

]]> https://bioinformaticsonline.com/blog/view/43997/tools-for-rna-classification Tue, 08 Nov 2022 03:39:11 -0600 https://bioinformaticsonline.com/blog/view/43997/tools-for-rna-classification <![CDATA[Tools for RNA classification]]> barrnap - https://github.com/tseemann/barrnap

CPAT - https://github.com/liguowang/cpathttp://lilab.research.bcm.edu/ (web server)

CPC2 - https://github.com/gao-lab/CPC2_standalonehttp://cpc2.gao-lab.org/ (web server)

Infernal - http://eddylab.org/infernal/https://github.com/EddyRivasLab/infernal

NCBI RefSeq - https://www.ncbi.nlm.nih.gov/refseq/

Rfam - http://rfam.xfam.org/https://docs.rfam.org/en/latest/index.html

SILVA - https://www.arb-silva.de/

RNAmmer - http://www.cbs.dtu.dk/services/RNAmmer/ (web server, standalone download link)

]]> Abhi https://bioinformaticsonline.com/news/view/44724/step-by-step-guide-to-detect-pirnas-using-bioinformatics Fri, 13 Dec 2024 11:41:46 -0600 https://bioinformaticsonline.com/news/view/44724/step-by-step-guide-to-detect-pirnas-using-bioinformatics <![CDATA[Step-by-Step Guide to Detect piRNAs Using Bioinformatics]]> Piwi-interacting RNAs (piRNAs) are a class of small non-coding RNAs that play crucial roles in silencing transposable elements and regulating gene expression, particularly in germline cells. Detecting piRNAs involves identifying their unique characteristics, such as size, sequence motifs, and association with Piwi proteins, from high-throughput RNA sequencing data.

This blog provides a comprehensive step-by-step guide to detect piRNAs using bioinformatics tools and workflows.

Step 1: Prepare Your Data

  1. Obtain RNA Sequencing Data
    Acquire raw small RNA-seq data in FASTQ format. Datasets can be sourced from repositories like NCBI SRA, EMBL-EBI, or specific small RNA sequencing projects.

  2. Quality Control (QC)
    Use FastQC to assess the quality of raw reads:

    fastqc reads.fastq

    Evaluate the per-base quality, adapter content, and overrepresented sequences.

  3. Trimming and Adapter Removal
    Use tools like Cutadapt or Trim Galore! to remove adapters and low-quality bases:

    cutadapt -a TGGAATTCTCGGGTGCCAAGG -o trimmed_reads.fastq reads.fastq

    Ensure the remaining reads are of high quality for downstream analysis.

Step 2: Map Reads to the Genome

Mapping reads to the reference genome is crucial for identifying piRNA loci.

  1. Reference Genome Preparation
    Download the genome assembly of your organism from databases like Ensembl, UCSC Genome Browser, or NCBI.

  2. Align Reads
    Use Bowtie or STAR for small RNA alignment:

    bowtie -v 1 -k 1 --best genome_index trimmed_reads.fastq -S aligned_reads.sam
    • -v 1: Allows one mismatch.
    • -k 1: Reports the best alignment.

  3. Convert SAM to BAM
    Convert and sort alignments using SAMtools:

    samtools view -Sb aligned_reads.sam | samtools sort -o sorted_reads.bam

Step 3: Identify Small RNAs

piRNAs are characterized by their size (24–32 nt) and strand bias.

  1. Extract Reads by Size
    Use tools like BEDtools or custom scripts to filter reads between 24 and 32 nt:

    bedtools bamtofastq -i sorted_reads.bam -fq all_reads.fastq seqkit seq -m 24 -M 32 all_reads.fastq > piRNA_size_reads.fastq

  2. Check for Sequence Bias
    piRNAs often have a strong bias for a uridine at the 5’ end (1U bias). Use tools like WebLogo to visualize sequence motifs.

Step 4: Detect Ping-Pong Signature

The ping-pong amplification loop is a hallmark of piRNA biogenesis, characterized by a 10 nt overlap between piRNAs on opposite strands.

  1. Generate Overlap Statistics
    Use the piPipes tool or custom scripts to calculate overlap:

    python ping_pong_overlap.py sorted_reads.bam

  2. Visualize Overlap Distribution
    Plot the distribution of overlaps to confirm the presence of the 10 nt ping-pong signature.

Step 5: Annotate piRNA Clusters

piRNAs are often generated from genomic clusters.

  1. Cluster Identification
    Use tools like proTRAC or PIRANHA to identify piRNA-producing clusters:

    proTRAC.pl -s sorted_reads.bam -g genome.fa -o clusters

  2. Annotate Genomic Regions
    Annotate the identified clusters using gene annotation files (GTF/GFF). Tools like BEDtools intersect can help associate piRNA clusters with genes or transposable elements:

    bedtools intersect -a clusters.bed -b genome_annotation.gtf > annotated_clusters.bed

Step 6: Functional Analysis

Functional analysis of piRNAs can uncover their targets and regulatory roles.

  1. Predict piRNA Targets
    Use tools like IntaRNA or RNAhybrid to predict interactions between piRNAs and potential target mRNAs:

    RNAhybrid -t target_transcripts.fa -q piRNAs.fa > piRNA_targets.txt

  2. Enrichment Analysis
    Perform GO or KEGG enrichment analysis of target genes using tools like g:Profiler or DAVID.

Step 7: Validation and Visualization

  1. Validate piRNA Candidates
    Cross-check the identified piRNAs against known piRNA databases, such as piRBase or piRNAdb.

  2. Visualize Results

    • Use IGV (Integrative Genomics Viewer) to visualize piRNA alignment and clusters on the genome.
    • Generate heatmaps or circos plots to present piRNA distributions.

Step 8: Share and Publish Findings

  1. Archive Data
    Submit sequencing data to public repositories like SRA or GEO with metadata specifying piRNA-related experiments.

  2. Publish Results
    Share findings in journals or conferences, emphasizing novel piRNA candidates, target genes, or regulatory mechanisms.

Conclusion

Detecting piRNAs involves a combination of computational and analytical methods to identify these unique small RNAs and their roles in gene regulation and transposable element suppression. By following this step-by-step guide, you can confidently navigate the complexities of piRNA detection and contribute to the growing understanding of their biological significance.

]]> Abhi https://bioinformaticsonline.com/view/2044 Mon, 12 Aug 2013 12:19:29 -0500 https://bioinformaticsonline.com/view/2044 <![CDATA[Does anyone have Nanopore latest updates?]]> There was a lot of buzz about Oxford Nanopore Technologies® is developing the GridION™ system and miniaturised MinION™ device. These are a new generation of electronic molecular analysis system for use in scientific research, personalised medicine, crop science, security/defence and more. The platform technology uses nanopores to analyse single molecules including DNA/RNA and proteins. With a broad patent portfolio, the Oxford Nanopore pipeline includes biological nanopores and solid-state nanopores.

Is this available, or still under trial mode? 

https://www.nanoporetech.com/

https://www.nanoporetech.com/technology/the-minion-device-a-miniaturised-sensing-system/the-minion-device-a-miniaturised-sensing-system

]]> Poonam Mahapatra https://bioinformaticsonline.com/bookmarks/view/4208/latest-paper-on-comparison-of-mapping-tools Tue, 03 Sep 2013 18:00:38 -0500 https://bioinformaticsonline.com/bookmarks/view/4208/latest-paper-on-comparison-of-mapping-tools <![CDATA[Latest paper on comparison of mapping tools]]> A. Hatem, D. Bozdag, A. E. Toland, U. V. Catalyurek "Benchmarking short sequence mapping tools" BMC Bioinformatics, 14(1):184, 2013.

http://bmi.osu.edu/hpc/software/benchmark/

http://bmi.osu.edu/hpc/software/pmap/pmap.html

Other similiar papers:

http://online.liebertpub.com/doi/pdf/10.1089/cmb.2012.0022

http://bioinformatics.oxfordjournals.org/content/28/24/3169

Some new Mapping tool links:

GSNAP

http://research-pub.gene.com/gmap/

RMAP

http://rulai.cshl.edu/rmap/

mrsFAST

http://mrsfast.sourceforge.net/Home

http://sourceforge.net/projects/mrsfast/files/mrsfast-ultra-3.1.0/

BFAST

http://sourceforge.net/apps/mediawiki/bfast/index.php?title=Main_Page

SHRiMP (for AB SOLiD color-space reads)

http://compbio.cs.toronto.edu/shrimp/

RazerA 3

http://www.seqan.de/projects/razers/

Address of the bookmark: http://www.biomedcentral.com/1471-2105/14/184

]]> Rahul Agarwal https://bioinformaticsonline.com/bookmarks/view/9400/largest-genome-sequenced Fri, 21 Mar 2014 13:57:19 -0500 https://bioinformaticsonline.com/bookmarks/view/9400/largest-genome-sequenced <![CDATA[Largest Genome Sequenced]]> The enormous size of the loblolly pine genome having 22 billion base pairs compared to only 3 billion in the human genome. In other words, it is seven times larger than a human’s and also the largest and the most complete conifer genome ever sequenced.

Related Paper:

http://genomebiology.com/2014/15/3/R59/abstract

 

Address of the bookmark: http://www.news.ucdavis.edu/search/news_detail.lasso?id=10859

]]> Rahul Agarwal https://bioinformaticsonline.com/bookmarks/view/10243/new-rna-seq-tool Fri, 25 Apr 2014 10:59:04 -0500 https://bioinformaticsonline.com/bookmarks/view/10243/new-rna-seq-tool <![CDATA[New RNA Seq tool]]> "By removing the time-consuming step of read mapping, the authors reported, Sailfish able to provide quantification estimates 20–30 times faster than current methods without loss of accuracy."

Tool link:

http://www.cs.cmu.edu/~ckingsf/software/sailfish/

Address of the bookmark: http://www.genengnews.com/gen-news-highlights/lightweight-algorithms-sail-through-rna-sequencing-data/81249765/

]]> Rahul Agarwal https://bioinformaticsonline.com/news/view/10966/genxpro-gmbh Thu, 22 May 2014 07:18:35 -0500 https://bioinformaticsonline.com/news/view/10966/genxpro-gmbh <![CDATA[GenXPro GmbH]]> GenXPro GMbH is service provider for entire spectrum of nucleotide-based information of any biological sample. By combining intelligent data reduction techniques and latest next generation sequencing technologies, our service portfolio provides most accurate and cost efficient solutions for transcriptomic-, genomic- or epigenomic research.

GENXPRO GMBHALTENHÖFERALLEE 3, 60438 FRANKFURT MAIN, GERMANY

Websitehttp://www.genxpro.info/products_and_services/

PHONE: +49 (0)69- 95 73 97 10, FAX: +49 (0)69- 95 73 97 06

EMAIL: info@genxpro.de

]]> Rahul Agarwal