5,251 research outputs found
Prospects and limitations of full-text index structures in genome analysis
The combination of incessant advances in sequencing technology producing large amounts of data and innovative bioinformatics approaches, designed to cope with this data flood, has led to new interesting results in the life sciences. Given the magnitude of sequence data to be processed, many bioinformatics tools rely on efficient solutions to a variety of complex string problems. These solutions include fast heuristic algorithms and advanced data structures, generally referred to as index structures. Although the importance of index structures is generally known to the bioinformatics community, the design and potency of these data structures, as well as their properties and limitations, are less understood. Moreover, the last decade has seen a boom in the number of variant index structures featuring complex and diverse memory-time trade-offs. This article brings a comprehensive state-of-the-art overview of the most popular index structures and their recently developed variants. Their features, interrelationships, the trade-offs they impose, but also their practical limitations, are explained and compared
SOAP3-dp: Fast, Accurate and Sensitive GPU-based Short Read Aligner
To tackle the exponentially increasing throughput of Next-Generation
Sequencing (NGS), most of the existing short-read aligners can be configured to
favor speed in trade of accuracy and sensitivity. SOAP3-dp, through leveraging
the computational power of both CPU and GPU with optimized algorithms, delivers
high speed and sensitivity simultaneously. Compared with widely adopted
aligners including BWA, Bowtie2, SeqAlto, GEM and GPU-based aligners including
BarraCUDA and CUSHAW, SOAP3-dp is two to tens of times faster, while
maintaining the highest sensitivity and lowest false discovery rate (FDR) on
Illumina reads with different lengths. Transcending its predecessor SOAP3,
which does not allow gapped alignment, SOAP3-dp by default tolerates alignment
similarity as low as 60 percent. Real data evaluation using human genome
demonstrates SOAP3-dp's power to enable more authentic variants and longer
Indels to be discovered. Fosmid sequencing shows a 9.1 percent FDR on newly
discovered deletions. SOAP3-dp natively supports BAM file format and provides a
scoring scheme same as BWA, which enables it to be integrated into existing
analysis pipelines. SOAP3-dp has been deployed on Amazon-EC2, NIH-Biowulf and
Tianhe-1A.Comment: 21 pages, 6 figures, submitted to PLoS ONE, additional files
available at "https://www.dropbox.com/sh/bhclhxpoiubh371/O5CO_CkXQE".
Comments most welcom
The Parallelism Motifs of Genomic Data Analysis
Genomic data sets are growing dramatically as the cost of sequencing
continues to decline and small sequencing devices become available. Enormous
community databases store and share this data with the research community, but
some of these genomic data analysis problems require large scale computational
platforms to meet both the memory and computational requirements. These
applications differ from scientific simulations that dominate the workload on
high end parallel systems today and place different requirements on programming
support, software libraries, and parallel architectural design. For example,
they involve irregular communication patterns such as asynchronous updates to
shared data structures. We consider several problems in high performance
genomics analysis, including alignment, profiling, clustering, and assembly for
both single genomes and metagenomes. We identify some of the common
computational patterns or motifs that help inform parallelization strategies
and compare our motifs to some of the established lists, arguing that at least
two key patterns, sorting and hashing, are missing
Indexing large genome collections on a PC
Motivation: The availability of thousands of invidual genomes of one species
should boost rapid progress in personalized medicine or understanding of the
interaction between genotype and phenotype, to name a few applications. A key
operation useful in such analyses is aligning sequencing reads against a
collection of genomes, which is costly with the use of existing algorithms due
to their large memory requirements.
Results: We present MuGI, Multiple Genome Index, which reports all
occurrences of a given pattern, in exact and approximate matching model,
against a collection of thousand(s) genomes. Its unique feature is the small
index size fitting in a standard computer with 16--32\,GB, or even 8\,GB, of
RAM, for the 1000GP collection of 1092 diploid human genomes. The solution is
also fast. For example, the exact matching queries are handled in average time
of 39\,s and with up to 3 mismatches in 373\,s on the test PC with
the index size of 13.4\,GB. For a smaller index, occupying 7.4\,GB in memory,
the respective times grow to 76\,s and 917\,s.
Availability: Software and Suuplementary material:
\url{http://sun.aei.polsl.pl/mugi}
Parallel approach to sliding window sums
Sliding window sums are widely used in bioinformatics applications, including
sequence assembly, k-mer generation, hashing and compression. New vector
algorithms which utilize the advanced vector extension (AVX) instructions
available on modern processors, or the parallel compute units on GPUs and
FPGAs, would provide a significant performance boost for the bioinformatics
applications. We develop a generic vectorized sliding sum algorithm with
speedup for window size w and number of processors P is O(P/w) for a generic
sliding sum. For a sum with commutative operator the speedup is improved to
O(P/log(w)). When applied to the genomic application of minimizer based k-mer
table generation using AVX instructions, we obtain a speedup of over 5X.Comment: 10 pages, 5 figure
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