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    gpuPairHMM accelerates DNA variant calling by optimizing pairwise sequence alignments using a novel GPU parallelization. This significantly speeds up processing of large DNA datasets compared to previous methods.

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    Area of Science:

    • Bioinformatics
    • Computational Biology
    • Genomics

    Background:

    • Increasing DNA sequence data volume necessitates faster core algorithms.
    • Pairwise sequence alignment using Pair-HMMs is crucial for DNA variant calling but computationally intensive.
    • Existing GPU acceleration methods for Pair-HMMs suffer from inefficient memory access.

    Purpose of the Study:

    • To develop a significantly faster GPU-based solution for Pair-HMM computations.
    • To address the limitations of previous GPU acceleration approaches for sequence alignment.

    Main Methods:

    • Introduced gpuPairHMM, a novel GPU parallelization scheme for the Pair-HMM forward algorithm.
    • Utilized wavefronts and warp-shuffles to minimize memory accesses and instructions.
    • Implemented on multiple generations of CUDA-enabled GPUs (Volta, Ampere, Ada, Hopper, Blackwell).

    Main Results:

    • Achieved close-to-peak performance on various modern GPUs.
    • Outperformed prior GPU implementations by at least 11.7x.
    • Demonstrated superior performance over CPU and FPGA implementations by 14.2x and 19.8x, respectively.

    Conclusions:

    • gpuPairHMM offers a substantial speedup for Pair-HMM based sequence alignment.
    • The novel parallelization scheme effectively overcomes memory access limitations in GPU computing.
    • This advancement significantly enhances the efficiency of DNA variant calling tools.