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- Title
An application of slow feature analysis to the genetic sequences of coronaviruses and influenza viruses.
- Authors
Tsonis, Anastasios A.; Wang, Geli; Zhang, Lvyi; Lu, Wenxu; Kayafas, Aristotle; Del Rio-Tsonis, Katia
- Abstract
Background: Mathematical approaches have been for decades used to probe the structure of DNA sequences. This has led to the development of Bioinformatics. In this exploratory work, a novel mathematical method is applied to probe the DNA structure of two related viral families: those of coronaviruses and those of influenza viruses. The coronaviruses are SARS-CoV-2, SARS-CoV-1, and MERS. The influenza viruses include H1N1-1918, H1N1-2009, H2N2-1957, and H3N2-1968. Methods: The mathematical method used is the slow feature analysis (SFA), a rather new but promising method to delineate complex structure in DNA sequences. Results: The analysis indicates that the DNA sequences exhibit an elaborate and convoluted structure akin to complex networks. We define a measure of complexity and show that each DNA sequence exhibits a certain degree of complexity within itself, while at the same time there exists complex inter-relationships between the sequences within a family and between the two families. From these relationships, we find evidence, especially for the coronavirus family, that increasing complexity in a sequence is associated with higher transmission rate but with lower mortality. Conclusions: The complexity measure defined here may hold a promise and could become a useful tool in the prediction of transmission and mortality rates in future new viral strains.
- Publication
Human Genomics, 2021, Vol 15, Issue 1, p1
- ISSN
1473-9542
- Publication type
Article
- DOI
10.1186/s40246-021-00327-2