Seqanswers Leaderboard Ad

Collapse

Announcement

Collapse
No announcement yet.
X
Collapse
 
  • Page of 1
  • Filter
  • Time
  • Show
Clear All
new posts
Previous template Next
  • #1

    Bacterial RNA-Seq - Problem Counting Reads with htseq

    I'm having problems utilizing htseq.

    I have a sam file of paired end illumina reads. These have been sorted by the read name (1st column). Here are the first few lines of data:


    HWI-ST261:3960D48ABXX:4:1101:10002:96209 147 gi|237809907|ref|NC_012692.1| 30581 255 79M = 30446 -214 AGGCCCCCAGCGTCATGCAGGCGCTCTCCGCCTACCGCGATGGCGCGCGCATCCATGCCGGCACGCGACCGGGCGCACC #####################################?C<562'93>>6BFHBA<@B=A7(:A@@@IIGHFDHHDDD XA:i:0 MD:Z:1T4G4T3G9G0C0T51 NM:i:7
    HWI-ST261:3960D48ABXX:4:1101:10002:96209 99 gi|237809907|ref|NC_012692.1| 30446 255 79M = 30581 214 AGCAGCCGGCGCTTTACTGGCACTTCAGGAACAAGCGGGCGCTGCTCGACGCACTGGCCGAAGCCATGCTGGGGGAGAA FFHGHHHHGHHJJHIIIIIJJJIIIJJIFIIIGIJ@@EHF?8=@85:<0:<BD@59AADB################### XA:i:0 MD:Z:72C6 NM:i:1
    HWI-ST261:3960D48ABXX:4:1101:10007:167767 163 gi|237809907|ref|NC_012692.1| 115957 255 79M = 116090 212 ACTGGTCCAGAACCTTGACCGAACGCAGCGGTGGTAACGGCGCAGTGGCGGTTTTCATGGCTTTTTTTTTTCTGTTTTT FFHHHHHJJJGIJJJJIGIIIJJJJJGJJJJFHGHGGHHHFDDDDDCDDDD00;B######################## XA:i:0 MD:Z:63G2A1G0A0C0T0G0T5 NM:i:8
    HWI-ST261:3960D48ABXX:4:1101:10007:167767 83 gi|237809907|ref|NC_012692.1| 116090 255 79M = 115957 -212 ATGTTTGATGTTATGGAGCAGCAACGATGTTACGCAGCAGGGCAGTCGCCCTAAAACAAAGTTAGACATCATGAGGGTA DDDDDDDDDDDDDDDDDDDDDEDDFFFFFHHHJJJJJJJJJJJJJJJJJIJJJJJJJJJIHJJJHIGJJJJIHHHHHFF XA:i:0 MD:Z:79 NM:i:0
    HWI-ST261:3960D48ABXX:4:1101:10013:104772 163 gi|237809907|ref|NC_012692.1| 119786 255 79M = 119940 233 TCGAAGACGCCCTGCATGCCACCCGTGCGGCGGTCGAGGAAGGCATCGTCCCGGGCGGCGGGGCCGCCCCGGTCCGTGC FFHGHFHGIIIIIGIADFHHJJJJIAGIIIHDD?B6-9:&8<@??9?@DA@D&077;@##################### XA:i:0 MD:Z:61C1T5T1A7 NM:i:4
    HWI-ST261:3960D48ABXX:4:1101:10013:104772 83 gi|237809907|ref|NC_012692.1| 119940 255 79M = 119786 -233 GAAAGCCCCGCGCCGCGAGTTCGCCCCCAACGCCGGCGACGAGCCGAGCGTGGTGCTGAACCGCGTCGCCGAAGGCACC ########################################B<@@;>;BCCDDB?@@BEA<IHBEHHHGIGJIFHFADFF XA:i:0 MD:Z:1G9T0G6A3T1A53 NM:i:6

    Next I have a GTF file. Here the first few lines:

    ##gff-version 3
    #!gff-spec-version 1.20
    #!processor NCBI annotwriter
    ##sequence-region NC_012692.1 1 166530
    ##species http://www.ncbi.nlm.nih.gov/Taxonomy...tax.cgi?id=562
    NC_012692.1 RefSeq region 1 166530 . + . ID=id0;Dbxref=taxon:562;Is_circular=true;gbkey=Src;genome=plasmid;mol_type=genomic DNA;plasmid-name=pAR060302;strain=AR060302
    NC_012692.1 RefSeq gene 323 862 . + . ID=gene0;Name=pAR060302_0001;Dbxref=GeneID:7872685;gbkey=Gene;locus_tag=pAR060302_0001
    NC_012692.1 RefSeq CDS 323 862 . + 0 ID=cds0;Name=YP_002894347.1;Parent=gene0;Note=identified by Glimmer 2%3B sequence similarity to pSN254_0002%3B blastp_match %3D ZP_01176338.1;Dbxref=Genbank:YP_002894347.1,GeneID:7872685;gbkey=CDS;product=hypothetical protein;protein_id=YP_002894347.1;transl_table=11
    NC_012692.1 RefSeq gene 867 1154 . + . ID=gene1;Name=pAR060302_0002;Dbxref=GeneID:7872573;gbkey=Gene;locus_tag=pAR060302_0002
    NC_012692.1 RefSeq CDS 867 1154 . + 0 ID=cds1;Name=YP_002894348.1;Parent=gene1;Note=identified by Glimmer 2%3B sequence similarity to pSN254_0002%3B blastp_match %3D ZP_01176339.1;Dbxref=Genbank:YP_002894348.1,GeneID:7872573;gbkey=CDS;product=hypothetical protein;protein_id=YP_002894348.1;transl_table=11
    NC_012692.1 RefSeq gene 1139 2239 . + . ID=gene2;Name=repA;Dbxref=GeneID:7872574;gbkey=Gene;gene=repA;locus_tag=pAR060302_0003
    NC_012692.1 RefSeq CDS 1139 2239 . + 0 ID=cds2;Name=YP_002894349.1;Parent=gene2;Note=identified by Glimmer 2%3B sequence similarity to pSN254_0003%3B blastp_match %3D ZP_01176340.1;Dbxref=Genbank:YP_002894349.1,GeneID:7872574;gbkey=CDS;product=plasmid replication protein RepA;protein_id=YP_002894349.1;transl_table=11

    What I want to do is count the reads that align to the CDS and return a file with the GeneID and the number of reads that align to it so that I can use these in subsequent edgeR analyses.

    The command I run is

    -m HTSeq.scripts.count -m intersection-nonempty -t CDS -s no -i Dbxref pAR_sorted.sam NC_012692.gff > test.txt

    in my output I get no reads aligning to any CDS

    no_feature 49397
    ambiguous 0
    too_low_aQual 0
    not_aligned 0
    alignment_not_unique 0


    However I know that this cannot be true - I have viewed this data on IGV and there are many many reads aligned to the CDS

    Any thoughts?
    Tags: None
  • #2
    I have run HTSeq successfully on similar GFF files with the options

    -i locus_tag -t Gene

    I wonder if it is the Dbxref that is messing up things for you, but I am not sure. You could try to use "Gene" and "locus_tag" or "Name" instead.

    Comment

    • #3
      I've found the answer.

      In my sam file the reference (3 column) the accession was given as gi|237809907|ref|NC_012692.1|.

      But my gff file it was simply NC_012692.1. A simple find (NC_012692.1) replace (gi|237809907|ref|NC_012692.1|) in my gff file is all I needed.

      Comment

      • #4
        Thanks!!!! great detail

        Comment

        Previous template Next

        Latest Articles

        Collapse
        • seqadmin
          Essential Discoveries and Tools in Epitranscriptomics
          by seqadmin




          The field of epigenetics has traditionally concentrated more on DNA and how changes like methylation and phosphorylation of histones impact gene expression and regulation. However, our increased understanding of RNA modifications and their importance in cellular processes has led to a rise in epitranscriptomics research. “Epitranscriptomics brings together the concepts of epigenetics and gene expression,” explained Adrien Leger, PhD, Principal Research Scientist...
          04-22-2024, 07:01 AM
        • seqadmin
          Current Approaches to Protein Sequencing
          by seqadmin


          Proteins are often described as the workhorses of the cell, and identifying their sequences is key to understanding their role in biological processes and disease. Currently, the most common technique used to determine protein sequences is mass spectrometry. While still a valuable tool, mass spectrometry faces several limitations and requires a highly experienced scientist familiar with the equipment to operate it. Additionally, other proteomic methods, like affinity assays, are constrained...
          04-04-2024, 04:25 PM
        View All

        ad_right_rmr

        Collapse

        News

        Collapse
        Topics Statistics Last Post
        Expanding the Horizons of Cellular Research with the Single Cell Atlas by seqadmin
        Started by seqadmin, 04-25-2024, 11:49 AM
        0 responses
        19 views
        0 likes
        		 Last Post seqadmin
        by seqadmin
        04-25-2024, 11:49 AM  
        Genetic Variants and Diabetes Risk in Childhood Cancer Survivors by seqadmin
        Started by seqadmin, 04-24-2024, 08:47 AM
        0 responses
        18 views
        0 likes
        		 Last Post seqadmin
        by seqadmin
        04-24-2024, 08:47 AM  
        Cancer Metastasis: A Deep Dive into Cellular Plasticity by seqadmin
        Started by seqadmin, 04-11-2024, 12:08 PM
        0 responses
        62 views
        0 likes
        		 Last Post seqadmin
        by seqadmin
        04-11-2024, 12:08 PM  
        Proteogenomic Profiles Offer New Clues in Prostate Cancer by seqadmin
        Started by seqadmin, 04-10-2024, 10:19 PM
        0 responses
        60 views
        0 likes
        		 Last Post seqadmin
        by seqadmin
        04-10-2024, 10:19 PM  
        View All
        Working...
        X