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    Area of Science:

    • Computational Biology
    • Bioinformatics
    • Parallel Computing

    Background:

    • k-mismatch shortest unique substring (SUS) queries are crucial for analyzing biological sequences.
    • Existing methods focus on sequential CPU computation, facing challenges with large datasets.
    • Efficiently computing SUS for all positions in long strings remains a significant computational hurdle.

    Purpose of the Study:

    • To develop the first parallel algorithm for k-mismatch SUS queries.
    • To leverage graphic processing unit (GPU) technology for accelerated SUS computation.
    • To provide a practical and efficient tool for analyzing massive biological strings.

    Main Methods:

    • Designed a parallel algorithm utilizing the multi-threading capabilities of GPUs.
    • Implemented and tested the algorithm on real-world DNA sequence data.
    • Compared performance against state-of-the-art sequential CPU-based SUS query methods.

    Main Results:

    • Achieved speedups of at least 6x for exact (k=0) SUS queries on a GPU.
    • Demonstrated speedups of at least 23x for approximate (k>0) SUS queries on DNA sequences.
    • Maintained comparable memory usage to the most memory-efficient sequential CPU approaches.

    Conclusions:

    • The proposed GPU-based parallel approach offers significant performance improvements for k-mismatch SUS queries.
    • This work presents the first practical solution for approximate SUS computation on large biological sequences.
    • The GPU acceleration makes SUS analysis feasible for massive datasets where CPU methods are too slow.