New techniques for DNA sequence classification

Jason T.L. Wang; Steve Rozen; Bruce A. Shapiro; Dennis Shasha; Zhiyuan Wang; Maisheng Yin

doi:10.1089/cmb.1999.6.209

New techniques for DNA sequence classification

Jason T.L. Wang^*
, Steve Rozen
, Bruce A. Shapiro
, Dennis Shasha
, Zhiyuan Wang
, Maisheng Yin

^*Corresponding author for this work

Research output: Contribution to journal › Journal Article › peer-review

36 Scopus citations

Abstract

DNA sequence classification is the activity of determining whether or not an unlabeled sequence S belongs to an existing class C. This paper proposes two new techniques for DNA sequence classification. The first technique works by comparing the unlabeled sequence S with a group of active motifs discovered from the elements of C and by distinction with elements outside of C. The second technique generates and matches gapped fingerprints of S with elements of C. Experimental results obtained by running these algorithms on long and well conserved Alu sequences demonstrate the good performance of the presented methods compared with FASTA. When applied to less conserved and relatively short functional sites such as splice- junctions, a variation of the second technique combining fingerprinting with consensus sequence analysis gives better results than the current classifiers employing text compression and machine learning algorithms.

Original language	English
Pages (from-to)	209-218
Number of pages	10
Journal	Journal of Computational Biology
Volume	6
Issue number	2
DOIs	https://doi.org/10.1089/cmb.1999.6.209
State	Published - 1999
Externally published	Yes

Keywords

Algorithms
Consensus sequence
DNA sequence recognition
Pattern matching
Tools for computational biology

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10.1089/cmb.1999.6.209

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title = "New techniques for DNA sequence classification",

abstract = "DNA sequence classification is the activity of determining whether or not an unlabeled sequence S belongs to an existing class C. This paper proposes two new techniques for DNA sequence classification. The first technique works by comparing the unlabeled sequence S with a group of active motifs discovered from the elements of C and by distinction with elements outside of C. The second technique generates and matches gapped fingerprints of S with elements of C. Experimental results obtained by running these algorithms on long and well conserved Alu sequences demonstrate the good performance of the presented methods compared with FASTA. When applied to less conserved and relatively short functional sites such as splice- junctions, a variation of the second technique combining fingerprinting with consensus sequence analysis gives better results than the current classifiers employing text compression and machine learning algorithms.",

keywords = "Algorithms, Consensus sequence, DNA sequence recognition, Pattern matching, Tools for computational biology",

author = "Wang, \{Jason T.L.\} and Steve Rozen and Shapiro, \{Bruce A.\} and Dennis Shasha and Zhiyuan Wang and Maisheng Yin",

year = "1999",

doi = "10.1089/cmb.1999.6.209",

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T1 - New techniques for DNA sequence classification

AU - Wang, Jason T.L.

AU - Rozen, Steve

AU - Shapiro, Bruce A.

AU - Shasha, Dennis

AU - Wang, Zhiyuan

AU - Yin, Maisheng

PY - 1999

Y1 - 1999

N2 - DNA sequence classification is the activity of determining whether or not an unlabeled sequence S belongs to an existing class C. This paper proposes two new techniques for DNA sequence classification. The first technique works by comparing the unlabeled sequence S with a group of active motifs discovered from the elements of C and by distinction with elements outside of C. The second technique generates and matches gapped fingerprints of S with elements of C. Experimental results obtained by running these algorithms on long and well conserved Alu sequences demonstrate the good performance of the presented methods compared with FASTA. When applied to less conserved and relatively short functional sites such as splice- junctions, a variation of the second technique combining fingerprinting with consensus sequence analysis gives better results than the current classifiers employing text compression and machine learning algorithms.

AB - DNA sequence classification is the activity of determining whether or not an unlabeled sequence S belongs to an existing class C. This paper proposes two new techniques for DNA sequence classification. The first technique works by comparing the unlabeled sequence S with a group of active motifs discovered from the elements of C and by distinction with elements outside of C. The second technique generates and matches gapped fingerprints of S with elements of C. Experimental results obtained by running these algorithms on long and well conserved Alu sequences demonstrate the good performance of the presented methods compared with FASTA. When applied to less conserved and relatively short functional sites such as splice- junctions, a variation of the second technique combining fingerprinting with consensus sequence analysis gives better results than the current classifiers employing text compression and machine learning algorithms.

KW - Algorithms

KW - Consensus sequence

KW - DNA sequence recognition

KW - Pattern matching

KW - Tools for computational biology

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DO - 10.1089/cmb.1999.6.209

M3 - 文章

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AN - SCOPUS:0033052632

SN - 1066-5277

VL - 6

SP - 209

EP - 218

JO - Journal of Computational Biology

JF - Journal of Computational Biology

IS - 2

ER -

New techniques for DNA sequence classification

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Keywords

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