Difference between revisions of "Part:BBa K5490000:Design"
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References | References | ||
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+ | [1] Wessels, H. H., Méndez-Mancilla, A., Guo, X., Legut, M., Daniloski, Z., & Sanjana, N. E. (2020). Massively parallel Cas13 screens reveal principles for guide RNA design. Nature biotechnology, 38(6), 722-727. | ||
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+ | [2] Keng, C. T., Yogarajah, T., Lee, R. C. H., Muhammad, I. B. H., Chia, B. S., Vasandani, S. R., ... & Chew, W. L. (2023). AAV-CRISPR-Cas13 eliminates human enterovirus and prevents death of infected mice. EBioMedicine, 93. | ||
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+ | [3] https://gitlab.com/sanjanalab/cas13/-/tree/master/Cas13designGuidePredictor | ||
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+ | [4] https://github.com/chewlabSB2/Cas13gRNAtor | ||
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+ | [5] https://gitlab.igem.org/2024/software-tools/ioannina | ||
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+ | [6] https://www.ncbi.nlm.nih.gov/labs/virus/vssi/#/virus?SeqType_s=Nucleotide&VirusLineage_ss=West%20Nile%20virus,%20taxid:11082&Completeness_s=complete&Region_s=Africa&Region_s=Europe | ||
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+ | [7] https://support.illumina.com/sequencing/sequencing_software/igenome.html | ||
Latest revision as of 17:28, 27 September 2024
23-nt sequence binds CasRx to cleave WNV genome modifiable target 1.
- 10COMPATIBLE WITH RFC[10]
- 12COMPATIBLE WITH RFC[12]
- 21COMPATIBLE WITH RFC[21]
- 23COMPATIBLE WITH RFC[23]
- 25COMPATIBLE WITH RFC[25]
- 1000COMPATIBLE WITH RFC[1000]
Design Notes
ATROPOS required the use of good quality CRISPR guide RNAs (gRNAs). To this end the Dry Lab was tasked with providing a software solution that would generate those gRNAs for our system. After investigating the literature, we discovered an existing solution to the problem of gRNA generation by Wessels et al. [1] and an improved version by Keng et al. [2]. Wessel’s solution called Cas13designGuidePredictor is an R script [3] that takes as input RNA sequences and produces 23-mer gRNAs. It first generates a pool of all possible 23-mers from a reference RNA sequence and then generates a GuideScore value for each based on a Random-Forest AI algorithm. The algorithm is fitted to data provided with the script and then can predict the guide score for any 23-mer given as input. The data consists of 23-mers, calculated physical characteristics (base counts, minimum free energy and others) along with a known GuideScore. The Random-Forest model is able to fit the data and produce GuideScores for 23-mers it has not seen before, given their physical characteristics. Keng improves on this model with Cas13gRNAtor [4]. Cas13gRNAtor is a collection of Python scripts working along with Cas13designGuidePredictor. Except from calculating Wessel’s GuideScore, Cas13gRNAtor filters out offtargets to the human genome and also calculates conservation scored based on a consensus sequence. The consensus RNA sequence is derived by choosing the most common base along all the input sequences. Due to this Cas13gRNAtor requires not only a reference RNA sequence but also as many RNA sequence samples as we can provide. These sequences are first aligned to the reference before being given to Cas13gRNAtor.
The Cas13gRNAtor was chosen to be used by the Dry Lab as it fitted the needs of ATROPOS more directly. Cas13gRNAtor is provided as open source software, but it is not provided in an executable format, only the source code is provided. This means that, in order to utilize it, the user needs to have installed the necessary dependencies. Dependencies are other pieces of software usually open source themselves that the program can not run without, so they have to be downloaded along with their own dependencies. In most cases installing dependencies is easily done, but when the number of dependencies is large this task becomes more difficult. To run Cas13gRNAtor we decided on using a Personal Computer (PC) with the Ubuntu Linux operating system. The workload is low so consumer PC hardware will suffice for running the program, there is no need for High Performance Computing (HPC). Linux as an operating system is supported by both Python and R and makes it easy to find and install any other dependencies we might need.
References
[1] Wessels, H. H., Méndez-Mancilla, A., Guo, X., Legut, M., Daniloski, Z., & Sanjana, N. E. (2020). Massively parallel Cas13 screens reveal principles for guide RNA design. Nature biotechnology, 38(6), 722-727.
[2] Keng, C. T., Yogarajah, T., Lee, R. C. H., Muhammad, I. B. H., Chia, B. S., Vasandani, S. R., ... & Chew, W. L. (2023). AAV-CRISPR-Cas13 eliminates human enterovirus and prevents death of infected mice. EBioMedicine, 93.
[3] https://gitlab.com/sanjanalab/cas13/-/tree/master/Cas13designGuidePredictor
[4] https://github.com/chewlabSB2/Cas13gRNAtor
[5] https://gitlab.igem.org/2024/software-tools/ioannina
[7] https://support.illumina.com/sequencing/sequencing_software/igenome.html
Source
Source:Silvana Konermann Laboratory of Molecular and Cell Biology, Salk Institute for Biological Studies, 10010 N Torrey Pines Rd, La Jolla, CA 92037, USA Direct repeat sequence,firstly identified at Ruminococcus Spacer sequence desingned by iGEM IOANNINA 2024 dry lab team