Tweet
Hi,
Do you know a free software like REPuter for find and visualise repeat sequences?
Thanks
Do you know a free software like REPuter for find and visualise repeat sequences?
Thanks
-
-
By repeat structures, I assume you mean transposable elements? If so, there are more sophisticated programs to predict both Class I and Class II TEs based on structure and domain architecture. Tell us what you want to find so that we can make suggestions. The general topic of repeat finding is so broad that it would be hard to start listing programs without a better idea of what you are trying to do. Also, the visualization offered by that program is pretty crude. What type of visualization did you have in mind? -
Hi!
I'm working on de novo chloroplast genome, and there are a lot of little repeated sequences.
For exemple, REPuter can find all little repeated sequences who have more than 30 nucleotid. This is an output example:
There are other kind of output file. After, I can use REPEATmasker for mask all repeated sequences in my genome and know what is pourcentage of it. What I mean by ''visualise'', it's the density of repeated sequences, for exemple:Code:>Sequence1 tcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtatt >Sequence2 tcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtatt >Sequence3 tcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtatt >Sequence4 tcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtatt >Sequence5 tcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtatt >Sequence6 tcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtatt >Sequence7 tcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtatt >Sequence8 aggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagagga >Sequence9 tcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtatt >Sequence10 aggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagagga >Sequence11 tcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtatt >Sequence12 aggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagagga >Sequence13 aggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagagga >Sequence14 tcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtatt >Sequence15 aggaacttctcgaccgtatgggagaggaacttctcgaccgtatgggagaggaacttctcgaccgtatgggagaggaacttctcgaccgtatgggagaggaacttctcgaccgtatgggagaggaacttctcgaccgtatgggagaggaacttctcgaccgtatgggagaggaacttctcgaccgtatgggagaggaacttctcgaccgtatgggagaggaacttctcgaccgtatgggagaggaacttctcgaccgtatgggagaggaacttctcgaccgtatgggagaggaacttctcgaccgtatgggagag >Sequence16 aggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagaggatgagcatagcgaatactcgtcagagga >Sequence17 aggaacttctcgaccgtatgggagaggaacttctcgaccgtatgggagaggaacttctcgaccgtatgggagaggaacttctcgaccgtatgggagaggaacttctcgaccgtatgggagaggaacttctcgaccgtatgggagaggaacttctcgaccgtatgggagaggaacttctcgaccgtatgggagaggaacttctcgaccgtatgggagaggaacttctcgaccgtatgggagaggaacttctcgaccgtatgggagaggaacttctcgaccgtatgggagag >Sequence18 tcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtattacatgcgtagcatgtattcctctcattcttcgagtatt >Sequence19
http://t1.gstatic.com/images?q=tbn:A...DXF8fmO8LizSEu
Thanks!Comment
-
There are no transposable elements in the chloroplast genome, but there are large (and probably numerous small) tandem repeats. One idea would be to just calculate the density of repeats across the genome and plot that as a histogram. I have done this for looking at the tandem repeats in chloroplast genomes.Comment
-
Thanks for you answer! Do you know a software for do this?Comment
-
You could use TRF or Vmatch or any number of tools to find the repeats. From there it may take a little scripting so you can plot the repeat density in R (or any other plotting program).Originally posted by Antony03 View PostComment
-
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 -
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
Comment