Improving bacterial genome assembly using a test of strand orientation

Greenberg, Grant; Shomorony, Ilan

doi:10.1093/bioinformatics/btac516

Cited by 2 publications

(1 citation statement)

References 29 publications

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“…In [52] The computational burden of algorithm is alleviated by utilizing the LexicHash method to estimate sequence similarities. To achieve this, the algorithm performs a hash function on each k-mer within the read sequence and stores the minimum hash value.…”

Section: Literature Reviewmentioning

confidence: 99%

PSALR: Parallel Sequence Alignment for long Sequence Read with Hash model

Nasrin,

Amin,

Sima

et al. 2024

Preprint

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Sequence alignment and genome mapping pose significant challenges, primarily focusing on speed and storage space requirements for mapped sequences. With the ever-increasing volume of DNA sequence data, it becomes imperative to develop efficient alignment methods that not only reduce storage demands but also offer rapid alignment. This study introduces the Parallel Sequence Alignment with a Hash-Based Model (PSALR) algorithm, specifically designed to enhance alignment speed and optimize storage space while maintaining utmost accuracy. In contrast to other algorithms like BLAST, PSALR efficiently indexes data using a hash table, resulting in reduced computational load and processing time. This algorithm utilizes data compression and packetization with conventional bandwidth sizes, distributing data among different nodes to reduce memory and transfer time. Upon receiving compressed data, nodes can seamlessly perform searching and mapping, eliminating the need for unpacking and decoding at the destination. As an additional innovation, PSALR not only divides sequences among processors but also breaks down large sequences into sub-sequences, forwarding them to nodes. This approach eliminates any restrictions on query length sent to nodes, and evaluation results are returned directly to the user without central node involvement. Another notable feature of PSALR is its utilization of overlapping sub-sequences within both query and reference sequences. This ensures that the search and mapping process includes all possible sub-sequences of the target sequence, rather than being limited to a subset. Performance tests indicate that the PSALR algorithm outperforms its counterparts, positioning it as a promising solution for efficient sequence alignment and genome mapping.

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Section: Literature Reviewmentioning

confidence: 99%

PSALR: Parallel Sequence Alignment for long Sequence Read with Hash model

Nasrin,

Amin,

Sima

et al. 2024

Preprint

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Genome-mining algorithm to identify identical repetitive sequences for sensitive and specific diagnostic assays for infectious diseases

Rajeswari,

Poojary,

Padiwal

et al. 2024

Preprint

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Nucleic acid amplification-based approaches are extensively used as the first line of choice for infectious diseases. However, the success rates of DNA amplification or hybridization techniques are highly dependent on short primer or probe sequences. A pair of primers that can bind at multiple loci across the genome and randomly amplify multiple copies increases the analytical sensitivity of the currently used diagnostic assays. Herein, we developed a novel genome mining algorithm to identify short identical repeat sequences (IRSs) dispersed across the genome, which can amplify multiple nonhomologous regions of variable sizes via three potential priming combinations. Using this algorithm, we analysed the genomes of five pathogens, namely, gammaherpesvirus, vaccinia virus, Mycobacterium tuberculosis, Plasmodium falciparum, and Phytophthora palmivora, and identified short identical sequences that were repeated at multiple loci. In silico PCR revealed that these identical repeat sequences can amplify multiple copies with different amplicon sizes in these five species. We further performed a polymerase chain reaction assay with short identical repeat pairs identified from M. tuberculosis. Very interestingly, the amplification yielded multiple copies for individual IRSs and even more copies, as in a pair of IRSs. These results indicate that the IRS-based approach can detect pathogens during disease progression in the case of low-concentration DNA. The genome mining algorithm can be used as a translation technology platform for developing highly sensitive varieties of PCR, microarray, loop-mediated isothermal amplification, fluorescence in situ hybridization, and DNA‒DNA hybridization-based diagnostic assays.

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Improving bacterial genome assembly using a test of strand orientation

Cited by 2 publications

References 29 publications

PSALR: Parallel Sequence Alignment for long Sequence Read with Hash model

PSALR: Parallel Sequence Alignment for long Sequence Read with Hash model

Genome-mining algorithm to identify identical repetitive sequences for sensitive and specific diagnostic assays for infectious diseases

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