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Literature DB >> 6174935

Efficient algorithms for folding and comparing nucleic acid sequences.

Abstract

Fast algorithms for analysing sequence data are presented. An algorithm for strict homologies finds all common subsequences of length greater than or equal to 6 in two given sequences. With it, nucleic acid pieces five thousand nucleotides long can be compared in five seconds on CDC 6600. Secondary structure algorithms generate the N most stable secondary structures of an RNA molecule, taking into account all loop contributions, and the formation of all possible base-pairs in stems, including odd pairs (G.G., C.U., etc.). They allow a typical 100-nucleotide sequence to be analysed in 10 seconds. The homology and secondary structure programs are respectively illustrated with a comparison of two phage genomes, and a discussion of Drosophila melanogaster 55 RNA folding.

Entities: Species

Mesh：

Substances：
RNA, Viral
RNA
DNA

Year: 1982 PMID： 6174935 PMCID： PMC326126 DOI： 10.1093/nar/10.1.197

Source DB: PubMed Journal: Nucleic Acids Res ISSN： 0305-1048 Impact factor: 16.971

23 in total

1. Computer method for predicting the secondary structure of single-stranded RNA.

Authors: G M Studnicka; G M Rahn; I W Cummings; W A Salser
Journal: Nucleic Acids Res Date: 1978-09 Impact factor: 16.971

2. Method for predicting RNA secondary structure.

Authors: J M Pipas; J E McMahon
Journal: Proc Natl Acad Sci U S A Date: 1975-06 Impact factor: 11.205

3. Sequence of Drosophila 5S RNA synthesized by cultured cells and by the insect at different developmental stages. Homogeneity of the product and homologies with other 5S RNA's at the level of primary and secondary structure.

Authors: J Benhamou; R Jourdan; B R Jordan
Journal: J Mol Evol Date: 1977-05-13 Impact factor: 2.395

Efficient algorithms for folding and comparing nucleic acid sequences.

1. Computer method for predicting the secondary structure of single-stranded RNA.

2. Method for predicting RNA secondary structure.

3. Sequence of Drosophila 5S RNA synthesized by cultured cells and by the insect at different developmental stages. Homogeneity of the product and homologies with other 5S RNA's at the level of primary and secondary structure.

4. Nucleotide sequence of 5 S RNA from Torulopsis utilis.

5. The nucleotide sequence of 5 S rRNA from the blue-green alga Anacystis nidulans.

6. Properties of nucleic acid representations. I. Topology.

7. Secondary structure of Qbeta RNA.

8. Nucleotide sequence of bacteriophage G4 DNA.

9. Sequence data handling by computer.

10. An improved method of testing for evolutionary homology.

1. The folding of large RNAs studied by hybridization to arrays of complementary oligonucleotides.

2. Statistical analysis of nucleotide sequences.

3. A survey of multiple sequence comparison methods.

4. Sequence alignments in the neighborhood of the optimum with general application to dynamic programming.

5. Consistency of optimal sequence alignments.

6. K-tuple frequency in the human genome and polymerase chain reaction.

7. Cooperation of Spaln and Prrn5 for Construction of Gene-Structure-Aware Multiple Sequence Alignment.

8. A dynamic programming algorithm for finding alternative RNA secondary structures.

9. Multisequence comparisons in protein coding genes. Search for functional constraints.

10. Cgaln: fast and space-efficient whole-genome alignment.